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Memory-Immersed Collaborative Digitization for Area-Efficient Compute-in-Memory Deep Learning

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arxiv 2307.03863 v1 pith:JPH76Y34 submitted 2023-07-07 cs.AR cs.LG

Memory-Immersed Collaborative Digitization for Area-Efficient Compute-in-Memory Deep Learning

classification cs.AR cs.LG
keywords arraysdigitizationlesstimesareamemory-immersedschemearea-efficient
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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This work discusses memory-immersed collaborative digitization among compute-in-memory (CiM) arrays to minimize the area overheads of a conventional analog-to-digital converter (ADC) for deep learning inference. Thereby, using the proposed scheme, significantly more CiM arrays can be accommodated within limited footprint designs to improve parallelism and minimize external memory accesses. Under the digitization scheme, CiM arrays exploit their parasitic bit lines to form a within-memory capacitive digital-to-analog converter (DAC) that facilitates area-efficient successive approximation (SA) digitization. CiM arrays collaborate where a proximal array digitizes the analog-domain product-sums when an array computes the scalar product of input and weights. We discuss various networking configurations among CiM arrays where Flash, SA, and their hybrid digitization steps can be efficiently implemented using the proposed memory-immersed scheme. The results are demonstrated using a 65 nm CMOS test chip. Compared to a 40 nm-node 5-bit SAR ADC, our 65 nm design requires $\sim$25$\times$ less area and $\sim$1.4$\times$ less energy by leveraging in-memory computing structures. Compared to a 40 nm-node 5-bit Flash ADC, our design requires $\sim$51$\times$ less area and $\sim$13$\times$ less energy.

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