A method for measuring the dimensions and characteristic angles of wheels, steering system and chassis of vehicles by means of an apparatus comprising a plurality of 3D scanners, functionally connected to a computer and arranged peripherally to a vehicle whose dimensions and characteristic angles of wheels, steering system and chassis are to be measured; each one of the 3D scanners having a viewing field, the merging of the viewing fields defining a viewing field of the apparatus; the method is characterized in that it comprises: a total measurement step, in which all the wheels of the vehicle are at least partially visible in the viewing field of the apparatus; and a partial measurement step, in which at least one wheel of the vehicle is not visible in the viewing field of the apparatus.

A system and method of calibrating an ADAS sensor of a vehicle by aligning a target with the sensor, where the vehicle is initially nominally positioned in front of a target adjustment stand that includes a stationary base frame and a movable target mount configured to support a target, with the target adjustment stand including one or more actuators for adjusting the position of the target mount. A computer system is used to determine an orientation of the vehicle relative to the target adjustment stand, with the position of the target mount being adjusted based on the determined orientation of the vehicle relative to the target adjustment stand. Upon properly orienting the target mount, and the target supported thereon, a calibration routine is performed whereby the sensor is calibrated using the target.

A system and method for aligning a target to a vehicle for calibration of a sensor equipped on the vehicle includes multiple non-contact wheel alignment sensors configured for use in determining the orientation of tire and wheel assemblies of the vehicle. A target adjustment frame includes a target mount moveably mounted on a base frame, and includes multiple actuators configured to selectively move the target mount relative to the base frame, where the base frame is in a known orientation to the non-contact wheel alignment sensors. A computer system selectively actuates the actuators to position a target relative to the vehicle, with the target mount being moveable about a plurality of axes based on the determination of the orientation of the vehicle relative to the target adjustment frame to position the target relative to a sensor of the vehicle whereby the sensor is able to be calibrated using the target.

A non-contact sensor for determining orientation of an object, such as a tire and wheel assembly of a vehicle, includes a projector assembly having a light emitter, a lens assembly and a mask, with the mask including mask apertures and the light emitter configured to project light through the lens assembly and mask apertures and onto the object, and with the mask apertures creating a light pattern of projected light onto the object. The sensor also includes an imager configured to image reflections of the light pattern from the object, and a processor. The projector assembly and imager are angled with respect to one another, and the processor is configured to process imaged reflections of the light pattern to derive the orientation of the object, such as the alignment orientation of the tire and wheel assembly.

A system and method for aligning a target to a vehicle for calibration of a sensor equipped on the vehicle includes multiple non-contact wheel alignment sensors configured for use in determining the orientation of tire and wheel assemblies of the vehicle. A target adjustment frame includes a target mount moveably mounted on a base frame, and includes multiple actuators configured to selectively move the target mount relative to the base frame, where the base frame is in a known orientation to the non-contact wheel alignment sensors. A computer system selectively actuates the actuators to position a target relative to the vehicle, with the target mount being moveable about a plurality of axes based on the determination of the orientation of the vehicle relative to the target adjustment frame to position the target relative to a sensor of the vehicle whereby the sensor is able to be calibrated using the target.

A method for measuring the dimensions and characteristic angles of wheels, steering system and chassis of vehicles by means of an apparatus comprising a plurality of 3D scanners, functionally connected to a computer and arranged peripherally to a vehicle whose dimensions and characteristic angles of wheels, steering system and chassis are to be measured; each one of the 3D scanners having a viewing field, the merging of the viewing fields defining a viewing field of the apparatus; the method is characterized in that it comprises: a total measurement step, in which all the wheels of the vehicle are at least partially visible in the viewing field of the apparatus; and a partial measurement step, in which at least one wheel of the vehicle is not visible in the viewing field of the apparatus

A vehicle equipment comprises a scanning system for the contactless measurement of at least one projector arranged at least for the projection onto an object to be measured of a structured light with a pattern, at least one video camera arranged for the acquisition of the image of the object to be measured, and a processing unit for processing the acquired image for the three-dimensional reconstruction of the object to be measured, the projector comprising in turn at least one matrix of emitters integrated into a monolithic substrate.

A vehicle wheel assembly position measurement apparatus measures, at each of at least three measurement positions in a circumferential direction, a distance in a vehicle width direction between each of plural measurement points located on a specified line that crosses a lateral surface of a tire section from an inner circumferential end to an outer circumferential end and a respective one of distance measuring instruments, calculates an approximate curve indicating a relationship between a position in an extending direction of the specified line and the distance of each of the measurement points at the respective measurement position, calculates a rotation center position of a wheel assembly from a specific position of the approximate curve at the measurement position, and calculates a height position of the wheel assembly relative to a vehicle body from the rotation center position and a height position of a specified portion of the vehicle body.

A system and method of calibrating an ADAS sensor of a vehicle by aligning a target with the sensor, where the vehicle is initially nominally positioned in front of a target adjustment stand that includes a stationary base frame and a movable target mount configured to support a target, with the target adjustment stand including one or more actuators for adjusting the position of the target mount. A computer system is used to determine an orientation of the vehicle relative to the target adjustment stand, with the position of the target mount being adjusted based on the determined orientation of the vehicle relative to the target adjustment stand. Upon properly orienting the target mount, and the target supported thereon, a calibration routine is performed whereby the sensor is calibrated using the target.

The present invention relates to a method for determining parameters of the chassis geometry of wheels of a non steered axle, amuse of the method, a test bench for a vehicle, and a measuring unit. The method relates to determining the parameters of the chassis geometry of the Wheels of the rear axle of a vehicle from measurements of the toe angle in two measuring positions of the vehicle in the test bench, which positions are mutually offset in the x-direction. Wheel runout compensation is achieved thereby. The geometric driving axle thus determined can be used for setting driver assistance systems and for setting the parameters of the chassis geometry of the steered wheels of the front axle. A measuring unit can be designed such that a plurality of parallel lines for generating a planar pattern are generated by means of a parallel displacement of a sensor in the x-direction, which sensor emits linear light having one line. A linear sensor of this kind can in turn be replaced by a sensor comprising a point light source by means of which a line is scanned.