A computer includes a processor and a memory storing instructions executable by the processor to detect an object in data received from a rear-facing radar on a vehicle and activate an alarm in response to the object moving through a predesignated region behind the vehicle at a speed below a threshold speed or for a duration above a threshold time.

Various embodiments include a method for providing an image using a camera monitor system for a motor vehicle with a trailer, wherein the camera monitor system has a rear camera assigned to a rear side of the trailer, a side camera assigned to a longitudinal side of the motor vehicle, and a monitor for presenting images of the cameras. The method may include: capturing a first image with the rear camera; capturing a second image with the side camera; constructing a composite image comprising the first image and the second image based at least in part on an ascertained trajectory of the motor vehicle; and displaying the composite image on the monitor.

A vehicle includes a first sensor for acquiring image data of a rear side, a second sensor for acquiring gaze data of a user, a display for outputting a screen of the image data, an input device for setting a sensitivity to a movement of a user gaze, and a controller for determining reference vector data based on the gaze data at a point in time at which the gaze data starts to be acquired or the gaze data that is preset, for outputting a control signal to output a screen of the image data corresponding to the reference vector data, for acquiring result data including relative position data and relative velocity data of gaze movement data with respect to the reference vector data, and for controlling a signal to output a screen of the image data.

The present technology relates to, for example, an image-capturing apparatus, an image processing method, and a program that make it possible to suppress an increase in costs. A controller performs an extraction control for extracting a first image and a second image from a captured image captured by an image sensor that performs image-capturing, the first image being displayed on a first display section, the second image being displayed on a second display section. A data amount adjuster adjusts data amounts of the first image and the second image according to vehicle information acquired from a vehicle. For example, the present technology is applicable to a viewing system that displays an image of a region behind a vehicle.

Aspects of the present invention relate to an imaging system (1) for a towing vehicle (V1). The imaging system (1) includes a processor configured to determine a reference speed (Vref) of the towing vehicle (V1). First image data (D1) is received from a first imaging device (C1); and second image data (D2) is received from a second imaging device (C2). The first imaging device (C1) may be disposed on the towing vehicle (V1); and the second imaging device (C2) may be disposed on a towed vehicle (V2). A first scaling factor (SF1, SF2) is applied to the second image data (D2) to generate scaled second image data (D2). The first scaling factor (SF1, SF2) is determined in dependence on the determined reference speed (Vref) of the towing vehicle (V1). Composite image data (D3) is generated by combining at least a part of the scaled second image data (D2) with at least a part of the first image data (D1). The composite image data (D3) is output for display on a display screen (10). Aspects of the present invention also relate a vehicle (V1) having an image system (1); a method of generating a composite image (IMG3); and a non-transitory computer-readable medium.

A vehicular imaging system includes an imaging device comprising an array of photo-sensing pixels and a control having an image processor operable for processing image data captured by the imaging device. The control utilizes edge detection in processing captured image data by the image processor for detecting objects present exterior of the vehicle. Responsive at least in part to processing at the control of captured image data by the image processor, the control detects an object of interest present in the field of view of the imaging device. In detecting the object of interest present in the field of view of the imaging device and responsive at least in part to processing at the control of captured image data by the image processor, shadows present in the field of view of the imaging device are discerned and distinguished from the object of interest.

The invention relates to various low flow rate fluidic nozzle inserts having a reverse mushroom-shaped mushroom insert geometry that are useful for a wide range of spraying and cleaning applications. In one embodiment, the present invention relates to fluidic nozzle inserts that are able to perform at low flow rates with geometrical and dimensional limitations. In still another embodiment, the present invention relates to compact fluidic nozzle inserts that provide a manner by which to attain a desired level of performance in a fluidic nozzle assembly for small scale applications at low flow rates.

A rear module for a vehicle includes a crossmember that extends along a transverse direction and is connected to the vehicle body and a bumper connected to the crossmember. The bumper includes an aperture. The rear module further includes a reversing camera that protrudes through the bumper, and a first impact element and a second impact element arranged on the bumper to a respective first side and a respective second side of the reversing camera and at a lateral spacing, in the transverse direction, from the reversing camera. The first impact element and the second impact element protrude, in the longitudinal direction, beyond the reversing camera and/or the bumper.

A vehicular control system includes a first communication device disposed at a first vehicle, a second communication device disposed at a second vehicle, a camera disposed at the second vehicle, and an electronic control unit (ECU) of the second vehicle. The vehicular control system determines a potential collision between the first vehicle and the second vehicle based at least in part on (i) a wireless communication received at the second communication device from the first communication device and provided to the ECU of the second vehicle and/or (ii) processing at the ECU of image data captured by the camera disposed at the second vehicle. Responsive to determination of the potential collision between the first vehicle and the second vehicle, the vehicular control system controls (i) braking of the second vehicle and/or (ii) steering of the second vehicle.

A motor vehicle includes a left side view camera attached to the left lateral side of the body and having a field of view in a rearward direction. A right side view camera is attached to the right lateral side of the body and has a field of view in a rearward direction. There is a right back up camera and a left back up camera. An optics module receives resulting video signals and produces light fields such that the light fields are reflected off of windows of the motor vehicle and are then visible to a driver of the motor vehicle as virtual images.