A photographic scene replacement system includes a photographic scene with a detectable pattern. The system operates to capture a digital photograph of a subject and the photographic scene having the detectable pattern with a digital camera when the subject is arranged between the digital camera and the photographic scene. The system also operates to process the digital photograph at least in part by automatically detecting the detectable pattern in the digital photograph, to distinguish the subject from the photographic scene in the digital photograph.

An image pickup apparatus includes a light emission unit configured to be able to move to light emission and non-light emission positions, an operation unit operable by a user, and a display control unit configured to display a setting screen related to the light emission unit, in which the first light emission unit is configured to move from the non-light emission position to the light emission position upon operation of the operation unit when the first light emission unit is located at the non-light emission position and configured not to move from the light emission position to the non-light emission position upon operation of the operation unit when the first light emission unit is located at the light emission position, and the display control unit is configured to display the first setting screen upon operation unit when the first light emission unit is located at the light emission position.

A digital camera includes an optical assembly and image sensor for capturing still and/or video images and displaying the images on a rear display screen. The camera includes a magnifying viewfinder that is coupled to the housing and is movable between a stowed position out of the way of the display screen and an active position for viewing a subset of display screen pixels with magnification.

A system and method for controlling and selecting sources in a room on a network. The system allows a remote viewer to create a virtual presence within the room by providing the available displays, corresponding to the sources, to the remote viewer. The system includes a standardizing technique for improving the communication and overall switching of data for streaming on a network. The system can include a recording server for performing dual recording of the video files in each of a local database and a remote database. A graphical user interface (GUI) display is provided to guide a local user through a medical procedure in the standardized system.

The present invention relates to a method for controlling a lighting device to produce user customisable lighting effects, the method comprising: calculating a time varying lighting value based on at least one simulation parameter; and outputting said time varying lighting value thereby to simulate a lighting effect. The invention also relates to a controller for controlling a lighting device to produce a lighting effect, the controller comprising: a calculating device adapted to calculate a time varying lighting value based on at least one simulation parameter; and an output adapted to control a lighting device according to the determined variation of lighting over time. In a further aspect of the present invention there is provided a light with the built-in capability to generate a range of customizable cinematic special lighting effects, by modulating the speed, duration, power/brightness, and/or colour temperature of the light output.

An imaging system that is translucent can be achieved by placing an image sensor (204) at one of more edges or periphery of a translucent window (202). A small fraction of light from the outside scene scatters off imperfections (218) in the translucent window (202) and reach the peripheral image sensor (204). Based on appropriate calibration of the response of point sources (206) from the outside scene, the full scene can be reconstructed computationally from the peripherally scattered light (210, 212). The technique can be extended to color, multi-spectral, light-field, 3D, and polarization selective imaging. Applications can include surveillance, imaging for autonomous agents, microscopy, etc.

A system for motion control is presented. In one embodiment, a motion control 3D projection system includes a projector; and a projection surface coupled to a robotic arm, where the robotic arm moves the projection surface through a set of spatial coordinates, and a 3D projection from the projector is projected onto a set of coordinates of the projection surface and matches the 3D projection to the set of coordinates of the projection surface as the projection surface moves through the set of spatial coordinates. In additional embodiments, a master control system may integrate additional robotic arms and other devices to create a motion control scene with a master timeline.

An imaging apparatus includes an imaging optical system, an imaging element acquiring an image of an object, a unit that acquires distance information corresponding to distance between the imaging optical system and the object, a unit that generates a map information corresponding to the image based on the distance information, a unit that is able to detect touch operation of a user on a display unit displaying the image and that detects a position in the image corresponding to a position touched by the user, and a control unit configured to acquire the distance information at the position of the acquired image from the map information to set the position as a focus point according to the acquired distance information, or configured to display, on the display unit, an enlarged image obtained by cutting an area of part of the image including the position.

An imaging apparatus includes a reading unit, a display unit, and a control unit. The reading unit reads pixel signals from imaging pixels and focus detection pixels. The display unit displays an image. When both exposure/reading of the imaging pixels and the focus detection pixels are achievable within time corresponding to a display frame rate of the display unit, the control unit controls to alternate the exposure/reading of the imaging pixels and the exposure/reading of the focus detection pixels. When both the exposure/reading of imaging pixels and the focus detection pixels are not achievable within the time, the control unit controls to perform the exposure of the imaging pixels and the focus detection pixels at the same time and read the pixel signals of the imaging pixels and the focus detection pixels after the end of the exposure of the imaging pixels and the focus detection pixels.

An information processing apparatus includes a control unit that performs first control processing of deciding an analysis engine for scene detection from among a plurality of analysis engines on the basis of scene detection information for scene detection with respect to an input video, and second control processing of deciding an analysis engine for obtaining second result information related to the scene from among a plurality of analysis engines, on the basis of scene-related information regarding a scene obtained as first result information by the analysis engine decided in the first control processing.