A camera system mounted on a vehicle includes a first substrate including an image sensor that generates image information by photoelectric conversion and a first communication unit, and a second substrate including a second communication unit for performing wireless communication with the first communication unit and a first information processing section at least capable of recognition processing for recognizing a situation outside the vehicle based on the image information acquired via the second communication unit.

Methods and apparatus are disclosed for contamination prevention of vehicle cameras and sensors. An example vehicle includes an exterior, a camera along the exterior and including a lens, and a controller. The controller is to determine, based upon images captured by the camera, whether a contaminant is approaching the lens and identify a contaminant state upon determining the contaminant is approaching the lens. The example vehicle also includes a nozzle to spray washer fluid to prevent contamination of the lens responsive to the controller identifying that the contaminant is a liquid.

A vehicle display device includes: a display; a vehicle information image generator; an external image obtaining device; a display controller that displays the vehicle information image and the external image on the display; and an external image display determination device that determines whether the display controller is going to display the not displayed external image. When the display controller is going to display the not displayed external image, the display controller displays the external image, which the display controller is going to display, on the display with gradually increasing brightness of the external image from the brightness that is lower by a predetermined amount than original brightness to predetermined brightness that is determined based on the original brightness.

An in-vehicle display device includes an image acquiring unit, a position predicting unit, and an image converting unit. The image acquiring unit acquires an image obtained by capturing an object existing around a host vehicle by a camera mounted on the host vehicle. The position predicting unit calculates a first positional relationship between the object and the host vehicle at timing T1 and calculates a second positional relationship between the host vehicle and the object at timing T2 after timing T1 based on the image acquired by the image acquiring unit and a capture timing. Furthermore, the position predicting unit predicts a third positional relationship between the host vehicle and the object at timing T3 after timing T2 based on the first positional relationship and the second positional relationship. The image converting unit converts the image acquired by the image acquiring unit such that the positional relationship between the host vehicle and the object becomes the third positional relationship predicted by the position predicting unit.

A camera assembly of a motor vehicle includes a carrier which is adapted to be fastened to the motor vehicle and a camera unit which is immovably fastened to the carrier and has an objective. A cleaning unit is supported on the carrier and is connected to a fluid line that conducts a cleaning fluid which is used to clean the objective. A flap element is provided which is adapted to be moved into a cleaning position and into a resting position. The flap element is retracted in an accommodating chamber of the carrier in the resting position and is extended out of the accommodating chamber so that the flap element covers the objective of the camera unit in the cleaning position.

A light emitting device of an embodiment includes at least one light source; a wavelength conversion unit for converting the wavelength of excitation light so as to emit the excitation light having the converted wavelength as conversion light; a light transfer unit disposed on a light path between the at least one light source and the wavelength conversion unit for transferring the excitation light to the wavelength conversion unit; and a light-path controller moving at least a part of the light transfer unit so as to adjust at least one from among the direction and intensity of excitation light which enters the wavelength conversion unit.

The display device for a vehicle has a display portion that is provided at a ceiling of a vehicle cabin interior, and a control device that, in a case in which a vehicle is traveling within a legal speed limit, carries out display control that displays, on the display portion, moving images that are based on the vehicle speed and a peripheral environment of the vehicle.

A light identification (ID) transmission device includes: a light emitter that is elongated in a lateral direction and is configured to be attached to a first vehicle; and a light emission controller that divides a transmission target ID into packets of data, and causes the light emitter to emit modulated light that is modulated according to the packets.

A vehicle includes at least one image capture device and a user display configured to display images receive from the at least one image capture device. The vehicle also includes a controller programmed to generate a user prompt to set a home vehicle position in response the vehicle entering a first parked state. The controller is also programmed to store at least one reference image indicative of an area in a vicinity of the vehicle corresponding to the home vehicle position. The controller is further programmed to collect a current image corresponding to a current vehicle position in response to a subsequent approach toward the vicinity, and compare the current image to the reference image. The controller is further programmed to generate a user display depicting the vicinity, the current vehicle position, and the home vehicle position.

A vehicle includes a vehicle body having a cabin area and a cargo area including a truck bed assembly. A tailgate assembly is pivotally connected to the truck bed assembly. The tailgate assembly is moveable between a raised configuration and a lowered configuration. A control unit includes logic that, when executed by a non-transitory processor, causes the processor to compare a first accelerometer signal from a first accelerometer mounted to the tailgate and another accelerometer signal from a second accelerometer located outside the tailgate to determine if the tailgate is in the raised configuration or the lowered configuration.