System-level design automation tools for digital microfluidic biochips

Biochips based on digital microfluidics offer a powerful platform for massively parallel biochemical analysis such as clinical diagnosis and DNA sequencing. Current full-custom design techniques for digital microfluidic biochips do not scale well for increasing levels of system integration. Analogous to classical VLSI synthesis, a top-down system-level design automation approach can shorten the biochip design cycle and reduce human effort. We present here an overview of a system-level design methodology that includes architectural synthesis and physical design. The proposed design automation approach is expected to relieve biochip users from the burden of manual optimization of bioassays, time-consuming hardware design, and costly testing and maintenance procedures.

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