A rear-view mirror and modular monitor system and method include an interior mirror that embeds a modular monitor behind see-through mirror glass. In some embodiments, the system includes multiple cameras, some in the vehicle, bus and/or truck, as well as some cameras outside the vehicle, bus and/or truck, advantageously providing the driver an opportunity to view what is happening, for example, in the back rows of the bus and/or cabin, while also using the mirror to look at objects in the bus and/or cabin that are visible using the mirror. The rear-view mirror and modular monitor system is configured to be easily assembled and/or disassembled when necessary for maintenance and/or to replace parts.

An imaging assembly includes an image acquisition circuit provided in a rear portion of a moving body. The image acquisition circuit includes an optical circuit and an image capturing circuit. The optical circuit forms an image in a first region and an image in a second region on the peripheral side having a lower image capturing magnification than the first region. A light receiving surface of the image capturing circuit includes a region in which light is incident along the optical axis of the optical circuit through the first region, and a region in which light is incident through the second region. The image acquisition circuit is disposed so that the optical axis of the optical circuit passes through an opening provided in the moving body, and light from the rear end of the moving body is incident on the image capturing surface.

A vehicular collision avoidance system includes a forward-viewing camera viewing through the windshield at least forward of the equipped vehicle, a rearward-sensing radar sensor sensing at least rearward of the equipped vehicle, and an electronic control unit. The vehicular collision avoidance system detects vehicles present forward and/or rearward of the equipped vehicle. Responsive to data processing of radar data captured by the rearward-sensing radar sensor, the vehicular collision avoidance system detects another vehicle approaching the equipped vehicle from the rear, determines distance between the equipped vehicle and the other vehicle, and determines speed difference between the equipped vehicle and the other vehicle. Based at least in part on the determined distance between the equipped vehicle and the other vehicle and the determined speed difference between the equipped vehicle and the other vehicle, the vehicular collision avoidance system controls the equipped vehicle to mitigate impact by the other vehicle.

Vehicle display device (10) including a display unit (50), installed in a cabin of a vehicle and having a display face oriented in a different direction from a direction of a driver (DR), configured to display an image depicting a surrounding area of the vehicle, and a mirror unit (55) installed in the cabin of the vehicle and configured to reflect some or all of an image area displayed on the display unit (50). A visible range of the surrounding area visible to the driver through an image of the display unit (50) reflected in the mirror unit (55) changes according to movement of a viewing position of the driver (DR) with respect to the mirror unit (55).

A periphery monitoring device according to an embodiment includes: an acquisition unit configured to acquire captured image data from an image-capturing unit that captures a region including a road surface in a traveling direction of a vehicle and a region above the road surface; a storage unit configured to store the captured image data; and an image processing unit configured to display, in a case of displaying a peripheral image in the traveling direction of the vehicle on a display unit, a first region including a road surface on a under-floor portion of the vehicle or a road surface on a vicinity of the under-floor portion by using a corresponding image in past captured image data stored in the storage unit, and display a second region including the region above the road surface by using a corresponding image in current captured image data acquired by the acquisition unit.

A vehicular display system shows a view image including a blind area with superior visibility. Embodiments include an imaging unit that captures an image of a surrounding area of a vehicle; an image processing unit that converts the image into a view image of the surrounding area of the vehicle seen from inside a cabin; and a display unit. The image processing unit generates a rear-view image acquired when an area behind the vehicle is seen from a first virtual viewpoint located in the cabin, and a front-view image acquired when an area in front of the vehicle is seen from a second virtual viewpoint located behind the first virtual viewpoint in the cabin. The display unit shows the rear-view image when the vehicle travels backward, the front-view image when the vehicle travels forward, and shows both of the view images at substantially the same angle of view.

A method for the reliable and error-robust analysis of visually captured vehicle surroundings is provided. A deviation of a camera orientation caused by a force impacting an exterior mirror carrying the camera can be compensated fully automatically. As a result, the method can be used during active travels in the field and creates more safety, in particular for autonomous driving.

A vehicle image processing device includes a camera that images surroundings of a vehicle and outputs video data. An image extraction unit extracts an image from the video data when a predetermined operation for instructing image acquisition is performed, and an image processing unit processes the extracted image in accordance with a field of view of the user in a vehicle interior. A display processing unit and a display device display the processed image on a screen arranged at a position aligned with a line of sight of the user.

A vehicular rear backup system includes a rear backup digital camera disposed at a vehicle and a display device having a video display screen disposed in an interior cabin of the vehicle and viewable by the driver of the vehicle. Rear backup video images that are derived from image data captured by the rear backup digital camera are displayed on the video display screen no later than two seconds after the driver of the vehicle first changes propulsion of the vehicle during a new ignition cycle to reverse mode to commence a first backup event. Until the first backup event is completed, the video display screen displays rear backup video images. During a backup event of the vehicle, image data captured by the rear backup digital camera is provided to and is processed by an image processor of the system to detect presence of an object rearward of the vehicle.

The invention relates to a method and system for adapting to a driver position an image displayed on a monitor in a cab of the vehicle. The invention further relates to a vehicle including such a system. The invention is particularly well suited for heavy-duty vehicles, such as trucks, buses and construction equipment. The invention may also be used in other vehicles such as a car.