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Modeling and Optimization of SRAM-based In-Memory Computing Hardware Design

Jyotishman Saikia, Shihui Yin, Sai Kiran Cherupally, Bo Zhang, Jian Meng, Mingoo Seok, Jae-sun Seo

202117 citationsDOI

Abstract

In-memory computing (IMC) has been demonstrated as a promising technique to significantly improve energy-efficiency for deep neural network (DNN) hardware accelerators. However, designing one involves setting many design variables such as the number of parallel rows to assert, analog-to-digital converter (ADC) at the periphery of memory sub-array, activation/weight precisions of DNNs, etc., which affect energy-efficiency, DNN accuracy, and area. While individual IMC designs have been presented in the literature, they have not investigated this multi-dimensional design optimization. In this paper, to fill this knowledge gap, we present a SRAM-based IMC hardware modeling and optimization framework. A unified systematic study closely models IMC hardware, and investigates how a number of design variables and nonidealities (e.g. device mismatch and ADC quantization) affect the DNN accuracy of IMC design. To maintain high DNN accuracy for the IMC SRAM hardware, it is shown that the number of activated rows, ADC resolution, ADC quantization range, and different sources of variability/noise need to be carefully selected and co-optimized with an underlying DNN algorithm to implement.

Topics & Concepts

Static random-access memoryQuantization (signal processing)Computer scienceArtificial neural networkComputer hardwareRowComputer engineeringAlgorithmArtificial intelligenceDatabaseAdvanced Memory and Neural ComputingFerroelectric and Negative Capacitance DevicesParallel Computing and Optimization Techniques
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