A multifunctional rear camera system includes a rear camera and a processor. Responsive to processing of captured image data, the processor generates respective outputs for (i) a rear backup assist function, (ii) a mirror dimming control for at least an electro-optic interior rearview mirror assembly of the vehicle and (iii) ambient light detection. The processor processes a mirror zone of captured image data for mirror dimming control and processes upper corner regions of captured image data for ambient light detection. The processor processes at least lower regions of captured image data for the rear backup assist function. The generated output for the mirror dimming control is provided to the electro-optic interior rearview mirror assembly to control dimming of the electro-optic reflective element. The generated output for the rear backup assist function provides (i) object detection and/or (ii) video display of video images derived from captured image data.

A system and rearview assembly is disclosed. The system includes a rearview assembly, an imager, and a controller. The rearview assembly comprises a backlight. Further, the rearview assembly is operable to provide a driver with a view of a scene rearward of a vehicle. Additionally, the rearview assembly is operable to emit light to illuminate the driver with at least one of infra-red and near infra-red light from the backlight. The imager is operable to image the driver in the at least one of infra-red and near infra-red light. The controller is communicatively connected to the imager and operable to analyze images of the driver to perform at least one of a biometric and a driver awareness analysis.

A rearview device having a housing that defines a cavity. The rearview device additionally includes an electro-optic element. In some embodiments, the housing may comprise a peripheral flange. The peripheral flange may have a mounting surface and a lip. The electro-optic element may be associated with the mounting surface. Further, the lip may substantially circumscribe the electro-optic element. In other embodiments, the rearview device may further comprise a mounting assembly having one or more mechanical fastener acceptors. One or more mechanical fasteners may be received by the mechanical fastener acceptors and extend through holes both in a holder and a circuit board disposed in the cavity. In yet other embodiments, the one or more mechanical fasteners may be received by the mechanical fastener acceptors and extend through and be supported by a washer disposed in the cavity.

A vehicular interior rearview mirror assembly includes a mounting structure and a mirror head pivotally mounted at the mounting structure via a pivot joint. The mirror head includes a mirror casing and a display and mirror assembly, which includes a frame portion, a video display screen at a front side of the frame portion, and a mirror reflective element at a front side of the video mirror display screen. The mirror reflective element includes a variable reflectivity liquid crystal (VRLC) stack of layers, which have a liquid crystal (LC) layer disposed between a rear glass substrate and a front glass substrate. The front and rear glass substrates are integrated in the VRLC stack of layers. With the mounting structure mounted at an interior portion of a vehicle, the video display screen is operable to display video images derived from video images provided by an ECU of the vehicle.

A method for assembling an electro-optic mirror reflective element for a vehicular rearview mirror assembly includes providing a container having a plurality of holes for dispensing spacer beads, supporting the container over a dispensing area via an electrically powered shaking device, positioning a glass substrate at the dispensing area, and automatically shaking the container so that spacer beads fall through the holes in the container and onto the glass substrate. The shaking of the container is controlled so that the shaking device is deactivated after an appropriate amount of spacer beads are dispensed onto the glass substrate. The glass substrate is mated with another glass substrate with the dispensed spacer beads between the glass substrates and bounded by a perimeter seal. The cavity between the glass substrates is filled with an electro-optic medium, and the cavity is sealed with the electro-optic medium and spacer beads disposed therein.

A vehicular interior rearview mirror assembly includes a mirror head and a mounting assembly. The mirror casing includes a sidewall having an outer end region that circumscribes an open portion of the mirror casing. The outer end region includes a rounded outer surface curving between the open portion and a less-curved outer surface of the sidewall. The mirror reflective element is disposed at the open portion of the mirror casing. The mirror reflective element has a glass substrate having a rounded perimeter edge of at least 2.5 mm and a thickness of less than 2 mm. Curvature of the rounded outer surface of the outer end region of the sidewall matches curvature of the rounded perimeter edge of the glass substrate to provide a curved transition between a flat region at the front surface of the glass substrate and the less-curved outer surface of the sidewall of the mirror casing.

A rearview system may comprise a light sensor assembly having: a photosensor operable to detect light and generate a signal based, at least in part, on the detected light; a dichroic filter in optical communication with the photosensor and operable to filter light; and a rearview assembly having an electro-optic element may comprise an electro-optic medium and operable to variably change the amount of light passing through the electro-optic medium based, at least in part, on the signal. The dichroic filter may be configured to substantially inhibit light having a wavelength of less than 400 nm or greater than 650 nm from transmitting therethrough.

A vehicular rearview assembly includes an electro-optic element. A first substrate defines a first element surface and a second element surface. A first polarizer is coupled to the second element surface. A second substrate is spaced away from the first substrate and defines a third element surface and a fourth element surface. An electro-optic material is positioned between the first and second substrates. A second polarizer is coupled to the second substrate. A display is configured to emit light having a first polarization toward the second polarizer.

A rear-view mirror includes a body, wherein the body includes a first polarizer, a dimming layer, a transflective polarizer, and a display component which are sequentially laminated. The dimming layer is configured to adjust a polarization direction of light passing through the dimming layer. By adjusting the polarization direction of the light passing through the dimming layer via the dimming layer, the reflectivity and transmittance of the transflective polarizer to the light can be changed, such that both an anti-glare function and a display function of the rear-view mirror can be achieved.

A vehicular exterior rearview mirror assembly includes a mounting arm and a mirror head at one end of the mounting arm distal from an attachment portion of the mounting arm that is configured for attachment at a vehicle. A mirror reflective element is fixedly attached at the mirror head. An innermost side of the mirror reflective element is attached at a front side of an attachment plate. The mirror reflective element moves in tandem with movement of the mirror head relative to the mounting arm when the driver of the vehicle operates an electrically-operable actuator. The attachment plate includes wall structure that extends from the front side of the attachment plate and circumscribes and spans the perimeter circumferential edge of the glass substrate and does not encroach onto and does not overlap the front surface of the glass substrate of the exterior mirror reflective element.