SELF-CALIBRATING MULTI-CAMERA ALIGNMENT SYSTEM
A portable vehicle alignment system is provided having two base tower assemblies, each having a pedestal, a columnar tower removably attachable to the top of the pedestal, and a camera pod movable along a length of the tower; and a data processor with a wireless communication device for processing image data from the camera pods. Each camera pod includes a camera for capturing image data of a target mounted on a vehicle, and a communication device for wirelessly communicating with the data processor. One pod has a calibration target and the other pod has a calibration camera for capturing images of the calibration target. The pedestals each have a manually-operated clamp for removably fixedly attaching the tower to the pedestal in one of a plurality of positions such that the orientation of the camera pod to the pedestal is angularly adjustable, allowing horizontal rotation of the camera pod.
The present application is a U.S. Continuation Application of U.S. patent application Ser. No. 14/463,604, filed Aug. 19, 2014, which claims priority to U.S. Provisional Application No. 61/867,276, entitled “Improved Self-Calibrating Multi-Camera Alignment System,” filed Aug. 19, 2013, all of which are incorporated herein by reference in their entirety.
FIELDEmbodiments relate generally to machine vision vehicle wheel alignment systems and methods, and more particularly to machine vision alignment systems having movable cameras that continuously self-calibrate their position relative to that of vehicle-mounted targets.
BACKGROUNDMachine vision vehicle alignment systems using movable cameras and targets attached to vehicle wheels are well known. The targets are viewed by the cameras such that image data obtained for a prescribed alignment process can be used to calculate vehicle alignment angles for display through a user interface, usually a computer monitor. Early system implementations included rigid beams that connected the cameras so that their position and orientation with respect to each other could be determined and be relied upon as unchanging. Later system implementations were introduced comprising the use of cameras not rigidly connected to each other, but using a separate camera/target system to continuously calibrate the position of one vehicle mounted target viewing camera to another. This type of system is described in U.S. Pat. Nos. 5,724,743; 5,535,522; 6,931,340; 6,959,253; and 6,968,282, all of which are hereby incorporated by reference herein.
Camera based wheel aligner systems are typically shipped in large boxes and installed by trained technicians. The system usually includes parts that cannot be easily and safely handled by a single technician, often requiring assistance from the customers or a second technician. For example, these alignment systems comprise a camera support mechanism to allow the cameras to be positioned and directed as required to incorporate a field of view including targets attached to vehicle wheels. The camera support mechanism usually comprises of some type of solid base or beam that is fixed to the ground so that the cameras are solidly supported. Some alignment systems use solid horizontal beams that permanently fix the distance and orientation between the cameras, while other systems use solid vertical beams and cameras that travel along the beams as necessary to maintain the targets in the camera field of view. Given the constraint of maximum vehicle dimensions, the camera supporting beams are long and heavy enough to make handling during installation difficult for a single person. A need exists for a more modular installation approach using parts that can be easily handled by one person.
In addition, each installation site poses specific challenges with regard to the physical limitations of the shop environment, including the availability of power and floor space. Space constraints and power availability locations of the specific shop create problems that cannot be solved by a large, inflexible system.
Once installation is complete, the system is typically fixed to the floor and cannot be easily relocated or adjusted by the end user. Accordingly, a need exists for an alignment system that can be moved safely and easily by an end user when a need is identified, and has the flexibility for minor adjustment without physical movement of the supporting structure.
SUMMARYOne or more embodiments can include a portable vehicle alignment system comprising a pair of base tower assemblies, each base tower assembly comprising a pedestal, a columnar tower removably attachable to a top portion of the pedestal to extend substantially vertically upward from the pedestal, and a camera pod mounted to move along a length of the tower. The system further includes a data processor for processing image data from the camera pods, and having a wireless communication device. A first one of the camera pods comprises a first camera for capturing image data of a first target mounted on a vehicle, a calibration target disposed in a fixed relationship to the first camera, and a wireless communication device for communicating with the data processor's wireless communication device. A second one of the camera pods comprises a second camera for capturing image data of a second target mounted on the vehicle, a calibration camera disposed in a fixed relationship to the second camera for capturing images of the calibration target, and a wireless communication device for communicating with the data processor's wireless communication device. The base tower assemblies are each separately movable by a user, and each of the pedestals comprises a manually-operated clamp proximal its top portion for removably fixedly attaching the tower to the pedestal in one of a plurality of positions such that the orientation of the camera pod to the pedestal is angularly adjustable, allowing horizontal rotation of the camera pod.
Embodiments can further include a portable vehicle alignment system comprising a pair of base tower assemblies, each base tower assembly comprising a pedestal, a columnar tower removably attachable to a top portion of the pedestal to extend substantially vertically upward from the pedestal, and a camera pod mounted to move along a length of the tower. The system further includes a data processor for processing image data from the camera pods, and having a wireless communication device. A first one of the camera pods comprises a first camera for capturing image data of a first target mounted on a vehicle, a calibration target disposed in a fixed relationship to the first camera, and a wireless communication device for communicating with the data processor's wireless communication device. A second one of the camera pods comprises a second camera for capturing image data of a second target mounted on the vehicle, a calibration camera disposed in a fixed relationship to the second camera for capturing images of the calibration target, and a wireless communication device for communicating with the data processor's wireless communication device. Each pedestal comprises a power supply electrically connected to its camera pod for supplying all electrical power needed to operate its camera pod, each power supply having a battery.
Objects and advantages of embodiments of the disclosed subject matter will become apparent from the following description when considered in conjunction with the accompanying drawings.
Embodiments will hereinafter be described in detail below with reference to the accompanying drawings, wherein like reference numerals represent like elements. The accompanying drawings have not necessarily been drawn to scale. Where applicable, some features may not be illustrated to assist in the description of underlying features.
It should be understood that the principles described herein are not limited in application to the details of construction or the arrangement of components set forth in the following description or illustrated in the following drawings. The principles can be embodied in other embodiments and can be practiced or carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting.
This disclosure describes a camera based aligner system that includes enhancements directed at improving the safety, flexibility and functionality of the installation. According to one aspect of this disclosure, a multi-piece support beam is provided, to reduce the maximum weight of the camera support beam so that the beam can be safely handled by a single person.
According to another aspect of this disclosure, an aligner system is made portable by providing easily moveable camera support beam assemblies which can be quickly and safely moved from one shop bay to another without the need for intervention by a factory technician to provide relocation and calibration services. As a further related aspect of this disclosure, docking stations are provided (e.g., at each shop bay where a vehicle alignment could be performed) so that repositioning the aligner camera supports from one bay to another can be accomplished quickly, and the supports held securely in place once located as desired. Since power outlets are not always available at all locations in a shop, in certain embodiments the docking stations are supplied with power and network connections (e.g., Ethernet connections) so that the act of docking the camera support assemblies also makes necessary power and communication connections.
Another aspect of this disclosure addresses the need for small adjustments in the camera field of view to accommodate unusually large or small vehicles. A mechanism is provided to allow small field of view adjustments without moving the entire camera support beam assembly. A lock mechanism is provided to secure the camera position once the appropriate field of view is obtained.
Electrical power must be supplied to the camera assemblies travelling vertically along the camera support beams. In another aspect of this disclosure, a guide wire with a coiled power cable is provided to accomplish this task.
Synchronizing the movement of the cameras on multiple vertical camera support beams is necessary to maintain camera field of view of the wheel mounted targets. As the vehicle is raised on a lift, it is desirable to move the cameras to keep the targets near the field of view of the cameras. In another aspect of this disclosure, a DC motor is used in communication with the camera outputs to accomplish this task.
Arrow 30 schematically represents a motor vehicle undergoing alignment. The vehicle includes left and right front wheels 22L, 22R and left and right rear wheels 24L, 24R. An alignment target 80a, 80b, 80c, 80d is secured to each of the wheels 22L, 22R, 24L, 24R, respectively. Each alignment target generally comprises a plate 82 on which target information is imprinted and a clamping mechanism 88 for securing the target to a wheel.
The left camera module 2 comprises a left alignment camera 10L and a calibration camera 20. Left alignment camera 10L faces the vehicle and views the left side targets 80a, 80b along axis 42. Camera 10L is rigidly mounted to left rigid mount 12. A calibration camera 20 faces the right camera module 4 and views a calibration target 16 along axis 46. The calibration camera 20 also is affixed rigidly to mount 12. In this exemplary embodiment, calibration camera 20 is illustrated as forming a part of left camera module 2. However, the calibration camera 20 also may be configured as part of right camera module 4, in which case its view would be directed leftward toward left camera module 2.
Right camera module 4 comprises a right camera 10R that faces the vehicle and functions as a second alignment camera in a 3D alignment system. Right camera 10R is affixed to a rigid camera mount 14. Calibration target 16 is rigidly affixed to camera mount 14 in a position visible to calibration camera 20 along axis 46.
Calibration camera 20 and left camera 10L are fixed in pre-determined, known positions. Similarly, right camera 10R and calibration target 16 are fixed in pre-determined, known positions. Thus, the relative position of calibration camera to left camera 10L is known, and the relative position of right camera 10R to calibration target 16 is also known.
For illuminating the calibration target 16 and wheel targets 80a-80d, left camera module 2 and right camera module 4 further may comprise light sources 62, 64, 66. A first light source 62 is aligned perpendicular to axis 46 to direct light along that axis to illuminate calibration target 16; a second light source 64 is aligned perpendicular to axis 42 to direct light along that axis to illuminate left side wheel targets 80a, 80b; and a third light source 66 is aligned perpendicular to axis 44 to direct light along that axis to illuminate right side wheel targets 80c, 80d. Each of the light sources 62, 64, 66 can comprise a plurality of light-emitting diodes (LEDs); however, any other light source may be used.
Exemplary imaging alignment systems according to the present disclosure, comprising three wireless cameras, will now be described with reference to
Referring now to
As shown in
According to certain embodiments shown in
In an alternative embodiment shown in
The stationary bar 400 can be made from a variety of materials; e.g., roll formed steel, extruded aluminum, extruded plastic. In some embodiments, the length of bar 400 is approximately 75 inches. In the embodiment shown in
The movements of the two camera pods 120a, 120b up and down are kept synchronous by utilizing the calibration camera 155 and calibration target 140, along with wheel target information from the vehicle 30. The processing of this information allows the data processor 125 to adjust the motor speed to keep the camera pods 120a, 120b in sync with each other, and adjusts the pod speed to stay in synch with movement of a vehicle lift (not shown) on which the vehicle 30 can be carried while the alignment is being performed.
The base tower assemblies 105a, 105b can be broken into shorter elements for minimal length of packaging during transportation, shipping and warehousing, and are each separately movable by a user. In certain embodiments, each of the pedestals 110a, 110b comprises a manually-operated clamp 200, such as shown in
As shown in
Clamp 200 is pressed against and locked to top flange 230 by downward pressure applied by the cam action of the cam levers 240 when they are in a locked position shown in
Since the camera pods 120a, 120b of the disclosed embodiment are wireless, no wires are needed for communication purposes. However, electrical power must be supplied to each camera pod 120a, 120b for powering the camera(s) and motor drive. In certain embodiments, each pedestal 110a, 110b comprises a power supply 250 including a battery, the power supply 250 electrically connected to its respective camera pod 120a, 120b for supplying all electrical power needed to operate its camera pod. The battery can be a rechargeable battery, and the power supply 250 can further include a charger for charging the battery. In other embodiments, the battery or batteries are removable for remote recharge. In one example, a pedestal-mounted battery is charged from an electrical wall outlet. This battery can be disconnected from the wall, and will supply electrical power to the camera measuring system, allowing each pedestal to have no electrical or communication cables/wires.
In certain embodiments, power supply 250 is designed for a variety of DC input voltages; i.e., 19 volts to 32 volts, enabling commonly used power supplies from laptop computers or printers to be used. This feature is a convenience for local sourcing of components around the world. It provides flexibility to use almost any power supply locally available for inclusion with new units built in Europe or Asia, and has the added advantage that a service technician can purchase a replacement power supply locally if a factory service part is not easily available.
An additional feature of this disclosure is the design of a cable management system, which ensures power from the power supply 250 is connected to the cameras and motors, while allowing the camera and pod assembly 120a, 120b to freely move vertically along the columnar tower 115a, 115b. Referring now to
In some embodiments, the disclosed wireless alignment system is rendered portable around a shop to multiple alignment bays. This portability is made possible by a wheeled base, which allows the base tower assemblies 105a, 105b to be easily moved about the shop as required. Referring now to
In certain embodiments, a docking station 350 as shown in
Each docking station 350 comprises a pocket 355 for receiving the at least one wheel 305 of its associated pedestal 105a, 105b, and for indicating to a user that the wheel 305 is engaged with the docking station 350. The docking station can also include a funnel shaped area 365 to guide the wheel 305 into the pocket 355. The docking plate can be made in a bright color (e.g., yellow or red) to make it highly visible to the user. To lock the cart into position such that it cannot be moved inadvertently (e.g., bumped), each docking station 350 can also comprise a pocket 360 for receiving at least one of the leveling feet 315 of its associated pedestal 105a, 105b for locking the pedestal to the docking station 350. As seen in
The disclosed system provides several advantages. No wires are required to connect the cameras to the PC. Thus, the PC and its hosting cabinet can be moved to any position around the vehicle for an easier and/or more customizable set up. Also, problems with bystander or user entanglement in conventional wired connections between cameras and PC are eliminated. The disclosed system allows the imaging cameras to be easily moved around the shop from bay to bay as needed, and allows the imaging cameras to be used as audit aligners in a drive-through shop area where no connecting wires are desired. Moreover, the disclosed system provides flexibility so that wireless camera pods can be mounted directly to a wall or ceiling, allowing the shop floor area to be open for vehicle and pedestrian traffic.
The present disclosure can be practiced by employing conventional materials, methodology and equipment. Accordingly, the details of such materials, equipment and methodology are not set forth herein in detail. In the previous descriptions, numerous specific details are set forth, such as specific materials, structures, chemicals, processes, etc., in order to provide a thorough understanding of the present teachings. However, it should be recognized that the present teachings can be practiced without resorting to the details specifically set forth. In other instances, well known processing structures have not been described in detail, in order not to unnecessarily obscure aspects of the present teachings.
While the foregoing has described several examples, it is understood that various modifications may be made therein and that the subject matter disclosed herein may be implemented in various forms and examples, and that the teachings may be applied in numerous applications, only some of which have been described herein. It is intended by the following claims to claim any and all applications, modifications and variations that fall within the true scope of the present teachings.
Claims
1. A portable vehicle alignment system, comprising:
- a pair of base tower assemblies, each base tower assembly comprising a columnar tower extending substantially vertically upward, and a camera pod mounted to move along a length of the tower; and
- a data processor in communication with the camera pods for processing image data from the camera pods;
- wherein a first one of the camera pods comprises a first camera for capturing image data of a first target mounted on a vehicle, and a calibration target disposed in a fixed relationship to the first camera;
- wherein a second one of the camera pods comprises a second camera for capturing image data of a second target mounted on the vehicle, and a calibration camera disposed in a fixed relationship to the second camera for capturing images of the calibration target;
- wherein each camera pod has a motor drive to move the pod along the length of the tower, and the data processor is for controlling the motor drives using the images captured by the calibration camera such that the motion of the camera pods is synchronous with each other;
- wherein the base tower assemblies are each separately movable by a user.
2. The system of claim 1, wherein each base tower assembly comprises a pedestal, and the columnar tower is removably attachable to a top portion of the pedestal; and
- wherein each of the base tower assemblies further comprises a portable base attachable to a lower distal portion of the pedestal, the portable base having at least one wheel engageable with a floor surface for moving the base tower assembly.
3. The system of claim 2, wherein the portable base comprises a plate having a plurality of leveling feet for leveling the base tower assembly, and the at least one wheel is for selectively engaging the floor surface by tilting the plate.
4. The system of claim 2, further comprising a docking station associated with each base tower assembly, each docking station being fixedly attachable to the floor;
- wherein each docking station is for engaging the at least one wheel of its associated pedestal to orient the pedestal relative to the docking station.
5. The system of claim 4, wherein each docking station comprises a pocket for receiving the at least one wheel of its associated pedestal and for indicating to a user that the wheel is engaged with the docking station.
6. The system of claim 5, wherein each docking station comprises a pocket for receiving at least one of the leveling feet of its associated pedestal for locking the pedestal to the docking station.
7. The system of claim 4, wherein each pedestal comprises a power supply electrically connected to its camera pod, and each docking station includes an electrical connection to the pedestal power supply.
8. The system of claim 1, each pedestal comprising:
- a power supply for providing power to its associated camera pod;
- a guide wire extending from a lower portion of the pedestal to a top portion of the tower; and
- a coiled electrical cable connected between the power supply and the camera pod, and disposed around the guide wire.
9. The system of claim 1, wherein each tower comprises a bar having a T-shaped cross section, and the bar has a linear rack of gear teeth; and
- wherein each tower's associated camera pod has a slide car for engaging the bar to guide motion of the camera pod along the bar, and the motor drive of the associated camera pod has a pinion gear for engaging the rack to drive the camera pod along a length of the bar.
10. The system of claim 1, wherein each tower comprises a stationary bar, a lead screw, and a motor for rotating the lead screw;
- wherein each tower's associated camera pod has a slide car for engaging the bar to guide motion of the camera pod along the bar, the slide car comprising a threaded portion for engaging the lead screw to drive the camera pod along a length of the bar when the lead screw is rotated by the motor.
11. The system of claim 10, wherein the bar and slide car are for preventing rotation of the camera pod as it moves relative to the tower.
12. The system of claim 8, wherein the power supply comprises a rechargeable battery and a charger for charging the battery.
13. The system of claim 8, wherein the power supply comprises a rechargeable battery.
Type: Application
Filed: Mar 26, 2019
Publication Date: Jul 18, 2019
Inventors: James Rodney Harrell (Greenbrier, AR), Brian K. Gray (Conway, AR), David A. Jackson (Points Roberts, WA), Ronald D. Swayne (Sherwood, AR), Darwin Y. Chen (Conway, AR), Bryan C. Minor (Conway, AR)
Application Number: 16/364,272