An imaging system includes first and second light source devices configured to irradiate a subject with lights having different wavelength bands, first and second imaging devices configured to image the subject, and first and second video processing devices configured to process an imaged video of the subject imaged by either of the corresponding imaging devices and to output the processed video to an output unit. The first and second light source devices alternately perform lighting in synchronization with a frame period of the imaged video or an integer multiple thereof based on a genlock signal. The first imaging device performs imaging in synchronization with the lighting of each of the first and second light source devices. The second imaging device performs imaging in synchronization with the lighting of each of the first and second light source devices.

An image capture apparatus acquires exposure delay times and communication delay times of respective other image capture apparatuses, the exposure delay times being information of times from when the other image capture apparatuses receive a shooting command until when the other image capture apparatuses start exposure, the communication delay times being information of times required in communication with the other image capture apparatuses, and determines a common delay time based on the acquired communication delay times and exposure delay times of the respective other image capture apparatuses, the common delay time being delay time information that is common to all of the other image capture apparatuses, and upon accepting a shooting instruction, transmits the shooting command including a common timing obtained from the common delay time to the other image capture apparatuses.

Multiple image capture devices may individually generate time information and capture images. Individual image captures devices may receive time information of other image capture device(s). Individual image capture devices may transmit its time information to other image capture device(s) independent of reception of the time information of other image capture device(s). Individual image capture devices may generate time synchronization information for the captured images based on its time information and the received time information of other image capture device(s). Images captured by different image capture devices may be time-synchronized based on at least one of generated time-synchronization information.

An apparatus and method are provided for viewing panoramic images and videos through the selection of a particular viewing angle and window (zoom) within that panorama while allowing the viewer to simultaneously implement temporal transport control, allowing the video to be in a state of pause, play, fast forward, fast rewind, slow forward, slow rewind, or frame-by-frame. This capability may be used on video that is residing in memory on the viewer's viewing system, in a hard disk local to the viewer or in a shared location, or on a live buffered feed of video. A second capability of this apparatus and method relates to the use of a plurality of panoramic video or images from multiple synchronized cameras. In those cases, all panoramic video feeds are synchronized so that as a viewer pauses, rewinds, forwards a video in one panorama, all panoramas are time synchronized and go through the same states as the panorama being viewed. When the user selects a different panorama for viewing from a different camera, this panorama comes up in the same state as the panorama previously being viewed.

An initialization method for initializing a transfer of a recording image data stream from an image sensor of an image recording apparatus to a display unit, wherein initially a display image data stream in the form of a test image is transferred from an image processing apparatus to the display unit and a recording image data stream is transferred from an image recording apparatus to the image processing apparatus. A changeover of a reproduction on the display unit to the recording image data stream is preceded by a correction value being calculated for a phase shift between the display image data stream and the recording image data stream and being transferred to the image recording apparatus, and the recording image data stream is phase-shifted by the correction value. Subsequently the display image data stream is changed over to the recording image data stream (21) and the image recorded by the image sensor or the sequence of images is reproduced with the display unit.

A method implemented on a computing device including at least one processor and a storage for synchronizing video transmission with physical layer. The method includes determining a first time point corresponding to a frame header of a video frame, determining a second time point corresponding to a frame header of a physical layer frame based at least in part on the first time point, and starting transmitting the video frame at the second time point.

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.

Multiple image capture devices may individually generate time information and capture images. Individual image captures devices may receive time information of other image capture device(s). Individual image capture devices may transmit its time information to other image capture device(s) independent of reception of the time information of other image capture device(s). Individual image capture devices may generate time synchronization information for the captured images based on its time information and the received time information of other image capture device(s). Images captured by different image capture devices may be time-synchronized based on at least one of generated time-synchronization information.

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 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.