A Local Computing Cell and 6T SRAM-Based Computing-in-Memory Macro With 8-b MAC Operation for Edge AI Chips

A Local Computing Cell and 6T SRAM-Based Computing-in-Memory Macro With 8-b MAC Operation for Edge AI Chips

This article presents a computing-in-memory (CIM) structure aimed at improving the energy efficiency of edge devices running multi-bit multiply-and-accumulate (MAC) operations. The proposed scheme includes a 6T SRAM-based CIM (SRAM-CIM) macro capable of: 1) weight-bitwise MAC (WbwMAC) operations to...

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Veröffentlicht in:IEEE journal of solid-state circuits 2021-09, Vol.56 (9), p.2817-2831
Hauptverfasser: Si, Xin, Tu, Yung-Ning, Huang, Wei-Hsing, Su, Jian-Wei, Lu, Pei-Jung, Wang, Jing-Hong, Liu, Ta-Wei, Wu, Ssu-Yen, Liu, Ruhui, Chou, Yen-Chi, Chung, Yen-Lin, Shih, William, Lo, Chung-Chuan, Liu, Ren-Shuo, Hsieh, Chih-Cheng, Tang, Kea-Tiong, Lien, Nan-Chun, Shih, Wei-Chiang, He, Yajuan, Li, Qiang, Chang, Meng-Fan
Format: Artikel
Sprache:eng
Schlagworte:
Adaptive algorithms
Artificial intelligence (AI)
Common Information Model (computing)
Computation
Computer architecture
computing-in-memory
Energy efficiency
Engineering
Engineering, Electrical & Electronic
local computing cell (LCC)
Microprocessors
Multiplication
Neural networks
random access memory
Science & Technology
Sense amplifiers
Software
SRAM cells
Static random access memory
Technology
Transistors
Weight
weight-bitwise MAC (WbwMAC) operation
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Zusammenfassung:This article presents a computing-in-memory (CIM) structure aimed at improving the energy efficiency of edge devices running multi-bit multiply-and-accumulate (MAC) operations. The proposed scheme includes a 6T SRAM-based CIM (SRAM-CIM) macro capable of: 1) weight-bitwise MAC (WbwMAC) operations to expand the sensing margin and improve the readout accuracy for high-precision MAC operations; 2) a compact 6T local computing cell to perform multiplication with suppressed sensitivity to process variation; 3) an algorithm-adaptive low MAC-aware readout scheme to improve energy efficiency; 4) a bitline header selection scheme to enlarge signal margin; and 5) a small-offset margin-enhanced sense amplifier for robust read operations against process variation. A fabricated 28-nm 64-kb SRAM-CIM macro achieved access times of 4.1-8.4 ns with energy efficiency of 11.5-68.4 TOPS/W, while performing MAC operations with 4- or 8-b input and weight precision.
ISSN:0018-9200
1558-173X
DOI:10.1109/JSSC.2021.3073254