Biomedical Engineering Reference
In-Depth Information
Acknowledgements. Monash Vision Group is funded through the Australian Research
Council Research in Bionic Vision Science and Technology Initiative (SR1000006).
The authors would like to thank the members of Monash Vision Group that participated
in the trials and all those that shared their valuable opinions and advice. Thanks to Dr.
Nicholas Price, for help with designing the Ball Interception Test. Finally, thanks to
Grey Innovation for help with the physical layout of the integrated simulator system.
References
1. Bak, M., Girvin, J.P., Hambrecht, F.T., Kufts, C.V., Loeb, G.E., Schmidt, E.M.: Visual Sen-
sations Produced by Intracortical Microstimulation of the Human Occipital Cortex. Medical
& Biological Engineering & Computing 28, 257-259 (1990)
2. Balasubramanian, M., Polimeni, J.R., Schwartz, E.L.: The V1-V2-V3 complex: quasi-
conformal dipole maps in primate striate and extra-striate cortex. Neural Networks 15,
1157-1163 (2002)
3. Bear, M.F., Connors, B.W., Paradiso, M.A.: Neuroscience: Exploring the Brain. Lippincott
Williams & Wilkins, Baltimore (2007)
4. Brindley, G.S., Lewin, W.S.: The Visual Sensations Produced by Electrical Stimulation of
the Visual Cortex. J. Physiology 196, 479-493 (1968)
5. Canny, J.: A Computational Approach to Edge Detection. IEEE Transactions on Pattern
Analysis and Machine Intelligence 8, 679-698 (1986)
6. Chen, S.C., Hallum, L.E., Lovell, N.H., Suaning, G.J.: Visual Acuity Measurement of Pros-
thetic Vision: A Virtual-Reality Stimulation Study. J. Neural Engineering 2, S135-S145
(2005)
7. Chen, S.C., Suaning, G.J., Morley, J.W., Lovell, N.H.: Simulating Prosthetic Vision: I. Visual
Models of Phosphenes. Vision Research 49, 1493-1506 (2009)
8. Dobelle, W.H., Mladejovsky, M.G.: Phosphenes produced by Electrical Stimulation of Hu-
man Occipital Cortex, and their Application to the Development of a Prosthesis for the Blind.
J. Physiology 243, 553-576 (1974)
9. Dobelle, W.H., Mladejovsky, M.G., Evans, J.R., Roberts, T.S., Girvin, J.P.: 'Braille' Reading
by a Blind Volunteer by Visual Cortex Stimulation. Nature 259, 111-112 (1976)
10. Dowling, J.A., Maeder, A.J., Boles, W.: Mobility Enhancement and Assessment for a Vi-
sual Prosthesis. In: Proceedings of SPIE Medical Imaging 2004: Physiology, Function and
Structure from Medical Images, vol. 5369, pp. 780-791 (2004)
11. Duncan, R.O., Boynton, G.M.: Cortical Magnification within Human Primary Visual Cortex
Correlates with Acuity Thresholds. Neuron. 38, 659-671 (2003)
12. Fehervari, T., Matsuoka, M., Okuno, H., Yagi, T.: Real-Time Simulation of Phosphene Im-
ages Evoked by Electrical Stimulation of the Visual Cortex. In: Wong, K.W., Mendis, B.S.U.,
Bouzerdoum, A. (eds.) ICONIP 2010, Part I. LNCS, vol. 6443, pp. 171-178. Springer,
Heidelberg (2010)
13. Horton, J.C., Hoyt, W.F.: The Representation of the Visual Field in Human Striate Cortex: A
Revision of the Classic Holmes Map. Archives of Opthalmology 109, 816-824 (1991)
14. Humayun, M.S., De Juan, E., Dagnelie, G., Greenberg, R.J., Propst, R.H., Phillips, D.H.:
Visual Perception Elicited by Electrical Stimulation of the Retina in Blind Humans. Archives
of Opthalmology 114, 40-46 (1996)
15. Lee, J.S.J., Haralick, R.M., Shapiro, L.G.: Morphologic Edge Detection. J. Robotics and
Automation 3, 142-156 (1987)
16. Monash Vision Group, http://www.monash.edu.au/bioniceye
 
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