A method and apparatus for utilizing a machine vision vehicle wheel alignment system to measure an orientation of one or more vehicle supporting surfaces of a vehicle lift system, and to measure and compensate one or more vehicle measurements relative to the vehicle supporting surface of the vehicle
A method and apparatus for utilizing a machine vision vehicle wheel alignment system to measure an orientation of one or more vehicle supporting surfaces of a vehicle lift system, and to measure and compensate one or more vehicle measurements relative to the vehicle supporting surface of the vehicle lift system.
대표청구항▼
The invention claimed is: 1. A method for determining a surface orientation of a runway of a vehicle lift having a pair of runways, using a machine vision vehicle wheel alignment system configured to acquire position and orientation data associated with at least one optical target disposed in a fie
The invention claimed is: 1. A method for determining a surface orientation of a runway of a vehicle lift having a pair of runways, using a machine vision vehicle wheel alignment system configured to acquire position and orientation data associated with at least one optical target disposed in a field of view, comprising: establishing a reference plane for the pair of runways; disposing an optical target in at least one predetermined relationship to an upper surface of the runway of the vehicle lift; acquiring at least one image of said optical target; determining a position and orientation of said optical target from said at least one acquired image; utilizing said established reference plane, said at least one predetermined relationship, and said determined position and orientation of said optical target, to identify an initial orientation of said upper surface of the runway relative to said established reference plane; and wherein said initial orientation is a measurement of a deformation of said upper surface of the runway at the location of said optical target by twisting or flexing relative to said established reference plane. 2. The method of claim 1 further including: altering an elevation of said runway; repeating the steps of disposing, acquiring, and determining; and utilizing said established reference plane, said at least one predetermined relationship, and said determined position and orientation to identify a current orientation of said upper surface of the runway at said altered elevation, said current orientation representing a measurement of a deformation of said upper surface of the runway at the location of said optical target by twisting or flexing relative to said established reference plane. 3. The method of claim 2 further including the step of comparing said current orientation of said upper surface of the runway with said initial orientation to identify a change in orientation of said upper surface of the runway, said change in orientation representing a measurement of a deformation of said upper surface of the runway by twisting or flexing. 4. The method of claim 3 further including the step of providing a visual representation of said identified change in orientation. 5. The method of claim 3 further including the step of altering an orientation of said upper surface of the runway responsive to said identified change in orientation. 6. The method of claim 1 further including the step of supporting at least one wheel of a vehicle on said portion of said upper surface of the runway; repeating the steps of disposing, acquiring, determining; and utilizing said established reference plane, said at least one predetermined relationship, and said determined position and orientation to identify a current orientation of said portion of the upper surface of the runway supporting said vehicle, said current orientation representing a measurement of a deformation of said upper surface of the runway at the location of said optical target by twisting or flexing relative to said established reference plane. 7. The method of claim 6 wherein said step of disposing further includes disposing said optical target in at least one predetermined relationship to said portion of the upper surface of the runway, adjacent said at least one wheel of said vehicle. 8. The method of claim 6 further including the step of comparing said current orientation of said portion of said upper surface of the runway with said initial orientation to identify a change in orientation of said upper surface of the runway. 9. The method of claim 8 further including the steps of measuring an alignment angle for said at least one wheel of said vehicle supported on said upper surface of said runway; identifying a lateral position of said at least one wheel of said vehicle on said upper surface of the runway; and compensating said measured alignment angle for angular changes related to said change in orientation of said upper surface of the runway at said lateral position of said at least one wheel. 10. The method of claim 1 further including the step of adjusting said runway to alter said identified initial orientation of said upper surface of the runway. 11. The method of claim 1 further including the steps of measuring an alignment angle for at least one wheel of a vehicle supported on said upper surface of the runway; and compensating said measured alignment angle for an angular effect resulting from said initial orientation of said upper surface of the runway. 12. The method of claim 11 further including the steps of identifying a lateral position of said at least one wheel of said vehicle on said upper surface of the runway; and wherein said compensating step further includes compensating said measured alignment angle for said angular effect resulting from an orientation of said upper surface of said runway at said lateral position of said at least one wheel. 13. The method of claim 1 further including the steps of identifying a lateral position of at least one wheel of a vehicle supported on said upper surface of the runway; measuring an alignment angle for said at least one wheel; and compensating said measured alignment angle for an angular effect resulting from an orientation of said upper surface of said runway at said lateral position of said at least one wheel on said upper surface of the runway. 14. The method of claim 1 further including the steps of disposing said optical target in at least a second predetermined relationship to said upper surface of said runway of the vehicle lift at a position longitudinally spaced from that of said first predetermined relationship; determining a second position and orientation of at least one optical target disposed in said second predetermined relationship to the runway; utilizing said established reference plane, each of said predetermined relationships, and each of said first and second determined positions and orientations to identify a surface orientation of said upper surface of said runway relative to said established reference plane; and wherein said surface orientation is a measurement of a deformation of said upper surface of the runway between said first and second predetermined relationships of the optical target by twisting or flexing relative to said established reference plane. 15. The method of claim 14, further including the steps of determining at least first and second positions and orientations of at least one optical target disposed in first and second predetermined relationships to a second runway, at longitudinally spaced positions; and utilizing said established reference plane, each of said predetermined relationships, and each of said determined positions and orientations to identify a surface orientation of said upper surface of said second runway relative to said established reference plane; and wherein said surface orientation is a measurement of a deformation of said upper surface of the second runway between said first and second predetermined relationships of the optical target to the second runway by twisting or flexing relative to said established reference plane. 16. A method for determining a surface orientation of a runway of a vehicle lift having a pair of runways, using a vehicle wheel alignment system configured to acquire orientation data associated with at least one sensor means, comprising: establishing a reference plane for the pair of runways; disposing a sensor means in a support fixture, the support fixture configured to position and orient said sensor to a predetermined relationship relative to an upper surface of a runway of the vehicle lift; determining a position and orientation of said sensor means relative to said established reference plane; utilizing said established reference plane, said at least one predetermined relationship, and said determined position and orientation, to identify an initial orientation of said upper surface of the runway relative to said established reference plane; and wherein said initial orientation is a measurement of a deformation of said upper surface of the runway at the location of said support fixture by twisting or flexing relative to said established reference plane. 17. A machine vision vehicle wheel alignment system having an optical imaging system configured to acquire at least one image of an optical target disposed within a field of view, and a central processing unit configured to determining a surface orientation of at least one runway of an associated vehicle lift having a pair of runways, comprising: a support fixture configured for placement of an optical target in a predetermined relationship relative to an upper surface of the runway; wherein the central processing unit is configured to establish a reference plane for the pair of runways; wherein the central processing unit is configured to determine an orientation and position of an optical target supported by said support fixture from at least one image of said optical target acquired by said optical imaging system; and wherein the central processing unit is further configured to utilize said established reference plane, said predetermined relationship, and said determined orientation and position of said optical target, to identify a surface orientation of at least a portion of said upper surface of the runway relative to said established reference plane, said surface orientation representing a measurement of a deformation of said upper surface of the runway by twisting or flexing at a location of said support fixture and said optical target.
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