Visual prosthesis

What is claimed is: 1. A pair of glasses comprising: a frame suitable to be supported by a user's ears and nose; a camera supported by the frame; an electronic circuit mounted on the frame receiving data from the camera; a transmitter mounted on the frame receiving data from the electronic circuit; a touch sensor, mounted on the frame, controlling a low power mode and an operating mode of the electronic circuit, wherein the transmitter is turned off when in the low power mode and on when in the operating mode, and the electronic circuit monitors the touch sensor and returns to the operating mode in response to actuation of the touch sensor; and a communications system for communicating with a processor, the processor configured to be external to a body, and not on the frame. 2. The pair of glasses according to claim 1 , wherein the sensor is a capacitive touch sensor. 3. The pair of glasses according to claim 1 , wherein the electronic circuit is in the low power mode when the glasses are not currently being worn by the user. 4. The pair of glasses according to claim 1 , further comprising a camera supplying video data to the electronic circuit. 5. The pair of glasses according to claim 4 , wherein the electronic circuit alters the video data producing altered video data. 6. The pair of glasses according to claim 5 , further comprising a transmitter coil suitable to transmit the altered video data. 7. The pair of glasses according to claim 5 , wherein the altered video data comprises stimulation patterns suitable to drive an implantable stimulation device. 8. The pair of glasses according to claim 1 , wherein the sensor is mounted on the frame toward the user when in use. 9. The pair of glasses according to claim 1 , further including a touch sensor. 10. The pair of glasses according to claim 9 , wherein the touch sensor is a capacitive touch sensor. 11. A visual prosthesis apparatus comprising: glasses, including a camera for capturing a video image, a transmitter, a transmitter coil, and a capacitive touch sensor suitable to detect contact with a face when the frame is supported by the user's ears and nose; a video processing unit associated with the camera, receiving the video image from the camera, the video processing unit configured to convert the video image to stimulation patterns and return those stimulation patterns to the transmitter and transmitter coil via a communications system, the video processing unit configured to be external to a body, and not on the frame; and a retinal stimulation system configured to stimulate neural tissue in a subject's eye based on the stimulation patterns received from a receiver coil in communication with the transmitter coil; a sensor, suitable to detect if the glasses are currently being worn by a user, and mounted on the glasses controlling the video processing unit; wherein the video processing unit enters a low power mode, turns off the transmitter and does not transmit stimulation patterns to the transmitter coil, senses for physical contact with the capacitive touch sensor, and upon contact with the touch sensor, the video processing unit returns to an operating mode, turns on the transmitter, and transmits stimulation patterns to the transmitter coil. 12. The visual prosthesis apparatus according to claim 11 , further comprising: a fitting system connected with the video processing unit, the fitting system adapted to modify parameters in the video processing unit. 13. The visual prosthesis apparatus according to claim 11 , wherein the retinal stimulation system comprises: an electronics package; an inductive coil electrically coupled to the electronics package; an electrode array disposed on the subject's retina; and a cable electrically coupling the electronics package and the electrode array. 14. The visual prosthesis apparatus of claim 13 , wherein the inductive coil comprises a receiver and transmitter antennae made from wound wire. 15. The visual prosthesis apparatus of claim 13 , wherein the electronics package comprises an Application Specific Integrated Circuit (ASIC) for processing the stimulation patterns and generating an output to stimulate the neural tissue in the subject's eye. 16. The visual prosthesis apparatus of claim 13 , further comprising a second inductive coil, wherein the stimulation patterns and power are transmitted to the electronics package by the second inductive coil through the inductive coil of the retinal stimulation system. 17. The visual prosthesis apparatus of claim 11 , further comprising an external inductive coil configured to transmit the stimulation patterns to the retinal stimulation system using radio-frequency (RF). 18. The visual prosthesis apparatus of claim 17 , wherein the external inductive coil comprises a receiver and transmitter antennae and a radio-frequency (RF) electronics card for communicating with the retinal stimulation system. 19. The visual prosthesis apparatus of claim 11 , wherein the retinal stimulation system is configured to transmit telemetry to the video processing unit, the telemetry identifying various operational conditions of the retinal stimulation system. 20. The visual prosthesis apparatus of claim 11 , wherein the video processing unit comprises: filters for processing and reducing resolution of the captured video image; and a mapping function to adjust a stimulation intensity of the stimulation patterns. 21. The visual prosthesis apparatus of claim 11 , wherein the video processing unit comprises: a power button for turning the video processing unit on and off, a settings button for controlling the video processing unit; and zoom buttons for controlling the camera. 22. The visual prosthesis apparatus of claim 21 , wherein at least two of the buttons of the video processing unit are of different shape to help identify a functionality of each button. 23. A pair of glasses comprising: a frame suitable to be supported by a user's ears and nose; a camera mounted on the frame; an electronic circuit mounted on the frame receiving data from the camera; a transmitter on the frame and electrically connected to the electronic circuit and receiving data from the circuit; a dedicated sensor mounted on the frame controlling a low power mode and operating mode of the electronic circuit; wherein the transmitter is turned off when in the low power mode and on in the operating mode, and the electronic circuit monitors the touch sensor and returns to a normal operating mode in response to actuation of the touch sensor; and a communications system for communicating with a processor, the processor configured to be external to a body, and not on the frame.