A viewing device for a vehicle is provided with plural cameras, an image generation unit, a display and a switching control unit. The plural cameras have different imaging ranges. On the basis of captured images from one or a plural number of the cameras, the image generation unit generates plural viewing images that differ in at least one of viewpoint or viewing angle. The display displays the viewing images. The switching control unit is capable of switching a viewing image being displayed at the display to another of the viewing images.

Method and apparatus are disclosed for detection and presentation of obstructed vehicle views. An example vehicle includes a first side mirror, a first camera adjacent to the first side mirror, a first sensor module to detect opaque material on the first side mirror, an obstruction identifier to determine whether viewing of a first area via the first side mirror is obstructed, and a display to present, via the camera, the first area responsive to the obstruction identifier determining viewing via the first side mirror is obstructed.

A display control apparatus includes a captured data acquisition unit, a motion state detection unit, an extracted image data generation unit, a display image data generation unit, and an output unit. The captured data acquisition unit is configured to acquire captured data generated as a result of a camera capturing scenery outside a vehicle. The motion state detection unit is configured to detect a motion state of the vehicle. The extracted image data generation unit is configured to generate an extracted image from the captured data by using an angle of view set in accordance with the motion state. The display image data generation unit is configured to generate display image data related to a display image having a preset image size, from extracted image data. The output unit is configured to output the display image to a display unit having the image size.

A work vehicle has display devices and cameras coupled to display feeds at display areas. The cameras include a first set on the first side, second side, and central location relative to the first FOV and a second set on a first side, second side, and central location relative to the second FOV. A control system is configured to: in a first mode, display a first set of feeds from the first side, second side, and central location of the display areas so that the feeds are arranged at the first side, second side, and central location relative to the first FOV; and in a second mode, display a second set of feeds from the first side, second side, and central location of the second set at display areas so that the feeds are arranged at the first side, second side, and central location relative to the second FOV.

A driving assistance system provides driving assistance to a driver in a vehicle which includes a display disposed in front of a driver seat and an electronic side mirror, and includes: a display condition determiner that determines whether a predetermined condition is satisfied in the vehicle driven by the driver; an image processor that generates an overhead image including an area around the vehicle when the predetermined condition is satisfied; a first control device that displays, on the electronic side mirror, a first image including the overhead image generated by the image processor; and a second control device that displays, on the display, a second image including the overhead image generated by the image processor.

In a camera system, a captured image of a rear of a vehicle is acquired, an optical image having a high-resolution region and a low-resolution region is formed on an imaging unit, a first image is generated by cutting out a first region from an image region corresponding to the high-resolution region in an image read from the imaging unit, a second image is generated by cutting out a second region from an image region different from the first region, the first image and the second image are generated such that at least a portion of a lower end of the second region is positioned below a lower end of the first region, and at least a portion of an upper end of the second region is positioned below an upper end of the first region, and at least one of the first image and the second image is output for display.

An image display system includes: an external environment information acquiring device configured to acquire external environment information around a mobile body; a display device configured to display the external environment information; and a control device configured to control a display of the external environment information on the display device, wherein the control device is configured to generate a virtual viewpoint image in which the mobile body and an object around the mobile body are viewed from a virtual viewpoint, cause the display device to display the virtual viewpoint image, move the virtual viewpoint along a trajectory set around the mobile body, set a restricted section in the trajectory such that the restricted section is arranged in front of the mobile body in a plan view, and execute viewpoint restricting control to restrict a display of the virtual viewpoint image from the virtual viewpoint in the restricted section.

Disclosed herein are a display system of a vehicle and a method of driving the same. The display system includes a plurality of camera modules configured to capture a front side, a rear side, a rear left side, and a rear right side relative to the vehicle and generate image data, a plurality of display panels configured to receive the image data and display front side images, rear side images, rear left side images, and rear right side images relative to the vehicle, a driver pupil detection sensor configured to sense a pupil of a driver and generate pupil position data, a driver posture detection sensor configured to sense a position of the driver, a body direction thereof, and a head height thereof and generate posture data, a calculator configured to calculate a position of a field of view of the driver on the basis of the pupil position data and the posture data and generate a display correction value on the basis of the position of the field of view, and a display correction device configured to adjust a horizontal tilt and a vertical tilt of each of the plurality of display panels on the basis of the display correction value.

Examples of techniques for overlaying on an in-vehicle display road objects associated with potential hazards are disclosed. In one example implementation, a method may include: responsive to detecting a presence of a detected vehicle in proximity to the local vehicle, determining, by a processing device, a position of the detected vehicle, a speed of the detected vehicle, and a time to the local vehicle of the detected vehicle; determining, by the processing device, whether the detected vehicle, in proximity to the local vehicle, represents a potential hazard to the local vehicle based on the position of the detected vehicle, the speed of the detected vehicle, and a time to the local vehicle of the detected vehicle; and responsive to determining that the detected vehicle, in proximity to the local vehicle, represents a potential hazard to the local vehicle, overlaying, by the processing device, a warning indicium on the in-vehicle display.

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.