A display device for a vehicle includes: a plurality of imaging units configured to capture images around the vehicle; an image compositing unit configured to composite the images captured by the imaging units to generate a composite image; an image display unit configured to display the composite image generated by the image compositing unit; and an acquiring unit configured to acquire information about an object around the vehicle. The imaging units are arranged such that imaging areas thereof overlap with each other. The image compositing unit is configured to set a boundary between the captured images in the composite image such that the boundary is provided in a part where the imaging areas of the imaging units overlap with each other. In a case where the acquiring unit acquires the information about the object, the image compositing unit changes the boundary.

An imaging apparatus comprises a camera and a controller. The camera generates a captured image. The controller superimposes a calibration object movable by translation or rotation in the captured image. In the case where a plurality of indexes I located at positions determined with respect to a moveable body having the camera mounted therein are subjected to imaging, the controller moves the calibration object so that a first corresponding portion coincides with an image of a first index of the plurality of indexes, and performs distortion correction on an area in the captured image determined based on a position of the image of the first index and a position of an image of a second index in the captured image and a position at which the calibration object is superimposed so that the image of the second index coincides with a second corresponding portion.

Embodiments of the present disclosure relate to a camera monitor system providing areas of importance to a driver, to a corresponding vehicle and to a method for operating such a camera monitor system comprising at least two separate cameras arranged to record camera views of the surrounding of the vehicle being different for each camera and at least one monitor with a monitor screen suitably arranged to provide the recorded camera views on the screen at least to the driver of the vehicle, wherein the provided camera views and/or an arrangement of the different recorded camera views on the monitor screen depend(s) on a status of the vehicle, wherein a control unit is adapted to observe the status of the vehicle and to alter the arrangement of the camera views provided on the screen in dependence on the observed status of the vehicle.

A vehicle and a method for controlling the vehicle are provided. The vehicle includes a first camera configured to capture a front image of the vehicle; a head-up display configured to project an image onto a windshield of the vehicle; an input device configured to input a boundary line for setting an area in which the image is projected from the windshield; and a controller configured to determine a projection area in which the image is projected based on the inputted boundary line, to determine an interest area of the front image based on the determined projection area and a speed of the vehicle, and to display the determined interest area in the determined projection area on the head-up display.

Example implementations are provided for an arrangement of co-aligned rotating sensors. One example device includes a light detection and ranging (LIDAR) transmitter that emits light pulses toward a scene according to a pointing direction of the device. The device also includes a LIDAR receiver that detects reflections of the emitted light pulses reflecting from the scene. The device also includes an image sensor that captures an image of the scene based on at least external light originating from one or more external light sources. The device also includes a platform that supports the LIDAR transmitter, the LIDAR receiver, and the image sensor in a particular relative arrangement. The device also includes an actuator that rotates the platform about an axis to adjust the pointing direction of the device.

Provided are systems for switchable wheel view mirrors, which can selectively provide views of one or more wheels of a vehicle to, for example, check for obstructions. A system for a switchable wheel view mirror can include an image sensor coupled to a vehicle, a reflective surface, and an actuator. The image sensor can capture an image within a field of view of the image sensor. The reflective surface can be coupled to the actuator which moves the reflective surface between a first position and a second position. In the first position, a view of at least a portion of a wheel of the vehicle is visible within the reflective surface and the reflective surface is disposed at least partially within the field of view of the image sensor. Methods and computer program products are also provided.

A rear view camera assembly includes an actuator that is mounted to a bottom side of a vehicle. The actuator is actuatable into an extended condition or a retracted condition. A camera is coupled to the actuator and the camera has a pair of lenses. Each of the lenses is partially angled toward a respective right side and left side of the vehicle to capture imagery within 180.0 degrees of the rear end of the vehicle. A display is disposed in the vehicle such that the display is visible to the driver. The display displays video footage of the imagery captured by each of the lenses on the camera to facilitate a driver of the vehicle to see objects approaching from either the right side or the left side when the driver is backing the vehicle.

The camera assembly (50) comprises: —a supporting arm (51) having a main axis (A51), said supporting arm (51) including a first portion (41) and a second portion (42), the first portion (41) having a first end (53) provided with a mounting device (54) for mounting on a vehicle cab and a second end (57) coupled to the second portion (42); —a camera (52) arranged on said second portion (42) of the supporting arm (51), for providing an image of a surrounding area. The first portion (41) and the second portion (42) of the supporting arm (51) are coupled via coupling means (45) which are configured so that the second portion (42) can move relative to the first portion (41) between: —a first operative position, in which the camera (52) is adapted to provide an image of a first surrounding area; —and a second operative position, in which the camera (52) is adapted to provide an image of a second surrounding area distinct from the first surrounding area.

A sideview mirror assembly for a vehicle can comprise a body including a sideview mirror housing. The sideview mirror assembly can include a camera located in the body about the sideview mirror housing. The camera can have a field-of-view including an above-horizontal region directed rearward toward an overhead target position past the sideview mirror housing. The camera can be mounted for movement relative to the body between a normal position, in which the sideview mirror housing intersects the camera and the overhead target position in the above-horizontal region, and an extended position, in which the sideview mirror housing does not intersect the camera and the overhead target position in the above-horizontal region. Movement of the camera from the normal position to the extended position can unblock camera visibility of the overhead target position by the sideview mirror housing.

A control device includes circuitry configured to: generate a surroundings image of a moving body based on imaging data obtained by an imaging device provided in an openable and closable side mirror of the moving body; cause a display device to display the generated surroundings image; and determine whether the side mirror is in an opened state or a closed state. The circuitry is configured to set, in the surroundings image, a mask area of a range that is based on a determination result as to a state of the side mirror.