A Robust and Power-Efficient Power Line Interference Canceling VLSI Design

2021 34th SBC/SBMicro/IEEE/ACM Symposium on Integrated Circuits and Systems Design (SBCCI) Pub Date : 2021-08-23 DOI:10.1109/SBCCI53441.2021.9529983

M. D. da Rosa, P. D. da Costa, E. D. da Costa, S. Almeida, Guilherme Paim, S. Bampi

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引用次数: 2

Abstract

The electric generators functional performance is prone to suffer from harmonic distortions such as first, second, and third-order. This work proposes a low power dissipation VLSI hardware architecture for a robust power line interference canceling (PLIC). Our proposed Least Mean Square (LMS) architecture has just four clock cycles of latency per sample. The Harmonic Generator (HG) architectures are exploited and optimized in their arithmetic operations. We substituted conventional multiplier by adders and shifters, and used efficient and previously published squared multipliers. In particular, the Vedic multiplier architecture is proven to be an efficient alternative for use in the HG. Our VLSI synthesis results show that the proposed approach, combining the optimized adaptive filters LMS and HG's hardware architecture, turns the PLIC VLSI structure robust and power-efficient by effectively suppressing interferences in both ECG (Electrocardiogram) and EEG (Electroencephalo-gram) signals. Notably, the PLIC architecture is more efficient in the circuit area and power dissipation with the Vedic multiplier in the HG, with savings of up to 40% in total power and 15% in VLSI area, compared to the state-of-the-art solution.

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一种鲁棒且节能的电力线干扰消除VLSI设计

发电机的功能性能容易受到一阶、二阶和三阶谐波畸变的影响。本文提出了一种低功耗的VLSI硬件架构，用于鲁棒的电力线干扰消除(PLIC)。我们提出的最小均方(LMS)架构每个样本只有四个时钟周期的延迟。对谐波发生器(HG)结构的算术运算进行了开发和优化。我们用加法器和移法器代替了传统的乘法器，并使用了有效的和先前发表的平方乘法器。特别是，吠陀乘法器架构被证明是一种有效的替代方案。我们的VLSI合成结果表明，该方法结合了优化的自适应滤波器LMS和HG的硬件架构，通过有效抑制ECG(心电图)和EEG(脑电图)信号的干扰，使PLIC VLSI结构变得鲁棒且节能。值得注意的是，与最先进的解决方案相比，PLIC架构在电路面积和功耗方面更高效，并且在HG中使用了Vedic乘法器，可节省高达40%的总功率和15%的VLSI面积。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 34th SBC/SBMicro/IEEE/ACM Symposium on Integrated Circuits and Systems Design (SBCCI)

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