An image display apparatus includes: cameras each configured to take an image representing a view outside a vehicle; displays each configured to display the image taken by a corresponding one of the cameras; and a controller configured to control the cameras and the displays. The controller detects a first action that is a preliminary action taken by an occupant of the vehicle to get out of the vehicle in a state in which the cameras and the displays are not activated. When the first action is detected, the controller activates at least one of the cameras and at least one of the displays and control the at least one of the displays to display an image taken by the at least one of the cameras.

A collision avoidance and/or pedestrian detection system for a large passenger vehicle such as commuter bus, which includes one or more exterior and/or interior sensing devices positioned strategically around the exterior and interior of the vehicle for recording data, method for avoiding collisions and/or detecting pedestrians, and features/articles of manufacture for improving same, is described herein in various embodiments. The sensing devices may be responsive to one or more situational sensors, and may be connected to one or more interior and/or exterior warning systems configured to alert a driver inside the vehicle and/or a pedestrian outside the vehicle that a collision may be possible and/or imminent based on a path of the vehicle and/or a position of the pedestrian as detected by one or more sensing devices and/or situational sensors.

In one embodiment, a vehicle mirror includes an on-board diagnostics (OBD) transceiver and one or more processors. The processors access OBD data received by the OBD transceiver from an OBD port of a vehicle. The processors further determine, from the OBD data, a vehicle type, a change in voltage of the vehicle's battery, and a secondary vehicle factor. When the vehicle is determined to be a combustion engine vehicle, the processors transition the vehicle mirror from a sleep power state to an awake power state when the change in voltage is greater than a predetermined amount and the secondary factor of the vehicle is greater than a predetermined threshold. When the vehicle is determined to be an electric vehicle, the processors transition the vehicle mirror from the sleep power state to the awake power state when any activity is detected in the OBD data and the secondary factor of the vehicle is greater than the predetermined threshold.

A camera system is installed on the front end of a vehicle, either on the left front, the right front, or both sides. The camera is linked via wired or wireless connection to an onboard computer and a navigation display that is located within the passenger compartment of the vehicle. The driver reviews a visual description on the display of any oncoming traffic in the form of motor vehicles, pedestrians, cyclists, animals and the like on the navigation display via a single screen, split screen or alternating screens. The camera system can include a speed sensor that detects when the vehicle reaches a threshold speed to activate or de-activate the camera. Alternatively, the computer can activate the system when a turn signal is activated, and de-activate the system when the turn signal is no longer activated. This camera system can be retrofitted into older vehicles.

In one embodiment, a vehicle mirror includes a heads-up display (HUD) projector, an on-board diagnostics (OBD) transceiver, and one or more processors. The processors access OBD data received by the OBD transceiver from an OBD port of a vehicle. The processors further determine an identification of the vehicle from the accessed OBD data and determine one or more calibration parameters for the HUD projector based on the determined identification of the vehicle. The one or more calibration parameters are operable to position a displayed image from the HUD projector onto a HUD reflector within a line-of-sight of a driver of the vehicle. The processors further send one or more instructions based on the one or more calibration parameters to the HUD projector.

A work screen display system including a position information obtaining unit for obtaining position information on a work vehicle based on positioning correction information supplied from a first reference station; a region shape determination unit for determining a shape of a specific region where the work vehicle performs autonomous travel, based on positioning correction information supplied from a second reference station; and a display control unit for displaying, on a display unit, a specific region indication section indicating the specific region determined by the region shape determination unit. The display control unit displays the specific region indication section in a display mode that varies between a case where the first and second reference stations are identical and a case where the first and second reference stations are not identical

A vehicle includes a display device, a radar sensor having a detection region perpendicular to a vehicle longitudinal axis, a radar analyzer connected to the radar sensor, and a camera having a switchable field of view for covering an angular range behind the vehicle direction between a narrower angular range and a wider angular range. The display device is configured to display an image from the camera, at the narrower range, responsive to a sensor sensing vehicle movement in a direction included in a field of view of the camera, and the display device is configured to display an image from the camera at the wider range, responsive to the radar sensor detecting an object moving towards the vehicle. The vehicle may also be configured to automatically stop responsive to certain characteristics of objects detected by the radar sensor.

A work screen display system including a position information obtaining unit for obtaining position information on a work vehicle based on positioning correction information supplied from a first reference station; a region shape determination unit for determining a shape of a specific region where the work vehicle performs autonomous travel, based on positioning correction information supplied from a second reference station; and a display control unit for displaying, on a display unit, a specific region indication section indicating the specific region determined by the region shape determination unit. The display control unit displays the specific region indication section in a display mode that varies between a case where the first and second reference stations are identical and a case where the first and second reference stations are not identical.

A method for monitoring an interior of a motor vehicle using at least one camera directed into the interior during a temporary access to the interior or to a trunk of the motor vehicle, the camera being switched on by a control unit during the entire access or in the event of deviations from specified rules for the access and transmitting the recorded data to a storage device.

A method is provided using a system mounted in a vehicle. The system includes a rear-viewing camera and a processor attached to the rear-viewing camera. When the driver shifts the vehicle into reverse gear, and while the vehicle is still stationary, image frames from the immediate vicinity behind the vehicle are captured. The immediate vicinity behind the vehicle is in a field of view of the rear-viewing camera. The image frames are processed and thereby the object is detected which if present in the immediate vicinity behind the vehicle would obstruct the motion of the vehicle. The processing is preferably performed in parallel for a plurality of classes of obstructing objects using a single image frame of the image frames.