An image pickup apparatus comprising: an image pickup unit; a display unit; a display control unit; an object image detection unit; a distance information acquisition unit; and a binocular vision suitability determination unit, wherein the display control unit displays a second guide frame of a larger size than the first guide frame on the display unit in addition to the first guide frame, and, in a case where the object image detection unit detects at least one other object image different from the object image determined to be suitable for the binocular vision by the binocular vision suitability determination unit from the second guide frame, the display control unit matches the second guide frame to the at least one other object image.

A system for performing depth-based scaling of 3D content. The system comprises: 1) a content source configured to provide an input image comprising a plurality of input image objects; and 2) a processor configured to receive the input image and to receive a depth map comprising depth data associated with each of the plurality of input image objects. The processor generates an output image comprising a plurality of output image objects, wherein each of the plurality of output image objects corresponding to one of the plurality of input image objects. The processor scales a size of a first output image object relative to the size of a second output image object based on depth data associated with the first output image object and the second output image object.

An image processing apparatus is provided, that is configured to: extract a first pixel value corresponding to a first viewpoint that is one of a plurality of viewpoints to capture a subject image, at a target pixel position from image data having the first pixel value; extract second and third luminance values corresponding to second and third viewpoints that are different from the first viewpoint, at the target pixel position from luminance image data having the second and third luminance values; and calculate at least any of second and third pixel values of the second and third viewpoints such that a relational expression between the second or third pixel value and the first pixel value extracted by the pixel value extracting unit remains correlated with a relational expression defined by the second and third luminance values.

A main body of a camera accommodates a light receiving part. The main body has a flat bottom surface. A support is aligned with the main body in a left-right direction, and supports the main body in such a manner that an orientation of the light receiving part can be controlled in a vertical direction. A bottom surface of the support is located on a common plane on which a bottom surface of the main body is also located. The bottom surface of the support can be attached to and detached from a stand member which is mounted to a display device. This camera promises enhanced stability of mounting of the camera to an edge of a display device.

A method for three-dimensional imaging is provided, storing a first two-dimensional image of field of view of a scanning device at a first position where a first three-dimensional view of the object is captured with said handheld scanning device; estimating location metric of a second two-dimensional image of field of view of said scanning device at a second position relative to said first image while said scanning device is being moved from said first position to said second position; and generating instructions on providing feedback to the user based on said location metric; wherein said feedback is provided to indicate if said second position is adequate for capturing a second three-dimensional view. A system for three-dimensional imaging is provided as well.

Various embodiments of the present invention relate generally to systems and methods for analyzing and manipulating images and video. According to particular embodiments, the spatial relationship between multiple images and video is analyzed together with location information data, for purposes of creating a representation referred to herein as a surround view. In particular embodiments, a surround view can be generated by combining a panoramic view of an object with a panoramic view of a distant scene, such that the object panorama is placed in a foreground position relative to the distant scene panorama. Such combined panoramas can enhance the interactive and immersive viewing experience of the surround view.

Near real-time imagery of a given location may be provided to user upon request. Most popularly viewed geographic locations are determined, and a 360 degree image capture device is positioned at one or more of the determined locations. The image capture device may continually provide image information, which is processed, for example, to remove personal information and filter spam. Such image information may then be provided to users upon request. The image capture device continually captures multiple views of the given location, and the requesting user can select which perspective to view.

A perspective-correct communication window system and method for communicating between participants in an online meeting, where the participants are not in the same physical locations. Embodiments of the system and method provide an in-person communications experience by changing virtual viewpoint for the participants when they are viewing the online meeting. The participant sees a different perspective displayed on a monitor based on the location of the participant's eyes. Embodiments of the system and method include a capture and creation component that is used to capture visual data about each participant and create a realistic geometric proxy from the data. A scene geometry component is used to create a virtual scene geometry that mimics the arrangement of an in-person meeting. A virtual viewpoint component displays the changing virtual viewpoint to the viewer and can add perceived depth using motion parallax.

A blended optical device includes a first objective with a first axis and a first image position adjustment means for adjusting the position of a first image. An electronic control circuitry is configured to control the first adjustment means to adjust a position of the first image. A second objective includes a second axis and a variable focus mechanism, and a blender configured to form a blended image from the first image and a second image. The electronic control circuitry is configured to receive data from the second objective regarding a range to a target of the second objective as a function of the focus setting, and to adjust the position of the first image so that the blended image is corrected for parallax errors.

A three-dimensional information reconstraction device includes a corresponding point detector that detects a plurality of corresponding point pairs to which a first feature point included in a first image captured by a first image capturing device and a second feature point included in a second image captured by a second image capturing device correspond, and a three-dimensional coordinate deriver that, based on the plurality of corresponding point pairs, reconstructs three-dimensional coordinates to which the first feature point is inverse-projected.