A vehicle driving assist system includes at least a first camera (1) located at a rear part of the vehicle (10) for capturing a first field of view (11) outside of the rear of the vehicle (10). The first field of view (11) is larger than a second field of view (12) covered by a transflective element (22) of an optional rear-view mirror (21). The system further includes: a display (2) configurable for displaying an image of the first rear field of view (11) captured by the at least one, first camera (1); processing means for modifying the image to be displayed by the display (2) and for overlaying on the image displayed by the display (2) at least a reference line (41, 51, 52, 52) which corresponds to a predetermined distance at ground level (40) from the driver's ocular points (42) or from the rear of the vehicle (10).

There is provided an image generation apparatus used for a vehicle having side mirrors. An image acquisition unit is configured to acquire a plurality of captured images obtained by a plurality of cameras including side cameras provided in the side mirrors. A generation unit is configured to generate a composite image which indicates a periphery of the vehicle viewed from a virtual viewpoint, by using target areas defined for the respective captured images. A state acquisition unit is configured to acquire a developed or folded state of the side mirrors. The generation unit changes the target areas in accordance with the developed or folded state of the side mirrors.

The present invention relates to a camera for a vehicle and a control method for the same and an exemplary embodiment of the present invention provides a camera for a vehicle which is provided in any one of a plurality of designated installation positions of the vehicle, including: an image sensor which generates a driving image; a receiving unit which receives a plurality of RF signals which are transmitted from a TPMS sensor unit which detects states of a plurality of tires included in the vehicle; and a position determining unit which determines which position among the plurality of installation positions is a position where the camera is installed, based on the plurality of RF signals which is received by the receiving unit.

There is provided a vehicular visual recognition device including: an imaging section that is provided at a rear of a vehicle and that captures images rearward of a vehicle; a display section that displays an image captured by the imaging section; an optical mirror that is provided at a display face side of the display section, that transmits the captured image being displayed when the display section is in a display state, and that reflects light from rearward of the vehicle when the display section is in a non-display state; and a controller that controls the display section so as to switch the display state of the display section in accordance with a predetermined signal.

A camera monitor system includes: a capturing device; a displaying device; a detecting device detecting at least one of a state of an engine switch of a vehicle, a state of an engine, a state of a gear shift, an open/closed state of a door, and a seated state of a driver; and a control device controlling consumed power by the capturing device and the displaying device on the basis of at least one type of detection output of the detecting device. The control device controls at least one of the capturing device and the displaying device to a low power consumption state when a specified time elapses since the detection output of the detecting device is changed.

A camera monitor system includes: left and right capturing devices; left and right displaying devices; and a control device detecting an abnormality of each of the left and right capturing devices and controlling a displaying state of each of the left and right displaying devices based on the detected abnormality. The control device individually controls each of the left and right displaying devices to be in a low power consumption state in accordance with a mode of the detected abnormality.

A vision system for a vehicle is provided including a camera for capturing images within a field of view; a display device movably mounted relative to the vehicle for displaying a portion of the field of view of the camera; a movement sensor for sensing movement of the display device; and a processing circuit in communication with the movement sensor, the display device, and the camera for selecting the portion of the field of view to be displayed on the display device in response to movement of the display device as sensed by the movement sensor.

An HUD superimposes a display object, as a stereoscopic image or a planar image, on an actual scene. A display control device acquires information about a moving object and information about surrounding and estimates a relative distance between a display obstacle and the moving object. When it is determined that the display obstacle exists or can exist between the display object and the moving object, the display control device changes the display mode of the display object in accordance with the amount of change in the relative distance and notifies the HUD of the display mode.

A view friendly monitor system provides a monitor and a sequence of views that are regions of interest. The monitor can display a region of the camera view; the system is configured such that the displayed region of the camera view is a region of interest to the user. The displayed portion of the camera view changes to match the changing interests of the user. For example, a user that is interested to see a view in a direction beyond a certain edge of the monitor would move her head generally in an opposite direction. To see farther outside the edge, she needs to move her head farther in the opposite direction. In response to her head movement, the view friendly monitor system would change the region of interest based on the direction and the length of her head movement and display the new region of interest on the monitor.

A vehicular vision system includes a rearview video camera and a video processor operable to process captured video image data that includes at least a left zone image data set, a middle zone image data set and a right zone image data set. A single video display screen displays video images and includes a left display region at a left portion, a right display region at a right portion, and a middle display region between the left and right display regions. The display screen is operable to use each display region to display video images derived from the respective zone image data set. When the display screen is displaying video images at the right or left display region that are derived from the respective zone image data, the single video display screen does not display video images representative of the other zone image data at the other display region.