Biomedical Engineering Reference
In-Depth Information
50. Xu, T. and K. Chakrabarty, Integrated droplet routing and defect tolerance in the
synthesis of digital microfluidic biochips,
ACM Journal on Emerging Technologies
in Computing Systems
, vol. 4, no. 3, article 11, 2008.
51. Xu, T., K. Chakrabarty, and F. Su, Defect-aware synthesis of droplet-based
microfluidic biochips,
Proceeding of IEEE International Conference on VLSI Design
,
pp. 647-652, 2007.
52. Su, F. and K. Chakrabarty, Module placement for fault-tolerant microfluidics-
based biochips,
ACM Transactions on Design Automation of Electronic Systems
,
vol. 11, pp. 682-710, 2006.
53. Xu, T. and K. Chakrabarty, Parallel scan-like test and multiple-defect diagnosis
for digital microfluidic biochips,
IEEE Transactions on Biomedical Circuits and
Systems
, vol. 1, pp. 148-158, June 2007.
54. Xu, T. and K. Chakrabarty, Integrated droplet routing and defect tolerance in the
synthesis of digital microfluidic biochips,
ACM Journal on Emerging Technologies
in Computing Systems
, vol. 4, no. 3, article 11, August 2008.
55. Xu, T., W. Hwang, F. Su, and K. Chakrabarty, Automated design of pin-constrained
digital microfluidic biochips under droplet-interference constraints,
ACM Journal
on Emerging Technologies in Computing Systems
, vol. 3, article 14, 2007.
56. Diestel, R.,
Graph Theory
, Berlin: Springer, 2005.
57. Papadimitriou, C. H.,
Computational Complexity
, Reading, MA: Addison Wesley,
1993.
58. Breuer, M. A., A class of min-cut placement algorithms,
Proceeding of IEEE/ACM
Design Automation
Conference,
pp. 284-290, 1977.
59. Dunlop, A. and B. Kernighan, A procedure for placement of standard cell VLSI
circuits,
IEEE Transactions on Computer-Aided Design of Integrated Circuits and
Systems
, vol. 1, pp. 92-98, 1985.
60. Kahng, A. B., I. I. Mandoiu, S. Reda, X. Xu, and A. Zeilikoysky, Evaluation of
placement techniques for DNA probe array layout,
Proceeding of IEEE/ACM
International Conference on Computer-Aided Design
, pp. 262-269, 2003.
61. Connect5 strategies,
www.springfrog.com/games/gomoku
.
62. Xu, T. and K. Chakrabarty, A droplet-manipulation method for achieving high-
throughput in cross-referencing-based digital microfluidic biochips,
IEEE
Transactions on Computer-Aided Design of Integrated Circuits and Systems
, vol. 27,
pp. 1905-1917, 2008.
63. Griffith, E. J., S. Akella, and M. K. Goldberg, Performance characterization of a
reconfigurable planar-array digital microfluidic system,
IEEE Transactions on
Computer-Aided Design of Integrated Circuits and Systems
, vol. 25, pp. 340-352, 2006.
64. Xu, T. and K. Chakrabarty, Broadcast electrode-addressing for pin-constrained
multi-functional digital microfluidic biochips,
Proceeding of IEEE/ACM Design
Automation Conference
, pp. 173-178, 2008.
65. Xu, T. and K. Chakrabarty, Parallel scan-like test and multiple-defect diagno-
sis for digital microfluidic biochips,
IEEE Transactions on Biomedical Circuits and
Systems
, vol. 1, pp. 148-158, 2007.
66. Xu, T. and K. Chakrabarty, Functional testing of digital microfluidic biochips,
Proceeding of IEEE International Test Conference
, 2007.
67. Pollack, M. G., Electrowetting-Based Microactuation of Droplets for Digital
Microfluidics, Ph.D thesis, Duke University, Durham, NC, 2001.
68. SiliconBiosystems,
http://www.siliconbiosystems.com/applications/webwork/
