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采用深度学习模型加速多媒体应用的高效能级联无效应 GDI 近似加法器

Power and Area Efficient Cascaded Effectless GDI Approximate Adder for Accelerating Multimedia Applications Using Deep Learning Model.

机构信息

School of Computing, SASTRA Deemed University, Thanjavur 613 401, India.

Department of Electronic and Electrical Engineering, The University of Sheffield, Sheffield S1 3JD, UK.

出版信息

Comput Intell Neurosci. 2022 Mar 19;2022:3505439. doi: 10.1155/2022/3505439. eCollection 2022.

DOI:10.1155/2022/3505439
PMID:35345797
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8957425/
Abstract

Approximate computing is an upsurging technique to accelerate the process through less computational effort while keeping admissible accuracy of error-tolerant applications such as multimedia and deep learning. Inheritance properties of the deep learning process aid the designer to abridge the circuitry and also to increase the computation speed at the cost of the accuracy of results. High computational complexity and low-power requirement of portable devices in the dark silicon era sought suitable alternate for Complementary Metal Oxide Semiconductor (CMOS) technology. Gate Diffusion Input (GDI) logic is one of the prompting alternatives to CMOS logic to reduce transistors and low-power design. In this work, a novel energy and area efficient 1-bit GDI-based full swing Energy and Area efficient Full Adder (EAFA) with minimum error distance is proposed. The proposed architecture was constructed to mitigate the cascaded effect problem in GDI-based circuits. It is proved by extending the proposed 1-bit GDI-based adder for different 16-bit Energy and Area Efficient High-Speed Error-Tolerant Adders (EAHSETA) segmented as accurate and inaccurate adder circuits. The proposed adder's design metrics in terms of delay, area, and power dissipation are verified through simulation using the Cadence tool. The proposed logic is deployed to accelerate the convolution process in the Low-Weight Digit Detector neural network for real-time handwritten digit classification application as a case study in the Intel Cyclone IV Field Programmable Gate Array (FPGA). The results confirm that our proposed EAHSETA occupies fewer logic elements and improves operation speed with the speed-up factor of 1.29 than other similar techniques while producing 95% of classification accuracy.

摘要

近似计算是一种新兴技术,通过减少计算工作量来加速处理过程,同时保持多媒体和深度学习等容错应用的可接受误差精度。深度学习过程的继承属性有助于设计人员简化电路,并以牺牲结果精度为代价提高计算速度。在暗硅时代,对便携式设备的高计算复杂性和低功耗要求需要为互补金属氧化物半导体 (CMOS) 技术寻找合适的替代方案。门扩散输入 (GDI) 逻辑是降低晶体管数量和实现低功耗设计的 CMOS 逻辑的替代方案之一。在这项工作中,提出了一种新颖的基于 1 位 GDI 的全摆幅能量和面积高效全加器 (EAFA),具有最小的误差距离。所提出的架构是为了减轻 GDI 电路中的级联效应问题而构建的。通过将基于 1 位 GDI 的加法器扩展为不同的 16 位能量和面积高效高速容错加法器 (EAHSETA),并将其划分为准确和不准确的加法器电路,证明了这一点。所提出的加法器的设计指标(延迟、面积和功耗)通过使用 Cadence 工具进行的模拟得到验证。所提出的逻辑被部署在低权重数字检测器神经网络中,以加速卷积过程,用于实时手写数字分类应用作为 Intel Cyclone IV 现场可编程门阵列 (FPGA) 中的案例研究。结果证实,我们提出的 EAHSETA 占用的逻辑元件更少,与其他类似技术相比,操作速度提高了 1.29 倍,同时产生了 95%的分类准确率。

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