The present disclosure relates to a controller for generating a composite image (IMG3) of a region behind a towing vehicle (V). The controller is operable to receive a towing vehicle image data (DV1) from a towing vehicle camera (C1); and a trailer image data (DV2) from a trailer camera (C2). The controller combines the towing vehicle image data (DV1) and the trailer image data (DV2) to generate a composite image data (DV3) corresponding to a composite image (IMG3). The controller is operable to output the composite image data (DV3). The controller is operable selectively to enable and/or disable the output of the composite image data (DV3). The controller is configured to monitor a status of a turn signal indicator. The controller is configured to disable the output of the composite image data (DV3) when the turn signal indicator is activated; and/or enable the output of the composite image data (DV3) when the turn signal indicator is de-activated.

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 solid-state imaging device includes a photon detector that operates in a Geiger mode and outputs an output signal in accordance with incidence of a photon, a quench element that causes the photon detector to transition to a non-Geiger mode in accordance with the output signal, a control unit that, when the photon detector transitions from a Geiger mode to a non-Geiger mode, switches the quench element from a detection mode, in which the quench element is in a relatively low resistance state and the photon detector detects a photon, to a hold mode, in which the quench element is in a relatively high resistance state and holds the output signal, and a signal processing circuit that performs a predetermined process on the output signal.

A vehicle recording device includes a video acquisition unit that acquires video of a first camera for shooting front or rear of a vehicle and video of a second camera for shooting a range including a lower part of a front, a rear, left and right of the vehicle, a cutout unit that performs cutout processing on the video of the second camera acquired by the video acquisition unit with a first cutout range to be used as an overhead video image and a second cutout range at least including an area in a direction further away from the vehicle than the first cutout range is, and a recording control unit that records the video of the second camera cut out with the second cutout range to be recorded when the vehicle is stopping, and record the video of the first camera to be recorded when the vehicle is moving.

The disclosed computer-implemented method may include displaying vehicle environment awareness. In some embodiments, a visualization system may display an abstract representation of a vehicle's physical environment via a mobile device and/or a device embedded in the vehicle. For example, the visualization may use a voxel grid to represent the environment and may alter characteristics of shapes in the grid to increase their visual prominence when the sensors of the vehicle detect that an object is occupying the space represented by the shapes. In some embodiments, the visualization may gradually increase and reduce the visual prominence of shapes in the grid to create a soothing wave effect. Various other methods, systems, and computer-readable media are also disclosed.

A system in a vehicle for generating and displaying three-dimensional images may comprise a first imager having a first field of view; a second imager having a second field of view at least partially overlapping the first field of view, the second imager disposed a distance from first imager; and an image signal processor in communication with the first and second imagers; wherein the image signal processor is configured to generate an image having a three-dimensional appearance from the data from the first and second imagers. The first and second imagers may be disposed on a vehicle. The first and second imagers may be configured to capture a scene; and the scene may be exterior to the vehicle.

An apparatus comprising a sensor and a processor. The sensor may be configured to generate a first video signal based on a targeted view from a vehicle. The processor may be configured to (A) receive the first video signal, (B) generate a second video signal and (C) present the second video signal to a display. The second video signal presents a series of video frames configured to fit a shape of the display. The processor selects among a plurality of fields of view for the video frames based on a decision by the processor.

A vehicular trailering assist system includes a vehicle rear backup camera disposed at a rear portion of a vehicle and viewing at least rearward of the vehicle. A trailer hitched to the vehicle includes a trailer rear camera disposed at a rear portion of the trailer and viewing at least rearward of the trailer. The control displays at a display device in the vehicle a surround view image using an avatar of the vehicle and an avatar of the trailer. The control stitches images derived from image data captured by the vehicle rear backup camera and images derived from the trailer rear camera to provide a transparent trailer view, and the display device displays transparent trailer view video images. Responsive to the vehicle being shifted into a reverse gear, the display device automatically displays rear backup images derived from image data captured by the trailer rear camera.

An electronic device includes: a processor configured to: based on two images captured at two different time points by a camera of a vehicle that is traveling and traveling information of the vehicle, determine a first transformation matrix of a camera coordinate system comprising a rotation matrix and a translation matrix for a movement of the vehicle between the two time points; transform the first transformation matrix into a second transformation matrix of a vehicle coordinate system; update a parameter of the camera to apply the movement of the vehicle to the parameter of the camera, based on either one or both of roll information and pitch information of the vehicle acquired from the rotation matrix; and visualize a blind spot of the camera based on the either one or both of the roll information and the pitch information, and based on the updated parameter and the second transformation matrix.

An image display apparatus has: an imaging device (11L, 11R) that is placed at a tiltable housing (15L, 15R) and that is configured to image a rear side area (BL_area, BR_area) of a vehicle (1), the housing being allowed to rotate around a predetermined rotational axis (L, R) that is along a direction inclined to a yaw axis of the vehicle; and a displaying device (14) that is configured to display an external image captured by the imaging device.