Biomedical Engineering Reference
In-Depth Information
wiring requirements and uses only six interface wires for power and control.
Furthermore, the prosthesis does not require direct addressing of any probe for
active stimulation. Rather, a sequential stimulation by the clock timing eliminates
need for wireless address transmission overhead. The system is also capable of
stimulating the retina by programming large variety of experimental waveforms.
References
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M. S. Humayun, E. DeJuan, J. D. Weiland, and R. Greenberg, “A Neuro-stimulus
Chip with Telemetry Unit for Retinal Prosthetic Device,” IEEE Journal of Solid-State
Circuits, vol. 35, no. 10, Oct 2000, pp. 1487-1497.
2. E. Zrenner, K. D. Miliczek, V. P. Gabel, H. G. Graf, E. Guenther, H. Haemmerle,
B. Hoefflinger, K. Kohler, W. Nisch, M. Schubert, A. Stett, and S. Weiss,
“The development of sub-retinal microphotodiodes for replacement of degenerated
photoreceptors.” Opthalmic Research, 1997, 29, 269-280.
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“Subretinal semiconductor microphotodiode array,” Ophthalmic Surg. Lasers,
vol. 29, pp. 234-241, 1998.
4. H.K. Trieu, L. Ewe, W. Mokwa, M. Schwarz, and B. J. Hostica, “Flexible Silicon
Structures For A Retina Implant”,
IEEE Transaction, 1998
, vol. 10, pp. 515-519 VI.
5. Y. Yao, M. N. Gulari, J. F. Hetke, and K. D. Wise, “A self-testing multiplexed
CMOS stimulating probe for a 1024-site neural prosthesis”, The 12th International
Conference on Solid State Sensors, Actuators and Microsystems, Boston, June 8-12,
2003, Transducer '03, pp. 1213-1216.
6. Shuenn-Yuh Lee, Shyh-Chyang Lee, and Jia-Jin Jason Chen, “VLSI Implemen-
tation of Implantable Wireless Power and Data Transmission Micro-Stimulator for
Neuromuscular Stimulation”, IEICE Transactions on Electronics, vol. E87-C, no.6,
June 2004, pp. 1062-1067.
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