A New Fluid-Chip Co-Design for Digital Microfluidic Biochips Considering Cost Drivers and Design Convergence

IEEE Transactions on Multi-Scale Computing Systems Pub Date : 2018-10-05 DOI:10.1109/TMSCS.2018.2874248

Arpan Chakraborty;Piyali Datta;Rajat Kumar Pal

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引用次数: 4

Abstract

The design process for digital microfluidic biochips (DMFBs) is becoming more complex due to the growing need for essential bio-protocols. A number of significant fluid- and chip-level synthesis tools have been offered previously for designing an efficient system. Several important cost drivers like bioassay schedule length, total pin count, congestion-free wiring, total wire length, and total layer count together measure the efficiency of the DMFBs. Besides, existing design gaps among the sub-tasks of the fluid and chip level make the design process expensive delaying the time-to-market and increasing the overall cost. In this context, removal of design cycles among the sub-tasks is a prior need to obtain a low-cost and efficient platform. Hence, this paper aims to propose a fluid-chip co-design methodology in dealing with the consideration of the fluid-chip cost drivers, while reducing the design cycles in between. A simulation study considering a number of benchmarks has been presented to observe the performance.

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考虑成本驱动因素和设计融合的新型数字微流控生物芯片流体芯片联合设计

由于对基本生物协议的需求不断增长，数字微流控生物芯片的设计过程变得越来越复杂。以前已经提供了许多重要的流体和芯片级合成工具来设计高效的系统。几个重要的成本驱动因素，如生物测定计划长度、总引脚数、无拥塞布线、总导线长度和总层数，共同衡量DMFB的效率。此外，流体级和芯片级的子任务之间存在的设计差距使得设计过程昂贵，延迟了上市时间并增加了总体成本。在这种情况下，去除子任务之间的设计周期是获得低成本和高效平台的先决条件。因此，本文旨在提出一种流体芯片协同设计方法，以处理流体芯片成本驱动因素的考虑，同时减少其间的设计周期。为了观察性能，已经提出了一项考虑了许多基准的模拟研究。

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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