A motor vehicle includes a rearview camera capturing images of a scene behind the motor vehicle. An electronic processor receives the images captured by the camera. A virtual image projection arrangement is communicatively coupled to the electronic processor and presents a virtual image dependent upon the images captured by the camera. The virtual image is visible by a driver of the vehicle after being reflected by a windshield.

A vehicle reflective device where the device reflectivity is adjustable by automatic or manual means, the variable reflectance element including a metallic mirror reflector on one side of a substrate. The variable reflectance function is automatically referenced to ambient light levels (day or night) and manually adjusted in response thereto. In an automatic mode, the variable reflectance assembly provides the user immediate eye protection from reflected high intensity glare by effecting near instantaneous adjustment in mirror reflectivity, such that the intensity of the reflected light impinging on the eye is automatically adjusted so as to be at comfortable levels. The mirror construction is one piece, and allows the viewing of a display monitor located behind the mirror, the mirror and monitor being operatively coupled together. In addition, the device houses a microprocessor that supports a number of software applications whose output is displayable on a designated portion of the device, the microprocessor also establishing a reflectance level within a relatively linear value of the ratio of glare light to ambient light to ensure that information displayed on the monitor screen is always available for viewing by the driver.

A vehicular control system includes a camera having an exterior field of view at least rearward of the vehicle and operable to capture image data. A trailer is attached to the vehicle and image data captured by the camera includes image data captured when the vehicle is maneuvered with the trailer at an angle relative to the vehicle. The vehicular control system determines a trailer angle of the trailer and is operable to determine a path of the trailer responsive at least to a steering angle of the vehicle and the determined trailer angle of the trailer. The vehicular control system determines an object present exterior of the vehicle and the vehicular control system distinguishes a drivable surface from a prohibited space, and the vehicular control system plans a driving path for the vehicle that neither impacts the object nor violates the prohibited space.

The present invention relates to a vehicle display device comprising: a display unit comprising a transparent flexible display disposed in a state of being rolled around a certain axis; a driving unit for adjusting the length of a region, of the transparent flexible display, exposed inside the vehicle; and a processor for controlling the driving unit and controlling the display of a picture on the transparent flexible display.

A vehicle dashboard structure is provided. A steering unit of a vehicle is provided with a screen-included dashboard. The screen-included dashboard includes a screen-based display zone, which is operable to display different message modes. The steering unit includes a steering grip, which is provided with a control operator seat, which is provided with a control operator module that is operable to control the screen-based display zone for switching of the different message displaying mode. As such, one the one hand, switching of the display mode contents of the screen-based display zone is made easy to ensure riding safety of a rider, and on the other hand, the space of the control operator seat that is provided on the steering grip can be better used.

A system for and method of displaying multiple images on an electronic display included in a vehicle. The method may include altering the position or one or more properties of a secondary image based on whether an object is detected in a primary image. The electronic display can be an electronic display mirror providing a view of an area behind the vehicle as the primary image.

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.

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 monitor the OBD data to determine whether communications with the OBD port have been lost, determine an OBD speed of the vehicle, and determine an RPM of an engine of the vehicle. The processors further determine a GPS speed of the vehicle from a GPS transceiver. When communications with the OBD port are lost, the processors transition the vehicle mirror to a sleep power state. When communications with the OBD port have not been lost, the processors transition the vehicle mirror to the sleep power state when the OBD speed is determined to be zero for at least a first predetermined amount of time and the RPM of the engine is determined to be less than a threshold RPM amount.

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 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.