An apparatus comprises: a camera module for obtaining a first image, the camera module having at least one port, each of the at least one ports being associated with an attachment position for receiving a second camera module for obtaining a second image; a processor for detecting a position of a second camera module and providing, to an image processing controller, information relating to at least one of the position of the second camera module and the first image obtained by the camera module; and a memory for storing the information relating to at least one of the position of the second camera module and the first image obtained by the camera module.

An image capture device may switch operation between a spherical capture mode or a non-spherical capture mode. Operation of the image capture device in the spherical capture mode includes generation of spherical visual content based on the visual content generated by multiple image sensors. Operation of the image capture device in the non-spherical capture mode includes generation of non-spherical visual content based on visual content generated by a single image sensor.

An image capture device may switch operation between a spherical capture mode or a non-spherical capture mode. Operation of the image capture device in the spherical capture mode includes generation of spherical visual content based on the visual content generated by multiple image sensors. Operation of the image capture device in the non-spherical capture mode includes generation of non-spherical visual content based on visual content generated by a single image sensor.

Aspects of the present invention relate to methods and systems for the see-through computer display systems with adjustable-zoom cameras positioned such that their respective capture fields-of-view at least partially overlap at a target distance.

A frame for a low parallax imaging device includes a plurality of interconnected faces configured to mount cameras. The faces are mounted along peripheral edges using kinematic connections. The frame provides a structure on which the mounted cameras provide a combined field of view of up to about 360-degrees with minimal parallax between adjacent cameras.

A frame for a low parallax imaging device includes a plurality of interconnected faces configured to mount cameras. The faces are mounted along peripheral edges using kinematic connections. The frame provides a structure on which the mounted cameras provide a combined field of view of up to about 360-degrees with minimal parallax between adjacent cameras.

The embodiments of the present application relates to a camera, comprising a first housing, a stitching lens mechanism, and a driving assembly. The stitching lens mechanism is mounted in the first housing, and the stitching lens mechanism comprises at least two first assemblies, the first lens assembly comprises a first lens, a first included angle is formed between at least two first lenses. A driving assembly is connected to the first lens assembly through a rotating assembly. At least two first lenses are distributed in a first plane, the first housing is rotatably arranged in a second plane, and the second plane is perpendicular to the first plane. Each of the first lens assemblies takes pictures in different orientations for the same scene, so that the imaging field of view is larger. So that the first housing can rotate under the drive of the driving assembly, that is, the stitching lens mechanism can rotate. Compared with the existing stitching camera with a fixed structure, the imaging field of view of the camera of the present application is larger. That is, the camera of the present application can further expand the range of the imaging field of view compared to the existing camera.

An electronic device comprising: an acquisition unit configured to acquire an image set including a first image and a second image which have parallax from each other; and a control unit configured to perform control such that 1) in a case of a first display mode where the first image is to be displayed without displaying the second image, the first image is displayed on a display with an orientation of the first image being corrected to be directed to be in a predetermined orientation, and 2) in a case of a second display mode where both the first image and the second image are to be displayed, the first image and the second image are displayed on the display without an orientation of the first image and the second image being corrected to be directed to be in the predetermined orientation.

An electronic device comprising: an acquisition unit configured to acquire an image set including a first image and a second image which have parallax from each other; and a control unit configured to perform control such that 1) in a case of a first display mode where the first image is to be displayed without displaying the second image, the first image is displayed on a display with an orientation of the first image being corrected to be directed to be in a predetermined orientation, and 2) in a case of a second display mode where both the first image and the second image are to be displayed, the first image and the second image are displayed on the display without an orientation of the first image and the second image being corrected to be directed to be in the predetermined orientation.

The present technology relates to an information processing device and an information processing method capable of implementing video projection using a plurality of projection devices more reliably. There is provided an information processing device including a control unit configured to detect a manipulation of a user on a designator projected to a projection area of each of a plurality of projection devices and generate relative position information regarding relative positions of the plurality of projection areas based on a detection result. The present technology can be applied to, for example, a device controlling a plurality of projectors.