Optical-effect touchpad on a steering wheel for finger detection

The invention claimed is: 1. A system for detecting command gestures made by at least one finger (P, F) of a driver of a motor vehicle, the system comprising: at least one interface pad ( 3 ) located in proximity to the rim of the steering wheel ( 8 ), at least one light source ( 4 ) that emits an optical beam (L 1 ) mainly in the infrared band toward the interface pad, an imaging sensor ( 5 ), for capturing at least images steered (L 2 ) by the interface pad away from the driver, wherein the interface pad ( 3 ) comprises a base frame ( 1 ) and a movable plate ( 2 ) that is movable between a rest position (PO) and one or more activation positions (P 1 , P 2 ) obtained by pressing one of the fingers (P, F) on the movable plate ( 2 ), the base frame ( 1 ) and the movable plate ( 2 ) lying generally in a reference plane XY and having a small thickness in the direction Z perpendicular to said reference plane XY, an optical zone of interest seen by the imaging sensor being defined at the interface between the base frame ( 1 ) and the movable plate ( 2 ), wherein charactcrizcd in that the interface pad ( 3 ) comprises an elastic deformable seal ( 6 ; 7 ) interposed between the base frame ( 1 ) and the movable plate ( 2 ), the elastic deformable seal ( 6 ; 7 ) comprising at least one inclined facet ( 13 ; 15 ), so that an optical path (L 1 , L 2 ) passing via the first inclined facet ( 13 ) is proportionally modified by the deformation of the elastic deformable seal ( 6 ; 7 ) under the effect of the movement of the movable plate ( 2 ) and the modification of the optical path (L 1 , L 2 ) is detectable by the imaging sensor ( 5 ), cspccially in its gc mctry, in the optical zone of interest seen by the imaging sensor ( 5 ). 2. The system as claimed in claim 1 , wherein the first inclined facet ( 13 ) is located facing a second inclined facet ( 14 ), which is separated from the first inclined facet ( 13 ) by a wedge-shaped interval ( 60 ) the geometry of which is gradually modified depending on a force exerted on the movable plate ( 2 ). 3. The system as claimed in claim 2 , wherein the wedge-shaped interval ( 60 ) closes when a finger (P) presses on the movable plate ( 2 ) in the direction of the imaging sensor ( 5 ). 4. The system as claimed in claim 3 , wherein the wedge-shaped interval ( 60 ) opens when a finger (F) presses on the movable plate ( 2 ) in the direction of the driver. 5. The system as claimed in claim 3 , wherein the segment of the optical beam (L 1 , L 2 ) that returns to the imaging sensor ( 5 ) comprises a diffraction from the first inclined facet ( 13 ), a reflection from a reflective strip ( 17 ) and a new diffraction on the first inclined facet ( 13 ), then a return to the imaging sensor ( 5 ). 6. The system as claimed in claim 4 , wherein the segment of the optical beam (L 1 ) that does not return to the imaging sensor ( 5 ) passes through the first and second inclined facets ( 13 , 14 ) substantially in a straight line. 7. The system as claimed in claim 1 , wherein the elastic deformable seal ( 7 ) has a trapezoidal general cross section with a first inclined facet ( 15 ) and a second inclined facet ( 16 ) that is inclined opposite the first, the segment of the optical beam (L 1 , L 2 ) that returns to the imaging sensor ( 5 ) comprising a diffraction from the first inclined facet ( 15 ) and a diffraction on the second inclined facet ( 16 ). 8. The system as claimed in claim 1 , wherein bright zones (ZC) and dim zones (ZF) are created as seen by the imaging sensor ( 5 ), the bright zones (ZC) and the dim zones (ZF) being separated by a limit (K), and this limit is moved proportionally to the force exerted on the movable plate ( 2 ). 9. The system as claimed in claim 1 , wherein the movable plate ( 2 ) is transparent at least to infrared light, so as to be able to detect movements of a finger inside the zone covered by the movable plate ( 2 ) through the movable plate ( 2 ). 10. The system as claimed in claim 1 , wherein the light source ( 4 ) emits in the near-infrared band, typically in the wavelength band 850 nm- 940 nm, and does not emit in the visible band. 11. The system as claimed in claim 1 , wherein provision is made for an elastic return of the movable plate ( 2 ) to the rest position. 12. The system of claim 1 , wherein the modification of the optical path (L 1 , L 2 ) is detectable by the imaging sensor ( 5 ), in its geometry, in the optical zone of interest seen by the imaging sensor ( 5 ). 13. The system as claimed in claim 2 , wherein bright zones (ZC) and dim zones (ZF) are created as seen by the imaging sensor ( 5 ), the bright zones (ZC) and the dim zones (ZF) being separated by a limit (K), and this limit is moved proportionally to the force exerted on the movable plate ( 2 ). 14. The system as claimed in claim 3 , wherein bright zones (ZC) and dim zones (ZF) are created as seen by the imaging sensor ( 5 ), the bright zones (ZC) and the dim zones (ZF) being separated by a limit (K), and this limit is moved proportionally to the force exerted on the movable plate ( 2 ). 15. The system as claimed in claim 4 , wherein bright zones (ZC) and dim zones (ZF) are created as seen by the imaging sensor ( 5 ), the bright zones (ZC) and the dim zones (ZF) being separated by a limit (K), and this limit is moved proportionally to the force exerted on the movable plate ( 2 ). 16. The system as claimed in claim 5 , wherein bright zones (ZC) and dim zones (ZF) are created as seen by the imaging sensor ( 5 ), the bright zones (ZC) and the dim zones (ZF) being separated by a limit (K), and this limit is moved proportionally to the force exerted on the movable plate ( 2 ). 17. The system as claimed in claim 6 , wherein bright zones (ZC) and dim zones (ZF) are created as seen by the imaging sensor ( 5 ), the bright zones (ZC) and the dim zones (ZF) being separated by a limit (K), and this limit is moved proportionally to the force exerted on the movable plate ( 2 ). 18. The system as claimed in claim 7 , wherein bright zones (ZC) and dim zones (ZF) are created as seen by the imaging sensor ( 5 ), the bright zones (ZC) and the dim zones (ZF) being separated by a limit (K), and this limit is moved proportionally to the force exerted on the movable plate ( 2 ). 19. The system as claimed in claim 2 , wherein the movable plate ( 2 ) is transparent at least to infrared light, so as to be able to detect movements of a finger inside the zone covered by the movable plate ( 2 ) through the movable plate ( 2 ). 20. The system as claimed in claim 1 , wherein provision is made for an elastic return of the movable plate ( 2 ) to the rest position, said return being achieved via the intrinsic resilience of the elastic deformable seal ( 6 ; 7 ).