LUNA-CIM: Lookup Table based Programmable Neural Processing in Memory

This paper presents a novel approach for performing computations using Look-Up Tables (LUTs) tailored specifically for Compute-in-Memory applications. The aim is to address the scalability challenges associated with LUT-based computation by reducing storage requirements and energy consumption while capitalizing on the faster and more energy-efficient nature of look-up methods compared to conventional mathematical computations. The proposed method leverages a divide and conquer (D&C) strategy to enhance the scalability of LUT-based computation. By breaking down high-precision multiplications into lower-precision operations, the technique achieves significantly lower area overheads, up to approximately 3.7 times less than conventional LUT-based approaches, without compromising accuracy. To validate the effectiveness of the proposed method, extensive simulations using TSMC 65 nm technology were conducted. The experimental analysis reveals that the proposed approach accounts for less than 0.1\% of the total energy consumption, with only a 32\% increase in area overhead. These results demonstrate considerable improvements achieved in energy efficiency and area utilization through the novel low-energy, low-area-overhead LUT-based computation in an SRAM array.