The apparatus comprises a target structure (101) having a reflective surface (102) and a crossbar structure oriented parallel to an axel of the vehicle; a first reference structure (107) having a pass-through channel (108) and an aiming surface (109); a second reference structure (111) having a laser emitter (102). In the method the first reference structure is aligned with a midpoint of a side of the vehicle nearest to the target structure and the second reference structure with the laser emitter is aligned with a midpoint of a side of the vehicle furthest from the target structure with the laser emitter oriented toward the target structure. The emitted laser beam passes through the channel of the first reference structure and is reflected by the reflective surface. The relative angle and alignment of the target structure at the reflection position is adjusted such that the reflected beam is reflected onto a designated region of the aiming surface on the first structure. The laser measurement may be in the form of a line generator to provide visual aid to the user in alignment.

A measurement panel (8) for the optical measurement or calibration of a vehicle component, in particular a wheel system or driver assistance system, comprises at least one optical feature (30, 32) and at least one optically detectable information carrier (34) of measurement panel information relating to the measurement panel (8) itself. The at least one optical feature (30, 32) is formed on or attached to a front side of the measurement panel (8), and the at least one optically detectable information carrier (34) is formed on or attached to a rear side of the measurement panel (8).

A measurement panel (8) for the optical measurement or calibration of a vehicle component, in particular a wheel system or driver assistance system, comprises at least one optical feature (30, 32) and at least one optically detectable information carrier (34) of measurement panel information relating to the measurement panel (8) itself. The at least one optical feature (30, 32) is formed on or attached to a front side of the measurement panel (8), and the at least one optically detectable information carrier (34) is formed on or attached to a rear side of the measurement panel (8).

A wheel alignment detection system for a vehicle includes a plurality of sensors and a controller. Each of the plurality of sensors is configured to generate a signal. The controller is in communication with the plurality of sensors and is configured to: detect an external force exerted on the vehicle based on the signal from at least one of the plurality of sensors; determine whether the external force exerted on the vehicle has a magnitude that is between a first predetermined value and a second predetermined value; and command the vehicle to provide an alert in response to determining that the magnitude of the external force exerted on the vehicle is between the first predetermined value and the second predetermined value, wherein the alert is indicative that a wheel alignment check should be performed.

A wheel alignment detection system for a vehicle includes a plurality of sensors and a controller. Each of the plurality of sensors is configured to generate a signal. The controller is in communication with the plurality of sensors and is configured to: detect an external force exerted on the vehicle based on the signal from at least one of the plurality of sensors; determine whether the external force exerted on the vehicle has a magnitude that is between a first predetermined value and a second predetermined value; and command the vehicle to provide an alert in response to determining that the magnitude of the external force exerted on the vehicle is between the first predetermined value and the second predetermined value, wherein the alert is indicative that a wheel alignment check should be performed.

A support structure having a vertical element supporting a set of cameras associated with a vehicle measurement or inspection system together with at least one target structure required for realignment or recalibration of onboard vehicle safety system sensors. A camera crossbeam carried by the support structure locates the set of cameras as required to view a vehicle undergoing measurement or inspection. The target structure is affixed to the vertical element of the support structure, at an elevation suitable for observation by at least one vehicle onboard sensors during a realignment or recalibration procedure. A set of rollers facilitates positioning of the target structure on a supporting floor surface during a realignment or recalibration procedure.

Methods and systems measure a vehicle body parameter; e.g., a wheel alignment parameter such as ride height. Embodiments include a system having a target attachable to a vehicle body, and an image sensor for viewing the target and capturing image data thereof. A processor processes the image data, determines an initial spatial position of the target based on the processed image data, compares the initial spatial position of the target with a reference position, and prompts a user to align the target to an adjusted spatial position when the initial spatial position differs from the reference position more than a threshold amount. The vehicle body parameter value is determined based on the target's adjusted spatial position. In certain embodiments, the adjusted spatial position differs from the reference position by a position error value, and the processor mathematically corrects the vehicle body parameter value based on the position error value.

Vehicle alignment systems and methods are disclosed which operate based on a calculation of “drive direction,” or the direction in which a vehicle is moving. Since a vehicle can be assumed to be a rigid body, each wheel has the same drive direction. Consequently, an alignment parameter of one wheel can be compared to the same parameter of another wheel by equating their drive direction, eliminating the need for the aligner to “see” both sides of the vehicle at the same time. Embodiments include a system having one or more cameras on a fixture carrying a calibration element for an ADAS system, and one or more targets placed on the vehicle to measure the drive direction of the vehicle. The drive direction is assumed to be parallel to the vehicle thrust line and can be used as the line for orientation of the fixture to the vehicle.

A target alignment system for calibrating a safety sensor mounted on a vehicle with front and rear wheels by locating an optimum target position upon a horizontal surface for accurate calibration of the sensor. The target alignment system comprises a plurality of visual guide projectors and a pair of target assemblies which project a visible guide line perimeter around the vehicle, the perimeter including parallel longitudinal lines on either side of the vehicle, a lateral alignment guide line crossing the longitudinal lines in front of the vehicle, and a center guide line colinear with the vehicle center line. The front and rear wheels of the vehicle are longitudinally aligned causing the vehicle thrust line to match the vehicle center line. One of the visual guide projectors projects a transverse line across the center guide line, creating an intersection point which marks the optimum target position.

A target alignment system for calibrating a safety sensor mounted on a vehicle with front and rear wheels by locating an optimum target position upon a horizontal surface for accurate calibration of the sensor. The target alignment system comprises a plurality of visual guide projectors and a pair of target assemblies which project a visible guide line perimeter around the vehicle, the perimeter including parallel longitudinal lines on either side of the vehicle, a lateral alignment guide line crossing the longitudinal lines in front of the vehicle, and a center guide line colinear with the vehicle center line. The front and rear wheels of the vehicle are longitudinally aligned causing the vehicle thrust line to match the vehicle center line. One of the visual guide projectors projects a transverse line across the center guide line, creating an intersection point which marks the optimum target position.