A video signal processing apparatus according to an embodiment includes a controller. The controller receives (i) a plurality of video signals from a plurality of video sources including a camera and (ii) a specifying signal that specifies which one of the video signals is to be output to a display apparatus. The controller changes a wait time from an input of the specifying signal to an output of the video signal specified by the specifying signal to the display apparatus based on which one of the plurality of the video sources corresponds to the video signal specified by the specifying signal.

Automatic exposure control of an in-vehicle camera is performed under dark driving environments such as at night. An in-vehicle camera system includes a vehicle camera mounted in a vehicle configured to capture surroundings of the vehicle, and control circuitry that controls an exposure level of an image captured by the vehicle camera, the control of the exposure level being based on brightness information of a detection area set within the image, the detection area being a portion of the captured image and configured to output the image having exposure control performed thereon to a display.

An apparatus for monitoring the blind spot of a motor vehicle has a mirror assembly with at least one mirror element that can be moved using an actuator, and a microphone assembly. The microphone assembly is designed to determine the sound direction, and the movable mirror element is in the form of a sound reflector.

A display control device displays, on an electronic inner mirror, a composite image composited by performing image processing on a rear image captured by a rear camera and rear lateral images captured by an outer camera unit such that the rear image and the rear lateral images become a continuous image. A subject vehicle virtual image superimposition display unit of the display control device generates a virtual image of a subject vehicle virtually showing a subject vehicle and displays the virtual image of the subject vehicle superimposed on the composite image. A subject vehicle travel trajectory superimposition display unit of the display control device generates a virtual image of travel trajectory, which extends from left and right rear wheels toward the rear of the vehicle in the composite image, and displays the virtual image of travel trajectory superimposed on the composite image.

There is disclosed a viewing system coupled to a motor vehicle having a frame having a roof, at least one support, and a body with the at least one support supporting the roof over the body. The system can comprise at least one camera, at least one screen coupled to the support. In addition each camera is coupled to the at least one support and wherein said at least one screen is in communication with the first set of cameras, wherein said at least one screen displays images presented by the first set of cameras. This device can provide additional view in the blind spot of the vehicle.

A method for providing a panoramic view (152) of an environment behind a trailer (106) of a vehicle-trailer system (100). The method includes receiving a first image (133, 133b) from a rear trailer camera (132, 132b), a second image (133, 133c) from a right-side trailer camera (132, 132c), and a third image (133, 133d) from a left-side trailer camera (132, 132d). The method includes determining a panoramic view (152) based on the first image (133, 133b), the second image (133, 133c), and the third image (133, 133d). Additionally, the method includes determining a trailer angle (α) based on sensor system data (131) received from a sensor system (130). The method includes determining a viewing area (154) within the panoramic view (152) based on the trailer angle (α) and sending instructions (156) to a display (122) to display the viewing area (154).

An imaging device includes a plurality of pixels that receives incident light entering from an object after passing through neither an imaging lens nor a pinhole, and each outputs a detection signal indicating an output pixel value modulated in accordance with an incident angle of the incident light. The imaging device is attached to a vehicle so that a light receiving surface faces a side of the vehicle, and the average of the centroids of incident angle directivities indicating directivities of the plurality of pixels with respect to the incident angle of the incident light deviates in one direction from the center of the pixel. The present technology can be applied to an electronic sideview mirror, for example.

A rearward camera of a vehicle electronic mirror system images a rearward view of a vehicle, and a lateral rearward camera unit images each of right and left lateral rearward views of the vehicle. A control device compresses at least one of a rearward view picture after imaging by the rearward camera and right and left lateral rearward view pictures after imaging by the lateral rearward camera unit, at least in a vehicle-width direction, and performs display on an inner mirror display. The control device changes the compression ratio of the picture in the control device, depending on at least one of a state and peripheral situation of the vehicle. Accordingly, when a vehicle rearward side including lateral rearward sides contains a site requiring an easy distance-sense grasp, it is possible to easily grasp distance sense by decreasing the compression ratio of the picture corresponding to the site.

A vehicular camera monitoring system includes a pair of rearward viewing cameras disposed at a vehicle with overlapping fields of view. A driver-monitoring camera is disposed at the vehicle. An ECU includes an image processor that processes image data captured by the driver-monitor camera and the rearward viewing cameras. A stereographic video display screen is disposed at the vehicle and viewable by the driver of the vehicle. Responsive to processing of image data captured by the driver-monitoring camera, the ECU determines location of each eye of the driver of the vehicle. Responsive to processing of image data captured by each of the rearward viewing cameras, the stereographic video display screen displays video images derived at least in part from image data captured by both rearward viewing cameras and provides depth perception to the driver of the vehicle viewing the displayed video images.

A vehicular camera monitoring system a driver-side camera, a driver-side video display screen disposed at a driver-side cabin region of an interior cabin of the vehicle, a passenger-side camera and a passenger-side video display screen disposed at a passenger-side cabin region of the interior cabin of the vehicle. During a parking maneuver or parking-space exit maneuver of the vehicle, the driver-side video display screen displays parking assist images derived from image data captured by the driver-side camera and the passenger-side video display screen displays parking assist images derived from image data captured by the passenger-side camera. Upon completion of the parking-space exit maneuver where the vehicle exits a parking space, the driver-side and passenger-side video display screens automatically operate to display driving assist video images derived from image data captured by the respective side camera, with the displayed driving assist video images being different from the displayed parking assist images.