基于内禀阻抗增强和adc内计算的高并行rram内存宏

IF 2 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE IEEE Journal on Exploratory Solid-State Computational Devices and Circuits Pub Date : 2023-03-14 DOI:10.1109/JXCDC.2023.3255788

Tian Xie;Shimeng Yu;Shaolan Li

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引用次数: 1

摘要

电阻随机存取存储器（RRAM）被认为是一个很有前途的内存计算（CIM）平台；然而，在高通量和高分辨率的情况下，它们往往会迅速失去能量效率。这项工作没有使用存取晶体管作为开关，而是探索了它们作为公共栅极电流缓冲器的模拟特性。因此，可以使电池电流最小化，并提高输出阻抗。为了进一步降低外围电路的复杂度，还提出了ADC内计算（IAC）的思想。得益于所提出的思想，可以实现基于CIFAR-10数据集的预训练VGG-8网络，并且以8.9TOPS/W的能量效率（对于8位乘法和累加（MAC）运算）实现87.2%的准确率，表明所提出的技术能够实现低失真的部分和结果，同时仍然能够以功率有效的方式操作。

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A High-Parallelism RRAM-Based Compute-In-Memory Macro With Intrinsic Impedance Boosting and In-ADC Computing

Resistive random access memory (RRAM) is considered to be a promising compute-in-memory (CIM) platform; however, they tend to lose energy efficiency quickly in high-throughput and high-resolution cases. Instead of using access transistors as switches, this work explores their analog characteristics as common-gate current buffers. So the cell current can be minimized and the output impedance is boosted. The idea of In-ADC Computing (IAC) is also proposed to further decrease the complexity of the peripheral circuits. Benefiting from the proposed ideas, a pretrained VGG-8 network based on the CIFAR-10 dataset can be implemented, and an accuracy of 87.2% is achieved with 8.9 TOPS/W energy efficiency (for 8-bit multiply-and-accumulate (MAC) operation), demonstrating that the proposed techniques enable low-distortion partial sum results while still being able to operate in a power-efficient way.

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