DREAM-CIM: A Digital SRAM-Based CIM Accelerator for Energy- and Area-Efficient Edge AI

With the rise of energy-constrained smart edge applications, there is a pressing need for energy-efficient computing engines that process generated data locally, at least for small and medium-sized applications. To address this issue, this paper proposes DREAM-CIM, a digital SRAM-based computation-in-memory (CIM) accelerator. It targets an energy- and area-efficient implementation of the multiply-and-accumulate (MAC) operation, which is the core operation of neural networks. The accelerator is based on a multi-sub-array macro to increase parallelism, integrates multiplication operations within the memory cells such that they are executed while reading the cells, makes use of pipelining to further optimize the throughput of the MAC operations, and gets rid of the expensive adder-tree structures commonly used in State-of-The-Art (SOTA) digital CIM solutions by replacing them with a custom accumulation circuit to reduce power and area. The SPICE simulation results of the DREAM-CIM accelerator show an energy efficiency of 5097 TOPS/W (normalized to a 1-bit ${\boldsymbol{\times}}$ 1-bit MAC operation) and an area efficiency of 3854 TOPS/mm${}^{2}$ using 22 nm technology node. The obtained circuit-level results were fed into a python-based system-level simulator to benchmark the system architecture using two applications, i.e., image classification (using MNIST and CIFAR-10 dataset on LeNet5 and Resnet-20 models) and object detection (using COCO dataset on the YoloV6 model). The system-level results show that DREAM-CIM can achieve an energy efficiency of 0.1mJ, 0.2mJ, and 11.02mJ per inference for the MNIST, YOLOv6, and CIFAR-10 datasets, respectively, while maintaining SOTA accuracy.