静态随机存取存储器
芯(光纤)
卷积神经网络
二进制数
功率(物理)
特征(语言学)
计算机科学
多核处理器
人工智能
并行计算
计算机硬件
电信
物理
数学
量子力学
语言学
算术
哲学
作者
Ruiyong Zhao,Zhenghui Gong,Yulan Liu,Jing Chen
出处
期刊:Micromachines
[Multidisciplinary Digital Publishing Institute]
日期:2024-04-30
卷期号:15 (5): 617-617
被引量:1
摘要
This article proposes a novel design for an in-memory computing SRAM, the DAM SRAM CORE, which integrates storage and computational functionality within a unified 11T SRAM cell and enables the performance of large-scale parallel Multiply–Accumulate (MAC) operations within the SRAM array. This design not only improves the area efficiency of the individual cells but also realizes a compact layout. A key highlight of this design is its employment of a dynamic aXNOR-based computation mode, which significantly reduces the consumption of both dynamic and static power during the computational process within the array. Additionally, the design innovatively incorporates a self-stabilizing voltage gradient quantization circuit, which enhances the computational accuracy of the overall system. The 64 × 64 bit DAM SRAM CORE in-memory computing core was fabricated using the 55 nm CMOS logic process and validated via simulations. The experimental results show that this core can deliver 5-bit output results with 1-bit input feature data and 1-bit weight data, while maintaining a static power consumption of 0.48 mW/mm2 and a computational power consumption of 11.367 mW/mm2. This showcases its excellent low-power characteristics. Furthermore, the core achieves a data throughput of 109.75 GOPS and exhibits an impressive energy efficiency of 21.95 TOPS/W, which robustly validate the effectiveness and advanced nature of the proposed in-memory computing core design.
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