Techniques for vehicle collision avoidance are disclosed. Driver position data identifying a position of a driver with respect to a reference point is received from position sensor. The driver position data is compared by a processor against a predefined position threshold. A rear-view display mounted in a rear-view mirror housing is activated to display signals received from a wide-view rear facing camera when a result of comparing the driver position data against a predefined position threshold indicates that the driver position is at least equal to the predefined position threshold.

Embodiments of the present disclosure relate to a camera monitor system providing areas of importance to a driver, to a corresponding vehicle and to a method for operating such a camera monitor system comprising at least two separate cameras arranged to record camera views of the surrounding of the vehicle being different for each camera and at least one monitor with a monitor screen suitably arranged to provide the recorded camera views on the screen at least to the driver of the vehicle, wherein the provided camera views and/or an arrangement of the different recorded camera views on the monitor screen depend(s) on a status of the vehicle, wherein a control unit is adapted to observe the status of the vehicle and to alter the arrangement of the camera views provided on the screen in dependence on the observed status of the vehicle.

A vehicle and a method for controlling the vehicle are provided. The vehicle includes a first camera configured to capture a front image of the vehicle; a head-up display configured to project an image onto a windshield of the vehicle; an input device configured to input a boundary line for setting an area in which the image is projected from the windshield; and a controller configured to determine a projection area in which the image is projected based on the inputted boundary line, to determine an interest area of the front image based on the determined projection area and a speed of the vehicle, and to display the determined interest area in the determined projection area on the head-up display.

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 imaging apparatus provided in a moving object to capture an image of an area behind the moving object includes an imaging circuit and an optical system. The imaging circuit outputs an image based on an optical image input to a light-receiving surface. The optical system inputs the optical image to the imaging circuit. The optical system forms a first region at a first magnification and a second region at a second magnification lower than the first magnification. The second region is formed around the first region. The imaging apparatus is installed in the moving object so that, on the light-receiving surface of the imaging circuit, an axis passing through a center of the first region and extending in a direction from which the optical system receives light is inclined toward an upper side of the moving object with respect to a backward direction of the moving object.

A vehicular vision system includes a plurality of cameras and an ECU. The cameras are in communication with one another via a vehicle network and image data captured by the cameras is provided to the ECU. Responsive to a type of driving maneuver of the vehicle, (i) the ECU generates a first control signal that enables automatic control of exposure, gain and white balance of one camera of the plurality of cameras and (ii) the ECU generates respective second control signals that disable automatic control of exposure, gain and white balance of at least one other camera of the plurality of cameras. Responsive to processing of captured image data, composite video images derived from image data captured by the plurality of cameras are synthesized, and composite images are displayed that provides bird's eye view video images derived from video image data captured by the cameras.

A vehicular collision avoidance system includes a forward-viewing camera, a rearward-viewing camera, a rearward-sensing non-vision sensor and an electronic control unit. The vehicular collision avoidance system detects vehicles present forward and/or rearward of the equipped vehicle. Responsive to at least one selected from the group consisting of (i) data processing of image data captured by the rearward-viewing camera and (ii) data processing of sensor data captured by the rearward-sensing non-vision sensor, the vehicular collision avoidance system detects another vehicle approaching the equipped vehicle from the rear, determines that the other vehicle is traveling in the same traffic lane as the equipped vehicle, determines speed difference between the vehicles, and determines distance from the equipped vehicle to the other vehicle. Based on such determinations, the system determines that impact with the equipped vehicle by the other vehicle is imminent.

Systems and methods are provided for using video/still images captured by continuously recording optical sensors mounted on waste collection vehicles used in in the waste collection, disposal and recycling industry for operational and customer service related purposes. Optical sensors are integrated into the in-cab monitor as well as the onboard computer, digital video recorder and other external devices.

Disclosed are a system and method for controlling a vehicle. The system includes a vehicle that obtains driving information and a blind spot image, and transmits the driving information and the blind spot image, and a wearable device that receives the driving information and the blind spot image from the vehicle, and outputs the blind spot image based on the driving information and gaze information of a driver.

A moving body includes: a main body section provided with a moving mechanism; a peripheral information detection sensor configured to detect an obstacle peripheral to the main body section; and a control section configured to cause the main body section to autonomously travel by controlling the moving mechanism based on information regarding the peripheral obstacle detected by the peripheral information detection sensor, and configured to cause information relating to the peripheral obstacle, in a direction of progress of the main body section, to be displayed in a surrounding area of the main body section.