Method and apparatus for calibrating an inspection system for moving vehicles

The invention claimed is: 1. A method for calibrating a laser displacement sensor of a vehicle alignment inspection system, the laser displacement sensor consisting of at least one laser emitter configured to illuminate a vehicle surface with a laser beam along a measurement axis, and an associated imaging sensor configured to receive reflected laser light from said vehicle surface on a sensing surface, comprising: positioning a calibration target having first and second planar surfaces within a drive-through vehicle inspection lane at a known distance from said laser displacement sensor, within an operative field of view of said associated imaging sensor; establishing a spatial model from said known distance and said associated imaging sensor configuration, said spatial model identifying a calibration location on a plane of said sensing surface for a dot of laser light from said laser beam reflected off said calibration target first planar surface positioned at said known distance; illuminating a point on said calibration target first planar surface with said laser beam; identifying, on said sensing surface plane, an actual location for said dot of laser light reflected from said calibration target first planar surface; responsive to a displacement between said actual location and said calibration location on said plane of said sensing surface, altering said configuration of said associated imaging sensor to align said reflected laser light dot with said calibration location to within a tolerance. 2. The method of claim 1 wherein said step of altering said configuration of said associated imaging sensor includes adjusting at least one of an orientation of said sensing surface about at least one axis and a location of said sensing surface along at least one axis. 3. The method of claim 1 wherein said step of altering said configuration of said associated imaging sensor includes adjusting at least one of a focal length, focus, or f-stop setting of an optical element of said associated imaging sensor. 4. The method of claim 1 further including the step of moving said calibration target first planar surface orthogonal to said emitted laser beam during said step of identifying, said movement of said calibration target first planar surface consisting of either reciprocating linear motion or rotational motion. 5. The method of claim 1 wherein said sensing surface consists of at least a one-dimensional array of light-sensitive pixels; and wherein identifying said actual location of said dot of laser light on said sensor surface includes calculating, to sub-pixel resolution, a centroid location for said dot of laser light in at least one dimension of said array of light-sensitive pixels. 6. A method for calibrating and utilizing a laser displacement sensor of a vehicle alignment inspection system, the laser displacement sensor consisting of at least one laser emitter configured to illuminate a point on a vehicle surface with a laser beam along a measurement axis, and an associated imaging sensor configured to receive reflected laser light from said point on said vehicle surface within a field of view encompassing a portion of a vehicle inspection lane, comprising: positioning a calibration target having first and second planar surfaces within a drive-through vehicle inspection lane at a first distance from said laser displacement sensor, along said measurement axis of said laser beam and within said operative field of view of said associated imaging sensor; illuminating a point on said calibration target first planar surface with said laser beam; identifying, on a pixel array of said associated imaging sensor, a corresponding location of a dot of said laser light reflected from said calibration target first planar surface; repositioning said calibration target first planar surface to a second distance from said laser displacement sensor along said measurement axis, within said operative field of view of said associated imaging sensor; repeating said step of identifying; and using said first and second distances along said measurement axis, together with said corresponding identified locations on said pixel array, establishing a parametric model for distances associated with laser dot locations on said pixel array of said associated imaging sensor corresponding to laser light reflected from vehicle surfaces at unknown distances along said measurement axis and within said operative field of view of said associated imaging sensor. 7. The method of claim 6 further including the step of measuring a vehicle surface positioned at an unknown distance along said measurement axis from said laser displacement sensor, and within said operative field of view; identifying, on said pixel array of said associated imaging sensor, a current location of a dot of laser light reflected off said vehicle surface; and interpolating a distance from said laser displacement sensor to said vehicle surface along said measurement axis using said identified current location and said established parametric model. 8. The method of claim 6 further including the step of moving said calibration target first planar surface orthogonal to said emitted laser beam during said step of observing, said movement of said target surface consisting of either reciprocating linear motion or rotational motion. 9. A method for calibrating a laser displacement sensor of a drive-through vehicle alignment inspection system, the laser displacement sensor consisting of a plurality of vertically spaced laser emitters each configured to illuminate a surface of a vehicle within an inspection lane with an associated laser beam, and an imaging sensor configured to receive reflected laser light from said vehicle surface, comprising: positioning a calibration target having first and second planar surfaces at a known distance from said laser displacement sensor, within an operative field of view of said imaging sensor, said calibration target surfaces aligned to a reference orientation; identifying locations on said imaging sensor of laser light dots from laser light reflected off said calibration target first planar surface from each of said plurality of vertically spaced laser emitters; selecting one of said vertically spaced laser emitters as a reference, such that an identified location for a laser light dot on said imaging sensor associated with laser light emitted by said reference laser emitter defines a reference displacement to said calibration target first planar surface; and using said reference displacement to said calibration target first planar surface, establishing a reference displacement offset value for each of said remaining vertically spaced laser emitters based on said identified locations of said associated reflected laser light dots on said imaging sensor. 10. The method of claim 9 further including the step of moving said calibration target first planar surface orthogonal to at least one of said associated laser beams during said step of identifying, said movement of said first planar surface consisting of either reciprocating linear motion or rotational motion. 11. The method of claim 9 further including: repositioning said calibration target first planar surface to at least one additional known distance from said laser displacement sensor within an operative field of view of said imaging sensor; identifying corresponding locations for each of said associated reflected laser light dots on said imaging sensor from said laser light reflected off said calibration target first planar surface at said at least one additional known distance; and using said identified corresponding locations, said reference displacement offset value