A vehicle monitor system includes: a detection unit that detects a vehicle located on the rear lateral side of a host vehicle; a rear lateral imaging unit that images a prescribed angle range on the rear lateral side of the host vehicle; a display unit that displays an image captured by the rear lateral imaging unit; and an image processor that extracts a first image in a range of a first angle with reference to a rear side of the host vehicle from the captured image, and displays the extracted first image on the display unit, wherein when the vehicle is detected by the detection unit, the image processor extracts the first image and a second image in a range of a second angle greater than the first angle with reference to the rear side from the captured image, and displays the first and second images on the display unit.

The present technology relates to an image generating device, an image generating method, and a program which are capable of calling attention of a user quickly. An integrating unit integrates a first image and a second image and generates an integrated image. A superimposition executing unit causes an alert mark to be superimposed on the integrated image and generates a superimposed image in a case in which an object shown in the second image is positioned on a farther side than an object shown in the first image. The present technology can be applied to, for example, a Camera Monitor System (CMS) which provides, for example, an image corresponding to an image observed by a side mirror or a rearview mirror or the like.

A vehicle surroundings display device is provided. The vehicle surroundings display device includes an imaging device, a display device, and a display controller. The imaging device images a region toward a rear side of a vehicle and sideways from the vehicle. The display device is capable of displaying an image captured by the imaging device. The display controller displays a first predetermined area of the image as a first display image on the display device in cases in which a direction indicator of the vehicle is in an inactive state, displays a second predetermined area of the image corresponding to an activated side of the direction indicator as a second display image on the display device in cases in which the direction indicator has transitioned from an inactive state to an active state, the second predetermined area being wider than the first predetermined area and including the first predetermined area, and switches a display on the display device from the second display image to the first display image after a predetermined standby duration has elapsed when the direction indicator has transitioned from an active state to an inactive state.

An image processing device includes: an obtainer which obtains, from an imaging device provided in a vehicle so as to be oriented to capture an image of an area behind the vehicle, an image captured by the imaging device; a position detector which detects a face position of a driver; and an image processor which performs image processing to clip, according to the face position detected by the position detector, an image having a range corresponding to the face position, out of a combined image including the image, and superimpose a position image indicating a position in the vehicle, on the image at a position corresponding to the face position, and outputs an image resulting from the image processing.

A side mirror for a vehicle includes a camera, a mirror panel disposed at a portion of the side mirror, a display panel stacked on the mirror panel, and at least one processor configured to cause the side mirror to enter one of a mirror mode or a display mode based on vehicle traveling information, based on the side mirror being in the mirror mode, to output, on a portion of the display panel, a visualization on a mirror image that appears in the mirror panel, based on the side mirror being in the display mode, to output, on the display panel in the display mode, a side-rear image captured by the camera, and based on the side mirror being in the display mode, to provide, a visual effect to a portion of the side-rear image regarding ambient situation information.

A mirror display system for a vehicle includes an interior rearview mirror assembly having a mirror head and a display device having a video display screen disposed in the mirror head and behind the reflective element of the mirror head. The display screen, when actuated, is viewable through the reflective element. The display screen, when actuated, displays video images derived from image data captured by one or more of a plurality of vehicle-mounted cameras that have respective fields of view exterior of the vehicle. Responsive to a driver's touch at a respective region of the turn signal actuator of the vehicle, the video display screen displays video images derived from image data captured by a respective side camera so as to display video images of the blind zone at the respective side of the vehicle.

Vehicle safety is enhanced by providing a video system incorporating multiple cameras providing separate video feeds that are stitched together by a controller to provide a composite video viewable by the operator that changes in real time along with changes to the speed and direction of the vehicle.

Systems and methods are provided for detecting an object in front of a vehicle. In one implementation, an object detecting system includes an image capture device configured to acquire a plurality of images of an area, a data interface, and a processing device programmed to compare a first image to a second image to determine displacement vectors between pixels, to search for a region of coherent expansion that is a set of pixels in at least one of the first image and the second image, for which there exists a common focus of expansion and a common scale magnitude such that the set of pixels satisfy a relationship between pixel positions, displacement vectors, the common focus of expansion, and the common scale magnitude, and to identify presence of a substantially upright object based on the set of pixels.

A monitoring system for a vehicle. The monitoring system includes at least one imaging sensor arranged at a side mirror of a front-seat passenger side of the vehicle, a displaying unit arranged in a visual range of a driver of the vehicle, and a control unit configured to receive information on a status of at least a turning indicator. The imaging sensor is configured to capture image data of an environment of the vehicle. The displaying unit is configured to display the image data of the imaging sensor. The control unit is configured to control the display of the image data by means of the displaying unit based on the information of the status of the turning indicator.

A system for automotive trailer tracking side view mirrors where the side view mirrors are dynamically adjusted to follow and track a trailer, semi-trailer, or other towed load during turning, backing or other maneuvers. The driver is provided with an optimized view of the rear of the trailer without the need to manually adjust side view mirrors. As the vehicle and trailer turn and articulate, the side view mirror system automatically adjusts to turn, rotate, and follow the trailer. The system may provide imaging sensors, digital cameras, Lidar sensors, or other sensor modalities as input to an electronic control module. The control module is provided with image or sensor data regarding the location, angle or orientation of optical markers or targets installed on the trailer. Alternatively, the control module is provided with high resolution imaging or sensor data and applies machine vision and object recognition algorithm to identify the position of the trailer. The control modules provides a control signal output to the side view mirror motors and actuators, to dynamically adjust the side view mirrors, with a frequency response of less than 100 ms in order to provide the driver with a clear unobstructed view.