A method for reconstructing a three-dimensional space scene based on photographing is disclosed, comprising the following steps: S1, importing photos of all spaces, and making the photos correspond to a three-dimensional space according to directions and viewing angles during capture, so that a viewing direction of each pixel, when viewed from the camera position of the three-dimensional space, is in line with that during capture; S2, regarding a room as a set of multiple planes, determining a first plane, and then determining all the planes one by one according to relationships and intersections between the planes; S3, marking a spatial structure of the room by a marking system and obtaining dimension information; and S4, establishing a three-dimensional space model of the room by point coordinate information collected in the step S3. In the present disclosure, the three-dimensional space model of a scene including dimensions and texture can be restored with no details lost; meanwhile, the three-dimensional space scene can be edited and modified quickly and conveniently, and a two-dimensional floor plan with dimensions and adequate accuracy can also be generated.

Disclosed are systems and methods for visualizing workplace layout safety. A data structure of a workplace layout is processed to identify workplace objects and determine their respective locations. Likely locations of individuals are determined, corresponding to locations of the workplace objects. Safety parameters indicative of a required minimum separation between individuals are received, and a 3D model representation of the workplace layout is generated with a plurality of safety zones, each of the safety zones having a location corresponding to one of the likely locations of individuals in the workplace layout, and having a size corresponding to the safety parameter. Interference between at least two of the safety zones is determined, and a visual representation of the workplace layout is generated using the 3D model representation with a first visual indicator indicative of the safety zones, and a second visual indicator indicative of the determined interference between safety zones.

An object management system, an aircraft design system, and a method for managing an object. A three-dimensional environment with a model of an object and an avatar representing a human operator from a viewpoint relative to the avatar is displayed on a display system. A motion of the human operator is detected. An interaction between the avatar and the model of the object is identified in real time using information about motions of the human operator that are detected in real time. The interaction changes a group of dimensions in the model of the object. Further, the interaction between the avatar and the model of the object in the three-dimensional environment is displayed on the display system, enabling design changes in the model of the object made by the human operator.

An example computing system is configured to extract gridline information from a two-dimensional drawing file and determine, for the gridline information, first coordinate information that is based on a first datum. The computing system converts the first coordinate information into second coordinate information that is based on a second datum, where the second coordinate information is used by a three-dimensional drawing file. The computing system is also configured to receive a request to generate a two-dimensional view of the three-dimensional drawing file, where the two-dimensional view includes an intersection of two meshes within the three-dimensional drawing file. The computing device generates the two-dimensional view of the three-dimensional drawing file and adds, to the generated two-dimensional view, (i) at least one gridline corresponding to the gridline information and (ii) dimensioning information involving the at least one gridline and at least one of the two meshes.

A boundary surface setting section sets the boundary surface for delimiting a permissible region that is the region which is located inside the real space and in which the user wearing a head-mounted display is permitted to exist and an impermissible region that is the region which is located inside the real space and in which the user is not permitted to exist. A display control section causes a portion or a whole of a virtual object representing the boundary surface to be displayed on the head-mounted display. The boundary surface includes a first boundary line having a first height and a second boundary line having a second height, and a portion or all of the first boundary line is different from the second boundary line.

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.

Methods, systems, apparatuses, and computer-readable media are provided for moving a virtual cursor along two traversing virtual planes. In one implementation, the computer-readable medium includes instructions to cause a processor to generate, via a wearable extended reality appliance, a display including a virtual cursor and virtual objects located on a first virtual plane that traverses a second virtual plane overlying a physical surface; receive a first two-dimensional input reflective of an intent to select a first virtual object located on the first virtual plane; cause a first cursor movement, toward the first virtual object, along the first virtual plane; receive a second two-dimensional input reflective of an intent to select a second virtual object appearing on the physical surface; and cause a second cursor movement, toward the second virtual object, including a partial movement along the first virtual plane and a partial movement along the second virtual plane.

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.

A method for designing a part member of a custom-made furniture includes: producing a rectangular parallelepiped part member in a rectangular parallelepiped space; setting a XY coordinate system on six faces of the rectangular parallelepiped space using a corner of a rectangle of each face as an origin and two sides of a rectangle of each face as X axis and Y axis; setting one or more predetermined rules for determining positions of one or more machinings based on lengths p and q from a corner of the rectangle and designating a XY coordinate positions of the one or more machinings as a function of p and q; altering the dimensions of the rectangular parallelepiped space of the part member; calculating the positions of the machinings after the dimensions of the rectangular space are altered in accordance with the predetermined rules; and outputting the machining specification.

A method includes receiving data characterizing a target surface extending in three dimensions. The method also includes rendering in a graphical user interface display space, a first visual representation including a two-dimensional image of a first portion of the target surface, and a second visual representation including a three-dimensional representation of at least a subset of the first portion of the target surface included in the first visual representation. The method further includes receiving, based on a first user interaction with the three-dimensional representation via a cursor configured to move over the three-dimensional representation, a first user input indicative of selection of a first location of the target surface. The method also includes rendering a first graphical object at a first target position in the three-dimensional representation and a second graphical object at a second target position in the two-dimensional image. The first and the second target positions are indicative of the first location of the target surface.