面向区域高效内存计算深度学习的沉浸式协同数字化

Shamma Nasrin, Maeesha Binte Hashem, Nastaran Darabi, Benjamin Parpillon, F. Fahim, Wilfred Gomes, A. Trivedi
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引用次数: 3

摘要

这项工作讨论了内存中计算(CiM)阵列之间的内存沉浸式协作数字化,以最大限度地减少用于深度学习推理的传统模数转换器(ADC)的面积开销。因此,使用所提出的方案,可以在有限的内存占用设计中容纳更多的CiM阵列,从而提高并行性并最大限度地减少外部内存访问。在数字化方案下,CiM阵列利用其寄生位线形成内存内电容数模转换器(DAC),促进面积高效连续逼近(SA)数字化。CiM阵列协作时,当阵列计算输入和权重的标量积时,近端阵列将模拟域积和数字化。我们讨论了CiM阵列之间的各种网络配置,其中Flash, SA及其混合数字化步骤可以使用所提出的内存浸入式方案有效地实现。结果用65纳米CMOS测试芯片进行了验证。与40 nm节点的5位SAR ADC相比,我们的65 nm设计通过利用内存计算结构,减少了~25 area×和~ 1.4×的能量。与40nm节点的5位Flash ADC相比,我们的设计所需面积减少~ 51x,能耗减少~ 13x。
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Memory-Immersed Collaborative Digitization for Area-Efficient Compute-in-Memory Deep Learning
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 ~25 area× less and ∼1.4× less energy by leveraging in-memory computing structures. Compared to a 40 nm-node 5-bit Flash ADC, our design requires ∼51× less area and ∼13× less energy.
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