A method of scanning an oral cavity including: acquiring, using an intraoral scanner (IOS) head, without changing a position of the IOS head, a first image of a first region of interest (ROI) and a second image of a second ROI where the first and the second ROIs are of different portions of a dental arch of the oral cavity and do not overlap; reconstructing depth information for the first and the second ROI; and generating a single model of the dental arch by combing the depth information.

Proposed is a method of compensating data, the method including: acquiring a plurality of initial scan shots by scanning a target object onto which a predetermined pattern is projected; detecting a non-scan region on the basis of the plurality of initial scan shots; and acquiring at least one compensated scan shot by additionally scanning at least one portion of the target object when the non-scan region is detected.

An optical imaging and processing system includes an optical element and a processor configured to process the plurality of image frames to generate a three-dimensional model of at least a portion of the turbine component interior. The system may also include a display coupled to the processor to display the three-dimensional model. An operator may view and analyze the three-dimensional model on the display for defects. The processor may further be configured to automatically navigate the three-dimensional model to determine defects within the turbine component interior. The system may also include a repositioning device configured to reposition the optical element such that the optical element may capture the plurality of image frames from multiple vantage points within the turbine component interior.

A 3D object sensing system includes an object positioning unit, an object sensing unit, and an evaluation unit. The object positioning unit has a rotatable platform and a platform position sensing unit. The object sensing unit includes two individual sensing systems which each have a sensing area. A positioning unit defines a positional relation of the individual sensing systems to one another. The two individual sensing systems sense object data of object points of the 3D object and provide the object data the evaluation unit. The evaluation unit includes respective evaluation modules for each of the at least two individual sensing systems, an overall evaluation module and a generation module.

An inspection system for mounting on a user's hand. The inspection system comprising: an imaging unit comprising two sub-units, the first sub-unit being configured to provide images from a first point of view and the second sub-unit being configured to provide images from a second point of view; and a measuring unit configured to provide data relating to a physical property measured at a measurement location on the user's hand. The imaging unit has a separation sensor configured to measure the separation between the two sub-units of the imaging unit. A method of inspecting and/or servicing a machine is also disclosed.

A three-dimensional (3D) dental scanning system (1) for scanning a dental object (D) includes a scanning surface (124a) to support the dental object (D); a scanning section (130) to capture a 3D scan of the dental object (D); a motion section (120) to move the scanning surface (124a) and scanning section (130) relative to each other in five axes of motion, whilst retaining the scanning surface (124a) in a substantially horizontal plane, and a control unit (140) configured to control the motion section (120) and the scanning section (130) to obtain a 3D scan of the dental object (D).

In a method and system for measuring a height map of a surface of an object, the following steps are carried out. Height maps of different sections of the surface of the object are measured, using an optical profilometer having a field of view covering an individual section, wherein each height map comprises height data. The measured height maps are grouped into different sets of height maps, wherein within each set each one of the height maps of the set has a valid overlap to at least one other height map of the set, and wherein each height map belongs to one set and does not have a valid overlap with any height map of another set. Within each set, the measured height maps are stitched to a sub-composite stitched height map. The sub-composite stitched height maps are combined to a composite height map.

A method including determining with a three-dimensional (3D) measuring instrument 3D coordinates of an object for each of a plurality of poses of the 3D measuring instrument; capturing with a camera first- and higher-order diffraction components of markers near or on the object, the camera having a diffractive optical element (DOE), a lens, and a photosensitive array; and registering with a processor the determined 3D coordinates based at least in part on the determined 3D coordinates and on the imaged zero- and higher-order diffraction components.

Dynamically customized animatable 3D models of virtual characters (“avatars”) are generated in real time from multiple inputs from one or more devices having various sensors. Each input may comprise a point cloud associated with a user's face/head. An example method comprises receiving inputs from sensor data from multiple sensors of the device(s) in real time, and pre-processing the inputs for determining orientation of the point clouds. The method may include registering the point clouds to align them to a common reference; automatically detecting features of the point clouds; deforming a template geometry based on the features to automatically generate a custom geometry; determining a texture of the inputs and transferring the texture to the custom geometry; deforming a template control structure based on the features to automatically generate a custom control structure; and generating an animatable object having the custom geometry, the transferred texture, and the custom control structure.

The invention relates to a method for inspecting a part mounted in a manufacturing fixture between two manufacturing operations by means comprising: a sensor a robot to hold and move the sensor a computer comprising memory means, computation means and display means, comprising in its memory means a three-dimensional digital model of the workpiece, and able to record the coordinates of the points acquired by the sensorthe method comprising the steps consisting of: segmenting (1010) of the CAD model into a set of surfaces, designated as nodes, each node corresponding to a surface that is visible in a single acquisition according to the characteristics of the sensor determining (1020) the visibility of each node from each position of the sensor relative to said node determining common visibilities (1030) between the nodes.