A touch sensitive optical control device comprising a set of light emitters 14, 22 and light detectors 18, 24 arranged relative to a touchable surface 30 such that light transmitted by the emitters is received by the detectors along multiple intersecting beams which pass transversely of the surface
A touch sensitive optical control device comprising a set of light emitters 14, 22 and light detectors 18, 24 arranged relative to a touchable surface 30 such that light transmitted by the emitters is received by the detectors along multiple intersecting beams which pass transversely of the surface and touching the surface at a beam interrupts the light transmitted along the beam. Candidate touch points T1, T2, F1, F2 are defined at the intersections of interrupted beams and are confirmed or not as actual touch points by examining test beams 40, 42, 54, 56 near to or coincident with the candidate touch point.
대표청구항▼
1. A method for determining a touch event on a touch-sensitive optical device comprising a plurality of optical emitters and a plurality of optical detectors, the optical emitters and the optical detectors defining therebetween a plurality of optical beam paths forming an optical beam intersection p
1. A method for determining a touch event on a touch-sensitive optical device comprising a plurality of optical emitters and a plurality of optical detectors, the optical emitters and the optical detectors defining therebetween a plurality of optical beam paths forming an optical beam intersection pattern that extends over an area and is symmetrical about at least one axis of the area, the method comprising the steps of: detecting modulation of energy transmitted along each of a pair of optical beam paths;assigning a candidate touch point at the intersection of said pair of modulated beams;retrieving stored data regarding symmetric beams on a first side of the at least one axis;extrapolating the symmetric beam data to identify predetermined other beams on a symmetrically opposite side of the first axis, wherein the predetermined other beams are identified based on the assigned candidate touch point;analyzing the predetermined other beams; andresponsive to said analysis, determining whether the candidate touch point is an actual touch point. 2. The method of claim 1, wherein assigning is based on a function of the degree of modulation of the predetermined other beams. 3. The method of claim 2, wherein contributions of the predetermined other beams are weighted in said function dependent on the degree of modulation. 4. The method as claimed in claim 3, wherein the weighting for each predetermined other beam depends upon one or more of a proximity of the predetermined other beam to the candidate touch point; an angle of the predetermined other beam to an angle of the modulated beam defining the candidate touch point; and a number of predetermined other beams. 5. The method as claimed in claim 1, wherein analyzing is based on the predetermined other beam intersection points near to or coincident with said candidate touch point. 6. The method as claimed in claim 1, further comprising: designating said modulation as an interruption of the modulated beam if said modulation exceeds a threshold level,and wherein assigning further comprises assigning said candidate touch point responsive to determining that both modulated beams are interrupted. 7. The method as claimed in claim 6, wherein designating comprises: comparing the detected modulation with a predefined modulation level for that touch point region; andretrieving stored data from the database, the stored data including a typical threshold level indicative of a typical modulation level for an actual touch point for that touch point region, wherein said stored data comprises one or more of the following: a number of beams passing through the touch point region; a number of intersections of any beams falling within the touch point region; or a maximum modulation to be expected in the touch point region. 8. The method as claimed in claim 1, comprising the steps of: initializing a point validity value for said candidate touch point;selecting a predetermined other test beam near to or coincident with said candidate touch point;measuring a strength of said predetermined other test beam;calculating an attenuation margin for said predetermined other test beam based on said measured beam strength;multiplying said attenuation margin by a weighting value;adding the weighted attenuation margin to said point validity value;repeating the selecting, measuring, calculating, multiplying, and adding steps for a plurality of predetermined other beams near to or coincident with said candidate touch point;normalizing said point validity value; andresponsive to said point validity value exceeding a threshold value, designating said candidate touch point as an actual touch point. 9. The method as claimed in claim 8, wherein calculating further comprises subtracting a threshold value from said measured beam strength. 10. The method as claimed claim in 8, wherein normalizing further comprises dividing said point validity value by the number of predetermined other beams. 11. A touch-sensitive optical device comprising a plurality of optical emitters and a plurality of optical detectors, the optical emitters and the optical detectors arranged relative to a touchable surface such that energy transmitted by the emitters is received by the detectors along multiple intersecting beams that pass adjacent the surface and that form an optical beam intersection pattern that extends over an area and is symmetrical about at least one axis of the area, and wherein touching the surface at a beam causes a detectable modulation of the energy transmitted along the beam, the device further comprising a processing means operable to perform the following steps: detect modulation of energy transmitted along each of a pair of optical beam paths;assign a candidate touch point at the intersection of said pair of modulated beams;retrieve stored data regarding symmetric beams on a first side of the at least one axis;extrapolate the symmetric beam data to identify predetermined other beams on a symmetrically opposite side of the first axis, wherein the predetermined other beams are identified based on the assigned candidate touch point;analyze the predetermined other beams; andresponsive to said analysis, determine whether the candidate touch point is an actual touch point. 12. The method of claim 11, wherein assigning is based on a function of the degree of modulation of the predetermined other beams. 13. The method of claim 12, wherein contributions of the predetermined other beams are weighted in said function dependent on the degree of modulation. 14. The method as claimed in claim 13, wherein the weighting for each predetermined other beam depends upon one or more of a proximity of the predetermined other beam to the candidate touch point; an angle of the predetermined other beam to an angle of the modulated beam defining the candidate touch point; and a number of predetermined other beams. 15. The method as claimed in claim 11, wherein analyzing is based on the predetermined other beam intersection points near to or coincident with said candidate touch point. 16. The touch-sensitive optical device of claim 11, wherein the emitters are non-uniformly optically coupled to the touchable surface so that emitted beams are received by a maximum number of the detectors. 17. The touch-sensitive optical device of claim 11, wherein the detectors are non-uniformly optically coupled to the touchable surface so that received beams are received from a maximum number of the emitters. 18. The touch-sensitive optical device of claim 11, wherein the emitters and detectors are arranged relative to only two opposing sides of the touchable surface. 19. The touch-sensitive optical device of claim 11, wherein the touchable surface comprises a plurality of mechanical control devices arranged over the beams, wherein the beams pass adjacent to the mechanical control devices, and wherein touching the surface at a beam comprises pressing one or more of the mechanical control devices, causing the detectable modulation of energy transmitted along the beam.
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