A third imaging unit including a pixel not having a polarization characteristic is interposed between a first imaging unit and a second imaging unit including a pixel having a polarization characteristic for each of a plurality of polarization directions. A depth map is generated from a viewpoint of the first imaging unit by matching processing using a first image generated by the first imaging unit and a second image generated by the second imaging unit A normal map is generated on the basis of a polarization state of the first image. Integration processing of the depth map and the normal map is performed and a depth map with a high accuracy is generated. The depth map generated by the map integrating unit is converted into a map from a viewpoint of the third imaging unit, and an image free from deterioration can be generated.

A system for capturing horizontal disparity stereo panorama is disclosed. The system includes a multi surface selective light reflector unit, a secondary reflector and a computing unit. The multi surface selective light reflector unit (a) obtains light rays from a 3D scene of outside world that are relevant to create (i) a left eye panorama and (ii) a right eye panorama and (b) reflects the light rays without internal reflections between the light rays. The secondary reflector (a) obtains the reflected light rays from the multi surface selective light reflector unit and (b) reflects the light rays through the viewing aperture. The computing unit captures (i) the reflected light rays from the secondary reflector and (ii) the upper part of the 3D scene from a concave lens as a warped image and processes the warped image to (a) the left eye panorama and (b) the right eye panorama.

A system and method for creating a 3D virtual model of an event, such as a wedding or sporting event, and for sharing the event with one or more virtual attendees. Virtual attendees connect to the experience platform to view the 3d virtual model of the event on virtual reality glasses, i.e. a head mounted display, from a virtual gallery, preferably from a user selected location and orientation or a common location and orientation for all virtual attendees. In one form the virtual attendees can see and interact with other virtual attendees in the virtual gallery.

A stereo image generating method and an electronic apparatus utilizing the method are provided. The electronic apparatus includes a first camera and a second camera capable of capturing stereo images, and a resolution of the first camera is larger than that of the second camera. In the method, a first image is captured by the first camera, and a second image is captured by the second camera. The second image is upscaled to the resolution of the first camera, and a depth map is generated with use of the first image and the upscaled second image. With reference to the depth map, the first image is re-projected to reconstruct a reference image of the second image. An occlusion region in the reference image is detected and compensated by using the upscaled second image. A stereo image including the first image and the compensated reference image is generated.

A system for acquiring a sequence of image frames for display having depth perception through motion parallax includes a base unit, a stage unit, and a camera unit. The stage unit is disposed over the base unit and is configured to rotate, with respect to the base unit, about an axis of rotation, and is configured to hold the camera element thereon at a predetermined offset, as measured from the axis of rotation to a no-parallax point or least-parallax point of the camera element. The camera element is configured to acquire a sequence of image frames, as it is rotated about the axis of rotation by the stage unit and is kept at the predetermined offset, and is configured to acquire the sequence of image frames during the rotation. The predetermined offset is a positive distance value.

Apparatuses, methods and storage media for providing a depth image of an object are described. In some embodiments, the apparatus may include a projector to project a light pattern on an object, and to move the projected light pattern over the object, to swipe the object with the light pattern, and a camera coupled with the projector. The camera may include a dynamic vision sensor (DVS) device, to capture changes in at least some image elements that correspond to an image of the object, during the swipe of the object with the light pattern. The apparatus may further include a processor coupled with the projector and the camera, to generate a depth image of the object, based at least in part on the changes in the at least some image elements. Other embodiments may be described and claimed.

In on the general aspect, a camera rig can include a first tier of images sensors including a first plurality of image sensors where the first plurality of image sensors are arranged in a circular shape and oriented such that a field of view of each of the first plurality of image sensors has an axis perpendicular to a tangent of the circular shape. The camera rig can include a second tier of image sensors including a second plurality of image sensors where the second plurality of image sensors are oriented such that a field of view of each of the second plurality of image sensors has an axis non-parallel to the field of view of each of the first plurality of image sensors.

A stereo camera device with tilted fields of view is provided, which includes a pair of camera devices located such that respective fields of view (FOVs) of the pair of camera devices are tilted away from each other, and at least partially overlapping in a common working FOV. The device further includes a processor which receives respective images from each of the pair of camera devices, combines respective portions of the respective images corresponding to the common working FOV into stereo images.

An image detecting device includes a color image sensor configured to sense visible light and to output color image data based on the sensed visible light; a first infrared lighting source configured to provide first infrared rays to a subject; a second infrared lighting source configured to provide second infrared rays to the subject; a mono image sensor configured to sense a first infrared light or a second infrared light reflected from the subject and output infrared image data; and an image signal processor configured to, measure an illuminance value based on the color image data, measure a distance value of the subject based on a portion of the infrared image data corresponding to the first infrared light, and obtain an identification image of the subject based on the illuminance value, the distance value, and a portion of the infrared image data corresponding to the second infrared light.

According to an aspect of an embodiment, a method may include obtaining a first digital image that depicts a first aerial view of a first area of a setting. The method may additionally include obtaining a second digital image that depicts a second aerial view of a second area of the setting. Further, the method may include determining an overlapping area where the first area and the second area overlap and obtaining a third digital image based on the overlapping area, the first digital image, and the second digital image. In addition, the method may include generating a stereoscopic image of the setting based on the first digital image and the third digital image.