In a method of operating a dimensioning system with a plurality of laser scanners, a processor controls the operations of the scanners and processes the scanner signals, and further with memory for storing data delivered by the processor, the data acquired by the dimensioning system in its regular mode of operation are used to construct a three-dimensional model of surface points of the object including spatial coordinates and image intensity for each surface point. The three-dimensional model is stored in the memory. Based on the three-dimensional model, two-dimensional images from any desired viewing angle that was exposed to the scanner rays can be produced on demand to document the appearance of the object at the time the scan was taken.

An object surface managing method comprising: (a) emitting detecting light to the groove via alight source; (b) receiving first reflected detecting light from the surface and second reflected detecting light from a bottom of the groove via a light sensor; and (c) calculating a groove depth of the groove according to the first reflected detecting light and the second reflected detecting light.

A three-dimension measurement device includes a moving device, a projecting device, a surface-type image-capturing device and a processing device. The moving device carries an object, and moves the object to a plurality of positions. The projecting device generates a first light to the object. The surface-type image-capturing device senses a second light generated by the object in response to the first light to generate a phase image on each of the positions. The processing device is coupled to the surface-type image-capturing device and receives the phase images. The processing device performs a region-of-interest (ROI) operation for the phase images to generate a plurality of ROI images. The processing device performs a multi-step phase-shifting operation for the ROI images to calculate the surface height distribution of the object.

A method of generating a three-dimensional topological surface representation of a tyre on a vehicle, the method comprising: using a tread depth measurement device to record tread depth data for a tyre surface moving relative to the tread depth measurement device; generating a movement profile of the tyre surface; and using the movement profile of the tyre surface to map the tread depth data onto a base tyre structure, thereby generating a three-dimensional topological surface representation of the tyre.

A positioning device combining mark point positioning and intelligent reverse positioning and method thereof, comprising a binocular camera, a third camera, and a laser; the laser is used for emitting laser projection, the binocular camera is used for acquiring images with laser lines and reflective mark points on the surface of the scanned object, and the third camera is used for acquiring images with coding points and mark points in the peripheral environment; the method comprises the following steps of: S1. calibrating parameters of each camera under different scanning modes, and enabling the parameters of each camera to synchronously and correspondingly transform when the scanning modes are switched; S2. judging and switching the scanning mode into a mark point mode or an intelligent reverse tracking mode through the scanning scene. The two positioning modes are flexibly switched, and the use of a user is facilitated.

A method for estimating vehicle location by obtaining change events from an event camera's observations of a ground surface moving relative to the vehicle, determining a signature of the ground surface from the change events; and estimating the location using the signature. The change events may be processed to produce an 1st invariant representation of a ground surface patch for use as the signature. Alternatively, range measurements representing a patch may be used as the signature. A map is constructed having the representations of the ground surface patches including the locations of the patches. The same patch of ground surface is subsequently measured thereby obtaining a sequence of change events which are processed to produce a 2nd representation. The 2nd representation is matched to the map of 1st invariant representations. The location of the vehicle on the ground is determined based on the match.

A device is proposed for the contactless three-dimensional inspection of a blade (5) for a turbomachine, comprising: means for scanning the teeth, comprising at least one first pair of laser measurement modules (2A, 2B) and means for the rotational driving, about the main axis, of the blade relative to the modules along the main axis of the blade; means for the rebuilding of a three-dimensional virtual representation of the blade using data coming from said scanning means; means of dimensional inspection using the three-dimensional representation; each pair of modules comprising a first module (2A) oriented towards a first face of a tooth and a second module oriented towards a second face of a tooth;
the modules being oriented relative to the blade so that during a rotation of the blade about the main axis, the scanning means scan the first and second faces of the blade on the entire rim of said blade, and so that during a translation of the blade along the main axis, said scanning means scan the first and second faces of the blade throughout their height.

The invention relates to a method for determining deformations on an object, wherein the object is illuminated and moved while being illuminated. In the process, the object is observed by means of at least one camera and at least two camera images are generated at different times by said camera. In the camera images, polygonal chains are ascertained in each case for reflections at the object caused by form features. The form features are classified on the basis of the behavior of the polygonal chains over the at least two camera images and a two-dimensional representation is generated, the latter representing a spatial distribution of deformations. Moreover, the invention relates to a corresponding apparatus.

Manufacturing of a shoe is enhanced by creating 3-D models of shoe parts. For example, a laser beam may be projected onto a shoe-part surface, such that a projected laser line appears on the shoe part. An image of the projected laser line may be analyzed to determine coordinate information, which may be converted into geometric coordinate values usable to create a 3-D model of the shoe part. Once a 3-D model is known and is converted to a coordinate system recognized by shoe-manufacturing tools, certain manufacturing steps may be automated.

A profilometer provides, to a controller, a feedback signal indicative of topography of an exposed surface of an object that is being manufactured by a 3d printer. The profilometer includes an emitter and a camera. The emitter illuminates a region of surface of the object with a pattern having an edge that defines a boundary of an illuminated portion of the surface. The camera receives an image that transitions between a first state in which the edge is visible in the image at a location that is indicative of the surface's depth and a second state in which the edge is not visible at all. From this second state, the controller obtains information representative of a depth of the surface.