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Sudhir Satpathy
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2020 – today
- 2021
- [j12]Raghavan Kumar
, Xiaosen Liu
A Time-/Frequency-Domain Side-Channel Attack Resistant AES-128 and RSA-4K Crypto-Processor in 14-nm CMOS. IEEE J. Solid State Circuits 56(4): 1141-1151 (2021) - 2020
- [j11]Raghavan Kumar
A 4900- $\mu$ m2 839-Mb/s Side-Channel Attack- Resistant AES-128 in 14-nm CMOS With Heterogeneous Sboxes, Linear Masked MixColumns, and Dual-Rail Key Addition. IEEE J. Solid State Circuits 55(4): 945-955 (2020) - [c37]Raghavan Kumar, Sudhir Satpathy, Vikram B. Suresh, Mark A. Anders, Himanshu Kaul, Vivek De, Sanu Mathew:
A 435MHz, 2.5Mbps/W Side-Channel-Attack Resistant Crypto-Processor for Secure RSA-4K Public-Key Encryption in 14nm CMOS. VLSI Circuits 2020: 1-2
2010 – 2019
- 2019
- [j10]Sudhir Satpathy
An All-Digital Unified Physically Unclonable Function and True Random Number Generator Featuring Self-Calibrating Hierarchical Von Neumann Extraction in 14-nm Tri-gate CMOS. IEEE J. Solid State Circuits 54(4): 1074-1085 (2019) - [c36]Sudhir Satpathy, Vikram B. Suresh, Raghavan Kumar, Vinodh Gopal, James Guilford, Kirk Yap, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Ram Krishnamurthy, Sanu Mathew:
A 220-900mV 179Mcode/s 36pJ/code Canonical Huffman Encoder for DEFLATE Compression in 14nm CMOS. CICC 2019: 1-4 - [c35]Vikram B. Suresh, Sudhir Satpathy, Raghavan Kumar, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Ram Krishnamurthy, Sanu Mathew:
A 225-950mV 1.5Tbps/W Whirlpool Hashing Accelerator for Secure Automotive Platforms in 14nm CMOS. CICC 2019: 1-4 - [c34]Vikram B. Suresh, Sudhir Satpathy, Raghavan Kumar, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Ram Krishnamurthy, Vivek De, Sanu Mathew:
A 250Mv, 0.063J/Ghash Bitcoin Mining Engine in 14nm CMOS Featuring Dual-Vcc Sha256 Datapath and 3-Phase Latch Based Clocking. VLSI Circuits 2019: 32- - [c33]Steven Hsu, Amit Agarwal, Monodeep Kar, Mark A. Anders, Himanshu Kaul, Raghavan Kumar, Sudhir Satpathy, Vikram B. Suresh, Sanu Mathew, Ram Krishnamurthy, Vivek De:
A Microwatt-Class Always-On Sensor Fusion Engine Featuring Ultra-Low-Power AOI Clocked Circuits in 14nm CMOS. VLSI Circuits 2019: 50- - [c32]Raghavan Kumar, Vikram B. Suresh, Monodeep Kar, Sudhir Satpathy, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Gregory K. Chen, Ram Krishnamurthy, Vivek De, Sanu Mathew:
A 4900×m2 839Mbps Side-Channel Attack Resistant AES-128 in 14nm CMOS with Heterogeneous Sboxes, Linear Masked MixColumns and Dual-Rail Key Addition. VLSI Circuits 2019: 234- - [c31]Sudhir Satpathy, Vikram B. Suresh, Raghavan Kumar, Vinodh Gopal, James Guilford, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Ram Krishnamurthy, Vivek De, Sanu Mathew:
A 1.4GHz 20.5Gbps GZIP decompression accelerator in 14nm CMOS featuring dual-path out-of-order speculative Huffman decoder and multi-write enabled register file array. VLSI Circuits 2019: 238- - 2018
- [c30]Himanshu Kaul, Mark A. Anders, Sanu Mathew, Vikram B. Suresh, Sudhir Satpathy, Amit Agarwal, Steven Hsu, Ram Krishnamurthy:
Ultra-Lightweight 548-1080 Gate 166Gbps/W-12.6Tbps/W SIMON 32/64 Cipher Accelerators for IoT in 14nm Tri-gate CMOS. A-SSCC 2018: 1-4 - [c29]Sudhir Satpathy, Sanu Mathew, Vikram B. Suresh, Vinodh Gopal, James Guilford, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Ram Krishnamurthy:
A 280mV 3.1pJ/code Huffman Decoder for DEFLATE Decompression Featuring Opportunistic Code Skip and 3-way Symbol Generation in 14nm Tri-gate CMOS. A-SSCC 2018: 263-266 - [c28]Sanu Mathew, Sudhir Satpathy, Vikram B. Suresh, Ram Krishnamurthy:
Ultra-low energy circuit building blocks for security technologies. DATE 2018: 391-394 - [c27]Sudhir Satpathy, Sanu Mathew, Vikram B. Suresh, Vinodh Gopal, James Guilford, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Kam Krisnnamurthy:
34.4Mbps 1.56Tbps/W DEFLATE Decompression Accelerator Featuring Block-Adaptive Huffman Decoder in 14nm Tri-Gate CMOS for IoT Platforms. ESSCIRC 2018: 90-93 - [c26]Vikram B. Suresh, Sudhir Satpathy, Sanu Mathew, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Ram Krishnamurthy:
A 230mV-950mV 2.8Tbps/W Unified SHA256/SM3 Secure Hashing Hardware Accelerator in 14nm Tri-Gate CMOS. ESSCIRC 2018: 98-101 - [c25]Mark A. Anders, Himanshu Kaul, Sanu Mathew, Vikram B. Suresh, Sudhir Satpathy, Amit Agarwal, Steven Hsu, Ram Krishnamurthy:
2.9TOPS/W Reconfigurable Dense/Sparse Matrix-Multiply Accelerator with Unified INT8/INTI6/FP16 Datapath in 14NM Tri-Gate CMOS. VLSI Circuits 2018: 39-40 - [c24]Sudhir Satpathy, Sanu Mathew, Vikram B. Suresh, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Ram Krishnamurthy, Vivek De:
An All-Digital Unified Static/Dynamic Entropy Generator Featuring Self-Calibrating Hierarchical Von Neumann Extraction for Secure Privacy-Preserving Mutual Authentication in IoT Mote Platforms. VLSI Circuits 2018: 169-170 - [c23]Sudhir Satpathy, Vikram B. Suresh, Sanu Mathew, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Ram Krishnamurthy:
220MV-900MV 794/584/754 GBPS/W Reconfigurable GF(24)2 AES/SMS4/Camellia Symmetric-Key Cipher Accelerator in 14NM Tri-Gate CMOS. VLSI Circuits 2018: 175-176 - 2017
- [j9]Sudhir Satpathy
A 4-fJ/b Delay-Hardened Physically Unclonable Function Circuit With Selective Bit Destabilization in 14-nm Trigate CMOS. IEEE J. Solid State Circuits 52(4): 940-949 (2017) - [c22]Sanu Mathew, Sudhir Satpathy, Vikram B. Suresh, Ram K. Krishnamurthy:
Energy efficient and ultra low voltage security circuits for nanoscale CMOS technologies. CICC 2017: 1-4 - [c21]Sanu Mathew, Sudhir Satpathy, Vikram B. Suresh, Ram Krishnamurthy:
Invited paper: Ultra-low energy security circuit primitives for IoT platforms. ISLPED 2017: 1-4 - 2016
- [j8]Sanu K. Mathew, David Johnston, Sudhir Satpathy, Vikram B. Suresh, Paul Newman, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Gregory K. Chen, Ram K. Krishnamurthy:
µRNG: A 300-950 mV, 323 Gbps/W All-Digital Full-Entropy True Random Number Generator in 14 nm FinFET CMOS. IEEE J. Solid State Circuits 51(7): 1695-1704 (2016) - [c20]Sudhir Satpathy, Sanu Mathew, Vikram B. Suresh, Mark A. Anders, Gregory K. Chen, Himanshu Kaul, Amit Agarwal, Steven Hsu, Ram Krishnamurthy, Vivek De:
A 305mV-850mV 400μW 45GSamples/J reconfigurable compressive sensing engine with early-termination for ultra-low energy target detection in 14nm tri-gate CMOS. A-SSCC 2016: 253-256 - [c19]Sudhir Satpathy, Sanu Mathew, Vikram B. Suresh, Ram Krishnamurthy:
Ultra-low energy security circuits for IoT applications. ICCD 2016: 682-685 - [c18]Himanshu Kaul, Mark A. Anders, Sanu K. Mathew, Gregory K. Chen, Sudhir Satpathy, Steven Hsu, Amit Agarwal, Ram Krishnamurthy:
14.4 A 21.5M-query-vectors/s 3.37nJ/vector reconfigurable k-nearest-neighbor accelerator with adaptive precision in 14nm tri-gate CMOS. ISSCC 2016: 260-261 - [c17]Amit Agarwal, Steven Hsu, Mark A. Anders, Sanu Mathew, Gregory K. Chen, Himanshu Kaul, Sudhir Satpathy, Ram Krishnamurthy:
A 350mV-900mV 2.1GHz 0.011mm2 regular expression matching accelerator with aging-tolerant low-VMIN circuits in 14nm tri-gate CMOS. VLSI Circuits 2016: 1-2 - [c16]Sanu Mathew, Sudhir Satpathy, Vikram B. Suresh, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Gregory K. Chen, Ram Krishnamurthy, Vivek De:
A 4fJ/bit delay-hardened physically unclonable function circuit with selective bit destabilization in 14nm tri-gate CMOS. VLSI Circuits 2016: 1-2 - [c15]Sudhir Satpathy, Sanu Mathew, Vikram B. Suresh, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Gregory K. Chen, Ram Krishnamurthy:
250mV-950mV 1.1Tbps/W double-affine mapped Sbox based composite-field SMS4 encrypt/decrypt accelerator in 14nm tri-gate CMOS. VLSI Circuits 2016: 1-2 - 2015
- [j7]Gregory K. Chen, Mark A. Anders, Himanshu Kaul, Sudhir Satpathy, Sanu K. Mathew, Steven Hsu, Amit Agarwal, Ram Krishnamurthy, Vivek De, Shekhar Borkar:
A 340 mV-to-0.9 V 20.2 Tb/s Source-Synchronous Hybrid Packet/Circuit-Switched 16 × 16 Network-on-Chip in 22 nm Tri-Gate CMOS. IEEE J. Solid State Circuits 50(1): 59-67 (2015) - [j6]Sanu Mathew, Sudhir Satpathy, Vikram B. Suresh, Mark A. Anders, Himanshu Kaul, Amit Agarwal, Steven Hsu, Gregory K. Chen, Ram Krishnamurthy:
340 mV-1.1 V, 289 Gbps/W, 2090-Gate NanoAES Hardware Accelerator With Area-Optimized Encrypt/Decrypt GF(2 4 ) 2 Polynomials in 22 nm Tri-Gate CMOS. IEEE J. Solid State Circuits 50(4): 1048-1058 (2015) - [c14]Sanu Mathew, David Johnston
μRNG: A 300-950mV 323Gbps/W all-digital full-entropy true random number generator in 14nm FinFET CMOS. ESSCIRC 2015: 116-119 - 2014
- [c13]Sudhir Satpathy, Sanu Mathew, Jiangtao Li, Patrick Koeberl, Mark A. Anders, Himanshu Kaul, Gregory K. Chen, Amit Agarwal, Steven Hsu, Ram Krishnamurthy:
13fJ/bit probing-resilient 250K PUF array with soft darkbit masking for 1.94% bit-error in 22nm tri-gate CMOS. ESSCIRC 2014: 239-242 - [c12]Gregory K. Chen, Mark A. Anders, Himanshu Kaul, Sudhir Satpathy, Sanu K. Mathew, Steven K. Hsu, Amit Agarwal, Ram K. Krishnamurthy, Shekhar Borkar, Vivek De:
16.1 A 340mV-to-0.9V 20.2Tb/s source-synchronous hybrid packet/circuit-switched 16×16 network-on-chip in 22nm tri-gate CMOS. ISSCC 2014: 276-277 - [c11]Sanu K. Mathew, Sudhir Satpathy, Mark A. Anders, Himanshu Kaul, Steven K. Hsu, Amit Agarwal, Gregory K. Chen, Rachael J. Parker, Ram K. Krishnamurthy, Vivek De:
16.2 A 0.19pJ/b PVT-variation-tolerant hybrid physically unclonable function circuit for 100% stable secure key generation in 22nm CMOS. ISSCC 2014: 278-279 - [c10]Sanu Mathew, Sudhir Satpathy, Vikram B. Suresh, Himanshu Kaul, Mark A. Anders, Gregory K. Chen, Amit Agarwal, Steven Hsu, Ram Krishnamurthy:
340mV-1.1V, 289Gbps/W, 2090-gate NanoAES hardware accelerator with area-optimized encrypt/decrypt GF(24)2 polynomials in 22nm tri-gate CMOS. VLSIC 2014: 1-2 - 2013
- [j5]Ronald G. Dreslinski, David Fick, Bharan Giridhar, Gyouho Kim, Sangwon Seo, Matthew Fojtik, Sudhir Satpathy, Yoonmyung Lee
Centip3De: a many-core prototype exploring 3D integration and near-threshold computing. Commun. ACM 56(11): 97-104 (2013) - [j4]David Fick, Ronald G. Dreslinski, Bharan Giridhar, Gyouho Kim, Sangwon Seo, Matthew Fojtik, Sudhir Satpathy, Yoonmyung Lee
Centip3De: A Cluster-Based NTC Architecture With 64 ARM Cortex-M3 Cores in 3D Stacked 130 nm CMOS. IEEE J. Solid State Circuits 48(1): 104-117 (2013) - [j3]Ronald G. Dreslinski, David Fick, Bharan Giridhar, Gyouho Kim, Sangwon Seo, Matthew Fojtik, Sudhir Satpathy, Yoonmyung Lee
Centip3De: A 64-Core, 3D Stacked Near-Threshold System. IEEE Micro 33(2): 8-16 (2013) - [c9]Reetuparna Das
Catnap: energy proportional multiple network-on-chip. ISCA 2013: 320-331 - 2012
- [j2]Korey Sewell, Ronald G. Dreslinski, Thomas Manville, Sudhir Satpathy, Nathaniel Ross Pinckney, Geoffrey Blake, Michael Cieslak, Reetuparna Das
Swizzle-Switch Networks for Many-Core Systems. IEEE J. Emerg. Sel. Topics Circuits Syst. 2(2): 278-294 (2012) - [j1]Sanu Mathew, Suresh Srinivasan, Mark A. Anders, Himanshu Kaul, Steven Hsu, Farhana Sheikh
2.4 Gbps, 7 mW All-Digital PVT-Variation Tolerant True Random Number Generator for 45 nm CMOS High-Performance Microprocessors. IEEE J. Solid State Circuits 47(11): 2807-2821 (2012) - [c8]Ronald G. Dreslinski, Thomas Manville, Korey Sewell, Reetuparna Das
XPoint cache: scaling existing bus-based coherence protocols for 2D and 3D many-core systems. PACT 2012: 75-86 - [c7]Sudhir Satpathy, Reetuparna Das
High radix self-arbitrating switch fabric with multiple arbitration schemes and quality of service. DAC 2012: 406-411 - [c6]Ronald G. Dreslinski, David Fick, Bharan Giridhar, Gyouho Kim, Sangwon Seo, Matthew Fojtik, Sudhir Satpathy, Yoonmyung Lee
Centip3De: A 64-core, 3D stacked, near-threshold system. Hot Chips Symposium 2012: 1-30 - [c5]Ronald G. Dreslinski, Korey Sewell, Thomas Manville, Sudhir Satpathy, Nathaniel Ross Pinckney, Geoffrey Blake, Michael Cieslak, Reetuparna Das
Swizzle Switch: A self-arbitrating high-radix crossbar for NoC systems. Hot Chips Symposium 2012: 1-44 - [c4]David Fick, Ronald G. Dreslinski, Bharan Giridhar, Gyouho Kim, Sangwon Seo, Matthew Fojtik, Sudhir Satpathy, Yoonmyung Lee
Centip3De: A 3930DMIPS/W configurable near-threshold 3D stacked system with 64 ARM Cortex-M3 cores. ISSCC 2012: 190-192 - [c3]Sudhir Satpathy, Korey Sewell, Thomas Manville, Yen-Po Chen, Ronald G. Dreslinski, Dennis Sylvester, Trevor N. Mudge, David T. Blaauw:
A 4.5Tb/s 3.4Tb/s/W 64×64 switch fabric with self-updating least-recently-granted priority and quality-of-service arbitration in 45nm CMOS. ISSCC 2012: 478-480 - [c2]Sudhir Satpathy, Dennis Sylvester, David T. Blaauw:
A standard cell compatible bidirectional repeater with thyristor assist. VLSIC 2012: 174-175 - 2011
- [c1]Mark Woh, Sudhir Satpathy, Ronald G. Dreslinski, Danny Kershaw, Dennis Sylvester, David T. Blaauw, Trevor N. Mudge:
Low power interconnects for SIMD computers. DATE 2011: 600-605
Coauthor Index
Vivek De
aka: Vivek K. De
aka: Vivek K. De
Steven Hsu
aka: Steven K. Hsu
aka: Steven K. Hsu
Ram Krishnamurthy 0001
aka: Ram K. Krishnamurthy
aka: Ram K. Krishnamurthy
Sanu Mathew
aka: Sanu K. Mathew
aka: Sanu K. Mathew
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