A camera monitoring system for a vehicle includes an interior rearview mirror assembly with a video display screen disposed behind the interior mirror reflective element. The video display screen is operable to display video images derived at least in part from image data captured by at least one video camera of a plurality of video cameras of the equipped vehicle. Image data captured by at least a driver-side viewing video camera and a passenger-side viewing video camera is provided to an image processor and is processed by the image processor to detect vehicles present exterior of the equipped vehicle. Responsive at least in part to detection of another vehicle, video images derived at least in part from image data captured by the driver-side viewing video camera, a rear viewing video camera and/or the passenger-side viewing video camera are displayed by the video display screen.

A method for mounting an accessory at a vehicular windshield includes adhesively attaching a base portion of each of at least three fixing elements at an interior cabin side of the windshield in a spaced apart non-contiguous manner. A frame includes a plurality of individual receiving portions. With the windshield installed in the vehicle, the frame is attached at the fixing elements via receiving an elongated portion of a respective and corresponding one of the fixing elements in a respective and corresponding one of the receiving portions of the frame. With the windshield installed in the vehicle, and with the frame attached at the fixing elements, a camera is disposed at the frame and received at structure of the frame, such that the camera views through the windshield via an aperture existing in the frame and a light transmissive aperture in a light absorbing layer of the windshield.

A driving assistance apparatus installed in a vehicle, the apparatus comprising an image capturing unit configured to capture an image of a left-rearward area and a right-rearward area of the vehicle, a display unit configured to display an image capturing result from the image capturing unit as an image, and a control unit configured to control the driving of the display unit, wherein the control unit causes an icon for communicating predetermined information to a driver to be displayed over the image capturing result, at a position of a corner part corresponding to an upper part on a vehicle body side of the image displayed by the display unit.

A vehicular camera system includes a black-out layer disposed at an upper central region of a windshield as installed in a vehicle, an attachment member configured for attachment at the upper central region of the windshield where the black-out layer is disposed, and an accessory module including a camera. The accessory module is configured to detachably mount at the attachment member at the windshield such that the lens of the camera is spaced from the windshield, and such that the camera views forward of the vehicle through an aperture in the black-out layer via a tapered structure that is widest at the windshield and that tapers from the windshield towards where the lens of the camera is located. The tapered structure is at an acute angle relative to the vehicle windshield. The camera captures image data for a driver assistance system of the equipped vehicle.

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 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.

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 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.

Systems for monitoring a temperature within a child safety seat and methods for sending and receiving temperature data indicative of a temperature within a child safety seat are described.

A method for mounting an accessory at a vehicular windshield includes adhesively attaching a base portion of each of at least three fixing elements at an interior cabin side of the windshield in a spaced apart non-contiguous manner. A frame includes a plurality of individual receiving portions. With the windshield installed in the vehicle, the frame is attached at the fixing elements via receiving an elongated portion of a respective and corresponding one of the fixing elements in a respective and corresponding one of the receiving portions of the frame. With the windshield installed in the vehicle, and with the frame attached at the fixing elements, a camera is disposed at the frame and received at structure of the frame, such that the camera views through the windshield via an aperture existing in the frame and a light transmissive aperture in a light absorbing layer of the windshield.