Unified high-level synthesis and module placement for defect-tolerant microfluidic biochips

Author

Su, Fei ; Chakrabarty, Krishnendu

Author_Institution

Dept. of Electr. & Comput. Eng., Duke Univ., Durham, NC, USA

fYear

2005

fDate

13-17 June 2005

Firstpage

825

Lastpage

830

Abstract

Microfluidic biochips promise to revolutionize biosensing and clinical diagnostics. As more bioassays are executed concurrently on a biochip, system integration and design complexity are expected to increase dramatically. This problem is also identified by the 2003 ITRS document as a major system-level design challenge beyond 2009. We focus here on the automated design of droplet-based microfluidic biochips. We present a synthesis methodology that unifies operation scheduling, resource binding, and module placement for such "digital" biochips. The proposed technique, which is based on parallel recombinative simulated annealing, can also be used after fabrication to bypass defective cells in the microfluidic array. A real-life protein assay is used to evaluate the synthesis methodology.

Keywords

biosensors; high level synthesis; microfluidics; microsensors; biosensing; clinical diagnostics; defect-tolerant microfluidic biochips; digital biochips; droplet-based microfluidic biochips; microfluidic array; module placement; operation scheduling; parallel recombinative simulated annealing; real-life protein assay; resource binding; unified high-level synthesis; Biosensors; Circuit testing; Design automation; High level synthesis; Integrated circuit reliability; Integrated circuit synthesis; Integrated circuit yield; Microfluidics; Permission; System-level design;

fLanguage

English

Publisher

ieee

Conference_Titel

Design Automation Conference, 2005. Proceedings. 42nd

Print_ISBN

1-59593-058-2

Type

conf

DOI

10.1109/DAC.2005.193929

Filename

1510449