Digital Control of Active Network Microstructures on Silicon Wafers

Network-on-Chip - Architecture, Optimization, and Design Explorations [Working Title] Pub Date : 2021-12-07 DOI:10.5772/intechopen.101486

Zhongjing Ren, Jianping Yuan, Peng Yan

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引用次数: 7

Abstract

This chapter presents a promising digital control of active microstructures developed and tested on silicon chips by current division and thus independent Joule heating powers, especially for planar submillimeter two-dimensional (2-D) grid microstructures built on silicon wafers by surface microfabrication. Current division on such 2-D grid networks with 2 × 2, 3 × 3, and n × n loops was modeled and analyzed theoretically by employing Kirchhoff’s voltage law (KVL) and Kirchhoff’s current law (KCL), which demonstrated the feasibility of active control of the networks by Joule heating effect. Furthermore, in situ testing of a typical 2-D microstructure with 2 × 2 loops by different DC sources was carried out, and the thermomechanical deformation due to Joule heating was recorded. As a result, active control of the current division has been proven to be a reliable and efficient approach to achieving the digital actuation of 2-D microstructures on silicon chips. Digital control of such microstructural networks on silicon chips envisions great potential applications in active reconfigurable buses for microrobots and flexible electronics.

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硅片上有源网络微结构的数字控制

本章介绍了一种很有前途的数字控制有源微结构的方法，该方法通过电流划分和独立焦耳加热功率在硅片上开发和测试，特别是对于通过表面微加工建立在硅片上的平面亚毫米二维(2d)网格微结构。利用基尔霍夫电压定律(KVL)和基尔霍夫电流定律(KCL)对2 × 2、3 × 3和n × n环的二维网格网络进行了电流划分建模和理论分析，证明了利用焦耳热效应对网络进行主动控制的可行性。在此基础上，利用不同的直流电源对典型的2 × 2环二维微观结构进行了原位测试，记录了焦耳加热引起的热力学变形。因此，电流分割的主动控制已被证明是实现硅芯片上二维微结构的数字驱动的可靠和有效的方法。硅芯片上这种微结构网络的数字控制设想了在微型机器人和柔性电子设备的主动可重构总线中的巨大潜在应用。

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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Network-on-Chip - Architecture, Optimization, and Design Explorations [Working Title]

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