The present application discloses a method of controlling a rear-view mirror for a vehicle. The method includes determining a gaze position and a gaze direction of a user; and controlling the rear-view mirror based on the user's gaze position and gaze direction.

A multi-camera vehicular video display system includes an interior rearview mirror assembly having a mirror head that includes a transflective mirror element and a video display screen disposed behind the transflective mirror element. The mirror assembly includes a mechanism that is operable to change orientation of the transflective mirror element relative to a driver of the vehicle. When the mechanism changes orientation to a second position that is tilted away from the eyes of the driver of the vehicle, the video display screen displays video images viewable through the transflective mirror element. When the mechanism changes orientation to a first position that is tilted towards the eyes of the driver of the vehicle, the video display screen does not display video images. The displayed video images are derived, at least in part, from image data captured by at least one exterior viewing camera of the vehicle.

An interior rearview mirror assembly includes a mounting structure configured for mounting at an interior portion of a vehicle. A distal end portion of the mounting arm is at an angle relative to a proximal end portion of the mounting arm at the interior portion of the vehicle. An attaching element is fixedly disposed at the distal end portion. A mirror housing includes an aperture, and the mounting arm of the mounting structure passes through the aperture without making contact with the mirror housing. A reflective element is attached at an attachment plate disposed within the mirror housing. A motorized actuator is mounted at the attachment plate at the reflective element or at the attaching element at the distal end portion of the mounting arm. The motorized actuator is electrically operable to adjust the reflective element and the mirror housing together and in tandem relative to the mounting structure.

A rotatable rear-view mirror with a display may include a rear-view mirror housing having two openings to make it possible to select one of more visible view surfaces of a display mirror and a general mirror, wherein the rotatable rear-view mirror further include a housing coupled to a mounting guide device disposed inside a windshield glass and having two different openings; a mirror device disposed in one of the openings of the housing; and a display device disposed in a remaining one of the openings and wherein the housing may be configured to be rotatable by a predetermined angle based on a first end portion of the mounting guide device so that a rear view is provided through the mirror device or the display device depending on a request of a driver.

A display mirror assembly having a mount operably coupled to a vehicle interior. The mount includes one of a ball and a socket extending forwardly therefrom. An engagement plate is pivotally coupled with the mount via the other of a ball and a socket extending rearwardly from the engagement plate. The engagement plate includes a first support member and a second support member pivotally coupled to the first support member. A carrier plate is operably coupled with the engagement plate. The carrier plate supports a rear housing on a rear portion thereof. A glass element is operably coupled with the carrier plate. A display module is configured to be turned to an on state and an off state. An actuator device is disposed on a bottom surface of the housing and is operably coupled with the glass element. The actuator device is adjustable to tilt the glass element.

An interior rearview mirror assembly for a vehicle includes a reflective element disposed at a housing. The housing and the reflective element are tandemly and pivotally adjustable about a mounting structure mounted at an interior portion of the vehicle to provide a desired rearward field of view to a driver of the vehicle. A user input is actuatable by the driver of the vehicle. A motorized actuator is operable responsive to actuation of the user input to tilt the reflective element and the housing in tandem about a horizontal axis. Responsive to actuation of the motorized actuator responsive to the user input, the motorized actuator tandemly tilts the reflective element and the housing about the horizontal axis to orientate an outermost front surface of the reflective element more towards the driver or more away from the driver.

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 rear view mirror for use in a motor vehicle includes a support element having a reflective element attached to a first side; and a frame element detachably attached to a second side of the support element which is located opposite the first side. The frame element includes an adjusting element that is adapted to connect the rear view mirror to a stationary support arm holding the rear view minor. The frame element is adapted to move the rear view minor relative to the stationary support arm and comprises active material to move the rear view mirror.

A vehicular interior rearview mirror assembly includes a mounting assembly having a base portion and a mounting arm extending from the base portion. A mirror head is pivotally adjustable relative to the mounting assembly via a pivot joint having first and second pivot elements. The mirror head includes a mirror reflective element, with the first pivot element disposed at the rear side of the mirror reflective element and fixed thereat. The mounting arm includes a proximal end proximate the base portion and a distal end distal from the base portion, with the second pivot element being at the distal end of the mounting arm. The second pivot element is disposed at a damping element that is received at the distal end of the mounting arm. The damping element and the second pivot element are biased toward the distal end of the mounting arm and away from the base portion.

A mirror assembly includes a housing, a reflective element, a display, a light sensor, a controller, and an interface. The reflective element is adapted to change beween high and low reflection states. The display is positioned behind, and visible through, the reflective element when activated and the switchable reflective element is in the low reflection state. The sensor is configured to output a light signal. The controller is configured to receive the signal, compare the signal to a threshold, and output a signal to the switchable reflective element to facilitate changing between the high and low reflection states and based on the comparison. The controller outputs a signal to activate the display when the switchable reflective element is in the low reflection state. The interface outputs a signal to the controller to activate the display and place the reflective element in the low reflection state regardless of the light signal.