A vehicular image processing system includes: a plurality of first camera units configured to acquire a recognition image which is used for a recognition process of recognizing an object present in a nearby area of a vehicle; a recognition unit configured to perform the recognition process; and a communication unit communicatively connected to the first camera units and the recognition unit and configured to receive the recognition images transmitted from the first camera units and to transmit the recognition images to the recognition unit. The communication unit is configured to transmit the recognition images to the recognition unit such that timings of transmission of the recognition images received from the plurality of first camera units to the recognition unit differ. The recognition unit is configured to perform the recognition process using the recognition images received from the communication unit.

A periphery monitoring device includes: an acquisition unit configured to acquire a captured image from an imaging unit that captures an image of a periphery of a vehicle and positional information regarding an attention area set around the vehicle; and a controller configured to superimpose and display an own vehicle image showing a position of the vehicle and an indicator indicating a position of the attention area based on the positional information on a peripheral image as a bird's-eye view image based on the captured image, and to perform display such that a display mode of the indicator changes over time.

A vehicle camera system includes: an around view camera device including a front camera, a left camera, a right camera, and a rear camera, and configured to vary a field of view of one or more of the cameras in response to a control signal; and a control device configured to control the field of view by generating the control signal, in response to an operating mode.

Methods and systems for generating and utilizing a road friction estimate (RFE) indicating the expected friction level between a road surface and the tires of a vehicle based on forward looking camera image signal processing. A forward-looking camera image is pre-processed, patch segmented (both laterally and longitudinally, as defined by wheel tracks or the like), transformed into a bird's eye view (BEV) image using perspective transformation, patch quantized, and finally classified. The resulting RFE may be used to provide driver information, automatically control the associated vehicle's motion, and/or inform a cloud-based alert service to enhance driver safety.

A motor vehicle, having a plurality of image recording devices arranged across the entire vehicle for recording images of the vehicle environment, includes a control device for generating an image representation showing the 360° environment around the motor vehicle on the basis of the images. The motor vehicle further includes a display device for displaying the image representation. The control device is designed to generate an additional partial image representation showing the area below the motor vehicle on the basis of images recorded, and to integrate the partial image representation into the displayed image representation for outputting an overall image representation. At least one sensor device is provided which detects the area below the motor vehicle and communicates with the control device. The overall image representation can be modifiable at least in the area of the partial image representation on the basis of the sensor information.

A vehicular camera system includes a camera module having an imager assembly, a main circuit board and a camera housing. The imager assembly includes (i) an imager disposed on an imager circuit board and (ii) a lens holder having a lens assembly that includes a lens barrel accommodating a lens. The imager assembly includes a flexible ribbon cable that electrically connects to an electrical connector at a multilayered PCB of the main circuit board. The camera housing includes an upper cover and a lower cover and includes a forward portion and a rearward portion. The main circuit board is accommodated within the forward and rearward portions, and the imager is disposed at the rearward portion and is not disposed at the forward portion of the camera housing. The lens holder is attached at the upper cover of the camera housing.

A vehicular camera system includes a camera module having an imager assembly, a main circuit board and a camera housing. The imager assembly includes (i) an imager disposed on an imager circuit board and (ii) a lens holder having a lens assembly that includes a lens barrel accommodating a lens. The imager assembly includes a flexible ribbon cable that electrically connects to an electrical connector at a multilayered PCB of the main circuit board. The camera housing includes an upper cover and a lower cover and includes a forward portion and a rearward portion. The main circuit board is accommodated within the forward and rearward portions, and the imager is disposed at the rearward portion and is not disposed at the forward portion of the camera housing. The lens holder is attached at the upper cover of the camera housing.

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 display system of a vehicle includes a person detection device that detects a person on one side of the vehicle in a top view of the vehicle, a display device provided on the vehicle exterior on the side opposite to the one side of the vehicle, and a controller that controls the display device. When the person detection device detects a person, the controller controls the display device to display a warning indicating presence of the person, on a display of the display device.

A vehicular vision system includes a plurality of surround view cameras disposed at a vehicle, an electronic control unit (ECU), and a video display screen disposed in the vehicle and viewable by a driver of the vehicle for displaying video images derived from image data captured by the surround view cameras. The vehicular vision system, responsive to determining an impending lane change of the equipped vehicle toward an adjacent traffic lane and responsive to processing at the ECU of image data captured by at least one of the surround view cameras of the plurality of surround view cameras, displays on the video display video images derived at least in part from image data captured by at least two of the side view cameras. The displayed video images include a portion of the adjacent traffic lane.