Efficient One-pass Synthesis for Digital Microfluidic Biochips

ACM Transactions on Design Automation of Electronic Systems (TODAES) Pub Date : 2021-04-22 DOI:10.1145/3446880

N. Mohammadzadeh, R. Wille, Oliver Keszöcze

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Abstract

Digital microfluidics biochips are a promising emerging technology that provides fluidic experimental capabilities on a chip (i.e., following the lab-on-a-chip paradigm). However, the design of such biochips still constitutes a challenging task that is usually tackled by multiple individual design steps, such as binding, scheduling, placement, and routing. Performing these steps consecutively may lead to design gaps and infeasible results. To address these shortcomings, the concept of one-pass design for digital microfluidics biochips has recently been proposed—a holistic approach avoiding the design gaps by considering the whole synthesis process as large. But implementations of this concept available thus far suffer from either high computational effort or costly results. In this article, we present an efficient one-pass solution that is runtime efficient (i.e., rarely needing more than a second to successfully synthesize a design) while, at the same time, producing better results than previously published heuristic approaches. Experimental results confirm the benefits of the proposed solution and allow for realizing really large assays composed of thousands of operations in reasonable runtime.

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数字微流控生物芯片的高效单通合成

数字微流体生物芯片是一种很有前途的新兴技术，它在芯片上提供流体实验能力(即遵循芯片上的实验室范例)。然而，这种生物芯片的设计仍然是一项具有挑战性的任务，通常由多个单独的设计步骤来解决，例如绑定、调度、放置和路由。连续执行这些步骤可能会导致设计空白和不可行的结果。为了解决这些缺点，最近提出了数字微流体生物芯片的单通设计概念——一种通过考虑整个合成过程来避免设计空白的整体方法。但是迄今为止，这个概念的实现要么是计算量大，要么是结果昂贵。在本文中，我们提出了一种高效的一次性解决方案，它运行时效率高(即，很少需要超过一秒钟的时间来成功地合成一个设计)，同时产生比以前发布的启发式方法更好的结果。实验结果证实了所提出的解决方案的好处，并允许在合理的运行时间内实现由数千个操作组成的真正大型的分析。

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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ACM Transactions on Design Automation of Electronic Systems (TODAES)

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