Body Bias Control for Renewable Energy Source with a High Inner Resistance

IEEE Transactions on Multi-Scale Computing Systems Pub Date : 2018-04-17 DOI:10.1109/TMSCS.2018.2827980

Keita Azegami;Hayate Okuhara;Hideharu Amano

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引用次数: 1

Abstract

Sensor nodes used in Internet of Things (IoT) are required to work an extremely long time without replacing the battery. Natural renewable energy such as a solar battery is a hopeful candidate for such nodes. Here, a power model for operating an Silicon on Insulator (SOI) device with a solar battery including a large inner resistance is proposed, and applied to a micro-controller V850E-star and an accelerator CMA-SOTB2. Unlike the ideal case, the maximum operational frequency was achieved with reverse biasing by suppressing the leakage current which decreases the supply voltage. Under the room light with a large inner resistance, the strong reverse bias is effective, while a relatively weak reverse bias is advantageous under the bright light. The proposed model is appeared to be useful to estimate the appropriate body bias voltage both for V850E-star and CMA-SOTB2. In the V850E-star, the estimated operational frequencies were different from the real chip, while they were relatively matched when CMA-SOTB2 was used under the low illuminance.

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高内阻可再生能源的体偏控制

物联网（IoT）中使用的传感器节点需要在不更换电池的情况下工作很长时间。太阳能电池等天然可再生能源有望成为此类节点的候选能源。在此，提出了一种用于操作具有包括大内阻的太阳能电池的绝缘体上硅（SOI）器件的功率模型，并将其应用于微控制器V850E星和加速器CMA-SOTB2。与理想情况不同，通过抑制降低电源电压的泄漏电流，通过反向偏置实现了最大工作频率。在内阻较大的室内光线下，强反向偏压是有效的，而在明亮的光线下，相对较弱的反向偏压是有利的。所提出的模型似乎有助于估计V850E恒星和CMA-SOTB2的适当体偏置电压。在V850E恒星中，估计的工作频率与实际芯片不同，而在低照度下使用CMA-SOTB2时，它们相对匹配。

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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IEEE Transactions on Multi-Scale Computing Systems

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