可穿戴生物可降解可拉伸互连的信号完整性分析

IF 2.2 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Gulafsha Bhatti;Devkaran Maru;Kamlesh Patle;Kinnaree Shah;Vinay Palaparthy;Yash Agrawal
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引用次数: 0

摘要

兼容电子设备的出现导致了生物传感器、柔性电子和可穿戴应用等新兴领域的巨大发展。蛇形互连的制作对柔性电子系统的可行性至关重要。在这项工作中,可生物降解的纺织品被认为是一种柔性或可拉伸的基底。纺织品在电子产品中的使用已经成为可穿戴电子产品应用的一个引人注目的解决方案。由于其坚固的特性,包括多种拉伸能力和无摩擦性能,它是一种优秀的基板。可伸缩互连是可穿戴设备发展的另一个重要实体。在目前的工作中,这是用蛇形结构和石墨烯作为导电材料在可生物降解的纺织品上制造的。除了制造之外,还采用了可拉伸互连的驱动-互连-负载(DIL)模型来评估其信号完整性。在可重构系统领域,DIL模型对实现电子系统设计的可靠性起着至关重要的作用。互连设计对于缓解时序问题和提高系统性能至关重要。这封信探讨了DIL框架内可拉伸互连的优化和意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Signal Integrity Analysis of Biodegradable Stretchable Interconnect for Wearable Application
The advent of conformable electronic devices has led to immense development in emerging sectors, such as biosensors, flexible electronics, and wearable applications. Fabrication of serpentine interconnect is of supreme importance for the feasibility of the flexible electronics system. In this work, biodegradable textile is considered as a flexible or stretchable substrate. The use of textiles in electronics has emerged as a compelling solution for wearable electronics applications. Due to its robust characteristics, including multiple stretching capabilities and frictionless properties, it serves as an excellent substrate. The stretchable interconnect is another essential entity in the development of wearable devices. In the current work, this is fabricated over biodegradable textile using serpentine structure and graphene as conductive material. In addition to fabrication, the driver-interconnect-load (DIL) model of the stretchable interconnect is novelly incorporated to assess its signal integrity. In the domain of reconfigurable systems, the DIL model plays a crucial role in achieving the reliability of electronic system design. The interconnect design is vital to mitigate timing issues and enhance system performance. This letter explores the optimization and significance of stretchable interconnects within the DIL framework.
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来源期刊
IEEE Sensors Letters
IEEE Sensors Letters Engineering-Electrical and Electronic Engineering
CiteScore
3.50
自引率
7.10%
发文量
194
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