Method for use with an optical aligner system for positioning a fixture relative to a vehicle
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01B-005/25
G01B-005/24
G01B-011/275
출원번호
US-0785586
(2007-04-18)
등록번호
US-7424387
(2008-09-09)
발명자
/ 주소
Gill,George M.
Jackson,David A.
Glickman,Steve L.
Rigsby,Stephen K.
출원인 / 주소
Snap On Incorporated
대리인 / 주소
McDermott Will & Emery LLP
인용정보
피인용 횟수 :
9인용 특허 :
22
초록▼
A method is provided for positioning a free-standing fixture relative to a vehicle, using a visual aligner system for imaging vehicle-mounted targets with reference image sensors and processing the resultant images. Embodiments include calculating locations of the vehicle-mounted targets, calculatin
A method is provided for positioning a free-standing fixture relative to a vehicle, using a visual aligner system for imaging vehicle-mounted targets with reference image sensors and processing the resultant images. Embodiments include calculating locations of the vehicle-mounted targets, calculating a location of a reference point on the vehicle, and determining a longitudinal line along a longitudinal axis of the vehicle. A location of a center of the fixture and an axis of the fixture is then calculated based on an image of one of the targets obtained by a remote image sensor attached to the fixture. The fixture is positioned by adjusting the fixture relative to the vehicle to achieve a desired position or orientation of the fixture based on the performed comparison steps and angle calculations.
대표청구항▼
What is claimed is: 1. A method of positioning a free-standing fixture relative to a vehicle, using a visual aligner system for imaging vehicle-mounted targets with reference image sensors and processing the resultant images, the method comprising: calculating locations of the vehicle-mounted targe
What is claimed is: 1. A method of positioning a free-standing fixture relative to a vehicle, using a visual aligner system for imaging vehicle-mounted targets with reference image sensors and processing the resultant images, the method comprising: calculating locations of the vehicle-mounted targets based on the images of the targets obtained by the reference image sensors of the visual aligner system; calculating a location of a reference point on the vehicle; attaching a remote image sensor to the fixture at a predetermined mounting point on the fixture; positioning the fixture to allow imaging of one of the targets with the attached remote image sensor; calculating a location of a center of the fixture and an axis of the fixture based on an image of one of the targets obtained by the remote image sensor; determining a longitudinal line along a longitudinal axis of the vehicle using the visual aligner system; performing at least one of the steps of: comparing the intersection of the longitudinal line and the axis of the fixture with the center of the fixture; comparing the location of the center of the fixture and the location of the reference point; comparing the location of the center of the fixture and a reference plane calculated by the visual aligner; and comparing the location of the axis of the fixture and the reference plane; and adjusting the fixture relative to the vehicle to achieve a desired position or orientation of the fixture based on the performed at least one of the comparison steps. 2. The method of claim 1, wherein the respective locations of the targets, the reference point, the center of the fixture and the axis of the fixture are calculated relative to a point of origin of a coordinate system, wherein calculating the location of the center of the fixture and the axis of the fixture comprises: determining a location of the center of the fixture, and a location of an axis of the fixture intersecting the center of the fixture, relative to the remote image sensor; calculating a location of the center of the fixture relative to one of the targets of the visual aligner system based on at least one image of the target obtained by the remote image sensor; calculating the location of the center of the fixture relative to the point of origin based on the calculated location of the center of the fixture relative to the one of the targets; and calculating the location of the axis of the fixture relative to the point of origin based on the location of the axis of the fixture relative to the remote image sensor. 3. The method of claim 1, wherein determining the longitudinal line comprises operating the visual aligner system to calculate a thrust line determined in relation to a pair of wheels of the vehicle. 4. The method of claim 1, wherein comparing the intersection of the longitudinal line and the axis of the fixture with the center of the fixture comprises: calculating the location of the intersection of the longitudinal line and the axis of the fixture; and calculating a differential lateral distance from the intersection of the longitudinal line and the axis of the fixture to the center of the fixture; wherein the adjusting step comprises moving the fixture the differential lateral distance to substantially center the fixture with the longitudinal line. 5. The method of claim 1, wherein comparing the location of the center of the fixture and the location of the reference point comprises: calculating a longitudinal distance from the center of the fixture to the reference point; and calculating a differential longitudinal distance between the longitudinal distance and a predetermined longitudinal distance; wherein the adjusting step comprises moving the fixture the differential longitudinal distance to position the fixture substantially at the predetermined longitudinal distance from the reference point. 6. The method of claim 1, wherein the respective locations of the targets, the reference point, the center of the fixture and the axis of the fixture are calculated relative to a point of origin of a coordinate system. 7. The method of claim 1, wherein comparing the location of the center of the fixture and the reference plane comprises: calculating a vertical distance from the center of the fixture to the reference plane; and calculating a differential vertical distance between the vertical distance and a predetermined vertical distance; wherein the adjusting step comprises moving the fixture the differential vertical distance to position the fixture substantially at the predetermined vertical distance from the reference plane. 8. The method of claim 1, wherein calculating the location of the reference point on the vehicle comprises calculating a location of a center point between a pair of front wheels of the vehicle or a pair of rear wheels of the vehicle. 9. The method of claim 1, wherein the reference point is the center of the vehicle, and comparing the location of the center of the fixture and the location of the reference point comprises: calculating a wheelbase of the vehicle; calculating a longitudinal distance from the center of the fixture to the center of the vehicle; subtracting half the wheelbase from the longitudinal distance; and calculating a differential longitudinal distance between the result of the subtracting step and a predetermined longitudinal distance; the method further comprising moving the fixture the differential longitudinal distance to position the fixture substantially at the predetermined longitudinal distance. 10. The method of claim 1, wherein the fixture comprises a substantially horizontal bar, and the predetermined mounting point for the remote image sensor is disposed at a distal end of the bar. 11. The method of claim 2, wherein determining the location of the axis of the fixture intersecting the center of the fixture relative to the remote image sensor comprises: rotatably mounting the remote image sensor at the predetermining mounting point such that the remote image sensor is rotatable about the axis of the fixture; rotating the remote image sensor to obtain images of one of the optical targets in at least two rotational positions; and processing the images of the target at the at least two rotational positions to determine the location of the axis of the fixture relative to the remote image sensor. 12. The method of claim 2, wherein determining the location of the center of the fixture comprises measuring a distance between a center of the mounted remote image sensor and the center of the fixture. 13. The method of claim 2, wherein determining the location of the axis of the fixture intersecting the center of the fixture relative to the remote image sensor comprises: providing the fixture with first and second predetermined mounting points equidistant from the center of the fixture for rotatably mounting the remote image sensor such that the remote image sensor is rotatable about the axis of the fixture; positioning the fixture to allow imaging of a first one of the targets with the remote image sensor attached to the first predetermined mounting point, and of a second one of the targets with the remote image sensor attached to the second predetermined mounting point; mounting the remote image sensor at the first predetermining mounting point; rotating the remote image sensor to obtain images of the first optical target in at least two rotational positions; mounting the remote image sensor at the second predetermining mounting point; rotating the remote image sensor to obtain images of the second optical target in at least two rotational positions; processing the images of the first target at the at least two rotational positions to determine a first axis of rotation of the fixture relative to the remote image sensor; processing the images of the second target at the at least two rotational positions to determine a second axis of rotation of the fixture relative to the remote image sensor; and combining the first and second axes of rotation of the fixture to determine the location of the axis of the fixture relative to the remote image sensor. 14. The method of claim 13, wherein determining the location of the center of the fixture relative to the remote image sensor comprises processing the images of the first and second targets obtained by the remote image sensor, and the images of the first and second targets obtained by the reference image sensors. 15. The method of claim 2, wherein determining the location of the axis of the fixture intersecting the center of the fixture relative to the remote image sensor comprises: providing the fixture with first and second predetermined mounting points equidistant from the center of the fixture for rotatably mounting first and second remote image sensors such that the remote image sensors are rotatable about the axis of the fixture; positioning the fixture to allow imaging of a first one of the targets with the first remote image sensor attached to the first predetermined mounting point, and of a second one of the targets with the second remote image sensor attached to the second predetermined mounting point; mounting the first remote image sensor at the first predetermining mounting point, and the second remote image sensor at the second predetermining mounting point; rotating the first remote image sensor to obtain images of the first optical target in at least two rotational positions; rotating the second remote image sensor to obtain images of the second optical target in at least two rotational positions; processing the images of the first target at the at least two rotational positions to determine a first axis of rotation of the fixture relative to the first remote image sensor; processing the images of the second target at the at least two rotational positions to determine a second axis of rotation of the fixture relative to the second remote image sensor; and combining the first and second axes of rotation of the fixture to determine the location of the axis of the fixture relative to the remote image sensors. 16. The method of claim 15, wherein determining the location of the center of the fixture relative to the remote image sensor comprises processing the images of the first and second targets obtained by the remote image sensors, and the images of the first and second targets obtained by the reference image sensors. 17. The method of claim 1, wherein comparing the location of the axis of the fixture to the reference plane comprises determining whether the axis of the fixture and the reference plane are parallel; and wherein the adjusting step includes leveling the fixture by adjusting the fixture such that the axis of the fixture and the reference plane are substantially parallel. 18. The method of claim 1, comprising calculating an angle between the longitudinal line and the axis of the fixture, and adjusting the fixture relative to the vehicle to achieve the desired orientation of the fixture based on the result of the angle calculation. 19. The method of claim 18, wherein the adjusting step comprises rotating the fixture substantially about the center of the fixture based on the results of the calculation of the angle, such that the axis of the fixture is substantially perpendicular to the longitudinal axis. 20. The method of claim 1, wherein the reference plane is a plane through points where wheels of the vehicle contact an alignment rack.
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