A communication control apparatus includes a generation unit, a receiving unit, a first sending unit configured to cause a first image packet received by the receiving unit to be sent by a first communication interface included in a plurality of communication interfaces, a second sending unit configured to cause a second image packet generated by the generation unit to be sent by the first communication interface at timing that is based on reception of predetermined information included in the first image packet, and a control unit configured to, in a case where the first communication interface has become unable to perform sending during sending of the first image packet or the second image packet from the first communication interface, cause a communication packet including at least the predetermined information to be sent by a second communication interface included in the plurality of communication interfaces.

A first image sensor device is operable to produce first orientation information indicating an orientation of the first image sensor device at a time of capturing a first image of an object. A second image sensor device is operable to produce second orientation information indicating an orientation of the second image sensor device at a time of capturing a second image of the object. The image capturing system further includes measurement hardware to measure a distance between the first image sensor device and the second image sensor device at times of capturing the first image and the second image. According to one configuration, a combination of the first orientation information, the second orientation information, and the distance between the first image sensor device and the second image sensor device is used to derive a 3-D stereo view of the object using the first image and the second image.

A communication apparatus accepts remote control from an external apparatus via wireless communication, and includes a communication unit configured to communicate with the external apparatus, and a control unit configured to execute, in response to an operation request that the communication unit has received from the external apparatus, the request being performed through the remote control, a task corresponding to the operation. The control unit sets a time interval relating to a timing at which communication with the external apparatus is performed, and controls the communication unit to perform communication with the external apparatus in compliance with the set time interval.

A first imaging device and a second image device are connected with each other in a communicatable manner, and data of imaging timing and data of an exposure period of the first imaging device are transmitted to the second imaging device. In the second imaging device, the imaging timing and the exposure period can be set based on the data of the imaging timing and the data of the exposure period which are received. Therefore, an image is taken by the first imaging device and the second imaging device with the imaging timing and the exposure period of the first imaging device agreeing with those of the second imaging device.

Provided is a processing apparatus including a processing unit that is connectable to a data bus, and performs output control on respective images captured by a plurality of image sensors connected to the data bus during a predetermined period of time. A timing of output of the image performed by each of the plurality of image sensors is changed by the output control.

It is provided a method for a computerized, server autonomously producing a TV show of a sports game in a scene. The method includes receiving from several video cameras a stream of video images of the scene for capturing a panoramic view of the scene, analyzing the stream of video images for allowing definition of several frame streams, determining location data of the frame streams accordingly, and rendering an active frame stream with images imaging a respective portion of the panoramic view of the scene. The method includes also transmitting for broadcasting a stream of image frames imaging the respective portion of the panoramic view. The step of analyzing the stream of video images includes identifying a playing object, tracking the playing, object and identifying players. The method also includes calibrating the cameras using points in the playing field. The method may include analyzing the stream of video images for identifying an event in the scene for switching between the active frame stream and a different frame stream. Also, the method may include directing a directed sensor to a region of interest in accordance with location data of the active, frame stream.

A head-mounted display (HMD) is configured to capture images and/or video of a local area. The HMD includes an imaging assembly and a controller. The imaging assembly includes a plurality of cameras positioned at different locations on the HMD and oriented to capture images of different portions of a local area surrounding the HMD. The controller generates imaging instructions for each camera using image information. The imaging instructions cause respective midpoints of exposure times for each camera to occur at a same time value for each of the captured images. The cameras capture images of the local area in accordance with the imaging instructions. The controller determines a location of the HMD in the local area using the captured images and updates a model that represents a mapping function of the depth and exposure settings of the local area.

A first imaging device and a second image device are connected with each other in a communicatable manner, and data of imaging timing and data of an exposure period of the first imaging device are transmitted to the second imaging device. In the second imaging device, the imaging timing and the exposure period can be set based on the data of the imaging timing and the data of the exposure period which are received. Therefore, an image is taken by the first imaging device and the second imaging device with the imaging timing and the exposure period of the first imaging device agreeing with those of the second imaging device.

A method for adjusting exposure of a camera device is provided to include steps of: using first to M.sup.th camera modules to continuously capture images in sync; reducing an exposure value of the first camera module according to a first current image captured at a latest time point by the first camera module until a first condition associated with the first current image is met; adjusting an exposure value of an i.sup.th camera module according to an i.sup.th current image, which is captured at the latest time point by the i.sup.th camera module, and an (i1).sup.th previous image, which is captured at a time point immediately previous to the latest time point by an (i1).sup.th camera module.

A dual-aperture camera comprising a first camera having a first sensor and a first image signal processor (ISP), the first camera operative to output a first stream of frames, a second camera having a second sensor and a second ISP, the second camera operative to output a second stream of frames, and a synchronization and operation control module configurable to control operation of one camera in a fully operational mode and operation of the other camera in a partially operational mode and to output an output of the fully operational camera as a dual-aperture camera output, whereby the partially operational mode of the other camera reduces a dual-aperture camera the power consumption in comparison with a full operational mode of the other camera.