Robust optical encoder

The invention claimed is: 1. An optical encoder comprising a movable part bearing a scattering zone and an absorbing zone, a light emitter that is positioned so as to emit light radiation in the direction of the movable part, a sensor that is sensitive to the light emitted by the emitter, the sensor being positioned so as to detect light radiation that is reflected by the scattering zone, the movement of the movable part making it possible to place either the scattering zone or the absorbing zone on an optical path between the emitter and the sensor, an optical waveguide having a first and a second external face, the light emitter being positioned so as to emit the light radiation into the waveguide, the light radiation being able to totally reflect between the first face and the second face, the optical waveguide being positioned between the movable part and the sensor, the movable part being positioned on the side of the first face, the sensor being positioned on the side of the second face, the first face comprising a first altered zone that is configured so that a portion of the light radiation exits the waveguide via the altered zone in the direction of the movable part, the optical waveguide being passed through by the light radiation that is reflected by the scattering zone. 2. The optical encoder according to claim 1 , further comprising an electrical shielding screen that is positioned on the surface of the plate, the electrical shielding screen being transparent to the light radiation. 3. The optical encoder according to claim 1 , further comprising at least one shield making it possible to protect the sensor from stray radiation not originating from the movable part. 4. The optical encoder according to claim 3 , wherein the shield is formed by a mask that is opaque to the light radiation, the mask covering the plate with the exception of a hole made facing the sensor. 5. The optical encoder according to claim 1 , wherein the altered zone comprises means for focusing the light radiation extracted via the face around a direction perpendicular to the plane of the waveguide. 6. The optical encoder according to claim 1 , wherein the altered zone is formed by local geometric splitting of the first face, the local geometric split disrupting the total reflection of the light radiation in the waveguide. 7. The optical encoder according to claim 1 , wherein the first face of the waveguide comprises a second altered zone that is separate from the first altered zone so that a portion of the light radiation exits the waveguide via the second altered zone so as to illuminate a legend that is associated with the movable part. 8. The optical encoder according to claim 7 , wherein the emitter is called the first emitter, the encoder further comprising a second light emitter that is positioned so as to emit light radiation into the waveguide, the first and the second light emitters each emitting in one wavelength band, the two bands being separate, the sensor being configured to detect radiation in the wavelength band of the first emitter, the wavelength band of the second emitter being used to exit the waveguide via the second altered zone. 9. The optical encoder according to claim 1 , further comprising a second sensor, the second sensor being capable of detecting light radiation that is reflected by one of the zones of the movable part, the second sensor being positioned so that when one of the two sensors receives light radiation that is reflected by a scattering zone, the other of the two sensors is facing an absorbing zone and vice versa. 10. The optical encoder according to claim 1 , further comprising a plurality of sensors that are positioned so that all of them are able to receive radiation that is reflected by one and the same scattering zone. 11. The optical encoder according to claim 1 , further comprising a light source that is controlled by a signal issued by the sensor and allowing information to be fedback to the user depending on movements of the movable part. 12. The optical encoder according to claim 11 , wherein the light source allowing the information to be fedback is positioned so as to emit light perpendicularly to the plate while passing therethrough. 13. The optical encoder according to claim 11 , wherein the light source allowing the information to be fedback emits in a wavelength band that is separate from that for which the sensor is configured.