Hardware Reference
In-Depth Information
7. O. Levenspiel, “Chemical reaction engineering”,
New York: Wiley
, 1999.
8. M. Iyengar and M. McGuire, “Imprecise and qualitative probability in systems biology”,
International Conference on Systems Biology
, Long Beach, California, 2007.
9. J. Gong,
Portable Digital Microfluidic System: Direct Referencing EWOD Devices and
Operating Control Board
, PhD thesis, UCLA, 2007.
10. M. Schertzer, R. Ben-Mrad, and P. Sullivan, “Using capacitance measurements in EWOD
devices to identify fluid composition and control droplet mixing”,
Sensors and Actuators B:
Chemical
, volume 145, pp. 340-347, 2010.
11. Y. Luo, K. Chakrabarty, and T.-Y. Ho, “A cyberphysical synthesis approach for error recovery
in digital microfluidic biochips”,
Proc. DATE
, pp. 1239-1244, 2012.
12. M. Alistar, P. Pop, and J. Madsen, “Online synthesis for error recovery in digital microfluidic
biochips with operation variability”,
Symposium on Design, Test, Integration and Packaging of
MEMS/MOEMS
, pp. 53-58, 2012.
13. D. Grissom and P. Brisk, “Fast online synthesis of generally programmable digital microfluidic
biochips”,
Proc. CODES+ISSS
, pp. 413-422, 2012.
14. J. Gong and C.-J. Kim, “Direct-referencing two-dimensional-array digital microfluidics using
multi-layer printed circuit board”,
J Microelectromech Syst.
, vol. 17, Issue 2, pp. 257 U-264,
2008.
15. Q. Al-Gayem, H. Liu, A. Richardson, N. Burd, and M. Kumar, “An on-line monitoring
technique for electrode degradation in bio-fluidic microsystems”,
IEEE International Test
Conference
, pp. 654-663, 2010.
16. L. Huang, B. Koo, and C. J. Kim, “Evaluation of anodic Ta
2
O
5
as the dielectric layer for
EWOD devices”,
IEEE MEMS
, pp. 428-431, 2012.
17. K. Bohringer, “Modeling and controlling parallel tasks in droplet-based microfluidic systems”,
IEEE Transactions on Computer-Aided Design of Integrated Circuits & Systems
,vol.2,
pp. 329-339, 2006.
18. P.-H. Yuh, C.-L. Yang, and Y.-W. Chang, “BioRoute: a network-flow based routing algorithm
for digital microfluidic biochips”,
Proc. IEEE/ACM International Conference on Computer-
Aided Design
, pp. 752-757, 2007.
19. M. Cho and D. Pan, “A high-performance droplet-routing algorithm for digital microfluidic
biochips”,
IEEE Transactions on Computer-Aided Design of Integrated Circuits & Systems
,
vol. 27, pp. 1714-1724, 2008.
20. T.-W. Huang and T.-Y. Ho, “A fast routability- and performance-driven droplet-routing
algorithm for digital microfluidic biochips”,
Proc. International Conference on Computer
Design
, pp. 445-450, 2009.
21. Y. Luo, K. Chakrabarty, and T.-Y. Ho, “Dictionary-based error recovery in cyberphysical
digital-microfluidic biochips”,
Proc. IEEE/ACM International Conference on Computer-Aided
Design
, pp. 369-376, 2012.
22. Y. Luo, K. Chakrabarty, and T.-Y. Ho, “A cyberphysical synthesis approach for error recovery
in digital microfluidic biochips”,
IEEE/ACM Design, Automation and Test in Europe Confer-
ence
, pp. 1239-1244, 2012.
23. V. Kumar and N. Sharma, “SU-8 as hydrophobic and dielectric thin film in electrowetting-on-
dielectric based microfluidics device”,
Journal of Nanotechnology
, pp. 1-6, 2012.
24. F. Su and K. Chakrabarty, “Unified high-level synthesis and module-placement for
defect-tolerant microfluidic biochips”,
Proc. IEEE/ACM Design Automation Conference
,
pp. 825-830, 2005.
