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Am 1806

AM1806 ARM Microprocessor

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37 views247 pages

Am 1806

AM1806 ARM Microprocessor

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Laurentiu Mandru
Copyright
© © All Rights Reserved
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AM1806
SPRS658F – FEBRUARY 2010 – REVISED MARCH 2014

AM1806 ARM® Microprocessor


1 AM1806 ARM Microprocessor

1.1
1
Features
• 375- and 456-MHz ARM926EJ-S™ RISC MPU Output of the PRU Cores.
• Enhanced Direct Memory Access Controller 3 – Standard Power-Management Mechanism
(EDMA3): • Clock Gating
– 2 Channel Controllers • Entire Subsystem Under a Single PSC Clock
– 3 Transfer Controllers Gating Domain
– 64 Independent DMA Channels – Dedicated Interrupt Controller
– 16 Quick DMA Channels – Dedicated Switched Central Resource
– Programmable Transfer Burst Size • USB 2.0 OTG Port with Integrated PHY (USB0)
• 1.8-V or 3.3-V LVCMOS I/Os (Except for USB and – USB 2.0 High- and Full-Speed Client
DDR2 Interfaces) – USB 2.0 High-, Full-, and Low-Speed Host
• Two External Memory Interfaces: – End Point 0 (Control)
– EMIFA – End Points 1,2,3,4 (Control, Bulk, Interrupt or
• NOR (8- or 16-Bit-Wide Data) ISOC) RX and TX
• NAND (8- or 16-Bit-Wide Data) • One Multichannel Audio Serial Port (McASP):
• 16-Bit SDRAM with 128-MB Address Space – Transmit and Receive Clocks
– DDR2/Mobile DDR Memory Controller with one – Two Clock Zones and 16 Serial Data Pins
of the following: – Supports TDM, I2S, and Similar Formats
• 16-Bit DDR2 SDRAM with 256-MB Address – DIT-Capable
Space – FIFO Buffers for Transmit and Receive
• 16-Bit mDDR SDRAM with 256-MB Address • Two Multichannel Buffered Serial Ports (McBSPs):
Space – Transmit and Receive Clocks
• Three Configurable 16550-Type UART Modules: – Supports TDM, I2S, and Similar Formats
– With Modem Control Signals – AC97 Audio Codec Interface
– 16-Byte FIFO – Telecom Interfaces (ST-Bus, H100)
– 16x or 13x Oversampling Option – 128-Channel TDM
• LCD Controller – FIFO Buffers for Transmit and Receive
• Two Serial Peripheral Interfaces (SPIs) Each with • Video Port Interface (VPIF):
Multiple Chip Selects – Two 8-Bit SD (BT.656), Single 16-Bit or Single
• Two Multimedia Card (MMC)/Secure Digital (SD) Raw (8-, 10-, and 12-Bit) Video Capture
Card Interfaces with Secure Data I/O (SDIO) Channels
Interfaces – Two 8-Bit SD (BT.656), Single 16-Bit Video
• Two Master and Slave Inter-Integrated Circuits Display Channels
( I2C Bus™) • Universal Parallel Port (uPP):
• One Host-Port Interface (HPI) with 16-Bit-Wide – High-Speed Parallel Interface to FPGAs and
Muxed Address and Data Bus For High Bandwidth Data Converters
• Programmable Real-Time Unit Subsystem – Data Width on Both Channels is 8- to 16-Bit
(PRUSS) Inclusive
– Two Independent Programmable Real-Time Unit – Single-Data Rate or Dual-Data Rate Transfers
(PRU) Cores
– Supports Multiple Interfaces with START,
• 32-Bit Load-Store RISC Architecture ENABLE, and WAIT Controls
• 4KB of Instruction RAM per Core • Real-Time Clock (RTC) with 32-kHz Oscillator and
• 512 Bytes of Data RAM per Core Separate Power Rail
• PRUSS can be Disabled via Software to • Three 64-Bit General-Purpose Timers (Each
Save Power Configurable as Two 32-Bit Timers)
• Register 30 of Each PRU is Exported from • One 64-Bit General-Purpose or Watchdog Timer
the Subsystem in Addition to the Normal R31 (Configurable as Two 32-Bit General-Purpose
1

An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
AM1806
SPRS658F – FEBRUARY 2010 – REVISED MARCH 2014 www.ti.com

Timers) • Three 32-Bit Enhanced Capture (eCAP) Modules:


• Two Enhanced High-Resolution Pulse Width – Configurable as 3 Capture Inputs or 3 Auxiliary
Modulators (eHRPWMs): Pulse Width Modulator (APWM) Outputs
– Dedicated 16-Bit Time-Base Counter with – Single-Shot Capture of up to Four Event Time-
Period and Frequency Control Stamps
– 6 Single-Edge Outputs, 6 Dual-Edge Symmetric • 361-Ball Pb-Free Plastic Ball Grid Array (PBGA)
Outputs, or 3 Dual-Edge Asymmetric Outputs [ZCE Suffix], 0.65-mm Ball Pitch
– Dead-Band Generation • 361-Ball Pb-Free PBGA [ZWT Suffix], 0.80-mm
– PWM Chopping by High-Frequency Carrier Ball Pitch
– Trip Zone Input • Commercial or Extended Temperature

1.2 Applications
• Gaming • Data Concentrators
• Medical, Healthcare, Fitness • Building Automation
• Printers • Set Top Box
• ePOS • Industrial Automation

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1.3 Description
The AM1806 ARM Microprocessor is a low-power applications processor based on ARM926EJ-S.
The device enables original-equipment manufacturers (OEMs) and original-design manufacturers (ODMs)
to quickly bring to market devices featuring robust operating systems support, rich user interfaces, and
high processing performance life through the maximum flexibility of a fully integrated mixed processor
solution.
The ARM926EJ-S is a 32-bit RISC processor core that performs 32-bit or 16-bit instructions and
processes 32-bit, 16-bit, or 8-bit data. The core uses pipelining so that all parts of the processor and
memory system can operate continuously.
The ARM core has a coprocessor 15 (CP15), protection module, and data and program memory
management units (MMUs) with table look-aside buffers. The ARM core processor has separate 16-KB
instruction and 16-KB data caches. Both are four-way associative with virtual index virtual tag (VIVT). The
ARM core also has 8KB of RAM (Vector Table) and 64KB of ROM.
The peripheral set includes: one USB2.0 OTG interface; two inter-integrated circuit (I2C Bus) interfaces;
one multichannel audio serial port (McASP) with 16 serializers and FIFO buffers; two multichannel
buffered serial ports (McBSPs) with FIFO buffers; two serial peripheral interfaces (SPIs) with multiple chip
selects; four 64-bit general-purpose timers each configurable (one configurable as watchdog); a
configurable 16-bit host-port interface (HPI); up to 9 banks of general-purpose input/output (GPIO) pins,
with each bank containing 16 pins with programmable interrupt and event generation modes, multiplexed
with other peripherals; three UART interfaces (each with RTS and CTS); two enhanced high-resolution
pulse width modulator (eHRPWM) peripherals; three 32-bit enhanced capture (eCAP) module peripherals
which can be configured as 3 capture inputs or 3 auxiliary pulse width modulator (APWM) outputs; two
external memory interfaces; an asynchronous and SDRAM external memory interface (EMIFA) for slower
memories or peripherals; and a higher speed DDR2/Mobile DDR controller.
The universal parallel port (uPP) provides a high-speed interface to many types of data converters,
FPGAs or other parallel devices. The uPP supports programmable data widths between 8- to 16-bits on
both channels. Single-data rate and double-data rate transfers are supported as well as START, ENABLE,
and WAIT signals to provide control for a variety of data converters.
A video port interface (VPIF) is included providing a flexible video I/O port.
The rich peripheral set provides the ability to control external peripheral devices and communicate with
external processors. For details on each of the peripherals, see the related sections in this document and
the associated peripheral reference guides.
The device has a complete set of development tools for the ARM processor. These tools include C
compilers, and scheduling, and a Windows® debugger interface for visibility into source code execution.

Device Information
PART NUMBER PACKAGE BODY SIZE
AM1806ZCE NFBGA (361) 13,00 mm x 13,00 mm
AM1806ZWT NFBGA (361) 16,00 mm x 16,00 mm

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1.4 Functional Block Diagram


Figure 1-1 shows the functional block diagram of the device.

JTAG Interface ARM Subsystem

System Control
ARM926EJ-S CPU
PLL/Clock With MMU
Input
Clock(s) Generator Memory
w/OSC Protection 4KB ETB
General-
Purpose 16KB 16KB
Timer (x3) I-Cache D-Cache
Power/Sleep
Controller 8KB RAM
RTC/ (Vector Table)
32-kHz Pin
OSC Multiplexing 64KB ROM

Switched Central Resource (SCR)

Peripherals
DMA Audio Ports Serial Interfaces Display Video Parallel Port Internal Memory Customizable Interface

EDMA3 McASP McBSP I2C SPI UART LCD


VPIF uPP 128KB PRU Subsystem
(x2) w/FIFO (x2) (x2) (x2) (x3) Ctlr RAM

Control Timers Connectivity External Memory Interfaces

ePWM eCAP USB2.0 MMC/SD EMIFA(8b/16B)


(8b) DDR2/MDDR
(x2) (x3) OTG Ctlr HPI NAND/Flash
(x2) Controller
PHY 16b SDRAM

(1) Note: Not all peripherals are available at the same time due to multiplexing.

Figure 1-1. Functional Block Diagram

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Table of Contents
1 AM1806 ARM Microprocessor......................... 1 6.8 Power and Sleep Controller (PSC) .................. 82
1.1 Features .............................................. 1 6.9 EDMA ............................................... 87
1.2 Applications ........................................... 2 6.10 External Memory Interface A (EMIFA) .............. 93
1.3 Description ............................................ 3 6.11 DDR2/mDDR Memory Controller .................. 104
1.4 Functional Block Diagram ............................ 4 6.12 Memory Protection Units .......................... 117
2 Revision History ......................................... 6 6.13 MMC / SD / SDIO (MMCSD0, MMCSD1) ......... 120
3 Device Overview ......................................... 7 6.14 Multichannel Audio Serial Port (McASP) .......... 123
3.1 Device Characteristics ................................ 7 6.15 Multichannel Buffered Serial Port (McBSP)........ 132
3.2 Device Compatibility .................................. 8 6.16 Serial Peripheral Interface Ports (SPI0, SPI1) ..... 141
3.3 ARM Subsystem ...................................... 8 6.17 Inter-Integrated Circuit Serial Ports (I2C) ..........
162
3.4 Memory Map Summary ............................. 11 6.18 Universal Asynchronous Receiver/Transmitter
3.5 Pin Assignments .................................... 14 (UART) ............................................. 166
6.19 Universal Serial Bus OTG Controller (USB0)
3.6 Pin Multiplexing Control ............................. 17
[USB2.0 OTG] ..................................... 168
3.7 Terminal Functions .................................. 18
6.20 LCD Controller (LCDC) ............................ 175
3.8 Unused Pin Configurations.......................... 54
6.21 Host-Port Interface (UHPI) ......................... 190
4 Device Configuration .................................. 55
6.22 Universal Parallel Port (uPP) ...................... 198
4.1 Boot Modes ......................................... 55
6.23 Video Port Interface (VPIF) ........................ 203
4.2 SYSCFG Module .................................... 55
6.24 Enhanced Capture (eCAP) Peripheral............. 208
4.3 Pullup/Pulldown Resistors .......................... 58
6.25 Enhanced High-Resolution Pulse-Width Modulator
5 Specifications ........................................... 59 (eHRPWM) ......................................... 211
5.1 Absolute Maximum Ratings Over Operating 6.26 Timers .............................................. 216
Junction Temperature Range
(Unless Otherwise Noted) ................................. 59 6.27 Real Time Clock (RTC) ............................ 218
5.2 Handling Ratings .................................... 59 6.28 General-Purpose Input/Output (GPIO)............. 221
6.29 Programmable Real-Time Unit Subsystem (PRUSS)
5.3 Recommended Operating Conditions ............... 60
..................................................... 225
5.4 Notes on Recommended Power-On Hours (POH) . 62
6.30 Emulation Logic .................................... 228
5.5 Electrical Characteristics Over Recommended
Ranges of Supply Voltage and Operating Junction 7 Device and Documentation Support .............. 236
Temperature (Unless Otherwise Noted) ............ 63 7.1 Device Support..................................... 236
6 Peripheral Information and Electrical 7.2 Documentation Support ............................ 237
Specifications ........................................... 64 7.3 Community Resources............................. 237
6.1 Parameter Information .............................. 64 7.4 Trademarks ........................................ 237
6.2 Recommended Clock and Control Signal Transition 7.5 Electrostatic Discharge Caution ................... 238
Behavior ............................................. 65
7.6 Glossary............................................ 238
6.3 Power Supplies ...................................... 65
8 Mechanical Packaging and Orderable
6.4 Reset ................................................ 66 Information ............................................. 238
6.5 Crystal Oscillator or External Clock Input ........... 70 8.1 Thermal Data for ZCE Package ................... 238
6.6 Clock PLLs .......................................... 71 8.2 Thermal Data for ZWT Package ................... 239
6.7 Interrupts ............................................ 76

Copyright © 2010–2014, Texas Instruments Incorporated Table of Contents 5


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2 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.

This data manual revision history highlights the changes made to the SPRS658E device-specific data
manual to make it an SPRS658F revision.
Revision History
SEE ADDITIONS/MODIFICATIONS/DELETIONS
• Moved Trademarks information from first page to within Section 7, Device and Documentation
Support.
Global
• Moved ESDS Warning to within Section 7, Device and Documentation Support.
• Updated Features, Applications, and Description for consistency and translation.
Section 1.3
Added NEW Device Information Table.
Description
Table 3-3 thru Table 3-25:
Section 3.7
Terminal Functions • Updated/Changed footnote beginning with "IPD = Internal Pulldown resistor..."; added
sentence "For more detailed information on pullup/pulldown..."
Section 3.7.17 Table 3-19, Universal Serial Bus (USB) Terminal Functions
Universal Serial Bus Modules • Updated/Changed the capacitor value in USB0_VDDA12 pin DESCRIPTION from "1 μF" to
(USB0) "0.22-μF"
Table 3-28, Unused USB0 Signal Configurations:
Section 3.8
Unused Pin Configurations • Updated/Changed USB0_VDDA12 row text from "No Connect" to "...to an external 0.22-μF
filter capacitor"
Updated/Changed title from "Device Operating Conditions" to "Specifications"
Section 5 Section 5.2, Handling Ratings:
Specifications • Split handling, ratings, and certifications from the Abs Max table and placed in NEW Handling
Ratings table.
Section 5.4 Table 5-1, Recommended Power-On Hours:
Notes on Recommended
Power-On Hours • Updated/Changed all applicable Silicon Revisions from "B" to "B/E"

Figure 6-12, Asynchronous Memory Read Timing for EMIFA:


Section 6.10.5 • Added vertical lines to show difference between Setup, Strobe, and Hold
EMIFA Electrical/Timing Figure 6-13, Asynchronous Memory Write Timing for EMIFA:
• Added vertical lines to show difference between Setup, Strobe, and Hold
Section 7.1.2 Figure 7-1, Device Nomenclature:
Device and Development-
Support Tool Nomenclature • Added "E = Silicon Revision 2.3" under SILICON REVISION

Section 7.6
Added NEW section.
Glossary

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3 Device Overview
3.1 Device Characteristics
Table 3-1 provides an overview of the device. The table shows significant features of the device, including
the capacity of on-chip RAM, peripherals, and the package type with pin count.

Table 3-1. Characteristics of the Device


HARDWARE FEATURES AM1806
DDR2, 16-bit bus width, up to 156 MHz
DDR2/mDDR Controller
Mobile DDR, 16-bit bus width, up to 150 MHz
Asynchronous (8/16-bit bus width) RAM, Flash,
EMIFA
16-bit SDRAM, NOR, NAND
Flash Card Interface MMC and SD cards supported
64 independent channels, 16 QDMA channels,
EDMA3
2 channel controllers, 3 transfer controllers
4 64-Bit General Purpose (each configurable as 2 separate
Timers
32-bit timers, one configurable as Watch Dog)
Peripherals UART 3 (each with RTS and CTS flow control)
Not all peripherals pins SPI 2 (Each with one hardware chip select)
are available at the I2C 2 (both Master/Slave)
same time (for more
detail, see the Device Multichannel Audio Serial Port [McASP] 1 (each with transmit/receive, FIFO buffer, 16 serializers)
Configurations section). Multichannel Buffered Serial Port [McBSP] 2 (each with transmit/receive, FIFO buffer, 16)
4 Single Edge, 4 Dual Edge Symmetric, or
eHRPWM
2 Dual Edge Asymmetric Outputs
USB 2.0 (USB0) High-Speed OTG Controller with on-chip OTG PHY
General-Purpose Input/Output Port 9 banks of 16-bit
LCD Controller 1
Universal Parallel Port (uPP) 1
Video Port Interface (VPIF) 1 (video in and video out)
PRU Subsystem (PRUSS) 2 Programmable PRU Cores
Size (Bytes) 168KB RAM
ARM
16KB I-Cache
On-Chip Memory 16KB D-Cache
Organization 8KB RAM (Vector Table)
64KB ROM
ADDITIONAL MEMORY
128KB RAM
JTAG BSDL_ID DEVIDR0 Register 0x0B7D_102F
CPU Frequency MHz ARM926 375 MHz (1.2V) or 456 MHz (1.3V)
1.2 V nominal for 375 MHz version
Core (V)
Voltage 1.3 V nominal for 456 MHz version
I/O (V) 1.8V or 3.3 V
13 mm x 13 mm, 361-Ball 0.65 mm pitch, PBGA (ZCE)
Packages
16 mm x 16 mm, 361-Ball 0.80 mm pitch, PBGA (ZWT)
Product Preview (PP),
375 MHz versions - PD
Product Status (1) Advance Information (AI),
456 MHz versions - PD
or Production Data (PD)
(1) PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not necessarily include testing of all parameters.

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3.2 Device Compatibility


The ARM926EJ-S RISC CPU is compatible with other ARM9 CPUs from ARM Holdings plc.

3.3 ARM Subsystem


The ARM Subsystem includes the following features:
• ARM926EJ-S RISC processor
• ARMv5TEJ (32/16-bit) instruction set
• Little endian
• System Control Co-Processor 15 (CP15)
• MMU
• 16KB Instruction cache
• 16KB Data cache
• Write Buffer
• Embedded Trace Module and Embedded Trace Buffer (ETM/ETB)
• ARM Interrupt controller

3.3.1 ARM926EJ-S RISC CPU


The ARM Subsystem integrates the ARM926EJ-S processor. The ARM926EJ-S processor is a member of
ARM9 family of general-purpose microprocessors. This processor is targeted at multi-tasking applications
where full memory management, high performance, low die size, and low power are all important. The
ARM926EJ-S processor supports the 32-bit ARM and 16 bit THUMB instruction sets, enabling the user to
trade off between high performance and high code density. Specifically, the ARM926EJ-S processor
supports the ARMv5TEJ instruction set, which includes features for efficient execution of Java byte codes,
providing Java performance similar to Just in Time (JIT) Java interpreter, but without associated code
overhead.
The ARM926EJ-S processor supports the ARM debug architecture and includes logic to assist in both
hardware and software debug. The ARM926EJ-S processor has a Harvard architecture and provides a
complete high performance subsystem, including:
• ARM926EJ -S integer core
• CP15 system control coprocessor
• Memory Management Unit (MMU)
• Separate instruction and data caches
• Write buffer
• Separate instruction and data (internal RAM) interfaces
• Separate instruction and data AHB bus interfaces
• Embedded Trace Module and Embedded Trace Buffer (ETM/ETB)
For more complete details on the ARM9, refer to the ARM926EJ-S Technical Reference Manual, available
at http://www.arm.com

3.3.2 CP15
The ARM926EJ-S system control coprocessor (CP15) is used to configure and control instruction and
data caches, Memory Management Unit (MMU), and other ARM subsystem functions. The CP15 registers
are programmed using the MRC and MCR ARM instructions, when the ARM in a privileged mode such as
supervisor or system mode.

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3.3.3 MMU
A single set of two level page tables stored in main memory is used to control the address translation,
permission checks and memory region attributes for both data and instruction accesses. The MMU uses a
single unified Translation Lookaside Buffer (TLB) to cache the information held in the page tables. The
MMU features are:
• Standard ARM architecture v4 and v5 MMU mapping sizes, domains and access protection scheme.
• Mapping sizes are:
– 1MB (sections)
– 64KB (large pages)
– 4KB (small pages)
– 1KB (tiny pages)
• Access permissions for large pages and small pages can be specified separately for each quarter of
the page (subpage permissions)
• Hardware page table walks
• Invalidate entire TLB, using CP15 register 8
• Invalidate TLB entry, selected by MVA, using CP15 register 8
• Lockdown of TLB entries, using CP15 register 10

3.3.4 Caches and Write Buffer


The size of the Instruction cache is 16KB, Data cache is 16KB. Additionally, the caches have the following
features:
• Virtual index, virtual tag, and addressed using the Modified Virtual Address (MVA)
• Four-way set associative, with a cache line length of eight words per line (32-bytes per line) and with
two dirty bits in the Dcache
• Dcache supports write-through and write-back (or copy back) cache operation, selected by memory
region using the C and B bits in the MMU translation tables
• Critical-word first cache refilling
• Cache lockdown registers enable control over which cache ways are used for allocation on a line fill,
providing a mechanism for both lockdown, and controlling cache corruption
• Dcache stores the Physical Address TAG (PA TAG) corresponding to each Dcache entry in the TAG
RAM for use during the cache line write-backs, in addition to the Virtual Address TAG stored in the
TAG RAM. This means that the MMU is not involved in Dcache write-back operations, removing the
possibility of TLB misses related to the write-back address.
• Cache maintenance operations provide efficient invalidation of, the entire Dcache or Icache, regions of
the Dcache or Icache, and regions of virtual memory.
The write buffer is used for all writes to a noncachable bufferable region, write-through region and write
misses to a write-back region. A separate buffer is incorporated in the Dcache for holding write-back for
cache line evictions or cleaning of dirty cache lines. The main write buffer has 16-word data buffer and a
four-address buffer. The Dcache write-back has eight data word entries and a single address entry.

3.3.5 Advanced High-Performance Bus (AHB)


The ARM Subsystem uses the AHB port of the ARM926EJ-S to connect the ARM to the Config bus and
the external memories. Arbiters are employed to arbitrate access to the separate D-AHB and I-AHB by the
Config Bus and the external memories bus.

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3.3.6 Embedded Trace Macrocell (ETM) and Embedded Trace Buffer (ETB)
To support real-time trace, the ARM926EJ-S processor provides an interface to enable connection of an
Embedded Trace Macrocell (ETM). The ARM926ES-J Subsystem in the device also includes the
Embedded Trace Buffer (ETB). The ETM consists of two parts:
• Trace Port provides real-time trace capability for the ARM9.
• Triggering facilities provide trigger resources, which include address and data comparators, counter,
and sequencers.
The device trace port is not pinned out and is instead only connected to the Embedded Trace Buffer. The
ETB has a 4KB buffer memory. ETB enabled debug tools are required to read/interpret the captured trace
data.

3.3.7 ARM Memory Mapping


By default the ARM has access to most on and off chip memory areas, including EMIFA, DDR2, and the
additional 128K byte on chip SRAM. Likewise almost all of the on chip peripherals are accessible to the
ARM by default.
To improve security and/or robustness, the device has extensive memory and peripheral protection units
which can be configured to limit access rights to the various on/off chip resources to specific hosts;
including the ARM as well as other master peripherals. This allows the system tasks to be partitioned
between the ARM and DSP as best suites the particular application; while enhancing the overall
robustness of the solution.
See Table 3-2 for a detailed top level device memory map that includes the ARM memory space.

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3.4 Memory Map Summary


Note: Read/Write accesses to illegal or reserved addresses in the memory map may cause undefined
behavior.

Table 3-2. Device Top Level Memory Map


Start Address End Address Size ARM Mem Map EDMA Mem Map PRUSS Mem Master LCDC Mem
Map Peripheral Mem Map
Map
0x0000 0000 0x0000 0FFF 4K PRUSS Local
Address Space
0x0000 1000 0x01BB FFFF
0x01BC 0000 0x01BC 0FFF 4K ARM ETB
memory
0x01BC 1000 0x01BC 17FF 2K ARM ETB reg
0x01BC 1800 0x01BC 18FF 256 ARM Ice Crusher
0x01BC 1900 0x01BF FFFF
0x01C0 0000 0x01C0 7FFF 32K EDMA3 CC
0x01C0 8000 0x01C0 83FF 1K EDMA3 TC0
0x01C0 8400 0x01C0 87FF 1K EDMA3 TC1
0x01C0 8800 0x01C0 FFFF
0x01C1 0000 0x01C1 0FFF 4K PSC 0
0x01C1 1000 0x01C1 1FFF 4K PLL Controller 0
0x01C1 2000 0x01C1 3FFF
0x01C1 4000 0x01C1 4FFF 4K SYSCFG0
0x01C1 5000 0x01C1 FFFF
0x01C2 0000 0x01C2 0FFF 4K Timer0
0x01C2 1000 0x01C2 1FFF 4K Timer1
0x01C2 2000 0x01C2 2FFF 4K I2C 0
0x01C2 3000 0x01C2 3FFF 4K RTC
0x01C2 4000 0x01C3 FFFF
0x01C4 0000 0x01C4 0FFF 4K MMC/SD 0
0x01C4 1000 0x01C4 1FFF 4K SPI 0
0x01C4 2000 0x01C4 2FFF 4K UART 0
0x01C4 3000 0x01CF FFFF
0x01D0 0000 0x01D0 0FFF 4K McASP 0 Control
0x01D0 1000 0x01D0 1FFF 4K McASP 0 AFIFO Ctrl
0x01D0 2000 0x01D0 2FFF 4K McASP 0 Data
0x01D0 3000 0x01D0 BFFF
0x01D0 C000 0x01D0 CFFF 4K UART 1
0x01D0 D000 0x01D0 DFFF 4K UART 2
0x01D0 E000 0x01D0 FFFF
0x01D1 0000 0x01D1 07FF 2K McBSP0
0x01D1 0800 0x01D1 0FFF 2K McBSP0 FIFO Ctrl
0x01D1 1000 0x01D1 17FF 2K McBSP1
0x01D1 1800 0x01D1 1FFF 2K McBSP1 FIFO Ctrl
0x01D1 2000 0x01DF FFFF
0x01E0 0000 0x01E0 FFFF 64K USB0
0x01E1 0000 0x01E1 0FFF 4K UHPI
0x01E1 1000 0x01E1 2FFF
0x01E1 3000 0x01E1 3FFF 4K LCD Controller
0x01E1 4000 0x01E1 4FFF 4K Memory Protection Unit 1 (MPU 1)

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Table 3-2. Device Top Level Memory Map (continued)


Start Address End Address Size ARM Mem Map EDMA Mem Map PRUSS Mem Master LCDC Mem
Map Peripheral Mem Map
Map
0x01E1 5000 0x01E1 5FFF 4K Memory Protection Unit 2 (MPU 2)
0x01E1 6000 0x01E1 6FFF 4K UPP
0x01E1 7000 0x01E1 7FFF 4K VPIF
0x01E1 8000 0x01E1 9FFF
0x01E1 A000 0x01E1 AFFF 4K PLL Controller 1
0x01E1 B000 0x01E1 BFFF 4K MMCSD1
0x01E1 C000 0x01E2 5FFF
0x01E2 6000 0x01E2 6FFF 4K GPIO
0x01E2 7000 0x01E2 7FFF 4K PSC 1
0x01E2 8000 0x01E2 8FFF 4K I2C 1
0x01E2 9000 0x01E2 BFFF
0x01E2 C000 0x01E2 CFFF 4K SYSCFG1
0x01E2 D000 0x01E2 FFFF
0x01E3 0000 0x01E3 7FFF 32K EDMA3 CC1
0x01E3 8000 0x01E3 83FF 1K EDMA3 TC2
0x01E3 8400 0x01EF FFFF
0x01F0 0000 0x01F0 0FFF 4K eHRPWM 0
0x01F0 1000 0x01F0 1FFF 4K HRPWM 0
0x01F0 2000 0x01F0 2FFF 4K eHRPWM 1
0x01F0 3000 0x01F0 3FFF 4K HRPWM 1
0x01F0 4000 0x01F0 5FFF
0x01F0 6000 0x01F0 6FFF 4K ECAP 0
0x01F0 7000 0x01F0 7FFF 4K ECAP 1
0x01F0 8000 0x01F0 8FFF 4K ECAP 2
0x01F0 9000 0x01F0 BFFF
0x01F0 C000 0x01F0 CFFF 4K Timer2
0x01F0 D000 0x01F0 DFFF 4K Timer3
0x01F0 E000 0x01F0 EFFF 4K SPI1
0x01F0 F000 0x01F0 FFFF
0x01F1 0000 0x01F1 0FFF 4K McBSP0 FIFO Data
0x01F1 1000 0x01F1 1FFF 4K McBSP1 FIFO Data
0x01F1 2000 0x3FFF FFFF
0x4000 0000 0x5FFF FFFF 512M EMIFA SDRAM data (CS0)
0x6000 0000 0x61FF FFFF 32M EMIFA async data (CS2)
0x6200 0000 0x63FF FFFF 32M EMIFA async data (CS3)
0x6400 0000 0x65FF FFFF 32M EMIFA async data (CS4)
0x6600 0000 0x67FF FFFF 32M EMIFA async data (CS5)
0x6800 0000 0x6800 7FFF 32K EMIFA Control Regs
0x6800 8000 0x7FFF FFFF
0x8000 0000 0x8001 FFFF 128K On-Chip RAM
0x8002 0000 0xAFFF FFFF
0xB000 0000 0xB000 7FFF 32K DDR2/mDDR Control Regs
0xB000 8000 0xBFFF FFFF
0xC000 0000 0xCFFF FFFF 256M DDR2/mDDR Data
0xD000 0000 0xE000 0000
0xFFFD 0000 0xFFFD FFFF 64K ARM local ROM

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Table 3-2. Device Top Level Memory Map (continued)


Start Address End Address Size ARM Mem Map EDMA Mem Map PRUSS Mem Master LCDC Mem
Map Peripheral Mem Map
Map
0xFFFE 0000 0xFFFE DFFF
0xFFFE E000 0xFFFE FFFF 8K ARM Interrupt
Controller
0xFFFF 0000 0xFFFF 1FFF 8K ARM local RAM ARM Local RAM
(PRU0 only)
0xFFFF 2000 0xFFFF FFFF

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3.5 Pin Assignments


Extensive use of pin multiplexing is used to accommodate the largest number of peripheral functions in
the smallest possible package. Pin multiplexing is controlled using a combination of hardware
configuration at device reset and software programmable register settings.

3.5.1 Pin Map (Bottom View)


The following graphics show the bottom view of the ZCE and ZWT packages pin assignments in four
quadrants (A, B, C, and D). The pin assignments for both packages are identical.
1 2 3 4 5 6 7 8 9 10

VP_DOUT[0]/ VP_DOUT[1]/ VP_DOUT[2]/


LCD_D[0]/ LCD_D[1]/ LCD_D[2]/
W UPP_XD[8]/ UPP_XD[9]/ UPP_XD[10]/ DDR_A[10] DDR_A[6] DDR_A[2] DDR_CLKN DDR_CLKP DDR_RAS DDR_D[15] W
GP7[8]/ GP7[9]/ GP7[10]/
PRU1_R31[8] PRU1_R31[9] PRU1_R31[10]

VP_DOUT[3]/ VP_DOUT[4]/ VP_DOUT[5]/


LCD_D[3]/ LCD_D[4]/ LCD_D[5]/
V UPP_XD[11]/ UPP_XD[12]/ UPP_XD[13]/ DDR_A[12] DDR_A[5] DDR_A[3] DDR_CKE DDR_BA[0] DDR_CS DDR_D[13] V
GP7[11]/ GP7[12]/ GP7[13]/
PRU1_R31[11] PRU1_R31[12] PRU1_R31[13]

VP_DOUT[6]/ VP_DOUT[7]/ VP_DOUT[8]/


LCD_D[6]/ LCD_D[7]/ LCD_D[8]/
U UPP_XD[14]/ UPP_XD[15]/ UPP_XD[0]/ DDR_A[8] DDR_A[4] DDR_A[7] DDR_A[0] DDR_BA[2] DDR_CAS DDR_D[12] U
GP7[14]/ GP7[15]/ GP7[0]/
PRU1_R31[14] PRU1_R31[15] BOOT[0]

VP_DOUT[9]/ VP_DOUT[10]/ VP_DOUT[11]/


LCD_D[9]/ LCD_D[10]/ LCD_D[11]/
T UPP_XD[1]/ UPP_XD[2]/ UPP_XD[3]/ DDR_A[11] DDR_A[13] DDR_A[9] DDR_A[1] DDR_WE DDR_BA[1] DDR_D[10] T
GP7[1]/ GP7[2]/ GP7[3]/
BOOT[1] BOOT[2] BOOT[3]

VP_DOUT[12]/ VP_DOUT[13]/ VP_DOUT[14]/


LCD_D[12]/ LCD_D[13]/ LCD_D[14]/ LCD_AC_ENB_CS/
R UPP_XD[4]/ UPP_XD[5]/ UPP_XD[6]/ DVDD3318_C GP6[0]/ DDR_VREF DDR_DVDD18 DDR_DVDD18 DDR_DVDD18 DDR_DQM[1] R
GP7[4]/ GP7[5]/ GP7[6]/ PRU1_R31[28]
BOOT[4] BOOT[5] BOOT[6]

VP_DOUT[15]/
LCD_D[15]/
P NC NC NC UPP_XD[7]/ DVDD3318_C DVDD3318_C DDR_DVDD18 DDR_DVDD18 DDR_DVDD18 DDR_DVDD18 P
GP7[7]/
BOOT[7]

N NC NC NC NC VSS DDR_DVDD18 RVDD CVDD DDR_DVDD18 DDR_DVDD18 N

M VSS NC NC VSS VSS VSS VSS CVDD CVDD VSS M

L NC NC VSS DVDD3318_C VSS DVDD18 VSS VSS VSS VSS L

VP_CLKOUT2/
VP_CLKOUT3/
MMCSD1_DAT[2]/
VSS VSS PRU1_R30[0]/
K PRU1_R30[2]/ DVDD18 CVDD VSS VSS VSS VSS K
GP6[1]/
GP6[3]/
PRU1_R31[1]
PRU1_R31[3]

1 2 3 4 5 6 7 8 9 10
A B

D C

Figure 3-1. Pin Map (Quad A)

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11 12 13 14 15 16 17 18 19

VP_CLKIN0/
PRU0_R30[28]/ VP_DIN[4]/ VP_DIN[2]/ VP_DIN[1]/ VP_DIN[0]/
UHPI_HCS/
UHPI_HCNTL1/ UHPI_HD[12]/ UHPI_HD[10]/ UHPI_HD[9]/ UHPI_HD[8]/
W DDR_D[7] DDR_D[6] DDR_DQM[0] PRU1_R30[10]/ W
UPP_CHA_START/ UPP_D[12]/ UPP_D[10]/ UPP_D[9]/ UPP_D[8]/
GP6[7]/
GP6[10] PRU0_R31[26] PRU0_R31[24] PRU0_R31[23] PRU1_R31[29]
UPP_2xTXCLK

VP_DIN[15]_ VP_DIN[14]_
VP_CLKIN1/
VP_DIN[6]/ VP_DIN[3]/ VSYNC/ HSYNC/
UHPI_HDS1/
UHPI_HD[14]/ UHPI_HD[11]/ UHPI_HD[7]/ UHPI_HD[6]/
V DDR_DQS[1] DDR_D[5] DDR_D[4] DDR_D[2] PRU1_R30[9]/ V
UPP_D[14]/ UPP_D[11]/ UPP_D[7]/ UPP_D[6]/
GP6[6]/
PRU0_R31[28] PRU0_R31[25] PRU0_R30[15]/ PRU0_R30[14]/
PRU1_R31[16]
PRU0_R31[15] PRU0_R31[14]

VP_DIN[13]_
PRU0_R30[27]/ PRU0_R30[29]/ VP_DIN[7]/ FIELD/
UHPI_HHWIL/ UHPI_HCNTL0/ UHPI_HD[15]/ UHPI_HD[5]/
U DDR_D[14] DDR_ZP DDR_D[3] DDR_D[1] DDR_D[0] U
UPP_CHA_ENABLE/ UPP_CHA_CLOCK/ UPP_D[15]/ UPP_D[5]/
GP6[9] GP6[11] PRU0_R31[29] PRU0_R30[13]/
PRU0_R31[13]

PRU0_R30[26]/ VP_DIN[12]/
RESETOUT/ CLKOUT/
UHPI_HRW/ UHPI_HD[4]/
UHPI_HAS/ UHPI_HDS2/
T DDR_D[9] DDR_D[11] DDR_D[8] DDR_DQS[0] UPP_CHA_WAIT/ UPP_D[4]/ RSV2 T
PRU1_R30[14]/ PRU1_R30[13]/
GP6[8]/ PRU0_R30[12]/
GP6[15] GP6[14]
PRU1_R31[17] PRU0_R31[12]

VP_DIN[9]/ VP_DIN[11]/ VP_DIN[10]/


VP_DIN[5]/ PRU0_R30[30] / PRU0_R30[31]/
UHPI_HD[1]/ UHPI_HD[3]/ UHPI_HD[2]/
UHPI_HD[13]/ UHPI_HINT/ UHPI_HRDY/
R DDR_DQGATE0 DDR_DQGATE1 DVDD18 UPP_D[1]/ UPP_D[3]/ UPP_D[2]/ R
UPP_D[13]/ PRU1_R30[11]/ PRU1_R30[12]
PRU0_R30[9]/ PRU0_R30[11]/ PRU0_R30[10]/
PRU0_R31[27] GP6[12] GP6[13]
PRU0_R31[9] PRU0_R31[11] PRU0_R31[10]

VP_DIN[8]/
UHPI_HD[0]/
P VSS DVDD3318_C DVDD18 NC NC USB0_ID UPP_D[0]/ NC NC P
GP6[5]/
PRU1_R31[0]

N VSS VSS DVDD3318_C USB0_VDDA18 PLL1_VDDA NC USB0_VDDA12 USB0_VDDA33 USB0_VBUS N

M VSS USB_CVDD DVDD3318_C NC PLL1_VSSA TDI PLL0_VSSA USB0_DM USB0_DP M

L VSS CVDD DVDD3318_C RTC_CVDD PLL0_VDDA TMS TRST OSCVSS OSCIN L

RTCK/
K VSS CVDD DVDD3318_C RESET DVDD3318_B EMU1 USB0_DRVVBUS OSCOUT K
GP8[0]

11 12 13 14 15 16 17 18 19
A B

D C

Figure 3-2. Pin Map (Quad B)

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A B

D C
11 12 13 14 15 16 17 18 19

J VSS CVDD DVDD18 DVDD3318_B TCK EMU0 RSVDN TDO RTC_XI J

SPI1_ENA/ SPI1_SOMI/
H CVDD CVDD CVDD RVDD VSS RTC_VSS RTC_XO H
GP2[12] GP2[11]

SPI1_SCS[7]/ SPI1_SCS[6]/
I2C0_SCL/ SPI1_SIMO/ I2C0_SDA/ SPI1_CLK/
G DVDD18 DVDD18 CVDD DVDD3318_A DVDD3318_A G
TM64P2_OUT12/ GP2[10] TM64P3_OUT12/ GP2[13]
GP1[5] GP1[4]

SPI1_SCS[1]/
SPI1_SCS[4]/ SPI1_SCS[5]/
EPWM1A/ SPI1_SCS[2]/
DVDD3318_B DVDD3318_B DVDD3318_B DVDD3318_A UART2_TXD/ UART2_RXD/
F DVDD18 PRU0_R30[8]/ UART1_TXD/ F
I2C1_SDA/ I2C1_SCL/
GP2[15]/ GP1[0]
GP1[2] GP1[3]
TM64P2_IN12

SPI1_SCS[0]/
EMA_A[18]/ EMA_A[16]/ SPI0_SCS[1]/
MMCSD0_DAT[3]/ MMCSD0_DAT[5]/ EMA_A[6]/ SPI0_SCS[3]/ SPI1_SCS[3]/ EPWM1B/
DVDD3318_B TM64P0_OUT12/
E CVDD UART0_CTS/ UART1_RXD/ PRU0_R30[7]/ E
PRU1_R30[26]/ PRU1_R30[24]/ GP5[6] GP1[7]/
GP4[2] GP4[0] GP8[2] GP1[1] GP2[14]/
TM64P0_IN12
TM64P3_IN12

EMA_A[13]/
EMA_A[12]/ SPI0_SCS[0]/
PRU0_R30[21]/ EMA_A[9]/ SPI0_SCS[2]/ SPI0_SCS[4]/ SPI0_CLK/
PRU1_R30[20]/ EMA_A[3]/ EMA_A[1]/ TM64P1_OUT12/
D PRU1_R30[21] PRU1_R30[17]/ UART0_RTS/ UART0_TXD/ EPWM0A/ D
GP5[12]/ GP5[3] GP5[1] GP1[6]/
GP5[13]/ GP5[9] GP8[1] GP8[3] GP1[8]
PRU1_R31[20] TM64P1_IN12
PRU1_R31[21]

EMA_A[15]/
EMA_A[10]/
MMCSD0_DAT[6]/ SPI0_SOMI/ SPI0_ENA/ SPI0_SIMO/ SPI0_SCS[5]/
PRU1_R30[18]/ EMA_A[5]/ EMA_A[0]/ EMA_BA[0]/
C PRU1_R30[23]/ EPWMSYNCI/ EPWM0B/ EPWMSYNCO/ UART0_RXD/ C
GP5[10]/ GP5[5] GP5[0] GP2[8]
GP5[15]/ GP8[6] PRU0_R30[6] GP8[5] GP8[4]
PRU1_R31[18]
PRU1_R31[23]

EMA_A[17]/ EMA_A[11]/ EMA_WAIT[0]/ EMA_WAIT[1]/


EMA_A[7]/
MMCSD0_DAT[4]/ PRU1_R30[19]/ EMA_A[2]/ EMA_OE/ EMA_CS[5]/ EMA_CS[2]/ PRU0_R30[0]/ PRU0_R30[1]/
B PRU1_R30[15]/ B
PRU1_R30[25] GP5[11]/ GP5[2] GP3[10] GP3[12] GP3[15] GP3[8]/ GP2[1]/
GP5[7]
GP4[1] PRU1_R31[19] PRU0_R31[0] PRU0_R31[1]

EMA_A[14]/
EMA_A[20]/ EMA_RAS/
MMCSD0_DAT[7]/ EMA_A[8]/
MMCSD0_DAT[1]/ EMA_A[4]/ EMA_BA[1]/ PRU0_R30[3]/ EMA_CS[3]/ EMA_CS[0]/
A PRU1_R30[22]/ PRU1_R30[16]/ VSS A
PRU1_R30[28]/ GP5[4] GP2[9] GP2[5]/ GP3[14] GP2[0]
GP5[14]/ GP5[8]
GP4[4] PRU0_R31[3]
PRU1_R31[22]

11 12 13 14 15 16 17 18 19

Figure 3-3. Pin Map (Quad C)

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A B

D C

1 2 3 4 5 6 7 8 9 10

VP_CLKIN3/ PRU0_R30[23]/
MMCSD1_DAT[1]/ MMCSD1_CMD/
J NC NC PRU1_R30[1]/ UPP_CHB_ENABLE/ DVDD3318_C CVDD VSS VSS VSS VSS J
GP6[2]/ GP8[13]/
PRU1_R31[2] PRU1_R31[25]

VP_CLKIN2/ MMCSD1_DAT[5]/
MMCSD1_DAT[3]/ LCD_HSYNC/
H VSS VSS PRU1_R30[3]/ PRU1_R30[5]/ DVDD3318_A CVDD CVDD VSS VSS CVDD H
GP6[4]/ GP8[9]/
PRU1_R31[4] PRU1_R31[6]

PRU0_R30[25]/ PRU0_R30[24]/ MMCSD1_DAT[4]/


MMCSD1_DAT[0]/ MMCSD1_CLK/ LCD_VSYNC/
PRU0_R30[22]/
G UPP_CHB_CLOCK/ UPP_CHB_START/ PRU1_R30[4]/ DVDD3318_A DVDD18 CVDD CVDD DVDD3318_B DVDD18 G
PRU1_R30[8]/
GP8[15]/ GP8[14]/ GP8[8]/
UPP_CHB_WAIT/
PRU1_R31[27] PRU1_R31[26] PRU1_R31[5]
GP8[12]/
PRU1_R31[24]

MMCSD1_DAT[7]/ AXR0/ RTC_ALARM/


MMCSD1_DAT[6]/
LCD_PCLK/ ECAP0_APWM0/ UART2_CTS/ EMA_CS[4]/
F LCD_MCLK/ DVDD3318_A DVDD3318_B DVDD3318_B DVDD3318_B DVDD3318_B F
PRU1_R30[7]/ GP8[7]/ GP0[8]/ GP3[13]
PRU1_R30[6]/
GP8[11] CLKS0 DEEPSLEEP
GP8[10]/
PRU1_R31[7]

AXR8/
AXR1/ AXR2/ AXR3/ CLKS1/ MMCSD0_CLK/
EMA_D[15]/ EMA_D[5]/ EMA_D[3]/ EMA_D[8]/
E DX0/ DR0/ FSX0/ ECAP1_APWM1/ RVDD PRU1_R30[31]/ E
GP3[7] GP4[13] GP4[11] GP3[0]
GP1[9] GP1[10] GP1[11] GP0[0]/ GP4[7]
PRU0_R31[8]

AXR7/ AMUTE/
EMA_SDCKE/
AXR4/ EPWM1TZ[0]/ AXR5/ AXR10/ PRU0_R30[16]/
EMA_D[11]/ EMA_D[7]/ PRU0_R30[4]/ EMA_D[9]/ EMA_A_RW/
D FSR0/ PRU0_R30[17] CLKX0/ DR1/ UART2_RTS/ D
GP3[3] GP4[15] GP2[6]/ GP3[1] GP3[9]
GP1[12] GP1[15]/ GP1[13] GP0[2] GP0[9]/
PRU0_R31[4]
PRU0_R31[7] PRU0_R31[16]

AXR6/ EMA_A[19]/
AFSR/ AXR9/ AXR12/ AXR11/
CLKR0/ EMA_D[6]/ EMA_D[14]/ EMA_WEN_DQM[0]/ EMA_D[0]/ MMCSD0_DAT[2]/
C GP0[13]/ DX1/ FSR1/ FSX1/ C
GP1[14]/ GP4[14] GP3[6] GP2[3] GP4[8] PRU1_R30[27]/
PRU0_R31[20] GP0[1] GP0[4] GP0[3]
PRU0_R31[6] GP4[3]

ACLKX/ EMA_CLK/ EMA_A[21]/


AFSX/ AXR13/ AXR14/
PRU0_R30[19]/ EMA_D[4]/ EMA_D[13]/ PRU0_R30[5]/ EMA_D[2]/ EMA_WE/ MMCSD0_DAT[0]/
B GP0[12]/ CLKX1/ CLKR1/ B
GP0[14]/ GP4[12] GP3[5] GP2[7]/ GP4[10] GP3[11] PRU1_R30[29]/
PRU0_R31[19] GP0[5] GP0[6]
PRU0_R31[21] PRU0_R31[5] GP4[5]

AHCLKR/ AHCLKX/
ACLKR/ AXR15/ EMA_CAS/ EMA_A[22]/
PRU0_R30[18]/ USB_REFCLKIN/
PRU0_R30[20]/ EPWM0TZ[0]/ EMA_WEN_DQM[1]/ EMA_D[12]/ EMA_D[10]/ EMA_D[1]/ PRU0_R30[2]/ MMCSD0_CMD/
A UART1_RTS/ UART1_CTS/ A
GP0[15]/ ECAP2_APWM2/ GP2[2] GP3[4] GP3[2] GP4[9] GP2[4]/ PRU1_R30[30]/
GP0[11]/ GP0[10]/
PRU0_R31[22] GP0[7] PRU0_R31[2] GP4[6]
PRU0_R31[18] PRU0_R31[17]

1 2 3 4 5 6 7 8 9 10

Figure 3-4. Pin Map (Quad D)

3.6 Pin Multiplexing Control


Device level pin multiplexing is controlled by registers PINMUX0 - PINMUX19 in the SYSCFG module.
For the device family, pin multiplexing can be controlled on a pin-by-pin basis. Each pin that is multiplexed
with several different functions has a corresponding 4-bit field in one of the PINMUX registers.
Pin multiplexing selects which of several peripheral pin functions controls the pin's IO buffer output data
and output enable values only. The default pin multiplexing control for almost every pin is to select 'none'
of the peripheral functions in which case the pin's IO buffer is held tri-stated.
Note that the input from each pin is always routed to all of the peripherals that share the pin; the PINMUX
registers have no effect on input from a pin.

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3.7 Terminal Functions


Table 3-3 to Table 3-27 identify the external signal names, the associated pin/ball numbers along with the
mechanical package designator, the pin type (I, O, IO, OZ, or PWR), whether the pin/ball has any internal
pullup/pulldown resistors, whether the pin/ball is configurable as an IO in GPIO mode, and a functional pin
description.

3.7.1 Device Reset and JTAG

Table 3-3. Reset and JTAG Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
RESET
RESET K14 I IPU B Device reset input
RESETOUT / UHPI_HAS / PRU1_R30[14] /
T17 O (4) CP[21] C Reset output
GP6[15]
JTAG
TMS L16 I IPU B JTAG test mode select
TDI M16 I IPU B JTAG test data input
TDO J18 O IPU B JTAG test data output
TCK J15 I IPU B JTAG test clock
TRST L17 I IPD B JTAG test reset
EMU0 J16 I/O IPU B Emulation pin
EMU1 K16 I/O IPU B Emulation pin
(5)
RTCK/ GP8[0] K17 I/O IPD B JTAG Test Clock Return Clock Output
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: For multiplexed pins where functions have different types (ie., input versus output), the table reflects the pin function direction for
that particular peripheral.
(2) IPD = Internal Pulldown resistor, IPU = Internal Pullup resistor. CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. For more detailed information on pullup/pulldown resistors and situations
where external pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and
internal pulldown circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.
(4) Open drain mode for RESETOUT function.
(5) GP8[0] is initially configured as a reserved function after reset and will not be in a predictable state. This signal will only be stable after
the GPIO configuration for this pin has been completed. Users should carefully consider the system implications of this pin being in an
unknown state after reset.

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3.7.2 High-Frequency Oscillator and PLL

Table 3-4. High-Frequency Oscillator and PLL Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
CLKOUT / UHPI_HDS2 /
T18 O CP[22] C PLL Observation Clock
PRU1_R30[13] / GP6[14]
1.2-V OSCILLATOR
OSCIN L19 I — — Oscillator input
OSCOUT K19 O — — Oscillator output
OSCVSS L18 GND — — Oscillator ground
1.2-V PLL0
PLL0_VDDA L15 PWR — — PLL analog VDD (1.2-V filtered supply)
PLL0_VSSA M17 GND — — PLL analog VSS (for filter)
1.2-V PLL1
PLL1_VDDA N15 PWR — — PLL analog VDD (1.2-V filtered supply)
PLL1_VSSA M15 GND — — PLL analog VSS (for filter)
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: For multiplexed pins where functions have different types (ie., input versus output), the table reflects the pin function direction for
that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. For more detailed information on pullup/pulldown resistors and situations
where external pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and
internal pulldown circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.3 Real-Time Clock and 32-kHz Oscillator

Table 3-5. Real-Time Clock (RTC) and 1.2-V, 32-kHz Oscillator Terminal Functions
SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
RTC_XI J19 I — — RTC 32-kHz oscillator input
RTC_XO H19 O — — RTC 32-kHz oscillator output
RTC_ALARM / UART2_CTS / GP0[8] / DEEPSLEEP F4 O CP[0] A RTC Alarm
RTC module core power
RTC_CVDD L14 PWR — —
(isolated from chip CVDD)
RTC_Vss H18 GND — — Oscillator ground
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: For multiplexed pins where functions have different types (ie., input versus output), the table reflects the pin function direction for
that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

3.7.4 DEEPSLEEP Power Control

Table 3-6. DEEPSLEEP Power Control Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
RTC_ALARM / UART2_CTS / GP0[8] / DEEPSLEEP F4 I CP[0] A DEEPSLEEP power control output
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: For multiplexed pins where functions have different types (ie., input versus output), the table reflects the pin function direction for
that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.5 External Memory Interface A (EMIFA)

Table 3-7. External Memory Interface A (EMIFA) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
EMA_D[15] / GP3[7] E6 I/O CP[17] B
EMA_D[14] / GP3[6] C7 I/O CP[17] B
EMA_D[13] / GP3[5] B6 I/O CP[17] B
EMA_D[12] / GP3[4] A6 I/O CP[17] B
EMA_D[11] / GP3[3] D6 I/O CP[17] B
EMA_D[10] / GP3[2] A7 I/O CP[17] B
EMA_D[9] / GP3[1] D9 I/O CP[17] B
EMA_D[8] / GP3[0] E10 I/O CP[17] B
EMIFA data bus
EMA_D[7] / GP4[15] D7 I/O CP[17] B
EMA_D[6] / GP4[14] C6 I/O CP[17] B
EMA_D[5] / GP4[13] E7 I/O CP[17] B
EMA_D[4] / GP4[12] B5 I/O CP[17] B
EMA_D[3] / GP4[11] E8 I/O CP[17] B
EMA_D[2] / GP4[10] B8 I/O CP[17] B
EMA_D[1] / GP4[9] A8 I/O CP[17] B
EMA_D[0] / GP4[8] C9 I/O CP[17] B

(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.
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Table 3-7. External Memory Interface A (EMIFA) Terminal Functions (continued)


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
EMA_A[22] / MMCSD0_CMD /
A10 O CP[18] B
PRU1_R30[30] / GP4[6]
EMA_A[21] / MMCSD0_DAT[0] /
B10 O CP[18] B
PRU1_R30[29] / GP4[5]
EMA_A[20] / MMCSD0_DAT[1] /
A11 O CP[18] B
PRU1_R30[28] / GP4[4]
EMA_A[19] / MMCSD0_DAT[2] /
C10 O CP[18] B
PRU1_R30[27] / GP4[3]
EMA_A[18] / MMCSD0_DAT[3] /
E11 O CP[18] B
PRU1_R30[26] / GP4[2]
EMA_A[17] / MMCSD0_DAT[4] /
B11 O CP[18] B EMIFA address bus
PRU1_R30[25] / GP4[1]
EMA_A[16] / MMCSD0_DAT[5] /
E12 O CP[18] B
PRU1_R30[24] / GP4[0]
EMA_A[15] / MMCSD0_DAT[6] /
C11 O CP[19] B
PRU1_R30[23] / GP5[15] / PRU1_R31[23]
EMA_A[14] / MMCSD0_DAT[7] /
A12 O CP[19] B
PRU1_R30[22] / GP5[14] / PRU1_R31[22]
EMA_A[13] /PRU0_R30[21] / PRU1_R30[21]
D11 O CP[19] B
/ GP5[13] / PRU1_R31[21]
EMA_A[12] / PRU1_R30[20] / GP5[12] /
D13 O CP[19] B
PRU1_R31[20]
EMA_A[11] / PRU1_R30[19] / GP5[11] /
B12 O CP[19] B
PRU1_R31[19]
EMA_A[10] / PRU1_R30[18] / GP5[10] /
C12 O CP[19] B
PRU1_R31[18]
EMA_A[9] / PRU1_R30[17] / GP5[9] D12 O CP[19] B
EMA_A[8] / PRU1_R30[16] / GP5[8] A13 O CP[19] B
EMA_A[7] / PRU1_R30[15] / GP5[7] B13 O CP[20] B
EMA_A[6] / GP5[6] E13 O CP[20] B EMIFA address bus
EMA_A[5] / GP5[5] C13 O CP[20] B
EMA_A[4] / GP5[4] A14 O CP[20] B
EMA_A[3] / GP5[3] D14 O CP[20] B
EMA_A[2] / GP5[2] B14 O CP[20] B
EMA_A[1] / GP5[1] D15 O CP[20] B
EMA_A[0] / GP5[0] C14 O CP[20] B
EMA_BA[0] / GP2[8] C15 O CP[16] B
EMIFA bank address
EMA_BA[1] / GP2[9] A15 O CP[16] B
EMA_CLK / PRU0_R30[5] / GP2[7] /
B7 O CP[16] B EMIFA clock
PRU0_R31[5]
EMA_SDCKE / PRU0_R30[4] / GP2[6] /
D8 O CP[16] B EMIFA SDRAM clock enable
PRU0_R31[4]
EMA_RAS / PRU0_R30[3] / GP2[5] /
A16 O CP[16] B EMIFA SDRAM row address strobe
PRU0_R31[3]
EMA_CAS / PRU0_R30[2] / GP2[4] /
A9 O CP[16] B EMIFA SDRAM column address strobe
PRU0_R31[2]
EMA_CS[0] / GP2[0] A18 O CP[16] B EMIFA SDRAM Chip Select
EMA_CS[2] / GP3[15] B17 O CP[16] B
EMA_CS[3] / GP3[14] A17 O CP[16] B
EMIFA Async Chip Select
EMA_CS[4] / GP3[13] F9 O CP[16] B
EMA_CS[5] / GP3[12] B16 O CP[16] B
EMA_A_RW / GP3[9] D10 O CP[16] B EMIFA Async Read/Write control

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Table 3-7. External Memory Interface A (EMIFA) Terminal Functions (continued)


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
EMA_WE / GP3[11] B9 O CP[16] B EMIFA SDRAM write enable
EMIFA write enable/data mask for
EMA_WEN_DQM[1] / GP2[2] A5 O CP[16] B
EMA_D[15:8]
EMA_WEN_DQM[0] / GP2[3] C8 O CP[16] B EMIFA write enable/data mask for EMA_D[7:0]
EMA_OE / GP3[10] B15 O CP[16] B EMIFA output enable
EMA_WAIT[0] / PRU0_R30[0] / GP3[8] /
B18 I CP[16] B
PRU0_R31[0]
EMIFA wait input/interrupt
EMA_WAIT[1] / PRU0_R30[1] / GP2[1] /
B19 I CP[16] B
PRU0_R31[1]

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3.7.6 DDR2/mDDR Memory Controller

Table 3-8. DDR2/mDDR Terminal Functions


SIGNAL
TYPE (1) PULL (2) DESCRIPTION
NAME NO.
DDR_D[15] W10 I/O IPD
DDR_D[14] U11 I/O IPD
DDR_D[13] V10 I/O IPD
DDR_D[12] U10 I/O IPD
DDR_D[11] T12 I/O IPD
DDR_D[10] T10 I/O IPD
DDR_D[9] T11 I/O IPD
DDR_D[8] T13 I/O IPD
DDR2 SDRAM data bus
DDR_D[7] W11 I/O IPD
DDR_D[6] W12 I/O IPD
DDR_D[5] V12 I/O IPD
DDR_D[4] V13 I/O IPD
DDR_D[3] U13 I/O IPD
DDR_D[2] V14 I/O IPD
DDR_D[1] U14 I/O IPD
DDR_D[0] U15 I/O IPD
DDR_A[13] T5 O IPD
DDR_A[12] V4 O IPD
DDR_A[11] T4 O IPD
DDR_A[10] W4 O IPD
DDR_A[9] T6 O IPD
DDR_A[8] U4 O IPD
DDR_A[7] U6 O IPD
DDR2 row/column address
DDR_A[6] W5 O IPD
DDR_A[5] V5 O IPD
DDR_A[4] U5 O IPD
DDR_A[3] V6 O IPD
DDR_A[2] W6 O IPD
DDR_A[1] T7 O IPD
DDR_A[0] U7 O IPD
DDR_CLKP W8 O IPD DDR2 clock (positive)
DDR_CLKN W7 O IPD DDR2 clock (negative)
DDR_CKE V7 O IPD DDR2 clock enable
DDR_WE T8 O IPD DDR2 write enable
DDR_RAS W9 O IPD DDR2 row address strobe
DDR_CAS U9 O IPD DDR2 column address strobe
DDR_CS V9 O IPD DDR2 chip select

(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. For more detailed information on pullup/pulldown resistors and situations
where external pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and
internal pulldown circuits, see the Device Operating Conditions section.
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Table 3-8. DDR2/mDDR Terminal Functions (continued)


SIGNAL
TYPE (1) PULL (2) DESCRIPTION
NAME NO.
DDR_DQM[0] W13 O IPD
DDR2 data mask outputs
DDR_DQM[1] R10 O IPD
DDR_DQS[0] T14 I/O IPD
DDR2 data strobe inputs/outputs
DDR_DQS[1] V11 I/O IPD
DDR_BA[2] U8 O IPD
DDR_BA[1] T9 O IPD DDR2 SDRAM bank address
DDR_BA[0] V8 O IPD
DDR2 loopback signal for external DQS gating.
DDR_DQGATE0 R11 O IPD Route to DDR and back to DDR_DQGATE1 with
same constraints as used for DDR clock and data.
DDR2 loopback signal for external DQS gating.
DDR_DQGATE1 R12 I IPD Route to DDR and back to DDR_DQGATE0 with
same constraints as used for DDR clock and data.
DDR2 reference output for drive strength calibration
DDR_ZP U12 O — of N and P channel outputs. Tie to ground via 50
ohm resistor @ 5% tolerance.
DDR voltage input for the DDR2/mDDR I/O buffers.
DDR_VREF R6 I — Note even in the case of mDDR an external resistor
divider connected to this pin is necessary.
N10, P10, N9,
P9, R9, P8,
DDR_DVDD18 PWR — DDR PHY 1.8V power supply pins
R8, P7, R7,
N6

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3.7.7 Serial Peripheral Interface Modules (SPI)

Table 3-9. Serial Peripheral Interface (SPI) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
SPI0
SPI0_CLK / EPWM0A / GP1[8] D19 I/O CP[7] A SPI0 clock
SPI0_ENA / EPWM0B / PRU0_R30[6] C17 I/O CP[7] A SPI0 enable
SPI0_SCS[0] / TM64P1_OUT12 / GP1[6] / TM64P1_IN12 D17 I/O CP[10] A
SPI0_SCS[1] / TM64P0_OUT12 / GP1[7] / TM64P0_IN12 E16 I/O CP[10] A
SPI0_SCS[2] / UART0_RTS / GP8[1] D16 I/O CP[9] A
SPI0 chip selects
SPI0_SCS[3] / UART0_CTS / GP8[2] E17 I/O CP[9] A
SPI0_SCS[4] / UART0_TXD / GP8[3] D18 I/O CP[8] A
SPI0_SCS[5] / UART0_RXD / GP8[4] C19 I/O CP[8] A
SPI0 data slave-in-
SPI0_SIMO / EPWMSYNCO / GP8[5] C18 I/O CP[7] A
master-out
SPI0 data slave-out-
SPI0_SOMI / EPWMSYNCI / GP8[6] C16 I/O CP[7] A
master-in
SPI1
SPI1_CLK / GP2[13] G19 I/O CP[15] A SPI1 clock
SPI1_ENA / GP2[12] H16 I/O CP[15] A SPI1 enable
SPI1_SCS[0] / EPWM1B / PRU0_R30[7] / GP2[14] / TM64P3_IN12 E19 I/O CP[14] A
SPI1_SCS[1] / EPWM1A / PRU0_R30[8] / GP2[15] / TM64P2_IN12 F18 I/O CP[14] A
SPI1_SCS[2] / UART1_TXD / GP1[0] F19 I/O CP[13] A
SPI1_SCS[3] / UART1_RXD / GP1[1] E18 I/O CP[13] A
SPI1 chip selects
SPI1_SCS[4] / UART2_TXD / I2C1_SDA /GP1[2] F16 I/O CP[12] A
SPI1_SCS[5] / UART2_RXD / I2C1_SCL /GP1[3] F17 I/O CP[12] A
SPI1_SCS[6] / I2C0_SDA / TM64P3_OUT12 / GP1[4] G18 I/O CP[11] A
SPI1_SCS[7] / I2C0_SCL / TM64P2_OUT12 / GP1[5] G16 I/O CP[11] A
SPI1 data slave-in-
SPI1_SIMO / GP2[10] G17 I/O CP[15] A
master-out
SPI1 data slave-out-
SPI1_SOMI / GP2[11] H17 I/O CP[15] A
master-in
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.8 Programmable Real-Time Unit (PRU)

Table 3-10. Programmable Real-Time Unit (PRU) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
PRU0 Signals
PRU0_R30[31] / UHPI_HRDY / PRU1_R30[12] / GP6[13] R17 O CP[23] C
PRU0_R30[30] / UHPI_HINT / PRU1_R30[11] / GP6[12] R16 O CP[23] C
PRU0_R30[29] / UHPI_HCNTL0 / UPP_CHA_CLOCK / GP6[11] U17 O CP[24] C
PRU0_R30[28] / UHPI_HCNTL1 / UPP_CHA_START / GP6[10] W15 O CP[24] C
PRU0_R30[27] / UHPI_HHWIL / UPP_CHA_ENABLE / GP6[9] U16 O CP[24] C
PRU0_R30[26] / UHPI_HRW / / UPP_CHA_WAITGP6[8] / PRU1_R31[17] T15 O CP[24] C
PRU0_R30[25] / MMCSD1_DAT[0] / UPP_CHB_CLOCK / GP8[15] /
G1 O CP30] C
PRU1_R31[27]
PRU0_R30[24] / MMCSD1_CLK / UPP_CHB_START / GP8[14] /
G2 O CP[30] C
PRU1_R31[26]
PRU0_R30[23] / MMCSD1_CMD / UPP_CHB_ENABLE / GP8[13] /
J4 O CP[30] C
PRU1_R31[25]
PRU0_R30[22] / PRU1_R30[8] / UPP_CHB_WAIT / GP8[12] /
G3 O CP[30] C
PRU1_R31[24]
EMA_A[13] / PRU0_R30[21] / PRU1_R30[21] / GP5[13] / PRU1_R31[21] D11 O CP[19] B
ACLKR / PRU0_R30[20] / GP0[15] / PRU0_R31[22] A1 O CP[0] A
ACLKX / PRU0_R30[19] / GP0[14] / PRU0_R31[21] B1 O CP[0] A PRU0 Output
Signals
AHCLKR / PRU0_R30[18] / UART1_RTS / GP0[11] / PRU0_R31[18] A2 O CP[0] A
AXR7 / EPWM1TZ[0] / PRU0_R30[17] / GP1[15] / PRU0_R31[7] D2 O CP[4] A
AMUTE / PRU0_R30[16] / UART2_RTS / GP0[9] / PRU0_R31[16] D5 O CP[0] A
VP_DIN[15]_VSYNC / UHPI_HD[7] / UPP_D[7] / PRU0_R30[15] /
V18 O CP[27] C
PRU0_R31[15]
VP_DIN[14]_HSYNC / UHPI_HD[6] / UPP_D[6] / PRU0_R30[14] /
V19 O CP[27] C
PRU0_R31[14]
VP_DIN[13]_FIELD / UHPI_HD[5] / UPP_D[5] / PRU0_R30[13] /
U19 O CP[27] C
PRU0_R31[13]
VP_DIN[12] / UHPI_HD[4] / UPP_D[4] / PRU0_R30[12] / PRU0_R31[12] T16 O CP[27] C
VP_DIN[11] / UHPI_HD[3] / UPP_D[3] / PRU0_R30[11] / PRU0_R31[11] R18 O CP[27] C
VP_DIN[10] / UHPI_HD[2] / UPP_D[2] / PRU0_R30[10] / PRU0_R31[10] R19 O CP[27] C
VP_DIN[9] / UHPI_HD[1] / UPP_D[1] / PRU0_R30[9] / PRU0_R31[9] R15 O CP[27] C
SPI1_SCS[1] / EPWM1A / PRU0_R30[8] / GP2[15] / TM64P2_IN12 F18 O CP[14] A
SPI1_SCS[0] / EPWM1B / PRU0_R30[7] / GP2[14] / TM64P3_IN12 E19 O CP[14] A
SPI0_ENA / EPWM0B / PRU0_R30[6] C17 O CP[7] A

(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.
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Table 3-10. Programmable Real-Time Unit (PRU) Terminal Functions (continued)


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
EMA_CLK / PRU0_R30[5] / GP2[7] / PRU0_R31[5] B7 O CP[16] B
EMA_SDCKE / PRU0_R30[4] / GP2[6] / PRU0_R31[4] D8 O CP[16] B
EMA_RAS / PRU0_R30[3] / GP2[5] / PRU0_R31[3] A16 O CP[16] B PRU0 Output
EMA_CAS / PRU0_R30[2] / GP2[4] / PRU0_R31[2] A9 O CP[16] B Signals
EMA_WAIT[1] / PRU0_R30[1] / GP2[1] / PRU0_R31[1] B19 O CP[16] B
EMA_WAIT[0] / PRU0_R30[0] / GP3[8] / PRU0_R31[0] B18 O CP[16] B
VP_DIN[7] / UHPI_HD[15] / UPP_D[15] / PRU0_R31[29] U18 I CP[26] C
VP_DIN[6] / UHPI_HD[14] / UPP_D[14] / PRU0_R31[28] V16 I CP[26] C
VP_DIN[5] / UHPI_HD[13] / UPP_D[13] / PRU0_R31[27] R14 I CP[26] C
VP_DIN[4] / UHPI_HD[12] / UPP_D[12] / PRU0_R31[26] W16 I CP[26] C
VP_DIN[3] / UHPI_HD[11] / UPP_D[11] / PRU0_R31[25] V17 I CP[26] C
VP_DIN[2] / UHPI_HD[10] / UPP_D[10] / PRU0_R31[24] W17 I CP[26] C
VP_DIN[1] / UHPI_HD[9]UPP_D[9] / PRU0_R31[23] W18 I CP[26] C
ACLKR / PRU0_R30[20] / GP0[15] / PRU0_R31[22] A1 I CP[0] A
ACLKX / PRU0_R30[19] / GP0[14] / PRU0_R31[21] B1 I CP[0] A
AFSR / GP0[13] / PRU0_R31[20] C2 I CP[0] A
AFSX / GP0[12] / PRU0_R31[19] B2 I CP[0] A
AHCLKR / PRU0_R30[18] / UART1_RTS / GP0[11] / PRU0_R31[18] A2 I CP[0] A
AHCLKX / USB_REFCLKIN / UART1_CTS / GP0[10] / PRU0_R31[17] A3 I CP[0] A
AMUTE / PRU0_R30[16] / UART2_RTS / GP0[9] / PRU0_R31[16] D5 I CP[0] A
VP_DIN[15]_VSYNC / UHPI_HD[7] / UPP_D[7] / PRU0_R30[15] /
V18 I CP[27] C
PRU0_R31[15]
PRU0 Input
VP_DIN[14]_HSYNC / UHPI_HD[6] / UPP_D[6] / PRU0_R30[14] / Signals
V19 I CP[27] C
PRU0_R31[14]
VP_DIN[13]_FIELD / UHPI_HD[5] / UPP_D[5] / PRU0_R30[13] /
U19 I CP[27] C
PRU0_R31[13]
VP_DIN[12] / UHPI_HD[4] / UPP_D[4] / PRU0_R30[12] / PRU0_R31[12] T16 I CP[27] C
VP_DIN[11] / UHPI_HD[3] / UPP_D[3] / PRU0_R30[11] / PRU0_R31[11] R18 I CP[27] C
VP_DIN[10] / UHPI_HD[2] / UPP_D[2] / PRU0_R30[10] / PRU0_R31[10] R19 I CP[27] C
VP_DIN[9] / UHPI_HD[1] / UPP_D[1] / PRU0_R30[9] / PRU0_R31[9] R15 I CP[27] C
AXR8 / CLKS1 / ECAP1_APWM1 / GP0[0] / PRU0_R31[8] E4 I CP[3] A
AXR7 / EPWM1TZ[0] / PRU0_R30[17] / GP1[15] / PRU0_R31[7] D2 I CP[4] A
AXR6 / CLKR0 / GP1[14] / PRU0_R31[6] C1 I CP[5] A
EMA_CLK / PRU0_R30[5] / GP2[7] / PRU0_R31[5] B7 I CP[16] B
EMA_SDCKE / PRU0_R30[4] / GP2[6] / PRU0_R31[4] D8 I CP[16] B
EMA_RAS / PRU0_R30[3] / GP2[5] / PRU0_R31[3] A16 I CP[16] B
EMA_CAS / PRU0_R30[2] / GP2[4] / PRU0_R31[2] A9 I CP[16] B
EMA_WAIT[1] / PRU0_R30[1] / GP2[1] / PRU0_R31[1] B19 I CP[16] B
EMA_WAIT[0] / PRU0_R30[0] / GP3[8] / PRU0_R31[0] B18 I CP[16] B

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Table 3-10. Programmable Real-Time Unit (PRU) Terminal Functions (continued)


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
PRU1 Signals
MMCSD0_CLK / PRU1_R30[31] /GP4[7] E9 O CP[18] B
EMA_A[22] / MMCSD0_CMD / PRU1_R30[30] / GP4[6] A10 O CP[18] B
EMA_A[21] / MMCSD0_DAT[0] / PRU1_R30[29] / GP4[5] B10 O CP[18] B
EMA_A[20] / MMCSD0_DAT[1] / PRU1_R30[28] / GP4[4] A11 O CP[18] B
EMA_A[19] / MMCSD0_DAT[2] / PRU1_R30[27] / GP4[3] C10 O CP[18] B
EMA_A[18] / MMCSD0_DAT[3] / PRU1_R30[26] / GP4[2] E11 O CP[18] B
EMA_A[17] / MMCSD0_DAT[4] / PRU1_R30[25] / GP4[1] B11 O CP[18] B
EMA_A[16] / MMCSD0_DAT[5] / PRU1_R30[24] / GP4[0] E12 O CP[18] B
EMA_A[15] / MMCSD0_DAT[6] / PRU1_R30[23] / GP5[15] /
C11 O CP[19] B
PRU1_R31[23]
EMA_A[14] / MMCSD0_DAT[7] / PRU1_R30[22] / GP5[14] /
A12 O CP[19] B
PRU1_R31[22]
EMA_A[13] / PRU0_R30[21] / PRU1_R30[21] / GP5[13] / PRU1_R31[21] D11 O CP[19] B
EMA_A[12] / PRU1_R30[20] / GP5[12] / PRU1_R31[20] D13 O CP[19] B
EMA_A[11] / PRU1_R30[19] / GP5[11] / PRU1_R31[19] B12 O CP[19] B
EMA_A[10] / PRU1_R30[18] / GP5[10] / PRU1_R31[18] C12 O CP[19] B
EMA_A[9] / PRU1_R30[17] / GP5[9] D12 O CP[19] B
EMA_A[8] / PRU1_R30[16] / GP5[8] A13 O CP[19] B PRU1 Output
EMA_A[7] / PRU1_R30[15] / GP5[7] B13 O CP[20] B Signals
RESETOUT / UHPI_HAS / PRU1_R30[14] / GP6[15] T17 O CP[21] C
CLKOUT / UHPI_HDS2 / PRU1_R30[13] / GP6[14] T18 O CP[22] C
PRU0_R30[31] / UHPI_HRDY / PRU1_R30[12] / GP6[13] R17 O CP[23] C
PRU0_R30[30] / UHPI_HINT / PRU1_R30[11] / GP6[12] R16 O CP[23] C
VP_CLKIN0 / UHPI_HCS / PRU1_R30[10] / GP6[7] / UPP_2xTXCLK W14 O CP[25] C
VP_CLKIN1 / UHPI_HDS1 / PRU1_R30[9] / GP6[6] / PRU1_R31[16] V15 O CP[25] C
PRU0_R30[22] / PRU1_R30[8] / UPP_CHB_WAIT / GP8[12] /
G3 O CP[30] C
PRU1_R31[24]
MMCSD1_DAT[7] / LCD_PCLK / PRU1_R30[7] / GP8[11] F1 O CP[31] C
MMCSD1_DAT[6] / LCD_MCLK / PRU1_R30[6] / GP8[10] / PRU1_R31[7] F2 O CP[31] C
MMCSD1_DAT[5] / LCD_HSYNC / PRU1_R30[5] / GP8[9] / PRU1_R31[6] H4 O CP[31] C
MMCSD1_DAT[4] / LCD_VSYNC / PRU1_R30[4] / GP8[8] / PRU1_R31[5] G4 O CP[31] C
VP_CLKIN2 / MMCSD1_DAT[3] / PRU1_R30[3] / GP6[4] / PRU1_R31[4] H3 O CP[30] C
VP_CLKOUT2 / MMCSD1_DAT[2] / PRU1_R30[2] / GP6[3] /
K3 O CP[30] C
PRU1_R31[3]
VP_CLKIN3 / MMCSD1_DAT[1] / PRU1_R30[1] / GP6[2] / PRU1_R31[2] J3 O CP[30] C
VP_CLKOUT3 / PRU1_R30[0] / GP6[1] / PRU1_R31[1] K4 O CP[30] C

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Table 3-10. Programmable Real-Time Unit (PRU) Terminal Functions (continued)


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
VP_DIN[0] / UHPI_HD[8] / UPP_D[8] / PRU1_R31[29] W19 I CP[26] C
LCD_AC_ENB_CS / GP6[0] / PRU1_R31[28] R5 I CP[31] C
PRU0_R30[25] / MMCSD1_DAT[0] / UPP_CHB_CLOCK / GP8[15] /
G1 I CP[30] C
PRU1_R31[27]
PRU0_R30[24] / MMCSD1_CLK / UPP_CHB_START / GP8[14] /
G2 I CP[30] C
PRU1_R31[26]
PRU0_R30[23] / MMCSD1_CMD / UPP_CHB_ENABLE / GP8[13] /
J4 I CP[30] C
PRU1_R31[25]
PRU0_R30[22] / PRU1_R30[8] / UPP_CHB_WAIT / GP8[12] /
G3 I CP[30] C
PRU1_R31[24]
EMA_A[15] / MMCSD0_DAT[6] / PRU1_R30[23] / GP[15] / PRU1_R31[23] C11 I CP[19] B
EMA_A[14] / MMCSD0_DAT[7] / PRU1_R30[22] /GP[14] / PRU1_R31[22] A12 I CP[19] B
EMA_A[13] / PRU0_R30[21] / PRU1_R30[21] /GP[13] / PRU1_R31[21] D11 I CP[19] B
EMA_A[12] / PRU1_R30[20] / GP[12] / PRU1_R31[20] D13 I CP[19] B
EMA_A[11] / PRU1_R30[19] /GP[11] / PRU1_R31[19] B12 I CP[19] B
EMA_A[10] / PRU1_R30[18] /GP[10] / PRU1_R31[18] C12 I CP[19] B
PRU0_R30[26] / UHPI_HRW / UPP_CHA_WAIT / GP6[8] / PRU1_R31[17] T15 I CP[24] C
VP_CLKIN1 / UHPI_HDS1 / PRU1_R30[9] / GP6[6] / PRU1_R31[16] V15 I CP[25] C PRU1 Input
VP_DOUT[7] / LCD_D[7] / UPP_XD[15] / GP7[15] / PRU1_R31[15] U2 I CP[28] C Signals
VP_DOUT[6] / LCD_D[6] / UPP_XD[14] / GP7[14] / PRU1_R31[14] U1 I CP[28] C
VP_DOUT[5] / LCD_D[5] / UPP_XD[13] / GP7[13] / PRU1_R31[13] V3 I CP[28] C
VP_DOUT[4] / LCD_D[4] / UPP_XD[12] / GP7[12] / PRU1_R31[12] V2 I CP[28] C
VP_DOUT[3] / LCD_D[3] / UPP_XD[11] / GP7[11] / PRU1_R31[11] V1 I CP[28] C
VP_DOUT[2] / LCD_D[2] / UPP_XD[10] / GP7[10] / PRU1_R31[10] W3 I CP[28] C
VP_DOUT[1] / LCD_D[1] / UPP_XD[9] / GP7[9] / PRU1_R31[9] W2 I CP[28] C
VP_DOUT[0] / LCD_D[0] / UPP_XD[8] / GP7[8] / PRU1_R31[8] W1 I CP[28] C
MMCSD1_DAT[6] / LCD_MCLK / PRU1_R30[6] / GP8[10] / PRU1_R31[7] F2 I CP[31] C
MMCSD1_DAT[5] / LCD_HSYNC / PRU1_R30[5] / GP8[9] / PRU1_R31[6] H4 I CP[31] C
MMCSD1_DAT[4] / LCD_VSYNC / PRU1_R30[4] / GP8[8] / PRU1_R31[5] G4 I CP[31] C
VP_CLKIN2 / MMCSD1_DAT[3] / PRU1_R30[3] / GP6[4] / PRU1_R31[4] H3 I CP[30] C
VP_CLKOUT2 / MMCSD1_DAT[2] / PRU1_R30[2] / GP6[3] /
K3 I CP[30] C
PRU1_R31[3]
VP_CLKIN3 / MMCSD1_DAT[1] / PRU1_R30[1] / GP6[2] / PRU1_R31[2] J3 I CP[30] C
VP_CLKOUT3 / PRU1_R30[0] / GP6[1] / PRU1_R31[1] K4 I CP[30] C
VP_DIN[8] / UHPI_HD[0] / UPP_D[0] / GP6[5] / PRU1_R31[0] P17 I CP[27] C

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3.7.9 Enhanced Capture/Auxiliary PWM Modules (eCAP0)


The eCAP Module pins function as either input captures or auxiliary PWM 32-bit outputs, depending upon
how the eCAP module is programmed.

Table 3-11. Enhanced Capture Module (eCAP) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
eCAP0
enhanced capture 0 input or
AXR0 / ECAP0_APWM0 / GP8[7] / CLKS0 F3 I/O CP[6] A
auxiliary PWM 0 output
eCAP1
enhanced capture 1 input or
AXR8 / CLKS1 / ECAP1_APWM1 / GP0[0] / PRU0_R31[8] E4 I/O CP[3] A
auxiliary PWM 1 output
eCAP2
enhanced capture 2 input or
AXR15 / EPWM0TZ[0] / ECAP2_APWM2 / GP0[7] A4 I/O CP[1] A
auxiliary PWM 2 output
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.10 Enhanced Pulse Width Modulators (eHRPWM)

Table 3-12. Enhanced Pulse Width Modulator (eHRPWM) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
eHRPWM0
eHRPWM0 A output
SPI0_CLK / EPWM0A / GP1[8] D19 I/O CP[7] A
(with high-resolution)
SPI0_ENA / EPWM0B / PRU0_R30[6] C17 I/O CP[7] A eHRPWM0 B output
AXR15 / EPWM0TZ[0] / ECAP2_APWM2 / GP0[7] A4 I CP[1] A eHRPWM0 trip zone input
SPI0_SOMI / EPWMSYNCI / GP8[6] C16 I CP[7] A eHRPWM0 sync input
SPI0_SIMO / EPWMSYNCO / GP8[5] C18 I/O CP[7] A eHRPWM0 sync output
eHRPWM1
SPI1_SCS[1] / EPWM1A / PRU0_R30[8] / GP2[15] / eHRPWM1 A output
F18 I/O CP[14] A
TM64P2_IN12 (with high-resolution)
SPI1_SCS[0] / EPWM1B / PRU0_R30[7] / GP2[14] /
E19 I/O CP[14] A eHRPWM1 B output
TM64P3_IN12
AXR7 / EPWM1TZ[0] / PRU0_R30[17] / GP1[15] /
D2 I CP[4] A eHRPWM1 trip zone input
PRU0_R31[7]
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.11 Boot

Table 3-13. Boot Mode Selection Terminal Functions (1)


SIGNAL POWER
TYPE (2) PULL (3) DESCRIPTION
NAME NO. GROUP (4)
VP_DOUT[15] / LCD_D[15] / UPP_XD[7] /GP7[7] / BOOT[7] P4 I CP[29] C
VP_DOUT[14] / LCD_D[14] / UPP_XD[6] /GP7[6] / BOOT[6] R3 I CP[29] C
VP_DOUT[13] / LCD_D[13] / UPP_XD[5] /GP7[5] / BOOT[5] R2 I CP[29] C
VP_DOUT[12] / LCD_D[12] / UPP_XD[4] / GP7[4] / BOOT[4] R1 I CP[29] C
Boot Mode Selection Pins
VP_DOUT[11] / LCD_D[11] / UPP_XD[3] /GP7[3] / BOOT[3] T3 I CP[29] C
VP_DOUT[10] / LCD_D[10] / UPP_XD[2] /GP7[2] / BOOT[2] T2 I CP[29] C
VP_DOUT[9] / LCD_D[9] / UPP_XD[1] /GP7[1] / BOOT[1] T1 I CP[29] C
VP_DOUT[8] / LCD_D[8] / UPP_XD[0] /GP7[0] / BOOT[0] U3 I CP[29] C
(1) Boot decoding is defined in the bootloader application report.
(2) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(3) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(4) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.12 Universal Asynchronous Receiver/Transmitters (UART0, UART1, UART2)

Table 3-14. Universal Asynchronous Receiver/Transmitter (UART) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
UART0
SPI0_SCS[5] / UART0_RXD / GP8[4] C19 I CP[8] A UART0 receive data
SPI0_SCS[4] / UART0_TXD / GP8[3] D18 O CP[8] A UART0 transmit data
SPI0_SCS[2] / UART0_RTS / GP8[1] D16 O CP[9] A UART0 ready-to-send output
SPI0_SCS[3] / UART0_CTS / GP8[2] E17 I CP[9] A UART0 clear-to-send input
UART1
SPI1_SCS[3] / UART1_RXD / GP1[1] E18 I CP[13] A UART1 receive data
SPI1_SCS[2] / UART1_TXD / GP1[0] F19 O CP[13] A UART1 transmit data
AHCLKR / PRU0_R30[18] / UART1_RTS / GP0[11] /
A2 O CP[0] A UART1 ready-to-send output
PRU0_R31[18]
AHCLKX / USB_REFCLKIN / UART1_CTS / GP0[10] /
A3 I CP[0] A UART1 clear-to-send input
PRU0_R31[17]
UART2
SPI1_SCS[5] / UART2_RXD / I2C1_SCL / GP1[3] F17 I CP[12] A UART2 receive data
SPI1_SCS[4] / UART2_TXD / I2C1_SDA / GP1[2] F16 O CP[12] A UART2 transmit data
AMUTE / PRU0_R30[16] / UART2_RTS / GP0[9] /
D5 O CP[0] A UART2 ready-to-send output
PRU0_R31[16]
RTC_ALARM / UART2_CTS / GP0[8] / DEEPSLEEP F4 I CP[0] A UART2 clear-to-send input
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module.The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.13 Inter-Integrated Circuit Modules(I2C0, I2C1)

Table 3-15. Inter-Integrated Circuit (I2C) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
I2C0
SPI1_SCS[6] / I2C0_SDA / TM64P3_OUT12 / GP1[4] G18 I/O CP[11] A I2C0 serial data
SPI1_SCS[7] / I2C0_SCL / TM64P2_OUT12 / GP1[5] G16 I/O CP[11] A I2C0 serial clock
I2C1
SPI1_SCS[4] / UART2_TXD / I2C1_SDA / GP1[2] F16 I/O CP[12] A I2C1 serial data
SPI1_SCS[5] / UART2_RXD / I2C1_SCL / GP1[3] F17 I/O CP[12] A I2C1 serial clock
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module.The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.14 Timers

Table 3-16. Timers Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
TIMER0
SPI0_SCS[1] /TM64P0_OUT12 / GP1[7] / TM64P0_IN12 E16 I CP[10] A Timer0 lower input
Timer0 lower
SPI0_SCS[1] / TM64P0_OUT12 / GP1[7] / TM64P0_IN12 E16 O CP[10] A
output
TIMER1 (Watchdog)
SPI0_SCS[0] / TM64P1_OUT12 / GP1[6] / TM64P1_IN12 D17 I CP[10] A Timer1 lower input
Timer1 lower
SPI0_SCS[0] / TM64P1_OUT12 / GP1[6] / TM64P1_IN12 D17 O CP[10] A
output
TIMER2
SPI1_SCS[1] / EPWM1A / PRU0_R30[8] / GP2[15] / TM64P2_IN12 F18 I CP[14] A Timer2 lower input
Timer2 lower
SPI1_SCS[7] / I2C0_SCL / TM64P2_OUT12 / GP1[5] G16 O CP[11] A
output
TIMER3
SPI1_SCS[0] / EPWM1B / PRU0_R30[7] / GP2[14] / TM64P3_IN12 E19 I CP[14] A Timer3 lower input
Timer3 lower
SPI1_SCS[6] / I2C0_SDA / TM64P3_OUT12 / GP1[4] G18 O CP[11] A
output
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.15 Multichannel Audio Serial Ports (McASP)

Table 3-17. Multichannel Audio Serial Ports Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
McASP0
AXR15 / EPWM0TZ[0] / ECAP2_APWM2 / GP0[7] A4 I/O CP[1] A
AXR14 / CLKR1 / GP0[6] B4 I/O CP[2] A
AXR13 / CLKX1 / GP0[5] B3 I/O CP[2] A
AXR12 / FSR1 / GP0[4] C4 I/O CP[2] A
AXR11 / FSX1 / GP0[3] C5 I/O CP[2] A
AXR10 / DR1 / GP0[2] D4 I/O CP[2] A
AXR9 / DX1 / GP0[1] C3 I/O CP[2] A
AXR8 / CLKS1 / ECAP1_APWM1 / GP0[0] / PRU0_R31[8] E4 I/O CP[3] A
AXR7 / EPWM1TZ[0] / PRU0_R30[17] / GP1[15] / McASP0 serial data
D2 I/O CP[4] A
PRU0_R31[7]
AXR6 / CLKR0 / GP1[14] / PRU0_R31[6] C1 I/O CP[5] A
AXR5 / CLKX0 / GP1[13] D3 I/O CP[5] A
AXR4 / FSR0 / GP1[12] D1 I/O CP[5] A
AXR3 / FSX0 / GP1[11] E3 I/O CP[5] A
AXR2 / DR0 / GP1[10] E2 I/O CP[5] A
AXR1 / DX0 / GP1[9] E1 I/O CP[5] A
AXR0 / ECAP0_APWM0 / GP8[7] / CLKS0 F3 I/O CP[6] A
AHCLKX / USB_REFCLKIN / UART1_CTS / GP0[10] /
A3 I/O CP[0] A McASP0 transmit master clock
PRU0_R31[17]
ACLKX / PRU0_R30[19]/ GP0[14]/ PRU0_R31[21] B1 I/O CP[0] A McASP0 transmit bit clock
AFSX / GP0[12] / PRU0_R31[19] B2 I/O CP[0] A McASP0 transmit frame sync
AHCLKR / PRU0_R30[18] / UART1_RTS /GP0[11] /
A2 I/O CP[0] A McASP0 receive master clock
PRU0_R31[18]
ACLKR / PRU0_R30[20] / GP0[15] / PRU0_R31[22] A1 I/O CP[0] A McASP0 receive bit clock
AFSR / GP0[13] / PRU0_R31[20] C2 I/O CP[0] A McASP0 receive frame sync
AMUTE / PRU0_R30[16] / UART2_RTS / GP0[9] /
D5 I/O CP[0] A McASP0 mute output
PRU0_R31[16]
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.16 Multichannel Buffered Serial Ports (McBSP)

Table 3-18. Multichannel Buffered Serial Ports (McBSPs) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
McBSP0
AXR0 / ECAP0_APWM0 / GP8[7] / CLKS0 F3 I CP[6] A McBSP0 sample rate generator clock input
AXR6 / CLKR0 / GP1[14] / PRU0_R31[6] C1 I/O CP[5] A McBSP0 receive clock
AXR4 / FSR0 / GP1[12] D1 I/O CP[5] A McBSP0 receive frame sync
AXR2 / DR0 / GP1[10] E2 I CP[5] A McBSP0 receive data
AXR5 / CLKX0 / GP1[13] D3 I/O CP[5] A McBSP0 transmit clock
AXR3 / FSX0 / GP1[11] E3 I/O CP[5] A McBSP0 transmit frame sync
AXR1 / DX0 / GP1[9] E1 O CP[5] A McBSP0 transmit data
McBSP1
AXR8 / CLKS1 / ECAP1_APWM1 / GP0[0] /
E4 I CP[3] A McBSP1 sample rate generator clock input
PRU0_R31[8]
AXR14 / CLKR1 / GP0[6] B4 I/O CP[2] A McBSP1 receive clock
AXR12 / FSR1 / GP0[4] C4 I/O CP[2] A McBSP1 receive frame sync
AXR10 / DR1 / GP0[2] D4 I CP[2] A McBSP1 receive data
AXR13 / CLKX1 / GP0[5] B3 I/O CP[2] A McBSP1 transmit clock
AXR11 / FSX1 / GP0[3] C5 I/O CP[2] A McBSP1 transmit frame sync
AXR9 / DX1 / GP0[1] C3 O CP[2] A McBSP1 transmit data
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.17 Universal Serial Bus Modules (USB0)

Table 3-19. Universal Serial Bus (USB) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
USB0 2.0 OTG (USB0)
USB0_DM M18 A IPD — USB0 PHY data minus
USB0_DP M19 A IPD — USB0 PHY data plus
USB0_VDDA33 N18 PWR — — USB0 PHY 3.3-V supply
USB0 PHY identification
USB0_ID P16 A — —
(mini-A or mini-B plug)
USB0_VBUS N19 A — — USB0 bus voltage
USB0_DRVVBUS K18 O IPD B USB0 controller VBUS control output.
AHCLKX / USB_REFCLKIN / UART1_CTS /
A3 I CP[0] A USB_REFCLKIN. Optional clock input
GP0[10] / PRU0_R31[17]
USB0_VDDA18 N14 PWR — — USB0 PHY 1.8-V supply input
USB0 PHY 1.2-V LDO output for bypass cap
For proper device operation, this pin must
USB0_VDDA12 N17 A — — always be connected via a 0.22-μF capacitor
to VSS (GND), even if USB0 is not being
used.
USB_CVDD M12 PWR — — USB0 core logic 1.2-V supply input
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.18 Multimedia Card/Secure Digital (MMC/SD)

Table 3-20. Multimedia Card/Secure Digital (MMC/SD) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
MMCSD0
MMCSD0_CLK / PRU1_R30[31] / GP4[7] E9 O CP[18] B MMCSD0 Clock
EMA_A[22] / MMCSD0_CMD / PRU1_R30[30] / GP4[6] A10 I/O CP[18] B MMCSD0 Command
EMA_A[14] / MMCSD0_DAT[7] / PRU1_R30[22] / GP5[14] /
A12 I/O CP[19] B
PRU1_R31[22]
EMA_A[15] / MMCSD0_DAT[6] / PRU1_R30[23] / GP5[15] /
C11 I/O CP[19] B
PRU1_R31[23]
EMA_A[16] / MMCSD0_DAT[5] / PRU1_R30[24] / GP4[0] E12 I/O CP[18] B
EMA_A[17] / MMCSD0_DAT[4] / PRU1_R30[25] / GP4[1] B11 I/O CP[18] B MMC/SD0 data
EMA_A[18] / MMCSD0_DAT[3] / PRU1_R30[26] / GP4[2] E11 I/O CP[18] B
EMA_A[19] / MMCSD0_DAT[2] / PRU1_R30[27] / GP4[3] C10 I/O CP[18] B
EMA_A[20] / MMCSD0_DAT[1] / PRU1_R30[28] / GP4[4] A11 I/O CP[18] B
EMA_A[21] / MMCSD0_DAT[0] / PRU1_R30[29] / GP4[5] B10 I/O CP[18] B
MMCSD1
PRU0_R30[24] /MMCSD1_CLK / UPP_CHB_START /
G2 O CP[30] C MMCSD1 Clock
GP8[14]/PRU1_R31[26]/
PRU0_R30[23] /MMCSD1_CMD / UPP_CHB_ENABLE /
J4 I/O CP[30] C MMCSD1 Command
GP8[13]/PRU1_R31[25]
MMCSD1_DAT[7] / LCD_PCLK / PRU1_R30[7] / GP8[11] F1 I/O CP[31] C
MMCSD1_DAT[6] / LCD_MCLK /PRU1_R30[6] / GP8[10] /
F2 I/O CP[31] C
PRU1_R31[7]
MMCSD1_DAT[5] / LCD_HSYNC /PRU1_R30[5] / GP8[9] /
H4 I/O CP[31] C
PRU1_R31[6]
MMCSD1_DAT[4] / LCD_VSYNC /PRU1_R30[4] / GP8[8] /
G4 I/O CP[31] C
PRU1_R31[5]
VP_CLKIN2 / MMCSD1_DAT[3] / PRU1_R30[3] / GP6[4] / MMC/SD1 data
H3 I/O CP[30] C
PRU1_R31[4]
VP_CLKOUT2 / MMCSD1_DAT[2] / PRU1_R30[2] / GP6[3] /
K3 I/O CP[30] C
PRU1_R31[3]
VP_CLKIN3 / MMCSD1_DAT[1]/ PRU1_R30[1] / GP6[2] /
J3 I/O CP[30] C
PRU1_R31[2]
PRU0_R30[25] / MMCSD1_DAT[0] / UPP_CHB_CLOCK / GP8[15]/
G1 I/O CP[30] C
PRU1_R31[27]
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.19 Liquid Crystal Display Controller(LCD)

Table 3-21. Liquid Crystal Display Controller (LCD) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
VP_DOUT[15] / LCD_D[15] / UPP_XD[7] / GP7[7] / BOOT[7] P4 I/O CP[29] C
VP_DOUT[14] / LCD_D[14] / UPP_XD[6] / GP7[6] / BOOT[6] R3 I/O CP[29] C
VP_DOUT[13] / LCD_D[13] / UPP_XD[5] / GP7[5] / BOOT[5] R2 I/O CP[29] C
VP_DOUT[12] / LCD_D[12] / UPP_XD[4] / GP7[4] / BOOT[4] R1 I/O CP[29] C
VP_DOUT[11] / LCD_D[11] / UPP_XD[3] / GP7[3] / BOOT[3] T3 I/O CP[29] C
VP_DOUT[10] / LCD_D[10] / UPP_XD[2] / GP7[2] / BOOT[2] T2 I/O CP[29] C
VP_DOUT[9] / LCD_D[9] / UPP_XD[1] / GP7[1] / BOOT[1] T1 I/O CP[29] C
VP_DOUT[8] / LCD_D[8] / UPP_XD[0] / GP7[0] / BOOT[0] U3 I/O CP[29] C
VP_DOUT[7] / LCD_D[7] / UPP_XD[15] / GP7[15] /
U2 I/O CP[28] C
PRU1_R31[15]
VP_DOUT[6] / LCD_D[6] / UPP_XD[14] / GP7[14] / LCD data bus
U1 I/O CP[28] C
PRU1_R31[14]
VP_DOUT[5] / LCD_D[5] / UPP_XD[13] / GP7[13] /
V3 I/O CP[28] C
PRU1_R31[13]
VP_DOUT[4] / LCD_D[4] / UPP_XD[12] / GP7[12] /
V2 I/O CP[28] C
PRU1_R31[12]
VP_DOUT[3] / LCD_D[3] / UPP_XD[11] / GP7[11] /
V1 I/O CP[28] C
PRU1_R31[11]
VP_DOUT[2] / LCD_D[2] / UPP_XD[10] / GP7[10] /
W3 I/O CP[28] C
PRU1_R31[10]
VP_DOUT[1] / LCD_D[1] / UPP_XD[9] / GP7[9] / PRU1_R31[9] W2 I/O CP[28] C
VP_DOUT[0] / LCD_D[0] / UPP_XD[8] / GP7[8] / PRU1_R31[8] W1 I/O CP[28] C
MMCSD1_DAT[7] / LCD_PCLK / PRU1_R30[7] / GP8[11] F1 O CP[31] C LCD pixel clock
MMCSD1_DAT[5] / LCD_HSYNC / PRU1_R30[5] / GP8[9] /
H4 O CP[31] C LCD horizontal sync
PRU1_R31[6]
MMCSD1_DAT[4] / LCD_VSYNC / PRU1_R30[4] / GP8[8] /
G4 O CP[31] C LCD vertical sync
PRU1_R31[5]
LCD AC bias enable chip
LCD_AC_ENB_CS / GP6[0]/ / PRU1_R31[28] R5 O CP[31] C
select
MMCSD1_DAT[6] / LCD_MCLK / PRU1_R30[6] / GP8[10] /
F2 O CP[31] C LCD memory clock
PRU1_R31[7]
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.20 Universal Host-Port Interface (UHPI)

Table 3-22. Universal Host-Port Interface (UHPI) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
VP_DIN[7] / UHPI_HD[15] / UPP_D[15] / PRU0_R31[29] U18 I/O CP[26] C
VP_DIN[6] / UHPI_HD[14] / UPP_D[14] / PRU0_R31[28] V16 I/O CP[26] C
VP_DIN[5] / UHPI_HD[13] / UPP_D[13] / PRU0_R31[27] R14 I/O CP[26] C
VP_DIN[4] / UHPI_HD[12] / UPP_D[12] / PRU0_R31[26] W16 I/O CP[26] C
VP_DIN[3] / UHPI_HD[11] / UPP_D[11] / PRU0_R31[25] V17 I/O CP[26] C
VP_DIN[2] / UHPI_HD[10] / UPP_D[10] / PRU0_R31[24] W17 I/O CP[26] C
VP_DIN[1] / UHPI_HD[9] / UPP_D[9] / PRU0_R31[23] W18 I/O CP[26] C
VP_DIN[0] / UHPI_HD[8] / UPP_D[8] / PRU1_R31[29] W19 I/O CP[26] C
VP_DIN[15]_VSYNC / UHPI_HD[7] / UPP_D[7] / PRU0_R30[15] /
V18 I/O CP[27] C
PRU0_R31[15]
VP_DIN[14]_HSYNC / UHPI_HD[6] / UPP_D[6] / PRU0_R30[14] / UHPI data bus
V19 I/O CP[27] C
PRU0_R31[14]
VP_DIN[13]_FIELD / UHPI_HD[5] / UPP_D[5] / PRU0_R30[13] /
U19 I/O CP[27] C
PRU0_R31[13]
VP_DIN[12] / UHPI_HD[4] / UPP_D[4] / PRU0_R30[12] /
T16 I/O CP[27] C
PRU0_R31[12]
VP_DIN[11] / UHPI_HD[3] / UPP_D[3] / PRU0_R30[11] /
R18 I/O CP[27] C
PRU0_R31[11]
VP_DIN[10] / UHPI_HD[2] / UPP_D[2] / PRU0_R30[10] /
R19 I/O CP[27] C
PRU0_R31[10]
VP_DIN[9] / UHPI_HD[1] / UPP_D[1] / PRU0_R30[9] / PRU0_R31[9] R15 I/O CP[27] C
VP_DIN[8] / UHPI_HD[0] / UPP_D[0] / GP6[5] / PRU1_R31[0] P17 I/O CP[27] C
PRU0_R30[29] / UHPI_HCNTL0 / UPP_CHA_CLOCK / GP6[11] U17 I CP[24] C
UHPI access control
PRU0_R30[28] / UHPI_HCNTL1 / UPP_CHA_START / GP6[10] W15 I CP[24] C
UHPI half-word
PRU0_R30[27] / UHPI_HHWIL / UPP_CHA_ENABLE / GP6[9] U16 I CP[24] C
identification control
PRU0_R30[26] /UHPI_HRW / UPP_CHA_WAIT /
T15 I CP[24] C UHPI read/write
GP6[8]/PRU1_R31[17]
VP_CLKIN0 / UHPI_HCS / PRU1_R30[10] / GP6[7] / UPP_2xTXCLK W14 I CP[25] C UHPI chip select
VP_CLKIN1 / UHPI_HDS1 / PRU1_R30[9] / GP6[6] / PRU1_R31[16] V15 I CP[25] C
UHPI data strobe
CLKOUT / UHPI_HDS2 / PRU1_R30[13] / GP6[14] T18 I CP[22] C
PRU0_R30[30] / UHPI_HINT / PRU1_R30[11] / GP6[12] R16 O CP[23] C UHPI host interrupt
PRU0_R30[31] / UHPI_HRDY / PRU1_R30[12] /GP6[13] R17 O CP[23] C UHPI ready
RESETOUT / UHPI_HAS / PRU1_R30[14] / GP6[15] T17 I CP[21] C UHPI address strobe
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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3.7.21 Universal Parallel Port (uPP)

Table 3-23. Universal Parallel Port (uPP) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
VP_CLKIN0 / UHPI_HCS /PRU1_R30[10] / GP6[7] /
W14 I CP[25] C uPP 2x transmit clock input
UPP_2xTXCLK
PRU0_R30[25] /MMCSD1_DAT[0] / UPP_CHB_CLOCK /
G1 I/O CP[30] C uPP channel B clock
GP8[15]/PRU1_R31[27]
PRU0_R30[24]/ MMCSD1_CLK / UPP_CHB_START / GP8[14] /
G2 I/O CP[30] C uPP channel B start
PRU1_R31[26]
PRU0_R30[23] / MMCSD1_CMD / UPP_CHB_ENABLE /
J4 I/O CP[30] C uPP channel B enable
GP8[13]/PRU1_R31[25]
PRU0_R30[22] / PRU1_R30[8] / UPP_CHB_WAIT / GP8[12]/
G3 I/O CP[30] C uPP channel B wait
PRU1_R31[24]
PRU0_R30[29] /UHPI_HCNTL0 / UPP_CHA_CLOCK / GP6[11] U17 I/O CP[24] C uPP channel A clock
PRU0_R30[28] / UHPI_HCNTL1 / UPP_CHA_START / GP6[10] W15 I/O CP[24] C uPP channel A start
PRU0_R30[27] / UHPI_HHWIL / UPP_CHA_ENABLE / GP6[9] U16 I/O CP[24] C uPP channel A enable
PRU0_R30[26] /UHPI_HRW / UPP_CHA_WAIT / GP6[8] /
T15 I/O CP[24] C uPP channel A wait
PRU1_R31[17]
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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Table 3-23. Universal Parallel Port (uPP) Terminal Functions (continued)


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
VP_DOUT[7] / LCD_D[7] / UPP_XD[15] / GP7[15] /
U2 I/O CP[28] C
PRU1_R31[15]
VP_DOUT[6] / LCD_D[6] / UPP_XD[14] / GP7[14] /
U1 I/O CP[28] C
PRU1_R31[14]
VP_DOUT[5] / LCD_D[5] / UPP_XD[13] / GP7[13] /
V3 I/O CP[28] C
PRU1_R31[13]
VP_DOUT[4] / LCD_D[4] / UPP_XD[12] / GP7[12] /
V2 I/O CP[28] C
PRU1_R31[12]
VP_DOUT[3] / LCD_D[3] / UPP_XD[11] / GP7[11] /
V1 I/O CP[28] C
PRU1_R31[11]
VP_DOUT[2] / LCD_D[2] / UPP_XD[10] / GP7[10] /
W3 I/O CP[28] C
PRU1_R31[10]
VP_DOUT[1] / LCD_D[1] / UPP_XD[9] / GP7[9] / PRU1_R31[9] W2 I/O CP[28] C
VP_DOUT[0] / LCD_D[0] / UPP_XD[8] / GP7[8] / PRU1_R31[8] W1 I/O CP[28] C
VP_DOUT[15] / LCD_D[15] / UPP_XD[7] / GP7[7] / BOOT[7] P4 I/O CP[29] C
VP_DOUT[14] / LCD_D[14] / UPP_XD[6] / GP7[6] / BOOT[6] R3 I/O CP[29] C
VP_DOUT[13] / LCD_D[13] / UPP_XD[5] / GP7[5] / BOOT[5] R2 I/O CP[29] C
VP_DOUT[12] / LCD_D[12] / UPP_XD[4] / GP7[4] / BOOT[4] R1 I/O CP[29] C
VP_DOUT[11] / LCD_D[11] / UPP_XD[3] / GP7[3] / BOOT[3] T3 I/O CP[29] C
VP_DOUT[10] / LCD_D[10] / UPP_XD[2] / GP7[2] / BOOT[2] T2 I/O CP[29] C
VP_DOUT[9] / LCD_D[9] / UPP_XD[1] / GP7[1] / BOOT[1] T1 I/O CP[29] C
VP_DOUT[8] / UPP_XD[0] / GP7[0] / BOOT[0] U3 I/O CP[29] C
VP_DIN[7] / UHPI_HD[15] / UPP_D[15] / PRU0_R31[29] U18 I/O CP[26] C uPP data bus
VP_DIN[6] / UHPI_HD[14] / UPP_D[14] / PRU0_R31[28] V16 I/O CP[26] C
VP_DIN[5] / UHPI_HD[13] / UPP_D[13] / PRU0_R31[27] R14 I/O CP[26] C
VP_DIN[4] / UHPI_HD[12] / UPP_D[12] / PRU0_R31[26] W16 I/O CP[26] C
VP_DIN[3] / UHPI_HD[11] / UPP_D[11] / PRU0_R31[25] V17 I/O CP[26] C
VP_DIN[2] / UHPI_HD[10] / UPP_D[10] / PRU0_R31[24] W17 I/O CP[26] C
VP_DIN[1] / UHPI_HD[9] / UPP_D[9] / PRU0_R31[23] W18 I/O CP[26] C
VP_DIN[0] / UHPI_HD[8] / UPP_D[8] / PRU1_R31[29] W19 I/O CP[26] C
VP_DIN[15]_VSYNC / UHPI_HD[7] / UPP_D[7]/PRU0_R30[15] /
V18 I/O CP[27] C
PRU0_R31[15]
VP_DIN[14]_HSYNC / UHPI_HD[6] / UPP_D[6]/ PRU0_R30[14] /
V19 I/O CP[27] C
PRU0_R31[14]
VP_DIN[13]_FIELD / UHPI_HD[5] / UPP_D[5] /PRU0_R30[13] /
U19 I/O CP[27] C
PRU0_R31[13]
VP_DIN[12] / UHPI_HD[4] / UPP_D[4]/ PRU0_R30[12] /
T16 I/O CP[27] C
PRU0_R31[12]
VP_DIN[11] / UHPI_HD[3] / UPP_D[3]/ PRU0_R30[11] /
R18 I/O CP[27] C
PRU0_R31[11]
VP_DIN[10] / UHPI_HD[2] / UPP_D[2]/ PRU0_R30[10] /
R19 I/O CP[27] C
PRU0_R31[10]
VP_DIN[9] / UHPI_HD[1] / UPP_D[1]/ PRU0_R30[9] /
R15 I/O CP[27] C
PRU0_R31[9]
VP_DIN[8] / UHPI_HD[0] / UPP_D[0] / GP6[5] / PRU1_R31[0] P17 I/O CP[27] C

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3.7.22 Video Port Interface (VPIF)

Table 3-24. Video Port Interface (VPIF) Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
VIDEO INPUT
VP_CLKIN0 / UHPI_HCS / PRU1_R30[10] / GP6[7] / VPIF capture channel 0
W14 I CP[25] C
UPP_2xTXCLK input clock
VPIF capture channel 1
VP_CLKIN1 / UHPI_HDS1/PRU1_R30[9] / GP6[6] / PRU1_R31[16] V15 I CP[25] C
input clock
VP_DIN[15]_VSYNC / UHPI_HD[7] / UPP_D[7] / PRU0_R30[15] /
V18 I CP[27] C
PRU0_R31[15]
VP_DIN[14]_HSYNC / UHPI_HD[6] / UPP_D[6] / PRU0_R30[14] /
V19 I CP[27] C
PRU0_R31[14]
VP_DIN[13]_FIELD / UHPI_HD[5] / UPP_D[5] / PRU0_R30[13] /
U19 I CP[27] C
PRU0_R31[13]
VP_DIN[12] / UHPI_HD[4] / UPP_D[4] / PRU0_R30[12] /
T16 I CP[27] C
PRU0_R31[12]
VP_DIN[11] / UHPI_HD[3] / UPP_D[3] / PRU0_R30[11] /
R18 I CP[27] C
PRU0_R31[11]
VP_DIN[10] / UHPI_HD[2] / UPP_D[2] / PRU0_R30[10] /
R19 I CP[27] C
PRU0_R31[10]
VP_DIN[9] / UHPI_HD[1] / UPP_D[1] / PRU0_R30[9] / VPIF capture data bus
R15 I CP[27] C
PRU0_R31[9]
VP_DIN[8] / UHPI_HD[0] / UPP_D[0] / GP6[5] / PRU1_R31[0] P17 I CP[27] C
VP_DIN[7] / UHPI_HD[15] / UPP_D[15] / PRU0_R31[29] U18 I CP[26] C
VP_DIN[6] / UHPI_HD[14] / UPP_D[14] / PRU0_R31[28] V16 I CP[26] C
VP_DIN[5] / UHPI_HD[13] / UPP_D[13] / PRU0_R31[27] R14 I CP[26] C
VP_DIN[4] / UHPI_HD[12] / UPP_D[12] / PRU0_R31[26] W16 I CP[26] C
VP_DIN[3] / UHPI_HD[11] / UPP_D[11] / PRU0_R31[25] V17 I CP[26] C
VP_DIN[2] / UHPI_HD[10] / UPP_D[10] / PRU0_R31[24] W17 I CP[26] C
VP_DIN[1] / UHPI_HD[9] / UPP_D[9] / PRU0_R31[23] W18 I CP[26] C
VP_DIN[0] / UHPI_HD[8] / UPP_D[8] / PRU1_R31[29] W19 I CP[26] C
VIDEO OUTPUT
VP_CLKIN2 / MMCSD1_DAT[3] / PRU1_R30[3] / GP6[4] / VPIF display channel 2
H3 I CP[30] C
PRU1_R31[4] input clock
VP_CLKOUT2 / MMCSD1_DAT[2] / PRU1_R30[2] / GP6[3] / VPIF display channel 2
K3 O CP[30] C
PRU1_R31[3] output clock
VP_CLKIN3 / MMCSD1_DAT[1] / PRU1_R30[1] / GP6[2] / VPIF display channel 3
J3 I CP[30] C
PRU1_R31[2] input clock
VPIF display channel 3
VP_CLKOUT3 / PRU1_R30[0] / GP6[1] / PRU1_R31[1] K4 O CP[30] C
output clock

(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. or more detailed information on pullup/pulldown resistors and situations where external pullup/pulldown
resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown circuits, see the
Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.
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Table 3-24. Video Port Interface (VPIF) Terminal Functions (continued)


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
VP_DOUT[15] / LCD_D[15] / UPP_XD[7] / GP7[7] / BOOT[7] P4 O CP[29] C
VP_DOUT[14] / LCD_D[14] / UPP_XD[6]/ GP7[6] / BOOT[6] R3 O CP[29] C
VP_DOUT[13] / LCD_D[13] / UPP_XD[5] / GP7[5] / BOOT[5] R2 O CP[29] C
VP_DOUT[12] / LCD_D[12] / 4PP_XD[7] / GP7[4] / BOOT[4] R1 O CP[29] C
VP_DOUT[11] / LCD_D[11] / UPP_XD[3] / GP7[3] / BOOT[3] T3 O CP[29] C
VP_DOUT[10] / LCD_D[10] / UPP_XD[2] / GP7[2] / BOOT[2] T2 O CP[29] C
VP_DOUT[9] / LCD_D[9] / UPP_XD[1] / GP7[1] / BOOT[1] T1 O CP[29] C
VP_DOUT[8] / LCD_D[8] / UPP_XD[1] / GP7[0] / BOOT[0] U3 O CP[29] C
VPIF display data bus
VP_DOUT[7] / LCD_D[7] / UPP_XD[15]] / GP7[15] / PRU1_R31[15] U2 O CP[28] C
VP_DOUT[6] / LCD_D[6] / UPP_XD[14] / GP7[14] / PRU1_R31[14] U1 O CP[28] C
VP_DOUT[5] / LCD_D[5] / UPP_XD[13] / GP7[13] / PRU1_R31[13] V3 O CP[28] C
VP_DOUT[4] / LCD_D[4] / UPP_XD[12] / GP7[12] / PRU1_R31[12] V2 O CP[28] C
VP_DOUT[3] / LCD_D[3] / UPP_XD[11] / GP7[11] / PRU1_R31[11] V1 O CP[28] C
VP_DOUT[2] / LCD_D[2] / UPP_XD[10] / GP7[10] / PRU1_R31[10] W3 O CP[28] C
VP_DOUT[1] / LCD_D[1] / UPP_XD[9] / GP7[9] / PRU1_R31[9] W2 O CP[28] C
VP_DOUT[0] /LCD_D[0] / UPP_XD[8] / GP7[8] / PRU1_R31[8] W1 O CP[28] C

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3.7.23 General Purpose Input Output

Table 3-25. General Purpose Input Output Terminal Functions


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
GP0
ACLKR / PRU0_R30[20] / GP0[15] / PRU0_R31[22] A1 I/O CP[0] A
ACLKX / PRU0_R30[19] / GP0[14] / PRU0_R31[21] B1 I/O CP[0] A
AFSR / GP0[13] / PRU0_R31[20] C2 I/O CP[0] A
AFSX / GP0[12] /PRU0_R31[19] B2 I/O CP[0] A
AHCLKR / PRU0_R30[18] / UART1_RTS / GP0[11] /
A2 I/O CP[0] A
PRU0_R31[18]
AHCLKX / USB_REFCLKIN / UART1_CTS / GP0[10] /
A3 I/O CP[0] A
PRU0_R31[17]
AMUTE / PRU0_R30[16] / UART2_RTS / GP0[9] / PRU0_R31[16] D5 I/O CP[0] A
RTC_ALARM / UART2_CTS / GP0[8] / DEEPSLEEP F4 I/O CP[0] A GPIO Bank 0
AXR15 / EPWM0TZ[0] / ECAP2_APWM2 / GP0[7] A4 I/O CP[1] A
AXR14 / CLKR1 / GP0[6] B4 I/O CP[2] A
AXR13 / CLKX1 / GP0[5] B3 I/O CP[2] A
AXR12 / FSR1 / GP0[4] C4 I/O CP[2] A
AXR11 / FSX1 / GP0[3] C5 I/O CP[2] A
AXR10 / DR1 / GP0[2] D4 I/O CP[2] A
AXR9 / DX1 / GP0[1] C3 I/O CP[2] A
AXR8 / CLKS1 / ECAP1_APWM1 / GP0[0] / PRU0_R31[8] E4 I/O CP[3] A
(1) I = Input, O = Output, I/O = Bidirectional, Z = High impedance, PWR = Supply voltage, GND = Ground, A = Analog signal.
Note: The pin type shown refers to the input, output or high-impedance state of the pin function when configured as the signal name
highlighted in bold. All multiplexed signals may enter a high-impedance state when the configured function is input-only or the configured
function supports high-Z operation. All GPIO signals can be used as input or output. For multiplexed pins where functions have different
types (ie., input versus output), the table reflects the pin function direction for that particular peripheral.
(2) IPD = Internal Pulldown resistor; IPU = Internal Pullup resistor; CP[n] = configurable pull-up/pull-down (where n is the pin group) using
the PUPDENA and PUPDSEL registers in the System Module. The pull-up and pull-down control of these pins is not active until the
device is out of reset. During reset, all of the pins associated with these registers are pulled down. If the application requires a pull-up,
an external pull-up can be used. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see the Device Configuration section. For electrical specifications on pullup and internal pulldown
circuits, see the Device Operating Conditions section.
(3) This signal is part of a dual-voltage IO group (A, B or C). These groups can be operated at 3.3V or 1.8V nominal. The three groups can
be operated at independent voltages but all pins withina group will operate at the same voltage. Group A operates at the voltage of
power supply DVDD3318_A. Group B operates at the voltage of power supply DVDD3318_B. Group C operates at the voltage of power
supply DVDD3318_C.

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Table 3-25. General Purpose Input Output Terminal Functions (continued)


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
GP1
AXR7 / EPWM1TZ[0] / PRU0_R30[17] / GP1[15] / PRU0_R31[7] D2 I/O CP[4] A
AXR6 / CLKR0 / GP1[14] / PRU0_R31[6] C1 I/O CP[5] A
AXR5 / CLKX0 / GP1[13] D3 I/O CP[5] A
AXR4 / FSR0 / GP1[12] D1 I/O CP[5] A
AXR3 / FSX0 / GP1[11] E3 I/O CP[5] A
AXR2 / DR0 / GP1[10] E2 I/O CP[5] A
AXR1 / DX0 / GP1[9] E1 I/O CP[5] A
SPI0_CLK / EPWM0A / GP1[8] D19 I/O CP[7] A
GPIO Bank 1
SPI0_SCS[1] / TM64P0_OUT12 / GP1[7] / TM64P0_IN12 E16 I/O CP[10] A
SPI0_SCS[0] / TM64P1_OUT12 / GP1[6] / TM64P1_IN12 D17 I/O CP[10] A
SPI1_SCS[7] / I2C0_SCL / TM64P2_OUT12 / GP1[5] G16 I/O CP[11] A
SPI1_SCS[6] / I2C0_SDA / TM64P3_OUT12 / GP1[4] G18 I/O CP[11] A
SPI1_SCS[5] / UART2_RXD / I2C1_SCL / GP1[3] F17 I/O CP[12] A
SPI1_SCS[4] / UART2_TXD / I2C1_SDA / GP1[2] F16 I/O CP[12] A
SPI1_SCS[3] / UART1_RXD / GP1[1] E18 I/O CP[13] A
SPI1_SCS[2] / UART1_TXD / GP1[0] F19 I/O CP[13] A
GP2
SPI1_SCS[1] / EPWM1A / PRU0_R30[8] / GP2[15] / TM64P2_IN12 F18 I/O CP[14] A
SPI1_SCS[0] / EPWM1B / PRU0_R30[7] / GP2[14] / TM64P3_IN12 E19 I/O CP[14] A
SPI1_CLK / GP2[13] G19 I/O CP[15] A
SPI1_ENA / GP2[12] H16 I/O CP[15] A
SPI1_SOMI / GP2[11] H17 I/O CP[15] A
SPI1_SIMO / GP2[10] G17 I/O CP[15] A
EMA_BA[1] / GP2[9] A15 I/O CP[16] B
EMA_BA[0] / GP2[8] C15 I/O CP[16] B
GPIO Bank 2
EMA_CLK / PRU0_R30[5] / GP2[7] / PRU0_R31[5] B7 I/O CP[16] B
EMA_SDCKE / PRU0_R30[4] / GP2[6] / PRU0_R31[4] D8 I/O CP[16] B
EMA_RAS / PRU0_R30[3] / GP2[5] / PRU0_R31[3] A16 I/O CP[16] B
EMA_CAS / PRU0_R30[2] / GP2[4] / PRU0_R31[2] A9 I/O CP[16] B
EMA_WEN_DQM[0] / GP2[3] C8 I/O CP[16] B
EMA_WEN_DQM[1] / GP2[2] A5 I/O CP[16] B
EMA_WAIT[1] / PRU0_R30[1] / GP2[1] / PRU0_R31[1] B19 I/O CP[16] B
EMA_CS[0] / GP2[0] A18 I/O CP[16] B

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Table 3-25. General Purpose Input Output Terminal Functions (continued)


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
GP3
EMA_CS[2] / GP3[15] B17 I/O CP[16] B
EMA_CS[3] / GP3[14] A17 I/O CP[16] B
EMA_CS[4] / GP3[13] F9 I/O CP[16] B
EMA_CS[5] / GP3[12] B16 I/O CP[16] B
EMA_WE / GP3[11] B9 I/O CP[16] B
EMA_OE / GP3[10] B15 I/O CP[16] B
EMA_A_RW / GP3[9] D10 I/O CP[16] B
EMA_WAIT[0] / PRU0_R30[0] / GP3[8] / PRU0_R31[0] B18 I/O CP[16] B
GPIO Bank 3
EMA_D[15] / GP3[7] E6 I/O CP[17] B
EMA_D[14] / GP3[6] C7 I/O CP[17] B
EMA_D[13] / GP3[5] B6 I/O CP[17] B
EMA_D[12] / GP3[4] A6 I/O CP[17] B
EMA_D[11] / GP3[3] D6 I/O CP[17] B
EMA_D[10] / GP3[2] A7 I/O CP[17] B
EMA_D[9] / GP3[1] D9 I/O CP[17] B
EMA_D[8] / GP3[0] E10 I/O CP[17] B
GP4
EMA_D[7] / GP4[15] D7 I/O CP[17] B
EMA_D[6] / GP4[14] C6 I/O CP[17] B
EMA_D[5] / GP4[13] E7 I/O CP[17] B
EMA_D[4] / GP4[12] B5 I/O CP[17] B
EMA_D[3] / GP4[11] E8 I/O CP[17] B
EMA_D[2] / GP4[10] B8 I/O CP[17] B
EMA_D[1] / GP4[9] A8 I/O CP[17] B
EMA_D[0] / GP4[8] C9 I/O CP[17] B
GPIO Bank 4
MMCSD0_CLK / PRU1_R30[31] / GP4[7] E9 I/O CP[18] B
EMA_A[22] / MMCSD0_CMD / PRU1_R30[30] / GP4[6] A10 I/O CP[18] B
EMA_A[21] / MMCSD0_DAT[0] / PRU1_R30[29] / GP4[5] B10 I/O CP[18] B
EMA_A[20] / MMCSD0_DAT[1] / PRU1_R30[28] / GP4[4] A11 I/O CP[18] B
EMA_A[19] / MMCSD0_DAT[2] / PRU1_R30[27] / GP4[3] C10 I/O CP[18] B
EMA_A[18] / MMCSD0_DAT[3] / PRU1_R30[26] / GP4[2] E11 I/O CP[18] B
EMA_A[17] / MMCSD0_DAT[4] / PRU1_R30[25] / GP4[1] B11 I/O CP[18] B
EMA_A[16] / MMCSD0_DAT[5] / PRU1_R30[24] / GP4[0] E12 I/O CP[18] B

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Table 3-25. General Purpose Input Output Terminal Functions (continued)


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
GP5
EMA_A[15] / MMCSD0_DAT[6] / PRU1_R30[23] / GP5[15] /
C11 I/O CP[19] B
PRU1_R31[23]
EMA_A[14] / MMCSD0_DAT[7] /PRU1_R30[22] / GP5[14] /
A12 I/O CP[19] B
PRU1_R31[22]
EMA_A[13] / PRU0_R30[21] / PRU1_R30[21] / GP5[13] /
D11 I/O CP[19] B
PRU1_R31[21]
EMA_A[12] / PRU1_R30[20] / GP5[12] / PRU1_R31[20] D13 I/O CP[19] B
EMA_A[11] / PRU1_R30[19] / GP5[11] / PRU1_R31[19] B12 I/O CP[19] B
EMA_A[10] / PRU1_R30[18] / GP5[10] / PRU1_R31[18] C12 I/O CP[19] B
EMA_A[9] / PRU1_R30[17] / GP5[9] D12 I/O CP[19] B
GPIO Bank 5
EMA_A[8] / PRU1_R30[16] / GP5[8] A13 I/O CP[19] B
EMA_A[7] / PRU1_R30[15] / GP5[7] B13 I/O CP[20] B
EMA_A[6] / GP5[6] E13 I/O CP[20] B
EMA_A[5] / GP5[5] C13 I/O CP[20] B
EMA_A[4] / GP5[4] A14 I/O CP[20] B
EMA_A[3] / GP5[3] D14 I/O CP[20] B
EMA_A[2] / GP5[2] B14 I/O CP[20] B
EMA_A[1] / GP5[1] D15 I/O CP[20] B
EMA_A[0] / GP5[0] C14 I/O CP[20] B
GP6
RESETOUT / UHPI_HAS / PRU1_R30[14] / GP6[15] T17 I/O CP[21] C
CLKOUT / UHPI_HDS2 / PRU1_R30[13] / GP6[14] T18 I/O CP[22] C
PRU0_R30[31] / UHPI_HRDY / PRU1_R30[12] / GP6[13] R17 I/O CP[23] C
PRU0_R30[30] / UHPI_HINT / PRU1_R30[11] / GP6[12] R16 I/O CP[23] C
PRU0_R30[29] / UHPI_HCNTL0 / UPP_CHA_CLOCK / GP6[11] U17 I/O CP[24] C
PRU0_R30[28] / UHPI_HCNTL1 / UPP_CHA_START / GP6[10] W15 I/O CP[24] C
PRU0_R30[27] / UHPI_HHWIL / UPP_CHA_ENABLE / GP6[9] U16 I/O CP[24] C
PRU0_R30[26] / UHPI_HRW / UPP_CHA_WAIT / GP6[8] /
T15 I/O CP[24] C
PRU1_R31[17]
VP_CLKIN0 / UHPI_HCS / PRU1_R30[10] / GP6[7] /
W14 I/O CP[25] C
UPP_2xTXCLK GPIO Bank 6
VP_CLKIN1 / UHPI_HDS1 / PRU1_R30[9] / GP6[6] /
V15 I/O CP[25] C
PRU1_R31[16]
VP_DIN[8] / UHPI_HD[0] / UPP_D[0] / GP6[5] / PRU1_R31[0] P17 I/O CP[27] C
VP_CLKIN2 / MMCSD1_DAT[3] / PRU1_R30[3] / GP6[4] /
H3 I/O CP[30] C
PRU1_R31[4]
VP_CLKOUT2 / MMCSD1_DAT[2] / PRU1_R30[2] / GP6[3] /
K3 I/O CP[30] C
PRU1_R31[3]
VP_CLKIN3 / MMCSD1_DAT[1] / PRU1_R30[1] / GP6[2] /
J3 I/O CP[30] C
PRU1_R31[2]
VP_CLKOUT3 / PRU1_R30[0] / GP6[1] / PRU1_R31[1] K4 I/O CP[30] C
LCD_AC_ENB_CS / GP6[0] / PRU1_R31[28] R5 I/O CP[31] C

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Table 3-25. General Purpose Input Output Terminal Functions (continued)


SIGNAL POWER
TYPE (1) PULL (2) DESCRIPTION
NAME NO. GROUP (3)
GP7
VP_DOUT[7] / LCD_D[7] / UPP_XD[15] / GP7[15] / PRU1_R31[15] U2 I/O CP[28] C
VP_DOUT[6] / LCD_D[6] / UPP_XD[14] / GP7[14] / PRU1_R31[14] U1 I/O CP[28] C
VP_DOUT[5] / LCD_D[5] / UPP_XD[13] / GP7[13] / PRU1_R31[13] V3 I/O CP[28] C
VP_DOUT[4] / LCD_D[4] / UPP_XD[12] / GP7[12] / PRU1_R31[12] V2 I/O CP[28] C
VP_DOUT[3] / LCD_D[3] / UPP_XD[11] / GP7[11] / PRU1_R31[11] V1 I/O CP[28] C
VP_DOUT[2] / LCD_D[2] / UPP_XD[10] / GP7[10] / PRU1_R31[10] W3 I/O CP[28] C
VP_DOUT[1] / LCD_D[1] / UPP_XD[9] / GP7[9] / PRU1_R31[9] W2 I/O CP[28] C
VP_DOUT[0] / LCD_D[0] / UPP_XD[8] / GP7[8] /PRU1_R31[8] W1 I/O CP[28] C
GPIO Bank 7
VP_DOUT[15/] LCD_D[15] / UPP_XD[7] / GP7[7] / BOOT[7] P4 I/O CP[29] C
VP_DOUT[14] / LCD_D[14] / UPP_XD[6] / GP7[6] / BOOT[6] R3 I/O CP[29] C
VP_DOUT[13] / LCD_D[13] / UPP_XD[5] / GP7[5] / BOOT[5] R2 I/O CP[29] C
VP_DOUT[12] / LCD_D[12] / UPP_XD[4] / GP7[4] / BOOT[4] R1 I/O CP[29] C
VP_DOUT[11] / LCD_D[11] / UPP_XD[3] / GP7[3] / BOOT[3] T3 I/O CP[29] C
VP_DOUT[10] / LCD_D[10] / UPP_XD[2] / GP7[2] / BOOT[2] T2 I/O CP[29] C
VP_DOUT[9] / LCD_D[9] / UPP_XD[1] / GP7[1] / BOOT[1] T1 I/O CP[29] C
VP_DOUT[8] / LCD_D[8] / UPP_XD[0] / GP7[0] / BOOT[0] U3 I/O CP[29] C
GP8
PRU0_R30[25] / MMCSD1_DAT[0] / UPP_CHB_CLOCK / GP8[15]
G1 I/O CP30] C
/ PRU1_R31[27]
PRU0_R30[24] / MMCSD1_CLK / UPP_CHB_START / GP8[14] /
G2 I/O CP[30] C
PRU1_R31[26]
PRU0_R30[23] / MMCSD1_CMD / UPP_CHB_ENABLE / GP8[13] /
J4 I/O CP[30] C
PRU1_R31[25]
PRU0_R30[22] / PRU1_R30[8] / UPP_CHB_WAIT / GP8[12] /
G3 I/O CP[30] C
PRU1_R31[24]
MMCSD1_DAT[7] / LCD_PCLK / PRU1_R30[7] / GP8[11] F1 I/O CP[31] C
MMCSD1_DAT[6] / LCD_MCLK / PRU1_R30[6] / GP8[10] /
F2 I/O CP[31] C
PRU1_R31[7]
MMCSD1_DAT[5] / LCD_HSYNC / PRU1_R30[5] / GP8[9] /
H4 I/O CP[31] C GPIO Bank 8
PRU1_R31[6]
MMCSD1_DAT[4] / LCD_VSYNC / PRU1_R30[4] / GP8[8] /
G4 I/O CP[31] C
PRU1_R31[5]
AXR0 / ECAP0_APWM0 / GP8[7] / CLKS0 F3 I/O CP[6] A
SPI0_SOMI /EPWMSYNCI / GP8[6] / MII_RXER C16 I/O CP[7] A
SPI0_SIMO / EPWMSYNCO / GP8[5] C18 I/O CP[7] A
SPI0_SCS[5] / UART0_RXD / GP8[4] C19 I/O CP[8] A
SPI0_SCS[4] / UART0_TXD / GP8[3] D18 I/O CP[8] A
SPI0_SCS[3] / UART0_CTS / GP8[2] E17 I/O CP[9] A
SPI0_SCS[2] / UART0_RTS / GP8[1] D16 I/O CP[9] A
(1)
GP8[0] K17 I/O IPD B
(1) GP8[0] is initially configured as a reserved function after reset and will not be in a predictable state. This signal will only be stable after
the GPIO configuration for this pin has been completed. Users should carefully consider the system implications of this pin being in an
unknown state after reset.

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3.7.24 Reserved and No Connect

Table 3-26. Reserved and No Connect Terminal Functions


SIGNAL
TYPE (1) DESCRIPTION
NAME NO.
Reserved. For proper device operation, this pin must be tied either directly to
RSV2 T19 PWR
CVDD or left unconnected (do not connect to ground).
Reserved. For proper device operation, the pin must be pulled up to supply
RSVDN J17 I
DVDD3318_B.
NC M14, N16 — These pins may be left unconnected or connected to ground (VSS).
NC M3 — These pins should be left unconnected (do not connect to power or ground).
NC M2,N4,P1,P2 — These pins should be left unconnected (do not connect to power or ground).
NC N1 — This pin should be left unconnected (do not connect to power or ground).
NC N2 — This pin should be left unconnected (do not connect to power or ground).
NC N3 — This pin should be left unconnected (do not connect to power or ground).
NC J1 — This pin should be left unconnected (do not connect to power or ground).
NC J2 — This pin should be left unconnected (do not connect to power or ground).
NC L1 — This pin should be left unconnected (do not connect to power or ground).
NC L2 — This pin should be left unconnected (do not connect to power or ground).
NC P3 — This pin should be left unconnected (do not connect to power or ground).
NC P14 — This pin should be left unconnected (do not connect to power or ground).
NC P15 — This pin should be left unconnected (do not connect to power or ground).
NC P18 — This pin should be left unconnected (do not connect to power or ground).
NC P19 — This pin should be left unconnected (do not connect to power or ground).
(1) PWR = Supply voltage.

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3.7.25 Supply and Ground

Table 3-27. Supply and Ground Terminal Functions


SIGNAL
TYPE (1) DESCRIPTION
NAME NO.
E15, G7, G8,
G13, H6, H7,
H10, H11,
CVDD (Core supply) H12, H13, J6, PWR Variable (1.2V - 1.0V) core supply voltage pins
J12, K6, K12,
L12, M8, M9,
N8
RVDD (Internal RAM supply) E5, H14, N7 PWR 1.2V internal ram supply voltage pins
F14, G6, G10,
G11, G12, 1.8V I/O supply voltage pins. DVDD18 must be powered even if all of
DVDD18 (I/O supply) PWR
J13, K5, L6, the DVDD3318_x supplies are operated at 3.3V.
P13, R13
F5, F15, G5,
DVDD3318_A (I/O supply) PWR 1.8V or 3.3-V dual-voltage LVCMOS I/O supply voltage pins, Group A
G14, G15, H5
E14, F6, F7,
F8, F10, F11,
DVDD3318_B (I/O supply) PWR 1.8V or 3.3-V dual-voltage LVCMOS I/O supply voltage pins, Group B
F12, F13, G9,
J14, K15
J5, K13, L4,
L13, M13,
DVDD3318_C (I/O supply) PWR 1.8V or 3.3-V dual-voltage LVCMOS I/O supply voltage pins, Group C
N13, P5, P6,
P12, R4
A19, H1, H2,
H8, H9, H15,
J7, J8, J9, J10,
J11, K1, K2,
K7, K8, K9,
K10, K11, L3,
VSS (Ground) GND Ground pins.
L5, L7, L8, L9,
L10, L11, M1,
M4, M5, M6,
M7, M10, M11,
N5, N11, N12,
P11
USB0_VDDA33 N18 PWR USB0 PHY 3.3-V supply
USB0_VDDA18 N14 PWR USB0 PHY 1.8-V supply input
USB0_VDDA12 N17 A USB0 PHY 1.2-V LDO output for bypass cap
USB_CVDD M12 PWR USB0 core logic 1.2-V supply input
N10, P10, N9,
DDR_DVDD18 P9, R9, P8, PWR DDR PHY 1.8V power supply pins
R8, P7, R7, N6
(1) PWR = Supply voltage, GND - Ground.

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3.8 Unused Pin Configurations


All signals multiplexed with multiple functions may be used as an alternate function if a given peripheral is
not used. Unused non-multiplexed signals and some other specific signals should be handled as specified
in the tables below.
If NMI is unused, it should be pulled-high externally through a 10k-ohm resistor to supply DVDD3318_B.

Table 3-28. Unused USB0 Signal Configurations


SIGNAL NAME Configuration
USB0_DM No Connect
USB0_DP No Connect
USB0_ID No Connect
USB0_VBUS No Connect
USB0_DRVVBUS No Connect
USB0_VDDA33 No Connect
USB0_VDDA18 No Connect
USB0_VDDA12 Internal USB PHY output connected to an external 0.22-μF filter capacitor
USB_REFCLKIN No Connect or other peripheral function
USB_CVDD 1.2V

Table 3-29. Unused RTC Signal Configuration


SIGNAL NAME Configuration
RTC_XI May be held high (CVDD) or low
RTC_XO No Connect
RTC_ALARM May be used as GPIO or other peripheral function
RTC_CVDD Connect to CVDD
RTC_VSS VSS

Table 3-30. Unused DDR2/mDDR Controller Signal Configuration


(1)
SIGNAL NAME Configuration
DDR_D[15:0] No Connect
DDR_A[13:0] No Connect
DDR_CLKP No Connect
DDR_CLKN No Connect
DDR_CKE No Connect
DDR_WE No Connect
DDR_RAS No Connect
DDR_CAS No Connect
DDS_CS No Connect
DDR_DQM[1:0] No Connect
DDR_DQS[1:0] No Connect
DDR_BA[2:0] No Connect
DDR_DQGATE0 No Connect
DDR_DQGATE1 No Connect
DDR_ZP No Connect
DDR_VREF No Connect
DDR_DVDD18 No Connect
(1) The DDR2/mDDR input buffers are enabled by default on device power up and a maximum current draw of 25mA can result on the 1.8V
supply. To minimize power consumption, the DDR2/mDDR controller input receivers should be placed in power-down mode by setting
VTPIO[14] = 1.

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4 Device Configuration
4.1 Boot Modes
This device supports a variety of boot modes through an internal ARM ROM bootloader. This device does
not support dedicated hardware boot modes. The input states of the BOOT pins are sampled and latched
into the BOOTCFG register, which is part of the system configuration (SYSCFG) module, when device
reset is deasserted. Boot mode selection is determined by the values of the BOOT pins.
See Using the OMAP-L1x8 Bootloader Application Report (SPRAB41) for more details on the ROM Boot
Loader.
The following boot modes are supported:
• NAND Flash boot
– 8-bit NAND
– 16-bit NAND (supported on ROM revisions after d800k002 -- see the bootloader documents
mentioned above to determine the ROM revision)
• NOR Flash boot
– NOR Direct boot (8-bit or 16-bit)
– NOR Legacy boot (8-bit or 16-bit)
– NOR AIS boot (8-bit or 16-bit)
• HPI Boot
• I2C0/I2C1 Boot
– EEPROM (Master Mode)
– External Host (Slave Mode)
• SPI0/SPI1 Boot
– Serial Flash (Master Mode)
– SERIAL EEPROM (Master Mode)
– External Host (Slave Mode)
• UART0/UART1/UART2 Boot
– External Host
• MMC/SD0 Boot

4.2 SYSCFG Module


The following system level features of the chip are controlled by the SYSCFG peripheral:
• Readable Device, Die, and Chip Revision ID
• Control of Pin Multiplexing
• Priority of bus accesses different bus masters in the system
• Capture at power on reset the chip BOOT pin values and make them available to software
• Control of the DeepSleep power management function
• Enable and selection of the programmable pin pullups and pulldowns
• Special case settings for peripherals:
– Locking of PLL controller settings
– Default burst sizes for EDMA3 transfer controllers
– Selection of the source for the eCAP module input capture (including on chip sources)
– McASP AMUTEIN selection and clearing of AMUTE status for the McASP
– Control of the reference clock source and other side-band signals for both of the integrated USB
PHYs
– Clock source selection for EMIFA
– DDR2 Controller PHY settings

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• Selects the source of emulation suspend signal (from ARM) of peripherals supporting this function.
Many registers are accessible only by a host (ARM) when it is operating in its privileged mode. (ex. from
the kernel, but not from user space code).

Table 4-1. System Configuration (SYSCFG) Module Register Access


Register Address Register Name Register Description Register Access
0x01C1 4000 REVID Revision Identification Register —
0x01C14008 DIEIDR0 Device Identification Register 0 —
0x01C1400C DIEIDR1 Device Identification Register 1 —
0x01C14010 DIEIDR2 Device Identification Register 2 —
0x01C14014 DIEIDR3 Device Identification Register 3 —
0x01C1 4020 BOOTCFG Boot Configuration Register Privileged mode
0x01C1 4038 KICK0R Kick 0 Register Privileged mode
0x01C1 403C KICK1R Kick 1 Register Privileged mode
0x01C1 4040 HOST0CFG Host 0 Configuration Register —
0x01C1 4044 HOST1CFG Host 1 Configuration Register —
0x01C1 40E0 IRAWSTAT Interrupt Raw Status/Set Register Privileged mode
0x01C1 40E4 IENSTAT Interrupt Enable Status/Clear Register Privileged mode
0x01C1 40E8 IENSET Interrupt Enable Register Privileged mode
0x01C1 40EC IENCLR Interrupt Enable Clear Register Privileged mode
0x01C1 40F0 EOI End of Interrupt Register Privileged mode
0x01C1 40F4 FLTADDRR Fault Address Register Privileged mode
0x01C1 40F8 FLTSTAT Fault Status Register —
0x01C1 4110 MSTPRI0 Master Priority 0 Registers Privileged mode
0x01C1 4114 MSTPRI1 Master Priority 1 Registers Privileged mode
0x01C1 4118 MSTPRI2 Master Priority 2 Registers Privileged mode
0x01C1 4120 PINMUX0 Pin Multiplexing Control 0 Register Privileged mode
0x01C1 4124 PINMUX1 Pin Multiplexing Control 1 Register Privileged mode
0x01C1 4128 PINMUX2 Pin Multiplexing Control 2 Register Privileged mode
0x01C1 412C PINMUX3 Pin Multiplexing Control 3 Register Privileged mode
0x01C1 4130 PINMUX4 Pin Multiplexing Control 4 Register Privileged mode
0x01C1 4134 PINMUX5 Pin Multiplexing Control 5 Register Privileged mode
0x01C1 4138 PINMUX6 Pin Multiplexing Control 6 Register Privileged mode
0x01C1 413C PINMUX7 Pin Multiplexing Control 7 Register Privileged mode
0x01C1 4140 PINMUX8 Pin Multiplexing Control 8 Register Privileged mode
0x01C1 4144 PINMUX9 Pin Multiplexing Control 9 Register Privileged mode
0x01C1 4148 PINMUX10 Pin Multiplexing Control 10 Register Privileged mode
0x01C1 414C PINMUX11 Pin Multiplexing Control 11 Register Privileged mode
0x01C1 4150 PINMUX12 Pin Multiplexing Control 12 Register Privileged mode
0x01C1 4154 PINMUX13 Pin Multiplexing Control 13 Register Privileged mode
0x01C1 4158 PINMUX14 Pin Multiplexing Control 14 Register Privileged mode
0x01C1 415C PINMUX15 Pin Multiplexing Control 15 Register Privileged mode
0x01C1 4160 PINMUX16 Pin Multiplexing Control 16 Register Privileged mode
0x01C1 4164 PINMUX17 Pin Multiplexing Control 17 Register Privileged mode
0x01C1 4168 PINMUX18 Pin Multiplexing Control 18 Register Privileged mode
0x01C1 416C PINMUX19 Pin Multiplexing Control 19 Register Privileged mode
0x01C1 4170 SUSPSRC Suspend Source Register Privileged mode
0x01C1 4174 Reserved —
0x01C1 4178 Reserved —

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Table 4-1. System Configuration (SYSCFG) Module Register Access (continued)


Register Address Register Name Register Description Register Access
0x01C1 417C CFGCHIP0 Chip Configuration 0 Register Privileged mode
0x01C1 4180 CFGCHIP1 Chip Configuration 1 Register Privileged mode
0x01C1 4184 CFGCHIP2 Chip Configuration 2 Register Privileged mode
0x01C1 4188 CFGCHIP3 Chip Configuration 3 Register Privileged mode
0x01C1 418C CFGCHIP4 Chip Configuration 4 Register Privileged mode
0x01E2 C000 VTPIO_CTL VTPIO COntrol Register Privileged mode
0x01E2 C004 DDR_SLEW DDR Slew Register Privileged mode
0x01E2 C008 DeepSleep DeepSleep Register Privileged mode
0x01E2 C00C PUPD_ENA Pullup / Pulldown Enable Register Privileged mode
0x01E2 C010 PUPD_SEL Pullup / Pulldown Selection Register Privileged mode
0x01E2 C014 RXACTIVE RXACTIVE Control Register Privileged mode
0x01E2 C018 PWRDN PWRDN Control Register Privileged mode

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4.3 Pullup/Pulldown Resistors


Proper board design should ensure that input pins to the device always be at a valid logic level and not
floating. This may be achieved via pullup/pulldown resistors. The device features internal pullup (IPU) and
internal pulldown (IPD) resistors on most pins to eliminate the need, unless otherwise noted, for external
pullup/pulldown resistors.
An external pullup/pulldown resistor needs to be used in the following situations:
• Boot and Configuration Pins: If the pin is both routed out and 3-stated (not driven), an external
pullup/pulldown resistor is strongly recommended, even if the IPU/IPD matches the desired value/state.
• Other Input Pins: If the IPU/IPD does not match the desired value/state, use an external
pullup/pulldown resistor to pull the signal to the opposite rail.
For the boot and configuration pins, if they are both routed out and 3-stated (not driven), it is strongly
recommended that an external pullup/pulldown resistor be implemented. Although, internal
pullup/pulldown resistors exist on these pins and they may match the desired configuration value,
providing external connectivity can help ensure that valid logic levels are latched on these device boot and
configuration pins. In addition, applying external pullup/pulldown resistors on the boot and configuration
pins adds convenience to the user in debugging and flexibility in switching operating modes.
Tips for choosing an external pullup/pulldown resistor:
• Consider the total amount of current that may pass through the pullup or pulldown resistor. Make sure
to include the leakage currents of all the devices connected to the net, as well as any internal pullup or
pulldown resistors.
• Decide a target value for the net. For a pulldown resistor, this should be below the lowest VIL level of
all inputs connected to the net. For a pullup resistor, this should be above the highest VIH level of all
inputs on the net. A reasonable choice would be to target the VOL or VOH levels for the logic family of
the limiting device; which, by definition, have margin to the VIL and VIH levels.
• Select a pullup/pulldown resistor with the largest possible value; but, which can still ensure that the net
will reach the target pulled value when maximum current from all devices on the net is flowing through
the resistor. The current to be considered includes leakage current plus, any other internal and
external pullup/pulldown resistors on the net.
• For bidirectional nets, there is an additional consideration which sets a lower limit on the resistance
value of the external resistor. Verify that the resistance is small enough that the weakest output buffer
can drive the net to the opposite logic level (including margin).
• Remember to include tolerances when selecting the resistor value.
• For pullup resistors, also remember to include tolerances on the IO supply rail.
• For most systems, a 1-kΩ resistor can be used to oppose the IPU/IPD while meeting the above
criteria. Users should confirm this resistor value is correct for their specific application.
• For most systems, a 20-kΩ resistor can be used to compliment the IPU/IPD on the boot and
configuration pins while meeting the above criteria. Users should confirm this resistor value is correct
for their specific application.
• For more detailed information on input current (II), and the low-/high-level input voltages (VIL and VIH)
for the device, see Section 5.3, Recommended Operating Conditions.
• For the internal pullup/pulldown resistors for all device pins, see the peripheral/system-specific terminal
functions table.

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5 Specifications

5.1 Absolute Maximum Ratings Over Operating Junction Temperature Range


(Unless Otherwise Noted) (1)
Core Logic, Variable and Fixed -0.5 V to 1.4 V
(CVDD, RVDD, RTC_CVDD, PLL0_VDDA , PLL1_VDDA ,
USB_CVDD ) (2)
Supply voltage ranges I/O, 1.8V -0.5 V to 2 V
(2)
(USB0_VDDA18, DDR_DVDD18)
I/O, 3.3V -0.5 V to 3.8V
(2)
(DVDD3318_A, DVDD3318_B, DVDD3318_C, USB0_VDDA33)
Oscillator inputs (OSCIN, RTC_XI), 1.2V -0.3 V to CVDD + 0.3V
Dual-voltage LVCMOS inputs, 3.3V or 1.8V (Steady State) -0.3V to DVDD + 0.3V
Dual-voltage LVCMOS inputs, operated as 3.3V DVDD + 20%
(Transient Overshoot/Undershoot) up to 20% of Signal
Period
Input voltage (VI) ranges Dual-voltage LVCMOS inputs, operated as 1.8V DVDD + 30%
(Transient Overshoot/Undershoot) up to 30% of Signal
Period
USB 5V Tolerant IOs: 5.25V (3)
(USB0_DM, USB0_DP, USB0_ID)
USB0 VBUS Pin 5.50V (3)
Dual-voltage LVCMOS outputs, 3.3V or 1.8V -0.3 V to DVDD + 0.3V
(Steady State)
Dual-voltage LVCMOS outputs, operated as 3.3V DVDD + 20%
(Transient Overshoot/Undershoot) up to 20% of Signal
Output voltage (VO) ranges
Period
Dual-voltage LVCMOS outputs, operated as 1.8V DVDD + 30%
(Transient Overshoot/Undershoot) up to 30% of Signal
Period
Input or Output Voltages 0.3V above or below their respective power ±20mA
Clamp Current rails. Limit clamp current that flows through the I/O's internal diode
protection cells.
Operating Junction Temperature ranges, Commercial (default) 0°C to 90°C
TJ
(1) Stresses beyond those listed under "absolute maximum ratings" may cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any other conditions beyond those indicated under "recommended operating
conditions" is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
(2) All voltage values are with respect to VSS, USB0_VSSA33, USB0_VSSA, PLL0_VSSA, OSCVSS, RTC_VSS
(3) Up to a maximum of 24 hours.

5.2 Handling Ratings


MIN MAX UNIT
Storage temperature range, Tstg (default) -55 150 °C
(2)
(1)
Human Body Model (HBM) >1 >1 kV
ESD Stress Voltage, VESD (3)
Charged Device Model (CDM) >500 >500 V
(1) Electrostatic discharge (ESD) to measure device sensitivity/immunity to damage caused by electrostatic discharges into the device.
(2) Level listed above is the passing level per ANSI/ESDA/JEDEC JS-001-2010. JEDEC document JEP 155 states that 500V HBM allows
safe manufacturing with a standard ESD control process, and manufacturing with less than 500V HBM is possible if necessary
precautions are taken. Pins listed as 1000V may actually have higher performance.
(3) Level listed above is the passing level per EIA-JEDEC JESD22-C101E. JEDEC document JEP 157 states that 250V CDM allows safe
manufacturing with a standard ESD control process. Pins listed as 250V may actually have higher performance.

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5.3 Recommended Operating Conditions


NAME DESCRIPTION CONDITION MIN NOM MAX UNIT
CVDD Core Logic Supply Voltage (variable) 1.3V operating point 1.25 1.3 1.35 V
1.2V operating point 1.14 1.2 1.32 V
1.1V operating point 1.05 1.1 1.16 V
1.0V operating point 0.95 1.0 1.05 V
456 MHz versions 1.25 1.3 1.35
RVDD Internal RAM Supply Voltage V
375 MHz versions 1.14 1.2 1.32
(1)
RTC_CVDD RTC Core Logic Supply Voltage 0.9 1.2 1.32 V
PLL0_VDDA PLL0 Supply Voltage 1.14 1.2 1.32 V
PLL1_VDDA PLL1 Supply Voltage 1.14 1.2 1.32 V
USB_CVDD USB0 Core Logic Supply Voltage 1.14 1.2 1.32 V
USB0_VDDA18 USB0 PHY Supply Voltage 1.71 1.8 1.89 V
USB0_VDDA33 USB0 PHY Supply Voltage 3.15 3.3 3.45 V
Supply
Voltage DVDD18 (2) 1.8V Logic Supply 1.71 1.8 1.89 V
DDR_DVDD18
(2) DDR2 PHY Supply Voltage 1.71 1.8 1.89 V

0.5*
0.49* 0.51*
DDR_VREF DDR2/mDDR reference voltage DDR_DVDD1 V
DDR_DVDD18 DDR_DVDD18
8
DDR2/mDDR impedance control,
DDR_ZP Vss V
connected via 50Ω resistor to Vss

Power Group A Dual-voltage IO 1.8V operating point 1.71 1.8 1.89 V


DVDD3318_A
Supply Voltage 3.3V operating point 3.15 3.3 3.45 V

Power Group B Dual-voltage IO 1.8V operating point 1.71 1.8 1.89 V


DVDD3318_B
Supply Voltage 3.3V operating point 3.15 3.3 3.45 V

Power Group C Dual-voltage IO 1.8V operating point 1.71 1.8 1.89 V


DVDD3318_C
Supply Voltage 3.3V operating point 3.15 3.3 3.45 V
Supply
VSS Core Logic Digital Ground V
Ground
PLL0_VSSA PLL0 Ground V
PLL1_VSSA PLL1 Ground V
OSCVSS (3) Oscillator Ground 0 0 0 V
RTC_VSS (3) RTC Oscillator Ground V
USB0_VSSA USB0 PHY Ground V
USB0_VSSA33 USB0 PHY Ground V
Voltage
VIH High-level input voltage, Dual-voltage I/O, 3.3V (4) 2 V
Input High
(4)
High-level input voltage, Dual-voltage I/O, 1.8V 0.65*DVDD V
High-level input voltage, RTC_XI 0.8*RTC_CVDD V
High-level input voltage, OSCIN 0.8*CVDD V

Voltage VIL Low-level input voltage, Dual-voltage I/O, 3.3V (4) 0.8 V
Input Low Low-level input voltage, Dual-voltage I/O, 1.8V (4)
0.35*DVDD V
Low-level input voltage, RTC_XI 0.2*RTC_CVDD V
Low-level input voltage, OSCIN 0.2*CVDD V
USB USB0_VBUS USB external charge pump input 0 5.25 V

(1) The RTC provides an option for isolating the RTC_CVDD from the CVDD to reduce current leakage when the RTC is powered
independently. If these power supplies are not isolated (CTRL.SPLITPOWER=0), RTC_CVDD must be equal to or greater than CVDD.
If these power supplies are isolated (CTRL.SPLITPOWER=1), RTC_CVDD may be lower than CVDD.
(2) DVDD18 must be powered even if all of the DVDD3318_x supplies are operated at 3.3V.
(3) When an external crystal is used oscillator (OSC_VSS, RTC_VSS) ground must be kept separate from other grounds and connected
directly to the crystal load capacitor ground. These pins are shorted to VSS on the device itself and should not be connected to VSS on
the circuit board. If a crystal is not used and the clock input is driven directly, then the oscillator VSS may be connected to board ground.
(4) These IO specifications apply to the dual-voltage IOs only and do not apply to the DDR2/mDDR . DDR2/mDDR IOs are 1.8V IOs and
adhere to the JESD79-2A standard.
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Recommended Operating Conditions (continued)


NAME DESCRIPTION CONDITION MIN NOM MAX UNIT
Transition Transition time, 10%-90%, All Inputs (unless otherwise (5)
tt 0.25P or 10 ns
Time specified in the electrical data sections)
CVDD = 1.3V
0 456
operating point
CVDD = 1.2V
0 375
Commercial temperature grade operating point
MHz
(default) CVDD = 1.1V
0 200
operating point
CVDD = 1.0V
0 100
Operating operating point
FPLL0_SYSCLK6
Frequency CVDD = 1.3V
0 456
operating point
CVDD = 1.2V
0 375
Extended temperature grade (A operating point
MHz
suffix) CVDD = 1.1V
0 200
operating point
CVDD = 1.0V
0 100
operating point

(5) Whichever is smaller. Where P = the period of the applied signal. Maintaining transition times as fast as possible is recommended to
improve noise immunity on input signals.

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5.4 Notes on Recommended Power-On Hours (POH)


The information in the section below is provided solely for your convenience and does not extend or
modify the warranty provided under TI’s standard terms and conditions for TI semiconductor products.
To avoid significant degradation, the device power-on hours (POH) must be limited to the following:

Table 5-1. Recommended Power-On Hours


Silicon Operating Junction Power-On Hours [POH]
Speed Grade Nominal CVDD Voltage (V)
Revision Temperature (Tj) (hours)
B/E 300 MHz 0 to 90 °C 1.2V 100,000
B/E 375 MHz 0 to 90 °C 1.2V 100,000
B/E 375 MHz -40 to 105 °C 1.2V 75,000 (1)
B/E 456 MHz 0 to 90 °C 1.3V 100,000
B/E 456 MHz -40 to 90 °C 1.3V 100,000
(1) 100,000 POH can be achieved at this temperature condition if the device operation is limited to 345 MHz

Note: Logic functions and parameter values are not assured out of the range specified in the recommended
operating conditions.
The above notations cannot be deemed a warranty or deemed to extend or modify the warranty under
TI’s standard terms and conditions for TI semiconductor products.

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5.5 Electrical Characteristics Over Recommended Ranges of Supply Voltage and


Operating Junction Temperature (Unless Otherwise Noted)
PARAMETER TEST CONDITIONS MIN TYP MAX UNIT

High-level output voltage DVDD= 3.15V, IOH = -4 mA 2.4 V


(dual-voltage LVCMOS IOs at 3.3V) (1) DVDD= 3.15V, IOH = -100 μA 2.95 V
VOH
High-level output voltage
DVDD= 1.71V, IOH = -2 mA DVDD-0.45 V
(dual-voltage LVCMOS IOs at 1.8V) (1)

Low-level output voltage DVDD= 3.15V, IOL = 4mA 0.4 V


(dual-voltage LVCMOS I/Os at 3.3V) DVDD= 3.15V, IOL = 100 μA 0.2 V
VOL
Low-level output voltage
DVDD= 1.71V, IOL = 2mA 0.45 V
(dual-voltage LVCMOS I/Os at 1.8V)
VI = VSS to DVDD without opposing
±9 μA
internal resistor
(1)
Input current VI = VSS to DVDD with opposing
70 310 μA
(2)
(dual-voltage LVCMOS I/Os) internal pullup resistor (3)
II
VI = VSS to DVDD with opposing
-75 -270 μA
internal pulldown resistor (3)
VI = VSS to DVDD with opposing
Input current (DDR2/mDDR I/Os) -77 -286 μA
internal pulldown resistor (3)
High-level output current (1)
IOH -6 mA
(dual-voltage LVCMOS I/Os)
Low-level output current (1)
IOL 6 mA
(dual-voltage LVCMOS I/Os)
Input capacitance (dual-voltage
3 pF
LVCMOS)
Capacitance
Output capacitance (dual-voltage
3 pF
LVCMOS)

(1) These IO specifications apply to the dual-voltage IOs only and do not apply to the DDR2/mDDR interface. DDR2/mDDR IOs are 1.8V
IOs and adhere to the JESD79-2A standard. USB0 I/Os adhere to the USB2.0 standard.
(2) II applies to input-only pins and bi-directional pins. For input-only pins, II indicates the input leakage current. For bi-directional pins, II
indicates the input leakage current and off-state (Hi-Z) output leakage current.
(3) Applies only to pins with an internal pullup (IPU) or pulldown (IPD) resistor. The pull-up and pull-down strengths shown represent the
minimum and maximum strength across process variation.

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6 Peripheral Information and Electrical Specifications


6.1 Parameter Information

6.1.1 Parameter Information Device-Specific Information

Tester Pin Electronics Data Sheet Timing Reference Point

42 Ω 3.5 nH Output
Transmission Line Under
Test
Z0 = 50 Ω
(see note) Device Pin
4.0 pF 1.85 pF (see note)

A. The data sheet provides timing at the device pin. For output timing analysis, the tester pin electronics and its
transmission line effects must be taken into account. A transmission line with a delay of 2 ns or longer can be used to
produce the desired transmission line effect. The transmission line is intended as a load only. It is not necessary to
add or subtract the transmission line delay (2 ns or longer) from the data sheet timings.
Input requirements in this data sheet are tested with an input slew rate of < 4 Volts per nanosecond (4 V/ns) at the
device pin and the input signals are driven between 0V and the appropriate IO supply rail for the signal.

Figure 6-1. Test Load Circuit for AC Timing Measurements

The load capacitance value stated is only for characterization and measurement of AC timing signals. This
load capacitance value does not indicate the maximum load the device is capable of driving.

6.1.1.1 Signal Transition Levels


All input and output timing parameters are referenced to Vref for both "0" and "1" logic levels.
For 3.3 V I/O, Vref = 1.65 V.
For 1.8 V I/O, Vref = 0.9 V.
For 1.2 V I/O, Vref = 0.6 V.

Vref

Figure 6-2. Input and Output Voltage Reference Levels for AC Timing Measurements

All rise and fall transition timing parameters are referenced to VIL MAX and VIH MIN for input clocks,
VOLMAX and VOH MIN for output clocks.

Vref = VIH MIN (or V OH MIN)

Vref = VIL MAX (or V OL MAX)

Figure 6-3. Rise and Fall Transition Time Voltage Reference Levels

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6.2 Recommended Clock and Control Signal Transition Behavior


All clocks and control signals must transition between VIH and VIL (or between VIL and VIH) in a monotonic
manner.

6.3 Power Supplies

6.3.1 Power-On Sequence


The device should be powered-on in the following order:
1. RTC (RTC_CVDD) may be powered from an external device (such as a battery) prior to all other
supplies being applied or powered-up at the same time as CVDD. If the RTC is not used, RTC_CVDD
should be connected to CVDD. RTC_CVDD should not be left unpowered while CVDD is powered.
2. Core logic supplies:
(a) All variable 1.2V - 1.0V core logic supplies (CVDD)
(b) All static core logic supplies (RVDD, PLL0_VDDA, PLL1_VDDA, USB_CVDD). If voltage scaling is
not used on the device, groups 2a) and 2b) can be controlled from the same power supply and
powered up together.
3. All static 1.8V IO supplies (DVDD18, DDR_DVDD18, USB0_VDDA18 ) and any of the LVCMOS IO
supply groups used at 1.8V nominal (DVDD3318_A, DVDD3318_B, or DVDD3318_C).
4. All analog 3.3V PHY supplies (USB0_VDDA33; this is not required if USB0 is not used) and any of the
LVCMOS IO supply groups used at 3.3V nominal (DVDD3318_A, DVDD3318_B, or DVDD3318_C).
There is no specific required voltage ramp rate for any of the supplies as long as the LVCMOS supplies
operated at 3.3V (DVDD3318_A, DVDD3318_B, or DVDD3318_C) never exceed the STATIC 1.8V
supplies by more than 2 volts.
RESET must be maintained active until all power supplies have reached their nominal values.

6.3.2 Power-Off Sequence


The power supplies can be powered-off in any order as long as LVCMOS supplies operated at 3.3V
(DVDD3318_A, DVDD3318_B, or DVDD3318_C) never exceed static 1.8V supplies by more than 2 volts.
There is no specific required voltage ramp down rate for any of the supplies (except as required to meet
the above mentioned voltage condition).

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6.4 Reset

6.4.1 Power-On Reset (POR)


A power-on reset (POR) is required to place the device in a known good state after power-up. Power-On
Reset is initiated by bringing RESET and TRST low at the same time. POR sets all of the device internal
logic to its default state. All pins are tri-stated with the exception of RESETOUT which remains active
through the reset sequence, and RTCK/GP8[0]. If an emulator is driving TCK into the device during reset,
then RTCK/GP8[0] will drive out RTCK. If TCK is not being driven into the device during reset, then
RTCK/GP8[0] will drive low. RESETOUT in an output for use by other controllers in the system that
indicates the device is currently in reset.
While both TRST and RESET need to be asserted upon power up, only RESET needs to be released for
the device to boot properly. TRST may be asserted indefinitely for normal operation, keeping the JTAG
port interface and device's emulation logic in the reset state.
TRST only needs to be released when it is necessary to use a JTAG controller to debug the device or
exercise the device's boundary scan functionality. Note: TRST is synchronous and must be clocked by
TCK; otherwise, the boundary scan logic may not respond as expected after TRST is asserted.
RESET must be released only in order for boundary-scan JTAG to read the variant field of IDCODE
correctly. Other boundary-scan instructions work correctly independent of current state of RESET. For
maximum reliability, the device includes an internal pulldown on the TRST pin to ensure that TRST will
always be asserted upon power up and the device's internal emulation logic will always be properly
initialized.
JTAG controllers from Texas Instruments actively drive TRST high. However, some third-party JTAG
controllers may not drive TRST high but expect the use of a pullup resistor on TRST. When using this type
of JTAG controller, assert TRST to intialize the device after powerup and externally drive TRST high
before attempting any emulation or boundary scan operations.
RTCK/GP8[0] is maintained active through a POR.
A summary of the effects of Power-On Reset is given below:
• All internal logic (including emulation logic and the PLL logic) is reset to its default state
• Internal memory is not maintained through a POR
• RESETOUT goes active
• All device pins go to a high-impedance state
• The RTC peripheral is not reset during a POR. A software sequence is required to reset the RTC
CAUTION: A watchdog reset triggers a POR.

6.4.2 Warm Reset


A warm reset provides a limited reset to the device. Warm Reset is initiated by bringing only RESET low
(TRST is maintained high through a warm reset). Warm reset sets certain portions of the device to their
default state while leaving others unaltered. All pins are tri-stated with the exception of RESETOUT which
remains active through the reset sequence, and RTCK/GP8[0]. If an emulator is driving TCK into the
device during reset, then RTCK/GP8[0] will drive out RTCK. If TCK is not being driven into the device
during reset, then RTCK/GP8[0] will drive low. RESETOUT is an output for use by other controllers in the
system that indicates the device is currently in reset.
During an emulation, the emulator will maintain TRST high and hence only warm reset (not POR) is
available during emulation debug and development.
RTCK/GP8[0] is maintained active through a warm reset.
A summary of the effects of Warm Reset is given below:
• All internal logic (except for the emulation logic and the PLL logic) is reset to its default state

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• Internal memory is maintained through a warm reset


• RESETOUT goes active
• All device pins go to a high-impedance state
• The RTC peripheral is not reset during a warm reset. A software sequence is required to reset the
RTC

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6.4.3 Reset Electrical Data Timings


Table 6-1 assumes testing over the recommended operating conditions.

Table 6-1. Reset Timing Requirements ( (1), (2)


)
1.3V, 1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX
1 tw(RSTL) Pulse width, RESET/TRST low 100 100 100 ns
2 tsu(BPV-RSTH) Setup time, boot pins valid before RESET/TRST high 20 20 20 ns
3 th(RSTH-BPV) Hold time, boot pins valid after RESET/TRST high 20 20 20 ns
td(RSTH- RESET high to RESETOUT high; Warm reset 4096 4096 4096 cycles (3)
4 RESETOUTH) RESET high to RESETOUT high; Power-on Reset 6169 6169 6169
td(RSTL- Delay time, RESET/TRST low to RESETOUT low ns
5 14 16 20
RESETOUTL)

(1) RESETOUT is multiplexed with other pin functions. See the Terminal Functions table, Table 3-3 for details.
(2) For power-on reset (POR), the reset timings in this table refer to RESET and TRST together. For warm reset, the reset timings in this
table refer to RESET only (TRST is held high).
(3) OSCIN cycles.

Power
Supplies Power Supplies Stable
Ramping
Clock Source Stable

OSCIN

1
RESET

TRST
4
RESETOUT

2 3

Boot Pins Config

Figure 6-4. Power-On Reset (RESET and TRST active) Timing

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Power Supplies Stable

OSCIN

TRST

RESET

5
4
RESETOUT

3
2
Boot Pins Driven or Hi-Z Config

Figure 6-5. Warm Reset (RESET active, TRST high) Timing

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6.5 Crystal Oscillator or External Clock Input


The device includes two choices to provide an external clock input, which is fed to the on-chip PLLs to
generate high-frequency system clocks. These options are illustrated in Figure 6-6 and Figure 6-7. For
input clock frequencies between 12 and 20 MHz, a crystal with 80 ohm max ESR is recommended. For
input clock frequencies between 20 and 30 MHz, a crystal with 60 ohm max ESR is recommended.
Typical load capacitance values are 10-20 pF, where the load capacitance is the series combination of C1
and C2.
The CLKMODE bit in the PLLCTL register must be 0 to use the on-chip oscillator. If CLKMODE is set to 1,
the internal oscillator is disabled.
Figure 6-6 illustrates the option that uses on-chip 1.2V oscillator with external crystal circuit. Figure 6-7
illustrates the option that uses an external 1.2V clock input.

C2
OSCIN Clock Input
to PLL

X1

OSCOUT

C1

OSCVSS

Figure 6-6. On-Chip Oscillator

Table 6-2. Oscillator Timing Requirements


MIN MAX UNIT
fosc Oscillator frequency range (OSCIN/OSCOUT) 12 30 MHz

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OSCIN Clock
Input
to PLL

OSCOUT
NC

OSCVSS

Figure 6-7. External 1.2V Clock Source

Table 6-3. OSCIN Timing Requirements for an Externally Driven Clock


MIN MAX UNIT
fOSCIN OSCIN frequency range 12 50 MHz
tc(OSCIN) Cycle time, external clock driven on OSCIN 20 ns
tw(OSCINH) Pulse width high, external clock on OSCIN 0.4 tc(OSCIN) ns
tw(OSCINL) Pulse width low, external clock on OSCIN 0.4 tc(OSCIN) ns
(1)
tt(OSCIN) Transition time, OSCIN 0.25P or 10 ns
tj(OSCIN) Period jitter, OSCIN 0.02P ns
(1) Whichever is smaller. P = the period of the applied signal. Maintaining transition times as fast as possible is recommended to improve
noise immunity on input signals.

6.6 Clock PLLs


The device has two PLL controllers that provide clocks to different parts of the system. PLL0 provides
clocks (though various dividers) to most of the components of the device. PLL1 provides clocks to the
mDDR/DDR2 Controller and provides an alternate clock source for the ASYNC3 clock domain. This allows
the peripherals on the ASYNC3 clock domain to be immune to frequency scaling operation on PLL0.
The PLL controller provides the following:
• Glitch-Free Transitions (on changing clock settings)
• Domain Clocks Alignment
• Clock Gating
• PLL power down
The various clock outputs given by the controller are as follows:
• Domain Clocks: SYSCLK [1:n]
• Auxiliary Clock from reference clock source: AUXCLK
Various dividers that can be used are as follows:
• Post-PLL Divider: POSTDIV
• SYSCLK Divider: D1, ¼, Dn
Various other controls supported are as follows:
• PLL Multiplier Control: PLLM
• Software programmable PLL Bypass: PLLEN

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6.6.1 PLL Device-Specific Information


The PLL requires some external filtering components to reduce power supply noise as shown in Figure 6-
8.

1.14V - 1.32V 50R PLL0_VDDA

0.1 0.01
µF µF

VSS 50R PLL0_VSSA

1.14V - 1.32V 50R PLL1_VDDA

0.1 0.01
µF µF

VSS 50R PLL1_VSSA

Ferrite Bead: Murata BLM31PG500SN1L or Equivalent

Figure 6-8. PLL External Filtering Components

The external filtering components shown above provide noise immunity for the PLLs. PLL0_VDDA and
PLL1_VDDA should not be connected together to provide noise immunity between the two PLLs.
Likewise, PLL0_VSSA and PLL1_VSSA should not be connected together.
The input to the PLL is either from the on-chip oscillator or from an external clock on the OSCIN pin. PLL0
outputs seven clocks that have programmable divider options. PLL1 outputs three clocks that have
programmable divider options. Figure 6-9 illustrates the high-level view of the PLL Topology.
The PLLs are disabled by default after a device reset. They must be configured by software according to
the allowable operating conditions listed in Table 6-4 before enabling the device to run from the PLL by
setting PLLEN = 1.

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PLL Controller 0
PLLCTL[EXTCLKSRC]

PLL1_SYSCLK3 1
PLLCTL[CLKMODE]
PLLCTL[PLLEN]
0
0 PLLDIV1 (/1) SYSCLK1
Square
1
Wave PLLDIV2 (/2)
OSCIN PREDIV PLL POSTDIV 1 SYSCLK2
Crystal 0 PLLDIV4 (/4) SYSCLK4
PLLM PLLDIV5 (/3)
DEEPSLEEP SYSCLK5
Enable
PLLDIV6 (/1) SYSCLK6
PLLDIV7 (/6) SYSCLK7
PLLDIV3 (/3) SYSCLK3

0 EMIFA
Internal
Clock
DIV4.5 1 Source

CFGCHIP3[EMA_CLKSRC]
AUXCLK

14h DIV4.5
OSCDIV PLLC0 OBSCLK
SYSCLK1 17h (CLKOUT Pin)
SYSCLK2 18h
SYSCLK3 19h
SYSCLK4 1Ah
SYSCLK5 1Bh
SYSCLK6 1Ch
SYSCLK7 1Dh
PLLC1 OBSCLK 1Eh

OCSEL[OCSRC]

PLLCTL[PLLEN] PLL Controller 1


0 PLLDIV2 (/2) SYSCLK2

PLLDIV3 (/3) SYSCLK3


PLL POSTDIV 1
PLLDIV1 (/1) SYSCLK1
PLLM
DDR2/mDDR
Internal
Clock
Source

14h
SYSCLK1 17h
OSCDIV PLLC1 OBSCLK
SYSCLK2 18h
SYSCLK3 19h

OCSEL[OCSRC]

Figure 6-9. PLL Topology

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Table 6-4. Allowed PLL Operating Conditions (PLL0 and PLL1)


NO Default
PARAMETER MIN MAX UNIT
. Value
1 PLLRST: Assertion time during initialization N/A 1000 N/A ns
2000 N
Max PLL Lock Time =
Lock time: The time that the application has to wait for m OSCIN
2 the PLL to acquire lock before setting PLLEN, after N/A N/A where N = Pre-Divider Ratio cycles
changing PREDIV, PLLM, or OSCIN
M = PLL Multiplier

3 PREDIV: Pre-divider value /1 /1 /32


30 (if internal oscillator is used)
4 PLLREF: PLL input frequency 12 MHz
50 (if external clock source is used)
5 PLLM: PLL multiplier values (1) x20 x4 x32
6 PLLOUT: PLL output frequency N/A 300 600 MHz
7 POSTDIV: Post-divider value /1 /1 /32
(1) The multiplier values must be chosen such that the PLL output frequency (at PLLOUT) is between 300 and 600 MHz, but the frequency
going into the SYSCLK dividers (after the post divider) cannot exceed the maximum clock frequency defined for the device at a given
voltage operating point.

6.6.2 Device Clock Generation


PLL0 is controlled by PLL Controller 0 and PLL1 is controlled by PLL Controller 1. PLLC0 and PLLC1
manage the clock ratios, alignment, and gating for the system clocks to the chip. The PLLCs are
responsible for controlling all modes of the PLL through software, in terms of pre-division of the clock
inputs (PLLC0 only), multiply factors within the PLLs, and post-division for each of the chip-level clocks
from the PLLs outputs. PLLC0 also controls reset propagation through the chip, clock alignment, and test
points.
PLLC0 provides clocks for the majority of the system but PLLC1 provides clocks to the mDDR/DDR2
Controller and the ASYNC3 clock domain to provide frequency scaling immunity to a defined set or
peripherals. The ASYNC3 clock domain can either derive its clock from PLL1_SYSCLK2 (for frequency
scaling immunity from PLL0) or from PLL0_SYSCLK2 (for synchronous timing with PLL0) depending on
the application requirements. In addition, some peripherals have specific clock options independent of the
ASYNC clock domain.

6.6.3 Dynamic Voltage and Frequency Scaling (DVFS)


The processor supports multiple operating points by scaling voltage and frequency to minimize power
consumption for a given level of processor performance.
Frequency scaling is achieved by modifying the setting of the PLL controllers’ multipliers, post-dividers
(POSTDIV), and system clock dividers (SYSCLKn). Modification of the POSTDIV and SYSCLK values
does not require relocking the PLL and provides lower latency to switch between operating points, but at
the expense of the frequencies being limited by the integer divide values (only the divide values are
altered the PLL multiplier is left unmodified). Non integer divide frequency values can be achieved by
changing both the multiplier and the divide values, but when the PLL multiplier is changed the PLL must
relock, incurring additional latency to change between operating points. Detailed information on modifying
the PLL Controller settings can be found in SPRUGU4 - AM1806 ARM Microprocessor System Reference
Guide.
Voltage scaling is enabled from outside the device by controlling an external voltage regulator. The
processor may communicate with the regulator using GPIOs, I2C or some other interface. When switching
between voltage-frequency operating points, the voltage must always support the desired frequency.
When moving from a high-performance operating point to a lower performance operating point, the
frequency should be lowered first followed by the voltage. When moving from a low-performance operating
point to a higher performance operating point, the voltage should be raised first followed by the frequency.
Voltage operating points refer to the CVdd voltage at that point. Other static supplies must be maintained
at their nominal voltages at all operating points.

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The maximum voltage slew rate for CVdd supply changes is 1 mV/us.
For additional information on power management solutions from TI for this processor, follow the Power
Management link in the Product Folder on www.ti.com for this processor.
The processor supports multiple clock domains some of which have clock ratio requirements to each
other. PLL0_SYSCLK2:PLL0_SYSCLK4:PLL0_SYSCLK6 are synchronous to each other and the
SYSCLKn dividers must always be configured such that the ratio between these domains is 2:4:1. The
ASYNC and ASYNC3 clock domains are asynchronous to the other clock domains and have no specific
ratio requirement.
The table below summarizes the maximum internal clock frequencies at each of the voltage operating
points.

Table 6-5. Maximum Internal Clock Frequencies at Each Voltage Operating Point
CLOCK SOURCE CLOCK DOMAIN 1.3V NOM 1.2V NOM 1.1V NOM 1.0V NOM
PLL0_SYSCLK1 Not used on this processor - - - -
SYSCLK2 clock domain peripherals and optional clock source
PLL0_SYSCLK2 228 MHz 187.5 MHz 100 MHz 50 MHz
for ASYNC3 clock domain peripherals
PLL0_SYSCLK3 Optional clock for ASYNC1 clock domain
PLL0_SYSCLK4 SYSCLK4 domain peripherals 114 MHz 93.75 MHz 50 MHz 25 MHz
PLL0_SYSCLK5 Not used on this processor - - - -
PLL0_SYSCLK6 ARM subsystem 456 MHz 375 MHz 200 MHz 100 MHz
PLL0_SYSCLK7 Not used on this processor - - - -
DDR2/mDDR Interface clock source (memory interface clock
PLL1_SYSCLK1 312 MHz 312 MHz 300 MHz 266 MHz
is one-half of the value shown)
PLL1_SYSCLK2 Optional clock source for ASYNC3 clock domain peripherals 152 MHz 150 MHz 100 MHz 75 MHz
PLL1_SYSCLK3 Alternate clock source input to PLL Controller 0 75 MHz 75 MHz 75 MHz 75 MHz
McASP AUXCLK Bypass clock source for the McASP 50 MHz 50 MHz 50 MHz 50 MHz
PLL0_AUXCLK Bypass clock source for the USB0 48 MHz 48 MHz 48 MHz 48 MHz
Async Mode 148 MHz 148 MHz 75 MHz 50 MHz
ASYNC1 ASYNC1 Clock Domain (EMIFA)
SDRAM Mode 100 MHz 100 MHz 66.6 MHz 50 MHz
ASYNC2 ASYNC2 Clock Domain (multiple peripherals) 50 MHz 50 MHz 50 MHz 50 MHz

Some interfaces have specific limitations on supported modes/speeds at each operating point. See the
corresponding peripheral sections of this document for more information.
TI provides software components (called the Power Manager) to perform DVFS and abstract the task from
the user. The Power Manager controls changing operating points (both frequency and voltage) and
handles the related tasks involved such as informing/controlling peripherals to provide graceful transitions
between operating points.

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6.7 Interrupts

6.7.1 ARM CPU Interrupts


The ARM9 CPU core supports 2 direct interrupts: FIQ and IRQ. The ARM Interrupt Controller (AINTC)
extends the number of interrupts to 100, and provides features like programmable masking, priority,
hardware nesting support, and interrupt vector generation.

6.7.1.1 ARM Interrupt Controller (AINTC) Interrupt Signal Hierarchy


The ARM Interrupt controller organizes interrupts into the following hierarchy:
• Peripheral Interrupt Requests
– Individual Interrupt Sources from Peripherals
• 101 System Interrupts
– One or more Peripheral Interrupt Requests are combined (fixed configuration) to generate a
System Interrupt.
– After prioritization, the AINTC will provide an interrupt vector based unique to each System Interrupt
• 32 Interrupt Channels
– Each System Interrupt is mapped to one of the 32 Interrupt Channels
– Channel Number determines the first level of prioritization, Channel 0 is highest priority and 31
lowest.
– If more than one system interrupt is mapped to a channel, priority within the channel is determined
by system interrupt number (0 highest priority)
• Host Interrupts (FIQ and IRQ)
– Interrupt Channels 0 and 1 generate the ARM FIQ interrupt
– Interrupt Channels 2 through 31 Generate the ARM IRQ interrupt
• Debug Interrupts
– Two Debug Interrupts are supported and can be used to trigger events in the debug subsystem
– Sources can be selected from any of the System Interrupts or Host Interrupts

6.7.1.2 AINTC Hardware Vector Generation


The AINTC also generates an interrupt vector in hardware for both IRQ and FIQ host interrupts. This may
be used to accelerate interrupt dispatch. A unique vector is generated for each of the 100 system
interrupts. The vector is computed in hardware as:
VECTOR = BASE + (SYSTEM INTERRUPT NUMBER × SIZE)
Where BASE and SIZE are programmable. The computed vector is a 32-bit address which may
dispatched to using a single instruction of type LDR PC, [PC, #-<offset_12>] at the FIQ and IRQ vector
locations (0xFFFF0018 and 0xFFFF001C respectively).

6.7.1.3 AINTC Hardware Interrupt Nesting Support


Interrupt nesting occurs when an interrupt service routine re-enables interrupts, to allow the CPU to
interrupt the ISR if a higher priority event occurs. The AINTC provides hardware support to facilitate
interrupt nesting. It supports both global and per host interrupt (FIQ and IRQ in this case) automatic
nesting. If enabled, the AINTC will automatically update an internal nesting register that temporarily masks
interrupts at and below the priority of the current interrupt channel. Then if the ISR re-enables interrupts;
only higher priority channels will be able to interrupt it. The nesting level is restored by the ISR by writing
to the nesting level register on completion. Support for nesting can be enabled/disabled by software, with
the option of automatic nesting on a global or per host interrupt basis; or manual nesting.

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6.7.1.4 AINTC System Interrupt Assignments

Table 6-6. AINTC System Interrupt Assignments


System Interrupt Interrupt Name Source
0 COMMTX ARM
1 COMMRX ARM
2 NINT ARM
3 PRU_EVTOUT0 PRUSS Interrupt
4 PRU_EVTOUT1 PRUSS Interrupt
5 PRU_EVTOUT2 PRUSS Interrupt
6 PRU_EVTOUT3 PRUSS Interrupt
7 PRU_EVTOUT4 PRUSS Interrupt
8 PRU_EVTOUT5 PRUSS Interrupt
9 PRU_EVTOUT6 PRUSS Interrupt
10 PRU_EVTOUT7 PRUSS Interrupt
11 EDMA3_0_CC0_INT0 EDMA3_0 Channel Controller 0 Shadow Region 0 Transfer
Completion Interrupt
12 EDMA3_0_CC0_ERRINT EDMA3_0 Channel Controller 0 Error Interrupt
13 EDMA3_0_TC0_ERRINT EDMA3_0 Transfer Controller 0 Error Interrupt
14 EMIFA_INT EMIFA
15 IIC0_INT I2C0
16 MMCSD0_INT0 MMCSD0 MMC/SD Interrupt
17 MMCSD0_INT1 MMCSD0 SDIO Interrupt
18 PSC0_ALLINT PSC0
19 RTC_IRQS[1:0] RTC
20 SPI0_INT SPI0
21 T64P0_TINT12 Timer64P0 Interrupt 12
22 T64P0_TINT34 Timer64P0 Interrupt 34
23 T64P1_TINT12 Timer64P1 Interrupt 12
24 T64P1_TINT34 Timer64P1 Interrupt 34
25 UART0_INT UART0
26 - Reserved
27 MPU_BOOTCFG_ERR Shared MPU and SYSCFG Address/Protection Error Interrupt
28-31 - Reserved
32 EDMA3_0_TC1_ERRINT EDMA3_0 Transfer Controller 1 Error Interrupt
33-40 - Reserved
41 DDR2_MEMERR DDR2 Controller
42 GPIO_B0INT GPIO Bank 0 Interrupt
43 GPIO_B1INT GPIO Bank 1 Interrupt
44 GPIO_B2INT GPIO Bank 2 Interrupt
45 GPIO_B3INT GPIO Bank 3 Interrupt
46 GPIO_B4INT GPIO Bank 4 Interrupt
47 GPIO_B5INT GPIO Bank 5 Interrupt
48 GPIO_B6INT GPIO Bank 6 Interrupt
49 GPIO_B7INT GPIO Bank 7 Interrupt
50 GPIO_B8INT GPIO Bank 8 Interrupt
51 IIC1_INT I2C1
52 LCDC_INT LCD Controller
53 UART_INT1 UART1
54 MCASP_INT McASP0 Combined RX / TX Interrupts

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Table 6-6. AINTC System Interrupt Assignments (continued)


System Interrupt Interrupt Name Source
55 PSC1_ALLINT PSC1
56 SPI1_INT SPI1
57 UHPI_ARMINT UHPI ARM Interrupt
58 USB0_INT USB0 Interrupt
59-60 - Reserved
61 UART2_INT UART2
62 - Reserved
63 EHRPWM0 HiResTimer / PWM0 Interrupt
64 EHRPWM0TZ HiResTimer / PWM0 Trip Zone Interrupt
65 EHRPWM1 HiResTimer / PWM1 Interrupt
66 EHRPWM1TZ HiResTimer / PWM1 Trip Zone Interrupt
67 - Reserved
68 T64P2_ALL Timer64P2 - Combined TINT12 and TINT34
69 ECAP0 ECAP0
70 ECAP1 ECAP1
71 ECAP2 ECAP2
72 MMCSD1_INT0 MMCSD1 MMC/SD Interrupt
73 MMCSD1_INT1 MMCSD1 SDIO Interrupt
74 T64P2_CMPINT0 Timer64P2 - Compare 0
75 T64P2_CMPINT1 Timer64P2 - Compare 1
76 T64P2_CMPINT2 Timer64P2 - Compare 2
77 T64P2_CMPINT3 Timer64P2 - Compare 3
78 T64P2_CMPINT4 Timer64P2 - Compare 4
79 T64P2_CMPINT5 Timer64P2 - Compare 5
80 T64P2_CMPINT6 Timer64P2 - Compare 6
81 T64P2_CMPINT7 Timer64P2 - Compare 7
82 T64P3_CMPINT0 Timer64P3 - Compare 0
83 T64P3_CMPINT1 Timer64P3 - Compare 1
84 T64P3_CMPINT2 Timer64P3 - Compare 2
85 T64P3_CMPINT3 Timer64P3 - Compare 3
86 T64P3_CMPINT4 Timer64P3 - Compare 4
87 T64P3_CMPINT5 Timer64P3 - Compare 5
88 T64P3_CMPINT6 Timer64P3 - Compare 6
89 T64P3_CMPINT7 Timer64P3 - Compare 7
90 ARMCLKSTOPREQ PSC0
91 uPP_ALLINT uPP Combined Interrupt
• Channel I End-of-Line Interrupt
• Channel I End-of-Window Interrupt
• Channel I DMA Access Interrupt
• Channel I Overflow-Underrun Interrupt
• Channel I DMA Programming Error Interrupt
• Channel Q End-of-Line Interrupt
• Channel Q End-of-Window Interrupt
• Channel Q DMA Access Interrupt
• Channel Q Overflow-Underrun Interrupt
• Channel Q DMA Programming Error Interrupt

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Table 6-6. AINTC System Interrupt Assignments (continued)


System Interrupt Interrupt Name Source
92 VPIF_ALLINT VPIF Combined Interrupt
• Channel 0 Frame Interrupt
• Channel 1 Frame Interrupt
• Channel 2 Frame Interrupt
• Channel 3 Frame Interrupt
• Error Interrupt
93 EDMA3_1_CC0_INT0 EDMA3_1 Channel Controller 0 Shadow Region 0 Transfer
Completion Interrupt
94 EDMA3_1_CC0_ERRINT EDMA3_1Channel Controller 0 Error Interrupt
95 EDMA3_1_TC0_ERRINT EDMA3_1 Transfer Controller 0 Error Interrupt
96 T64P3_ALL Timer64P 3 - Combined TINT12 and TINT34
97 MCBSP0_RINT McBSP0 Receive Interrupt
98 MCBSP0_XINT McBSP0 Transmit Interrupt
99 MCBSP1_RINT McBSP1 Receive Interrupt
100 MCBSP1_XINT McBSP1 Transmit Interrupt

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6.7.1.5 AINTC Memory Map

Table 6-7. AINTC Memory Map


BYTE ADDRESS ACRONYM DESCRIPTION
0xFFFE E000 REV Revision Register
0xFFFE E004 CR Control Register
0xFFFE E008 - 0xFFFE E00F - Reserved
0xFFFE E010 GER Global Enable Register
0xFFFE E014 - 0xFFFE E01B - Reserved
0xFFFE E01C GNLR Global Nesting Level Register
0xFFFE E020 SISR System Interrupt Status Indexed Set Register
0xFFFE E024 SICR System Interrupt Status Indexed Clear Register
0xFFFE E028 EISR System Interrupt Enable Indexed Set Register
0xFFFE E02C EICR System Interrupt Enable Indexed Clear Register
0xFFFE E030 - Reserved
0xFFFE E034 HIEISR Host Interrupt Enable Indexed Set Register
0xFFFE E038 HIDISR Host Interrupt Enable Indexed Clear Register
0xFFFE E03C - 0xFFFE E04F - Reserved
0xFFFE E050 VBR Vector Base Register
0xFFFE E054 VSR Vector Size Register
0xFFFE E058 VNR Vector Null Register
0xFFFE E05C - 0xFFFE E07F - Reserved
0xFFFE E080 GPIR Global Prioritized Index Register
0xFFFE E084 GPVR Global Prioritized Vector Register
0xFFFE E088 - 0xFFFE E1FF - Reserved
0xFFFE E200 SRSR[0] System Interrupt Status Raw / Set Registers
0xFFFE E204 SRSR[1]
0xFFFE E208 SRSR[2]
0xFFFE E20C SRSR[3]
0xFFFE E210- 0xFFFE E27F - Reserved
0xFFFE E280 SECR[0] System Interrupt Status Enabled / Clear Registers
0xFFFE E284 SECR[1]
0xFFFE E288 SECR[2]
0xFFFE E28C SECR[3]
0xFFFE E290 - 0xFFFE E2FF - Reserved
0xFFFE E300 ESR[0] System Interrupt Enable Set Registers
0xFFFE E304 ESR[1]
0xFFFE E308 ESR[2]
0xFFFE E30C ESR[3]
0xFFFE E310 - 0xFFFE E37F - Reserved
0xFFFE E380 ECR[0] System Interrupt Enable Clear Registers
0xFFFE E384 ECR[1]
0xFFFE E388 ECR[2]
0xFFFE E38C ECR[3]
0xFFFE E390 - 0xFFFE E3FF - Reserved

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Table 6-7. AINTC Memory Map (continued)


BYTE ADDRESS ACRONYM DESCRIPTION
0xFFFE E400 - 0xFFFE E45B CMR[0] Channel Map Registers
0xFFFE E404 CMR[1]
0xFFFE E408 CMR[2]
0xFFFE E40C CMR[3]
0xFFFE E410 CMR[4]
0xFFFE E414 CMR[5]
0xFFFE E418 CMR[6]
0xFFFE E41C CMR[7]
0xFFFE E420 CMR[8]
0xFFFE E424 CMR[9]
0xFFFE E428 CMR[10]
0xFFFE E42C CMR[11]
0xFFFE E430 CMR[12]
0xFFFE E434 CMR[13]
0xFFFE E438 CMR[14]
0xFFFE E43C CMR[15]
0xFFFE E440 CMR[16]
0xFFFE E444 CMR[17]
0xFFFE E448 CMR[18]
0xFFFE E44C CMR[19]
0xFFFE E450 CMR[20]
0xFFFE E454 CMR[21]
0xFFFE E458 CMR[22]
0xFFFE E45C CMR[23]
0xFFFE E460 CMR[24]
0xFFFE E464 CMR[25]
0xFFFE E468 - 0xFFFE E8FF - Reserved
0xFFFE E900 HIPIR[0] Host Interrupt Prioritized Index Registers
0xFFFE E904 HIPIR[1]
0xFFFE E908 - 0xFFFE EEFF - Reserved
0xFFFE EF00 DSR[0] Debug Select Registers
0xFFFE EF04 DSR[1]
0xFFFE EF08 - 0xFFFE F0FF - Reserved
0xFFFE F100 HINLR[0] Host Interrupt Nesting Level Registers
0xFFFE F104 HINLR[1]
0xFFFE F108 - 0xFFFE F4FF - Reserved
0xFFFE F500 HIER[0] Host Interrupt Enable Register
0xFFFE F504 - 0xFFFE F5FF - Reserved
0xFFFE F600 HIPVR[0] - Host Interrupt Prioritized Vector Registers
0xFFFE F604 HIPVR[1]
0xFFFE F608 - 0xFFFE FFFF - Reserved

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6.8 Power and Sleep Controller (PSC)


The Power and Sleep Controllers (PSC) are responsible for managing transitions of system power on/off,
clock on/off, resets (device level and module level). It is used primarily to provide granular power control
for on chip modules (peripherals and CPU). A PSC module consists of a Global PSC (GPSC) and a set of
Local PSCs (LPSCs). The GPSC contains memory mapped registers, PSC interrupts, a state machine for
each peripheral/module it controls. An LPSC is associated with every module that is controlled by the PSC
and provides clock and reset control.
The PSC includes the following features:
• Provides a software interface to:
– Control module clock enable/disable
– Control module reset
– Control CPU local reset
• Supports IcePick emulation features: power, clock and reset
PSC0 controls 16 local PSCs.
PSC1 controls 32 local PSCs.

Table 6-8. Power and Sleep Controller (PSC) Registers


PSC0 BYTE PSC1 BYTE
ACRONYM REGISTER DESCRIPTION
ADDRESS ADDRESS
0x01C1 0000 0x01E2 7000 REVID Peripheral Revision and Class Information Register
0x01C1 0018 0x01E2 7018 INTEVAL Interrupt Evaluation Register
0x01C1 0040 0x01E2 7040 MERRPR0 Module Error Pending Register 0 (module 0-15) (PSC0)
Module Error Pending Register 0 (module 0-31) (PSC1)
0x01C1 0050 0x01E2 7050 MERRCR0 Module Error Clear Register 0 (module 0-15) (PSC0)
Module Error Clear Register 0 (module 0-31) (PSC1)
0x01C1 0060 0x01E2 7060 PERRPR Power Error Pending Register
0x01C1 0068 0x01E2 7068 PERRCR Power Error Clear Register
0x01C1 0120 0x01E2 7120 PTCMD Power Domain Transition Command Register
0x01C1 0128 0x01E2 7128 PTSTAT Power Domain Transition Status Register
0x01C1 0200 0x01E2 7200 PDSTAT0 Power Domain 0 Status Register
0x01C1 0204 0x01E2 7204 PDSTAT1 Power Domain 1 Status Register
0x01C1 0300 0x01E2 7300 PDCTL0 Power Domain 0 Control Register
0x01C1 0304 0x01E2 7304 PDCTL1 Power Domain 1 Control Register
0x01C1 0400 0x01E2 7400 PDCFG0 Power Domain 0 Configuration Register
0x01C1 0404 0x01E2 7404 PDCFG1 Power Domain 1 Configuration Register
0x01C1 0800 0x01E2 7800 MDSTAT0 Module 0 Status Register
0x01C1 0804 0x01E2 7804 MDSTAT1 Module 1 Status Register
0x01C1 0808 0x01E2 7808 MDSTAT2 Module 2 Status Register
0x01C1 080C 0x01E2 780C MDSTAT3 Module 3 Status Register
0x01C1 0810 0x01E2 7810 MDSTAT4 Module 4 Status Register
0x01C1 0814 0x01E2 7814 MDSTAT5 Module 5 Status Register
0x01C1 0818 0x01E2 7818 MDSTAT6 Module 6 Status Register
0x01C1 081C 0x01E2 781C MDSTAT7 Module 7 Status Register
0x01C1 0820 0x01E2 7820 MDSTAT8 Module 8 Status Register
0x01C1 0824 0x01E2 7824 MDSTAT9 Module 9 Status Register
0x01C1 0828 0x01E2 7828 MDSTAT10 Module 10 Status Register
0x01C1 082C 0x01E2 782C MDSTAT11 Module 11 Status Register
0x01C1 0830 0x01E2 7830 MDSTAT12 Module 12 Status Register
0x01C1 0834 0x01E2 7834 MDSTAT13 Module 13 Status Register

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Table 6-8. Power and Sleep Controller (PSC) Registers (continued)


PSC0 BYTE PSC1 BYTE
ACRONYM REGISTER DESCRIPTION
ADDRESS ADDRESS
0x01C1 0838 0x01E2 7838 MDSTAT14 Module 14 Status Register
0x01C1 083C 0x01E2 783C MDSTAT15 Module 15 Status Register
- 0x01E2 7840 MDSTAT16 Module 16 Status Register
- 0x01E2 7844 MDSTAT17 Module 17 Status Register
- 0x01E2 7848 MDSTAT18 Module 18 Status Register
- 0x01E2 784C MDSTAT19 Module 19 Status Register
- 0x01E2 7850 MDSTAT20 Module 20 Status Register
- 0x01E2 7854 MDSTAT21 Module 21 Status Register
- 0x01E2 7858 MDSTAT22 Module 22 Status Register
- 0x01E2 785C MDSTAT23 Module 23 Status Register
- 0x01E2 7860 MDSTAT24 Module 24 Status Register
- 0x01E2 7864 MDSTAT25 Module 25 Status Register
- 0x01E2 7868 MDSTAT26 Module 26 Status Register
- 0x01E2 786C MDSTAT27 Module 27 Status Register
- 0x01E2 7870 MDSTAT28 Module 28 Status Register
- 0x01E2 7874 MDSTAT29 Module 29 Status Register
- 0x01E2 7878 MDSTAT30 Module 30 Status Register
- 0x01E2 787C MDSTAT31 Module 31 Status Register
0x01C1 0A00 0x01E2 7A00 MDCTL0 Module 0 Control Register
0x01C1 0A04 0x01E2 7A04 MDCTL1 Module 1 Control Register
0x01C1 0A08 0x01E2 7A08 MDCTL2 Module 2 Control Register
0x01C1 0A0C 0x01E2 7A0C MDCTL3 Module 3 Control Register
0x01C1 0A10 0x01E2 7A10 MDCTL4 Module 4 Control Register
0x01C1 0A14 0x01E2 7A14 MDCTL5 Module 5 Control Register
0x01C1 0A18 0x01E2 7A18 MDCTL6 Module 6 Control Register
0x01C1 0A1C 0x01E2 7A1C MDCTL7 Module 7 Control Register
0x01C1 0A20 0x01E2 7A20 MDCTL8 Module 8 Control Register
0x01C1 0A24 0x01E2 7A24 MDCTL9 Module 9 Control Register
0x01C1 0A28 0x01E2 7A28 MDCTL10 Module 10 Control Register
0x01C1 0A2C 0x01E2 7A2C MDCTL11 Module 11 Control Register
0x01C1 0A30 0x01E2 7A30 MDCTL12 Module 12 Control Register
0x01C1 0A34 0x01E2 7A34 MDCTL13 Module 13 Control Register
0x01C1 0A38 0x01E2 7A38 MDCTL14 Module 14 Control Register
0x01C1 0A3C 0x01E2 7A3C MDCTL15 Module 15 Control Register
- 0x01E2 7A40 MDCTL16 Module 16 Control Register
- 0x01E2 7A44 MDCTL17 Module 17 Control Register
- 0x01E2 7A48 MDCTL18 Module 18 Control Register
- 0x01E2 7A4C MDCTL19 Module 19 Control Register
- 0x01E2 7A50 MDCTL20 Module 20 Control Register
- 0x01E2 7A54 MDCTL21 Module 21 Control Register
- 0x01E2 7A58 MDCTL22 Module 22 Control Register
- 0x01E2 7A5C MDCTL23 Module 23 Control Register
- 0x01E2 7A60 MDCTL24 Module 24 Control Register
- 0x01E2 7A64 MDCTL25 Module 25 Control Register
- 0x01E2 7A68 MDCTL26 Module 26 Control Register
- 0x01E2 7A6C MDCTL27 Module 27 Control Register
- 0x01E2 7A70 MDCTL28 Module 28 Control Register

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Table 6-8. Power and Sleep Controller (PSC) Registers (continued)


PSC0 BYTE PSC1 BYTE
ACRONYM REGISTER DESCRIPTION
ADDRESS ADDRESS
- 0x01E2 7A74 MDCTL29 Module 29 Control Register
- 0x01E2 7A78 MDCTL30 Module 30 Control Register
- 0x01E2 7A7C MDCTL31 Module 31 Control Register

6.8.1 Power Domain and Module Topology


The device includes two PSC modules.
Each PSC module controls clock states for several of the on chip modules, controllers and interconnect
components. Table 6-9 and Table 6-10 lists the set of peripherals/modules that are controlled by the PSC,
the power domain they are associated with, the LPSC assignment and the default (power-on reset)
module states. See the device-specific data manual for the peripherals available on a given device. The
module states and terminology are defined in Section 6.8.1.1.

Table 6-9. PSC0 Default Module Configuration


LPSC Module Name Power Domain Default Module State Auto Sleep/Wake Only
Number
0 EDMA3 Channel Controller 0 AlwaysON (PD0) SwRstDisable —
1 EDMA3 Transfer Controller 0 AlwaysON (PD0) SwRstDisable —
2 EDMA3 Transfer Controller 1 AlwaysON (PD0) SwRstDisable —
3 EMIFA (Br7) AlwaysON (PD0) SwRstDisable —
4 SPI 0 AlwaysON (PD0) SwRstDisable —
5 MMC/SD 0 AlwaysON (PD0) SwRstDisable —
6 ARM Interrupt Controller AlwaysON (PD0) SwRstDisable —
7 ARM RAM/ROM AlwaysON (PD0) Enable Yes
8 — — — —
9 UART 0 AlwaysON (PD0) SwRstDisable —
10 SCR0 (Br 0, Br 1, Br 2, Br 8) AlwaysON (PD0) Enable Yes
11 SCR1 (Br 4) AlwaysON (PD0) Enable Yes
12 SCR2 (Br 3, Br 5, Br 6) AlwaysON (PD0) Enable Yes
13 PRUSS AlwaysON (PD0) SwRstDisable —
14 ARM AlwaysON (PD0) SwRstDisable —
15 — — — —

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Table 6-10. PSC1 Default Module Configuration


LPSC Module Name Power Domain Default Module State Auto Sleep/Wake Only
Number
0 EDMA3 Channel Controller 1 AlwaysON (PD0) SwRstDisable —
1 USB0 (USB2.0) AlwaysON (PD0) SwRstDisable —
2 — — — —
3 GPIO AlwaysON (PD0) SwRstDisable —
4 UHPI AlwaysON (PD0) SwRstDisable —
5 — — — —
6 DDR2 (and SCR_F3) AlwaysON (PD0) SwRstDisable —
7 McASP0 ( + McASP0 FIFO) AlwaysON (PD0) SwRstDisable —
8 — — — —
9 VPIF AlwaysON (PD0) SwRstDisable —
10 SPI 1 AlwaysON (PD0) SwRstDisable —
11 I2C 1 AlwaysON (PD0) SwRstDisable —
12 UART 1 AlwaysON (PD0) SwRstDisable —
13 UART 2 AlwaysON (PD0) SwRstDisable —
14 McBSP0 ( + McBSP0 FIFO) AlwaysON (PD0) SwRstDisable —
15 McBSP1 ( + McBSP1 FIFO) AlwaysON (PD0) SwRstDisable —
16 LCDC AlwaysON (PD0) SwRstDisable —
17 eHRPWM0/1 AlwaysON (PD0) SwRstDisable —
18 MMCSD1 AlwaysON (PD0) SwRstDisable —
19 uPP AlwaysON (PD0) SwRstDisable —
20 ECAP0/1/2 AlwaysON (PD0) SwRstDisable —
21 EDMA3 Transfer Controller 2 AlwaysON (PD0) SwRstDisable —
22-23 — — — —
24 SCR_F0 (and bridge F0) AlwaysON (PD0) Enable Yes
25 SCR_F1 (and bridge F1) AlwaysON (PD0) Enable Yes
26 SCR_F2 (and bridge F2) AlwaysON (PD0) Enable Yes
27 SCR_F6 (and bridge F3) AlwaysON (PD0) Enable Yes
28 SCR_F7 (and bridge F4) AlwaysON (PD0) Enable Yes
29 SCR_F8 (and bridge F5) AlwaysON (PD0) Enable Yes
30 Bridge F7 (DDR Controller AlwaysON (PD0) Enable Yes
path)
31 On-chip RAM (including PD_SHRAM Enable —
SCR_F4 and bridge F6)

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6.8.1.1 Module States


The PSC defines several possible states for a module. This states are essentially a combination of the
module reset asserted or de-asserted and module clock on/enabled or off/disabled. The module states are
defined in Table 6-11.

Table 6-11. Module States


Module State Module Reset Module Module State Definition
Clock
Enable De-asserted On A module in the enable state has its module reset de-asserted and it has its clock on.
This is the normal operational state for a given module
Disable De-asserted Off A module in the disabled state has its module reset de-asserted and it has its module
clock off. This state is typically used for disabling a module clock to save power. The
device is designed in full static CMOS, so when you stop a module clock, it retains the
module’s state. When the clock is restarted, the module resumes operating from the
stopping point.
SyncReset Asserted On A module state in the SyncReset state has its module reset asserted and it has its
clock on. Generally, software is not expected to initiate this state
SwRstDisable Asserted Off A module in the SwResetDisable state has its module reset asserted and it has its
clock disabled. After initial power-on, several modules come up in the SwRstDisable
state. Generally, software is not expected to initiate this state
Auto Sleep De-asserted Off A module in the Auto Sleep state also has its module reset de-asserted and its module
clock disabled, similar to the Disable state. However this is a special state, once a
module is configured in this state by software, it can “automatically” transition to
“Enable” state whenever there is an internal read/write request made to it, and after
servicing the request it will “automatically” transition into the sleep state (with module
reset re de-asserted and module clock disabled), without any software intervention.
The transition from sleep to enabled and back to sleep state has some cycle latency
associated with it. It is not envisioned to use this mode when peripherals are fully
operational and moving data.
Auto Wake De-asserted Off A module in the Auto Wake state also has its module reset de-asserted and its module
clock disabled, similar to the Disable state. However this is a special state, once a
module is configured in this state by software, it will “automatically” transition to
“Enable” state whenever there is an internal read/write request made to it, and will
remain in the “Enabled” state from then on (with module reset re de-asserted and
module clock on), without any software intervention. The transition from sleep to
enabled state has some cycle latency associated with it. It is not envisioned to use this
mode when peripherals are fully operational and moving data.

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6.9 EDMA
The EDMA controller handles all data transfers between memories and the device slave peripherals on
the device. These data transfers include cache servicing, non-cacheable memory accesses, user-
programmed data transfers, and host accesses.

6.9.1 EDMA3 Channel Synchronization Events


Each EDMA channel controller supports up to 32 channels which service peripherals and memory.
Table 6-12lists the source of the EDMA synchronization events associated with each of the programmable
EDMA channels.

Table 6-12. EDMA Synchronization Events


EDMA0 Channel Controller 0
Event Event Name / Source Event Event Name / Source
0 McASP0 Receive 16 MMCSD0 Receive
1 McASP0 Transmit 17 MMCSD0 Transmit
2 McBSP0 Receive 18 SPI1 Receive
3 McBSP0 Transmit 19 SPI1 Transmit
4 McBSP1 Receive 20 PRU_EVTOUT6
5 McBSP1 Transmit 21 PRU_EVTOUT7
6 GPIO Bank 0 Interrupt 22 GPIO Bank 2 Interrupt
7 GPIO Bank 1 Interrupt 23 GPIO Bank 3 Interrupt
8 UART0 Receive 24 I2C0 Receive
9 UART0 Transmit 25 I2C0 Transmit
10 Timer64P0 Event Out 12 26 I2C1 Receive
11 Timer64P0 Event Out 34 27 I2C1 Transmit
12 UART1 Receive 28 GPIO Bank 4 Interrupt
13 UART1 Transmit 29 GPIO Bank 5 Interrupt
14 SPI0 Receive 30 UART2 Receive
15 SPI0 Transmit 31 UART2 Transmit
EDMA1 Channel Controller 1
Event Event Name / Source Event Event Name / Source
0 Timer64P2 Compare Event 0 16 GPIO Bank 6 Interrupt
1 Timer64P2 Compare Event 1 17 GPIO Bank 7 Interrupt
2 Timer64P2 Compare Event 2 18 GPIO Bank 8 Interrupt
3 Timer64P2 Compare Event 3 19 Reserved
4 Timer64P2 Compare Event 4 20 Reserved
5 Timer64P2 Compare Event 5 21 Reserved
6 Timer64P2 Compare Event 6 22 Reserved
7 Timer64P2 Compare Event 7 23 Reserved
8 Timer64P3 Compare Event 0 24 Timer64P2 Event Out 12
9 Timer64P3 Compare Event 1 25 Timer64P2 Event Out 34
10 Timer64P3 Compare Event 2 26 Timer64P3 Event Out 12
11 Timer64P3 Compare Event 3 27 Timer64P3 Event Out 34
12 Timer64P3 Compare Event 4 28 MMCSD1 Receive
13 Timer64P3 Compare Event 5 29 MMCSD1 Transmit
14 Timer64P3 Compare Event 6 30 Reserved
15 Timer64P3 Compare Event 7 31 Reserved

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6.9.2 EDMA Peripheral Register Descriptions


Table 6-13 is the list of EDMA3 Channel Controller Registers and Table 6-14 is the list of EDMA3 Transfer
Controller registers.

Table 6-13. EDMA3 Channel Controller (EDMA3CC) Registers


EDMA0 Channel EDMA1 Channel ACRONYM REGISTER DESCRIPTION
Controller 0 Controller 0
BYTE ADDRESS BYTE ADDRESS
0x01C0 0000 0x01E3 0000 PID Peripheral Identification Register
0x01C0 0004 0x01E3 0004 CCCFG EDMA3CC Configuration Register
Global Registers
0x01C0 0200 0x01E3 0200 QCHMAP0 QDMA Channel 0 Mapping Register
0x01C0 0204 0x01E3 0204 QCHMAP1 QDMA Channel 1 Mapping Register
0x01C0 0208 0x01E3 0208 QCHMAP2 QDMA Channel 2 Mapping Register
0x01C0 020C 0x01E3 020C QCHMAP3 QDMA Channel 3 Mapping Register
0x01C0 0210 0x01E3 0210 QCHMAP4 QDMA Channel 4 Mapping Register
0x01C0 0214 0x01E3 0214 QCHMAP5 QDMA Channel 5 Mapping Register
0x01C0 0218 0x01E3 0218 QCHMAP6 QDMA Channel 6 Mapping Register
0x01C0 021C 0x01E3 021C QCHMAP7 QDMA Channel 7 Mapping Register
0x01C0 0240 0x01E3 0240 DMAQNUM0 DMA Channel Queue Number Register 0
0x01C0 0244 0x01E3 0244 DMAQNUM1 DMA Channel Queue Number Register 1
0x01C0 0248 0x01E3 0248 DMAQNUM2 DMA Channel Queue Number Register 2
0x01C0 024C 0x01E3 024C DMAQNUM3 DMA Channel Queue Number Register 3
0x01C0 0260 0x01E3 0260 QDMAQNUM QDMA Channel Queue Number Register
0x01C0 0284 0x01E3 0284 QUEPRI Queue Priority Register (1)
0x01C0 0300 0x01E3 0300 EMR Event Missed Register
0x01C0 0308 0x01E3 0308 EMCR Event Missed Clear Register
0x01C0 0310 0x01E3 0310 QEMR QDMA Event Missed Register
0x01C0 0314 0x01E3 0314 QEMCR QDMA Event Missed Clear Register
0x01C0 0318 0x01E3 0318 CCERR EDMA3CC Error Register
0x01C0 031C 0x01E3 031C CCERRCLR EDMA3CC Error Clear Register
0x01C0 0320 0x01E3 0320 EEVAL Error Evaluate Register
0x01C0 0340 0x01E3 0340 DRAE0 DMA Region Access Enable Register for Region 0
0x01C0 0348 0x01E3 0348 DRAE1 DMA Region Access Enable Register for Region 1
0x01C0 0350 0x01E3 0350 DRAE2 DMA Region Access Enable Register for Region 2
0x01C0 0358 0x01E3 0358 DRAE3 DMA Region Access Enable Register for Region 3
0x01C0 0380 0x01E3 0380 QRAE0 QDMA Region Access Enable Register for Region 0
0x01C0 0384 0x01E3 0384 QRAE1 QDMA Region Access Enable Register for Region 1
0x01C0 0388 0x01E3 0388 QRAE2 QDMA Region Access Enable Register for Region 2
0x01C0 038C 0x01E3 038C QRAE3 QDMA Region Access Enable Register for Region 3
0x01C0 0400 - 0x01E3 0400 - Q0E0-Q0E15 Event Queue Entry Registers Q0E0-Q0E15
0x01C0 043C 0x01E3 043C
0x01C0 0440 - 0x01E3 0440 - Q1E0-Q1E15 Event Queue Entry Registers Q1E0-Q1E15
0x01C0 047C 0x01E3 047C
0x01C0 0600 0x01E3 0600 QSTAT0 Queue 0 Status Register
0x01C0 0604 0x01E3 0604 QSTAT1 Queue 1 Status Register
0x01C0 0620 0x01E3 0620 QWMTHRA Queue Watermark Threshold A Register
0x01C0 0640 0x01E3 0640 CCSTAT EDMA3CC Status Register

(1) On previous architectures, the EDMA3TC priority was controlled by the queue priority register (QUEPRI) in the EDMA3CC memory-
map. However for this device, the priority control for the transfer controllers is controlled by the chip-level registers in the System
Configuration Module. You should use the chip-level registers and not QUEPRI to configure the TC priority.
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Table 6-13. EDMA3 Channel Controller (EDMA3CC) Registers (continued)


EDMA0 Channel EDMA1 Channel ACRONYM REGISTER DESCRIPTION
Controller 0 Controller 0
BYTE ADDRESS BYTE ADDRESS
Global Channel Registers
0x01C0 1000 0x01E3 1000 ER Event Register
0x01C0 1008 0x01E3 1008 ECR Event Clear Register
0x01C0 1010 0x01E3 1010 ESR Event Set Register
0x01C0 1018 0x01E3 1018 CER Chained Event Register
0x01C0 1020 0x01E3 1020 EER Event Enable Register
0x01C0 1028 0x01E3 1028 EECR Event Enable Clear Register
0x01C0 1030 0x01E3 1030 EESR Event Enable Set Register
0x01C0 1038 0x01E3 1038 SER Secondary Event Register
0x01C0 1040 0x01E3 1040 SECR Secondary Event Clear Register
0x01C0 1050 0x01E3 1050 IER Interrupt Enable Register
0x01C0 1058 0x01E3 1058 IECR Interrupt Enable Clear Register
0x01C0 1060 0x01E3 1060 IESR Interrupt Enable Set Register
0x01C0 1068 0x01E3 1068 IPR Interrupt Pending Register
0x01C0 1070 0x01E3 1070 ICR Interrupt Clear Register
0x01C0 1078 0x01E3 1078 IEVAL Interrupt Evaluate Register
0x01C0 1080 0x01E3 1080 QER QDMA Event Register
0x01C0 1084 0x01E3 1084 QEER QDMA Event Enable Register
0x01C0 1088 0x01E3 1088 QEECR QDMA Event Enable Clear Register
0x01C0 108C 0x01E3 108C QEESR QDMA Event Enable Set Register
0x01C0 1090 0x01E3 1090 QSER QDMA Secondary Event Register
0x01C0 1094 0x01E3 1094 QSECR QDMA Secondary Event Clear Register
Shadow Region 0 Channel Registers
0x01C0 2000 0x01E3 2000 ER Event Register
0x01C0 2008 0x01E3 2008 ECR Event Clear Register
0x01C0 2010 0x01E3 2010 ESR Event Set Register
0x01C0 2018 0x01E3 2018 CER Chained Event Register
0x01C0 2020 0x01E3 2020 EER Event Enable Register
0x01C0 2028 0x01E3 2028 EECR Event Enable Clear Register
0x01C0 2030 0x01E3 2030 EESR Event Enable Set Register
0x01C0 2038 0x01E3 2038 SER Secondary Event Register
0x01C0 2040 0x01E3 2040 SECR Secondary Event Clear Register
0x01C0 2050 0x01E3 2050 IER Interrupt Enable Register
0x01C0 2058 0x01E3 2058 IECR Interrupt Enable Clear Register
0x01C0 2060 0x01E3 2060 IESR Interrupt Enable Set Register
0x01C0 2068 0x01E3 2068 IPR Interrupt Pending Register
0x01C0 2070 0x01E3 2070 ICR Interrupt Clear Register
0x01C0 2078 0x01E3 2078 IEVAL Interrupt Evaluate Register
0x01C0 2080 0x01E3 2080 QER QDMA Event Register
0x01C0 2084 0x01E3 2084 QEER QDMA Event Enable Register
0x01C0 2088 0x01E3 2088 QEECR QDMA Event Enable Clear Register
0x01C0 208C 0x01E3 208C QEESR QDMA Event Enable Set Register
0x01C0 2090 0x01E3 2090 QSER QDMA Secondary Event Register
0x01C0 2094 0x01E3 2094 QSECR QDMA Secondary Event Clear Register
Shadow Region 1 Channel Registers
0x01C0 2200 0x01E3 2200 ER Event Register

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Table 6-13. EDMA3 Channel Controller (EDMA3CC) Registers (continued)


EDMA0 Channel EDMA1 Channel ACRONYM REGISTER DESCRIPTION
Controller 0 Controller 0
BYTE ADDRESS BYTE ADDRESS
0x01C0 2208 0x01E3 2208 ECR Event Clear Register
0x01C0 2210 0x01E3 2210 ESR Event Set Register
0x01C0 2218 0x01E3 2218 CER Chained Event Register
0x01C0 2220 0x01E3 2220 EER Event Enable Register
0x01C0 2228 0x01E3 2228 EECR Event Enable Clear Register
0x01C0 2230 0x01E3 2230 EESR Event Enable Set Register
0x01C0 2238 0x01E3 2238 SER Secondary Event Register
0x01C0 2240 0x01E3 2240 SECR Secondary Event Clear Register
0x01C0 2250 0x01E3 2250 IER Interrupt Enable Register
0x01C0 2258 0x01E3 2258 IECR Interrupt Enable Clear Register
0x01C0 2260 0x01E3 2260 IESR Interrupt Enable Set Register
0x01C0 2268 0x01E3 2268 IPR Interrupt Pending Register
0x01C0 2270 0x01E3 2270 ICR Interrupt Clear Register
0x01C0 2278 0x01E3 2278 IEVAL Interrupt Evaluate Register
0x01C0 2280 0x01E3 2280 QER QDMA Event Register
0x01C0 2284 0x01E3 2284 QEER QDMA Event Enable Register
0x01C0 2288 0x01E3 2288 QEECR QDMA Event Enable Clear Register
0x01C0 228C 0x01E3 228C QEESR QDMA Event Enable Set Register
0x01C0 2290 0x01E3 2290 QSER QDMA Secondary Event Register
0x01C0 2294 0x01E3 2294 QSECR QDMA Secondary Event Clear Register
0x01C0 4000 - 0x01E3 4000 - — Parameter RAM (PaRAM)
0x01C0 4FFF 0x01E3 4FFF

Table 6-14. EDMA3 Transfer Controller (EDMA3TC) Registers


EDMA0 EDMA0 EDMA1 ACRONYM REGISTER DESCRIPTION
Transfer Controller Transfer Controller Transfer Controller
0 1 0
BYTE ADDRESS BYTE ADDRESS BYTE ADDRESS
0x01C0 8000 0x01C0 8400 0x01E3 8000 PID Peripheral Identification Register
0x01C0 8004 0x01C0 8404 0x01E3 8004 TCCFG EDMA3TC Configuration Register
0x01C0 8100 0x01C0 8500 0x01E3 8100 TCSTAT EDMA3TC Channel Status Register
0x01C0 8120 0x01C0 8520 0x01E3 8120 ERRSTAT Error Status Register
0x01C0 8124 0x01C0 8524 0x01E3 8124 ERREN Error Enable Register
0x01C0 8128 0x01C0 8528 0x01E3 8128 ERRCLR Error Clear Register
0x01C0 812C 0x01C0 852C 0x01E3 812C ERRDET Error Details Register
0x01C0 8130 0x01C0 8530 0x01E3 8130 ERRCMD Error Interrupt Command Register
0x01C0 8140 0x01C0 8540 0x01E3 8140 RDRATE Read Command Rate Register
0x01C0 8240 0x01C0 8640 0x01E3 8240 SAOPT Source Active Options Register
0x01C0 8244 0x01C0 8644 0x01E3 8244 SASRC Source Active Source Address Register
0x01C0 8248 0x01C0 8648 0x01E3 8248 SACNT Source Active Count Register
0x01C0 824C 0x01C0 864C 0x01E3 824C SADST Source Active Destination Address Register
0x01C0 8250 0x01C0 8650 0x01E3 8250 SABIDX Source Active B-Index Register
0x01C0 8254 0x01C0 8654 0x01E3 8254 SAMPPRXY Source Active Memory Protection Proxy Register
0x01C0 8258 0x01C0 8658 0x01E3 8258 SACNTRLD Source Active Count Reload Register
0x01C0 825C 0x01C0 865C 0x01E3 825C SASRCBREF Source Active Source Address B-Reference Register
0x01C0 8260 0x01C0 8660 0x01E3 8260 SADSTBREF Source Active Destination Address B-Reference
Register

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Table 6-14. EDMA3 Transfer Controller (EDMA3TC) Registers (continued)


EDMA0 EDMA0 EDMA1 ACRONYM REGISTER DESCRIPTION
Transfer Controller Transfer Controller Transfer Controller
0 1 0
BYTE ADDRESS BYTE ADDRESS BYTE ADDRESS
0x01C0 8280 0x01C0 8680 0x01E3 8280 DFCNTRLD Destination FIFO Set Count Reload Register
0x01C0 8284 0x01C0 8684 0x01E3 8284 DFSRCBREF Destination FIFO Set Source Address B-Reference
Register
0x01C0 8288 0x01C0 8688 0x01E3 8288 DFDSTBREF Destination FIFO Set Destination Address B-
Reference Register
0x01C0 8300 0x01C0 8700 0x01E3 8300 DFOPT0 Destination FIFO Options Register 0
0x01C0 8304 0x01C0 8704 0x01E3 8304 DFSRC0 Destination FIFO Source Address Register 0
0x01C0 8308 0x01C0 8708 0x01E3 8308 DFCNT0 Destination FIFO Count Register 0
0x01C0 830C 0x01C0 870C 0x01E3 830C DFDST0 Destination FIFO Destination Address Register 0
0x01C0 8310 0x01C0 8710 0x01E3 8310 DFBIDX0 Destination FIFO B-Index Register 0
0x01C0 8314 0x01C0 8714 0x01E3 8314 DFMPPRXY0 Destination FIFO Memory Protection Proxy Register
0
0x01C0 8340 0x01C0 8740 0x01E3 8340 DFOPT1 Destination FIFO Options Register 1
0x01C0 8344 0x01C0 8744 0x01E3 8344 DFSRC1 Destination FIFO Source Address Register 1
0x01C0 8348 0x01C0 8748 0x01E3 8348 DFCNT1 Destination FIFO Count Register 1
0x01C0 834C 0x01C0 874C 0x01E3 834C DFDST1 Destination FIFO Destination Address Register 1
0x01C0 8350 0x01C0 8750 0x01E3 8350 DFBIDX1 Destination FIFO B-Index Register 1
0x01C0 8354 0x01C0 8754 0x01E3 8354 DFMPPRXY1 Destination FIFO Memory Protection Proxy Register
1
0x01C0 8380 0x01C0 8780 0x01E3 8380 DFOPT2 Destination FIFO Options Register 2
0x01C0 8384 0x01C0 8784 0x01E3 8384 DFSRC2 Destination FIFO Source Address Register 2
0x01C0 8388 0x01C0 8788 0x01E3 8388 DFCNT2 Destination FIFO Count Register 2
0x01C0 838C 0x01C0 878C 0x01E3 838C DFDST2 Destination FIFO Destination Address Register 2
0x01C0 8390 0x01C0 8790 0x01E3 8390 DFBIDX2 Destination FIFO B-Index Register 2
0x01C0 8394 0x01C0 8794 0x01E3 8394 DFMPPRXY2 Destination FIFO Memory Protection Proxy Register
2
0x01C0 83C0 0x01C0 87C0 0x01E3 83C0 DFOPT3 Destination FIFO Options Register 3
0x01C0 83C4 0x01C0 87C4 0x01E3 83C4 DFSRC3 Destination FIFO Source Address Register 3
0x01C0 83C8 0x01C0 87C8 0x01E3 83C8 DFCNT3 Destination FIFO Count Register 3
0x01C0 83CC 0x01C0 87CC 0x01E3 83CC DFDST3 Destination FIFO Destination Address Register 3
0x01C0 83D0 0x01C0 87D0 0x01E3 83D0 DFBIDX3 Destination FIFO B-Index Register 3
0x01C0 83D4 0x01C0 87D4 0x01E3 83D4 DFMPPRXY3 Destination FIFO Memory Protection Proxy Register
3

Table 6-15 shows an abbreviation of the set of registers which make up the parameter set for each of 128
EDMA events. Each of the parameter register sets consist of 8 32-bit word entries. Table 6-16 shows the
parameter set entry registers with relative memory address locations within each of the parameter sets.

Table 6-15. EDMA Parameter Set RAM


EDMA0 EDMA1
Channel Controller 0 Channel Controller 0 DESCRIPTION
BYTE ADDRESS RANGE BYTE ADDRESS RANGE
0x01C0 4000 - 0x01C0 401F 0x01E3 4000 - 0x01E3 401F Parameters Set 0 (8 32-bit words)
0x01C0 4020 - 0x01C0 403F 0x01E3 4020 - 0x01E3 403F Parameters Set 1 (8 32-bit words)
0x01C0 4040 - 0x01CC0 405F 0x01E3 4040 - 0x01CE3 405F Parameters Set 2 (8 32-bit words)
0x01C0 4060 - 0x01C0 407F 0x01E3 4060 - 0x01E3 407F Parameters Set 3 (8 32-bit words)
0x01C0 4080 - 0x01C0 409F 0x01E3 4080 - 0x01E3 409F Parameters Set 4 (8 32-bit words)
0x01C0 40A0 - 0x01C0 40BF 0x01E3 40A0 - 0x01E3 40BF Parameters Set 5 (8 32-bit words)

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Table 6-15. EDMA Parameter Set RAM (continued)


EDMA0 EDMA1
Channel Controller 0 Channel Controller 0 DESCRIPTION
BYTE ADDRESS RANGE BYTE ADDRESS RANGE
... ... ...
0x01C0 4FC0 - 0x01C0 4FDF 0x01E3 4FC0 - 0x01E3 4FDF Parameters Set 126 (8 32-bit words)
0x01C0 4FE0 - 0x01C0 4FFF 0x01E3 4FE0 - 0x01E3 4FFF Parameters Set 127 (8 32-bit words)

Table 6-16. Parameter Set Entries


OFFSET BYTE ADDRESS
ACRONYM PARAMETER ENTRY
WITHIN THE PARAMETER SET
0x0000 OPT Option
0x0004 SRC Source Address
0x0008 A_B_CNT A Count, B Count
0x000C DST Destination Address
0x0010 SRC_DST_BIDX Source B Index, Destination B Index
0x0014 LINK_BCNTRLD Link Address, B Count Reload
0x0018 SRC_DST_CIDX Source C Index, Destination C Index
0x001C CCNT C Count

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6.10 External Memory Interface A (EMIFA)


EMIFA is one of two external memory interfaces supported on the device. It is primarily intended to
support asynchronous memory types, such as NAND and NOR flash and Asynchronous SRAM. However
on this device, EMIFA also provides a secondary interface to SDRAM.

6.10.1 EMIFA Asynchronous Memory Support


EMIFA supports asynchronous:
• SRAM memories
• NAND Flash memories
• NOR Flash memories
The EMIFA data bus width is up to 16-bits.The device supports up to 23 address lines and two external
wait/interrupt inputs. Up to four asynchronous chip selects are supported by EMIFA (EMA_CS[5:2]).
Each chip select has the following individually programmable attributes:
• Data Bus Width
• Read cycle timings: setup, hold, strobe
• Write cycle timings: setup, hold, strobe
• Bus turn around time
• Extended Wait Option With Programmable Timeout
• Select Strobe Option
• NAND flash controller supports 1-bit and 4-bit ECC calculation on blocks of 512 bytes.

6.10.2 EMIFA Synchronous DRAM Memory Support


The device supports 16-bit SDRAM in addition to the asynchronous memories listed in Section 6.10.1. It
has a single SDRAM chip select (EMA_CS[0]). SDRAM configurations that are supported are:
• One, Two, and Four Bank SDRAM devices
• Devices with Eight, Nine, Ten, and Eleven Column Address
• CAS Latency of two or three clock cycles
• Sixteen Bit Data Bus Width
Additionally, the SDRAM interface of EMIFA supports placing the SDRAM in Self Refresh and Powerdown
Modes. Self Refresh mode allows the SDRAM to be put into a low power state while still retaining memory
contents; since the SDRAM will continue to refresh itself even without clocks from the device. Powerdown
mode achieves even lower power, except the device must periodically wake the SDRAM up and issue
refreshes if data retention is required.
Finally, note that the EMIFA does not support Mobile SDRAM devices.
Table 6-17 shows the supported SDRAM configurations for EMIFA.

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Table 6-17. EMIFA Supported SDRAM Configurations (1)


SDRAM
EMIFA Data Total Total Memory
Memory Number of
Bus Size Rows Columns Banks Memory Memory Density
Data Bus Memories
(bits) (Mbits) (Mbytes) (Mbits)
Width (bits)
1 16 16 8 1 256 32 256
1 16 16 8 2 512 64 512
1 16 16 8 4 1024 128 1024
1 16 16 9 1 512 64 512
1 16 16 9 2 1024 128 1024
16 1 16 16 9 4 2048 256 2048
1 16 16 10 1 1024 128 1024
1 16 16 10 2 2048 256 2048
1 16 16 10 4 4096 512 4096
1 16 16 11 1 2048 256 2048
1 16 16 11 2 4096 512 4096
1 16 15 11 4 4096 512 4096
2 16 16 8 1 256 32 128
2 16 16 8 2 512 64 256
2 16 16 8 4 1024 128 512
2 16 16 9 1 512 64 256
2 16 16 9 2 1024 128 512
8 2 16 16 9 4 2048 256 1024
2 16 16 10 1 1024 128 512
2 16 16 10 2 2048 256 1024
2 16 16 10 4 4096 512 2048
2 16 16 11 1 2048 256 1024
2 16 16 11 2 4096 512 2048
2 16 15 11 4 4096 512 2048
(1) The shaded cells indicate configurations that are possible on the EMIFA interface but as of this writing SDRAM memories capable of
supporting these densities are not available in the market.

6.10.3 EMIFA SDRAM Loading Limitations


EMIFA supports SDRAM up to 100 MHz with up to two SDRAM or asynchronous memory loads.
Additional loads will limit the SDRAM operation to lower speeds and the maximum speed should be
confirmed by board simulation using IBIS models.

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6.10.4 External Memory Interface Register Descriptions

Table 6-18. External Memory Interface (EMIFA) Registers


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x6800 0000 MIDR Module ID Register
0x6800 0004 AWCC Asynchronous Wait Cycle Configuration Register
0x6800 0008 SDCR SDRAM Configuration Register
0x6800 000C SDRCR SDRAM Refresh Control Register
0x6800 0010 CE2CFG Asynchronous 1 Configuration Register
0x6800 0014 CE3CFG Asynchronous 2 Configuration Register
0x6800 0018 CE4CFG Asynchronous 3 Configuration Register
0x6800 001C CE5CFG Asynchronous 4 Configuration Register
0x6800 0020 SDTIMR SDRAM Timing Register
0x6800 003C SDSRETR SDRAM Self Refresh Exit Timing Register
0x6800 0040 INTRAW EMIFA Interrupt Raw Register
0x6800 0044 INTMSK EMIFA Interrupt Mask Register
0x6800 0048 INTMSKSET EMIFA Interrupt Mask Set Register
0x6800 004C INTMSKCLR EMIFA Interrupt Mask Clear Register
0x6800 0060 NANDFCR NAND Flash Control Register
0x6800 0064 NANDFSR NAND Flash Status Register
0x6800 0070 NANDF1ECC NAND Flash 1 ECC Register (CS2 Space)
0x6800 0074 NANDF2ECC NAND Flash 2 ECC Register (CS3 Space)
0x6800 0078 NANDF3ECC NAND Flash 3 ECC Register (CS4 Space)
0x6800 007C NANDF4ECC NAND Flash 4 ECC Register (CS5 Space)
0x6800 00BC NAND4BITECCLOAD NAND Flash 4-Bit ECC Load Register
0x6800 00C0 NAND4BITECC1 NAND Flash 4-Bit ECC Register 1
0x6800 00C4 NAND4BITECC2 NAND Flash 4-Bit ECC Register 2
0x6800 00C8 NAND4BITECC3 NAND Flash 4-Bit ECC Register 3
0x6800 00CC NAND4BITECC4 NAND Flash 4-Bit ECC Register 4
0x6800 00D0 NANDERRADD1 NAND Flash 4-Bit ECC Error Address Register 1
0x6800 00D4 NANDERRADD2 NAND Flash 4-Bit ECC Error Address Register 2
0x6800 00D8 NANDERRVAL1 NAND Flash 4-Bit ECC Error Value Register 1
0x6800 00DC NANDERRVAL2 NAND Flash 4-Bit ECC Error Value Register 2

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6.10.5 EMIFA Electrical Data/Timing


Table 6-19 through Table 6-22 assume testing over recommended operating conditions.

Table 6-19. Timing Requirements for EMIFA SDRAM Interface


1.3V, 1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX
Input setup time, read data valid on EMA_D[15:0] before
19 tsu(EMA_DV-EM_CLKH) 2 3 3 ns
EMA_CLK rising
Input hold time, read data valid on EMA_D[15:0] after
20 th(CLKH-DIV) 1.6 1.6 1.6 ns
EMA_CLK rising

Table 6-20. Switching Characteristics for EMIFA SDRAM Interface


1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
1 tc(CLK) Cycle time, EMIF clock EMA_CLK 10 15 20 ns
2 tw(CLK) Pulse width, EMIF clock EMA_CLK high or low 3 5 8 ns
3 td(CLKH-CSV) Delay time, EMA_CLK rising to EMA_CS[0] valid 7 9.5 13 ns
4 toh(CLKH-CSIV) Output hold time, EMA_CLK rising to EMA_CS[0] invalid 1 1 1 ns
5 td(CLKH-DQMV) Delay time, EMA_CLK rising to EMA_WE_DQM[1:0] valid 7 9.5 13 ns
Output hold time, EMA_CLK rising to EMA_WE_DQM[1:0]
6 toh(CLKH-DQMIV) 1 1 1 ns
invalid
Delay time, EMA_CLK rising to EMA_A[12:0] and
7 td(CLKH-AV) 7 9.5 13 ns
EMA_BA[1:0] valid
Output hold time, EMA_CLK rising to EMA_A[12:0] and
8 toh(CLKH-AIV) 1 1 1 ns
EMA_BA[1:0] invalid
9 td(CLKH-DV) Delay time, EMA_CLK rising to EMA_D[15:0] valid 7 9.5 13 ns
10 toh(CLKH-DIV) Output hold time, EMA_CLK rising to EMA_D[15:0] invalid 1 1 1 ns
11 td(CLKH-RASV) Delay time, EMA_CLK rising to EMA_RAS valid 7 9.5 13 ns
12 toh(CLKH-RASIV) Output hold time, EMA_CLK rising to EMA_RAS invalid 1 1 1 ns
13 td(CLKH-CASV) Delay time, EMA_CLK rising to EMA_CAS valid 7 9.5 13 ns
14 toh(CLKH-CASIV) Output hold time, EMA_CLK rising to EMA_CAS invalid 1 1 1 ns
15 td(CLKH-WEV) Delay time, EMA_CLK rising to EMA_WE valid 7 9.5 13 ns
16 toh(CLKH-WEIV) Output hold time, EMA_CLK rising to EMA_WE invalid 1 1 1 ns
17 tdis(CLKH-DHZ) Delay time, EMA_CLK rising to EMA_D[15:0] tri-stated 7 9.5 13 ns
18 tena(CLKH-DLZ) Output hold time, EMA_CLK rising to EMA_D[15:0] driving 1 1 1 ns

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1
BASIC SDRAM
WRITE OPERATION 2 2
EMA_CLK
3 4
EMA_CS[0]
5 6
EMA_WE_DQM[1:0]
7 8
EMA_BA[1:0]
7 8
EMA_A[12:0]
9
10
EMA_D[15:0]
11 12
EMA_RAS
13
EMA_CAS
15 16
EMA_WE

Figure 6-10. EMIFA Basic SDRAM Write Operation

1
BASIC SDRAM
READ OPERATION 2 2
EMA_CLK
3 4
EMA_CS[0]
5 6
EMA_WE_DQM[1:0]
7 8
EMA_BA[1:0]
7 8
EMA_A[12:0]
19
2 EM_CLK Delay
17 20 18
EMA_D[15:0]
11 12
EMA_RAS
13 14
EMA_CAS
EMA_WE

Figure 6-11. EMIFA Basic SDRAM Read Operation

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(1)
Table 6-21. Timing Requirements for EMIFA Asynchronous Memory Interface
1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX
READS and WRITES
E tc(CLK) Cycle time, EMIFA module clock 6.75 13.33 20 ns
2 tw(EM_WAIT) Pulse duration, EM_WAIT assertion and deassertion 2E 2E 2E ns
READS
12 tsu(EMDV-EMOEH) Setup time, EM_D[15:0] valid before EM_OE high 3 5 7 ns
13 th(EMOEH-EMDIV) Hold time, EM_D[15:0] valid after EM_OE high 0 0 0 ns
tsu (EMOEL- Setup Time, EM_WAIT asserted before end of Strobe
14 4E+3 4E+3 4E+3 ns
EMWAIT) Phase
WRITES
tsu (EMWEL- Setup Time, EM_WAIT asserted before end of Strobe
28 4E+3 4E+3 4E+3 ns
EMWAIT) Phase
(1) E = EMA_CLK period or in ns. EMA_CLK is selected either as SYSCLK3 or the PLL0 output clock divided by 4.5. As an example, when
SYSCLK3 is selected and set to 100MHz, E=10ns

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(1) (2) (3)


Table 6-22. Switching Characteristics for EMIFA Asynchronous Memory Interface
1.3V, 1.2V, 1.1V, 1.0V
NO. PARAMETER UNIT
MIN Nom MAX
READS and WRITES
1 td(TURNAROUND) Turn around time (TA)*E - 3 (TA)*E (TA)*E + 3 ns
READS
EMIF read cycle time (EW = 0) (RS+RST+RH)*E - 3 (RS+RST+RH)*E (RS+RST+RH)*E + 3 ns
3 tc(EMRCYCLE)
EMIF read cycle time (EW = 1) (RS+RST+RH+EWC)*E - 3 (RS+RST+RH+EWC)*E (RS+RST+RH+EWC)*E + 3 ns
Output setup time, EMA_CE[5:2] low to EMA_OE low (SS = 0) (RS)*E-3 (RS)*E (RS)*E+3 ns
4 tsu(EMCEL-EMOEL)
Output setup time, EMA_CE[5:2] low to EMA_OE low (SS = 1) -3 0 +3 ns
Output hold time, EMA_OE high to EMA_CE[5:2] high (SS = 0) (RH)*E - 3 (RH)*E (RH)*E + 3 ns
5 th(EMOEH-EMCEH)
Output hold time, EMA_OE high to EMA_CE[5:2] high (SS = 1) -3 0 +3 ns
6 tsu(EMBAV-EMOEL) Output setup time, EMA_BA[1:0] valid to EMA_OE low (RS)*E-3 (RS)*E (RS)*E+3 ns
7 th(EMOEH-EMBAIV) Output hold time, EMA_OE high to EMA_BA[1:0] invalid (RH)*E-3 (RH)*E (RH)*E+3 ns
8 tsu(EMBAV-EMOEL) Output setup time, EMA_A[13:0] valid to EMA_OE low (RS)*E-3 (RS)*E (RS)*E+3 ns
9 th(EMOEH-EMAIV) Output hold time, EMA_OE high to EMA_A[13:0] invalid (RH)*E-3 (RH)*E (RH)*E+3 ns
EMA_OE active low width (EW = 0) (RST)*E-3 (RST)*E (RST)*E+3 ns
10 tw(EMOEL)
EMA_OE active low width (EW = 1) (RST+EWC)*E-3 (RST+EWC)*E (RST+EWC)*E+3 ns
11 td(EMWAITH-EMOEH) Delay time from EMA_WAIT deasserted to EMA_OE high 3E-3 4E 4E+3 ns
28 tsu(EMARW-EMOEL) Output setup time, EMA_A_RW valid to EMA_OE low (RS)*E-3 (RS)*E (RS)*E+3 ns
29 th(EMOEH-EMARW) Output hold time, EMA_OE high to EMA_A_RW invalid (RH)*E-3 (RH)*E (RH)*E+3 ns
WRITES
EMIF write cycle time (EW = 0) (WS+WST+WH)*E-3 (WS+WST+WH)*E (WS+WST+WH)*E+3 ns
15 tc(EMWCYCLE) (WS+WST+WH+EWC)*E +
EMIF write cycle time (EW = 1) (WS+WST+WH+EWC)*E - 3 (WS+WST+WH+EWC)*E ns
3
Output setup time, EMA_CE[5:2] low to EMA_WE low (SS = 0) (WS)*E - 3 (WS)*E (WS)*E + 3 ns
16 tsu(EMCEL-EMWEL)
Output setup time, EMA_CE[5:2] low to EMA_WE low (SS = 1) -3 0 +3 ns
Output hold time, EMA_WE high to EMA_CE[5:2] high (SS = 0) (WH)*E-3 (WH)*E (WH)*E+3 ns
17 th(EMWEH-EMCEH)
Output hold time, EMA_WE high to EMA_CE[5:2] high (SS = 1) -3 0 +3 ns
18 tsu(EMDQMV-EMWEL) Output setup time, EMA_BA[1:0] valid to EMA_WE low (WS)*E-3 (WS)*E (WS)*E+3 ns
19 th(EMWEH-EMDQMIV) Output hold time, EMA_WE high to EMA_BA[1:0] invalid (WH)*E-3 (WH)*E (WH)*E+3 ns
20 tsu(EMBAV-EMWEL) Output setup time, EMA_BA[1:0] valid to EMA_WE low (WS)*E-3 (WS)*E (WS)*E+3 ns
21 th(EMWEH-EMBAIV) Output hold time, EMA_WE high to EMA_BA[1:0] invalid (WH)*E-3 (WH)*E (WH)*E+3 ns

(1) TA = Turn around, RS = Read setup, RST = Read strobe, RH = Read hold, WS = Write setup, WST = Write strobe, WH = Write hold, MEWC = Maximum external wait cycles. These
parameters are programmed via the Asynchronous Bank and Asynchronous Wait Cycle Configuration Registers. These support the following range of values: TA[4-1], RS[16-1], RST[64-
1], RH[8-1], WS[16-1], WST[64-1], WH[8-1], and MEW[1-256].
(2) E = EMA_CLK period or in ns. EMA_CLK is selected either as SYSCLK3 or the PLL0 output clock divided by 4.5. As an example, when SYSCLK3 is selected and set to 100MHz,
E=10ns.
(3) EWC = external wait cycles determined by EMA_WAIT input signal. EWC supports the following range of values EWC[256-1]. Note that the maximum wait time before timeout is specified
by bit field MEWC in the Asynchronous Wait Cycle Configuration Register.

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(1) (2) (3)


Table 6-22. Switching Characteristics for EMIFA Asynchronous Memory Interface (continued)
1.3V, 1.2V, 1.1V, 1.0V
NO. PARAMETER UNIT
MIN Nom MAX
22 tsu(EMAV-EMWEL) Output setup time, EMA_A[13:0] valid to EMA_WE low (WS)*E-3 (WS)*E (WS)*E+3 ns
23 th(EMWEH-EMAIV) Output hold time, EMA_WE high to EMA_A[13:0] invalid (WH)*E-3 (WH)*E (WH)*E+3 ns
EMA_WE active low width (EW = 0) (WST)*E-3 (WST)*E (WST)*E+3 ns
24 tw(EMWEL)
EMA_WE active low width (EW = 1) (WST+EWC)*E-3 (WST+EWC)*E (WST+EWC)*E+3 ns
25 td(EMWAITH-EMWEH) Delay time from EMA_WAIT deasserted to EMA_WE high 3E-3 4E 4E+3 ns
26 tsu(EMDV-EMWEL) Output setup time, EMA_D[15:0] valid to EMA_WE low (WS)*E-3 (WS)*E (WS)*E+3 ns
27 th(EMWEH-EMDIV) Output hold time, EMA_WE high to EMA_D[15:0] invalid (WH)*E-3 (WH)*E (WH)*E+3 ns
30 tsu(EMARW-EMWEL) Output setup time, EMA_A_RW valid to EMA_WE low (WS)*E-3 (WS)*E (WS)*E+3 ns
31 th(EMWEH-EMARW) Output hold time, EMA_WE high to EMA_A_RW invalid (WH)*E-3 (WH)*E (WH)*E+3 ns

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SETUP STROBE HOLD

3
1

EMA_CS[5:2]

EMA_BA[1:0]

EMA_A[22:0]

EMA_WE_DQM[1:0]

1
EMA_A_RW

4 5
8 9
6 7
28 10 29
EMA_OE
13
12

EMA_D[15:0]

EMA_WE

Figure 6-12. Asynchronous Memory Read Timing for EMIFA

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SETUP STROBE HOLD

15
1

EMA_CS[5:2]

EMA_BA[1:0]

EMA_A[22:0]

EMA_WE_DQM[1:0]

EMA_A_RW
16 17 1
18 19
20 21
22 23
30 24 31
EMA_WE

26 27

EMA_D[15:0]

EMA_OE

Figure 6-13. Asynchronous Memory Write Timing for EMIFA

EMA_CS[5:2] SETUP STROBE Extended Due to EMA_WAIT STROBE HOLD

EMA_BA[1:0]

EMA_A[22:0]

EMA_D[15:0]

EMA_A_RW

14
11
EMA_OE

2
2
EMA_WAIT Asserted Deasserted

Figure 6-14. EMA_WAIT Read Timing Requirements

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EMA_CS[5:2]

EMA_BA[1:0]

EMA_A[22:0]

EMA_D[15:0]

EMA_A_RW

EMA_WE

EMA_WAIT

Figure 6-15. EMA_WAIT Write Timing Requirements

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6.11 DDR2/mDDR Memory Controller


The DDR2/mDDR Memory Controller is a dedicated interface to DDR2/mDDR SDRAM. It supports
JESD79-2A standard compliant DDR2 SDRAM devices and compliant Mobile DDR SDRAM devices.
The DDR2/mDDR Memory Controller support the following features:
• JESD79-2A standard compliant DDR2 SDRAM
• Mobile DDR SDRAM
• 256 MByte memory space for DDR2
• 256 MByte memory space for mDDR
• CAS latencies:
– DDR2: 2, 3, 4 and 5
– mDDR: 2 and 3
• Internal banks:
– DDR2: 1, 2, 4 and 8
– mDDR:1, 2 and 4
• Burst length: 8
• Burst type: sequential
• 1 chip select (CS) signal
• Page sizes: 256, 512, 1024 and 2048
• SDRAM autoinitialization
• Self-refresh mode
• Partial array self-refresh (for mDDR)
• Power down mode
• Prioritized refresh
• Programmable refresh rate and backlog counter
• Programmable timing parameters
• Little endian

6.11.1 DDR2/mDDR Memory Controller Electrical Data/Timing

Table 6-23. Switching Characteristics Over Recommended Operating Conditions for DDR2/mDDR
Memory Controller
No. PARAMETER 1.3V, 1.2V 1.1V 1.0V UNIT
MIN MAX MIN MAX MIN MAX
Cycle time, DDR2 125 156 125 150 — (1) — (1)
1 tc(DDR_CLK) MHz
DDR_CLKP / DDR_CLKN mDDR 105 150 100 133 95 133
(1) DDR2 is not supported at this voltage operating point.

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6.11.2 DDR2/mDDR Controller Register Description(s)

Table 6-24. DDR2/mDDR Controller Registers


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0xB000 0000 REVID Revision ID Register
0xB000 0004 SDRSTAT SDRAM Status Register
0xB000 0008 SDCR SDRAM Configuration Register
0xB000 000C SDRCR SDRAM Refresh Control Register
0xB000 0010 SDTIMR1 SDRAM Timing Register 1
0xB000 0014 SDTIMR2 SDRAM Timing Register 2
0xB000 001C SDCR2 SDRAM Configuration Register 2
0xB000 0020 PBBPR Peripheral Bus Burst Priority Register
0xB000 0040 PC1 Performance Counter 1 Registers
0xB000 0044 PC2 Performance Counter 2 Register
0xB000 0048 PCC Performance Counter Configuration Register
0xB000 004C PCMRS Performance Counter Master Region Select Register
0xB000 0050 PCT Performance Counter Time Register
0xB000 00C0 IRR Interrupt Raw Register
0xB000 00C4 IMR Interrupt Mask Register
0xB000 00C8 IMSR Interrupt Mask Set Register
0xB000 00CC IMCR Interrupt Mask Clear Register
0xB000 00E4 DRPYC1R DDR PHY Control Register 1
0x01E2 C000 VTPIO_CTL VTP IO Control Register

6.11.3 DDR2/mDDR Interface


This section provides the timing specification for the DDR2/mDDR interface as a PCB design and
manufacturing specification. The design rules constrain PCB trace length, PCB trace skew, signal
integrity, cross-talk, and signal timing. These rules, when followed, result in a reliable DDR2/mDDR
memory system without the need for a complex timing closure process. For more information regarding
guidelines for using this DDR2/mDDR specification, Understanding TI's PCB Routing Rule-Based DDR2
Timing Specification (SPRAAV0).

6.11.3.1 DDR2/mDDR Interface Schematic


Figure 6-16 shows the DDR2/mDDR interface schematic for a single-memory DDR2/mDDR system. The
dual-memory system shown in Figure 6-17. Pin numbers for the device can be obtained from the pin
description section.

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DDR2/mDDR Memory Controller DDR2/mDDR

ODT

DDR_D[0] T DQ0

DDR_D[7] T DQ7

DDR_DQM[0] T LDM
DDR_DQS[0] T LDQS
NC LDQS
DDR_D[8] T DQ8

DDR_D[15] T DQ15
DDR_DQM[1] T UDM
DDR_DQS[1] T UDQS
NC UDQS
DDR_BA[0] T BA0

DDR_BA[2] T BA2
DDR_A[0] T A0

DDR_A[13] T A13
DDR_CS T CS
DDR_CAS T CAS
DDR_RAS T RAS
DDR_WE T WE
DDR_CKE T CKE
DDR_CLKP T CK
DDR_CLKN T CK

DDR_ZP
50 Ω 5%

DDR_DQGATE0 T (1) DDR_DVDD18


(3)
VREF
DDR_DQGATE1 T

0.1 μF
1 K Ω 1%
DDR_VREF VREF
(2) (2) (2)
0.1 μF 0.1 μF 0.1 μF 0.1 μF 1 K Ω 1%

T Terminator, if desired. See terminator comments.


(1) See Figure 6-23 for DQGATE routing specifications.
(2) For DDR2, one of these capacitors can be eliminated if the divider and its capacitors are placed near a device VREF pin. For mDDR,
these capacitors can be eliminated completely.
(3) VREF applies in the case of DDR2 memories. For mDDR, the DDR_VREF pin still needs to be connected to the divider circuit.

Figure 6-16. DDR2/mDDR Single-Memory High Level Schematic

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DDR2/mDDR Memory Controller

ODT

DDR_D[0:7] T DQ0 - DQ7


BA0-BA2
A0-A13

DDR_DQM[0] T DM

DDR2/mDDR
Lower Byte
DDR_DQS[0] T DQS
NC DQS

CK
CK
CS
CAS
RAS
WE
CKE
VREF
DDR_BA[0:2] T BA0-BA2
DDR_A[0:13] T A0-A13
DDR_CLKP T CK
DDR_CLKN T CK
DDR_CS T CS
DDR_CAS T CAS
DDR_RAS T RAS

DDR2/mDDR
Upper Byte
DDR_WE T WE
DDR_CKE T CKE

DDR_DQM1 T DM
DDR_DQS1 T DQS
NC DQS
DDR_D[8:15] T DQ0 - DQ7 DDR_DVDD18
DDR_ZP ODT
50 Ω 5%

(1)
DDR_DQGATE0 T (3)
VREF
DDR_DQGATE1 T 0.1 μF
1 K Ω 1%
DDR_VREF VREF
(2) (2) (2)
0.1 μF 0.1 μF 0.1 μF 1 K Ω 1%
0.1 μF

T Terminator, if desired. See terminator comments.


(1) See Figure 6-23 for DQGATE routing specifications.
(2) For DDR2, one of these capacitors can be eliminated if the divider and its capacitors are placed near a device VREF pin. For mDDR,
these capacitors can be eliminated completely.
(3) VREF applies in the case of DDR2 memories. For mDDR, the DDR_VREF pin still needs to be connected to the divider circuit.

Figure 6-17. DDR2/mDDR Dual-Memory High Level Schematic

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6.11.3.2 Compatible JEDEC DDR2/mDDR Devices


Table 6-25 shows the parameters of the JEDEC DDR2/mDDR devices that are compatible with this
interface. Generally, the DDR2/mDDR interface is compatible with x16 DDR2-400/mDDR-200 speed
grade DDR2/mDDR devices.
The device also supports JEDEC DDR2/mDDR x8 devices in the dual chip configuration. In this case, one
chip supplies the upper byte and the second chip supplies the lower byte. Addresses and most control
signals are shared just like regular dual chip memory configurations.

Table 6-25. Compatible JEDEC DDR2/mDDR Devices


NO. PARAMETER MIN MAX UNIT
1 JEDEC DDR2/mDDR Device Speed Grade (1) DDR2-400/mDDR-
200
2 JEDEC DDR2/mDDR Device Bit Width x8 x16 Bits
3 JEDEC DDR2/mDDR Device Count (2) 1 2 Devices
(1) Higher DDR2/mDDR speed grades are supported due to inherent JEDEC DDR2/mDDR backwards compatibility.
(2) Supported configurations are one 16-bit DDR2/mDDR memory or two 8-bit DDR2/mDDR memories

6.11.3.3 PCB Stackup


The minimum stackup required for routing the device is a six layer stack as shown in Table 6-26.
Additional layers may be added to the PCB stack up to accommodate other circuitry or to reduce the size
of the PCB footprint.Complete stack up specifications are provided in Table 6-27.

Table 6-26. Device Minimum PCB Stack Up


LAYER TYPE DESCRIPTION
1 Signal Top Routing Mostly Horizontal
2 Plane Ground
3 Plane Power
4 Signal Internal Routing
5 Plane Ground
6 Signal Bottom Routing Mostly Vertical

Table 6-27. PCB Stack Up Specifications


NO. PARAMETER MIN TYP MAX UNIT
1 PCB Routing/Plane Layers 6
2 Signal Routing Layers 3
3 Full ground layers under DDR2/mDDR routing region 2
4 Number of ground plane cuts allowed within DDR routing region 0
5 Number of ground reference planes required for each DDR2/mDDR routing layer 1
6 Number of layers between DDR2/mDDR routing layer and reference ground plane 0
7 PCB Routing Feature Size 4 Mils
8 PCB Trace Width w 4 Mils
8 PCB BGA escape via pad size 18 Mils
9 PCB BGA escape via hole size 8 Mils
10 Device BGA pad size (1)
11 DDR2/mDDR Device BGA pad size (2)
12 Single Ended Impedance, Zo 50 75 Ω
13 Impedance Control (3) Z-5 Z Z+5 Ω
(1) Please refer to the Flip Chip Ball Grid Array Package Reference Guide (SPRU811) for device BGA pad size.
(2) Please refer to the DDR2/mDDR device manufacturer documentation for the DDR2/mDDR device BGA pad size.
(3) Z is the nominal singled ended impedance selected for the PCB specified by item 12.

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6.11.3.4 Placement
Figure 6-17 shows the required placement for the device as well as the DDR2/mDDR devices. The
dimensions for Figure 6-18 are defined in Table 6-28. The placement does not restrict the side of the PCB
that the devices are mounted on. The ultimate purpose of the placement is to limit the maximum trace
lengths and allow for proper routing space. For single-memory DDR2/mDDR systems, the second
DDR2/mDDR device is omitted from the placement.

A1

DDR2/mDDR
OFFSET

Controller
DDR2/mDDR
Y
Device
Y
OFFSET
A1

Recommended DDR2/mDDR
Device Orientation

Figure 6-18. Device and DDR2/mDDR Device Placement

Table 6-28. Placement Specifications (1) (2)


NO. PARAMETER MIN MAX UNIT
1 X 1750 Mils
2 Y 1280 Mils
(3)
3 Y Offset 650 Mils
4 Clearance from non-DDR2/mDDR signal to DDR2/mDDR Keepout Region (4) 4 w (5)
(1) See Figure 6-18 for dimension definitions.
(2) Measurements from center of device to center of DDR2/mDDR device.
(3) For single memory systems it is recommended that Y Offset be as small as possible.
(4) Non-DDR2/mDDR signals allowed within DDR2/mDDR keepout region provided they are separated from DDR2/mDDR routing layers by
a ground plane.
(5) w = PCB trace width as defined in Table 6-27.

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6.11.3.5 DDR2/mDDR Keep Out Region


The region of the PCB used for the DDR2/mDDR circuitry must be isolated from other signals. The
DDR2/mDDR keep out region is defined for this purpose and is shown in Figure 6-19. The size of this
region varies with the placement and DDR routing. Additional clearances required for the keep out region
are shown in Table 6-28.

A1

DDR2/mDDR
Controller
DDR2/mDDR
Device

A1

Region should encompass all DDR2/mDDR circuitry and varies


depending on placement. Non-DDR2/mDDR signals should not be
routed on the DDR signal layers within the DDR2/mDDR keep out
region. Non-DDR2/mDDR signals may be routed in the region
provided they are routed on layers separated from DDR2/mDDR
signal layers by a ground layer. No breaks should be allowed in the
reference ground layers in this region. In addition, the 1.8 V power
plane should cover the entire keep out region.

Figure 6-19. DDR2/mDDR Keepout Region

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6.11.3.6 Bulk Bypass Capacitors


Bulk bypass capacitors are required for moderate speed bypassing of the DDR2/mDDR and other
circuitry. Table 6-29 contains the minimum numbers and capacitance required for the bulk bypass
capacitors. Note that this table only covers the bypass needs of the device and DDR2/mDDR interfaces.
Additional bulk bypass capacitance may be needed for other circuitry.

Table 6-29. Bulk Bypass Capacitors


NO. PARAMETER MIN MAX UNIT
1 DDR_DVDD18 Supply Bulk Bypass Capacitor Count (1) 3 Devices
2 DDR_DVDD18 Supply Bulk Bypass Total Capacitance 30 μF
3 DDR#1 Bulk Bypass Capacitor Count (1) 1 Devices
4 DDR#1 Bulk Bypass Total Capacitance 22 μF
5 DDR#2 Bulk Bypass Capacitor Count (1) (2) 1 Devices
6 DDR#2 Bulk Bypass Total Capacitance (2) 22 μF
(1) These devices should be placed near the device they are bypassing, but preference should be given to the placement of the high-speed
(HS) bypass caps.
(2) Only used on dual-memory systems.

6.11.3.7 High-Speed Bypass Capacitors


High-speed (HS) bypass capacitors are critical for proper DDR2/mDDR interface operation. It is
particularly important to minimize the parasitic series inductance of the HS bypass cap,
device/DDR2/mDDR power, and device/DDR2/mDDR ground connections. Table 6-30 contains the
specification for the HS bypass capacitors as well as for the power connections on the PCB.

Table 6-30. High-Speed Bypass Capacitors


NO. PARAMETER MIN MAX UNIT
(1)
1 HS Bypass Capacitor Package Size 0402 10 Mils
2 Distance from HS bypass capacitor to device being bypassed 250 Mils
3 Number of connection vias for each HS bypass capacitor 2 (2) Vias
4 Trace length from bypass capacitor contact to connection via 1 30 Mils
5 Number of connection vias for each DDR2/mDDR device power or ground balls 1 Vias
6 Trace length from DDR2/mDDR device power ball to connection via 35 Mils
(3)
7 DDR_DVDD18 Supply HS Bypass Capacitor Count 10 Devices
8 DDR_DVDD18 Supply HS Bypass Capacitor Total Capacitance 0.6 μF
9 DDR#1 HS Bypass Capacitor Count (3) 8 Devices
10 DDR#1 HS Bypass Capacitor Total Capacitance 0.4 μF
(3) (4)
11 DDR#2 HS Bypass Capacitor Count 8 Devices
12 DDR#2 HS Bypass Capacitor Total Capacitance (4) 0.4 μF
(1) LxW, 10 mil units, i.e., a 0402 is a 40x20 mil surface mount capacitor
(2) An additional HS bypass capacitor can share the connection vias only if it is mounted on the opposite side of the board.
(3) These devices should be placed as close as possible to the device being bypassed.
(4) Only used on dual-memory systems.

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6.11.3.8 Net Classes


Table 6-31 lists the clock net classes for the DDR2/mDDR interface. Table 6-32 lists the signal net
classes, and associated clock net classes, for the signals in the DDR2/mDDR interface. These net classes
are used for the termination and routing rules that follow.

Table 6-31. Clock Net Class Definitions


CLOCK NET CLASS PIN NAMES
CK DDR_CLKP / DDR_CLKN
DQS0 DDR_DQS[0]
DQS1 DDR_DQS[1]

Table 6-32. Signal Net Class Definitions


ASSOCIATED CLOCK
SIGNAL NET CLASS NET CLASS PIN NAMES
ADDR_CTRL CK DDR_BA[2:0], DDR_A[13:0], DDR_CS, DDR_CAS, DDR_RAS, DDR_WE,
DDR_CKE
D0 DQS0 DDR_D[7:0], DDR_DQM0
D1 DQS1 DDR_D[15:8], DDR_DQM1
DQGATE CK, DQS0, DQS1 DDR_DQGATE0, DDR_DQGATE1

6.11.3.9 DDR2/mDDR Signal Termination


No terminations of any kind are required in order to meet signal integrity and overshoot requirements.
Serial terminators are permitted, if desired, to reduce EMI risk; however, serial terminations are the only
type permitted. Table 6-33 shows the specifications for the series terminators.

Table 6-33. DDR2/mDDR Signal Terminations (1) (2) (3)


NO. PARAMETER MIN TYP MAX UNIT
1 CK Net Class 0 10 Ω
2 ADDR_CTRL Net Class 0 22 Zo Ω
3 Data Byte Net Classes (DQS[0], DQS[1], D0, D1) (4) 0 22 Zo Ω
4 DQGATE Net Class (DQGATE) 0 10 Zo Ω
(1) Only series termination is permitted, parallel or SST specifically disallowed.
(2) Terminator values larger than typical only recommended to address EMI issues.
(3) Termination value should be uniform across net class.
(4) When no termination is used on data lines (0 Ω), the DDR2/mDDR devices must be programmed to operate in 60% strength mode.

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6.11.3.10 VREF Routing


VREF is used as a reference by the input buffers of the DDR2/mDDR memories as well as the device.
VREF is intended to be half the DDR2/mDDR power supply voltage and should be created using a
resistive divider as shown in Figure 6-16. Other methods of creating VREF are not recommended.
Figure 6-20 shows the layout guidelines for VREF.
VREF Bypass Capacitor

DDR2/mDDR Device
A1

VREF Nominal Minimum


DDR2/mDDR
Trace Width is 20 Mils

A1

Neck down to minimum in BGA escape


regions is acceptable. Narrowing to
accomodate via congestion for short
distances is also acceptable. Best
performance is obtained if the width
of VREF is maximized.

Figure 6-20. VREF Routing and Topology

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6.11.3.11 DDR2/mDDR CK and ADDR_CTRL Routing


Figure 6-21 shows the topology of the routing for the CK and ADDR_CTRL net classes. The route is a
balanced T as it is intended that the length of segments B and C be equal. In addition, the length of A
should be maximized.

A1

DDR2/mDDR
B

Controller
T
A
C

A1

Figure 6-21. CK and ADDR_CTRL Routing and Topology

Table 6-34. CK and ADDR_CTRL Routing Specification


NO. PARAMETER MIN TYP MAX UNIT
(1) (2)
1 Center to Center CK-CKN Spacing 2w
2 CK A to B/A to C Skew Length Mismatch (3) 25 Mils
3 CK B to C Skew Length Mismatch 25 Mils
4 Center to center CK to other DDR2/mDDR trace spacing (1) 4w (2)
5 CK/ADDR_CTRL nominal trace length (4) CACLM-50 CACLM CACLM+50 Mils
6 ADDR_CTRL to CK Skew Length Mismatch 100 Mils
7 ADDR_CTRL to ADDR_CTRL Skew Length Mismatch 100 Mils
(1) (2)
8 Center to center ADDR_CTRL to other DDR2/mDDR trace spacing 4w
9 Center to center ADDR_CTRL to other ADDR_CTRL trace spacing (1) 3w (2)

(3)
10 ADDR_CTRL A to B/A to C Skew Length Mismatch 100 Mils
11 ADDR_CTRL B to C Skew Length Mismatch 100 Mils
(1) Center to center spacing is allowed to fall to minimum (w) for up to 500 mils of routed length to accommodate BGA escape and routing
congestion.
(2) w = PCB trace width as defined in Table 6-27.
(3) Series terminator, if used, should be located closest to device.
(4) CACLM is the longest Manhattan distance of the CK and ADDR_CTRL net classes.

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Figure 6-22 shows the topology and routing for the DQS and D net class; the routes are point to point.
Skew matching across bytes is not needed nor recommended.

T
E0

DDR2/mDDR
A1

Controller
T
E1
A1

Figure 6-22. DQS and D Routing and Topology

Table 6-35. DQS and D Routing Specification


NO. PARAMETER MIN TYP MAX UNIT
1 Center to center DQS to other DDR2/mDDR trace spacing (1) 4w (2)
2 DQS/D nominal trace length (3) (4) DQLM-50 DQLM DQLM+50 Mils
3 D to DQS Skew Length Mismatch (4) 100 Mils
4 D to D Skew Length Mismatch (4) 100 Mils
5 Center to center D to other DDR2/mDDR trace spacing (1) (5) 4w (2)
6 Center to Center D to other D trace spacing (1) (6) 3w (2)
(1) Center to center spacing is allowed to fall to minimum (w) for up to 500 mils of routed length to accommodate BGA escape and routing
congestion.
(2) w = PCB trace width as defined in Table 6-27.
(3) Series terminator, if used, should be located closest to DDR.
(4) There is no need and it is not recommended to skew match across data bytes, i.e., from DQS0 and data byte 0 to DQS1 and data byte
1.
(5) D's from other DQS domains are considered other DDR2/mDDR trace.
(6) DQLM is the longest Manhattan distance of each of the DQS and D net class.

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Figure 6-23 shows the routing for the DQGATE net class. Table 6-36 contains the routing specification.

A1

T
F

DDR2/mDDR
Controller
T

A1

Figure 6-23. DQGATE Routing

Table 6-36. DQGATE Routing Specification


NO. PARAMETER MIN TYP MAX UNIT
(1)
1 DQGATE Length F CKB0B
2 Center to center DQGATE to any other trace spacing 4w (2)
3 DQS/D nominal trace length DQLM-50 DQLM DQLM+50 Mils
4 DQGATE Skew (3) 100 Mils
(1) CKB0B1 is the sum of the length of the CK net plus the average length of the DQS0 and DQS1 nets.
(2) w = PCB trace width as defined in Table 6-27.
(3) Skew from CKB0B1

6.11.3.12 MDDR/DDR2 Boundary Scan Limitations


Due to DDR implementation and timing restrictions, it was not possible to place boundary scan cells
between core logic and the IO like boundary scan cells for other IO. Instead, the boundary scan cells are
tapped-off to the DDR PHY and there is the equivalent of a multiplexer inside the DDR PHY which selects
between functional and boundary scan paths.
The implication for boundary scan is that the DDR pins will not support the SAMPLE function of the output
enable cells on the DDR pins and this is a violation of IEEE 1149.1. Full EXTEST and PRELOAD
capability is still available.

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6.12 Memory Protection Units


The MPU performs memory protection checking. It receives requests from a bus master in the system and
checks the address against the fixed and programmable regions to see if the access is allowed. If allowed,
the transfer is passed unmodified to its output bus (to the targeted address). If the transfer is illegal (fails
the protection check) then the MPU does not pass the transfer to the output bus but rather services the
transfer internally back to the input bus (to prevent a hang) returning the fault status to the requestor as
well as generating an interrupt about the fault. The following features are supported by the MPU:
• Provides memory protection for fixed and programmable address ranges.
• Supports multiple programmable address region.
• Supports secure and debug access privileges.
• Supports read, write, and execute access privileges.
• Supports privid(8) associations with ranges.
• Generates an interrupt when there is a protection violation, and saves violating transfer parameters.
• MMR access is also protected.

Table 6-37. MPU1 Configuration Registers


MPU1
ACRONYM REGISTER DESCRIPTION
BYTE ADDRESS
0x01E1 4000 REVID Revision ID
0x01E1 4004 CONFIG Configuration
0x01E1 4010 IRAWSTAT Interrupt raw status/set
0x01E1 4014 IENSTAT Interrupt enable status/clear
0x01E1 4018 IENSET Interrupt enable
0x01E1 401C IENCLR Interrupt enable clear
0x01E1 4020 - 0x01E1 41FF - Reserved
0x01E1 4200 PROG1_MPSAR Programmable range 1, start address
0x01E1 4204 PROG1_MPEAR Programmable range 1, end address
0x01E1 4208 PROG1_MPPA Programmable range 1, memory page protection attributes
0x01E1 420C - 0x01E1 420F - Reserved
0x01E1 4210 PROG2_MPSAR Programmable range 2, start address
0x01E1 4214 PROG2_MPEAR Programmable range 2, end address
0x01E1 4218 PROG2_MPPA Programmable range 2, memory page protection attributes
0x01E1 421C - 0x01E1 421F - Reserved
0x01E1 4220 PROG3_MPSAR Programmable range 3, start address
0x01E1 4224 PROG3_MPEAR Programmable range 3, end address
0x01E1 4228 PROG3_MPPA Programmable range 3, memory page protection attributes
0x01E1 422C - 0x01E1 422F - Reserved
0x01E1 4230 PROG4_MPSAR Programmable range 4, start address
0x01E1 4234 PROG4_MPEAR Programmable range 4, end address
0x01E1 4238 PROG4_MPPA Programmable range 4, memory page protection attributes
0x01E1 423C - 0x01E1 423F - Reserved
0x01E1 4240 PROG5_MPSAR Programmable range 5, start address
0x01E1 4244 PROG5_MPEAR Programmable range 5, end address
0x01E1 4248 PROG5_MPPA Programmable range 5, memory page protection attributes
0x01E1 424C - 0x01E1 424F - Reserved
0x01E1 4250 PROG6_MPSAR Programmable range 6, start address
0x01E1 4254 PROG6_MPEAR Programmable range 6, end address
0x01E1 4258 PROG6_MPPA Programmable range 6, memory page protection attributes
0x01E1 425C - 0x01E1 42FF - Reserved

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Table 6-37. MPU1 Configuration Registers (continued)


MPU1
ACRONYM REGISTER DESCRIPTION
BYTE ADDRESS
0x01E1 4300 FLTADDRR Fault address
0x01E1 4304 FLTSTAT Fault status
0x01E1 4308 FLTCLR Fault clear
0x01E1 430C - 0x01E1 4FFF - Reserved

Table 6-38. MPU2 Configuration Registers


MPU2
ACRONYM REGISTER DESCRIPTION
BYTE ADDRESS
0x01E1 5000 REVID Revision ID
0x01E1 5004 CONFIG Configuration
0x01E1 5010 IRAWSTAT Interrupt raw status/set
0x01E1 5014 IENSTAT Interrupt enable status/clear
0x01E1 5018 IENSET Interrupt enable
0x01E1 501C IENCLR Interrupt enable clear
0x01E1 5020 - 0x01E1 51FF - Reserved
0x01E1 5200 PROG1_MPSAR Programmable range 1, start address
0x01E1 5204 PROG1_MPEAR Programmable range 1, end address
0x01E1 5208 PROG1_MPPA Programmable range 1, memory page protection attributes
0x01E1 520C - 0x01E1 520F - Reserved
0x01E1 5210 PROG2_MPSAR Programmable range 2, start address
0x01E1 5214 PROG2_MPEAR Programmable range 2, end address
0x01E1 5218 PROG2_MPPA Programmable range 2, memory page protection attributes
0x01E1 521C - 0x01E1 521F - Reserved
0x01E1 5220 PROG3_MPSAR Programmable range 3, start address
0x01E1 5224 PROG3_MPEAR Programmable range 3, end address
0x01E1 5228 PROG3_MPPA Programmable range 3, memory page protection attributes
0x01E1 522C - 0x01E1 522F - Reserved
0x01E1 5230 PROG4_MPSAR Programmable range 4, start address
0x01E1 5234 PROG4_MPEAR Programmable range 4, end address
0x01E1 5238 PROG4_MPPA Programmable range 4, memory page protection attributes
0x01E1 523C - 0x01E1 523F - Reserved
0x01E1 5240 PROG5_MPSAR Programmable range 5, start address
0x01E1 5244 PROG5_MPEAR Programmable range 5, end address
0x01E1 5248 PROG5_MPPA Programmable range 5, memory page protection attributes
0x01E1 524C - 0x01E1 524F - Reserved
0x01E1 5250 PROG6_MPSAR Programmable range 6, start address
0x01E1 5254 PROG6_MPEAR Programmable range 6, end address
0x01E1 5258 PROG6_MPPA Programmable range 6, memory page protection attributes
0x01E1 525C - 0x01E1 525F - Reserved
0x01E1 5260 PROG7_MPSAR Programmable range 7, start address
0x01E1 5264 PROG7_MPEAR Programmable range 7, end address
0x01E1 5268 PROG7_MPPA Programmable range 7, memory page protection attributes
0x01E1 526C - 0x01E1 526F - Reserved
0x01E1 5270 PROG8_MPSAR Programmable range 8, start address
0x01E1 5274 PROG8_MPEAR Programmable range 8, end address
0x01E1 5278 PROG8_MPPA Programmable range 8, memory page protection attributes
0x01E1 527C - 0x01E1 527F - Reserved

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Table 6-38. MPU2 Configuration Registers (continued)


MPU2
ACRONYM REGISTER DESCRIPTION
BYTE ADDRESS
0x01E1 5280 PROG9_MPSAR Programmable range 9, start address
0x01E1 5284 PROG9_MPEAR Programmable range 9, end address
0x01E1 5288 PROG9_MPPA Programmable range 9, memory page protection attributes
0x01E1 528C - 0x01E1 528F - Reserved
0x01E1 5290 PROG10_MPSAR Programmable range 10, start address
0x01E1 5294 PROG10_MPEAR Programmable range 10, end address
0x01E1 5298 PROG10_MPPA Programmable range 10, memory page protection attributes
0x01E1 529C - 0x01E1 529F - Reserved
0x01E1 52A0 PROG11_MPSAR Programmable range 11, start address
0x01E1 52A4 PROG11_MPEAR Programmable range 11, end address
0x01E1 52A8 PROG11_MPPA Programmable range 11, memory page protection attributes
0x01E1 52AC - 0x01E1 52AF - Reserved
0x01E1 52B0 PROG12_MPSAR Programmable range 12, start address
0x01E1 52B4 PROG12_MPEAR Programmable range 12, end address
0x01E1 52B8 PROG12_MPPA Programmable range 12, memory page protection attributes
0x01E1 52BC - 0x01E1 52FF - Reserved
0x01E1 5300 FLTADDRR Fault address
0x01E1 5304 FLTSTAT Fault status
0x01E1 5308 FLTCLR Fault clear
0x01E1 530C - 0x01E1 5FFF - Reserved

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6.13 MMC / SD / SDIO (MMCSD0, MMCSD1)

6.13.1 MMCSD Peripheral Description


The device includes an two MMCSD controllers which are compliant with MMC V4.0, Secure Digital Part 1
Physical Layer Specification V1.1 and Secure Digital Input Output (SDIO) V2.0 specifications.
The MMC/SD Controller have following features:
• MultiMediaCard (MMC)
• Secure Digital (SD) Memory Card
• MMC/SD protocol support
• SD high capacity support
• SDIO protocol support
• Programmable clock frequency
• 512 bit Read/Write FIFO to lower system overhead
• Slave EDMA transfer capability
The device MMC/SD Controller does not support SPI mode.

6.13.2 MMCSD Peripheral Register Description(s)

Table 6-39. Multimedia Card/Secure Digital (MMC/SD) Card Controller Registers


MMCSD0 MMCSD1
ACRONYM REGISTER DESCSRIPTION
BYTE ADDRESS BYTE ADDRESS
0x01C4 0000 0x01E1 B000 MMCCTL MMC Control Register
0x01C4 0004 0x01E1 B004 MMCCLK MMC Memory Clock Control Register
0x01C4 0008 0x01E1 B008 MMCST0 MMC Status Register 0
0x01C4 000C 0x01E1 B00C MMCST1 MMC Status Register 1
0x01C4 0010 0x01E1 B010 MMCIM MMC Interrupt Mask Register
0x01C4 0014 0x01E1 B014 MMCTOR MMC Response Time-Out Register
0x01C4 0018 0x01E1 B018 MMCTOD MMC Data Read Time-Out Register
0x01C4 001C 0x01E1 B01C MMCBLEN MMC Block Length Register
0x01C4 0020 0x01E1 B020 MMCNBLK MMC Number of Blocks Register
0x01C4 0024 0x01E1 B024 MMCNBLC MMC Number of Blocks Counter Register
0x01C4 0028 0x01E1 B028 MMCDRR MMC Data Receive Register
0x01C4 002C 0x01E1 B02C MMCDXR MMC Data Transmit Register
0x01C4 0030 0x01E1 B030 MMCCMD MMC Command Register
0x01C4 0034 0x01E1 B034 MMCARGHL MMC Argument Register
0x01C4 0038 0x01E1 B038 MMCRSP01 MMC Response Register 0 and 1
0x01C4 003C 0x01E1 B03C MMCRSP23 MMC Response Register 2 and 3
0x01C4 0040 0x01E1 B040 MMCRSP45 MMC Response Register 4 and 5
0x01C4 0044 0x01E1 B044 MMCRSP67 MMC Response Register 6 and 7
0x01C4 0048 0x01E1 B048 MMCDRSP MMC Data Response Register
0x01C4 0050 0x01E1 B050 MMCCIDX MMC Command Index Register
0x01C4 0064 0x01E1 B064 SDIOCTL SDIO Control Register
0x01C4 0068 0x01E1 B068 SDIOST0 SDIO Status Register 0
0x01C4 006C 0x01E1 B06C SDIOIEN SDIO Interrupt Enable Register
0x01C4 0070 0x01E1 B070 SDIOIST SDIO Interrupt Status Register
0x01C4 0074 0x01E1 B074 MMCFIFOCTL MMC FIFO Control Register

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6.13.3 MMC/SD Electrical Data/Timing


Table 6-40 through Table 6-41 assume testing over recommended operating conditions.

Table 6-40. Timing Requirements for MMC/SD


(see Figure 6-25 and Figure 6-27)
1.3V, 1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX
tsu(CMDV-
1 Setup time, MMCSD_CMD valid before MMCSD_CLK high 4 4 6 ns
CLKH)
2 th(CLKH-CMDV) Hold time, MMCSD_CMD valid after MMCSD_CLK high 2.5 2.5 2.5 ns
3 tsu(DATV-CLKH) Setup time, MMCSD_DATx valid before MMCSD_CLK high 4.5 5 6 ns
4 th(CLKH-DATV) Hold time, MMCSD_DATx valid after MMCSD_CLK high 2.5 2.5 2.5 ns

Table 6-41. Switching Characteristics for MMC/SD (see Figure 6-24 through Figure 6-27)
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
7 f(CLK) Operating frequency, MMCSD_CLK 0 52 0 50 0 25 MHz
8 f(CLK_ID) Identification mode frequency, MMCSD_CLK 0 400 0 400 0 400 KHz
9 tW(CLKL) Pulse width, MMCSD_CLK low 6.5 6.5 10 ns
10 tW(CLKH) Pulse width, MMCSD_CLK high 6.5 6.5 10 ns
11 tr(CLK) Rise time, MMCSD_CLK 3 3 10 ns
12 tf(CLK) Fall time, MMCSD_CLK 3 3 10 ns
13 td(CLKL-CMD) Delay time, MMCSD_CLK low to MMCSD_CMD transition -4 2.5 -4 3 -4 4 ns
14 td(CLKL-DAT) Delay time, MMCSD_CLK low to MMCSD_DATx transition -4 3.3 -4 3.5 -4 4 ns

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10
7 9
MMCSD_CLK
13 13 13 13
START XMIT Valid Valid Valid END
MMCSD_CMD

Figure 6-24. MMC/SD Host Command Timing

9
7 10

MMCSD_CLK
1
2

MMCSD_CMD START XMIT Valid Valid Valid END

Figure 6-25. MMC/SD Card Response Timing

10
7 9
MMCSD_CLK

14 14 14 14
START D0 D1 Dx END
MMCSD_DATx

Figure 6-26. MMC/SD Host Write Timing

9
7 10

MMCSD_CLK
4 4
3 3
MMCSD_DATx Start D0 D1 Dx End

Figure 6-27. MMC/SD Host Read and Card CRC Status Timing

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6.14 Multichannel Audio Serial Port (McASP)


The McASP serial port is specifically designed for multichannel audio applications. Its key features are:
• Flexible clock and frame sync generation logic and on-chip dividers
• Up to sixteen transmit or receive data pins and serializers
• Large number of serial data format options, including:
– TDM Frames with 2 to 32 time slots per frame (periodic) or 1 slot per frame (burst)
– Time slots of 8,12,16, 20, 24, 28, and 32 bits
– First bit delay 0, 1, or 2 clocks
– MSB or LSB first bit order
– Left- or right-aligned data words within time slots
• DIT Mode with 384-bit Channel Status and 384-bit User Data registers
• Extensive error checking and mute generation logic
• All unused pins GPIO-capable
• Transmit & Receive FIFO Buffers allow the McASP to operate at a higher sample rate by making it
more tolerant to DMA latency.
• Dynamic Adjustment of Clock Dividers
– Clock Divider Value may be changed without resetting the McASP
Pins Function

Receive Logic AHCLKRx Receive Master Clock


Peripheral GIO
Configuration Control C lo ck /F ra m e G e n e ra to r ACLKRx Receive Bit Clock
Bus State Machine AFSRx R e c e iv e L e ft/R ig h t C lo ck o r F ra m e S y n c

Clock Check and AMUTEINx The McASP DOES NOT have a


DIT RAM Error Detection AMUTEx dedicated AMUTEIN pin.
384 C
384 U Tra n s m it L o g ic AFSXx Tra n s m it L e ft/R ig h t C lo ck o r F ra m e S y n c
Optional C lo ck /F ra m e G e n e ra to r ACLKXx Tra n s m it B it C lo ck
State Machine AHCLKXx Tra n s m it M a s te r C lo ck

Tra n s m it Serializer 0 AXRx[0] Tra n s m it/R e c e iv e S e ria l D a ta P in


F o rm a tte r
McASP
DMA Bus Serializer 1 AXRx[1] Tra n s m it/R e c e iv e S e ria l D a ta P in
(Dedicated)

Receive
F o rm a tte r Serializer y AXRx[y] Tra n s m it/R e c e iv e S e ria l D a ta P in

McASP

Figure 6-28. McASP Block Diagram

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6.14.1 McASP Peripheral Registers Description(s)


Registers for the McASP are summarized in Table 6-42. The registers are accessed through the
peripheral configuration port. The receive buffer registers (RBUF) and transmit buffer registers (XBUF) can
also be accessed through the DMA port, as listed in Table 6-43
Registers for the McASP Audio FIFO (AFIFO) are summarized in Table 6-44. Note that the AFIFO Write
FIFO (WFIFO) and Read FIFO (RFIFO) have independent control and status registers. The AFIFO control
registers are accessed through the peripheral configuration port.

Table 6-42. McASP Registers Accessed Through Peripheral Configuration Port


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01D0 0000 REV Revision identification register
0x01D0 0010 PFUNC Pin function register
0x01D0 0014 PDIR Pin direction register
0x01D0 0018 PDOUT Pin data output register
0x01D0 001C PDIN Read returns: Pin data input register
0x01D0 001C PDSET Writes affect: Pin data set register (alternate write address: PDOUT)
0x01D0 0020 PDCLR Pin data clear register (alternate write address: PDOUT)
0x01D0 0044 GBLCTL Global control register
0x01D0 0048 AMUTE Audio mute control register
0x01D0 004C DLBCTL Digital loopback control register
0x01D0 0050 DITCTL DIT mode control register
0x01D0 0060 Receiver global control register: Alias of GBLCTL, only receive bits are affected - allows
RGBLCTL
receiver to be reset independently from transmitter
0x01D0 0064 RMASK Receive format unit bit mask register
0x01D0 0068 RFMT Receive bit stream format register
0x01D0 006C AFSRCTL Receive frame sync control register
0x01D0 0070 ACLKRCTL Receive clock control register
0x01D0 0074 AHCLKRCTL Receive high-frequency clock control register
0x01D0 0078 RTDM Receive TDM time slot 0-31 register
0x01D0 007C RINTCTL Receiver interrupt control register
0x01D0 0080 RSTAT Receiver status register
0x01D0 0084 RSLOT Current receive TDM time slot register
0x01D0 0088 RCLKCHK Receive clock check control register
0x01D0 008C REVTCTL Receiver DMA event control register
0x01D0 00A0 Transmitter global control register. Alias of GBLCTL, only transmit bits are affected - allows
XGBLCTL
transmitter to be reset independently from receiver
0x01D0 00A4 XMASK Transmit format unit bit mask register
0x01D0 00A8 XFMT Transmit bit stream format register
0x01D0 00AC AFSXCTL Transmit frame sync control register
0x01D0 00B0 ACLKXCTL Transmit clock control register
0x01D0 00B4 AHCLKXCTL Transmit high-frequency clock control register
0x01D0 00B8 XTDM Transmit TDM time slot 0-31 register
0x01D0 00BC XINTCTL Transmitter interrupt control register
0x01D0 00C0 XSTAT Transmitter status register
0x01D0 00C4 XSLOT Current transmit TDM time slot register
0x01D0 00C8 XCLKCHK Transmit clock check control register
0x01D0 00CC XEVTCTL Transmitter DMA event control register
0x01D0 0100 DITCSRA0 Left (even TDM time slot) channel status register (DIT mode) 0
0x01D0 0104 DITCSRA1 Left (even TDM time slot) channel status register (DIT mode) 1
0x01D0 0108 DITCSRA2 Left (even TDM time slot) channel status register (DIT mode) 2

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Table 6-42. McASP Registers Accessed Through Peripheral Configuration Port (continued)
BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01D0 010C DITCSRA3 Left (even TDM time slot) channel status register (DIT mode) 3
0x01D0 0110 DITCSRA4 Left (even TDM time slot) channel status register (DIT mode) 4
0x01D0 0114 DITCSRA5 Left (even TDM time slot) channel status register (DIT mode) 5
0x01D0 0118 DITCSRB0 Right (odd TDM time slot) channel status register (DIT mode) 0
0x01D0 011C DITCSRB1 Right (odd TDM time slot) channel status register (DIT mode) 1
0x01D0 0120 DITCSRB2 Right (odd TDM time slot) channel status register (DIT mode) 2
0x01D0 0124 DITCSRB3 Right (odd TDM time slot) channel status register (DIT mode) 3
0x01D0 0128 DITCSRB4 Right (odd TDM time slot) channel status register (DIT mode) 4
0x01D0 012C DITCSRB5 Right (odd TDM time slot) channel status register (DIT mode) 5
0x01D0 0130 DITUDRA0 Left (even TDM time slot) channel user data register (DIT mode) 0
0x01D0 0134 DITUDRA1 Left (even TDM time slot) channel user data register (DIT mode) 1
0x01D0 0138 DITUDRA2 Left (even TDM time slot) channel user data register (DIT mode) 2
0x01D0 013C DITUDRA3 Left (even TDM time slot) channel user data register (DIT mode) 3
0x01D0 0140 DITUDRA4 Left (even TDM time slot) channel user data register (DIT mode) 4
0x01D0 0144 DITUDRA5 Left (even TDM time slot) channel user data register (DIT mode) 5
0x01D0 0148 DITUDRB0 Right (odd TDM time slot) channel user data register (DIT mode) 0
0x01D0 014C DITUDRB1 Right (odd TDM time slot) channel user data register (DIT mode) 1
0x01D0 0150 DITUDRB2 Right (odd TDM time slot) channel user data register (DIT mode) 2
0x01D0 0154 DITUDRB3 Right (odd TDM time slot) channel user data register (DIT mode) 3
0x01D0 0158 DITUDRB4 Right (odd TDM time slot) channel user data register (DIT mode) 4
0x01D0 015C DITUDRB5 Right (odd TDM time slot) channel user data register (DIT mode) 5
0x01D0 0180 SRCTL0 Serializer control register 0
0x01D0 0184 SRCTL1 Serializer control register 1
0x01D0 0188 SRCTL2 Serializer control register 2
0x01D0 018C SRCTL3 Serializer control register 3
0x01D0 0190 SRCTL4 Serializer control register 4
0x01D0 0194 SRCTL5 Serializer control register 5
0x01D0 0198 SRCTL6 Serializer control register 6
0x01D0 019C SRCTL7 Serializer control register 7
0x01D0 01A0 SRCTL8 Serializer control register 8
0x01D0 01A4 SRCTL9 Serializer control register 9
0x01D0 01A8 SRCTL10 Serializer control register 10
0x01D0 01AC SRCTL11 Serializer control register 11
0x01D0 01B0 SRCTL12 Serializer control register 12
0x01D0 01B4 SRCTL13 Serializer control register 13
0x01D0 01B8 SRCTL14 Serializer control register 14
0x01D0 01BC SRCTL15 Serializer control register 15

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Table 6-42. McASP Registers Accessed Through Peripheral Configuration Port (continued)
BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01D0 0200 XBUF0 (1) Transmit buffer register for serializer 0
0x01D0 0204 XBUF1 (1) Transmit buffer register for serializer 1
0x01D0 0208 XBUF2 (1) Transmit buffer register for serializer 2
0x01D0 020C XBUF3 (1) Transmit buffer register for serializer 3
(1)
0x01D0 0210 XBUF4 Transmit buffer register for serializer 4
0x01D0 0214 XBUF5 (1) Transmit buffer register for serializer 5
0x01D0 0218 XBUF6 (1) Transmit buffer register for serializer 6
(1)
0x01D0 021C XBUF7 Transmit buffer register for serializer 7
0x01D0 0220 XBUF8 (1) Transmit buffer register for serializer 8
0x01D0 0224 XBUF9 (1) Transmit buffer register for serializer 9
0x01D0 0228 XBUF10 (1) Transmit buffer register for serializer 10
(1)
0x01D0 022C XBUF11 Transmit buffer register for serializer 11
0x01D0 0230 XBUF12 (1) Transmit buffer register for serializer 12
0x01D0 0234 XBUF13 (1) Transmit buffer register for serializer 13
(1)
0x01D0 0238 XBUF14 Transmit buffer register for serializer 14
0x01D0 023C XBUF15 (1) Transmit buffer register for serializer 15
0x01D0 0280 RBUF0 (2) Receive buffer register for serializer 0
(2)
0x01D0 0284 RBUF1 Receive buffer register for serializer 1
0x01D0 0288 RBUF2 (2) Receive buffer register for serializer 2
0x01D0 028C RBUF3 (2) Receive buffer register for serializer 3
0x01D0 0290 RBUF4 (2) Receive buffer register for serializer 4
(2)
0x01D0 0294 RBUF5 Receive buffer register for serializer 5
0x01D0 0298 RBUF6 (2) Receive buffer register for serializer 6
0x01D0 029C RBUF7 (2) Receive buffer register for serializer 7
(2)
0x01D0 02A0 RBUF8 Receive buffer register for serializer 8
0x01D0 02A4 RBUF9 (2) Receive buffer register for serializer 9
0x01D0 02A8 RBUF10 (2) Receive buffer register for serializer 10
(2)
0x01D0 02AC RBUF11 Receive buffer register for serializer 11
0x01D0 02B0 RBUF12 (2) Receive buffer register for serializer 12
0x01D0 02B4 RBUF13 (2) Receive buffer register for serializer 13
0x01D0 02B8 RBUF14 (2) Receive buffer register for serializer 14
(2)
0x01D0 02BC RBUF15 Receive buffer register for serializer 15
(1) Writes to XRBUF originate from peripheral configuration port only when XBUSEL = 1 in XFMT.
(2) Reads from XRBUF originate on peripheral configuration port only when RBUSEL = 1 in RFMT.

Table 6-43. McASP Registers Accessed Through DMA Port


ACCESS BYTE ACRONYM REGISTER DESCRIPTION
TYPE ADDRESS
Read 0x01D0 2000 RBUF Receive buffer DMA port address. Cycles through receive serializers, skipping over transmit
Accesses serializers and inactive serializers. Starts at the lowest serializer at the beginning of each
time slot. Reads from DMA port only if XBUSEL = 0 in XFMT.
Write 0x01D0 2000 XBUF Transmit buffer DMA port address. Cycles through transmit serializers, skipping over receive
Accesses and inactive serializers. Starts at the lowest serializer at the beginning of each time slot.
Writes to DMA port only if RBUSEL = 0 in RFMT.

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Table 6-44. McASP AFIFO Registers Accessed Through Peripheral Configuration Port
BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01D0 1000 AFIFOREV AFIFO revision identification register
0x01D0 1010 WFIFOCTL Write FIFO control register
0x01D0 1014 WFIFOSTS Write FIFO status register
0x01D0 1018 RFIFOCTL Read FIFO control register
0x01D0 101C RFIFOSTS Read FIFO status register

6.14.2 McASP Electrical Data/Timing

6.14.2.1 Multichannel Audio Serial Port 0 (McASP0) Timing


Table 6-45 and Table 6-47 assume testing over recommended operating conditions (see Figure 6-29 and
Figure 6-30).

Table 6-45. Timing Requirements for McASP0 (1.3V, 1.2V, 1.1V) (1) (2)
1.3V, 1.2V 1.1V
NO. UNIT
MIN MAX MIN MAX
1 tc(AHCLKRX) Cycle time, AHCLKR/X 25 28 ns
2 tw(AHCLKRX) Pulse duration, AHCLKR/X high or low 12.5 14 ns
3 tc(ACLKRX) Cycle time, ACLKR/X AHCLKR/X ext 25 (3) 28 (3) ns
4 tw(ACLKRX) Pulse duration, ACLKR/W high or low AHCLKR/X ext 12.5 14 ns
AHCLKR/X int 11.5 12 ns
Setup time,
5 tsu(AFSRX-ACLKRX) AHCLKR/X ext input 4 5 ns
AFSR/X input to ACLKR/X (4)
AHCLKR/X ext output 4 5 ns
AHCLKR/X int -1 -2 ns
Hold time,
6 th(ACLKRX-AFSRX) AHCLKR/X ext input 1 1 ns
AFSR/X input after ACLKR/X (4)
AHCLKR/X ext output 1 1 ns
Setup time, AHCLKR/X int 11.5 12 ns
7 tsu(AXR-ACLKRX)
AXR0[n] input to ACLKR/X (4) (5) AHCLKR/X ext 4 5 ns
AHCLKR/X int -1 -2 ns
Hold time,
8 th(ACLKRX-AXR) AHCLKR/X ext input 3 4 ns
AXR0[n] input after ACLKR/X (4) (5)
AHCLKR/X ext output 3 4 ns
(1) ACLKX0 internal – McASP0 ACLKXCTL.CLKXM = 1, PDIR.ACLKX = 1
ACLKX0 external input – McASP0 ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 0
ACLKX0 external output – McASP0 ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 1
ACLKR0 internal – McASP0 ACLKRCTL.CLKRM = 1, PDIR.ACLKR =1
ACLKR0 external input – McASP0 ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 0
ACLKR0 external output – McASP0 ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 1
(2) P = SYSCLK2 period
(3) This timing is limited by the timing shown or 2P, whichever is greater.
(4) McASP0 ACLKXCTL.ASYNC=1: Receiver is clocked by its own ACLKR0
(5) McASP0 ACLKXCTL.ASYNC=0: Receiver is clocked by transmitter's ACLKX0

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Table 6-46. Timing Requirements for McASP0 (1.0V) (1) (2)


1.0V
NO. UNIT
MIN MAX
1 tc(AHCLKRX) Cycle time, AHCLKR/X 35 ns
2 tw(AHCLKRX) Pulse duration, AHCLKR/X high or low 17.5 ns
3 tc(ACLKRX) Cycle time, ACLKR/X AHCLKR/X ext 35 (3) ns
4 tw(ACLKRX) Pulse duration, ACLKR/W high or low AHCLKR/X ext 17.5 ns
AHCLKR/X int 16 ns
Setup time,
5 tsu(AFSRX-ACLKRX) AHCLKR/X ext input 5.5 ns
AFSR/X input to ACLKR/X (4)
AHCLKR/X ext output 5.5 ns
AHCLKR/X int -2 ns
Hold time,
6 th(ACLKRX-AFSRX) AHCLKR/X ext input 1 ns
AFSR/X input after ACLKR/X (4)
AHCLKR/X ext output 1 ns
Setup time, AHCLKR/X int 16 ns
7 tsu(AXR-ACLKRX)
AXR0[n] input to ACLKR/X (4) (5) AHCLKR/X ext 5.5 ns
AHCLKR/X int -2 ns
Hold time,
8 th(ACLKRX-AXR) AHCLKR/X ext input 5 ns
AXR0[n] input after ACLKR/X (4) (5)
AHCLKR/X ext output 5 ns
(1) ACLKX0 internal – McASP0 ACLKXCTL.CLKXM = 1, PDIR.ACLKX = 1
ACLKX0 external input – McASP0 ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 0
ACLKX0 external output – McASP0 ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 1
ACLKR0 internal – McASP0 ACLKRCTL.CLKRM = 1, PDIR.ACLKR =1
ACLKR0 external input – McASP0 ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 0
ACLKR0 external output – McASP0 ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 1
(2) P = SYSCLK2 period
(3) This timing is limited by the timing shown or 2P, whichever is greater.
(4) McASP0 ACLKXCTL.ASYNC=1: Receiver is clocked by its own ACLKR0
(5) McASP0 ACLKXCTL.ASYNC=0: Receiver is clocked by transmitter's ACLKX0

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Table 6-47. Switching Characteristics for McASP0 (1.3V, 1.2V, 1.1V) (1)
1.3V, 1.2V 1.1V
NO. PARAMETER UNIT
MIN MAX MIN MAX
9 tc(AHCLKRX) Cycle time, AHCLKR/X 25 28 ns
10 tw(AHCLKRX) Pulse duration, AHCLKR/X high or low AH – 2.5 (2) AH – 2.5 (2) ns
11 tc(ACLKRX) Cycle time, ACLKR/X ACLKR/X int 25 (3) (4) 28 (3) (4) ns
12 tw(ACLKRX) Pulse duration, ACLKR/X high or low ACLKR/X int A – 2.5 (5) A – 2.5 (5) ns
ACLKR/X int -1 6 -1 8 ns
Delay time, ACLKR/X transmit edge
13 td(ACLKRX-AFSRX) ACLKR/X ext input 2 13.5 2 14.5 ns
to AFSX/R output valid (6)
ACLKR/X ext output 2 13.5 2 14.5 ns
ACLKR/X int -1 6 -1 8 ns
Delay time, ACLKX transmit edge to
14 td(ACLKX-AXRV) ACLKR/X ext input 2 13.5 2 15 ns
AXR output valid
ACLKR/X ext output 2 13.5 2 15 ns
Disable time, ACLKR/X transmit ACLKR/X int 0 6 0 8 ns
15 tdis(ACLKX-AXRHZ) edge to AXR high impedance
following last data bit ACLKR/X ext 2 13.5 2 15 ns

(1) McASP0 ACLKX0 internal – ACLKXCTL.CLKXM = 1, PDIR.ACLKX = 1


ACLKX0 external input – McASP0 ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 0
ACLKX0 external output – McASP0ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 1
ACLKR0 internal – McASP0 ACLKR0CTL.CLKRM = 1, PDIR.ACLKR =1
ACLKR0 external input – McASP0 ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 0
ACLKR0 external output – McASP0 ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 1
(2) AH = (AHCLKR/X period)/2 in ns. For example, when AHCLKR/X period is 25 ns, use AH = 12.5 ns.
(3) P = SYSCLK2 period
(4) This timing is limited by the timing shown or 2P, whichever is greater.
(5) A = (ACLKR/X period)/2 in ns. For example, when AHCLKR/X period is 25 ns, use AH = 12.5 ns.
(6) McASP0 ACLKXCTL.ASYNC=1: Receiver is clocked by its own ACLKR0

Table 6-48. Switching Characteristics for McASP0 (1.0V) (1)


1.0V
NO. PARAMETER UNIT
MIN MAX
9 tc(AHCLKRX) Cycle time, AHCLKR/X 35 ns
10 tw(AHCLKRX) Pulse duration, AHCLKR/X high or low AH – 2.5 (2) ns
(3) (4)
11 tc(ACLKRX) Cycle time, ACLKR/X ACLKR/X int 35 ns
12 tw(ACLKRX) Pulse duration, ACLKR/X high or low ACLKR/X int A – 2.5 (5) ns
ACLKR/X int -0.5 10 ns
Delay time, ACLKR/X transmit edge to AFSX/R output
13 td(ACLKRX-AFSRX) ACLKR/X ext input 2 19 ns
valid (6)
ACLKR/X ext output 2 19 ns
ACLKR/X int -0.5 10 ns
14 td(ACLKX-AXRV) Delay time, ACLKX transmit edge to AXR output valid ACLKR/X ext input 2 19 ns
ACLKR/X ext output 2 19 ns
Disable time, ACLKR/X transmit edge to AXR high ACLKR/X int 0 10 ns
15 tdis(ACLKX-AXRHZ)
impedance following last data bit ACLKR/X ext 2 19 ns
(1) McASP0 ACLKX0 internal – ACLKXCTL.CLKXM = 1, PDIR.ACLKX = 1
ACLKX0 external input – McASP0 ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 0
ACLKX0 external output – McASP0ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 1
ACLKR0 internal – McASP0 ACLKR0CTL.CLKRM = 1, PDIR.ACLKR =1
ACLKR0 external input – McASP0 ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 0
ACLKR0 external output – McASP0 ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 1
(2) AH = (AHCLKR/X period)/2 in ns. For example, when AHCLKR/X period is 25 ns, use AH = 12.5 ns.
(3) P = SYSCLK2 period
(4) This timing is limited by the timing shown or 2P, whichever is greater.
(5) A = (ACLKR/X period)/2 in ns. For example, when AHCLKR/X period is 25 ns, use AH = 12.5 ns.
(6) McASP0 ACLKXCTL.ASYNC=1: Receiver is clocked by its own ACLKR0

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2
1 2
AHCLKR/X (Falling Edge Polarity)

AHCLKR/X (Rising Edge Polarity)

4
3 4
ACLKR/X (CLKRP = CLKXP = 0)(A)

ACLKR/X (CLKRP = CLKXP = 1)(B)

6
5
AFSR/X (Bit Width, 0 Bit Delay)

AFSR/X (Bit Width, 1 Bit Delay)

AFSR/X (Bit Width, 2 Bit Delay)

AFSR/X (Slot Width, 0 Bit Delay)

AFSR/X (Slot Width, 1 Bit Delay)

AFSR/X (Slot Width, 2 Bit Delay)

8
7
AXR[n] (Data In/Receive)

A0 A1 A30 A31 B0 B1 B30 B31 C0 C1 C2 C3 C31


A. For CLKRP = CLKXP = 0, the McASP transmitter is configured for rising edge (to shift data out) and the McASP
receiver is configured for falling edge (to shift data in).
B. For CLKRP = CLKXP = 1, the McASP transmitter is configured for falling edge (to shift data out) and the McASP
receiver is configured for rising edge (to shift data in).

Figure 6-29. McASP Input Timings

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10
9 10

AHCLKR/X (Falling Edge Polarity)

AHCLKR/X (Rising Edge Polarity)

12
11
12
ACLKR/X (CLKRP = CLKXP = 1)(A)

ACLKR/X (CLKRP = CLKXP = 0)(B)


13
13
13 13

AFSR/X (Bit Width, 0 Bit Delay)

AFSR/X (Bit Width, 1 Bit Delay)

AFSR/X (Bit Width, 2 Bit Delay)

13 13
13
AFSR/X (Slot Width, 0 Bit Delay)

AFSR/X (Slot Width, 1 Bit Delay)

AFSR/X (Slot Width, 2 Bit Delay) 14


15

AXR[n] (Data Out/Transmit)


A0 A1 A30 A31 B0 B1 B30 B31 C0 C1 C2 C3 C31
A. For CLKRP = CLKXP = 1, the McASP transmitter is configured for falling edge (to shift data out) and the McASP
receiver is configured for rising edge (to shift data in).
B. For CLKRP = CLKXP = 0, the McASP transmitter is configured for rising edge (to shift data out) and the McASP
receiver is configured for falling edge (to shift data in).

Figure 6-30. McASP Output Timings

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6.15 Multichannel Buffered Serial Port (McBSP)


The McBSP provides these functions:
• Full-duplex communication
• Double-buffered data registers, which allow a continuous data stream
• Independent framing and clocking for receive and transmit
• Direct interface to industry-standard codecs, analog interface chips (AICs), and other serially
connected analog-to-digital (A/D) and digital-to-analog (D/A) devices
• External shift clock or an internal, programmable frequency shift clock for data transfer
• Transmit & Receive FIFO Buffers allow the McBSP to operate at a higher sample rate by making it
more tolerant to DMA latency
If internal clock source is used, the CLKGDV field of the Sample Rate Generator Register (SRGR) must
always be set to a value of 1 or greater.

6.15.1 McBSP Peripheral Register Description(s)


Table 6-49. McBSP/FIFO Registers
McBSP0 McBSP1
ACRONYM REGISTER DESCRIPTION
BYTE ADDRESS BYTE ADDRESS
McBSP Registers
0x01D1 0000 0x01D1 1000 DRR McBSP Data Receive Register (read-only)
0x01D1 0004 0x01D1 1004 DXR McBSP Data Transmit Register
0x01D1 0008 0x01D1 1008 SPCR McBSP Serial Port Control Register
0x01D1 000C 0x01D1 100C RCR McBSP Receive Control Register
0x01D1 0010 0x01D1 1010 XCR McBSP Transmit Control Register
0x01D1 0014 0x01D1 1014 SRGR McBSP Sample Rate Generator register
0x01D1 0018 0x01D1 1018 MCR McBSP Multichannel Control Register
0x01D1 001C 0x01D1 101C RCERE0 McBSP Enhanced Receive Channel Enable Register 0 Partition A/B
0x01D1 0020 0x01D1 1020 XCERE0 McBSP Enhanced Transmit Channel Enable Register 0 Partition A/B
0x01D1 0024 0x01D1 1024 PCR McBSP Pin Control Register
0x01D1 0028 0x01D1 1028 RCERE1 McBSP Enhanced Receive Channel Enable Register 1 Partition C/D
0x01D1 002C 0x01D1 102C XCERE1 McBSP Enhanced Transmit Channel Enable Register 1 Partition C/D
0x01D1 0030 0x01D1 1030 RCERE2 McBSP Enhanced Receive Channel Enable Register 2 Partition E/F
0x01D1 0034 0x01D1 1034 XCERE2 McBSP Enhanced Transmit Channel Enable Register 2 Partition E/F
0x01D1 0038 0x01D1 1038 RCERE3 McBSP Enhanced Receive Channel Enable Register 3 Partition G/H
0x01D1 003C 0x01D1 103C XCERE3 McBSP Enhanced Transmit Channel Enable Register 3 Partition G/H
McBSP FIFO Control and Status Registers
0x01D1 0800 0x01D1 1800 BFIFOREV BFIFO Revision Identification Register
0x01D1 0810 0x01D1 1810 WFIFOCTL Write FIFO Control Register
0x01D1 0814 0x01D1 1814 WFIFOSTS Write FIFO Status Register
0x01D1 0818 0x01D1 1818 RFIFOCTL Read FIFO Control Register
0x01D1 081C 0x01D1 181C RFIFOSTS Read FIFO Status Register
McBSP FIFO Data Registers
0x01F1 0000 0x01F1 1000 RBUF McBSP FIFO Receive Buffer
0x01F1 0000 0x01F1 1000 XBUF McBSP FIFO Transmit Buffer

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6.15.2 McBSP Electrical Data/Timing


The following assume testing over recommended operating conditions.

6.15.2.1 Multichannel Buffered Serial Port (McBSP) Timing

Table 6-50. Timing Requirements for McBSP0 [1.3V, 1.2V, 1.1V] (1) (see Figure 6-31)
1.3V, 1.2V 1.1V
NO. UNIT
MIN MAX MIN MAX
2 tc(CKRX) Cycle time, CLKR/X CLKR/X ext 2P or 20 (2) (3) 2P or 25 (2) (3) ns
3 tw(CKRX) Pulse duration, CLKR/X high or CLKR/X low CLKR/X ext P - 1 (4) P - 1 (4) ns
Setup time, external FSR high before CLKR CLKR int 14 15.5
5 tsu(FRH-CKRL) ns
low CLKR ext 4 5
CLKR int 6 6
6 th(CKRL-FRH) Hold time, external FSR high after CLKR low ns
CLKR ext 3 3
CLKR int 14 15.5
7 tsu(DRV-CKRL) Setup time, DR valid before CLKR low ns
CLKR ext 4 5
CLKR int 3 3
8 th(CKRL-DRV) Hold time, DR valid after CLKR low ns
CLKR ext 3 3
Setup time, external FSX high before CLKX CLKX int 14 15.5
10 tsu(FXH-CKXL) ns
low CLKX ext 4 5
CLKX int 6 6
11 th(CKXL-FXH) Hold time, external FSX high after CLKX low ns
CLKX ext 3 3
(1) CLKRP = CLKXP = FSRP = FSXP = 0. If polarity of any of the signals is inverted, then the timing references of that signal are also
inverted.
(2) P = ASYNC3 period in ns. For example, when the ASYNC clock domain is running at 100 MHz, use 10 ns.
(3) Use whichever value is greater. Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock
source. The minimum CLKR/X cycle times are based on internal logic speed; the maximum usable speed may be lower due to EDMA
limitations and AC timing requirements.
(4) This parameter applies to the maximum McBSP frequency. Operate serial clocks (CLKR/X) in the reasonable range of 40/60 duty cycle.

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Table 6-51. Timing Requirements for McBSP0 [1.0V] (1) (see Figure 6-31)
1.0V
NO. UNIT
MIN MAX
2 tc(CKRX) Cycle time, CLKR/X CLKR/X ext 2P or 26.6 (2) (3) ns
3 tw(CKRX) Pulse duration, CLKR/X high or CLKR/X low CLKR/X ext P - 1 (4) ns
CLKR int 20
5 tsu(FRH-CKRL) Setup time, external FSR high before CLKR low ns
CLKR ext 5
CLKR int 6
6 th(CKRL-FRH) Hold time, external FSR high after CLKR low ns
CLKR ext 3
CLKR int 20
7 tsu(DRV-CKRL) Setup time, DR valid before CLKR low ns
CLKR ext 5
CLKR int 3
8 th(CKRL-DRV) Hold time, DR valid after CLKR low ns
CLKR ext 3
CLKX int 20
10 tsu(FXH-CKXL) Setup time, external FSX high before CLKX low ns
CLKX ext 5
CLKX int 6
11 th(CKXL-FXH) Hold time, external FSX high after CLKX low ns
CLKX ext 3
(1) CLKRP = CLKXP = FSRP = FSXP = 0. If polarity of any of the signals is inverted, then the timing references of that signal are also
inverted.
(2) P = ASYNC3 period in ns. For example, when the ASYNC clock domain is running at 100 MHz, use 10 ns.
(3) Use whichever value is greater. Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock
source. The minimum CLKR/X cycle times are based on internal logic speed; the maximum usable speed may be lower due to EDMA
limitations and AC timing requirements.
(4) This parameter applies to the maximum McBSP frequency. Operate serial clocks (CLKR/X) in the reasonable range of 40/60 duty cycle.

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Table 6-52. Switching Characteristics for McBSP0 [1.3V, 1.2V, 1.1V] (1) (2)
(see Figure 6-31)
1.3V, 1.2V 1.1V
NO. PARAMETER UNIT
MIN MAX MIN MAX
td(CKSH- Delay time, CLKS high to CLKR/X high for internal
1 2 14.5 2 16 ns
CKRXH) CLKR/X generated from CLKS input
2 tc(CKRX) Cycle time, CLKR/X CLKR/X int 2P or 20 (3) (4) (5) 2P or 25 (3) (4) (5) ns
Pulse duration, CLKR/X high or
3 tw(CKRX) CLKR/X int C - 2 (6) C + 2 (6) C - 2 (6) C + 2 (6) ns
CLKR/X low

Delay time, CLKR high to internal FSR CLKR int -4 5.5 -4 5.5
4 td(CKRH-FRV) ns
valid CLKR ext 2 14.5 2 16

Delay time, CLKX high to internal FSX CLKX int -4 5.5 -4 5.5
9 td(CKXH-FXV) ns
valid CLKX ext 2 14.5 2 16

tdis(CKXH- Disable time, DX high impedance CLKX int -4 7.5 -5.5 7.5
12 ns
DXHZ) following last data bit from CLKX high CLKX ext -2 16 -22 16
CLKX int -4 + D1 (7) 5.5 + D2 (7) -4 + D1 (7) 5.5 + D2 (7)
13 td(CKXH-DXV) Delay time, CLKX high to DX valid (7) (7) (7)
ns
CLKX ext 2 + D1 14.5 + D2 2 + D1 16 + D2 (7)
Delay time, FSX high to DX valid FSX int -4 (8) 5 (8) -4 (8) 5 (8)
14 td(FXH-DXV) ONLY applies when in data ns
FSX ext -2 (8) 14.5 (8) -2 (8) 16 (8)
delay 0 (XDATDLY = 00b) mode

(1) CLKRP = CLKXP = FSRP = FSXP = 0. If polarity of any of the signals is inverted, then the timing references of that signal are also
inverted.
(2) Minimum delay times also represent minimum output hold times.
(3) Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock source. Minimum CLKR/X cycle times
are based on internal logic speed; the maximum usable speed may be lower due to EDMA limitations and AC timing requirements.
(4) P = ASYNC3 period in ns. For example, when the ASYNC clock domain is running at 100 MHz, use 10 ns.
(5) Use whichever value is greater.
(6) C = H or L
S = sample rate generator input clock = P if CLKSM = 1 (P = ASYNC period)
S = sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period)
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
H = (CLKGDV + 1)/2 * S if CLKGDV is odd
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
L = (CLKGDV + 1)/2 * S if CLKGDV is odd
CLKGDV should be set appropriately to ensure the McBSP bit rate does not exceed the maximum limit (see (4) above).
(7) Extra delay from CLKX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR.
if DXENA = 0, then D1 = D2 = 0
if DXENA = 1, then D1 = 6P, D2 = 12P
(8) Extra delay from FSX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR.
if DXENA = 0, then D1 = D2 = 0
if DXENA = 1, then D1 = 6P, D2 = 12P

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Table 6-53. Switching Characteristics for McBSP0 [1.0V] (1) (2)

(see Figure 6-31)


1.0V
NO. PARAMETER UNIT
MIN MAX
Delay time, CLKS high to CLKR/X high for internal CLKR/X
1 td(CKSH-CKRXH) 3 21.5 ns
generated from CLKS input
2 tc(CKRX) Cycle time, CLKR/X CLKR/X int 2P or 26.6 (3) (4) (5) ns
3 tw(CKRX) Pulse duration, CLKR/X high or CLKR/X low CLKR/X int C - 2 (6) C + 2 (6) ns
CLKR int -4 10
4 td(CKRH-FRV) Delay time, CLKR high to internal FSR valid ns
CLKR ext 2.5 21.5
CLKX int -4 10
9 td(CKXH-FXV) Delay time, CLKX high to internal FSX valid ns
CLKX ext 2.5 21.5
Disable time, DX high impedance following last data CLKX int -4 10
12 tdis(CKXH-DXHZ) ns
bit from CLKX high CLKX ext -2 21.5
CLKX int -4 + D1 (7) 10 + D2 (7)
13 td(CKXH-DXV) Delay time, CLKX high to DX valid (7)
ns
CLKX ext 2.5 + D1 21.5 + D2 (7)
Delay time, FSX high to DX valid FSX int -4 (8) 5 (8)
14 td(FXH-DXV) ONLY applies when in data ns
FSX ext -2 (8) 21.5 (8)
delay 0 (XDATDLY = 00b) mode
(1) CLKRP = CLKXP = FSRP = FSXP = 0. If polarity of any of the signals is inverted, then the timing references of that signal are also
inverted.
(2) Minimum delay times also represent minimum output hold times.
(3) Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock source. Minimum CLKR/X cycle times
are based on internal logic speed; the maximum usable speed may be lower due to EDMA limitations and AC timing requirements.
(4) P = ASYNC3 period in ns. For example, when the ASYNC clock domain is running at 100 MHz, use 10 ns.
(5) Use whichever value is greater.
(6) C = H or L
S = sample rate generator input clock = P if CLKSM = 1 (P = ASYNC period)
S = sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period)
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
H = (CLKGDV + 1)/2 * S if CLKGDV is odd
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
L = (CLKGDV + 1)/2 * S if CLKGDV is odd
CLKGDV should be set appropriately to ensure the McBSP bit rate does not exceed the maximum limit (see (4) above).
(7) Extra delay from CLKX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR.
if DXENA = 0, then D1 = D2 = 0
if DXENA = 1, then D1 = 6P, D2 = 12P
(8) Extra delay from FSX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR.
if DXENA = 0, then D1 = D2 = 0
if DXENA = 1, then D1 = 6P, D2 = 12P

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Table 6-54. Timing Requirements for McBSP1 [1.3V, 1.2V, 1.1V] (1) (see Figure 6-31)
1.3V, 1.2V 1.1V
NO. UNIT
MIN MAX MIN MAX
2 tc(CKRX) Cycle time, CLKR/X CLKR/X ext 2P or 20 (2) (3) 2P or 25 (2) (4)
ns
Pulse duration, CLKR/X high or (5) (6)
3 tw(CKRX) CLKR/X ext P-1 P-1 ns
CLKR/X low
Setup time, external FSR high before CLKR int 15 18
5 tsu(FRH-CKRL) ns
CLKR low CLKR ext 5 5
Hold time, external FSR high after CLKR int 6 6
6 th(CKRL-FRH) ns
CLKR low CLKR ext 3 3
CLKR int 15 18
7 tsu(DRV-CKRL) Setup time, DR valid before CLKR low ns
CLKR ext 5 5
CLKR int 3 3
8 th(CKRL-DRV) Hold time, DR valid after CLKR low ns
CLKR ext 3 3
Setup time, external FSX high before CLKX int 15 18
10 tsu(FXH-CKXL) ns
CLKX low CLKX ext 5 5
Hold time, external FSX high after CLKX int 6 6
11 th(CKXL-FXH) ns
CLKX low CLKX ext 3 3
(1) CLKRP = CLKXP = FSRP = FSXP = 0. If polarity of any of the signals is inverted, then the timing references of that signal are also
inverted.
(2) P = ASYNC3 period in ns. For example, when the ASYNC clock domain is running at 100 MHz, use 10 ns.
(3) Use whichever value is greater. Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock
source. The minimum CLKR/X cycle times are based on internal logic speed; the maximum usable speed may be lower due to EDMA
limitations and AC timing requirements.
(4) Use whichever value is greater. Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock
source. The minimum CLKR/X cycle times are based on internal logic speed; the maximum usable speed may be lower due to EDMA
limitations and AC timing requirements.
(5) This parameter applies to the maximum McBSP frequency. Operate serial clocks (CLKR/X) in the reasonable range of 40/60 duty cycle.
(6) This parameter applies to the maximum McBSP frequency. Operate serial clocks (CLKR/X) in the reasonable range of 40/60 duty cycle.

Table 6-55. Timing Requirements for McBSP1 [1.0V] (1) (see Figure 6-31)
1.0V
NO. UNIT
MIN MAX
2 tc(CKRX) Cycle time, CLKR/X CLKR/X ext 2P or 26.6 (2) (3) ns
3 tw(CKRX) Pulse duration, CLKR/X high or CLKR/X low CLKR/X ext P - 1 (4) ns
CLKR int 21
5 tsu(FRH-CKRL) Setup time, external FSR high before CLKR low ns
CLKR ext 10
CLKR int 6
6 th(CKRL-FRH) Hold time, external FSR high after CLKR low ns
CLKR ext 3
CLKR int 21
7 tsu(DRV-CKRL) Setup time, DR valid before CLKR low ns
CLKR ext 10
CLKR int 3
8 th(CKRL-DRV) Hold time, DR valid after CLKR low ns
CLKR ext 3
CLKX int 21
10 tsu(FXH-CKXL) Setup time, external FSX high before CLKX low ns
CLKX ext 10
CLKX int 6
11 th(CKXL-FXH) Hold time, external FSX high after CLKX low ns
CLKX ext 3
(1) CLKRP = CLKXP = FSRP = FSXP = 0. If polarity of any of the signals is inverted, then the timing references of that signal are also
inverted.
(2) P = ASYNC3 period in ns. For example, when the ASYNC clock domain is running at 100 MHz, use 10 ns.
(3) Use whichever value is greater. Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock
source. The minimum CLKR/X cycle times are based on internal logic speed; the maximum usable speed may be lower due to EDMA
limitations and AC timing requirements.
(4) This parameter applies to the maximum McBSP frequency. Operate serial clocks (CLKR/X) in the reasonable range of 40/60 duty cycle.

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Table 6-56. Switching Characteristics for McBSP1 [1.3V, 1.2V, 1.1V] (1) (2)

(see Figure 6-31)


1.3V, 1.2V 1.1V
NO. PARAMETER UNIT
MIN MAX MIN MAX
Delay time, CLKS high to CLKR/X high for internal
1 td(CKSH-CKRXH) 0.5 16.5 1.5 18 ns
CLKR/X generated from CLKS input
2 tc(CKRX) Cycle time, CLKR/X CLKR/X int 2P or 20 (3) (4) (5) 2P or 25 (3) (4) (5)
ns
Pulse duration, CLKR/X high or
3 tw(CKRX) CLKR/X int C - 2 (6) C + 2 (6) C - 2 (6) C + 2 (6) ns
CLKR/X low

Delay time, CLKR high to internal CLKR int -4 6.5 -4 13


4 td(CKRH-FRV) ns
FSR valid CLKR ext 1 16.5 1 18

Delay time, CLKX high to internal CLKX int -4 6.5 -4 13


9 td(CKXH-FXV) ns
FSX valid CLKX ext 1 16.5 1 18
Disable time, DX high impedance CLKX int -4 6.5 -4 13
12 tdis(CKXH-DXHZ) following last data bit from CLKX ns
high CLKX ext -2 16.5 -2 18

CLKX int -4 + D1 (7) 6.5 + D2 (7) -4 + D1 (7) 13 + D2 (7)


13 td(CKXH-DXV) Delay time, CLKX high to DX valid (7) (7) (7)
ns
CLKX ext 1 + D1 16.5 + D2 1 + D1 18 + D2 (7)
Delay time, FSX high to DX valid FSX int -4 (8) 6.5 (8) -4 (8) 13 (8)
14 td(FXH-DXV) ONLY applies when in data ns
FSX ext -2 (8) 16.5 (8) -2 (8) 18 (9)
delay 0 (XDATDLY = 00b) mode

(1) CLKRP = CLKXP = FSRP = FSXP = 0. If polarity of any of the signals is inverted, then the timing references of that signal are also
inverted.
(2) Minimum delay times also represent minimum output hold times.
(3) Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock source. Minimum CLKR/X cycle times
are based on internal logic speed; the maximum usable speed may be lower due to EDMA limitations and AC timing requirements.
(4) P = ASYNC3 period in ns. For example, when the ASYNC clock domain is running at 100 MHz, use 10 ns.
(5) Use whichever value is greater.
(6) C = H or L
S = sample rate generator input clock = P if CLKSM = 1 (P = ASYNC period)
S = sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period)
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
H = (CLKGDV + 1)/2 * S if CLKGDV is odd
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
L = (CLKGDV + 1)/2 * S if CLKGDV is odd
CLKGDV should be set appropriately to ensure the McBSP bit rate does not exceed the maximum limit (see (4) above).
(7) Extra delay from CLKX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR.
if DXENA = 0, then D1 = D2 = 0
if DXENA = 1, then D1 = 6P, D2 = 12P
(8) Extra delay from FSX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR.
if DXENA = 0, then D1 = D2 = 0
if DXENA = 1, then D1 = 6P, D2 = 12P
(9) Extra delay from FSX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR.
if DXENA = 0, then D1 = D2 = 0
if DXENA = 1, then D1 = 6P, D2 = 12P

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Table 6-57. Switching Characteristics for McBSP1 [1.0V] (1) (2)

(see Figure 6-31)


1.0V
NO. PARAMETER UNIT
MIN MAX
Delay time, CLKS high to CLKR/X high for internal CLKR/X
1 td(CKSH-CKRXH) 1.5 23 ns
generated from CLKS input
2 tc(CKRX) Cycle time, CLKR/X CLKR/X int 2P or 26.6 (3) (4) (5) ns
3 tw(CKRX) Pulse duration, CLKR/X high or CLKR/X low CLKR/X int C - 2 (6) C + 2 (6) ns
CLKR int -4 13
4 td(CKRH-FRV) Delay time, CLKR high to internal FSR valid ns
CLKR ext 2.5 23
CLKX int -4 13
9 td(CKXH-FXV) Delay time, CLKX high to internal FSX valid ns
CLKX ext 1 23
Disable time, DX high impedance following last data CLKX int -4 13
12 tdis(CKXH-DXHZ) ns
bit from CLKX high CLKX ext -2 23
CLKX int -4 + D1 (7) 13 + D2 (8)
13 td(CKXH-DXV) Delay time, CLKX high to DX valid (8)
ns
CLKX ext 1 + D1 23 + D2 (8)
Delay time, FSX high to DX valid FSX int -4 (9) 13 (9)
14 td(FXH-DXV) ONLY applies when in data ns
FSX ext -2 (9) 23 (9)
delay 0 (XDATDLY = 00b) mode
(1) CLKRP = CLKXP = FSRP = FSXP = 0. If polarity of any of the signals is inverted, then the timing references of that signal are also
inverted.
(2) Minimum delay times also represent minimum output hold times.
(3) Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock source. Minimum CLKR/X cycle times
are based on internal logic speed; the maximum usable speed may be lower due to EDMA limitations and AC timing requirements.
(4) P = ASYNC3 period in ns. For example, when the ASYNC clock domain is running at 100 MHz, use 10 ns.
(5) Use whichever value is greater.
(6) C = H or L
S = sample rate generator input clock = P if CLKSM = 1 (P = ASYNC period)
S = sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period)
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
H = (CLKGDV + 1)/2 * S if CLKGDV is odd
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
L = (CLKGDV + 1)/2 * S if CLKGDV is odd
CLKGDV should be set appropriately to ensure the McBSP bit rate does not exceed the maximum limit (see (4) above).
(7) Extra delay from CLKX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR.
if DXENA = 0, then D1 = D2 = 0
if DXENA = 1, then D1 = 6P, D2 = 12P
(8) Extra delay from CLKX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR.
if DXENA = 0, then D1 = D2 = 0
if DXENA = 1, then D1 = 6P, D2 = 12P
(9) Extra delay from FSX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR.
if DXENA = 0, then D1 = D2 = 0
if DXENA = 1, then D1 = 6P, D2 = 12P

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CLKS
1
2
3 3
CLKR
4 4
FSR (int)
5 6
FSR (ext)
7 8
DR Bit(n1) (n2) (n3)
2
3 3
CLKX

9
FSX (int)

11
10
FSX (ext)

FSX (XDATDLY=00b)

14 13 (A)
12 13 (A)
DX Bit 0 Bit(n1) (n2) (n3)
A. No. 13 applies to the first data bit only when XDATDLY ≠ 0.

Figure 6-31. McBSP Timing

Table 6-58. Timing Requirements for McBSP0 FSR When GSYNC = 1 (see Figure 6-32)
1.3V, 1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX
1 tsu(FRH-CKSH) Setup time, FSR high before CLKS high 4 4.5 5 ns
2 th(CKSH-FRH) Hold time, FSR high after CLKS high 4 4 4 ns

Table 6-59. Timing Requirements for McBSP1 FSR When GSYNC = 1 (see Figure 6-32)
1.3V, 1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX
1 tsu(FRH-CKSH) Setup time, FSR high before CLKS high 5 5 10 ns
2 th(CKSH-FRH) Hold time, FSR high after CLKS high 4 4 4 ns

CLKS
1
2
FSR external

CLKR/X (no need to resync)

CLKR/X (needs resync)

Figure 6-32. FSR Timing When GSYNC = 1

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6.16 Serial Peripheral Interface Ports (SPI0, SPI1)


Figure 6-33 is a block diagram of the SPI module, which is a simple shift register and buffer plus control
logic. Data is written to the shift register before transmission occurs and is read from the buffer at the end
of transmission. The SPI can operate either as a master, in which case, it initiates a transfer and drives
the SPIx_CLK pin, or as a slave. Four clock phase and polarity options are supported as well as many
data formatting options.

SPIx_SIMO
SPIx_SOMI

Peripheral
Configuration Bus 16-Bit Shift Register SPIx_ENA
State
GPIO SPIx_SCS
Machine
Control
Interrupt and 16-Bit Buffer (all pins) Clock SPIx_CLK
DMA Requests Control

Figure 6-33. Block Diagram of SPI Module

The SPI supports 3-, 4-, and 5-pin operation with three basic pins (SPIx_CLK, SPIx_SIMO, and
SPIx_SOMI) and two optional pins (SPIx_SCS, SPIx_ENA).
The optional SPIx_SCS (Slave Chip Select) pin is most useful to enable in slave mode when there are
other slave devices on the same SPI port. The device will only shift data and drive the SPIx_SOMI pin
when SPIx_SCS is held low.
In slave mode, SPIx_ENA is an optional output. The SPIx_ENA output provides the status of the internal
transmit buffer (SPIDAT0/1 registers). In four-pin mode with the enable option, SPIx_ENA is asserted only
when the transmit buffer is full, indicating that the slave is ready to begin another transfer. In five-pin
mode, the SPIx_ENA is additionally qualified by SPIx_SCS being asserted. This allows a single
handshake line to be shared by multiple slaves on the same SPI bus.
In master mode, the SPIx_ENA pin is an optional input and the master can be configured to delay the start
of the next transfer until the slave asserts SPIx_ENA. The addition of this handshake signal simplifies SPI
communications and, on average, increases SPI bus throughput since the master does not need to delay
each transfer long enough to allow for the worst-case latency of the slave device. Instead, each transfer
can begin as soon as both the master and slave have actually serviced the previous SPI transfer.

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Optional − Slave Chip Select

SPIx_SCS SPIx_SCS
Optional Enable (Ready)

SPIx_ENA SPIx_ENA

SPIx_CLK SPIx_CLK

SPIx_SOMI SPIx_SOMI

SPIx_SIMO SPIx_SIMO

MASTER SPI SLAVE SPI

Figure 6-34. Illustration of SPI Master-to-SPI Slave Connection

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6.16.1 SPI Peripheral Registers Description(s)


Table 6-60 is a list of the SPI registers.

Table 6-60. SPIx Configuration Registers


SPI0 SPI1
ACRONYM DESCRIPTION
BYTE ADDRESS BYTE ADDRESS
0x01C4 1000 0x01F0 E000 SPIGCR0 Global Control Register 0
0x01C4 1004 0x01F0 E004 SPIGCR1 Global Control Register 1
0x01C4 1008 0x01F0 E008 SPIINT0 Interrupt Register
0x01C4 100C 0x01F0 E00C SPILVL Interrupt Level Register
0x01C4 1010 0x01F0 E010 SPIFLG Flag Register
0x01C4 1014 0x01F0 E014 SPIPC0 Pin Control Register 0 (Pin Function)
0x01C4 1018 0x01F0 E018 SPIPC1 Pin Control Register 1 (Pin Direction)
0x01C4 101C 0x01F0 E01C SPIPC2 Pin Control Register 2 (Pin Data In)
0x01C4 1020 0x01F0 E020 SPIPC3 Pin Control Register 3 (Pin Data Out)
0x01C4 1024 0x01F0 E024 SPIPC4 Pin Control Register 4 (Pin Data Set)
0x01C4 1028 0x01F0 E028 SPIPC5 Pin Control Register 5 (Pin Data Clear)
0x01C4 102C 0x01F0 E02C Reserved Reserved - Do not write to this register
0x01C4 1030 0x01F0 E030 Reserved Reserved - Do not write to this register
0x01C4 1034 0x01F0 E034 Reserved Reserved - Do not write to this register
0x01C4 1038 0x01F0 E038 SPIDAT0 Shift Register 0 (without format select)
0x01C4 103C 0x01F0 E03C SPIDAT1 Shift Register 1 (with format select)
0x01C4 1040 0x01F0 E040 SPIBUF Buffer Register
0x01C4 1044 0x01F0 E044 SPIEMU Emulation Register
0x01C4 1048 0x01F0 E048 SPIDELAY Delay Register
0x01C4 104C 0x01F0 E04C SPIDEF Default Chip Select Register
0x01C4 1050 0x01F0 E050 SPIFMT0 Format Register 0
0x01C4 1054 0x01F0 E054 SPIFMT1 Format Register 1
0x01C4 1058 0x01F0 E058 SPIFMT2 Format Register 2
0x01C4 105C 0x01F0 E05C SPIFMT3 Format Register 3
0x01C4 1060 0x01F0 E060 INTVEC0 Interrupt Vector for SPI INT0
0x01C4 1064 0x01F0 E064 INTVEC1 Interrupt Vector for SPI INT1

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6.16.2 SPI Electrical Data/Timing

6.16.2.1 Serial Peripheral Interface (SPI) Timing


Table 6-61 through Table 6-76 assume testing over recommended operating conditions (see Figure 6-35
through Figure 6-38).

Table 6-61. General Timing Requirements for SPI0 Master Modes (1)
1.3V, 1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX
1 tc(SPC)M Cycle Time, SPI0_CLK, All Master Modes 20 (2) 256P 30 (2) 256P 40 (2) 256P ns
2 tw(SPCH)M Pulse Width High, SPI0_CLK, All Master Modes 0.5M-1 0.5M-1 0.5M-1 ns
3 tw(SPCL)M Pulse Width Low, SPI0_CLK, All Master Modes 0.5M-1 0.5M-1 0.5M-1 ns
Polarity = 0, Phase = 0,
5 5 6
to SPI0_CLK rising
Polarity = 0, Phase = 1,
Delay, initial data bit valid on -0.5M+5 -0.5M+5 -0.5M+6
to SPI0_CLK rising
4 td(SIMO_SPC)M SPI0_SIMO after initial edge ns
on SPI0_CLK (3) Polarity = 1, Phase = 0,
5 5 6
to SPI0_CLK falling
Polarity = 1, Phase = 1,
-0.5M+5 -0.5M+5 -0.5M+6
to SPI0_CLK falling
Polarity = 0, Phase = 0,
5 5 6
from SPI0_CLK rising
Polarity = 0, Phase = 1,
Delay, subsequent bits valid 5 5 6
from SPI0_CLK falling
5 td(SPC_SIMO)M on SPI0_SIMO after transmit ns
edge of SPI0_CLK Polarity = 1, Phase = 0,
5 5 6
from SPI0_CLK falling
Polarity = 1, Phase = 1,
5 5 6
from SPI0_CLK rising
Polarity = 0, Phase = 0,
0.5M-3 0.5M-3 0.5M-3
from SPI0_CLK falling
Polarity = 0, Phase = 1,
Output hold time, SPI0_SIMO 0.5M-3 0.5M-3 0.5M-3
from SPI0_CLK rising
6 toh(SPC_SIMO)M valid after receive edge of ns
SPI0_CLK Polarity = 1, Phase = 0,
0.5M-3 0.5M-3 0.5M-3
from SPI0_CLK rising
Polarity = 1, Phase = 1,
0.5M-3 0.5M-3 0.5M-3
from SPI0_CLK falling
Polarity = 0, Phase = 0,
1.5 1.5 1.5
to SPI0_CLK falling
Polarity = 0, Phase = 1,
Input Setup Time, SPI0_SOMI 1.5 1.5 1.5
to SPI0_CLK rising
7 tsu(SOMI_SPC)M valid before receive edge of ns
SPI0_CLK Polarity = 1, Phase = 0,
1.5 1.5 1.5
to SPI0_CLK rising
Polarity = 1, Phase = 1,
1.5 1.5 1.5
to SPI0_CLK falling
Polarity = 0, Phase = 0,
4 4 5
from SPI0_CLK falling
Polarity = 0, Phase = 1,
Input Hold Time, SPI0_SOMI 4 4 5
from SPI0_CLK rising
8 tih(SPC_SOMI)M valid after receive edge of ns
SPI0_CLK Polarity = 1, Phase = 0,
4 4 5
from SPI0_CLK rising
Polarity = 1, Phase = 1,
4 4 5
from SPI0_CLK falling

(1) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)


(2) This timing is limited by the timing shown or 3P, whichever is greater.
(3) First bit may be MSB or LSB depending upon SPI configuration. MO(0) refers to first bit and MO(n) refers to last bit output on
SPI0_SIMO. MI(0) refers to the first bit input and MI(n) refers to the last bit input on SPI0_SOMI.

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Table 6-62. General Timing Requirements for SPI0 Slave Modes (1)
1.3V, 1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX
9 tc(SPC)S Cycle Time, SPI0_CLK, All Slave Modes 40 (2) 50 (2) 60 (2) ns
10 tw(SPCH)S Pulse Width High, SPI0_CLK, All Slave Modes 18 22 27 ns
11 tw(SPCL)S Pulse Width Low, SPI0_CLK, All Slave Modes 18 22 27 ns
Polarity = 0, Phase = 0,
2P 2P 2P
to SPI0_CLK rising
Setup time, transmit data Polarity = 0, Phase = 1,
2P 2P 2P
written to SPI before initial to SPI0_CLK rising
12 tsu(SOMI_SPC)S ns
clock edge from Polarity = 1, Phase = 0,
master. (3) (4) 2P 2P 2P
to SPI0_CLK falling
Polarity = 1, Phase = 1,
2P 2P 2P
to SPI0_CLK falling
Polarity = 0, Phase = 0,
17 20 27
from SPI0_CLK rising
Polarity = 0, Phase = 1,
Delay, subsequent bits valid from SPI0_CLK falling 17 20 27
13 td(SPC_SOMI)S on SPI0_SOMI after ns
transmit edge of SPI0_CLK Polarity = 1, Phase = 0, 17 20 27
from SPI0_CLK falling
Polarity = 1, Phase = 1,
17 20 27
from SPI0_CLK rising
Polarity = 0, Phase = 0,
0.5S-6 0.5S-16 0.5S-20
from SPI0_CLK falling
Polarity = 0, Phase = 1,
Output hold time, 0.5S-6 0.5S-16 0.5S-20
from SPI0_CLK rising
14 toh(SPC_SOMI)S SPI0_SOMI valid after ns
receive edge of SPI0_CLK Polarity = 1, Phase = 0,
0.5S-6 0.5S-16 0.5S-20
from SPI0_CLK rising
Polarity = 1, Phase = 1,
0.5S-6 0.5S-16 0.5S-20
from SPI0_CLK falling
Polarity = 0, Phase = 0,
1.5 1.5 1.5
to SPI0_CLK falling
Polarity = 0, Phase = 1,
Input Setup Time, 1.5 1.5 1.5
to SPI0_CLK rising
15 tsu(SIMO_SPC)S SPI0_SIMO valid before ns
receive edge of SPI0_CLK Polarity = 1, Phase = 0,
1.5 1.5 1.5
to SPI0_CLK rising
Polarity = 1, Phase = 1,
1.5 1.5 1.5
to SPI0_CLK falling
Polarity = 0, Phase = 0,
4 4 5
from SPI0_CLK falling
Polarity = 0, Phase = 1,
Input Hold Time, 4 4 5
from SPI0_CLK rising
16 tih(SPC_SIMO)S SPI0_SIMO valid after ns
receive edge of SPI0_CLK Polarity = 1, Phase = 0,
4 4 5
from SPI0_CLK rising
Polarity = 1, Phase = 1,
4 4 5
from SPI0_CLK falling
(1) P = SYSCLK2 period; S = tc(SPC)S (SPI slave bit clock period)
(2) This timing is limited by the timing shown or 3P, whichever is greater.
(3) First bit may be MSB or LSB depending upon SPI configuration. SO(0) refers to first bit and SO(n) refers to last bit output on
SPI0_SOMI. SI(0) refers to the first bit input and SI(n) refers to the last bit input on SPI0_SIMO.
(4) Measured from the termination of the write of new data to the SPI module, In analyzing throughput requirements, additional internal bus
cycles must be accounted for to allow data to be written to the SPI module by the CPU.

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(1) (2) (3)


Table 6-63. Additional SPI0 Master Timings, 4-Pin Enable Option
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
3P+5 3P+5 3P+6
to SPI0_CLK rising
Polarity = 0, Phase = 1,
0.5M+3P+5 0.5M+3P+5 0.5M+3P+6
Delay from slave assertion of SPI0_ENA to SPI0_CLK rising
17 td(ENA_SPC)M ns
active to first SPI0_CLK from master. (4) Polarity = 1, Phase = 0,
3P+5 3P+5 3P+6
to SPI0_CLK falling
Polarity = 1, Phase = 1,
0.5M+3P+5 0.5M+3P+5 0.5M+3P+6
to SPI0_CLK falling
Polarity = 0, Phase = 0,
0.5M+P+5 0.5M+P+5 0.5M+P+6
from SPI0_CLK falling
Polarity = 0, Phase = 1,
Max delay for slave to deassert SPI0_ENA P+5 P+5 P+6
from SPI0_CLK falling
18 td(SPC_ENA)M after final SPI0_CLK edge to ensure ns
master does not begin the next transfer. (5) Polarity = 1, Phase = 0,
0.5M+P+5 0.5M+P+5 0.5M+P+6
from SPI0_CLK rising
Polarity = 1, Phase = 1,
P+5 P+5 P+6
from SPI0_CLK rising
(1) These parameters are in addition to the general timings for SPI master modes (Table 6-61).
(2) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)
(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four master clocking modes.
(4) In the case where the master SPI is ready with new data before SPI0_ENA assertion.
(5) In the case where the master SPI is ready with new data before SPI0_EN A deassertion.

(1) (2) (3)


Table 6-64. Additional SPI0 Master Timings, 4-Pin Chip Select Option
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
2P-1 2P-2 2P-3
to SPI0_CLK rising
Polarity = 0, Phase = 1,
0.5M+2P-1 0.5M+2P-2 0.5M+2P-3
Delay from SPI0_SCS active to first to SPI0_CLK rising
19 td(SCS_SPC)M ns
SPI0_CLK (4) (5) Polarity = 1, Phase = 0,
2P-1 2P-2 2P-3
to SPI0_CLK falling
Polarity = 1, Phase = 1,
0.5M+2P-1 0.5M+2P-2 0.5M+2P-3
to SPI0_CLK falling

(1) These parameters are in addition to the general timings for SPI master modes (Table 6-61).
(2) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)
(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four master clocking modes.
(4) In the case where the master SPI is ready with new data before SPI0_SCS assertion.
(5) This delay can be increased under software control by the register bit field SPIDELAY.C2TDELAY[4:0].

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(1)(2)(3)
Table 6-64. Additional SPI0 Master Timings, 4-Pin Chip Select Option (continued)
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
0.5M+P-1 0.5M+P-2 0.5M+P-3
from SPI0_CLK falling
Polarity = 0, Phase = 1,
P-1 P-2 P-3
Delay from final SPI0_CLK edge to master from SPI0_CLK falling
20 td(SPC_SCS)M ns
deasserting SPI0_SCS (6) (7) Polarity = 1, Phase = 0,
0.5M+P-1 0.5M+P-2 0.5M+P-3
from SPI0_CLK rising
Polarity = 1, Phase = 1,
P-1 P-2 P-3
from SPI0_CLK rising
(6) Except for modes when SPIDAT1.CSHOLD is enabled and there is additional data to transmit. In this case, SPI0_SCS will remain asserted.
(7) This delay can be increased under software control by the register bit field SPIDELAY.T2CDELAY[4:0].

(1) (2) (3)


Table 6-65. Additional SPI0 Master Timings, 5-Pin Option
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
0.5M+P+5 0.5M+P+5 0.5M+P+6
from SPI0_CLK falling
Max delay for slave to deassert Polarity = 0, Phase = 1,
P+5 P+5 P+6
SPI0_ENA after final SPI0_CLK from SPI0_CLK falling
18 td(SPC_ENA)M ns
edge to ensure master does not Polarity = 1, Phase = 0,
begin the next transfer. (4) 0.5M+P+5 0.5M+P+5 0.5M+P+6
from SPI0_CLK rising
Polarity = 1, Phase = 1,
P+5 P+5 P+6
from SPI0_CLK rising
Polarity = 0, Phase = 0,
0.5M+P-2 0.5M+P-2 0.5M+P-3
from SPI0_CLK falling
Polarity = 0, Phase = 1,
Delay from final SPI0_CLK edge to from SPI0_CLK falling P-2 P-2 P-3
(5)
20 td(SPC_SCS)M master deasserting SPI0_SCS ns
(6) Polarity = 1, Phase = 0,
0.5M+P-2 0.5M+P-2 0.5M+P-3
from SPI0_CLK rising
Polarity = 1, Phase = 1,
P-2 P-2 P-3
from SPI0_CLK rising
Max delay for slave SPI to drive SPI0_ENA valid after master
21 td(SCSL_ENAL)M asserts SPI0_SCS to delay the master from beginning the C2TDELAY+P C2TDELAY+P C2TDELAY+P ns
next transfer,

(1) These parameters are in addition to the general timings for SPI master modes (Table 6-62).
(2) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)
(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four master clocking modes.
(4) In the case where the master SPI is ready with new data before SPI0_ENA deassertion.
(5) Except for modes when SPIDAT1.CSHOLD is enabled and there is additional data to transmit. In this case, SPI0_SCS will remain asserted.
(6) This delay can be increased under software control by the register bit field SPIDELAY.T2CDELAY[4:0].

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(1)(2)(3)
Table 6-65. Additional SPI0 Master Timings, 5-Pin Option (continued)
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
2P-2 2P-2 2P-3
to SPI0_CLK rising
Polarity = 0, Phase = 1,
0.5M+2P-2 0.5M+2P-2 0.5M+2P-3
Delay from SPI0_SCS active to to SPI0_CLK rising
22 td(SCS_SPC)M ns
first SPI0_CLK (7) (8) (9) Polarity = 1, Phase = 0,
2P-2 2P-2 2P-3
to SPI0_CLK falling
Polarity = 1, Phase = 1,
0.5M+2P-2 0.5M+2P-2 0.5M+2P-3
to SPI0_CLK falling
Polarity = 0, Phase = 0,
3P+5 3P+5 3P+6
to SPI0_CLK rising
Polarity = 0, Phase = 1,
0.5M+3P+5 0.5M+3P+5 0.5M+3P+6
Delay from assertion of SPI0_ENA to SPI0_CLK rising
23 td(ENA_SPC)M ns
low to first SPI0_CLK edge. (10) Polarity = 1, Phase = 0,
3P+5 3P+5 3P+6
to SPI0_CLK falling
Polarity = 1, Phase = 1,
0.5M+3P+5 0.5M+3P+5 0.5M+3P+6
to SPI0_CLK falling
(7) If SPI0_ENA is asserted immediately such that the transmission is not delayed by SPI0_ENA.
(8) In the case where the master SPI is ready with new data before SPI0_SCS assertion.
(9) This delay can be increased under software control by the register bit field SPIDELAY.C2TDELAY[4:0].
(10) If SPI0_ENA was initially deasserted high and SPI0_CLK is delayed.

(1) (2) (3)


Table 6-66. Additional SPI0 Slave Timings, 4-Pin Enable Option
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
1.5P-3 2.5P+17.5 1.5P-3 2.5P+20 1.5P-3 2.5P+27
from SPI0_CLK falling
Polarity = 0, Phase = 1,
– 0.5M+1.5P-3 – 0.5M+2.5P+17.5 – 0.5M+1.5P-3 – 0.5M+2.5P+20 – 0.5M+1.5P-3 – 0.5M+2.5P+27
Delay from final SPI0_CLK edge from SPI0_CLK falling
24 td(SPC_ENAH)S ns
to slave deasserting SPI0_ENA. Polarity = 1, Phase = 0,
1.5P-3 2.5P+17.5 1.5P-3 2.5P+20 1.5P-3 2.5P+27
from SPI0_CLK rising
Polarity = 1, Phase = 1,
– 0.5M+1.5P-3 – 0.5+2.5P+17.5 – 0.5M+1.5P-3 – 0.5+2.5P+20 – 0.5M+1.5P-3 – 0.5+2.5P+27
from SPI0_CLK rising

(1) These parameters are in addition to the general timings for SPI slave modes (Table 6-62).
(2) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)
(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four slave clocking modes.

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(1) (2) (3)


Table 6-67. Additional SPI0 Slave Timings, 4-Pin Chip Select Option
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Required delay from SPI0_SCS asserted at slave to first SPI0_CLK edge
25 td(SCSL_SPC)S P + 1.5 P + 1.5 P + 1.5 ns
at slave.
Polarity = 0, Phase = 0,
0.5M+P+4 0.5M+P+4 0.5M+P+5
from SPI0_CLK falling
Polarity = 0, Phase = 1,
P+4 P+4 P+5
Required delay from final SPI0_CLK edge from SPI0_CLK falling
26 td(SPC_SCSH)S ns
before SPI0_SCS is deasserted. Polarity = 1, Phase = 0,
0.5M+P+4 0.5M+P+4 0.5M+P+5
from SPI0_CLK rising
Polarity = 1, Phase = 1,
P+4 P+4 P+5
from SPI0_CLK rising
27 tena(SCSL_SOMI)S Delay from master asserting SPI0_SCS to slave driving SPI0_SOMI valid P+17.5 P+20 P+27 ns
28 tdis(SCSH_SOMI)S Delay from master deasserting SPI0_SCS to slave 3-stating SPI0_SOMI P+17.5 P+20 P+27 ns
(1) These parameters are in addition to the general timings for SPI slave modes (Table 6-62).
(2) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)
(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four slave clocking modes.

(1) (2) (3)


Table 6-68. Additional SPI0 Slave Timings, 5-Pin Option
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Required delay from SPI0_SCS asserted at slave to first
25 td(SCSL_SPC)S P + 1.5 P + 1.5 P + 1.5 ns
SPI0_CLK edge at slave.
Polarity = 0, Phase = 0,
0.5M+P+4 0.5M+P+4 0.5M+P+5
from SPI0_CLK falling
Polarity = 0, Phase = 1,
Required delay from final P+4 P+4 P+5
from SPI0_CLK falling
26 td(SPC_SCSH)S SPI0_CLK edge before SPI0_SCS ns
is deasserted. Polarity = 1, Phase = 0,
0.5M+P+4 0.5M+P+4 0.5M+P+5
from SPI0_CLK rising
Polarity = 1, Phase = 1,
P+4 P+4 P+5
from SPI0_CLK rising
Delay from master asserting SPI0_SCS to slave driving
27 tena(SCSL_SOMI)S P+17.5 P+20 P+27 ns
SPI0_SOMI valid
Delay from master deasserting SPI0_SCS to slave 3-stating
28 tdis(SCSH_SOMI)S P+17.5 P+20 P+27 ns
SPI0_SOMI
Delay from master deasserting SPI0_SCS to slave driving
29 tena(SCSL_ENA)S 17.5 20 27 ns
SPI0_ENA valid

(1) These parameters are in addition to the general timings for SPI slave modes (Table 6-62).
(2) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)
(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four slave clocking modes.

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(1)(2)(3)
Table 6-68. Additional SPI0 Slave Timings, 5-Pin Option (continued)
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
2.5P+17.5 2.5P+20 2.5P+27
from SPI0_CLK falling
Delay from final clock receive Polarity = 0, Phase = 1,
2.5P+17.5 2.5P+20 2.5P+27
edge on SPI0_CLK to slave 3- from SPI0_CLK rising
30 tdis(SPC_ENA)S ns
stating or driving high Polarity = 1, Phase = 0,
SPI0_ENA. (4) 2.5P+17.5 2.5P+20 2.5P+27
from SPI0_CLK rising
Polarity = 1, Phase = 1,
2.5P+17.5 2.5P+20 2.5P+27
from SPI0_CLK falling
(4) SPI0_ENA is driven low after the transmission completes if the SPIINT0.ENABLE_HIGHZ bit is programmed to 0. Otherwise it is tri-stated. If tri-stated, an external pullup resistor should
be used to provide a valid level to the master. This option is useful when tying several SPI slave devices to a single master.

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Table 6-69. General Timing Requirements for SPI1 Master Modes (1)
1.3V, 1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX
1 tc(SPC)M Cycle Time, SPI1_CLK, All Master Modes 20 (2) 256P 30 (2) 256P 40 (2) 256P ns
2 tw(SPCH)M Pulse Width High, SPI1_CLK, All Master Modes 0.5M-1 0.5M-1 0.5M-1 ns
3 tw(SPCL)M Pulse Width Low, SPI1_CLK, All Master Modes 0.5M-1 0.5M-1 0.5M-1 ns
Polarity = 0, Phase = 0,
5 5 6
to SPI1_CLK rising
Polarity = 0, Phase = 1,
Delay, initial data bit valid on -0.5M+5 -0.5M+5 -0.5M+6
to SPI1_CLK rising
4 td(SIMO_SPC)M SPI1_SIMO to initial edge on ns
SPI1_CLK (3) Polarity = 1, Phase = 0,
5 5 6
to SPI1_CLK falling
Polarity = 1, Phase = 1,
-0.5M+5 -0.5M+5 -0.5M+6
to SPI1_CLK falling
Polarity = 0, Phase = 0,
5 5 6
from SPI1_CLK rising
Polarity = 0, Phase = 1,
Delay, subsequent bits valid on from SPI1_CLK falling 5 5 6
5 td(SPC_SIMO)M SPI1_SIMO after transmit edge ns
of SPI1_CLK Polarity = 1, Phase = 0,
5 5 6
from SPI1_CLK falling
Polarity = 1, Phase = 1,
5 5 6
from SPI1_CLK rising
Polarity = 0, Phase = 0,
0.5M-3 0.5M-3 0.5M-3
from SPI1_CLK falling
Polarity = 0, Phase = 1,
Output hold time, SPI1_SIMO 0.5M-3 0.5M-3 0.5M-3
from SPI1_CLK rising
6 toh(SPC_SIMO)M valid after receive edge of ns
SPI1_CLK Polarity = 1, Phase = 0,
0.5M-3 0.5M-3 0.5M-3
from SPI1_CLK rising
Polarity = 1, Phase = 1,
0.5M-3 0.5M-3 0.5M-3
from SPI1_CLK falling
Polarity = 0, Phase = 0,
1.5 1.5 1.5
to SPI1_CLK falling
Polarity = 0, Phase = 1,
Input Setup Time, SPI1_SOMI 1.5 1.5 1.5
to SPI1_CLK rising
7 tsu(SOMI_SPC)M valid before receive edge of ns
SPI1_CLK Polarity = 1, Phase = 0,
1.5 1.5 1.5
to SPI1_CLK rising
Polarity = 1, Phase = 1,
1.5 1.5 1.5
to SPI1_CLK falling
Polarity = 0, Phase = 0,
4 5 6
from SPI1_CLK falling
Polarity = 0, Phase = 1,
Input Hold Time, SPI1_SOMI 4 5 6
from SPI1_CLK rising
8 tih(SPC_SOMI)M valid after receive edge of ns
SPI1_CLK Polarity = 1, Phase = 0,
4 5 6
from SPI1_CLK rising
Polarity = 1, Phase = 1,
4 5 6
from SPI1_CLK falling

(1) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)


(2) This timing is limited by the timing shown or 3P, whichever is greater.
(3) First bit may be MSB or LSB depending upon SPI configuration. MO(0) refers to first bit and MO(n) refers to last bit output on
SPI1_SIMO. MI(0) refers to the first bit input and MI(n) refers to the last bit input on SPI1_SOMI.

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Table 6-70. General Timing Requirements for SPI1 Slave Modes (1)
1.3V, 1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX
9 tc(SPC)S Cycle Time, SPI1_CLK, All Slave Modes 40 (2) 50 (2) 60 (2) ns
10 tw(SPCH)S Pulse Width High, SPI1_CLK, All Slave Modes 18 22 27 ns
11 tw(SPCL)S Pulse Width Low, SPI1_CLK, All Slave Modes 18 22 27 ns
Polarity = 0, Phase = 0,
2P 2P 2P
to SPI1_CLK rising
Setup time, transmit data Polarity = 0, Phase = 1,
2P 2P 2P
written to SPI before initial to SPI1_CLK rising
12 tsu(SOMI_SPC)S ns
clock edge from Polarity = 1, Phase = 0,
master. (3) (4) 2P 2P 2P
to SPI1_CLK falling
Polarity = 1, Phase = 1,
2P 2P 2P
to SPI1_CLK falling
Polarity = 0, Phase = 0,
15 17 19
from SPI1_CLK rising
Polarity = 0, Phase = 1,
Delay, subsequent bits valid 15 17 19
from SPI1_CLK falling
13 td(SPC_SOMI)S on SPI1_SOMI after transmit ns
edge of SPI1_CLK Polarity = 1, Phase = 0,
15 17 19
from SPI1_CLK falling
Polarity = 1, Phase = 1,
15 17 19
from SPI1_CLK rising
Polarity = 0, Phase = 0,
0.5S-4 0.5S-10 0.5S-12
from SPI1_CLK falling
Polarity = 0, Phase = 1,
Output hold time, SPI1_SOMI 0.5S-4 0.5S-10 0.5S-12
from SPI1_CLK rising
14 toh(SPC_SOMI)S valid after receive edge of ns
SPI1_CLK Polarity = 1, Phase = 0,
0.5S-4 0.5S-10 0.5S-12
from SPI1_CLK rising
Polarity = 1, Phase = 1,
0.5S-4 0.5S-10 0.5S-12
from SPI1_CLK falling
Polarity = 0, Phase = 0,
1.5 1.5 1.5
to SPI1_CLK falling
Polarity = 0, Phase = 1,
Input Setup Time, SPI1_SIMO to SPI1_CLK rising 1.5 1.5 1.5
15 tsu(SIMO_SPC)S valid before receive edge of ns
SPI1_CLK Polarity = 1, Phase = 0,
1.5 1.5 1.5
to SPI1_CLK rising
Polarity = 1, Phase = 1,
1.5 1.5 1.5
to SPI1_CLK falling
Polarity = 0, Phase = 0,
4 5 6
from SPI1_CLK falling
Polarity = 0, Phase = 1,
Input Hold Time, SPI1_SIMO 4 5 6
from SPI1_CLK rising
16 tih(SPC_SIMO)S valid after receive edge of ns
SPI1_CLK Polarity = 1, Phase = 0,
4 5 6
from SPI1_CLK rising
Polarity = 1, Phase = 1,
4 5 6
from SPI1_CLK falling
(1) P = SYSCLK2 period; S = tc(SPC)S (SPI slave bit clock period)
(2) This timing is limited by the timing shown or 3P, whichever is greater.
(3) First bit may be MSB or LSB depending upon SPI configuration. SO(0) refers to first bit and SO(n) refers to last bit output on
SPI1_SOMI. SI(0) refers to the first bit input and SI(n) refers to the last bit input on SPI1_SIMO.
(4) Measured from the termination of the write of new data to the SPI module, In analyzing throughput requirements, additional internal bus
cycles must be accounted for to allow data to be written to the SPI module by the CPU.

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Table 6-71. Additional (1) SPI1 Master Timings, 4-Pin Enable Option (2) (3)
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
3P+5 3P+5 3P+6
to SPI1_CLK rising
Delay from slave Polarity = 0, Phase = 1,
assertion of 0.5M+3P+5 0.5M+3P+5 0.5M+3P+6
to SPI1_CLK rising
17 td(EN A_SPC)M SPI1_ENA active to ns
first SPI1_CLK from Polarity = 1, Phase = 0,
3P+5 3P+5 3P+6
master. (4) to SPI1_CLK falling
Polarity = 1, Phase = 1,
0.5M+3P+5 0.5M+3P+5 0.5M+3P+6
to SPI1_CLK falling
Polarity = 0, Phase = 0,
0.5M+P+5 0.5M+P+5 0.5M+P+6
from SPI1_CLK falling
Max delay for slave to
deassert SPI1_ENA Polarity = 0, Phase = 1,
P+5 P+5 P+6
after final SPI1_CLK from SPI1_CLK falling
18 td(SPC_ENA)M ns
edge to ensure Polarity = 1, Phase = 0,
master does not begin 0.5M+P+5 0.5M+P+5 0.5M+P+6
from SPI1_CLK rising
the next transfer. (5)
Polarity = 1, Phase = 1,
P+5 P+5 P+6
from SPI1_CLK rising
(1) These parameters are in addition to the general timings for SPI master modes (Table 6-69).
(2) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)
(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four master clocking modes.
(4) In the case where the master SPI is ready with new data before SPI1_ENA assertion.
(5) In the case where the master SPI is ready with new data before SPI1_ENA deassertion.

Table 6-72. Additional (1) SPI1 Master Timings, 4-Pin Chip Select Option (2) (3)

1.3V, 1.2V 1.1V 1.0V


NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
2P-1 2P-5 2P-6
to SPI1_CLK rising
Delay from Polarity = 0, Phase = 1,
0.5M+2P-1 0.5M+2P-5 0.5M+2P-6
SPI1_SCS active to SPI1_CLK rising
19 td(SCS_SPC)M ns
to first Polarity = 1, Phase = 0,
SPI1_CLK (4) (5) 2P-1 2P-5 2P-6
to SPI1_CLK falling
Polarity = 1, Phase = 1,
0.5M+2P-1 0.5M+2P-5 0.5M+2P-6
to SPI1_CLK falling
Polarity = 0, Phase = 0,
0.5M+P-1 0.5M+P-5 0.5M+P-6
from SPI1_CLK falling
Delay from final Polarity = 0, Phase = 1,
SPI1_CLK edge to P-1 P-5 P-6
from SPI1_CLK falling
20 td(SPC_SCS)M master ns
deasserting Polarity = 1, Phase = 0,
0.5M+P-1 0.5M+P-5 0.5M+P-6
SPI1_SCS (6) (7) from SPI1_CLK rising
Polarity = 1, Phase = 1,
P-1 P-5 P-6
from SPI1_CLK rising
(1) These parameters are in addition to the general timings for SPI master modes (Table 6-69).
(2) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)
(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four master clocking modes.
(4) In the case where the master SPI is ready with new data before SPI1_SCS assertion.
(5) This delay can be increased under software control by the register bit field SPIDELAY.C2TDELAY[4:0].
(6) Except for modes when SPIDAT1.CSHOLD is enabled and there is additional data to transmit. In this case, SPI1_SCS will remain
asserted.
(7) This delay can be increased under software control by the register bit field SPIDELAY.T2CDELAY[4:0].

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Table 6-73. Additional (1) SPI1 Master Timings, 5-Pin Option (2) (3)
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
0.5M+P+5 0.5M+P+5 0.5M+P+6
from SPI1_CLK falling
Max delay for slave to deassert Polarity = 0, Phase = 1,
P+5 P+5 P+6
SPI1_ENA after final SPI1_CLK from SPI1_CLK falling
18 td(SPC_ENA)M ns
edge to ensure master does not Polarity = 1, Phase = 0,
begin the next transfer. (4) 0.5M+P+5 0.5M+P+5 0.5M+P+6
from SPI1_CLK rising
Polarity = 1, Phase = 1,
P+5 P+5 P+6
from SPI1_CLK rising
Polarity = 0, Phase = 0,
0.5M+P-1 0.5M+P-5 0.5M+P-6
from SPI1_CLK falling
Polarity = 0, Phase = 1,
P-1 P-5 P-6
Delay from final SPI1_CLK edge to from SPI1_CLK falling
20 td(SPC_SCS)M ns
master deasserting SPI1_SCS (5) (6) Polarity = 1, Phase = 0,
0.5M+P-1 0.5M+P-5 0.5M+P-6
from SPI1_CLK rising
Polarity = 1, Phase = 1,
P-1 P-5 P-6
from SPI1_CLK rising
Max delay for slave SPI to drive SPI1_ENA valid after master
21 td(SCSL_ENAL)M asserts SPI1_SCS to delay the C2TDELAY+P C2TDELAY+P C2TDELAY+P ns
master from beginning the next transfer,
Polarity = 0, Phase = 0,
2P-1 2P-5 2P-6
to SPI1_CLK rising
Polarity = 0, Phase = 1,
0.5M+2P-1 0.5M+2P-5 0.5M+2P-6
Delay from SPI1_SCS active to first to SPI1_CLK rising
22 td(SCS_SPC)M ns
SPI1_CLK (7) (8) (9) Polarity = 1, Phase = 0,
2P-1 2P-5 2P-6
to SPI1_CLK falling
Polarity = 1, Phase = 1,
0.5M+2P-1 0.5M+2P-5 0.5M+2P-6
to SPI1_CLK falling

(1) These parameters are in addition to the general timings for SPI master modes (Table 6-70).
(2) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)
(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four master clocking modes.
(4) In the case where the master SPI is ready with new data before SPI1_ENA deassertion.
(5) Except for modes when SPIDAT1.CSHOLD is enabled and there is additional data to transmit. In this case, SPI1_SCS will remain asserted.
(6) This delay can be increased under software control by the register bit field SPIDELAY.T2CDELAY[4:0].
(7) If SPI1_ENA is asserted immediately such that the transmission is not delayed by SPI1_ENA.
(8) In the case where the master SPI is ready with new data before SPI1_SCS assertion.
(9) This delay can be increased under software control by the register bit field SPIDELAY.C2TDELAY[4:0].

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Table 6-73. Additional(1) SPI1 Master Timings, 5-Pin Option(2)(3) (continued)


1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
3P+5 3P+5 3P+6
to SPI1_CLK rising
Polarity = 0, Phase = 1,
0.5M+3P+5 0.5M+3P+5 0.5M+3P+6
Delay from assertion of SPI1_ENA to SPI1_CLK rising
23 td(ENA_SPC)M ns
low to first SPI1_CLK edge. (10) Polarity = 1, Phase = 0,
3P+5 3P+5 3P+6
to SPI1_CLK falling
Polarity = 1, Phase = 1,
0.5M+3P+5 0.5M+3P+5 0.5M+3P+6
to SPI1_CLK falling
(10) If SPI1_ENA was initially deasserted high and SPI1_CLK is delayed.

Table 6-74. Additional (1) SPI1 Slave Timings, 4-Pin Enable Option (2) (3)
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
1.5P-3 2.5P+15 1.5P-10 2.5P+17 1.5P-12 2.5P+19
from SPI1_CLK falling
Polarity = 0, Phase = 1,
–0.5M+1.5P-3 –0.5M+2.5P+15 –0.5M+1.5P-10 –0.5M+2.5P+17 –0.5M+1.5P-12 –0.5M+2.5P+19
Delay from final SPI1_CLK edge to from SPI1_CLK falling
24 td(SPC_ENAH)S ns
slave deasserting SPI1_ENA. Polarity = 1, Phase = 0,
1.5P-3 2.5P+15 1.5P-10 2.5P+17 1.5P-12 2.5P+19
from SPI1_CLK rising
Polarity = 1, Phase = 1,
–0.5M+1.5P-3 –0.5M+2.5P+15 –0.5M+1.5P-10 –0.5M+2.5P+17 –0.5M+1.5P-12 –0.5M+2.5P+19
from SPI1_CLK rising

(1) These parameters are in addition to the general timings for SPI slave modes (Table 6-70).
(2) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)
(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four slave clocking modes.

Table 6-75. Additional (1) SPI1 Slave Timings, 4-Pin Chip Select Option (2) (3)
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Required delay from SPI1_SCS asserted at slave to first SPI1_CLK edge at
25 td(SCSL_SPC)S P+1.5 P+1.5 P+1.5 ns
slave.

(1) These parameters are in addition to the general timings for SPI slave modes (Table 6-70).
(2) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)
(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four slave clocking modes.

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Table 6-75. Additional(1) SPI1 Slave Timings, 4-Pin Chip Select Option(2)(3) (continued)
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Polarity = 0, Phase = 0,
0.5M+P+4 0.5M+P+5 0.5M+P+6
from SPI1_CLK falling
Polarity = 0, Phase = 1,
P+4 P+5 P+6
Required delay from final SPI1_CLK edge from SPI1_CLK falling
26 td(SPC_SCSH)S ns
before SPI1_SCS is deasserted. Polarity = 1, Phase = 0,
0.5M+P+4 0.5M+P+5 0.5M+P+6
from SPI1_CLK rising
Polarity = 1, Phase = 1,
P+4 P+5 P+6
from SPI1_CLK rising
27 tena(SCSL_SOMI)S Delay from master asserting SPI1_SCS to slave driving SPI1_SOMI valid P+15 P+17 P+19 ns
28 tdis(SCSH_SOMI)S Delay from master deasserting SPI1_SCS to slave 3-stating SPI1_SOMI P+15 P+17 P+19 ns

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Table 6-76. Additional (1) SPI1 Slave Timings, 5-Pin Option (2) (3)
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
Required delay from SPI1_SCS asserted at slave to
25 td(SCSL_SPC)S P+1.5 P+1.5 P+1.5 ns
first SPI1_CLK edge at slave.
Polarity = 0, Phase = 0,
0.5M+P+4 0.5M+P+5 0.5M+P+6
from SPI1_CLK falling
Polarity = 0, Phase = 1,
Required delay from final P+4 P+5 P+6
from SPI1_CLK falling
26 td(SPC_SCSH)S SPI1_CLK edge before ns
SPI1_SCS is deasserted. Polarity = 1, Phase = 0,
0.5M+P+4 0.5M+P+5 0.5M+P+6
from SPI1_CLK rising
Polarity = 1, Phase = 1,
P+4 P+5 P+6
from SPI1_CLK rising
tena(SCSL_SOMI) Delay from master asserting SPI1_SCS to slave
27 P+15 P+17 P+19 ns
S driving SPI1_SOMI valid
Delay from master deasserting SPI1_SCS to slave 3-
28 tdis(SCSH_SOMI)S P+15 P+17 P+19 ns
stating SPI1_SOMI
Delay from master deasserting SPI1_SCS to slave
29 tena(SCSL_ENA)S 15 17 19 ns
driving SPI1_ENA valid
Polarity = 0, Phase = 0,
2.5P+15 2.5P+17 2.5P+19
from SPI1_CLK falling

Delay from final clock Polarity = 0, Phase = 1,


2.5P+15 2.5P+17 2.5P+19
receive edge on SPI1_CLK from SPI1_CLK rising
30 tdis(SPC_ENA)S ns
to slave 3-stating or driving Polarity = 1, Phase = 0,
high SPI1_ENA. (4) 2.5P+15 2.5P+17 2.5P+19
from SPI1_CLK rising
Polarity = 1, Phase = 1,
2.5P+15 2.5P+17 2.5P+19
from SPI1_CLK falling

(1) These parameters are in addition to the general timings for SPI slave modes (Table 6-70).
(2) P = SYSCLK2 period; M = tc(SPC)M (SPI master bit clock period)
(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four slave clocking modes.
(4) SPI1_ENA is driven low after the transmission completes if the SPIINT0.ENABLE_HIGHZ bit is programmed to 0. Otherwise it is tri-
stated. If tri-stated, an external pullup resistor should be used to provide a valid level to the master. This option is useful when tying
several SPI slave devices to a single master.

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1 MASTER MODE
POLARITY = 0 PHASE = 0
2 3
SPIx_CLK

4 5 6
SPIx_SIMO MO(0) MO(1) MO(n−1) MO(n)

7 8
SPIx_SOMI MI(0) MI(1) MI(n−1) MI(n)

MASTER MODE
4 POLARITY = 0 PHASE = 1

SPIx_CLK

5 6
SPIx_SIMO MO(0) MO(1) MO(n−1) MO(n)

7 8
SPIx_SOMI MI(0) MI(1) MI(n−1) MI(n)

4 MASTER MODE
POLARITY = 1 PHASE = 0

SPIx_CLK

5 6
SPIx_SIMO MO(0) MO(1) MO(n−1) MO(n)

7 8
SPIx_SOMI MI(0) MI(1) MI(n−1) MI(n)

MASTER MODE
POLARITY = 1 PHASE = 1

SPIx_CLK

4 5 6
SPIx_SIMO MO(0) MO(1) MO(n−1) MO(n)

7 8
SPIx_SOMI MI(0) MI(1) MI(n−1) MI(n)

Figure 6-35. SPI Timings—Master Mode

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9 SLAVE MODE
POLARITY = 0 PHASE = 0
12 10 11
SPIx_CLK

15 16
SPIx_SIMO SI(0) SI(1) SI(n−1) SI(n)
13 14
SPIx_SOMI SO(0) SO(1) SO(n−1) SO(n)

12 SLAVE MODE
POLARITY = 0 PHASE = 1

SPIx_CLK

15 16
SPIx_SIMO SI(0) SI(1) SI(n−1) SI(n)

13 14
SPIx_SOMI SO(0) SO(1) SO(n−1) SO(n)

12 SLAVE MODE
POLARITY = 1 PHASE = 0

SPIx_CLK

15 16
SPIx_SIMO SI(0) SI(1) SI(n−1) SI(n)

13 14
SPIx_SOMI SO(0) SO(1) SO(n−1) SO(n)

SLAVE MODE
12
POLARITY = 1 PHASE = 1

SPIx_CLK

15 16
SPIx_SIMO SI(0) SI(1) SI(n−1) SI(n)

13 14
SPIx_SOMI SO(0) SO(1) SO(n−1) SO(n)

Figure 6-36. SPI Timings—Slave Mode

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MASTER MODE 4 PIN WITH ENABLE


17 18
SPIx_CLK

SPIx_SIMO MO(0) MO(1) MO(n−1) MO(n)


SPIx_SOMI MI(0) MI(1) MI(n−1) MI(n)
SPIx_ENA

MASTER MODE 4 PIN WITH CHIP SELECT


19 20
SPIx_CLK

SPIx_SIMO MO(0) MO(1) MO(n−1) MO(n)


SPIx_SOMI MI(0) MI(1) MI(n−1) MI(n)
SPIx_SCS

22 MASTER MODE 5 PIN 20


MO(1)
23 18
SPIx_CLK

SPIx_SIMO MO(0) MO(n−1) MO(n)


SPIx_SOMI

21 MI(0) MI(1) MI(n−1) MI(n)

SPIx_ENA DESEL(A) DESEL(A)


SPIx_SCS

A. DESELECTED IS PROGRAMMABLE EITHER HIGH OR


3−STATE (REQUIRES EXTERNAL PULLUP)

Figure 6-37. SPI Timings—Master Mode (4-Pin and 5-Pin)

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SLAVE MODE 4 PIN WITH ENABLE


24
SPIx_CLK

SPIx_SOMI SO(0) SO(1) SO(n−1) SO(n)


SPIx_SIMO

SPIx_ENA SI(0) SI(1) SI(n−1) SI(n)

SLAVE MODE 4 PIN WITH CHIP SELECT

25 26
SPIx_CLK

27 SO(n−1) 28

SPIx_SOMI SO(0) SO(1) SO(n)


SPIx_SIMO

SPIx_SCS SI(0) SI(1) SI(n−1) SI(n)

SLAVE MODE 5 PIN


26

25 30
SPIx_CLK

27 SO(1) 28
SPIx_SOMI SO(0) SO(n−1) SO(n)
SPIx_SIMO

29 SI(0) SI(1) SI(n−1) SI(n)


SPIx_ENA
DESEL(A) DESEL(A)
SPIx_SCS

A. DESELECTED IS PROGRAMMABLE EITHER HIGH OR


3−STATE (REQUIRES EXTERNAL PULLUP)

Figure 6-38. SPI Timings—Slave Mode (4-Pin and 5-Pin)

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6.17 Inter-Integrated Circuit Serial Ports (I2C)

6.17.1 I2C Device-Specific Information


Each I2C port supports:
• Compatible with Philips® I2C Specification Revision 2.1 (January 2000)
• Fast Mode up to 400 Kbps (no fail-safe I/O buffers)
• Noise Filter to Remove Noise 50 ns or less
• Seven- and Ten-Bit Device Addressing Modes
• Master (Transmit/Receive) and Slave (Transmit/Receive) Functionality
• Events: DMA, Interrupt, or Polling
• General-Purpose I/O Capability if not used as I2C
Figure 6-39 is block diagram of the device I2C Module.

Clock Prescaler Control


Prescaler Own Address
I2CPSCx I2CCOARx
Register Register

Slave Address
I2CSARx
Bit Clock Generator Register
Noise
I2Cx_SCL Clock Divide
Filter I2CCLKHx I2CCMDRx Mode Register
High Register

Clock Divide Extended Mode


I2CCLKLx I2CEMDRx
Low Register Register
Data Count Peripheral
I2CCNTx
Register Configuration
Transmit Bus
Transmit Shift Peripheral ID
I2CXSRx I2CPID1
Register Register 1
Peripheral ID
I2CPID2 Register 2
I2CDXRx Transmit Buffer

I2Cx_SDA Noise Interrupt/DMA


Filter Receive Interrupt Enable
I2CIERx Interrupt DMA
Register
I2CDRRx Receive Buffer Requests
Interrupt Status
I2CSTRx
Register
Receive Shift Interrupt Source
I2CRSRx Register I2CSRCx
Register

Control
Pin Function Pin Data Out
I2CPFUNC I2CPDOUT
Register Register
Pin Direction Pin Data Set
I2CPDIR I2CPDSET
Register Register
Pin Data In Pin Data Clear
I2CPDIN I2CPDCLR
Register Register

Figure 6-39. I2C Module Block Diagram

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6.17.2 I2C Peripheral Registers Description(s)


Table 6-77 is the list of the I2C registers.

Table 6-77. Inter-Integrated Circuit (I2C) Registers


I2C0 I2C1
ACRONYM REGISTER DESCRIPTION
BYTE ADDRESS BYTE ADDRESS
0x01C2 2000 0x01E2 8000 ICOAR I2C Own Address Register
0x01C2 2004 0x01E2 8004 ICIMR I2C Interrupt Mask Register
0x01C2 2008 0x01E2 8008 ICSTR I2C Interrupt Status Register
0x01C2 200C 0x01E2 800C ICCLKL I2C Clock Low-Time Divider Register
0x01C2 2010 0x01E2 8010 ICCLKH I2C Clock High-Time Divider Register
0x01C2 2014 0x01E2 8014 ICCNT I2C Data Count Register
0x01C2 2018 0x01E2 8018 ICDRR I2C Data Receive Register
0x01C2 201C 0x01E2 801C ICSAR I2C Slave Address Register
0x01C2 2020 0x01E2 8020 ICDXR I2C Data Transmit Register
0x01C2 2024 0x01E2 8024 ICMDR I2C Mode Register
0x01C2 2028 0x01E2 8028 ICIVR I2C Interrupt Vector Register
0x01C2 202C 0x01E2 802C ICEMDR I2C Extended Mode Register
0x01C2 2030 0x01E2 8030 ICPSC I2C Prescaler Register
0x01C2 2034 0x01E2 8034 REVID1 I2C Revision Identification Register 1
0x01C2 2038 0x01E2 8038 REVID2 I2C Revision Identification Register 2
0x01C2 2048 0x01E2 8048 ICPFUNC I2C Pin Function Register
0x01C2 204C 0x01E2 804C ICPDIR I2C Pin Direction Register
0x01C2 2050 0x01E2 8050 ICPDIN I2C Pin Data In Register
0x01C2 2054 0x01E2 8054 ICPDOUT I2C Pin Data Out Register
0x01C2 2058 0x01E2 8058 ICPDSET I2C Pin Data Set Register
0x01C2 205C 0x01E2 805C ICPDCLR I2C Pin Data Clear Register

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6.17.3 I2C Electrical Data/Timing

6.17.3.1 Inter-Integrated Circuit (I2C) Timing


Table 6-78 and Table 6-79 assume testing over recommended operating conditions (see Figure 6-40 and
Figure 6-41).

Table 6-78. Timing Requirements for I2C Input


1.3V, 1.2V, 1.1V, 1.0V
NO. Standard Mode Fast Mode UNIT
MIN MAX MIN MAX
1 tc(SCL) Cycle time, I2Cx_SCL 10 2.5 μs
2 tsu(SCLH-SDAL) Setup time, I2Cx_SCL high before I2Cx_SDA low 4.7 0.6 μs
3 th(SCLL-SDAL) Hold time, I2Cx_SCL low after I2Cx_SDA low 4 0.6 μs
4 tw(SCLL) Pulse duration, I2Cx_SCL low 4.7 1.3 μs
5 tw(SCLH) Pulse duration, I2Cx_SCL high 4 0.6 μs
6 tsu(SDA-SCLH) Setup time, I2Cx_SDA before I2Cx_SCL high 250 100 ns
7 th(SDA-SCLL) Hold time, I2Cx_SDA after I2Cx_SCL low 0 0 0.9 μs
8 tw(SDAH) Pulse duration, I2Cx_SDA high 4.7 1.3 μs
9 tr(SDA) Rise time, I2Cx_SDA 1000 20 + 0.1Cb 300 ns
10 tr(SCL) Rise time, I2Cx_SCL 1000 20 + 0.1Cb 300 ns
11 tf(SDA) Fall time, I2Cx_SDA 300 20 + 0.1Cb 300 ns
12 tf(SCL) Fall time, I2Cx_SCL 300 20 + 0.1Cb 300 ns
13 tsu(SCLH-SDAH) Setup time, I2Cx_SCL high before I2Cx_SDA high 4 0.6 μs
14 tw(SP) Pulse duration, spike (must be suppressed) N/A 0 50 ns
15 Cb Capacitive load for each bus line 400 400 pF

(1)
Table 6-79. Switching Characteristics for I2C
1.3V, 1.2V, 1.1V, 1.0V
NO. PARAMETER Standard Mode Fast Mode UNIT
MIN MAX MIN MAX
16 tc(SCL) Cycle time, I2Cx_SCL 10 2.5 μs
17 tsu(SCLH-SDAL) Setup time, I2Cx_SCL high before I2Cx_SDA low 4.7 0.6 μs
18 th(SDAL-SCLL) Hold time, I2Cx_SCL low after I2Cx_SDA low 4 0.6 μs
19 tw(SCLL) Pulse duration, I2Cx_SCL low 4.7 1.3 μs
20 tw(SCLH) Pulse duration, I2Cx_SCL high 4 0.6 μs
21 tsu(SDAV-SCLH) Setup time, I2Cx_SDA valid before I2Cx_SCL high 250 100 ns
22 th(SCLL-SDAV) Hold time, I2Cx_SDA valid after I2Cx_SCL low 0 0 0.9 μs
23 tw(SDAH) Pulse duration, I2Cx_SDA high 4.7 1.3 μs
28 tsu(SCLH-SDAH) Setup time, I2Cx_SCL high before I2Cx_SDA high 4 0.6 μs
(1) I2C must be configured correctly to meet the timings in Table 6-79.

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11 9

I2Cx_SDA

8 6 14
4
13
10 5

I2Cx_SCL

1 12 3
7 2
3

Stop Start Repeated Stop


Start

Figure 6-40. I2C Receive Timings

26 24

I2Cx_SDA

23 21
19
28
25 20

I2Cx_SCL

16 27 18
22 17
18

Stop Start Repeated Stop


Start

Figure 6-41. I2C Transmit Timings

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6.18 Universal Asynchronous Receiver/Transmitter (UART)


Each UART has the following features:
• 16-byte storage space for both the transmitter and receiver FIFOs
• 1, 4, 8, or 14 byte selectable receiver FIFO trigger level for autoflow control and DMA
• DMA signaling capability for both received and transmitted data
• Programmable auto-rts and auto-cts for autoflow control
• Programmable Baud Rate up to 12 MBaud
• Programmable Oversampling Options of x13 and x16
• Frequency pre-scale values from 1 to 65,535 to generate appropriate baud rates
• Prioritized interrupts
• Programmable serial data formats
– 5, 6, 7, or 8-bit characters
– Even, odd, or no parity bit generation and detection
– 1, 1.5, or 2 stop bit generation
• False start bit detection
• Line break generation and detection
• Internal diagnostic capabilities
– Loopback controls for communications link fault isolation
– Break, parity, overrun, and framing error simulation
• Modem control functions (CTS, RTS)
The UART registers are listed in Section 6.18.1

6.18.1 UART Peripheral Registers Description(s)


Table 6-80 is the list of UART registers.

Table 6-80. UART Registers


UART0 UART1 UART2
ACRONYM REGISTER DESCRIPTION
BYTE ADDRESS BYTE ADDRESS BYTE ADDRESS
0x01C4 2000 0x01D0 C000 0x01D0 D000 RBR Receiver Buffer Register (read only)
0x01C4 2000 0x01D0 C000 0x01D0 D000 THR Transmitter Holding Register (write only)
0x01C4 2004 0x01D0 C004 0x01D0 D004 IER Interrupt Enable Register
0x01C4 2008 0x01D0 C008 0x01D0 D008 IIR Interrupt Identification Register (read only)
0x01C4 2008 0x01D0 C008 0x01D0 D008 FCR FIFO Control Register (write only)
0x01C4 200C 0x01D0 C00C 0x01D0 D00C LCR Line Control Register
0x01C4 2010 0x01D0 C010 0x01D0 D010 MCR Modem Control Register
0x01C4 2014 0x01D0 C014 0x01D0 D014 LSR Line Status Register
0x01C4 2018 0x01D0 C018 0x01D0 D018 MSR Modem Status Register
0x01C4 201C 0x01D0 C01C 0x01D0 D01C SCR Scratchpad Register
0x01C4 2020 0x01D0 C020 0x01D0 D020 DLL Divisor LSB Latch
0x01C4 2024 0x01D0 C024 0x01D0 D024 DLH Divisor MSB Latch
0x01C4 2028 0x01D0 C028 0x01D0 D028 REVID1 Revision Identification Register 1
0x01C4 2030 0x01D0 C030 0x01D0 D030 PWREMU_MGMT Power and Emulation Management Register
0x01C4 2034 0x01D0 C034 0x01D0 D034 MDR Mode Definition Register

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6.18.2 UART Electrical Data/Timing

Table 6-81. Timing Requirements for UART Receive (1) (see Figure 6-42)
1.3V, 1.2V, 1.1V, 1.0V
NO. UNIT
MIN MAX
4 tw(URXDB) Pulse duration, receive data bit (RXDn) 0.96U 1.05U ns
5 tw(URXSB) Pulse duration, receive start bit 0.96U 1.05U ns
(1) U = UART baud time = 1/programmed baud rate.

Table 6-82. Switching Characteristics Over Recommended Operating Conditions for UARTx Transmit (1)
(see Figure 6-42)
1.3V, 1.2V, 1.1V, 1.0V
NO. PARAMETER UNIT
MIN MAX
(2) (3) (4)
1 f(baud) Maximum programmable baud rate D/E MBaud
2 tw(UTXDB) Pulse duration, transmit data bit (TXDn) U-2 U+2 ns
3 tw(UTXSB) Pulse duration, transmit start bit U-2 U+2 ns
(1) U = UART baud time = 1/programmed baud rate.
(2) D = UART input clock in MHz.
For UART0, the UART input clock is SYSCLK2.
For UART1 or UART2, the UART input clock is ASYNC3 (either PLL0_SYCLK2 or PLL1_SYSCLK2).
(3) E = UART divisor x UART sampling rate. The UART divisor is set through the UART divisor latch registers (DLL and DLH). The UART
sampling rate is set through the over-sampling mode select bit (OSM_SEL) of the UART mode definition register (MDR).
(4) Baud rate is not indicative of data rate. Actual data rate will be limited by system factors such as EDMA loading, EMIF/DDR loading,
system frequency, etc.

2
Start
UART_TXDn Bit
Data Bits

5
4

Start
UART_RXDn Bit
Data Bits

Figure 6-42. UART Transmit/Receive Timing

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6.19 Universal Serial Bus OTG Controller (USB0) [USB2.0 OTG]


The USB2.0 peripheral supports the following features:
• USB 2.0 peripheral at speeds high speed (HS: 480 Mb/s) and full speed (FS: 12 Mb/s)
• USB 2.0 host at speeds HS, FS, and low speed (LS: 1.5 Mb/s)
• All transfer modes (control, bulk, interrupt, and isochronous)
• 4 Transmit (TX) and 4 Receive (RX) endpoints in addition to endpoint 0
• FIFO RAM
– 4K endpoint
– Programmable size
• Integrated USB 2.0 High Speed PHY
• Connects to a standard Charge Pump for VBUS 5 V generation
• RNDIS mode for accelerating RNDIS type protocols using short packet termination over USB
Important Notice: The USB0 controller module clock (PLL0_SYSCLK2) must be greater than 30 MHz for
proper operation of the USB controller. A clock rate of 60 MHz or greater is recommended to avoid data
throughput reduction.
Table 6-83 is the list of USB OTG registers.

6.19.1 USB Peripheral Registers Description(s)


Table 6-83 is the list of the USB0 registers.

Table 6-83. Universal Serial Bus OTG (USB0) Registers


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01E0 0000 REVID Revision Register
0x01E0 0004 CTRLR Control Register
0x01E0 0008 STATR Status Register
0x01E0 000C EMUR Emulation Register
0x01E0 0010 MODE Mode Register
0x01E0 0014 AUTOREQ Autorequest Register
0x01E0 0018 SRPFIXTIME SRP Fix Time Register
0x01E0 001C TEARDOWN Teardown Register
0x01E0 0020 INTSRCR USB Interrupt Source Register
0x01E0 0024 INTSETR USB Interrupt Source Set Register
0x01E0 0028 INTCLRR USB Interrupt Source Clear Register
0x01E0 002C INTMSKR USB Interrupt Mask Register
0x01E0 0030 INTMSKSETR USB Interrupt Mask Set Register
0x01E0 0034 INTMSKCLRR USB Interrupt Mask Clear Register
0x01E0 0038 INTMASKEDR USB Interrupt Source Masked Register
0x01E0 003C EOIR USB End of Interrupt Register
0x01E0 0040 - Reserved
0x01E0 0050 GENRNDISSZ1 Generic RNDIS Size EP1
0x01E0 0054 GENRNDISSZ2 Generic RNDIS Size EP2
0x01E0 0058 GENRNDISSZ3 Generic RNDIS Size EP3
0x01E0 005C GENRNDISSZ4 Generic RNDIS Size EP4
0x01E0 0400 FADDR Function Address Register
0x01E0 0401 POWER Power Management Register
0x01E0 0402 INTRTX Interrupt Register for Endpoint 0 plus Transmit Endpoints 1 to 4
0x01E0 0404 INTRRX Interrupt Register for Receive Endpoints 1 to 4
0x01E0 0406 INTRTXE Interrupt enable register for INTRTX

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Table 6-83. Universal Serial Bus OTG (USB0) Registers (continued)


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01E0 0408 INTRRXE Interrupt Enable Register for INTRRX
0x01E0 040A INTRUSB Interrupt Register for Common USB Interrupts
0x01E0 040B INTRUSBE Interrupt Enable Register for INTRUSB
0x01E0 040C FRAME Frame Number Register
0x01E0 040E INDEX Index Register for Selecting the Endpoint Status and Control Registers
0x01E0 040F TESTMODE Register to Enable the USB 2.0 Test Modes
Indexed Registers
These registers operate on the endpoint selected by the INDEX register
0x01E0 0410 TXMAXP Maximum Packet Size for Peripheral/Host Transmit Endpoint (Index register set to select
Endpoints 1-4 only)
0x01E0 0412 PERI_CSR0 Control Status Register for Endpoint 0 in Peripheral Mode.
(Index register set to select Endpoint 0)
HOST_CSR0 Control Status Register for Endpoint 0 in Host Mode.
(Index register set to select Endpoint 0)
PERI_TXCSR Control Status Register for Peripheral Transmit Endpoint.
(Index register set to select Endpoints 1-4)
HOST_TXCSR Control Status Register for Host Transmit Endpoint.
(Index register set to select Endpoints 1-4)
0x01E0 0414 RXMAXP Maximum Packet Size for Peripheral/Host Receive Endpoint
(Index register set to select Endpoints 1-4 only)
0x01E0 0416 PERI_RXCSR Control Status Register for Peripheral Receive Endpoint.
(Index register set to select Endpoints 1-4)
HOST_RXCSR Control Status Register for Host Receive Endpoint.
(Index register set to select Endpoints 1-4)
0x01E0 0418 COUNT0 Number of Received Bytes in Endpoint 0 FIFO.
(Index register set to select Endpoint 0)
RXCOUNT Number of Bytes in Host Receive Endpoint FIFO.
(Index register set to select Endpoints 1- 4)
0x01E0 041A HOST_TYPE0 Defines the speed of Endpoint 0
HOST_TXTYPE Sets the operating speed, transaction protocol and peripheral endpoint number for the host
Transmit endpoint.
(Index register set to select Endpoints 1-4 only)
0x01E0 041B HOST_NAKLIMIT0 Sets the NAK response timeout on Endpoint 0.
(Index register set to select Endpoint 0)
HOST_TXINTERVAL Sets the polling interval for Interrupt/ISOC transactions or the NAK response timeout on Bulk
transactions for host Transmit endpoint.
(Index register set to select Endpoints 1-4 only)
0x01E0 041C HOST_RXTYPE Sets the operating speed, transaction protocol and peripheral endpoint number for the host
Receive endpoint.
(Index register set to select Endpoints 1-4 only)
0x01E0 041D HOST_RXINTERVAL Sets the polling interval for Interrupt/ISOC transactions or the NAK response timeout on Bulk
transactions for host Receive endpoint.
(Index register set to select Endpoints 1-4 only)
0x01E0 041F CONFIGDATA Returns details of core configuration. (Index register set to select Endpoint 0)
FIFO
0x01E0 0420 FIFO0 Transmit and Receive FIFO Register for Endpoint 0
0x01E0 0424 FIFO1 Transmit and Receive FIFO Register for Endpoint 1
0x01E0 0428 FIFO2 Transmit and Receive FIFO Register for Endpoint 2
0x01E0 042C FIFO3 Transmit and Receive FIFO Register for Endpoint 3
0x01E0 0430 FIFO4 Transmit and Receive FIFO Register for Endpoint 4
OTG Device Control
0x01E0 0460 DEVCTL Device Control Register
Dynamic FIFO Control

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Table 6-83. Universal Serial Bus OTG (USB0) Registers (continued)


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01E0 0462 TXFIFOSZ Transmit Endpoint FIFO Size
(Index register set to select Endpoints 1-4 only)
0x01E0 0463 RXFIFOSZ Receive Endpoint FIFO Size
(Index register set to select Endpoints 1-4 only)
0x01E0 0464 TXFIFOADDR Transmit Endpoint FIFO Address
(Index register set to select Endpoints 1-4 only)
0x01E0 0466 RXFIFOADDR Receive Endpoint FIFO Address
(Index register set to select Endpoints 1-4 only)
0x01E0 046C HWVERS Hardware Version Register
Target Endpoint 0 Control Registers, Valid Only in Host Mode
0x01E0 0480 TXFUNCADDR Address of the target function that has to be accessed through the associated Transmit
Endpoint.
0x01E0 0482 TXHUBADDR Address of the hub that has to be accessed through the associated Transmit Endpoint. This is
used only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 0483 TXHUBPORT Port of the hub that has to be accessed through the associated Transmit Endpoint. This is used
only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 0484 RXFUNCADDR Address of the target function that has to be accessed through the associated Receive
Endpoint.
0x01E0 0486 RXHUBADDR Address of the hub that has to be accessed through the associated Receive Endpoint. This is
used only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 0487 RXHUBPORT Port of the hub that has to be accessed through the associated Receive Endpoint. This is used
only when full speed or low speed device is connected via a USB2.0 high-speed hub.
Target Endpoint 1 Control Registers, Valid Only in Host Mode
0x01E0 0488 TXFUNCADDR Address of the target function that has to be accessed through the associated Transmit
Endpoint.
0x01E0 048A TXHUBADDR Address of the hub that has to be accessed through the associated Transmit Endpoint. This is
used only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 048B TXHUBPORT Port of the hub that has to be accessed through the associated Transmit Endpoint. This is used
only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 048C RXFUNCADDR Address of the target function that has to be accessed through the associated Receive
Endpoint.
0x01E0 048E RXHUBADDR Address of the hub that has to be accessed through the associated Receive Endpoint. This is
used only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 048F RXHUBPORT Port of the hub that has to be accessed through the associated Receive Endpoint. This is used
only when full speed or low speed device is connected via a USB2.0 high-speed hub.
Target Endpoint 2 Control Registers, Valid Only in Host Mode
0x01E0 0490 TXFUNCADDR Address of the target function that has to be accessed through the associated Transmit
Endpoint.
0x01E0 0492 TXHUBADDR Address of the hub that has to be accessed through the associated Transmit Endpoint. This is
used only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 0493 TXHUBPORT Port of the hub that has to be accessed through the associated Transmit Endpoint. This is used
only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 0494 RXFUNCADDR Address of the target function that has to be accessed through the associated Receive
Endpoint.
0x01E0 0496 RXHUBADDR Address of the hub that has to be accessed through the associated Receive Endpoint. This is
used only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 0497 RXHUBPORT Port of the hub that has to be accessed through the associated Receive Endpoint. This is used
only when full speed or low speed device is connected via a USB2.0 high-speed hub.
Target Endpoint 3 Control Registers, Valid Only in Host Mode
0x01E0 0498 TXFUNCADDR Address of the target function that has to be accessed through the associated Transmit
Endpoint.
0x01E0 049A TXHUBADDR Address of the hub that has to be accessed through the associated Transmit Endpoint. This is
used only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 049B TXHUBPORT Port of the hub that has to be accessed through the associated Transmit Endpoint. This is used
only when full speed or low speed device is connected via a USB2.0 high-speed hub.

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Table 6-83. Universal Serial Bus OTG (USB0) Registers (continued)


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01E0 049C RXFUNCADDR Address of the target function that has to be accessed through the associated Receive
Endpoint.
0x01E0 049E RXHUBADDR Address of the hub that has to be accessed through the associated Receive Endpoint. This is
used only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 049F RXHUBPORT Port of the hub that has to be accessed through the associated Receive Endpoint. This is used
only when full speed or low speed device is connected via a USB2.0 high-speed hub.
Target Endpoint 4 Control Registers, Valid Only in Host Mode
0x01E0 04A0 TXFUNCADDR Address of the target function that has to be accessed through the associated Transmit
Endpoint.
0x01E0 04A2 TXHUBADDR Address of the hub that has to be accessed through the associated Transmit Endpoint. This is
used only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 04A3 TXHUBPORT Port of the hub that has to be accessed through the associated Transmit Endpoint. This is used
only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 04A4 RXFUNCADDR Address of the target function that has to be accessed through the associated Receive
Endpoint.
0x01E0 04A6 RXHUBADDR Address of the hub that has to be accessed through the associated Receive Endpoint. This is
used only when full speed or low speed device is connected via a USB2.0 high-speed hub.
0x01E0 04A7 RXHUBPORT Port of the hub that has to be accessed through the associated Receive Endpoint. This is used
only when full speed or low speed device is connected via a USB2.0 high-speed hub.
Control and Status Register for Endpoint 0
0x01E0 0502 PERI_CSR0 Control Status Register for Endpoint 0 in Peripheral Mode
HOST_CSR0 Control Status Register for Endpoint 0 in Host Mode
0x01E0 0508 COUNT0 Number of Received Bytes in Endpoint 0 FIFO
0x01E0 050A HOST_TYPE0 Defines the Speed of Endpoint 0
0x01E0 050B HOST_NAKLIMIT0 Sets the NAK Response Timeout on Endpoint 0
0x01E0 050F CONFIGDATA Returns details of core configuration.
Control and Status Register for Endpoint 1
0x01E0 0510 TXMAXP Maximum Packet Size for Peripheral/Host Transmit Endpoint
0x01E0 0512 PERI_TXCSR Control Status Register for Peripheral Transmit Endpoint (peripheral mode)
HOST_TXCSR Control Status Register for Host Transmit Endpoint (host mode)
0x01E0 0514 RXMAXP Maximum Packet Size for Peripheral/Host Receive Endpoint
0x01E0 0516 PERI_RXCSR Control Status Register for Peripheral Receive Endpoint (peripheral mode)
HOST_RXCSR Control Status Register for Host Receive Endpoint (host mode)
0x01E0 0518 RXCOUNT Number of Bytes in Host Receive endpoint FIFO
0x01E0 051A HOST_TXTYPE Sets the operating speed, transaction protocol and peripheral endpoint number for the host
Transmit endpoint.
0x01E0 051B HOST_TXINTERVAL Sets the polling interval for Interrupt/ISOC transactions or the NAK response timeout on Bulk
transactions for host Transmit endpoint.
0x01E0 051C HOST_RXTYPE Sets the operating speed, transaction protocol and peripheral endpoint number for the host
Receive endpoint.
0x01E0 051D HOST_RXINTERVAL Sets the polling interval for Interrupt/ISOC transactions or the NAK response timeout on Bulk
transactions for host Receive endpoint.
Control and Status Register for Endpoint 2
0x01E0 0520 TXMAXP Maximum Packet Size for Peripheral/Host Transmit Endpoint
0x01E0 0522 PERI_TXCSR Control Status Register for Peripheral Transmit Endpoint (peripheral mode)
HOST_TXCSR Control Status Register for Host Transmit Endpoint (host mode)
0x01E0 0524 RXMAXP Maximum Packet Size for Peripheral/Host Receive Endpoint
0x01E0 0526 PERI_RXCSR Control Status Register for Peripheral Receive Endpoint (peripheral mode)
HOST_RXCSR Control Status Register for Host Receive Endpoint (host mode)
0x01E0 0528 RXCOUNT Number of Bytes in Host Receive endpoint FIFO
0x01E0 052A HOST_TXTYPE Sets the operating speed, transaction protocol and peripheral endpoint number for the host
Transmit endpoint.

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Table 6-83. Universal Serial Bus OTG (USB0) Registers (continued)


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01E0 052B HOST_TXINTERVAL Sets the polling interval for Interrupt/ISOC transactions or the NAK response timeout on Bulk
transactions for host Transmit endpoint.
0x01E0 052C HOST_RXTYPE Sets the operating speed, transaction protocol and peripheral endpoint number for the host
Receive endpoint.
0x01E0 052D HOST_RXINTERVAL Sets the polling interval for Interrupt/ISOC transactions or the NAK response timeout on Bulk
transactions for host Receive endpoint.
Control and Status Register for Endpoint 3
0x01E0 0530 TXMAXP Maximum Packet Size for Peripheral/Host Transmit Endpoint
0x01E0 0532 PERI_TXCSR Control Status Register for Peripheral Transmit Endpoint (peripheral mode)
HOST_TXCSR Control Status Register for Host Transmit Endpoint (host mode)
0x01E0 0534 RXMAXP Maximum Packet Size for Peripheral/Host Receive Endpoint
0x01E0 0536 PERI_RXCSR Control Status Register for Peripheral Receive Endpoint (peripheral mode)
HOST_RXCSR Control Status Register for Host Receive Endpoint (host mode)
0x01E0 0538 RXCOUNT Number of Bytes in Host Receive endpoint FIFO
0x01E0 053A HOST_TXTYPE Sets the operating speed, transaction protocol and peripheral endpoint number for the host
Transmit endpoint.
0x01E0 053B HOST_TXINTERVAL Sets the polling interval for Interrupt/ISOC transactions or the NAK response timeout on Bulk
transactions for host Transmit endpoint.
0x01E0 053C HOST_RXTYPE Sets the operating speed, transaction protocol and peripheral endpoint number for the host
Receive endpoint.
0x01E0 053D HOST_RXINTERVAL Sets the polling interval for Interrupt/ISOC transactions or the NAK response timeout on Bulk
transactions for host Receive endpoint.
Control and Status Register for Endpoint 4
0x01E0 0540 TXMAXP Maximum Packet Size for Peripheral/Host Transmit Endpoint
0x01E0 0542 PERI_TXCSR Control Status Register for Peripheral Transmit Endpoint (peripheral mode)
HOST_TXCSR Control Status Register for Host Transmit Endpoint (host mode)
0x01E0 0544 RXMAXP Maximum Packet Size for Peripheral/Host Receive Endpoint
0x01E0 0546 PERI_RXCSR Control Status Register for Peripheral Receive Endpoint (peripheral mode)
HOST_RXCSR Control Status Register for Host Receive Endpoint (host mode)
0x01E0 0548 RXCOUNT Number of Bytes in Host Receive endpoint FIFO
0x01E0 054A HOST_TXTYPE Sets the operating speed, transaction protocol and peripheral endpoint number for the host
Transmit endpoint.
0x01E0 054B HOST_TXINTERVAL Sets the polling interval for Interrupt/ISOC transactions or the NAK response timeout on Bulk
transactions for host Transmit endpoint.
0x01E0 054C HOST_RXTYPE Sets the operating speed, transaction protocol and peripheral endpoint number for the host
Receive endpoint.
0x01E0 054D HOST_RXINTERVAL Sets the polling interval for Interrupt/ISOC transactions or the NAK response timeout on Bulk
transactions for host Receive endpoint.
DMA Registers
0x01E0 1000 DMAREVID DMA Revision Register
0x01E0 1004 TDFDQ DMA Teardown Free Descriptor Queue Control Register
0x01E0 1008 DMAEMU DMA Emulation Control Register
0x01E0 1800 TXGCR[0] Transmit Channel 0 Global Configuration Register
0x01E0 1808 RXGCR[0] Receive Channel 0 Global Configuration Register
0x01E0 180C RXHPCRA[0] Receive Channel 0 Host Packet Configuration Register A
0x01E0 1810 RXHPCRB[0] Receive Channel 0 Host Packet Configuration Register B
0x01E0 1820 TXGCR[1] Transmit Channel 1 Global Configuration Register
0x01E0 1828 RXGCR[1] Receive Channel 1 Global Configuration Register
0x01E0 182C RXHPCRA[1] Receive Channel 1 Host Packet Configuration Register A
0x01E0 1830 RXHPCRB[1] Receive Channel 1 Host Packet Configuration Register B
0x01E0 1840 TXGCR[2] Transmit Channel 2 Global Configuration Register

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Table 6-83. Universal Serial Bus OTG (USB0) Registers (continued)


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01E0 1848 RXGCR[2] Receive Channel 2 Global Configuration Register
0x01E0 184C RXHPCRA[2] Receive Channel 2 Host Packet Configuration Register A
0x01E0 1850 RXHPCRB[2] Receive Channel 2 Host Packet Configuration Register B
0x01E0 1860 TXGCR[3] Transmit Channel 3 Global Configuration Register
0x01E0 1868 RXGCR[3] Receive Channel 3 Global Configuration Register
0x01E0 186C RXHPCRA[3] Receive Channel 3 Host Packet Configuration Register A
0x01E0 1870 RXHPCRB[3] Receive Channel 3 Host Packet Configuration Register B
0x01E0 2000 DMA_SCHED_CTRL DMA Scheduler Control Register
0x01E0 2800 WORD[0] DMA Scheduler Table Word 0
0x01E0 2804 WORD[1] DMA Scheduler Table Word 1
... ... ...
0x01E0 28FC WORD[63] DMA Scheduler Table Word 63
Queue Manager Registers
0x01E0 4000 QMGRREVID Queue Manager Revision Register
0x01E0 4008 DIVERSION Queue Diversion Register
0x01E0 4020 FDBSC0 Free Descriptor/Buffer Starvation Count Register 0
0x01E0 4024 FDBSC1 Free Descriptor/Buffer Starvation Count Register 1
0x01E0 4028 FDBSC2 Free Descriptor/Buffer Starvation Count Register 2
0x01E0 402C FDBSC3 Free Descriptor/Buffer Starvation Count Register 3
0x01E0 4080 LRAM0BASE Linking RAM Region 0 Base Address Register
0x01E0 4084 LRAM0SIZE Linking RAM Region 0 Size Register
0x01E0 4088 LRAM1BASE Linking RAM Region 1 Base Address Register
0x01E0 4090 PEND0 Queue Pending Register 0
0x01E0 4094 PEND1 Queue Pending Register 1
0x01E0 5000 QMEMRBASE[0] Memory Region 0 Base Address Register
0x01E0 5004 QMEMRCTRL[0] Memory Region 0 Control Register
0x01E0 5010 QMEMRBASE[1] Memory Region 1 Base Address Register
0x01E0 5014 QMEMRCTRL[1] Memory Region 1 Control Register
... ... ...
0x01E0 50F0 QMEMRBASE[15] Memory Region 15 Base Address Register
0x01E0 50F4 QMEMRCTRL[15] Memory Region 15 Control Register
0x01E0 600C CTRLD[0] Queue Manager Queue 0 Control Register D
0x01E0 601C CTRLD[1] Queue Manager Queue 1 Control Register D
... ... ...
0x01E0 63FC CTRLD[63] Queue Manager Queue 63 Status Register D
0x01E0 6800 QSTATA[0] Queue Manager Queue 0 Status Register A
0x01E0 6804 QSTATB[0] Queue Manager Queue 0 Status Register B
0x01E0 6808 QSTATC[0] Queue Manager Queue 0 Status Register C
0x01E0 6810 QSTATA[1] Queue Manager Queue 1 Status Register A
0x01E0 6814 QSTATB[1] Queue Manager Queue 1 Status Register B
0x01E0 6818 QSTATC[1] Queue Manager Queue 1 Status Register C
... ... ...
0x01E0 6BF0 QSTATA[63] Queue Manager Queue 63 Status Register A
0x01E0 6BF4 QSTATB[63] Queue Manager Queue 63 Status Register B
0x01E0 6BF8 QSTATC[63] Queue Manager Queue 63 Status Register C

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6.19.2 USB0 [USB2.0] Electrical Data/Timing


The USB PHY PLL can support input clock of the following frequencies: 12.0 MHz, 13.0 MHz, 19.2 MHz,
20.0 MHz, 24.0 MHz, 26.0 MHz, 38.4 MHz, 40.0 MHz or 48.0 MHz. USB_REFCLKIN jitter tolerance is 50
ppm maximum.

Table 6-84. Switching Characteristics Over Recommended Operating Conditions for USB0 [USB2.0] (see
Figure 6-43)
1.3V, 1.2V, 1.1V, 1.0V
LOW SPEED FULL SPEED HIGH SPEED
NO. PARAMETER UNIT
1.5 Mbps 12 Mbps 480 Mbps
MIN MAX MIN MAX MIN MAX
1 tr(D) Rise time, USB_DP and USB_DM signals (1) 75 300 4 20 0.5 ns
2 tf(D) Fall time, USB_DP and USB_DM signals (1) 75 300 4 20 0.5 ns
3 trfM Rise/Fall time, matching (2) 80 120 90 111 – – %
(1)
4 VCRS Output signal cross-over voltage 1.3 2 1.3 2 – – V
(3)
5 tjr(source)NT Source (Host) Driver jitter, next transition 2 2 ns
(3)
tjr(FUNC)NT Function Driver jitter, next transition 25 2 ns
6 tjr(source)PT Source (Host) Driver jitter, paired transition (4) 1 1 (3)
ns
(3)
tjr(FUNC)PT Function Driver jitter, paired transition 10 1 ns
7 tw(EOPT) Pulse duration, EOP transmitter 1250 1500 160 175 – – ns
8 tw(EOPR) Pulse duration, EOP receiver 670 82 – ns
9 t(DRATE) Data Rate 1.5 12 480 Mb/s
10 ZDRV Driver Output Resistance – – 40.5 49.5 40.5 49.5 Ω
11 ZINP Receiver Input Impedance 100k 100k - - Ω
(1) Low Speed: CL = 200 pF, Full Speed: CL = 50 pF, High Speed: CL = 50 pF
(2) tRFM = (tr/tf) x 100. [Excluding the first transaction from the Idle state.]
(3) For more detailed information, see the Universal Serial Bus Specification Revision 2.0, Chapter 7. Electrical.
(4) tjr = tpx(1) - tpx(0)

tper − tjr
USB_DM
90% VOH
VCRS
10% VOL
USB_DP
tf
tr

Figure 6-43. USB2.0 Integrated Transceiver Interface Timing

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6.20 LCD Controller (LCDC)


The LCD controller consists of two independent controllers, the Raster Controller and the LCD Interface
Display Driver (LIDD) controller. Each controller operates independently from the other and only one of
them is active at any given time.
• The Raster Controller handles the synchronous LCD interface. It provides timing and data for constant
graphics refresh to a passive display. It supports a wide variety of monochrome and full-color display
types and sizes by use of programmable timing controls, a built-in palette, and a gray-scale/serializer.
Graphics data is processed and stored in frame buffers. A frame buffer is a contiguous memory block
in the system. A built-in DMA engine supplies the graphics data to the Raster engine which, in turn,
outputs to the external LCD device.
• The LIDD Controller supports the asynchronous LCD interface. It provides full-timing programmability
of control signals (CS, WE, OE, ALE) and output data.
The maximum resolution for the LCD controller is 1024 x 1024 pixels. The maximum frame rate is
determined by the image size in combination with the pixel clock rate. For details, see SPRAB93.
Table 6-85 lists the LCD Controller registers.

Table 6-85. LCD Controller Registers


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01E1 3000 REVID LCD Revision Identification Register
0x01E1 3004 LCD_CTRL LCD Control Register
0x01E1 3008 LCD_STAT LCD Status Register
0x01E1 300C LIDD_CTRL LCD LIDD Control Register
0x01E1 3010 LIDD_CS0_CONF LCD LIDD CS0 Configuration Register
0x01E1 3014 LIDD_CS0_ADDR LCD LIDD CS0 Address Read/Write Register
0x01E1 3018 LIDD_CS0_DATA LCD LIDD CS0 Data Read/Write Register
0x01E1 301C LIDD_CS1_CONF LCD LIDD CS1 Configuration Register
0x01E1 3020 LIDD_CS1_ADDR LCD LIDD CS1 Address Read/Write Register
0x01E1 3024 LIDD_CS1_DATA LCD LIDD CS1 Data Read/Write Register
0x01E1 3028 RASTER_CTRL LCD Raster Control Register
0x01E1 302C RASTER_TIMING_0 LCD Raster Timing 0 Register
0x01E1 3030 RASTER_TIMING_1 LCD Raster Timing 1 Register
0x01E1 3034 RASTER_TIMING_2 LCD Raster Timing 2 Register
0x01E1 3038 RASTER_SUBPANEL LCD Raster Subpanel Display Register
0x01E1 3040 LCDDMA_CTRL LCD DMA Control Register
0x01E1 3044 LCDDMA_FB0_BASE LCD DMA Frame Buffer 0 Base Address Register
0x01E1 3048 LCDDMA_FB0_CEILING LCD DMA Frame Buffer 0 Ceiling Address Register
0x01E1 304C LCDDMA_FB1_BASE LCD DMA Frame Buffer 1 Base Address Register
0x01E1 3050 LCDDMA_FB1_CEILING LCD DMA Frame Buffer 1 Ceiling Address Register

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6.20.1 LCD Interface Display Driver (LIDD Mode)

Table 6-86. Timing Requirements for LCD LIDD Mode


1.3V, 1.2V,
1.0V
NO. 1.1V UNIT
MIN MAX MIN MAX
16 tsu(LCD_D) Setup time, LCD_D[15:0] valid before LCD_MCLK high 7 8 ns
17 th(LCD_D) Hold time, LCD_D[15:0] valid after LCD_MCLK high 0 0 ns

Table 6-87. Switching Characteristics Over Recommended Operating Conditions for LCD LIDD Mode
1.3V, 1.2V,
1.0V
NO. PARAMETER 1.1V UNIT
MIN MAX MIN MAX
4 td(LCD_D_V) Delay time, LCD_MCLK high to LCD_D[15:0] valid (write) 0 7 0 9 ns
5 td(LCD_D_I) Delay time, LCD_MCLK high to LCD_D[15:0] invalid (write) 0 7 0 9 ns
6 td(LCD_E_A) Delay time, LCD_MCLK high to LCD_AC_ENB_CS low 0 7 0 9 ns
7 td(LCD_E_I) Delay time, LCD_MCLK high to LCD_AC_ENB_CS high 0 7 0 9 ns
8 td(LCD_A_A) Delay time, LCD_MCLK high to LCD_VSYNC low 0 7 0 9 ns
9 td(LCD_A_I) Delay time, LCD_MCLK high to LCD_VSYNC high 0 7 0 9 ns
10 td(LCD_W_A) Delay time, LCD_MCLK high to LCD_HSYNC low 0 7 0 9 ns
11 td(LCD_W_I) Delay time, LCD_MCLK high to LCD_HSYNC high 0 7 0 9 ns
12 td(LCD_STRB_A) Delay time, LCD_MCLK high to LCD_PCLK active 0 7 0 9 ns
13 td(LCD_STRB_I) Delay time, LCD_MCLK high to LCD_PCLK inactive 0 7 0 9 ns
14 td(LCD_D_Z) Delay time, LCD_MCLK high to LCD_D[15:0] in 3-state 0 7 0 9 ns
15 td(Z_LCD_D) Delay time, LCD_MCLK high to LCD_D[15:0] (valid from 3-state) 0 7 0 9 ns

CS_DELA Y
1 R_SU R_HOLD
W_SU (0 to 31) (1 to 15)
2 (0 to 31) W_STROBE CS_DELA Y
W_HOLD R_STROBE
3 (1 to 63) (1 to 63)
(1 to 15)

LCD_MCLK
4 5 14 17
16 15

LCD_D[15:0] Write Data Data[7:0]


Read Status

LCD_PCLK Not Used

8 9

LCD_VSYNC RS

10 11

LCD_HSYNC R/W

12 12
13 13
E0
LCD_AC_ENB_CS E1

Figure 6-44. Character Display HD44780 Write

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R_SU W_HOLD
(0–31) (1–15)

R_STROBE R_HOLD CS_DELAY W_SU W_STROBE CS_DELAY


1
(1–63) (1–5) (0–31) (1–63) Not
2 3 Used

LCD_MCLK

14 16 17 15 4 5
LCD_D[7:0] Write Instruction Data[7:0]

Read
Data
LCD_PCLK Not
Used

8 9

LCD_VSYNC RS

10 11
LCD_HSYNC R/W

12 13 12 13 E0
E1
LCD_AC_ENB_CS

Figure 6-45. Character Display HD44780 Read

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W_HOLD W_HOLD
(1−15) (1−15)

W_SU W_STROBE CS_DELAY W_SU W_STROBE CS_DELAY


1
(0−31) (1−63) (0−31) (1−63)
2 3 Clock

LCD_MCLK

4 5 4 5
LCD_D[15:0] Write Address Write Data Data[15:0]

6 7 6 7
LCD_AC_ENB_CS
(async mode) CS0
CS1

8 9

LCD_VSYNC A0

10 11 10 11
R/W
LCD_HSYNC

12 13 12 13

LCD_PCLK E

Figure 6-46. Micro-Interface Graphic Display 6800 Write

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W_HOLD R_SU
(1−15) (0−31)

W_SU W_STROBE CS_DELAY R_STROBE R_HOLD CS_DELAY


1
(0−31) (1−63) (1−63 (1−15)
2 3 Clock

LCD_MCLK

4 5 14 16 17 15
LCD_D[15:0] Write Address Data[15:0]
Read
Data
6 7 6 7
LCD_AC_ENB_CS
(async mode) CS0
CS1

8 9
LCD_VSYNC A0

10 11
LCD_HSYNC R/W

12 13 12 13
LCD_PCLK E

Figure 6-47. Micro-Interface Graphic Display 6800 Read

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R_SU R_SU
(0−31) (0−31)

R_STROBE R_HOLD CS_DELAY R_STROBE R_HOLD CS_DELAY


1
(1−63) (1−15) (1−63) (1−15)
2 3
Clock

LCD_MCLK

14 16 17 15 14 16 17 15
LCD_D[15:0] Data[15:0]

Read
Read Status
6 Data 7 6 7
LCD_AC_ENB_CS
(async mode) CS0
CS1

8 9
LCD_VSYNC A0

LCD_HSYNC R/W

12 13 12 13
LCD_PCLK E

Figure 6-48. Micro-Interface Graphic Display 6800 Status

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W_HOLD W_HOLD
(1−15) (1−15)
W_SU W_STROBE CS_DELAY W_SU W_STROBE CS_DELAY
1
(0−31) (1−63) (0−31) (1−63)
2 3
Clock

LCD_MCLK

4 5 4 5
LCD_D[15:0] Write Address Write Data DATA[15:0]

6 7 6 7
LCD_AC_ENB_CS
(async mode) CS0
CS1

8 9
LCD_VSYNC A0

10 11 10 11
LCD_HSYNC WR

LCD_PCLK RD

Figure 6-49. Micro-Interface Graphic Display 8080 Write

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W_HOLD R_SU
(1−15) (0−31)
W_SU W_STROBE CS_DELAY R_STROBE R_HOLD CS_DELAY
1
(0−31) (1−63) (1−63) (1−15)
2 3 Clock

LCD_MCLK

4 5 14 16 17 15
LCD_D[15:0] Write Address Data[15:0]

Read
6 7 6 Data 7
LCD_AC_ENB_CS
(async mode) CS0
CS1

8 9
LCD_VSYNC A0

10 11
LCD_HSYNC WR

12 13
LCD_PCLK RD

Figure 6-50. Micro-Interface Graphic Display 8080 Read

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R_SU R_SU
(0−31) (0−31)

R_STROBE R_HOLD CS_DELAY R_STROBE R_HOLD CS_DELAY


1
(1−63) (1−15) (1−63) (1−15)
2
3 Clock

LCD_MCLK

14 16 17 15 14 16 17 15

LCD_D[15:0] Data[15:0]

Read Data Read Status


6 7 6 7
LCD_AC_ENB_CS
CS0
CS1

8 9

LCD_VSYNC A0

LCD_HSYNC WR

12 13 12 13

LCD_PCLK RD

Figure 6-51. Micro-Interface Graphic Display 8080 Status

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6.20.2 LCD Raster Mode

Table 6-88. Switching Characteristics Over Recommended Operating Conditions for LCD Raster Mode
See Figure 6-52 through Figure 6-56
1.3V, 1.2V,
1.0V
NO. PARAMETER 1.1V UNIT
MIN MAX MIN MAX
1 tc(PIXEL_CLK) Cycle time, pixel clock 26.66 33.33 ns
2 tw(PIXEL_CLK_H) Pulse duration, pixel clock high 10 10 ns
3 tw(PIXEL_CLK_L) Pulse duration, pixel clock low 10 10 ns
4 td(LCD_D_V) Delay time, LCD_PCLK high to LCD_D[15:0] valid (write) 0 7 0 9 ns
5 td(LCD_D_IV) Delay time, LCD_PCLK high to LCD_D[15:0] invalid (write) 0 7 0 9 ns
6 td(LCD_AC_ENB_CS_A) Delay time, LCD_PCLK low to LCD_AC_ENB_CS high 0 7 0 9 ns
7 td(LCD_AC_ENB_CS_I) Delay time, LCD_PCLK low to LCD_AC_ENB_CS high 0 7 0 9 ns
8 td(LCD_VSYNC_A) Delay time, LCD_PCLK low to LCD_VSYNC high 0 7 0 9 ns
9 td(LCD_VSYNC_I) Delay time, LCD_PCLK low to LCD_VSYNC low 0 7 0 9 ns
10 td(LCD_HSYNC_A) Delay time, LCD_PCLK high to LCD_HSYNC high 0 7 0 9 ns
11 td(LCD_HSYNC_I) Delay time, LCD_PCLK high to LCD_HSYNC low 0 7 0 9 ns

Frame-to-frame timing is derived through the following parameters in the LCD (RASTER_TIMING_1)
register:
• Vertical front porch (VFP)
• Vertical sync pulse width (VSW)
• Vertical back porch (VBP)
• Lines per panel (LPP)
Line-to-line timing is derived through the following parameters in the LCD (RASTER_TIMING_0) register:
• Horizontal front porch (HFP)
• Horizontal sync pulse width (HSW)
• Horizontal back porch (HBP)
• Pixels per panel (PPL)
LCD_AC_ENB_CS timing is derived through the following parameter in the LCD (RASTER_TIMING_2)
register:
• AC bias frequency (ACB)
The display format produced in raster mode is shown in Figure 6-52. An entire frame is delivered one line
at a time. The first line delivered starts at data pixel (1, 1) and ends at data pixel (P, 1). The last line
delivered starts at data pixel (1, L) and ends at data pixel (P, L). The beginning of each new frame is
denoted by the activation of I/O signal LCD_VSYNC. The beginning of each new line is denoted by the
activation of I/O signal LCD_HSYNC.

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Data Pixels (From 1 to P)

1, 1 2, 1 3, 1 P−2, P−1, P, 1
1 1

1, 2 2, 2 P−1, P, 2
2

1, 3 P, 3
Data Lines (From 1 to L)

LCD

1, P,
L−2 L−2

1, 2, P−1, P,
L−1 L−1 L−1 L−1

1, L 2, L 3, L P−2, P−1, P, L
L L

Figure 6-52. LCD Raster-Mode Display Format

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Frame Time ~ 70 Hz
Active TFT

VSW VBP LPP VFP VSW


(1 to 64) (0 to 255) (1 to 1024) (0 to 255) (1 to 64)
Line
Time
Hsync
LCD_HSYNC

LCD_VSYNC Vsync

Data
LCD_D[15:0]

1, 2 1, L-1 1, L
1, 1
P, 2 P, L-1 P, L
P, 1

LCD_AC_ENB_CS

10 11

LCD_HSYNC Hsync

CLK
LCD_PCLK

Data

LCD_D[15:0] 1, 1 2, 1 P, 1 1, 2 2, 2 P, 2

LCD_AC_ENB_CS Enable

PLL HFP HSW HBP PLL


16 × (1 to 1024) (1 to 256) (1 to 64) (1 to 256) 16 × (1 to 1024)
Line 1 Line 2

Figure 6-53. LCD Raster-Mode Active

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Figure 6-54. LCD Raster-Mode Passive

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6
LCD_AC_ENB_CS

8
LCD_VSYNC

10 11
LCD_HSYNC

1
2 3
LCD_PCLK
(passive mode)

4 5
LCD_D[7:0]
1, L 2, L P, L 1, 1 2, 1 P, 1
(passive mode)

1
2 3
LCD_PCLK
(active mode)

4 5
LCD_D[15:0]
1, L 2, L P, L
(active mode)

VBP = 0
VFP = 0
VSW = 1 PPL HFP HSW HBP PPL
16 × (1 to 1024) (1 to 256 (1 to 64) (1 to 256) 16 ×(1 to 1024)
Line L Line 1 (Passive Only)

Figure 6-55. LCD Raster-Mode Control Signal Activation

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7
LCD_AC_ENB_CS

9
LCD_VSYNC

10 11
LCD_HSYNC

1
4 3
LCD_PCLK
(passive mode)

4 5
LCD_D[7:0]
1, 1 2, 1 P, 1 1, 2 2, 2 P, 2
(passive mode)

1
2 3
LCD_PCLK
(active mode)

4 5
LCD_D[15:0]
1, 1 2, 1 P, 1
(active mode)

VBP = 0
VFP = 0
VSW = 1 PPL HFP HSW HBP PPL
16 × (1 to 1024) (1 to 256 (1 to 64) (1 to 256) 16 ×(1 to 1024)
Line 1 for passive Line 1 for active
Line 2 for passive

Figure 6-56. LCD Raster-Mode Control Signal Deactivation

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6.21 Host-Port Interface (UHPI)

6.21.1 HPI Device-Specific Information


The device includes a user-configurable 16-bit Host-port interface (HPI16).
The host port interface (UHPI) provides a parallel port interface through which an external host processor
can directly access the processor's resources (configuration and program/data memories). The external
host device is asynchronous to the CPU clock and functions as a master to the HPI interface. The UHPI
enables a host device and the processor to exchange information via internal or external memory.
Dedicated address (HPIA) and data (HPID) registers within the UHPI provide the data path between the
external host interface and the processor resources. A UHPI control register (HPIC) is available to the
host and the CPU for various configuration and interrupt functions.

6.21.2 HPI Peripheral Register Description(s)

Table 6-89. HPI Control Registers


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION COMMENTS
0x01E1 0000 PID Peripheral Identification Register
The CPU has read/write access
0x01E1 0004 PWREMU_MGMT HPI power and emulation management register
to the PWREMU_MGMT register.
0x01E1 0008 - Reserved
0x01E1 000C GPIO_EN General Purpose IO Enable Register
0x01E1 0010 GPIO_DIR1 General Purpose IO Direction Register 1
0x01E1 0014 GPIO_DAT1 General Purpose IO Data Register 1
0x01E1 0018 GPIO_DIR2 General Purpose IO Direction Register 2
0x01E1 001C GPIO_DAT2 General Purpose IO Data Register 2
0x01E1 0020 GPIO_DIR3 General Purpose IO Direction Register 3
0x01E1 0024 GPIO_DAT3 General Purpose IO Data Register 3
01E1 0028 - Reserved
01E1 002C - Reserved
The Host and the CPU both have
01E1 0030 HPIC HPI control register read/write access to the HPIC
register.
HPIA HPI address register The Host has read/write access
01E1 0034
(HPIAW) (1) (Write) to the HPIA registers. The CPU
HPIA HPI address register has only read access to the
01E1 0038 HPIA registers.
(HPIAR) (1) (Read)
01E1 000C - 01E1 07FF - Reserved
(1) There are two 32-bit HPIA registers: HPIAR for read operations and HPIAW for write operations. The HPI can be configured such that
HPIAR and HPIAW act as a single 32-bit HPIA (single-HPIA mode) or as two separate 32-bit HPIAs (dual-HPIA mode) from the
perspective of the Host. The CPU can access HPIAW and HPIAR independently.

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6.21.3 HPI Electrical Data/Timing

Table 6-90. Timing Requirements for Host-Port Interface [1.3V, 1.2V, 1.1V] (1) (2)

1.3V, 1.2V, 1.1V,


NO. 1.0V UNIT
MIN MAX
1 tsu(SELV-HSTBL) Setup time, select signals (3) valid before UHPI_HSTROBE low 5 ns
2 th(HSTBL-SELV) Hold time, select signals (3) valid after UHPI_HSTROBE low 2 ns
3 tw(HSTBL) Pulse duration, UHPI_HSTROBE active low 15 ns
4 tw(HSTBH) Pulse duration, UHPI_HSTROBE inactive high between consecutive accesses 2M ns
9 tsu(SELV-HASL) Setup time, selects signals valid before UHPI_HAS low 5 ns
10 th(HASL-SELV) Hold time, select signals valid after UHPI_HAS low 2 ns
11 tsu(HDV-HSTBH) Setup time, host data valid before UHPI_HSTROBE high 5 ns
12 th(HSTBH-HDV) Hold time, host data valid after UHPI_HSTROBE high 2 ns
Hold time, UHPI_HSTROBE high after UHPI_HRDY low. UHPI_HSTROBE
13 th(HRDYL-HSTBH) should not be inactivated until UHPI_HRDY is active (low); otherwise, HPI writes 2 ns
will not complete properly.
16 tsu(HASL-HSTBL) Setup time, UHPI_HAS low before UHPI_HSTROBE low 5 ns
17 th(HSTBL-HASH) Hold time, UHPI_HAS low after UHPI_HSTROBE low 2 ns
(1) UHPI_HSTROBE refers to the following logical operation on UHPI_HCS, UHPI_HDS1, and UHPI_HDS2: [NOT(UHPI_HDS1 XOR
UHPI_HDS2)] OR UHPI_HCS.
(2) M=SYSCLK2 period in ns.
(3) Select signals include: HCNTL[1:0], HR/W and HHWIL.

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Table 6-91. Switching Characteristics Over Recommended Operating Conditions for Host-Port Interface
[1.3V, 1.2V, 1.1V] (1) (2) (3)
1.3V, 1.2V 1.1V
NO. PARAMETER UNIT
MIN MAX MIN MAX
For HPI Write, HRDY can go high (not
ready) for these HPI Write conditions;
otherwise, HRDY stays low (ready):
Case 1: Back-to-back HPIA writes (can
be either first or second half-word)
Case 2: HPIA write following a
PREFETCH command (can be either
first or second half-word)
Case 3: HPID write when FIFO is full or
flushing (can be either first or second
half-word)
Case 4: HPIA write and Write FIFO not
empty
For HPI Read, HRDY can go high (not
ready) for these HPI Read conditions:
Delay time, HSTROBE low to Case 1: HPID read (with auto-
5 td(HSTBL-HRDYV) increment) and data not in Read FIFO 15 17 ns
HRDY valid
(can only happen to first half-word of
HPID access)
Case 2: First half-word access of HPID
Read without auto-increment
For HPI Read, HRDY stays low (ready)
for these HPI Read conditions:
Case 1: HPID read with auto-increment
and data is already in Read FIFO
(applies to either half-word of HPID
access)
Case 2: HPID read without auto-
increment and data is already in Read
FIFO (always applies to second half-
word of HPID access)
Case 3: HPIC or HPIA read (applies to
either half-word access)
5a td(HASL-HRDYV) Delay time, HAS low to HRDY valid 15 17 ns
6 ten(HSTBL-HDLZ) Enable time, HD driven from HSTROBE low 1.5 1.5 ns
7 td(HRDYL-HDV) Delay time, HRDY low to HD valid 0 0 ns
8 toh(HSTBH-HDV) Output hold time, HD valid after HSTROBE high 1.5 1.5 ns
14 tdis(HSTBH-HDHZ) Disable time, HD high-impedance from HSTROBE high 15 17 ns
For HPI Read. Applies to conditions
where data is already residing in
HPID/FIFO:
Case 1: HPIC or HPIA read
Delay time, HSTROBE low to
15 td(HSTBL-HDV) Case 2: First half-word of HPID read 15 17 ns
HD valid
with auto-increment and data is already
in Read FIFO
Case 3: Second half-word of HPID
read with or without auto-increment
For HPI Write, HRDY can go high (not
ready) for these HPI Write conditions;
otherwise, HRDY stays low (ready):
Case 1: HPID write when Write FIFO is
Delay time, HSTROBE high to full (can happen to either half-word)
18 td(HSTBH-HRDYV) 15 17 ns
HRDY valid Case 2: HPIA write (can happen to
either half-word)
Case 3: HPID write without auto-
increment (only happens to second
half-word)
(1) M=SYSCLK2 period in ns.
(2) HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS.
(3) By design, whenever HCS is driven inactive (high), HPI will drive HRDY active (low).

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Table 6-92. Switching Characteristics Over Recommended Operating Conditions for Host-Port Interface
[1.0V] (1) (2) (3)
1.0V
NO. PARAMETER UNIT
MIN MAX
For HPI Write, HRDY can go high (not ready) for
these HPI Write conditions; otherwise, HRDY
stays low (ready):
Case 1: Back-to-back HPIA writes (can be either
first or second half-word)
Case 2: HPIA write following a PREFETCH
command (can be either first or second half-
word)
Case 3: HPID write when FIFO is full or flushing
(can be either first or second half-word)
Case 4: HPIA write and Write FIFO not empty
For HPI Read, HRDY can go high (not ready)
for these HPI Read conditions:
Delay time, HSTROBE low to HRDY Case 1: HPID read (with auto-increment) and
5 td(HSTBL-HRDYV) 22 ns
valid data not in Read FIFO (can only happen to first
half-word of HPID access)
Case 2: First half-word access of HPID Read
without auto-increment
For HPI Read, HRDY stays low (ready) for
these HPI Read conditions:
Case 1: HPID read with auto-increment and
data is already in Read FIFO (applies to either
half-word of HPID access)
Case 2: HPID read without auto-increment and
data is already in Read FIFO (always applies to
second half-word of HPID access)
Case 3: HPIC or HPIA read (applies to either
half-word access)
5a td(HASL-HRDYV) Delay time, HAS low to HRDY valid 22 ns
6 ten(HSTBL-HDLZ) Enable time, HD driven from HSTROBE low 1.5 ns
7 td(HRDYL-HDV) Delay time, HRDY low to HD valid 0 ns
8 toh(HSTBH-HDV) Output hold time, HD valid after HSTROBE high 1.5 ns
14 tdis(HSTBH-HDHZ) Disable time, HD high-impedance from HSTROBE high 22 ns
For HPI Read. Applies to conditions where data
is already residing in HPID/FIFO:
Case 1: HPIC or HPIA read
Delay time, HSTROBE low to HD
15 td(HSTBL-HDV) Case 2: First half-word of HPID read with auto- 22 ns
valid
increment and data is already in Read FIFO
Case 3: Second half-word of HPID read with or
without auto-increment
For HPI Write, HRDY can go high (not ready) for
these HPI Write conditions; otherwise, HRDY
stays low (ready):
Case 1: HPID write when Write FIFO is full (can
Delay time, HSTROBE high to HRDY
18 td(HSTBH-HRDYV) happen to either half-word) 22 ns
valid
Case 2: HPIA write (can happen to either half-
word)
Case 3: HPID write without auto-increment (only
happens to second half-word)
(1) M=SYSCLK2 period in ns.
(2) HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS.
(3) By design, whenever HCS is driven inactive (high), HPI will drive HRDY active (low).

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UHPI_HCS

UHPI_HAS(D)
2 2
1 1
UHPI_HCNTL[1:0]
2 2
1 1
UHPI_HR/W
2 2
1 1
UHPI_HHWIL
4
3 3
UHPI_HSTROBE(A)(C)

15 15
14 14
6 8 6 8
UHPI_HD[15:0]
(output)
5 13 1st Half-Word 2nd Half-Word
7
UHPI_HRDY(B)

A. UHPI_HSTROBE refers to the following logical operation on UHPI_HCS, UHPI_HDS1, and UHPI_HDS2: [NOT(HDS1
XOR HDS2)] OR UHPI_HCS.
B. Depending on the type of write or read operation (HPID without auto-incrementing; HPIA, HPIC, or HPID with
auto-incrementing) and the state of the FIFO, transitions on UHPI_HRDY may or may not occur.
C. UHPI_HCS reflects typical UHPI_HCS behavior when UHPI_HSTROBE assertion is caused by UHPI_HDS1 or
UHPI_HDS2. UHPI_HCS timing requirements are reflected by parameters for UHPI_HSTROBE.
D The diagram above assumes UHPI_HAS has been pulled high.

Figure 6-57. UHPI Read Timing (HAS Not Used, Tied High)

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UHPI_HAS(A)
17 17
9 10
10 9
UHPI_HCNTL[1:0]

10 10
9 9
UHPI_HR/W

10 10
9 9
UHPI_HHWIL
4
3
UHPI_HSTROBE(B)
16 16
UHPI_HCS

14 14
6 8 15 8
UHPI_HD[15:0]
(output)
1st half-word 2nd half-word
5a 7
UHPI_HRDY
A. For correct operation, strobe the UHPI_HAS signal only once per UHPI_HSTROBE active cycle.
B. UHPI_HSTROBE refers to the following logical operation on UHPI_HCS, UHPI_HDS1, and UHPI_HDS2:
[NOT(UHPI_HDS1 XOR UHPI_HDS2)] OR UHPI_HCS.

Figure 6-58. UHPI Read Timing (HAS Used)

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UHPI_HCS

UHPI_HAS(D)

1 1
2 2

UHPI_HCNTL[1:0]

1 1
2 2

UHPI_HR/W

1 1
2 2

UHPI_HHWIL

3 3
4

UHPI_HSTROBE(A)(C)

11 11
12 12
UHPI_HD[15:0]
(input) 1st Half-Word 2nd Half-Word

18
5 18 13
13
5
UHPI_HRDY(B)

A. UHPI_HSTROBE refers to the following logical operation on UHPI_HCS, UHPI_HDS1, and UHPI_HDS2: [NOT(HDS1 XOR HDS2)] OR
UHPI_HCS.
B. Depending on the type of write or read operation (HPID without auto-incrementing; HPIA, HPIC, or HPID with auto-incrementing) and the
state of the FIFO, transitions on UHPI_HRDY may or may not occur.
C. UHPI_HCS reflects typical UHPI_HCS behavior when UHPI_HSTROBE assertion is caused by UHPI_HDS1 or UHPI_HDS2. UHPI_HCS
timing requirements are reflected by parameters for UHPI_HSTROBE.
D The diagram above assumes UHPI_HAS has been pulled high.

Figure 6-59. UHPI Write Timing (HAS Not Used, Tied High)

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17 17
UHPI_HAS†
10 10
9 9
UHPI_HCNTL[1:0]

10 10
9 9
UHPI_HR/W

10 10
9 9
UHPI_HHWIL
3
4
UHPI_HSTROBE‡
16 16
UHPI_HCS
11 11
12 12
UHPI_HD[15:0]
(input)
1st half-word 2nd half-word
5a 13
UHPI_HRDY
A. For correct operation, strobe the UHPI_HAS signal only once per UHPI_HSTROBE active cycle.
B. UHPI_HSTROBE refers to the following logical operation on UHPI_HCS, UHPI_HDS1, and UHPI_HDS2:
[NOT(UHPI_HDS1 XOR UHPI_HDS2)] OR UHPI_HCS.

Figure 6-60. UHPI Write Timing (HAS Used)

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6.22 Universal Parallel Port (uPP)


The Universal Parallel Port (uPP) peripheral is a multichannel, high-speed parallel interface with dedicated
data lines and minimal control signals. It is designed to interface cleanly with high-speed analog-to-digital
converters (ADCs) or digital-to-analog converters (DACs) with up to 16-bit data width (per channel). It may
also be interconnected with field-programmable gate arrays (FPGAs) or other uPP devices to achieve
high-speed digital data transfer. It can operate in receive mode, transmit mode, or duplex mode, in which
its individual channels operate in opposite directions.
The uPP peripheral includes an internal DMA controller to maximize throughput and minimize CPU
overhead during high-speed data transmission. All uPP transactions use the internal DMA to provide data
to or retrieve data from the I/O channels. The DMA controller includes two DMA channels, which typically
service separate I/O channels. The uPP peripheral also supports data interleave mode, in which all DMA
resources service a single I/O channel. In this mode, only one I/O channel may be used.
The features of the uPP include:
• Programmable data width per channel (from 8 to 16 bits inclusive)
• Programmable data justification
– Right-justify with zero extend
– Right-justify with sign extend
– Left-justify with zero fill
• Supports multiplexing of interleaved data during SDR transmit
• Optional frame START signal with programmable polarity
• Optional data ENABLE signal with programmable polarity
• Optional synchronization WAIT signal with programmable polarity
• Single Data Rate (SDR) or Double data Rate (DDR, interleaved) interface
– Supports multiplexing of interleaved data during SDR transmit
– Supports demultiplexing and multiplexing of interleaved data during DDR transfers

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6.22.1 uPP Register Descriptions

Table 6-93. Universal Parallel Port (uPP) Registers


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01E1 6000 UPPID uPP Peripheral Identification Register
0x01E1 6004 UPPCR uPP Peripheral Control Register
0x01E1 6008 UPDLB uPP Digital Loopback Register
0x01E1 6010 UPCTL uPP Channel Control Register
0x01E1 6014 UPICR uPP Interface Configuration Register
0x01E1 6018 UPIVR uPP Interface Idle Value Register
0x01E1 601C UPTCR uPP Threshold Configuration Register
0x01E1 6020 UPISR uPP Interrupt Raw Status Register
0x01E1 6024 UPIER uPP Interrupt Enabled Status Register
0x01E1 6028 UPIES uPP Interrupt Enable Set Register
0x01E1 602C UPIEC uPP Interrupt Enable Clear Register
0x01E1 6030 UPEOI uPP End-of-Interrupt Register
0x01E1 6040 UPID0 uPP DMA Channel I Descriptor 0 Register
0x01E1 6044 UPID1 uPP DMA Channel I Descriptor 1 Register
0x01E1 6048 UPID2 uPP DMA Channel I Descriptor 2 Register
0x01E1 6050 UPIS0 uPP DMA Channel I Status 0 Register
0x01E1 6054 UPIS1 uPP DMA Channel I Status 1 Register
0x01E1 6058 UPIS2 uPP DMA Channel I Status 2 Register
0x01E1 6060 UPQD0 uPP DMA Channel Q Descriptor 0 Register
0x01E1 6064 UPQD1 uPP DMA Channel Q Descriptor 1 Register
0x01E1 6068 UPQD2 uPP DMA Channel Q Descriptor 2 Register
0x01E1 6070 UPQS0 uPP DMA Channel Q Status 0 Register
0x01E1 6074 UPQS1 uPP DMA Channel Q Status 1 Register
0x01E1 6078 UPQS2 uPP DMA Channel Q Status 2 Register

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6.22.2 uPP Electrical Data/Timing

Table 6-94. Timing Requirements for uPP (see Figure 6-61, Figure 6-62, Figure 6-63, Figure 6-64)
1.3V, 1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX
SDR mode 13.33 20 26.66
1 tc(INCLK) Cycle time, CHn_CLK ns
DDR mode 26.66 40 53.33
SDR mode 5 8 10
2 tw(INCLKH) Pulse width, CHn_CLK high ns
DDR mode 10 16 20
SDR mode 5 8 10
3 tw(INCLKL) Pulse width, CHn_CLK low ns
DDR mode 10 16 20
4 tsu(STV-INCLKH) Setup time, CHn_START valid before CHn_CLK high 4 5.5 6.5 ns
5 th(INCLKH-STV) Hold time, CHn_START valid after CHn_CLK high 0.8 0.8 0.8 ns
6 tsu(ENV-INCLKH) Setup time, CHn_ENABLE valid before CHn_CLK high 4 5.5 6.5 ns
7 th(INCLKH-ENV) Hold time, CHn_ENABLE valid after CHn_CLK high 0.8 0.8 0.8 ns
Setup time, CHn_DATA/XDATA valid before CHn_CLK
8 tsu(DV-INCLKH) 4 5.5 6.5 ns
high
9 th(INCLKH-DV) Hold time, CHn_DATA/XDATA valid after CHn_CLK high 0.8 0.8 0.8 ns
Setup time, CHn_DATA/XDATA valid before CHn_CLK
10 tsu(DV-INCLKL) 4 5.5 6.5 ns
low
11 th(INCLKL-DV) Hold time, CHn_DATA/XDATA valid after CHn_CLK low 0.8 0.8 0.8 ns
19 tsu(WTV-INCLKL) Setup time, CHn_WAIT valid before CHn_CLK high 10 12 14 ns
20 th(INCLKL-WTV) Hold time, CHn_WAIT valid after CHn_CLK high 0.8 0.8 0.8 ns
21 tc(2xTXCLK) Cycle time, 2xTXCLK input clock (1) 6.66 10 13.33 ns
(1) 2xTXCLK is an alternate transmit clock source that must be at least 2 times the required uPP transmit clock rate (as it is is divided down
by 2 inside the uPP). 2xTXCLK has no specified skew relationship to the CHn_CLOCK and therefore is not shown in the timing diagram.

Table 6-95. Switching Characteristics Over Recommended Operating Conditions for uPP
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
SDR mode 13.33 20 26.66
12 tc(OUTCLK) Cycle time, CHn_CLK ns
DDR mode 26.66 40 53.33
SDR mode 5 8 10
13 tw(OUTCLKH) Pulse width, CHn_CLK high ns
DDR mode 10 16 20
SDR mode 5 8 10
14 tw(OUTCLKL) Pulse width, CHn_CLK low ns
DDR mode 10 16 20
15 td(OUTCLKH-STV) Delay time, CHn_START valid after CHn_CLK high 2 11 2 15 2 21 ns
16 td(OUTCLKH-ENV) Delay time, CHn_ENABLE valid after CHn_CLK high 2 11 2 15 2 21 ns
17 td(OUTCLKH-DV) Delay time, CHn_DATA/XDATA valid after CHn_CLK high 2 11 2 15 2 21 ns
18 td(OUTCLKL-DV) Delay time, CHn_DATA/XDATA valid after CHn_CLK low 2 11 2 15 2 21 ns

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1 2 3
CHx_CLK
4
5
CHx_START
6
7
CHx_ENABLE

CHx_WAIT
8
9
CHx_DATA[n:0]
Data1 Data2 Data3 Data4 Data5 Data6 Data7 Data8 Data9
CHx_XDATA[n:0]

Figure 6-61. uPP Single Data Rate (SDR) Receive Timing

1 2 3
CHx_CLK
4
5
CHx_START
6
7
CHx_ENABLE

CHx_WAIT

8 10
9 11
CHx_DATA[n:0]
CHx_XDATA[n:0] I1 Q1 I2 Q2 I3 Q3 I4 Q4 I5 Q5 I6 Q6 I7 Q7 I8 Q8 I9 Q9

Figure 6-62. uPP Double Data Rate (DDR) Receive Timing

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12 13 14
CHx_CLK

15
CHx_START

16
CHx_ENABLE

19 20
CHx_WAIT

17
CHx_DATA[n:0] Data1 Data2 Data3 Data4 Data5 Data6 Data7 Data8 Data9
CHx_XDATA[n:0]

Figure 6-63. uPP Single Data Rate (SDR) Transmit Timing

12 13 14
CHx_CLK

15
CHx_START

16
CHx_ENABLE

19 20
CHx_WAIT

17 18
CHx_DATA[n:0]
I1 Q1 I2 Q2 I3 Q3 I4 Q4 I5 Q5 I6 Q6 I7 Q7 I8 Q8 I9 Q9
CHx_XDATA[n:0]

Figure 6-64. uPP Double Data Rate (DDR) Transmit Timing

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6.23 Video Port Interface (VPIF)


The Video Port Interface (VPIF) allows the capture and display of digital video streams. Features include:
• Up to 2 Video Capture Channels (Channel 0 and Channel 1)
– Two 8-bit Standard-Definition (SD) Video with embedded timing codes (BT.656)
– Single 16-bit High-Definition (HD) Video with embedded timing codes (BT.1120)
– Single Raw Video (8-/10-/12-bit)
• Up to 2 Video Display Channels (Channel 2 and Channel 3)
– Two 8-bit SD Video Display with embedded timing codes (BT.656)
– Single 16-bit HD Video Display with embedded timing codes (BT.1120)
The VPIF capture channel input data format is selectable based on the settings of the specific Channel
Control Register (Channels 0–3). The VPIF Raw Video data-bus width is selectable based on the settings
of the Channel 0 Control Register.

6.23.1 VPIF Register Descriptions


Table 6-96 shows the VPIF registers.

Table 6-96. Video Port Interface (VPIF) Registers


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01E1 7000 PID Peripheral identification register
0x01E1 7004 CH0_CTRL Channel 0 control register
0x01E1 7008 CH1_CTRL Channel 1 control register
0x01E1 700C CH2_CTRL Channel 2 control register
0x01E1 7010 CH3_CTRL Channel 3 control register
0x01E1 7014 - 0x01E1 701F - Reserved
0x01E1 7020 INTEN Interrupt enable
0x01E1 7024 INTENSET Interrupt enable set
0x01E1 7028 INTENCLR Interrupt enable clear
0x01E1 702C INTSTAT Interrupt status
0x01E1 7030 INTSTATCLR Interrupt status clear
0x01E1 7034 EMU_CTRL Emulation control
0x01E1 7038 DMA_SIZE DMA size control
0x01E1 703C - 0x01E1 703F - Reserved
CAPTURE CHANNEL 0 REGISTERS
0x01E1 7040 CH0_TY_STRTADR Channel 0 Top Field luma buffer start address
0x01E1 7044 CH0_BY_STRTADR Channel 0 Bottom Field luma buffer start address
0x01E1 7048 CH0_TC_STRTADR Channel 0 Top Field chroma buffer start address
0x01E1 704C CH0_BC_STRTADR Channel 0 Bottom Field chroma buffer start address
0x01E1 7050 CH0_THA_STRTADR Channel 0 Top Field horizontal ancillary data buffer start address
0x01E1 7054 CH0_BHA_STRTADR Channel 0 Bottom Field horizontal ancillary data buffer start address
0x01E1 7058 CH0_TVA_STRTADR Channel 0 Top Field vertical ancillary data buffer start address
0x01E1 705C CH0_BVA_STRTADR Channel 0 Bottom Field vertical ancillary data buffer start address
0x01E1 7060 CH0_SUBPIC_CFG Channel 0 sub-picture configuration
0x01E1 7064 CH0_IMG_ADD_OFST Channel 0 image data address offset
0x01E1 7068 CH0_HA_ADD_OFST Channel 0 horizontal ancillary data address offset
0x01E1 706C CH0_HSIZE_CFG Channel 0 horizontal data size configuration
0x01E1 7070 CH0_VSIZE_CFG0 Channel 0 vertical data size configuration (0)
0x01E1 7074 CH0_VSIZE_CFG1 Channel 0 vertical data size configuration (1)
0x01E1 7078 CH0_VSIZE_CFG2 Channel 0 vertical data size configuration (2)
0x01E1 707C CH0_VSIZE Channel 0 vertical image size

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Table 6-96. Video Port Interface (VPIF) Registers (continued)


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
CAPTURE CHANNEL 1 REGISTERS
0x01E1 7080 CH1_TY_STRTADR Channel 1 Top Field luma buffer start address
0x01E1 7084 CH1_BY_STRTADR Channel 1 Bottom Field luma buffer start address
0x01E1 7088 CH1_TC_STRTADR Channel 1 Top Field chroma buffer start address
0x01E1 708C CH1_BC_STRTADR Channel 1 Bottom Field chroma buffer start address
0x01E1 7090 CH1_THA_STRTADR Channel 1 Top Field horizontal ancillary data buffer start address
0x01E1 7094 CH1_BHA_STRTADR Channel 1 Bottom Field horizontal ancillary data buffer start address
0x01E1 7098 CH1_TVA_STRTADR Channel 1 Top Field vertical ancillary data buffer start address
0x01E1 709C CH1_BVA_STRTADR Channel 1 Bottom Field vertical ancillary data buffer start address
0x01E1 70A0 CH1_SUBPIC_CFG Channel 1 sub-picture configuration
0x01E1 70A4 CH1_IMG_ADD_OFST Channel 1 image data address offset
0x01E1 70A8 CH1_HA_ADD_OFST Channel 1 horizontal ancillary data address offset
0x01E1 70AC CH1_HSIZE_CFG Channel 1 horizontal data size configuration
0x01E1 70B0 CH1_VSIZE_CFG0 Channel 1 vertical data size configuration (0)
0x01E1 70B4 CH1_VSIZE_CFG1 Channel 1 vertical data size configuration (1)
0x01E1 70B8 CH1_VSIZE_CFG2 Channel 1 vertical data size configuration (2)
0x01E1 70BC CH1_VSIZE Channel 1 vertical image size
DISPLAY CHANNEL 2 REGISTERS
0x01E1 70C0 CH2_TY_STRTADR Channel 2 Top Field luma buffer start address
0x01E1 70C4 CH2_BY_STRTADR Channel 2 Bottom Field luma buffer start address
0x01E1 70C8 CH2_TC_STRTADR Channel 2 Top Field chroma buffer start address
0x01E1 70CC CH2_BC_STRTADR Channel 2 Bottom Field chroma buffer start address
0x01E1 70D0 CH2_THA_STRTADR Channel 2 Top Field horizontal ancillary data buffer start address
0x01E1 70D4 CH2_BHA_STRTADR Channel 2 Bottom Field horizontal ancillary data buffer start address
0x01E1 70D8 CH2_TVA_STRTADR Channel 2 Top Field vertical ancillary data buffer start address
0x01E1 70DC CH2_BVA_STRTADR Channel 2 Bottom Field vertical ancillary data buffer start address
0x01E1 70E0 CH2_SUBPIC_CFG Channel 2 sub-picture configuration
0x01E1 70E4 CH2_IMG_ADD_OFST Channel 2 image data address offset
0x01E1 70E8 CH2_HA_ADD_OFST Channel 2 horizontal ancillary data address offset
0x01E1 70EC CH2_HSIZE_CFG Channel 2 horizontal data size configuration
0x01E1 70F0 CH2_VSIZE_CFG0 Channel 2 vertical data size configuration (0)
0x01E1 70F4 CH2_VSIZE_CFG1 Channel 2 vertical data size configuration (1)
0x01E1 70F8 CH2_VSIZE_CFG2 Channel 2 vertical data size configuration (2)
0x01E1 70FC CH2_VSIZE Channel 2 vertical image size
0x01E1 7100 CH2_THA_STRTPOS Channel 2 Top Field horizontal ancillary data insertion start position
0x01E1 7104 CH2_THA_SIZE Channel 2 Top Field horizontal ancillary data size
0x01E1 7108 CH2_BHA_STRTPOS Channel 2 Bottom Field horizontal ancillary data insertion start position
0x01E1 710C CH2_BHA_SIZE Channel 2 Bottom Field horizontal ancillary data size
0x01E1 7110 CH2_TVA_STRTPOS Channel 2 Top Field vertical ancillary data insertion start position
0x01E1 7114 CH2_TVA_SIZE Channel 2 Top Field vertical ancillary data size
0x01E1 7118 CH2_BVA_STRTPOS Channel 2 Bottom Field vertical ancillary data insertion start position
0x01E1 711C CH2_BVA_SIZE Channel 2 Bottom Field vertical ancillary data size
0x01E1 7120 - 0x01E1 713F - Reserved
DISPLAY CHANNEL 3 REGISTERS
0x01E1 7140 CH3_TY_STRTADR Channel 3 Field 0 luma buffer start address
0x01E1 7144 CH3_BY_STRTADR Channel 3 Field 1 luma buffer start address
0x01E1 7148 CH3_TC_STRTADR Channel 3 Field 0 chroma buffer start address

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Table 6-96. Video Port Interface (VPIF) Registers (continued)


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01E1 714C CH3_BC_STRTADR Channel 3 Field 1 chroma buffer start address
0x01E1 7150 CH3_THA_STRTADR Channel 3 Field 0 horizontal ancillary data buffer start address
0x01E1 7154 CH3_BHA_STRTADR Channel 3 Field 1 horizontal ancillary data buffer start address
0x01E1 7158 CH3_TVA_STRTADR Channel 3 Field 0 vertical ancillary data buffer start address
0x01E1 715C CH3_BVA_STRTADR Channel 3 Field 1 vertical ancillary data buffer start address
0x01E1 7160 CH3_SUBPIC_CFG Channel 3 sub-picture configuration
0x01E1 7164 CH3_IMG_ADD_OFST Channel 3 image data address offset
0x01E1 7168 CH3_HA_ADD_OFST Channel 3 horizontal ancillary data address offset
0x01E1 716C CH3_HSIZE_CFG Channel 3 horizontal data size configuration
0x01E1 7170 CH3_VSIZE_CFG0 Channel 3 vertical data size configuration (0)
0x01E1 7174 CH3_VSIZE_CFG1 Channel 3 vertical data size configuration (1)
0x01E1 7178 CH3_VSIZE_CFG2 Channel 3 vertical data size configuration (2)
0x01E1 717C CH3_VSIZE Channel 3 vertical image size
0x01E1 7180 CH3_THA_STRTPOS Channel 3 Top Field horizontal ancillary data insertion start position
0x01E1 7184 CH3_THA_SIZE Channel 3 Top Field horizontal ancillary data size
0x01E1 7188 CH3_BHA_STRTPOS Channel 3 Bottom Field horizontal ancillary data insertion start position
0x01E1 718C CH3_BHA_SIZE Channel 3 Bottom Field horizontal ancillary data size
0x01E1 7190 CH3_TVA_STRTPOS Channel 3 Top Field vertical ancillary data insertion start position
0x01E1 7194 CH3_TVA_SIZE Channel 3 Top Field vertical ancillary data size
0x01E1 7198 CH3_BVA_STRTPOS Channel 3 Bottom Field vertical ancillary data insertion start position
0x01E1 719C CH3_BVA_SIZE Channel 3 Bottom Field vertical ancillary data size
0x01E1 71A0 - 0x01E1 71FF - Reserved

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6.23.2 VPIF Electrical Data/Timing

Table 6-97. Timing Requirements for VPIF VP_CLKINx Inputs (1) (see Figure 6-65)
1.3V, 1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX
Cycle time, VP_CLKIN0 13.3 20 37 ns
1 tc(VKI)
Cycle time, VP_CLKIN1/2/3 13.3 20 37 ns
2 tw(VKIH) Pulse duration, VP_CLKINx high 0.4C 0.4C 0.4C ns
3 tw(VKIL) Pulse duration, VP_CLKINx low 0.4C 0.4C 0.4C ns
4 tt(VKI) Transition time, VP_CLKINx 5 5 5 ns
(1) C = VP_CLKINx period in ns.

1 4

2 3

VP_CLKINx

Figure 6-65. Video Port Capture VP_CLKINx Timing

Table 6-98. Timing Requirements for VPIF Channels 0/1 Video Capture Data and Control Inputs
(see Figure 6-66)
1.3V 1.2V 1.1V 1.0V
NO. UNIT
MIN MAX MIN MAX MIN MAX MIN MAX
Setup time, VP_DINx valid before
1 tsu(VDINV-VKIH) 4 4 6 7 ns
VP_CLKIN0/1 high
Hold time, VP_DINx valid after
2 th(VKIH-VDINV) 0.5 0 0 0 ns
VP_CLKIN0/1 high

VP_CLKIN0/1

VP_DINx/FIELD/
HSYNC/VSYNC

Figure 6-66. VPIF Channels 0/1 Video Capture Data and Control Input Timing

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Table 6-99. Switching Characteristics Over Recommended Operating Conditions for Video Data Shown
With Respect to VP_CLKOUT2/3 (1)
(see Figure 6-67)
1.3V, 1.2V 1.1V 1.0V
NO. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
1 tc(VKO) Cycle time, VP_CLKOUT2/3 13.3 20 37 ns
2 tw(VKOH) Pulse duration, VP_CLKOUT2/3 high 0.4C 0.4C 0.4C ns
3 tw(VKOL) Pulse duration, VP_CLKOUT2/3 low 0.4C 0.4C 0.4C ns
4 tt(VKO) Transition time, VP_CLKOUT2/3 5 5 5 ns
Delay time,
11 td(VKOH-VPDOUTV) 8.5 12 17 ns
VP_CLKOUT2/3 high to VP_DOUTx valid
Delay time,
12 td(VCLKOH-VPDOUTIV) 1.5 1.5 1.5 ns
VP_CLKOUT2/3 high to VP_DOUTx invalid
(1) C = VP_CLKO2/3 period in ns.

2
VP_CLKOUTx 1
(Positive Edge 3
Clocking)
4 4
VP_CLKOUTx
(Negative Edge
Clocking)
11 12

VP_DOUTx

Figure 6-67. VPIF Channels 2/3 Video Display Data Output Timing With Respect to VP_CLKOUT2/3

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6.24 Enhanced Capture (eCAP) Peripheral


The device contains up to three enhanced capture (eCAP) modules. Figure 6-68 shows a functional block
diagram of a module.
Uses for ECAP include:
• Speed measurements of rotating machinery (e.g. toothed sprockets sensed via Hall sensors)
• Elapsed time measurements between position sensor triggers
• Period and duty cycle measurements of pulse train signals
• Decoding current or voltage amplitude derived from duty cycle encoded current/voltage sensors
The ECAP module described in this specification includes the following features:
• 32 bit time base
• 4 event time-stamp registers (each 32 bits)
• Edge polarity selection for up to 4 sequenced time-stamp capture events
• Interrupt on either of the 4 events
• Single shot capture of up to 4 event time-stamps
• Continuous mode capture of time-stamps in a 4 deep circular buffer
• Absolute time-stamp capture
• Difference mode time-stamp capture
• All the above resources are dedicated to a single input pin
The eCAP modules are clocked at the ASYNC3 clock domain rate.

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CTRPHS
(phase register−32 bit) APWM mode

SYNC
SYNCIn
OVF CTR_OVF
TSCTR CTR [0−31]
SYNCOut PWM
(counter−32 bit) Delta−mode PRD [0−31] compare
RST
logic
CMP [0−31]
32

CTR [0−31] CTR=PRD


CTR=CMP
32
PRD [0−31]

eCAPx

MODE SELECT
32 CAP1 LD1 Polarity
LD
(APRD active) select

APRD 32
shadow CMP [0−31]
32

32 CAP2 LD2 Polarity


LD
(ACMP active) select

Event Event
32 ACMP
qualifier
shadow Pre-scale

32 Polarity
CAP3 LD3 select
LD
(APRD shadow)

32 CAP4 LD4
LD Polarity
(ACMP shadow) select

4
Capture events 4

CEVT[1:4]

Interrupt Continuous /
to Interrupt Trigger Oneshot
Controller and CTR_OVF Capture Control
Flag
CTR=PRD
control
CTR=CMP

Figure 6-68. eCAP Functional Block Diagram

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Table 6-100 is the list of the ECAP registers.

Table 6-100. ECAPx Configuration Registers


ECAP0 ECAP1 ECAP2
ACRONYM DESCRIPTION
BYTE ADDRESS BYTE ADDRESS BYTE ADDRESS
0x01F0 6000 0x01F0 7000 0x01F0 8000 TSCTR Time-Stamp Counter
0x01F0 6004 0x01F0 7004 0x01F0 8004 CTRPHS Counter Phase Offset Value Register
0x01F0 6008 0x01F0 7008 0x01F0 8008 CAP1 Capture 1 Register
0x01F0 600C 0x01F0 700C 0x01F0 800C CAP2 Capture 2 Register
0x01F0 6010 0x01F0 7010 0x01F0 8010 CAP3 Capture 3 Register
0x01F0 6014 0x01F0 7014 0x01F0 8014 CAP4 Capture 4 Register
0x01F0 6028 0x01F0 7028 0x01F0 8028 ECCTL1 Capture Control Register 1
0x01F0 602A 0x01F0 702A 0x01F0 802A ECCTL2 Capture Control Register 2
0x01F0 602C 0x01F0 702C 0x01F0 802C ECEINT Capture Interrupt Enable Register
0x01F0 602E 0x01F0 702E 0x01F0 802E ECFLG Capture Interrupt Flag Register
0x01F0 6030 0x01F0 7030 0x01F0 8030 ECCLR Capture Interrupt Clear Register
0x01F0 6032 0x01F0 7032 0x01F0 8032 ECFRC Capture Interrupt Force Register
0x01F0 605C 0x01F0 705C 0x01F0 805C REVID Revision ID

Table 6-101 shows the eCAP timing requirement and Table 6-102 shows the eCAP switching
characteristics.

Table 6-101. Timing Requirements for Enhanced Capture (eCAP)


TEST 1.3V, 1.2V, 1.1V, 1.0V UNIT
CONDITIONS
MIN MAX
tw(CAP) Capture input pulse width Asynchronous 2tc(SCO) cycles
Synchronous 2tc(SCO) cycles

Table 6-102. Switching Characteristics Over Recommended Operating Conditions for eCAP
PARAMETER 1.3V, 1.2V 1.1V 1.0V UNIT
MIN MAX MIN MAX MIN MAX
tw(APWM) Pulse duration, APWMx 20 20 20 ns
output high/low

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6.25 Enhanced High-Resolution Pulse-Width Modulator (eHRPWM)


The device contains two enhanced PWM Modules (eHRPWM). Figure 6-69 shows a block diagram of
multiple eHRPWM modules. Figure 4-4 shows the signal interconnections with the eHRPWM.

EPWMSYNCI

EPWM0SYNCI
EPWM0INT EPWM0A

ePWM0 module EPWM0B

TZ
Interrupt EPWM0SYNCO
Controllers
GPIO
MUX

EPWM1SYNCI
EPWM1INT EPWM1A

ePWM1 module EPWM1B

TZ
EPWM1SYNCO
To eCAP0 EPWMSYNCO
module
(sync in)

Peripheral Bus

Figure 6-69. Multiple PWM Modules in an AM1806 System

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Time−base (TB)

Sync
TBPRD shadow (16) CTR=ZERO in/out
select EPWMSYNCO
CTR=CMPB
TBPRD active (16) Mux
Disabled

CTR=PRD
TBCTL[SYNCOSEL]
TBCTL[CNTLDE]

Counter EPWMSYNCI
up/down TBCTL[SWFSYNC]
(16 bit) (software forced sync)
CTR=ZERO
TBCNT
active (16) CTR_Dir

TBPHSHR (8)
16 8
Phase CTR = PRD
TBPHS active (24) Event
control CTR = ZERO trigger
CTR = CMPA and EPWMxINT
CTR = CMPB interrupt
(ET)
Counter compare (CC) Action CTR_Dir
qualifier
CTR=CMPA (AQ)
CMPAHR (8)
16 8 HiRes PWM (HRPWM)

CMPA active (24)


EPWMA EPWMxA
CMPA shadow (24)

CTR=CMPB Dead PWM Trip


band chopper zone
16 (DB) (PC) (TZ)
EPWMB EPWMxB
CMPB active (16)
EPWMxTZINT
CMPB shadow (16) CTR = ZERO TZ

Figure 6-70. eHRPWM Sub-Modules Showing Critical Internal Signal Interconnections

6.25.1 eHRPWM Register Descriptions


Table 6-103 shows the eHRPWM registers.

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Table 6-103. eHRPWM Module Control and Status Registers Grouped by Submodule
eHRPWM0 eHRPWM1
BYTE ADDRESS BYTE ADDRESS ACRONYM SHADOW REGISTER DESCRIPTION
Time-Base Submodule Registers
0x01F0 0000 0x01F0 2000 TBCTL No Time-Base Control Register
0x01F0 0002 0x01F0 2002 TBSTS No Time-Base Status Register
(1)
0x01F0 0004 0x01F0 2004 TBPHSHR No Extension for HRPWM Phase Register
0x01F0 0006 0x01F0 2006 TBPHS No Time-Base Phase Register
0x01F0 0008 0x01F0 2008 TBCNT No Time-Base Counter Register
0x01F0 000A 0x01F0 200A TBPRD Yes Time-Base Period Register
Counter-Compare Submodule Registers
0x01F0 000E 0x01F0 200E CMPCTL No Counter-Compare Control Register
(1)
0x01F0 0010 0x01F0 2010 CMPAHR No Extension for HRPWM Counter-Compare A Register
0x01F0 0012 0x01F0 2012 CMPA Yes Counter-Compare A Register
0x01F0 0014 0x01F0 2014 CMPB Yes Counter-Compare B Register
Action-Qualifier Submodule Registers
0x01F0 0016 0x01F0 2016 AQCTLA No Action-Qualifier Control Register for Output A (eHRPWMxA)
0x01F0 0018 0x01F0 2018 AQCTLB No Action-Qualifier Control Register for Output B (eHRPWMxB)
0x01F0 001A 0x01F0 201A AQSFRC No Action-Qualifier Software Force Register
0x01F0 001C 0x01F0 201C AQCSFRC Yes Action-Qualifier Continuous S/W Force Register Set
Dead-Band Generator Submodule Registers
0x01F0 001E 0x01F0 201E DBCTL No Dead-Band Generator Control Register
0x01F0 0020 0x01F0 2020 DBRED No Dead-Band Generator Rising Edge Delay Count Register
0x01F0 0022 0x01F0 2022 DBFED No Dead-Band Generator Falling Edge Delay Count Register
PWM-Chopper Submodule Registers
0x01F0 003C 0x01F0 203C PCCTL No PWM-Chopper Control Register
Trip-Zone Submodule Registers
0x01F0 0024 0x01F0 2024 TZSEL No Trip-Zone Select Register
0x01F0 0028 0x01F0 2028 TZCTL No Trip-Zone Control Register
0x01F0 002A 0x01F0 202A TZEINT No Trip-Zone Enable Interrupt Register
0x01F0 002C 0x01F0 202C TZFLG No Trip-Zone Flag Register
0x01F0 002E 0x01F0 202E TZCLR No Trip-Zone Clear Register
0x01F0 0030 0x01F0 2030 TZFRC No Trip-Zone Force Register
Event-Trigger Submodule Registers
0x01F0 0032 0x01F0 2032 ETSEL No Event-Trigger Selection Register
0x01F0 0034 0x01F0 2034 ETPS No Event-Trigger Pre-Scale Register
0x01F0 0036 0x01F0 2036 ETFLG No Event-Trigger Flag Register
0x01F0 0038 0x01F0 2038 ETCLR No Event-Trigger Clear Register
0x01F0 003A 0x01F0 203A ETFRC No Event-Trigger Force Register
High-Resolution PWM (HRPWM) Submodule Registers
(1)
0x01F0 1040 0x01F0 3040 HRCNFG No HRPWM Configuration Register
(1) These registers are only available on eHRPWM instances that include the high-resolution PWM (HRPWM) extension; otherwise, these
locations are reserved.

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6.25.2 Enhanced Pulse Width Modulator (eHRPWM) Timing


PWM refers to PWM outputs on eHRPWM1-6. Table 6-104 shows the PWM timing requirements and
Table 6-105, switching characteristics.

Table 6-104. Timing Requirements for eHRPWM


TEST 1.3V, 1.2V, 1.1V, 1.0V
CONDITIONS UNIT
MIN MAX
tw(SYNCIN) Sync input pulse width Asynchronous 2tc(SCO) cycles
Synchronous 2tc(SCO) cycles

Table 6-105. Switching Characteristics Over Recommended Operating Conditions for eHRPWM
PARAMETER TEST 1.3V, 1.2V 1.1V 1.0V UNIT
CONDITIONS
MIN MAX MIN MAX MIN MAX
tw(PWM) Pulse duration, ns
20 20 26.6
PWMx output high/low
tw(SYNCOUT) Sync output cycles
8tc(SCO) 8tc(SCO) 8tc(SCO)
pulse width
td(PWM)TZA Delay time, trip input no pin load; no ns
active to PWM forced high additional
Delay time, programmable 25 25 25
trip input active to PWM delay
forced low
td(TZ-PWM)HZ Delay time, no additional ns
trip input active to PWM Hi-Z programmable 20 20 20
delay

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6.25.3 Trip-Zone Input Timing

tw(TZ)

TZ

td(TZ-PWM)HZ

PWM(A)

A. PWM refers to all the PWM pins in the device. The state of the PWM pins after TZ is taken high depends on the PWM
recovery software.

Figure 6-71. PWM Hi-Z Characteristics

Table 6-106. Trip-Zone input Timing Requirements


TEST CONDITIONS 1.3V, 1.2V, 1.1V, 1.0V
UNIT
MIN MAX
tw(TZ) Pulse duration, TZx input low Asynchronous 1tc(SCO) cycles
Synchronous 2tc(SCO) cycles

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6.26 Timers
The timers support the following features:
• Configurable as single 64-bit timer or two 32-bit timers
• Period timeouts generate interrupts, DMA events or external pin events
• 8 32-bit compare registers
• Compare matches generate interrupt events
• Capture capability
• 64-bit Watchdog capability (Timer64P1 only)
Table 6-107 lists the timer registers.

Table 6-107. Timer Registers


TIMER64P 0 TIMER64P 1 TIMER64P 2 TIMER64P 3 ACRONYM REGISTER DESCRIPTION
BYTE BYTE BYTE ADDRESS BYTE ADDRESS
ADDRESS ADDRESS
0x01C2 0000 0x01C2 1000 0x01F0 C000 0x01F0 D000 REV Revision Register
0x01C2 0004 0x01C2 1004 0x01F0 C004 0x01F0 D004 EMUMGT Emulation Management Register
0x01C2 0008 0x01C2 1008 0x01F0 C008 0x01F0 D008 GPINTGPEN GPIO Interrupt and GPIO Enable Register
0x01C2 000C 0x01C2 100C 0x01F0 C00C 0x01F0 D00C GPDATGPDIR GPIO Data and GPIO Direction Register
0x01C2 0010 0x01C2 1010 0x01F0 C010 0x01F0 D010 TIM12 Timer Counter Register 12
0x01C2 0014 0x01C2 1014 0x01F0 C014 0x01F0 D014 TIM34 Timer Counter Register 34
0x01C2 0018 0x01C2 1018 0x01F0 C018 0x01F0 D018 PRD12 Timer Period Register 12
0x01C2 001C 0x01C2 101C 0x01F0 C01C 0x01F0 D01C PRD34 Timer Period Register 34
0x01C2 0020 0x01C2 1020 0x01F0 C020 0x01F0 D020 TCR Timer Control Register
0x01C2 0024 0x01C2 1024 0x01F0 C024 0x01F0 D024 TGCR Timer Global Control Register
0x01C2 0028 0x01C2 1028 0x01F0 C028 0x01F0 D028 WDTCR Watchdog Timer Control Register
0x01C2 0034 0x01C2 1034 0x01F0 C034 0x01F0 D034 REL12 Timer Reload Register 12
0x01C2 0038 0x01C2 1038 0x01F0 C038 0x01F0 D038 REL34 Timer Reload Register 34
0x01C2 003C 0x01C2 103C 0x01F0 C03C 0x01F0 D03C CAP12 Timer Capture Register 12
0x01C2 0040 0x01C2 1040 0x01F0 C040 0x01F0 D040 CAP34 Timer Capture Register 34
0x01C2 0044 0x01C2 1044 0x01F0 C044 0x01F0 D044 INTCTLSTAT Timer Interrupt Control and Status Register
0x01C2 0060 0x01C2 1060 0x01F0 C060 0x01F0 D060 CMP0 Compare Register 0
0x01C2 0064 0x01C2 1064 0x01F0 C064 0x01F0 D064 CMP1 Compare Register 1
0x01C2 0068 0x01C2 1068 0x01F0 C068 0x01F0 D068 CMP2 Compare Register 2
0x01C2 006C 0x01C2 106C 0x01F0 C06C 0x01F0 D06C CMP3 Compare Register 3
0x01C2 0070 0x01C2 1070 0x01F0 C070 0x01F0 D070 CMP4 Compare Register 4
0x01C2 0074 0x01C2 1074 0x01F0 C074 0x01F0 D074 CMP5 Compare Register 5
0x01C2 0078 0x01C2 1078 0x01F0 C078 0x01F0 D078 CMP6 Compare Register 6
0x01C2 007C 0x01C2 107C 0x01F0 C07C 0x01F0 D07C CMP7 Compare Register 7

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6.26.1 Timer Electrical Data/Timing

Table 6-108. Timing Requirements for Timer Input (1) (2)


(see Figure 6-72)
1.3V, 1.2V, 1.1V, 1.0V
NO. UNIT
MIN MAX
1 tc(TM64Px_IN12) Cycle time, TM64Px_IN12 4P ns
2 tw(TINPH) Pulse duration, TM64Px_IN12 high 0.45C 0.55C ns
3 tw(TINPL) Pulse duration, TM64Px_IN12 low 0.45C 0.55C ns
4 tt(TM64Px_IN12) Transition time, TM64Px_IN12 0.05C or 10 (3) ns
(1) P = OSCIN cycle time in ns.
(2) C = TM64P0_IN12 cycle time in ns. For example, when TM64Px_IN12 frequency is 27 MHz, use C = 37.037 ns
(3) Whichever is smaller. P = the period of the applied signal. Maintaining transition times as fast as possible is recommended to improve
noise immunity on input signals.

2
3
4 4
TM64P0_IN12

Figure 6-72. Timer Timing

(1)
Table 6-109. Switching Characteristics Over Recommended Operating Conditions for Timer Output
1.3V, 1.2V, 1.1V, 1.0V
NO. PARAMETER UNIT
MIN MAX
5 tw(TOUTH) Pulse duration, TM64P0_OUT12 high 4P ns
6 tw(TOUTL) Pulse duration, TM64P0_OUT12 low 4P ns
(1) P = OSCIN cycle time in ns.

5
6
TM64P0_OUT12

Figure 6-73. Timer Timing

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6.27 Real Time Clock (RTC)


The RTC provides a time reference to an application running on the device. The current date and time is
tracked in a set of counter registers that update once per second. The time can be represented in 12-hour
or 24-hour mode. The calendar and time registers are buffered during reads and writes so that updates do
not interfere with the accuracy of the time and date.
Alarms are available to interrupt the CPU at a particular time, or at periodic time intervals, such as once
per minute or once per day. In addition, the RTC can interrupt the CPU every time the calendar and time
registers are updated, or at programmable periodic intervals.
The real-time clock (RTC) provides the following features:
• 100-year calendar (xx00 to xx99)
• Counts seconds, minutes, hours, day of the week, date, month, and year with leap year compensation
• Binary-coded-decimal (BCD) representation of time, calendar, and alarm
• 12-hour clock mode (with AM and PM) or 24-hour clock mode
• Alarm interrupt
• Periodic interrupt
• Single interrupt to the CPU
• Supports external 32.768-kHz crystal or external clock source of the same frequency
• Separate isolated power supply
Figure 6-74 shows a block diagram of the RTC.

Counter Oscillator Week


RTC_XI 32 kHz Compensation Days

XTAL

Seconds Minutes Hours Days Months Years


RTC_XO
Oscillator

Alarm
Alarm Interrupts

Periodic
Timer Interrupts

Figure 6-74. Real-Time Clock Block Diagram

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6.27.1 Clock Source


The clock reference for the RTC is an external 32.768-kHz crystal or an external clock source of the same
frequency. The RTC also has a separate power supply that is isolated from the rest of the system. When
the CPU and other peripherals are without power, the RTC can remain powered to preserve the current
time and calendar information. Even if the RTC is not used, it must remain powered when the rest of the
device is powered.
The source for the RTC reference clock may be provided by a crystal or by an external clock source. The
RTC has an internal oscillator buffer to support direct operation with a crystal. The crystal is connected
between pins RTC_XI and RTC_XO. RTC_XI is the input to the on-chip oscillator and RTC_XO is the
output from the oscillator back to the crystal.
An external 32.768-kHz clock source may be used instead of a crystal. In such a case, the clock source is
connected to RTC_XI, and RTC_XO is left unconnected.
If the RTC is not used, the RTC_XI pin should be held either low or high, RTC_XO should be left
unconnected, RTC_CVDD should be connected to the device CVDD and RTC_VSS should remain
grounded.

CVDD

RTC
Power RTC_CVDD
Source
C2
RTC_XI

XTAL
32.768 Real
kHz Time
RTC_XO 32K
Clock
OSC
(RTC)
C1 Module

RTC_VSS

Isolated RTC
Power Domain

Figure 6-75. Clock Source

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6.27.2 Real-Time Clock Register Descriptions

Table 6-110. Real-Time Clock (RTC) Registers


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01C2 3000 SECOND Seconds Register
0x01C2 3004 MINUTE Minutes Register
0x01C2 3008 HOUR Hours Register
0x01C2 300C DAY Day of the Month Register
0x01C2 3010 MONTH Month Register
0x01C2 3014 YEAR Year Register
0x01C2 3018 DOTW Day of the Week Register
0x01C2 3020 ALARMSECOND Alarm Seconds Register
0x01C2 3024 ALARMMINUTE Alarm Minutes Register
0x01C2 3028 ALARMHOUR Alarm Hours Register
0x01C2 302C ALARMDAY Alarm Days Register
0x01C2 3030 ALARMMONTH Alarm Months Register
0x01C2 3034 ALARMYEAR Alarm Years Register
0x01C2 3040 CTRL Control Register
0x01C2 3044 STATUS Status Register
0x01C2 3048 INTERRUPT Interrupt Enable Register
0x01C2 304C COMPLSB Compensation (LSB) Register
0x01C2 3050 COMPMSB Compensation (MSB) Register
0x01C2 3054 OSC Oscillator Register
0x01C2 3060 SCRATCH0 Scratch 0 (General-Purpose) Register
0x01C2 3064 SCRATCH1 Scratch 1 (General-Purpose) Register
0x01C2 3068 SCRATCH2 Scratch 2 (General-Purpose) Register
0x01C2 306C KICK0 Kick 0 (Write Protect) Register
0x01C2 3070 KICK1 Kick 1 (Write Protect) Register

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6.28 General-Purpose Input/Output (GPIO)


The GPIO peripheral provides general-purpose pins that can be configured as either inputs or outputs.
When configured as an output, a write to an internal register can control the state driven on the output pin.
When configured as an input, the state of the input is detectable by reading the state of an internal
register. In addition, the GPIO peripheral can produce CPU interrupts and EDMA events in different
interrupt/event generation modes. The GPIO peripheral provides generic connections to external devices.
The GPIO pins are grouped into banks of 16 pins per bank (i.e., bank 0 consists of GPIO [0:15]).
The device GPIO peripheral supports the following:
• Up to 144 Pins configurable as GPIO
• External Interrupt and DMA request Capability
– Every GPIO pin may be configured to generate an interrupt request on detection of rising and/or
falling edges on the pin.
– The interrupt requests within each bank are combined (logical or) to create eight unique bank level
interrupt requests.
– The bank level interrupt service routine may poll the INTSTATx register for its bank to determine
which pin(s) have triggered the interrupt.
– GPIO Banks 0, 1, 2, 3, 4, 5, 6, 7 and 8 Interrupts assigned to ARM INTC Interrupt Requests 42, 43,
44, 45, 46, 47, 48, 49 and 50 respectively
– GPIO Banks 0, 1, 2, 3, 4, and 5 are assigned to EDMA events 6, 7, 22, 23, 28, 29, and 29
respectively on Channel Controller 0 and GPIO Banks 6, 7, and 8 are assigned to EDMA events
16, 17, and 18 respectively on Channel Controller 1.
• Set/clear functionality: Firmware writes 1 to corresponding bit position(s) to set or to clear GPIO
signal(s). This allows multiple firmware processes to toggle GPIO output signals without critical section
protection (disable interrupts, program GPIO, re-enable interrupts, to prevent context switching to
anther process during GPIO programming).
• Separate Input/Output registers
• Output register in addition to set/clear so that, if preferred by firmware, some GPIO output signals can
be toggled by direct write to the output register(s).
• Output register, when read, reflects output drive status. This, in addition to the input register reflecting
pin status and open-drain I/O cell, allows wired logic be implemented.
The memory map for the GPIO registers is shown in Table 6-111.

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6.28.1 GPIO Register Description(s)

Table 6-111. GPIO Registers


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01E2 6000 REV Peripheral Revision Register
0x01E2 6004 RESERVED Reserved
0x01E2 6008 BINTEN GPIO Interrupt Per-Bank Enable Register
GPIO Banks 0 and 1
0x01E2 6010 DIR01 GPIO Banks 0 and 1 Direction Register
0x01E2 6014 OUT_DATA01 GPIO Banks 0 and 1 Output Data Register
0x01E2 6018 SET_DATA01 GPIO Banks 0 and 1 Set Data Register
0x01E2 601C CLR_DATA01 GPIO Banks 0 and 1 Clear Data Register
0x01E2 6020 IN_DATA01 GPIO Banks 0 and 1 Input Data Register
0x01E2 6024 SET_RIS_TRIG01 GPIO Banks 0 and 1 Set Rising Edge Interrupt Register
0x01E2 6028 CLR_RIS_TRIG01 GPIO Banks 0 and 1 Clear Rising Edge Interrupt Register
0x01E2 602C SET_FAL_TRIG01 GPIO Banks 0 and 1 Set Falling Edge Interrupt Register
0x01E2 6030 CLR_FAL_TRIG01 GPIO Banks 0 and 1 Clear Falling Edge Interrupt Register
0x01E2 6034 INTSTAT01 GPIO Banks 0 and 1 Interrupt Status Register
GPIO Banks 2 and 3
0x01E2 6038 DIR23 GPIO Banks 2 and 3 Direction Register
0x01E2 603C OUT_DATA23 GPIO Banks 2 and 3 Output Data Register
0x01E2 6040 SET_DATA23 GPIO Banks 2 and 3 Set Data Register
0x01E2 6044 CLR_DATA23 GPIO Banks 2 and 3 Clear Data Register
0x01E2 6048 IN_DATA23 GPIO Banks 2 and 3 Input Data Register
0x01E2 604C SET_RIS_TRIG23 GPIO Banks 2 and 3 Set Rising Edge Interrupt Register
0x01E2 6050 CLR_RIS_TRIG23 GPIO Banks 2 and 3 Clear Rising Edge Interrupt Register
0x01E2 6054 SET_FAL_TRIG23 GPIO Banks 2 and 3 Set Falling Edge Interrupt Register
0x01E2 6058 CLR_FAL_TRIG23 GPIO Banks 2 and 3 Clear Falling Edge Interrupt Register
0x01E2 605C INTSTAT23 GPIO Banks 2 and 3 Interrupt Status Register
GPIO Banks 4 and 5
0x01E2 6060 DIR45 GPIO Banks 4 and 5 Direction Register
0x01E2 6064 OUT_DATA45 GPIO Banks 4 and 5 Output Data Register
0x01E2 6068 SET_DATA45 GPIO Banks 4 and 5 Set Data Register
0x01E2 606C CLR_DATA45 GPIO Banks 4 and 5 Clear Data Register
0x01E2 6070 IN_DATA45 GPIO Banks 4 and 5 Input Data Register
0x01E2 6074 SET_RIS_TRIG45 GPIO Banks 4 and 5 Set Rising Edge Interrupt Register
0x01E2 6078 CLR_RIS_TRIG45 GPIO Banks 4 and 5 Clear Rising Edge Interrupt Register
0x01E2 607C SET_FAL_TRIG45 GPIO Banks 4 and 5 Set Falling Edge Interrupt Register
0x01E2 6080 CLR_FAL_TRIG45 GPIO Banks 4 and 5 Clear Falling Edge Interrupt Register
0x01E2 6084 INTSTAT45 GPIO Banks 4 and 5 Interrupt Status Register

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Table 6-111. GPIO Registers (continued)


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
GPIO Banks 6 and 7
0x01E2 6088 DIR67 GPIO Banks 6 and 7 Direction Register
0x01E2 608C OUT_DATA67 GPIO Banks 6 and 7 Output Data Register
0x01E2 6090 SET_DATA67 GPIO Banks 6 and 7 Set Data Register
0x01E2 6094 CLR_DATA67 GPIO Banks 6 and 7 Clear Data Register
0x01E2 6098 IN_DATA67 GPIO Banks 6 and 7 Input Data Register
0x01E2 609C SET_RIS_TRIG67 GPIO Banks 6 and 7 Set Rising Edge Interrupt Register
0x01E2 60A0 CLR_RIS_TRIG67 GPIO Banks 6 and 7 Clear Rising Edge Interrupt Register
0x01E2 60A4 SET_FAL_TRIG67 GPIO Banks 6 and 7 Set Falling Edge Interrupt Register
0x01E2 60A8 CLR_FAL_TRIG67 GPIO Banks 6 and 7 Clear Falling Edge Interrupt Register
0x01E2 60AC INTSTAT67 GPIO Banks 6 and 7 Interrupt Status Register
GPIO Bank 8
0x01E2 60B0 DIR8 GPIO Bank 8 Direction Register
0x01E2 60B4 OUT_DATA8 GPIO Bank 8 Output Data Register
0x01E2 60B8 SET_DATA8 GPIO Bank 8 Set Data Register
0x01E2 60BC CLR_DATA8 GPIO Bank 8 Clear Data Register
0x01E2 60C0 IN_DATA8 GPIO Bank 8 Input Data Register
0x01E2 60C4 SET_RIS_TRIG8 GPIO Bank 8 Set Rising Edge Interrupt Register
0x01E2 60C8 CLR_RIS_TRIG8 GPIO Bank 8 Clear Rising Edge Interrupt Register
0x01E2 60CC SET_FAL_TRIG8 GPIO Bank 8 Set Falling Edge Interrupt Register
0x01E2 60D0 CLR_FAL_TRIG8 GPIO Bank 8 Clear Falling Edge Interrupt Register
0x01E2 60D4 INTSTAT8 GPIO Bank 8 Interrupt Status Register

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6.28.2 GPIO Peripheral Input/Output Electrical Data/Timing

Table 6-112. Timing Requirements for GPIO Inputs (1) (see Figure 6-76)
1.3V, 1.2V, 1.1V, 1.0V
NO. UNIT
MIN MAX
1 tw(GPIH) Pulse duration, GPn[m] as input high 2C (1) (2)
ns
2 tw(GPIL) Pulse duration, GPn[m] as input low 2C (1) (2)
ns
(1) The pulse width given is sufficient to generate a CPU interrupt or an EDMA event. However, if a user wants to have the device
recognize the GPIx changes through software polling of the GPIO register, the GPIx duration must be extended to allow the device
enough time to access the GPIO register through the internal bus.
(2) C=SYSCLK4 period in ns.

Table 6-113. Switching Characteristics Over Recommended Operating Conditions for GPIO Outputs
(see Figure 6-76)
1.3V, 1.2V, 1.1V, 1.0V
NO. PARAMETER UNIT
MIN MAX
3 tw(GPOH) Pulse duration, GPn[m] as output high 2C (1) (2)
ns
(1) (2)
4 tw(GPOL) Pulse duration, GPn[m] as output low 2C ns
(1) This parameter value should not be used as a maximum performance specification. Actual performance of back-to-back accesses of the
GPIO is dependent upon internal bus activity.
(2) C=SYSCLK4 period in ns.

2
1
GPn[m]
as input 4
3
GPn[m]
as output

Figure 6-76. GPIO Port Timing

6.28.3 GPIO Peripheral External Interrupts Electrical Data/Timing

Table 6-114. Timing Requirements for External Interrupts (1) (see Figure 6-77)
1.3V, 1.2V, 1.1V,
NO. 1.0V UNIT
MIN MAX
1 tw(ILOW) Width of the external interrupt pulse low 2C (1) (2)
ns
2 tw(IHIGH) Width of the external interrupt pulse high 2C (1) (2)
ns
(1) The pulse width given is sufficient to generate an interrupt or an EDMA event. However, if a user wants to have the device recognize the
GPIO changes through software polling of the GPIO register, the GPIO duration must be extended to allow the device enough time to
access the GPIO register through the internal bus.
(2) C=SYSCLK4 period in ns.

2
GPn[m] 1
as input

Figure 6-77. GPIO External Interrupt Timing

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6.29 Programmable Real-Time Unit Subsystem (PRUSS)


The Programmable Real-Time Unit Subsystem (PRUSS) consists of
• Two Programmable Real-Time Units (PRU0 and PRU1) and their associated memories
• An Interrupt Controller (INTC) for handling system interrupt events. The INTC also supports posting
events back to the device level host CPU.
• A Switched Central Resource (SCR) for connecting the various internal and external masters to the
resources inside the PRUSS.
The two PRUs can operate completely independently or in coordination with each other. The PRUs can
also work in coordination with the device level host CPU. This is determined by the nature of the program
which is loaded into the PRUs instruction memory. Several different signaling mechanisms are available
between the two PRUs and the device level host CPU.
The PRUs are optimized for performing embedded tasks that require manipulation of packed memory
mapped data structures, handling of system events that have tight realtime constraints and interfacing with
systems external to the device.
The PRUSS comprises various distinct addressable regions. Externally the subsystem presents a single
64Kbyte range of addresses. The internal interconnect bus (also called switched central resource, or SCR)
of the PRUSS decodes accesses for each of the individual regions. The PRUSS memory map is
documented in Table 6-115 and in Table 6-116. Note that these two memory maps are implemented
inside the PRUSS and are local to the components of the PRUSS.

Table 6-115. Programmable Real-Time Unit Subsystem (PRUSS) Local Instruction Space Memory Map
BYTE ADDRESS PRU0 PRU1
0x0000 0000 - 0x0000 0FFF PRU0 Instruction RAM PRU1 Instruction RAM

Table 6-116. Programmable Real-Time Unit Subsystem (PRUSS) Local Data Space Memory Map
BYTE ADDRESS PRU0 PRU1
(1) (1)
0x0000 0000 - 0x0000 01FF Data RAM 0 Data RAM 1
0x0000 0200 - 0x0000 1FFF Reserved Reserved
(1) (1)
0x0000 2000 - 0x0000 21FF Data RAM 1 Data RAM 0
0x0000 2200 - 0x0000 3FFF Reserved Reserved
0x0000 4000 - 0x0000 6FFF INTC Registers INTC Registers
0x0000 7000 - 0x0000 73FF PRU0 Control Registers PRU0 Control Registers
0x0000 7400 - 0x0000 77FF Reserved Reserved
0x0000 7800 - 0x0000 7BFF PRU1 Control Registers PRU1 Control Registers
0x0000 7C00 - 0xFFFF FFFF Reserved Reserved
(1) Note that PRU0 accesses Data RAM0 at address 0x0000 0000, also PRU1 accesses Data RAM1 at address 0x0000 0000. Data RAM0
is intended to be the primary data memory for PRU0 and Data RAM1 is intended to be the primary data memory for PRU1. However for
passing information between PRUs, each PRU can access the data ram of the ‘other’ PRU through address 0x0000 2000.

The global view of the PRUSS internal memories and control ports is documented in Table 6-117. The
offset addresses of each region are implemented inside the PRUSS but the global device memory
mapping places the PRUSS slave port in the address range 0x01C3 0000-0x01C3 FFFF. The PRU0 and
PRU1 can use either the local or global addresses to access their internal memories, but using the local
addresses will provide access time several cycles faster than using the global addresses. This is because
when accessing via the global address the access needs to be routed through the switch fabric outside
PRUSS and back in through the PRUSS slave port.

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Table 6-117. Programmable Real-Time Unit Subsystem (PRUSS) Global Memory Map
BYTE ADDRESS REGION
0x01C3 0000 - 0x01C3 01FF Data RAM 0
0x01C3 0200 - 0x01C3 1FFF Reserved
0x01C3 2000 - 0x01C3 21FF Data RAM 1
0x01C3 2200 - 0x01C3 3FFF Reserved
0x01C3 4000 - 0x01C3 6FFF INTC Registers
0x01C3 7000 - 0x01C3 73FF PRU0 Control Registers
0x01C3 7400 - 0x01C3 77FF PRU0 Debug Registers
0x01C3 7800 - 0x01C3 7BFF PRU1 Control Registers
0x01C3 7C00 - 0x01C3 7FFF PRU1 Debug Registers
0x01C3 8000 - 0x01C3 8FFF PRU0 Instruction RAM
0x01C3 9000 - 0x01C3 BFFF Reserved
0x01C3 C000 - 0x01C3 CFFF PRU1 Instruction RAM
0x01C3 D000 - 0x01C3 FFFF Reserved

Each of the PRUs can access the rest of the device memory (including memory mapped peripheral and
configuration registers) using the global memory space addresses

6.29.1 PRUSS Register Descriptions

Table 6-118. Programmable Real-Time Unit Subsystem (PRUSS) Control / Status Registers
PRU0 BYTE ADDRESS PRU1 BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01C3 7000 0x01C3 7800 CONTROL PRU Control Register
0x01C3 7004 0x01C3 7804 STATUS PRU Status Register
0x01C3 7008 0x01C3 7808 WAKEUP PRU Wakeup Enable Register
0x01C3 700C 0x01C3 780C CYCLCNT PRU Cycle Count
0x01C3 7010 0x01C3 7810 STALLCNT PRU Stall Count
PRU Constant Table Block Index
0x01C3 7020 0x01C3 7820 CONTABBLKIDX0
Register 0
PRU Constant Table Programmable
0x01C3 7028 0x01C3 7828 CONTABPROPTR0
Pointer Register 0
PRU Constant Table Programmable
0x01C3 702C 0x01C3 782C CONTABPROPTR1
Pointer Register 1
PRU Internal General Purpose
0x01C37400 - 0x01C3747C 0x01C3 7C00 - 0x01C3 7C7C INTGPR0 – INTGPR31
Register 0 (for Debug)
PRU Internal General Purpose
0x01C37480 - 0x01C374FC 0x01C3 7C80 - 0x01C3 7CFC INTCTER0 – INTCTER31
Register 0 (for Debug)

Table 6-119. Programmable Real-Time Unit Subsystem Interrupt Controller (PRUSS INTC) Registers
BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01C3 4000 REVID Revision ID Register
0x01C3 4004 CONTROL Control Register
0x01C3 4010 GLBLEN Global Enable Register
0x01C3 401C GLBLNSTLVL Global Nesting Level Register
0x01C3 4020 STATIDXSET System Interrupt Status Indexed Set Register
0x01C3 4024 STATIDXCLR System Interrupt Status Indexed Clear Register
0x01C3 4028 ENIDXSET System Interrupt Enable Indexed Set Register
0x01C3 402C ENIDXCLR System Interrupt Enable Indexed Clear Register
0x01C3 4034 HSTINTENIDXSET Host Interrupt Enable Indexed Set Register
0x01C3 4038 HSTINTENIDXCLR Host Interrupt Enable Indexed Clear Register

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Table 6-119. Programmable Real-Time Unit Subsystem Interrupt Controller (PRUSS INTC)
Registers (continued)
BYTE ADDRESS ACRONYM REGISTER DESCRIPTION
0x01C3 4080 GLBLPRIIDX Global Prioritized Index Register
0x01C3 4200 STATSETINT0 System Interrupt Status Raw/Set Register 0
0x01C3 4204 STATSETINT1 System Interrupt Status Raw/Set Register 1
0x01C3 4280 STATCLRINT0 System Interrupt Status Enabled/Clear Register 0
0x01C3 4284 STATCLRINT1 System Interrupt Status Enabled/Clear Register 1
0x01C3 4300 ENABLESET0 System Interrupt Enable Set Register 0
0x01C3 4304 ENABLESET1 System Interrupt Enable Set Register 1
0x01C3 4380 ENABLECLR0 System Interrupt Enable Clear Register 0
0x01C3 4384 ENABLECLR1 System Interrupt Enable Clear Register 1
0x01C3 4400 - 0x01C3 4440 CHANMAP0 - CHANMAP15 Channel Map Registers 0-15
0x01C3 4800 - 0x01C3 4808 HOSTMAP0 - HOSTMAP2 Host Map Register 0-2
HOSTINTPRIIDX0 -
0x01C3 4900 - 0x01C3 4928 Host Interrupt Prioritized Index Registers 0-9
HOSTINTPRIIDX9
0x01C3 4D00 POLARITY0 System Interrupt Polarity Register 0
0x01C3 4D04 POLARITY1 System Interrupt Polarity Register 1
0x01C3 4D80 TYPE0 System Interrupt Type Register 0
0x01C3 4D84 TYPE1 System Interrupt Type Register 1
HOSTINTNSTLVL0-
0x01C3 5100 - 0x01C3 5128 Host Interrupt Nesting Level Registers 0-9
HOSTINTNSTLVL9
0x01C3 5500 HOSTINTEN Host Interrupt Enable Register

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6.30 Emulation Logic


This section describes the steps to use a third party debugger on the ARM926EJ-S within the device. The
debug capabilities and features for ARM are as shown below.
ARM:
• Basic Debug
– Execution Control
– System Visibility
• Advanced Debug
– Global Start
– Global Stop
• Advanced System Control
– Subsystem reset via debug
– Peripheral notification of debug events
– Cache-coherent debug accesses
• Program Trace
– Program flow corruption
– Code coverage
– Path coverage
– Thread/interrupt synchronization problems
• Data Trace
– Memory corruption
• Timing Trace
– Profiling
• Analysis Actions
– Stop program execution
– Control trace streams
– Generate debug interrupt
– Benchmarking with counters
– External trigger generation
– Debug state machine state transition
– Combinational and Sequential event generation
• Analysis Events
– Program event detection
– Data event detection
– External trigger Detection
– System event detection (i.e. cache miss)
– Debug state machine state detection
• Analysis Configuration
– Application access
– Debugger access

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Table 6-120. ARM Debug Features


Category Hardware Feature Availability
Software breakpoint Unlimited
Up to 14 HWBPs, including:
2 precise (1) HWBP inside ARM core which are shared with watch points.
Basic Debug
Hardware breakpoint 8 imprecise (1) HWBPs from ETM’s address comparators, which are shared with trace
function, and can be used as watch points.
4 imprecise (1) HWBPs from ICECrusher.
Up to 6 watch points, including:
2 from ARM core which is shared with HWBPs and can be associated with a data.
Watch point
8 from ETM’s address comparators, which are shared with trace function, and
HWBPs.
2 from ARM core which is shared with HWBPs.
Analysis
Watch point with Data 8 watch points from ETM can be associated with a data comparator, and ETM has
total 4 data comparators.
Counters/timers 3x32-bit (1 cycle ; 2 event)
External Event Trigger In 1
External Event Trigger Out 1
Address range for trace 4
Data qualification for trace 2
System events for trace control 20
Trace Control Counters/Timers for trace control 2x16-bit
State Machines/Sequencers 1x3-State State Machine
Context/Thread ID Comparator 1
Independent trigger control units 12
Capture depth PC 4k bytes ETB
On-chip Trace
Capture depth PC + Timing 4k bytes ETB
Capture
Application accessible Y
(1) Precise hardware breakpoints will halt the processor immediately prior to the execution of the selected instruction. Imprecise breakpoints
will halt the processor some number of cycles after the selected instruction depending on device conditions.

6.30.1 JTAG Port Description


The device target debug interface uses the five standard IEEE 1149.1(JTAG) signals (TRST, TCK, TMS,
TDI, and TDO), a return clock (RTCK) due to the clocking requirements of the ARM926EJ-S and
emulation signals EMU0 and EMU1. TRST holds the debug and boundary scan logic in reset when pulled
low (its default state). Since TRST has an internal pull-down resistor, this ensures that at power up the
device functions in its normal (non-test) operation mode if TRST is not connected. Otherwise, TRST
should be driven inactive by the emulator or boundary scan controller. Boundary scan test cannot be
performed while the TRST pin is pulled low.

Table 6-121. JTAG Port Description


PIN TYPE NAME DESCRIPTION
When asserted (active low) causes all test and debug logic in the device to be reset
TRST I Test Logic Reset
along with the IEEE 1149.1 interface
This is the test clock used to drive an IEEE 1149.1 TAP state machine and logic.
TCK I Test Clock Depending on the emulator attached to , this is a free running clock or a gated clock
depending on RTCK monitoring.
Synchronized TCK. Depending on the emulator attached to, the JTAG signals are
RTCK O Returned Test Clock
clocked from RTCK or RTCK is monitored by the emulator to gate TCK.
TMS I Test Mode Select Directs the next state of the IEEE 1149.1 test access port state machine
TDI I Test Data Input Scan data input to the device
TDO O Test Data Output Scan data output of the device

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Table 6-121. JTAG Port Description (continued)


PIN TYPE NAME DESCRIPTION
EMU0 I/O Emulation 0 Channel 0 trigger + HSRTDX
EMU1 I/O Emulation 1 Channel 1 trigger + HSRTDX

6.30.2 Scan Chain Configuration Parameters


Table 6-122 shows the TAP configuration details required to configure the router/emulator for this device.

Table 6-122. JTAG Port Description


Router Port ID Default TAP TAP Name Tap IR Length
17 No Reserved 38
18 No ARM926 4
19 No ETB 4

The router is revision C and has a 6-bit IR length.

6.30.3 Initial Scan Chain Configuration


The first level of debug interface that sees the scan controller is the TAP router module. The debugger
can configure the TAP router for serially linking up to 16 TAP controllers or individually scanning one of
the TAP controllers without disrupting the IR state of the other TAPs.

6.30.3.1 Adding TAPS to the Scan Chain


The TAP router must be programmed to add additional TAPs to the scan chain. The following JTAG scans
must be completed to add the ARM926EJ-S to the scan chain.
A Power-On Reset (POR) or the JTAG Test-Logic Reset state configures the TAP router to contain only
the router’s TAP.

TDO Router

TDI

CLK Steps

TMS

Router ARM926EJ-S/ETM

Figure 6-78. Adding ARM926EJ-S to the scan chain

Pre-amble: The device whose data reaches the emulator first is listed first in the board configuration file.
This device is a pre-amble for all the other devices. This device has the lowest device ID.
Post-amble: The device whose data reaches the emulator last is listed last in the board configuration file.
This device is a post-amble for all the other devices. This device has the highest device ID.

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• Function : Update the JTAG preamble and post-amble counts.


– Parameter : The IR pre-amble count is '0'.
– Parameter : The IR post-amble count is '0'.
– Parameter : The DR pre-amble count is '0'.
– Parameter : The DR post-amble count is '0'.
– Parameter : The IR main count is '6'.
– Parameter : The DR main count is '1'.
• Function : Do a send-only JTAG IR/DR scan.
– Parameter : The route to JTAG shift state is 'shortest transition'.
– Parameter : The JTAG shift state is 'shift-ir'.
– Parameter : The JTAG destination state is 'pause-ir'.
– Parameter : The bit length of the command is '6'.
– Parameter : The send data value is '0x00000007'.
– Parameter : The actual receive data is 'discarded'.
• Function : Do a send-only JTAG IR/DR scan.
– Parameter : The route to JTAG shift state is 'shortest transition'.
– Parameter : The JTAG shift state is 'shift-dr'.
– Parameter : The JTAG destination state is 'pause-dr'.
– Parameter : The bit length of the command is '8'.
– Parameter : The send data value is '0x00000089'.
– Parameter : The actual receive data is 'discarded'.
• Function : Do a send-only JTAG IR/DR scan.
– Parameter : The route to JTAG shift state is 'shortest transition'.
– Parameter : The JTAG shift state is 'shift-ir'.
– Parameter : The JTAG destination state is 'pause-ir'.
– Parameter : The bit length of the command is '6'.
– Parameter : The send data value is '0x00000002'.
– Parameter : The actual receive data is 'discarded'.
• Function : Embed the port address in next command.
– Parameter : The port address field is '0x0f000000'.
– Parameter : The port address value is '3'.
• Function : Do a send-only JTAG IR/DR scan.
– Parameter : The route to JTAG shift state is 'shortest transition'.
– Parameter : The JTAG shift state is 'shift-dr'.
– Parameter : The JTAG destination state is 'pause-dr'.
– Parameter : The bit length of the command is '32'.
– Parameter : The send data value is '0xa2002108'.
– Parameter : The actual receive data is 'discarded'.
• Function : Do a send-only all-ones JTAG IR/DR scan.
– Parameter : The JTAG shift state is 'shift-ir'.
– Parameter : The JTAG destination state is 'run-test/idle'.
– Parameter : The bit length of the command is '6'.
– Parameter : The send data value is 'all-ones'.
– Parameter : The actual receive data is 'discarded'.
• Function : Wait for a minimum number of TCLK pulses.
– Parameter : The count of TCLK pulses is '10'.

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• Function : Update the JTAG preamble and post-amble counts.


– Parameter : The IR pre-amble count is '0'.
– Parameter : The IR post-amble count is '6'.
– Parameter : The DR pre-amble count is '0'.
– Parameter : The DR post-amble count is '1'.
– Parameter : The IR main count is '4'.
– Parameter : The DR main count is '1'.
The initial scan chain contains only the TAP router module. The following steps must be completed in
order to add ETB TAP to the scan chain.

TDI Router ARM926EJ-S/ETM

TDO

CLK Steps

TMS

Router ARM926EJ-S/ETM ETB

Figure 6-79. Adding ETB to the scan chain


• Function : Do a send-only JTAG IR/DR scan.
– Parameter : The route to JTAG shift state is 'shortest transition'.
– Parameter : The JTAG shift state is 'shift-ir'.
– Parameter : The JTAG destination state is 'pause-ir'.
– Parameter : The bit length of the command is '6'.
– Parameter : The send data value is '0x00000007'.
– Parameter : The actual receive data is 'discarded'.
• Function : Do a send-only JTAG IR/DR scan.
– Parameter : The route to JTAG shift state is 'shortest transition'.
– Parameter : The JTAG shift state is 'shift-dr'.
– Parameter : The JTAG destination state is 'pause-dr'.
– Parameter : The bit length of the command is '8'.
– Parameter : The send data value is '0x00000089'.
– Parameter : The actual receive data is 'discarded'.
• Function : Do a send-only JTAG IR/DR scan.
– Parameter : The route to JTAG shift state is 'shortest transition'.
– Parameter : The JTAG shift state is 'shift-ir'.
– Parameter : The JTAG destination state is 'pause-ir'.
– Parameter : The bit length of the command is '6'.
– Parameter : The send data value is '0x00000002'.
– Parameter : The actual receive data is 'discarded'.
• Function : Embed the port address in next command.
– Parameter : The port address field is '0x0f000000'.
– Parameter : The port address value is '3'.

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• Function : Do a send-only JTAG IR/DR scan.


– Parameter : The route to JTAG shift state is 'shortest transition'.
– Parameter : The JTAG shift state is 'shift-dr'.
– Parameter : The JTAG destination state is 'pause-dr'.
– Parameter : The bit length of the command is '32'.
– Parameter : The send data value is '0xa3302108'.
– Parameter : The actual receive data is 'discarded'.
• Function : Do a send-only all-ones JTAG IR/DR scan.
– Parameter : The JTAG shift state is 'shift-ir'.
– Parameter : The JTAG destination state is 'run-test/idle'.
– Parameter : The bit length of the command is '6'.
– Parameter : The send data value is 'all-ones'.
– Parameter : The actual receive data is 'discarded'.
• Function : Wait for a minimum number of TCLK pulses.
– Parameter : The count of TCLK pulses is '10'.
• Function : Update the JTAG preamble and post-amble counts.
– Parameter : The IR pre-amble count is '0'.
– Parameter : The IR post-amble count is '6 + 4'.
– Parameter : The DR pre-amble count is '0'.
– Parameter : The DR post-amble count is '1 + 1'.
– Parameter : The IR main count is '4'.
– Parameter : The DR main count is '1'.

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6.30.4 IEEE 1149.1 JTAG


(1)
The JTAG interface is used for BSDL testing and emulation of the device.
The device requires that both TRST and RESET be asserted upon power up to be properly initialized.
While RESET initializes the device, TRST initializes the device's emulation logic. Both resets are required
for proper operation.
While both TRST and RESET need to be asserted upon power up, only RESET needs to be released for
the device to boot properly. TRST may be asserted indefinitely for normal operation, keeping the JTAG
port interface and device's emulation logic in the reset state.
TRST only needs to be released when it is necessary to use a JTAG controller to debug the device or
exercise the device's boundary scan functionality. Note: TRST is synchronous and must be clocked by
TCK; otherwise, the boundary scan logic may not respond as expected after TRST is asserted.
RESET must be released only in order for boundary-scan JTAG to read the variant field of IDCODE
correctly. Other boundary-scan instructions work correctly independent of current state of RESET.
For maximum reliability, the device includes an internal pulldown (IPD) on the TRST pin to ensure that
TRST will always be asserted upon power up and the device's internal emulation logic will always be
properly initialized.
JTAG controllers from Texas Instruments actively drive TRST high. However, some third-party JTAG
controllers may not drive TRST high but expect the use of a pullup resistor on TRST.
When using this type of JTAG controller, assert TRST to initialize the device after powerup and externally
drive TRST high before attempting any emulation or boundary scan operations.

6.30.4.1 JTAG Peripheral Register Description(s) – JTAG ID Register (DEVIDR0)

Table 6-123. DEVIDR0 Register


BYTE ADDRESS ACRONYM REGISTER DESCRIPTION COMMENTS
Read-only. Provides 32-bit
0x01C1 4018 DEVIDR0 JTAG Identification Register
JTAG ID of the device.
(1) IEEE Standard 1149.1-1990 Standard-Test-Access Port and Boundary Scan Architecture.

The JTAG ID register is a read-only register that identifies to the customer the JTAG/Device ID. For the
device, the JTAG ID register resides at address location 0x01C1 4018. The register hex value for each
silicon revision is:
• 0x0B7D 102F for silicon revision 1.0
• 0x0B7D 102F for silicon revision 1.1
• 0x1B7D 102F for silicon revision 2.0
For the actual register bit names and their associated bit field descriptions, see Figure 6-80 and Table 6-
124.

Figure 6-80. JTAG ID (DEVIDR0) Register Description - Register Value


31-28 27-12 11-1 0
VARIANT (4-Bit) PART NUMBER (16-Bit) MANUFACTURER (11-Bit) LSB
R-xxxx R-1011 0111 1101 0001 R-0000 0010 111 R-1
LEGEND: R = Read, W = Write, n = value at reset

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Table 6-124. JTAG ID Register Selection Bit Descriptions


BIT NAME DESCRIPTION
31:28 VARIANT Variant (4-Bit) value
27:12 PART NUMBER Part Number (16-Bit) value
11-1 MANUFACTURER Manufacturer (11-Bit) value
0 LSB LSB. This bit is read as a "1".

6.30.4.2 JTAG Test-Port Electrical Data/Timing

Table 6-125. Timing Requirements for JTAG Test Port (see Figure 6-81)
1.3V, 1.2V 1.1V 1.0V
No. UNIT
MIN MAX MIN MAX MIN MAX
1 tc(TCK) Cycle time, TCK 40 50 66.6 ns
2 tw(TCKH) Pulse duration, TCK high 16 20 26.6 ns
3 tw(TCKL) Pulse duration, TCK low 16 20 26.6 ns
4 tc(RTCK) Cycle time, RTCK 40 50 66.6 ns
5 tw(RTCKH) Pulse duration, RTCK high 16 20 26.6 ns
6 tw(RTCKL) Pulse duration, RTCK low 16 20 26.6 ns
7 tsu(TDIV-RTCKH) Setup time, TDI/TMS/TRST valid before RTCK high 4 4 4 ns
8 th(RTCKH-TDIV) Hold time, TDI/TMS/TRST valid after RTCK high 4 6 8 ns

Table 6-126. Switching Characteristics Over Recommended Operating Conditions for JTAG Test Port
(see Figure 6-81)
1.3V, 1.2V 1.1V 1.0V
No. PARAMETER UNIT
MIN MAX MIN MAX MIN MAX
9 td(RTCKL-TDOV) Delay time, RTCK low to TDO valid 18 23 31 ns

1
2
3
TCK

4
5
6
RTCK

TDO
8
7
TDI/TMS/TRST

Figure 6-81. JTAG Test-Port Timing

6.30.5 JTAG 1149.1 Boundary Scan Considerations


To use boundary scan, the following sequence should be followed:
• Execute a valid reset sequence and exit reset
• Wait at least 6000 OSCIN clock cycles
• Enter boundary scan mode using the JTAG pins
No specific value is required on the EMU0 and EMU1 pins for boundary scan testing. If TRST is not driven
by the boundary scan tool or tester, TRST should be externally pulled high during boundary scan testing.

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7 Device and Documentation Support


7.1 Device Support

7.1.1 Development Support


TI offers an extensive line of development tools for the device platform, including tools to evaluate the
performance of the processors, generate code, develop algorithm implementations, and fully integrate and
debug software and hardware modules. The tool's support documentation is electronically available within
the Code Composer Studio™ Integrated Development Environment (IDE).
The following products support development of the device applications:
Software Development Tools:
Code Composer Studio™ Integrated Development Environment (IDE): including Editor
C/C++/Assembly Code Generation, and Debug plus additional development tools
Hardware Development Tools:
Extended Development System (XDS™) Emulator
For a complete listing of development-support tools for the device, visit the Texas Instruments web site
on the Worldwide Web at www.ti.com uniform resource locator (URL). For information on pricing and
availability, contact the nearest TI field sales office or authorized distributor.

7.1.2 Device and Development-Support Tool Nomenclature


To designate the stages in the product development cycle, TI assigns prefixes to the part numbers of all
AM1xxx processors and support tools. Each commercial AM1xxx platform member has one of three
prefixes: X, P, or null (no prefix). Texas Instruments recommends two of three possible prefix designators
for its support tools: TMDX and TMDS. These prefixes represent evolutionary stages of product
development from engineering prototypes (TMDX) through fully qualified production devices/tools (TMDS).
Device development evolutionary flow:
X Experimental device that is not necessarily representative of the final device's electrical
specifications.
P Final silicon die that conforms to the device's electrical specifications but has not completed
quality and reliability verification.
NULL Fully-qualified production device.

Support tool development evolutionary flow:


TMDX Development-support product that has not yet completed Texas Instruments internal
qualification testing.
TMDS Fully qualified development-support product.

X and P devices and TMDX development-support tools are shipped against the following disclaimer:
"Developmental product is intended for internal evaluation purposes."
NULL devices and TMDS development-support tools have been characterized fully, and the quality and
reliability of the device have been demonstrated fully. TI's standard warranty applies.
Predictions show that prototype devices (X or P) have a greater failure rate than the standard production
devices. Texas Instruments recommends that these devices not be used in any production system
because their expected end-use failure rate still is undefined. Only qualified production devices are to be
used.
Figure 7-1 provides a legend for reading the complete device.

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X AM1806 ( ) ZWT ( ) 3
DEVICE SPEED RANGE
PREFIX 3 = 375 MHz
X = Experimental Device 4 = 456 MHz
P = Prototype Device TEMPERATURE RANGE (JUNCTION)
Blank = Production Device Blank = 0°C to 90°C (Commercial Grade)
D = -40°C to 90°C (Industrial Grade)
DEVICE A = -40°C to 105°C (Extended Grade)
SILICON REVISION
(B)
PACKAGE TYPE (A)
B = Silicon Revision 2.0 or 2.1 ZCE = 361 Pin Plastic BGA, with Pb-free
E = Silicon Revision 2.3 Soldered Balls [Green], 0.65-mm Ball Pitch
ZWT = 361 Pin Plastic BGA, with Pb-free
Soldered Balls [Green], 0.80-mm Ball Pitch
A. BGA = Ball Grid Array
B. Parts marked revision B are silicon revision 2.1 if '21' is marked on the package, and silicon revision 2.0 if there is no
'21' marking.

Figure 7-1. Device Nomenclature

7.2 Documentation Support


The following documents describe the device. Copies of these documents are available on the Internet at
www.ti.com. Tip: Enter the literature number in the search box provided at www.ti.com.
Reference Guides
SPRUGU4 AM1806 ARM Microprocessor System Reference Guide
SPRUFU0 AM17x/AM18x ARM Microprocessor Peripherals Overview Reference Guide

7.3 Community Resources


The following links connect to TI community resources. Linked contents are provided "AS IS" by the
respective contributors. They do not constitute TI specifications and do not necessarily reflect TI's views;
see TI's Terms of Use.
TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster
collaboration among engineers. At e2e.ti.com, you can ask questions, share knowledge,
explore ideas and help solve problems with fellow engineers.
TI Embedded Processors Wiki Texas Instruments Embedded Processors Wiki. Established to help
developers get started with Embedded Processors from Texas Instruments and to foster
innovation and growth of general knowledge about the hardware and software surrounding
these devices.

7.4 Trademarks
E2E is a trademark of Texas Instruments.
ARM926EJ-S is a trademark of ARM Ltd.
ARM is a registered trademark of ARM Ltd.
Windows is a registered trademark of Microsoft.
I2C Bus is a trademark of Phillips.
All other trademarks are the property of their respective owners.

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7.5 Electrostatic Discharge Caution


This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.

7.6 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms and definitions.

8 Mechanical Packaging and Orderable Information


This section describes the device orderable part numbers, packaging options, materials, thermal and
mechanical parameters.

8.1 Thermal Data for ZCE Package


The following table(s) show the thermal resistance characteristics for the PBGA–ZCE mechanical
package.

Table 8-1. Thermal Resistance Characteristics (PBGA Package) [ZCE]


NO. °C/W (1) AIR FLOW (m/s) (2)
1 RΘJC Junction-to-case 7.6 N/A
2 RΘJB Junction-to-board 11.3 N /A
3 RΘJA Junction-to-free air 23.9 0.00
4 21.2 0.50
5 20.3 1.00
RΘJMA Junction-to-moving air
6 19.5 2.00
7 18.6 4.00
8 0.2 0.00
9 0.3 0.50
10 PsiJT Junction-to-package top 0.3 1.00
11 0.4 2.00
12 0.5 4.00
13 11.2 0.00
14 11.1 0.50
15 PsiJB Junction-to-board 11.1 1.00
16 11.0 2.00
17 10.9 4.00
(1) These measurements were conducted in a JEDEC defined 2S2P system and will change based on environment as well as application.
For more information, see these EIA/JEDEC standards – EIA/JESD51-2, Integrated Circuits Thermal Test Method Environment
Conditions - Natural Convection (Still Air) and JESD51-7, High Effective Thermal Conductivity Test Board for Leaded Surface Mount
Packages. Power dissipation of 500 mW and ambient temp of 70C assumed. PCB with 2oz (70um) top and bottom copper thickness
and 1.5oz (50um) inner copper thickness
(2) m/s = meters per second

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8.2 Thermal Data for ZWT Package


The following table(s) show the thermal resistance characteristics for the PBGA–ZWT mechanical
package.

Table 8-2. Thermal Resistance Characteristics (PBGA Package) [ZWT]


NO. °C/W (1) AIR FLOW (m/s) (2)
1 RΘJC Junction-to-case 7.3 N/A
2 RΘJB Junction-to-board 12.4 N /A
3 RΘJA Junction-to-free air 23.7 0.00
4 21.0 0.50
5 20.1 1.00
RΘJMA Junction-to-moving air
6 19.3 2.00
7 18.4 4.00
8 0.2 0.00
9 0.3 0.50
10 PsiJT Junction-to-package top 0.3 1.00
11 0.4 2.00
12 0.5 4.00
13 12.3 0.00
14 12.2 0.50
15 PsiJB Junction-to-board 12.1 1.00
16 12.0 2.00
17 11.9 4.00
(1) These measurements were conducted in a JEDEC defined 2S2P system and will change based on environment as well as application.
For more information, see these EIA/JEDEC standards – EIA/JESD51-2, Integrated Circuits Thermal Test Method Environment
Conditions - Natural Convection (Still Air) and JESD51-7, High Effective Thermal Conductivity Test Board for Leaded Surface Mount
Packages. Power dissipation of 1W and ambient temp of 70C assumed. PCB with 2oz (70um) top and bottom copper thickness and
1.5oz (50um) inner copper thickness
(2) m/s = meters per second

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PACKAGE OPTION ADDENDUM

www.ti.com 27-Jun-2023

PACKAGING INFORMATION

Orderable Device Status Package Type Package Pins Package Eco Plan Lead finish/ MSL Peak Temp Op Temp (°C) Device Marking Samples
(1) Drawing Qty (2) Ball material (3) (4/5)
(6)

AM1806EZCE3 ACTIVE NFBGA ZCE 361 160 RoHS & Green SNAGCU Level-3-260C-168 HR 0 to 90 AM1806E Samples
ZCE
375
AM1806EZCE4 ACTIVE NFBGA ZCE 361 160 RoHS & Green SNAGCU Level-3-260C-168 HR 0 to 90 AM1806E Samples
ZCE
456
AM1806EZCEA3 ACTIVE NFBGA ZCE 361 160 RoHS & Green SNAGCU Level-3-260C-168 HR -40 to 105 AM1806E Samples
ZCE
A375
AM1806EZWT3 ACTIVE NFBGA ZWT 361 90 RoHS & Green SNAGCU Level-3-260C-168 HR 0 to 90 AM1806E Samples
ZWT
375
AM1806EZWT4 ACTIVE NFBGA ZWT 361 90 RoHS & Green SNAGCU Level-3-260C-168 HR 0 to 90 AM1806E Samples
ZWT
456
AM1806EZWTD4 ACTIVE NFBGA ZWT 361 90 RoHS & Green SNAGCU Level-3-260C-168 HR -40 to 90 AM1806E Samples
ZWT
D456

(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.

(2)
RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based
flame retardants must also meet the <=1000ppm threshold requirement.

(3)
MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.

(4)
There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.

Addendum-Page 1
PACKAGE OPTION ADDENDUM

www.ti.com 27-Jun-2023

(5)
Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.

(6)
Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two
lines if the finish value exceeds the maximum column width.

Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.

In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.

Addendum-Page 2
PACKAGE MATERIALS INFORMATION

www.ti.com 5-Jan-2022

TRAY

Chamfer on Tray corner indicates Pin 1 orientation of packed units.

*All dimensions are nominal


Device Package Package Pins SPQ Unit array Max L (mm) W K0 P1 CL CW
Name Type matrix temperature (mm) (µm) (mm) (mm) (mm)
(°C)
AM1806EZWT3 ZWT NFBGA 361 90 6 X 15 150 315 135.9 7620 20 17.5 15.45
AM1806EZWT4 ZWT NFBGA 361 90 6 X 15 150 315 135.9 7620 20 17.5 15.45
AM1806EZWTD4 ZWT NFBGA 361 90 6 X 15 150 315 135.9 7620 20 17.5 15.45

Pack Materials-Page 1
PACKAGE OUTLINE
ZCE0361A NFBGA - 1.30 mm max height
SCALE 1.100

PLASTIC BALL GRID ARRAY

A 13.1
12.9 B

BALL A1 CORNER

13.1
12.9

1.30 MAX
0.94
0.84
C

SEATING PLANE

BALL TYP 0.1 C


0.33 TYP
0.23

11.7 TYP
SYMM (0.65) TYP

W
V
U (0.65) TYP
T
R
P
N
M
11.7 L SYMM
TYP K
J
H
G
F
E
D 361X Ø0.46
0.36
C
0.15 C A B
B
A 0.05 C
0.65 TYP 1 3 5 7 9 11 13 15 17 19
2 4 6 8 10 12 14 16 18
BALL A1 CORNER
0.65 TYP

4224126/A 11/2018
NOTES:

1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.

www.ti.com
EXAMPLE BOARD LAYOUT
ZCE0361A NFBGA - 1.30 mm max height
PLASTIC BALL GRID ARRAY

(0.65) TYP

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
A
B
361X (Ø0.35)
C
(0.65) TYP
D
E
F
G
H
J SYMM
K
L
M
N
P
R
T
U
V
W
SYMM

LAND PATTERN EXAMPLE


EXPOSED METAL SHOWN
SCALE: 6X

(Ø0.35) 0.05 MAX 0.05 MIN METAL UNDER


METAL SOLDER MASK

(Ø0.35)
SOLDER MASK EXPOSED EXPOSED SOLDER MASK
OPENING METAL METAL OPENING
NON-SOLDER MASK SOLDER MASK
DEFINED DEFINED
(PREFERRED)

SOLDER MASK DETAILS


NOT TO SCALE

4224126/A 11/2018
NOTES: (continued)

3. Final dimensions may vary due to manufacturing tolerance considerations and also routing constraints.
For information, see Texas Instruments literature number SPRAA99 (www.ti.com/lit/spraa99).

www.ti.com
EXAMPLE STENCIL DESIGN
ZCE0361A NFBGA - 1.30 mm max height
PLASTIC BALL GRID ARRAY

(0.65) TYP

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
A
B

C 361X (Ø0.35)
(0.65) TYP
D
E
F
G
H
J SYMM
K
L
M
N
P
R
T
U
V
W
SYMM

SOLDER PASTE EXAMPLE


BASED ON 0.125 mm THICK STENCIL
SCALE:6X

4224126/A 11/2018
NOTES: (continued)

4. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release.

www.ti.com
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