A method for estimating tightly enclosing bounding boxes by a computing system includes: controlling a scanning system including one or more depth cameras to capture visual information of the scene including one or more objects; detecting the one or more objects of the scene based on the visual information; singulating each the one or more objects from the frame of the scene to generate one or more 3D models corresponding to the one or more objects, the one or more 3D models including a partial 3D model of a corresponding one of the one or more objects; extrapolating a more complete 3D model of the corresponding one of the one or more objects based on the partial 3D model; and estimating a tightly enclosing bounding box of the corresponding one of the one or more objects based on the more complete 3D model.

A method for estimating tightly enclosing bounding boxes by a computing system includes: controlling a scanning system including one or more depth cameras to capture visual information of the scene including one or more objects; detecting the one or more objects of the scene based on the visual information; singulating each the one or more objects from the frame of the scene to generate one or more 3D models corresponding to the one or more objects, the one or more 3D models including a partial 3D model of a corresponding one of the one or more objects; extrapolating a more complete 3D model of the corresponding one of the one or more objects based on the partial 3D model; and estimating a tightly enclosing bounding box of the corresponding one of the one or more objects based on the more complete 3D model.

The focus detection accuracy is improved in an imaging apparatus that detects focus of each of a plurality of lenses. A main side focus control section detects, as a main side in-focus position, a main side lens position where focus is achieved in a main side detection region inside a main side image. A parallax acquisition section acquires parallax proportional to a distance by finding the distance on the basis of the main side in-focus position. A subordinate side detection region setup section sets a subordinate side detection region position in a subordinate side image on the basis of the parallax and the main side detection region position. A subordinate side focus control section detects, as a subordinate side in-focus position, a subordinate side lens position where focus is achieved in the subordinate side detection region.

The focus detection accuracy is improved in an imaging apparatus that detects focus of each of a plurality of lenses. A main side focus control section detects, as a main side in-focus position, a main side lens position where focus is achieved in a main side detection region inside a main side image. A parallax acquisition section acquires parallax proportional to a distance by finding the distance on the basis of the main side in-focus position. A subordinate side detection region setup section sets a subordinate side detection region position in a subordinate side image on the basis of the parallax and the main side detection region position. A subordinate side focus control section detects, as a subordinate side in-focus position, a subordinate side lens position where focus is achieved in the subordinate side detection region.

There is provided an information processing apparatus, an information processing method, and a program, the information processing apparatus including: a control unit that determines a display method for an object in a virtual space on a basis of a positional relationship between the object and a viewpoint. A binocular parallax regarding the object which is to be imparted to a user varies depending on the determined display method.

There is provided an information processing apparatus, an information processing method, and a program, the information processing apparatus including: a control unit that determines a display method for an object in a virtual space on a basis of a positional relationship between the object and a viewpoint. A binocular parallax regarding the object which is to be imparted to a user varies depending on the determined display method.

A three-dimensional (3D) forensic evidence system is provided. The system includes a noncontact measurement device operable to measure a distance from the device to a surface. A first camera is operably coupled to the noncontact measurement device, the first camera having a field of view. A light source is operably coupled to the first camera and operable to emit light onto the surface within the field of view. A processor operably is coupled to the first camera, the processor operable to execute computer instructions when executed on the processor for determining 3D coordinates of at least one point in the field of view based at least in part on the distance, and assigning at least one color value to the at least one point in response to determining an interaction of a predefined wavelength of light with a substance in the field of view.

The present disclosure generally discloses a three-dimensional (3D) image reconstruction capability. The 3D image reconstruction capability may be configured to support reconstruction of a 3D image of a scene. The 3D image reconstruction capability may be configured to support reconstruction of a 3D image of a scene based on lensless compressive image acquisition performed using a lensless compressive camera having a single aperture and a set of multiple sensors. The reconstructed 3D image of a scene may include (1) image data indicative of a set of multiple two-dimensional (2D) images reconstructed based on the set of multiple sensors of the lensless compressive camera (which may be represented as images) and (2) depth information indicative of depths at points or areas of an overlapping portion of the multiple images reconstructed based on the set of multiple sensors of the lensless compressive camera (which may be represented as a depth map).

The present disclosure generally discloses a three-dimensional (3D) image reconstruction capability. The 3D image reconstruction capability may be configured to support reconstruction of a 3D image of a scene. The 3D image reconstruction capability may be configured to support reconstruction of a 3D image of a scene based on lensless compressive image acquisition performed using a lensless compressive camera having a single aperture and a set of multiple sensors. The reconstructed 3D image of a scene may include (1) image data indicative of a set of multiple two-dimensional (2D) images reconstructed based on the set of multiple sensors of the lensless compressive camera (which may be represented as images) and (2) depth information indicative of depths at points or areas of an overlapping portion of the multiple images reconstructed based on the set of multiple sensors of the lensless compressive camera (which may be represented as a depth map).

Provided is an image that is comfortably viewed and operated by a user. An electronic device acquires user information related to a relative position between a user and a display unit. Then, the electronic device transmits the user information to an information processing device. The information processing device includes a communication unit and a control unit. The communication unit receives the user information related to the relative position of the user and a display unit which is acquired by the electronic device from the electronic device. Further, the control unit performs control to decide a display mode of an image transmitted from a source device on the display unit on the basis of the user information received from the electronic device.