A method and device for measuring dimensions of a feature on or near an object using a video inspection device. A reference surface is determined based on reference surface points on the surface of the object. One or more measurement cursors are placed on measurement pixels of an image of the object. Projected reference surface points associated with the measurement pixels on the reference surface are determined. The dimensions of the feature can be determined using the three-dimensional coordinates of at least one of the projected reference surface points.

[Subject] To provide a size measuring device that can be readily handled and easily used for a size-taking process by even a user who has no specialized size-taking technique, a managing server, a user terminal and a size measuring system. [Means to Solve Problems] The size measuring system is provided with a size measuring device 10 that is attached to a user's body so as to measure the size of the user's body, and outputs sensor measurement information indicating the measured size or the like, a user terminal 20 operated by the user who measures the body and a managing server 30 that manages information or the like of the size and shape of apparel commodities, and based upon the sensor measurement information, supplies user size information corresponding to the information of the body size of the user and commodity retrieval results information corresponding to information about commodities that fit to the size to the user terminal 20.

Example systems and methods for virtual visualization of a three-dimensional (3D) model of an object in a two-dimensional (2) environment. The method may include capturing the 2D environment and adding scale and perspective to the 2D environment. Further, a user may select intersection points on a ground plane of the 2D environment to form walls, thereby converting the 2D environment into a 3D space. The user may further add 3D models of objects on the wall plane such that the objects may remain flush with the wall plane.

In one example, the present disclosure improves simulations based on the use of digital twins using social automatons. In one example, a method performed by a processing system including at least one processor includes constructing a digital twin of a physical environment, constructing a social automaton, wherein the social automaton comprises a virtual representation of an individual that is programmed to exhibit behaviors and characteristics of the individual, and inserting the social automaton into the digital twin to create an extended reality media in which interactions of the social automaton with the digital twin simulate interactions of the individual with the physical environment.

A method includes: obtaining a reference stereo image from a stereo camera assembly of a mobile computing device; detecting a reference surface from the reference stereo image; determining an inclination angle of the reference surface relative to an output vector of an auxiliary sensor of the mobile computing device; obtaining a first dimensioning stereo image from the stereo camera assembly; detecting the reference surface in the first dimensioning stereo image based on the inclination angle; detecting a first object surface in the first dimensioning stereo image; and generating dimensions of the object based on the first object surface and the reference surface.

A common task when designing computer-aided design (CAD) assemblies is to ensure that the tolerances applied to each component are such that the assembly will function as expected when the parts are made to the extremes of their tolerance zones. The disclosed methods and systems automatically generate dimension and tolerance information for fastened components. Given a source component with dimensions and tolerances, the dimensions and tolerances are automatically applied to mating entities of a target component such that fit is insured without interference when the parts are manufactured at worst case, or at the extremes of their tolerance zones.

Example systems and methods for virtual visualization of a three-dimensional (3D) model of an object in a two-dimensional (2D) environment. The method may include superimposing a first 3D model of an object onto the 2D environment, and replacing the first 3D model of the object with a second 3D model of an object. Further, the method may include superimposing a smart 3D model of an object onto the 2D environment. Additionally, the method may include a code or mark to identify images of the 2D environment to which 3D models of objects have been superimposed.

Methods, systems, apparatuses, and non-transitory computer-readable media are provided for enabling gesture interaction with invisible virtual objects. In one implementation, the computer-readable medium includes instructions to cause a processor to receive image data captured by at least one image sensor of a wearable extended reality appliance in a field of view; display a plurality of virtual objects in a portion of the field of view; receive a selection of a specific physical object; receive a selection of a specific virtual object; dock the specific virtual object with the specific physical object; when the specific physical object and the specific virtual object are outside the portion of the field of view such that the specific virtual object is invisible to a user of the wearable extended reality appliance, receive a gesture input indicating interaction with the specific virtual object; and cause an output associated with the specific virtual object.

The invention relates to a method for representing an environmental region of a motor vehicle in an image, in which real images of the environmental region are captured by a plurality of real cameras of the motor vehicle and the image is generated from these real images, which at least partially represents the environmental region, wherein the image is represented from a perspective of a virtual camera arranged in the environmental region, and the image is generated as a bowl shape, wherein at least one virtual elongated distance marker is represented in the image, by which a distance to the motor vehicle is symbolized in the virtual bowl shape. The invention also relates to a computer program product and a display system for a motor vehicle.

A computing device is configured to obtain gridline information for a three-dimensional drawing file and generate a two-dimensional view of the three-dimensional drawing file that includes (1) at least one gridline corresponding to the obtained gridline information, (2) at least one intersection between two meshes, and (3) initial dimensioning information involving (a) the at least one gridline and (b) at least one of the two meshes. Based on a user request to adjust a perspective of the two-dimensional view, the computing device adjusts the perspective of the two-dimensional view and thereby generates an updated two-dimensional view that includes updated dimensioning information corresponding to one or more meshes displayed in the updated two-dimensional view.