流动型微流控大规模集成生物芯片的控制合成

W. H. Minhass, P. Pop, J. Madsen, Tsung-Yi Ho
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引用次数: 55

摘要

在本文中,我们感兴趣的是基于流动的微流控生物芯片,它能够在芯片上集成生化分析所需的功能。在这些芯片中,液体的流动是由集成的微阀控制的。通过组合几个微阀,更复杂的单位,如微泵,混合器和多路复用器,可以建立。在本文中,我们首次提出了基于流的生物芯片的自上而下的控制合成框架。从给定的生化应用和生物芯片架构出发,我们综合了生物芯片控制器用于自动执行生化应用的控制逻辑。我们还提出了一种控制引脚数最小化方案,旨在有效利用芯片面积,减少芯片周围的宏组装,提高芯片的可扩展性。我们使用实际应用程序和合成基准测试对我们的方法进行了评估。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Control synthesis for the flow-based microfluidic large-scale integration biochips
In this paper we are interested in flow-based microfluidic biochips, which are able to integrate the necessary functions for biochemical analysis on-chip. In these chips, the flow of liquid is manipulated using integrated microvalves. By combining several microvalves, more complex units, such as micropumps, mixers, and multiplexers, can be built. In this paper we propose, for the first time to our knowledge, a top-down control synthesis framework for the flow-based biochips. Starting from a given biochemical application and a biochip architecture, we synthesize the control logic that is used by the biochip controller to automatically execute the biochemical application. We also propose a control pin count minimization scheme aimed at efficiently utilizing chip area, reducing macro-assembly around the chip and enhancing chip scalability. We have evaluated our approach using both real-life applications and synthetic benchmarks.
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