Biomedical Engineering Reference
In-Depth Information
65. 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, 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. (for general
reference; not cited in text.)
68. SiliconBiosystems,
http://www.siliconbiosystems.com/applications/webwork/
69. Xu, T., K. Chakrabarty, and V. K. Pamula, Design and optimization of a digital
microfluidic biochip for protein crystallization,
Proceeding of IEEE/ACM Inter-
national Conference on Computer-Aided Design
, 2008.
70. Xu, T., V. K. Pamula, and K. Chakrabarty, Automated, accurate and inexpen-
sive solution-preparation on a digital microfluidic biochip,
Proceeding of IEEE
International Conference on Biomedical Circuits and Systems
, 2008.
71. Moreno, A., E. Saridakis, and N. E. Chayen, Combination of oils and gels for
enhancing the growth of protein crystals,
Journal of Applied Crystallography
,
vol. 35, pp. 140-142, 2002.
72.
http://www.pcbdesign.org/pcb-layout/understanding-pcb-layers
.
73. Bach, E. and J. Shallit,
Algorithmic Number Theory: Efficient Algorithms,
Cambridge,
MA: MIT Press, 1996.
74. Scheid, F. J.,
Schaum's Outline of Theory and Problems of Numerical Analysis,
New York: McGraw-Hill, 1968.