BASICS OF THE I2C COMMUNICATION
PROTOCOL
I2C combines the best features of SPI and UARTs. With I2C, you can connect
multiple slaves to a single master (like SPI) and you can have multiple masters
cont rolling single, or multiple slaves. This is really useful when you want to have
more than one microcontroller logging data to a single memory card or displaying
text to a single LCD.
Like UART communication, I2C only uses two wires to transmit data between
devices:
SDA (Serial Data) – The line for the master and slave to send and receive data.
SCL (Serial Clock) –The line that carries the clock signal.
I2C is a serial communication protocol, so data is transferred bit by bit along a
single wire (the SDA line).
Like SPI, I2C is synchronous, so the output of bits is synchronized to the sampling
of bits by a clock signal shared between the master and the slave. The clock signal
is always controlled bythe master.
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�HOW I2C WORKS
W i th I2C, data is transferred in messages. Messages are broken up into frames of
data. Each message has an address frame that contains the binary address of the
slave, and one or more data frames that contain the data being transmitted. The
message also includes start and stop conditions, read/write bits, and ACK/NACK
bits between each data frame:
Start Condition: The SDA line switches from a high voltage level to a low voltage
level before the SCL line switches from high to low.
Stop Condition: The SDA line switches from a low voltage level to a high voltage
level after the SCL line switches from low to high.
Address Frame: A 7 or 10 bit sequence unique to each slave that identifies the slave
when the master wants to talk to it.
Read/Write Bit: A single bit specifying whether the master is sending data to the
slave (low voltage level) or requesting data from it (high voltage level).
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�ACK/NACK Bit: Each frame in a message is followed by an acknowledge/no-
acknowledge bit. If an address frame or data frame was successfully received, an
ACK bit is returned to the sender from the receiving device.
ADDRESSING
I2C doesn’t have slave select lines like SPI, so it needs another way to let the slave
know that data is being sent to it, and not another slave. It does this
by addressing. The address frame is always the first frame after the start bit in a
new message.
The master sends the address of the slave it wants to communi cate with to every
slave connected to it. Each slave then compares the address sent from the master
to its own address. If the address matches, it sends a low voltage ACK bit back to
the master. If the address doesn’t match, the slave does nothing and the SDA line
remains high.
READ/WRITE BIT
The address frame includes a single bit at the end that informs the slave whether
the master wants to write data to it or receive data from it. If the master wants to
send data to the slave, the read/write bit is a low voltage level. If the master is
requesting data from the slave, the bit is a high voltage level.
THE DATA FRAME
After the master detects the ACK bit from the slave, the first data frame is ready to
be sent.
The data frame is always 8 bits long, and sent with the most significant bit first.
Each data frame is immediately followed by an ACK/NACK bit to verify that the
frame has been received successfully. The ACK bit must be received by either the
master or the slave (depending on who is sending the data) before the next data
frame can be sent.
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�After all of the data frames have been sent, the master can send a stop condition
to the slave to halt the transmission. The stop condition is a voltage transition from
low to hi gh on the SDA line after a low to high transition on the SCL line, with the
SCL line remaining high.
STEPS OF I2C DATA TRANSMISSION
1. The master sends the start condition to every connected slave by switching the
SDA line from a high voltage level to a low voltage level before switching the SCL
line from hi gh to low:
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�2. The master sends each slave the 7 or 10 bit address of the slave it wants to
communicate with, along with the read/write bit:
3. Each slave compares the address sent from the master to its own address. If the
address matches, the slave returns an ACK bit by pulling the SDA line low for one
bit. If the address from the master does not mat ch the slave’s own address, the
slave leaves the SDA line high.
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�4.The master sends or receives the data frame:
5. After each data frame has been transferred, the receiving device returns
another ACK bit to the sender to acknowledge successful receipt of the frame:
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�6. To stop the data transmission, the master sends a stop condition to the slave by
switching SCL high before switching SDA high:
SINGLE MASTER WITH MULTIPLE SLAVES
Because I2C uses addressing, multiple slaves can be controlled from a single
master. With a 7 bit address, 128 (27) unique address are available. Using 10 bit
addresses is uncommon, but provides 1,024 (210) unique addresses. To connect
multiple slaves to a single master, wire t hem like this, with 4.7K Ohm pull-up
resistors connecting the SDA and SCL lines to Vcc:
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�MULTIPLE MASTERS WITH MULTIPLE SLAVES
Multiple masters can be connected to a single slave or multiple slaves. The
problem with multiple masters in the same system comes when two masters
try to send or receive data at the same time over the SDA line. To solve this
problem, each master needs to detect if the SDA line is low or hi gh before
transmitting a message. If the SDA line is low, this means that another master has
control of the bus, and the master should wait to send the message. If the SDA line
is high, then it’s safe to transmit the message. To connect multiple masters to
multiple slaves, use the following diagram, with 4.7K Ohm pull-up resistors
connecting the SDA and SCL lines to Vcc:
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�TIMING DIAGRAM FOR I2C PROTOCOL
ADVANTAGES AND DISADVANTAGES OF I2C
There is a lot to I2C that might make it sound complicated compared to other
protocols, but there are some good reasons why you may or may not want to use
I2C to connect to a particular device:
ADVANTAGES
• Onlyuses two wires
• Supports multiple masters and multiple slaves
• ACK/NACK bit gives confirmation that each frame is transferred
successfully
• Hardware is less complicated than with UARTs
• W ell known and widelyused protocol
DISADVANTAGES
• Slower data transfer rate than SP I
• The size of the data frame is limited to 8 bits
• More complicated hardware needed to implement than SPI
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�Thanks for reading! Hope you learned something from this series of CONTENTS on
electronic communi cation protocols. In case you have any questions or have
anything to add, feel free to leave a comment or inbox me. And be sure to follow
me to get more embedded systems content like this.
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