System and related method for determining vehicle wheel alignment
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01B-011/26
H04N-005/232
G01B-011/275
출원번호
US-0696069
(2011-05-05)
등록번호
US-9300864
(2016-03-29)
우선권정보
IT-TO2010A0377 (2010-05-05)
국제출원번호
PCT/IB2011/000955
(2011-05-05)
§371/§102 date
20121231
(20121231)
국제공개번호
WO2011/138662
(2011-11-10)
발명자
/ 주소
Cerruti, Piero
Manganelli, Fausto
출원인 / 주소
SPACE S.R.L. CON UNICO SOCIO
대리인 / 주소
The Belles Group, P.C.
인용정보
피인용 횟수 :
11인용 특허 :
33
초록▼
A system for determining the orientation of at least one first wheel of a vehicle and provided with: at least one first target integrally coupled to the first wheel, an image-capturing device that acquires a first two-dimensional image of the first target and a processing device, operatively connect
A system for determining the orientation of at least one first wheel of a vehicle and provided with: at least one first target integrally coupled to the first wheel, an image-capturing device that acquires a first two-dimensional image of the first target and a processing device, operatively connected to the image-capturing device and processing the first two-dimensional image. The first target has a three-dimensional shape suitable for defining geometric quantities arranged according to a known three-dimensional arrangement; the processing device processes the first two-dimensional image to identify the projections of the geometric quantities and determine a spatial arrangement of the first target with respect to a reference system based on the geometrical characteristics of the projections, to determine the orientation characteristics of the first wheel.
대표청구항▼
1. A system for determining an orientation of at least one first wheel of a vehicle, comprising: at least one first target configured to be integrally coupled to said first wheel;image capturing means configured so as to acquire a first two-dimensional image of said first target; anda processing dev
1. A system for determining an orientation of at least one first wheel of a vehicle, comprising: at least one first target configured to be integrally coupled to said first wheel;image capturing means configured so as to acquire a first two-dimensional image of said first target; anda processing device, operatively coupled to said image capturing means and configured to process said first two-dimensional image,wherein said first target comprises a plurality of target elements having a three-dimensional shape, reciprocally arranged according to a pre-determined three-dimensional geometric configuration, wherein said three-dimensional geometric configuration is designed to define a set of three orthogonal target vectors (vxtrg, vytrg, vztrg) defining a target reference system (SdRtrg), the spatial orientation of which corresponds to the orientation of said wheel;said processing device being configured to process said first two-dimensional image according to said three-dimensional geometric configuration, to identify therein positions of said target elements and projection vectors (vxtrg_prj, vytrg_prj, VZtrg_prj) of said target vectors (vxtrg, vytrg, vztrg), and to determine a spatial arrangement of said target vectors (vxtrg, vytrg, vztrg) with respect to a reference system based on geometrical characteristics of said projection vectors, thereby determining orientation characteristics of said first wheel;wherein said processing device is configured to determine linear measurements of said projection vectors (vxtrg_prj, vytrg_prj, vztrg_prj) in said first two-dimensional image, and to determine spatial rotation angles of said set of three orthogonal target vectors (vxtrg, vytrg, vztrg) with respect to said reference system as a function of said linear measurements and of corresponding actual known measurements of said target vectors (vxtrg, vytrg, vytrg). 2. The system according to claim 1, wherein said target elements have a three-dimensional shape with isotropic characteristics with respect to variations of an observation angle of said first target by said image capturing means. 3. The system according to claim 1, wherein said target elements have a spherical shape; and said processing device is configured to determine positions of the sphere centres of said target elements within said first two-dimensional image and to determine at least one of said projection vectors (vxtrg, vytrg, vztrg) of said target vectors (vxtrg, vytrg, vztrg) as the vector joining the sphere centres of a significant pair of said target elements. 4. The system according to claim 3, wherein said first target further comprises at least one reference element having a predetermined arrangement with respect to said significant pair of said target elements; and wherein said processing device is configured to identify said significant pair of said target elements based on the identification of a position of said reference element. 5. The system according to claim 3, wherein said target elements are arranged to form a first and a second ring, arranged on distinct planes and defining a first and a second centre (Of, O2); and wherein said processing device is configured to define an orthogonal projection vector (vztrg_prj) among said projection vectors (vxtrg_prj, vytrg_prj, vztrg_prj) as the vector joining said first and second centres (Of, O2). 6. The system according to claim 5, wherein said first and second rings are substantially circular; and wherein said processing device is configured to define a first and a second transversal projection vector (vxtrg-prj, vytrg_prj) among said projection vectors (vxtrg_prj, vytrg_prj, vztrg_prj) as the vectors joining the geometrical centres of a respective pair of target elements forming one ring of said first and second rings. 7. The system according to claim 1, wherein said first target further comprises a support structure internally defining a concave spherical surface; and wherein said target elements are mechanically coupled to said support structure and arranged on said spherical surface, so as to form said three-dimensional configuration. 8. The system according to claim 7, wherein at least some of said target elements are arranged along at least a first and respectively a second meridian (m1, m2) defined by said spherical surface of said support structure. 9. The system according to claim 7 wherein said support structure substantially has a concave spherical cap shape, and said target elements are arranged along six meridians defined by said spherical surface, angularly equispaced from one another. 10. The system according to claim 7, wherein said target elements are arranged on at least two mutually parallel sections of a spherical segment subtended by said support structure. 11. The system according to claim 1, wherein said target elements are of the active type and emit visible or infrared radiation. 12. The system according to claim 1, further comprising: at least one second target integrally coupled to a second wheel of said vehicle; andwherein said image capturing means are configured to acquire a second two-dimensional image of said second target, and said processing device is configured to process said second two-dimensional image to determine orientation characteristics of said second wheel, and to jointly process said orientation characteristics of said first and second wheels in order to determine the alignment characteristics of said vehicle. 13. The system according to claim 1, wherein said second wheel is arranged in a position diametrically opposite to said first wheel with respect to a longitudinal axis of said vehicle; and wherein said image capturing means comprise a first image-capturing device configured to acquire said first two-dimensional image of said first target, and a second image-capturing device configured to acquire said second two-dimensional image of said second target; said system further comprising determination means for determining the reciprocal orientation of said first and second image-capturing device, operatively coupled to said processing device for determining the alignment characteristics of said vehicle. 14. A method for determining an orientation of at least one first wheel of a vehicle, comprising: capturing a first two-dimensional image of at least one first target integrally coupled to said first wheel; andprocessing said first two-dimensional image,wherein said first target comprises a plurality of target elements having a three-dimensional shape, reciprocally arranged according to a pre-determined three-dimensional geometric configuration, said three-dimensional geometric configuration being designed to define a set of three orthogonal target vectors (vxtrg, vytrg, vztrg) defining a target reference system (SdRtrg), the spatial orientation of which corresponds to the orientation of said wheel; andin that said processing step comprises: processing said first two-dimensional image according to said three-dimensional geometric configuration,identifying positions of target elements and projections of said target vectors (vxtrg, vytrg, vztrg) in said first two-dimensional image; anddetermining a spatial arrangement of said target vectors (vxtrg, vytrg, vztrg) with respect to a reference system based on the geometrical characteristics of said projection vectors, thereby determining the orientation characteristics of said first wheel;wherein said step of determining a spatial arrangement comprises determining linear measurements of said projection vectors (vxtrg_prj, vytrg_prj, vztrg_prj) in said first two-dimensional image and determining spatial rotation angles of said set of three orthogonal target vectors (vxtrg, vytrg, vztrg) with respect to said reference system based on said linear measurement and corresponding actual known measurements of said target vectors (vxtrg, vytrg, vztrg). 15. The method according to claim 14, further comprising the steps of: capturing a second two-dimensional image of at least one second target integrally coupled to a second wheel of said vehicle;processing said second two-dimensional image to detect orientation characteristics of said second wheel; andjointly processing said orientation characteristics of said first and second wheels to determine alignment characteristics of said vehicle. 16. A computer program product comprising code portions stored on a computer readable medium, configured to implement, when executed by said computer, the steps of the method according to claim 14.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (33)
Jackson, David A.; Schmeisser, Gordon F., 3D machine vision measuring system with vehicle position adjustment mechanism for positioning vehicle.
Hoenke, Mark S.; Hulbert, Jack A.; Lehman, James R.; Menkveld, Todd K.; Momber, Gregory J.; Smith, Thomas D., Apparatus and method for determining the orientation of an object such as vehicle wheel alignment.
Muhle, Daniel; Svensson, Anke; Roland, Matthias; Wendt, Axel, Measuring head for a chassis measuring system, chassis measuring system and method for determining the position parameters of measuring heads of a chassis measuring system.
Stieff,Michael T.; Meyer,Gregory F.; Golab,Thomas J.; Dorrance,Daniel R.; Shylanski,Mark S., Method and apparatus for vehicle service system optical target.
Schommer, Stefan; Bux, Hermann, Method for locating a geometric detail for determining the spatial position of a wheel rim relative to a measuring instrument and method and device for determining the spatial position of a wheel rim with respect to a measuring instrument.
Nobis, Guenter; Uffenkamp, Volker, Unit of at least two target arrangements for optically measuring an axle and device for optically measuring an axle.
Kling ; III Michael J. (Mequon WI) Alusick Michael P. (Hartland WI) Kercheck Gary R. (Colgate WI) Krueger Jeff C. (Milwaukee WI) Schmitz Duane M. (Shorewood WI) Visser James L. (New Berlin WI), Wheel alignment system.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.