A rearview device for a motor vehicle includes a moveable head assembly, an actuator assembly having a fixed part and a moveable part, the moveable part being attached to the head assembly, a motor cradle configured to attach the actuator assembly to the moveable head assembly. A method of assembling a rearview device comprises providing the rearview device and attaching the actuator assembly to the moveable head assembly using the motor cradle.

This disclosure details vehicle static body structure mounted side view mirror assemblies. The exemplary side view mirror assemblies may include features for supporting vehicle off-roading, such as a pivoting and telescoping mirror section, a wind wing, lighting features, snorkel features, and/or accessory mounts, etc. The exemplary side view mirror assemblies may also include features for supporting improved vehicle security, such as mirror mounted radar sensors capable of establishing a security protection zone about the vehicle.

A mirror reflective element sub-assembly for use in an exterior rearview mirror assembly of a vehicle includes a mirror reflective element, a mirror reflector and a mirror back plate disposed at the rear side of the mirror reflective element. A heater pad is disposed between the mirror reflective element and the mirror back plate and has a light transmitting portion that is aligned with an aperture of the mirror back plate. A blind spot indicator module includes a body portion and a connector portion extending laterally from the body portion. Light emitted by at least one light emitting diode passes through the light transmitting portion of the heater pad and through a light-transmitting portion of the mirror reflector and exits the mirror reflective element to provide a visual icon visible to a driver of the vehicle who is driving the vehicle and who is viewing said mirror reflective element.

An apparatus includes a camera, a sensor and a processor. The camera may generate a video signal based on a targeted view of a driver. The sensor may generate a proximity signal in response to detecting an object within a predetermined radius. The processor may determine a location of the object with respect to the vehicle, determine a current location of eyes of the driver, determine a field of view of the driver at a time when the proximity signal is received based on the current location of the eyes, determine whether the object is within the field of view using the current location of the eyes, and generate a control signal. The distance may be determined based on a comparison of reference pixels of a vehicle component in a reference video frame to current pixels of the vehicle component in the video frames.

An apparatus comprising an interface to a sensor and a processor. The sensor may be configured to generate a video signal having a first field of view based on a targeted view from a vehicle. The processor may be configured to (A) receive the video signal from the interface, (B) generate a second field of view from the video signal based on (i) the first field of view, (ii) a shape of a display and (iii) an input and (C) present the second field of view from the video signal to the display. The second field of view is a cropped version of the first field of view. The second field of view is generated by adjusting video data in the first field of view. Portions of the first field of view not in the second field of view are hidden portions of the video signal.

A camera system comprising a first video camera having a first field of vision, an orientation adjustment switch, a first display, and an electronic processor. The electronic processor is configured to receive, from the first video camera, a non-rectilinear image of the first field of vision and receive, from the orientation adjustment switch, input defining an axis of a second field of vision within the first field of vision. The electronic processor is also configured to apply a distortion correction method to the non-rectilinear image of the first field of vision to produce a rectilinear image of the first field of vision. The electronic processor is further configured to determine a rectilinear image of the second field of vision within the rectilinear image of the first field of vision, and display the rectilinear image of the second field of vision on the first display.

An adjustable side view mirror apparatus including a casing having a front edge and a pair of mirrors disposed within the front edge. The pair of mirrors includes a flattened upper mirror and a convexly curved lower mirror. An attachment arm is attached to each of the casing and an exterior surface of a vehicle. Each of an upper servo motor and a lower servo motor of a pair of servo motors is disposed within the casing and rotatably attached to each of the upper mirror and the lower mirror, respectively. Each of an upper mirror control and a lower mirror control of a base unit is in operational communication with the upper servo motor and the lower servo motor, respectively, and configured to activate each of the upper servo motor and the lower servo motor, respectively, to adjust each of the upper mirror and the lower mirror, respectively.

The present invention relates to a backlight unit for an outside mirror of a vehicle, wherein the backlight unit can comprise: a light source unit having at least one light source; and an optical processing unit having at least one optical passage through which light emitted from the light source passes while being spread, and a reflective surface which reflects light which has passed through the optical passage.

Using communication unit positional information acquired using infrastructure communication and moving body positional information detected using millimeter-wave radar, a moving body existing in a blind spot of a radar detection region is recognized, and behavior is predicted from movement information of the moving body, by deleting the moving body information detected by millimeter-wave radar from the communication unit information acquired using infrastructure communication.

A rearview device for a vehicle, includes: a moveable mirror head assembly that includes an upper casing element, a lower casing element, and a bezel that carries a mirror glass; a base frame; a motor cradle connected to the upper and lower casing elements; and an actuator assembly attached to the base frame and configured to move the moveable mirror head assembly connected to the articulation assembly via the motor cradle. The actuator assembly is configured to adjust the moveable mirror head assembly inwardly or outwardly and upwardly or downwardly so that movement of the moveable mirror head assembly may be controlled using the actuator assembly to change a field of view in a drive position or to place the moveable mirror head assembly in a park position. The actuator assembly provides a range of angular motion of the moveable mirror head assembly that is greater in the inwardly or outwardly direction than in the upwardly or downwardly direction. Programmable actuator assembly settings for one or more of the field of view in the drive position or the park position of the moveable mirror head assembly are pre-set for selection by a user of the rearview device.