An interactive 3D electronic representation of a physical scene is executed in a browser. The browser has a limited computing capability compared to a native application or hardware usable by the computer. The interactive 3D representation is configured to minimize overall computing resources and processing time. Attributes of data items corresponding to surfaces and/or contents in the physical scene are extracted from the interactive 3D representation. Interactive verification of the attributes of the subset of data items is performed in the browser by: flattening a selected view of a ceiling, floor, or wall two dimensions; receiving user adjustments (if needed) to the dimensions and/or locations of the selected ceiling, floor, or wall; receiving user indications (if needed) of cut outs in the selected ceiling, floor, or wall; and updating the interactive 3D representation based on adjustments to the dimensions and/or locations, and/or the indications of cut outs.

Introduced here computer programs and associated computer-implemented techniques for establishing the dimensions of interior spaces. These computer programs are able to accomplish this by combining knowledge of these interior spaces with spatial information that is output by an augmented reality (AR) framework. Such an approach allows two-dimensional (2D) layouts to be seamlessly created through guided corner-to-corner measurement of interior spaces.

A method for identifying a geometric feature association for a 3D component model and a 3D manufacturing model is provided. The method includes superimposing the 3D manufacturing model on the 3D component model in a computer-aided drafting (CAD) environment, identifying correspondence between a first geometric feature of the 3D component model and a second geometric feature of the superimposed 3D manufacturing model, measuring at least one distance between the first geometric feature and the second geometric feature, and identifying an association between the first geometric feature and the second geometric feature based on the at least one measured distance.

A design method of an assistive device and an electronic system of assistive device design are provided. The design method of the assistive device are adapted for an electronic devices including a processor. The design method includes: obtaining a point cloud data of a limb part; determining a plurality of reference cross sections according to the point cloud data, wherein each of the reference cross sections is determined corresponding to bone protrusion feature points of the point cloud data, wherein the bone protrusion feature points are corresponding to the bony prominences of the limb parts respectively; establishing an initial digital model of the assistive device according to the reference cross sections; and performing a structural simulation analysis according to the initial digital model and design limitations to obtain a product digital model of the assistive device.

An augmented reality (AR) mirror system is described. In an example, the AR mirror system includes a sensor, a display device, a semi-reflecting surface, a processing system, and computer-readable storage media having instructions stored thereon. The instructions are executable by the processing system to cause display of augmented reality (AR) digital content by the display device to be simultaneously viewable with a reflection of a physical object.

Example systems and methods for virtual visualization of a three-dimensional model of an object in a two-dimensional environment. The method may include moving and aligning the three-dimensional model of the object along a plane in the two-dimensional environment.

Provided are a design assistance device, a design assistance system, a server, and a design assistance method that can display shapes and specification information of a plurality of items included in an item group so that a user can easily view the items. The design assistance device includes: a three-dimensional data acquisition unit that acquires three-dimensional data of an item group including a plurality of items; a display data generation unit that generates two-dimensional display data including a two-dimensional display representing an appearance of the item group and specification information of at least one of the items in one observation direction in the three-dimensional data; and a display mode determination unit that determines a display mode of the specification information in the two-dimensional display based on a shape of each of the items as well as relative positions and relative orientations between the items as viewed in the one observation direction.

The present invention relates to an ultrasound imaging system and a method for the measurement of a distance (58) between two points (54, 56) within a volume of a three-dimensional image (50). To avoid the commonly known fore-shortening effect, according to which a distance measured by the system is shorter than an actual distance (58) between the two points (54, 56), an in-depth control of a cursor (53) shown in the image (50) on the display as provided to the user. Further, an indication (72) may be given to the user that the cursor (53) collides with a structure (52) within the volume to allow the user to assess the movement of the cursor out of the plane shown on the display more conveniently. By this, occurrence of the fore-shortening effect may be avoided.

Certain embodiments include a computer-implemented method that includes receiving image data corresponding to a three-dimensional (3D) parametric model, receiving a selection of a scope of the 3D model, receiving a selection of one or more base lines for the scope, determining a slip type for the scope, calculating planes of the scope, calculating candidate dimension lines, selecting a dimension line of the candidate dimension lines based on dimension line placement rules, and displaying the selected dimension line adjacent to the scope that correspond to the selected one or more base lines. The calculated planes of the scope can be based on the one or more base lines and the slip type. The calculated candidate lines can be based on the calculated planes and dimension line placement guidelines.

A method and a computer programme product for virtually inspecting an actual produced part, comprising providing an ideal Finite Element (FE)-mesh corresponding to an ideal produced part, said ideal produced part comprising two or more mounting places, by measuring the actual produced part, generating a numerical representation of the actual produced part, generating an actual FE-mesh by modifying the ideal FE-mesh such that the shape of the ideal FE-mesh adapts to the numerical representation of the actual produced part, and performing an FE-analysis, by forcing the actual FE-mesh into position by constraining the mounting places of the actual FE-mesh, and determining a deformation of the actual FE mesh resulting from its constraint.