A system is provided that includes a housing [102], a display [100] attached to the housing [102], and a camera [104] attached to the housing located proximate the display [100], the camera [104] being configured to capture images over a 360-degree field of view in at least a first plane [110] through the housing and capture images over a 220-degree field of view in a second plane [112] perpendicular to the first plane [110].

A system is provided that includes a housing [102], a display [100] attached to the housing [102], and a camera [104] attached to the housing located proximate the display [100], the camera [104] being configured to capture images over a 360-degree field of view in at least a first plane [110] through the housing and capture images over a 220-degree field of view in a second plane [112] perpendicular to the first plane [110].

A night vision system including a thermal radiation night vision device for removably mounting to an exterior of a vehicle. The night vision device is to detect thermal radiation for objects present around the vehicle and to create a video with the detected objects. The created video may be communicated to a display device located within an interior region of the vehicle for displaying the video stream to a user driving the vehicle. The system may include a connector having a standard interface to easily and securely connect to a mounting device that is designed to mount to a roof, a light bar, a fender, a grill or a bumper of the vehicle. The mounting device may be configured to replace a portion of a frame of a spotlight mounted to the vehicle in order to secure the thermal radiation night vision device to the spotlight.

A vehicular driver monitoring system includes an interior rearview mirror assembly having a driver monitoring camera and first and second near-infrared light emitting elements accommodated by a mirror head. The light emitting elements are oriented at the mirror head so that (i) a beam of light emitted by the first light emitting element would be directed toward a driver's region of a left hand drive vehicle if the mirror assembly were installed in the LHD vehicle, and (ii) a beam of light emitted by the second light emitting element would be directed toward a driver's region of a right hand drive vehicle if the mirror assembly were installed in the RHD vehicle. The system enables and/or operates the first or second light emitting element for a driver monitoring function responsive to indication that the mirror assembly is installed or will be installed in a LHD vehicle or a RHD vehicle.

A vehicular driver monitoring system includes an interior rearview mirror assembly having a driver monitoring camera and first and second near-infrared light emitting elements accommodated by a mirror head. The light emitting elements are oriented at the mirror head so that (i) a beam of light emitted by the first light emitting element would be directed toward a driver's region of a left hand drive vehicle if the mirror assembly were installed in the LHD vehicle, and (ii) a beam of light emitted by the second light emitting element would be directed toward a driver's region of a right hand drive vehicle if the mirror assembly were installed in the RHD vehicle. The system enables and/or operates the first or second light emitting element for a driver monitoring function responsive to indication that the mirror assembly is installed or will be installed in a LHD vehicle or a RHD vehicle.

A vehicle glazing includes, in a peripheral zone, a traversing hole including an insert made of a material having a crystalline structure which is transparent in a range A of wavelengths in the infrared spectrum of at least from 9.5 μm to 10.5μm and the material of the insert is transparent in the visible region at a reference wavelength of between 500 nm and 600 nm.

A vehicle glazing includes, in a peripheral zone, a traversing hole including an insert made of a material having a crystalline structure which is transparent in a range A of wavelengths in the infrared spectrum of at least from 9.5 μm to 10.5μm and the material of the insert is transparent in the visible region at a reference wavelength of between 500 nm and 600 nm.

A camera monitor system includes a camera arm that has a camera with an image capture unit that is configured to capture an image of a desired field of view. A display is configured to display the desired field of view, and an IR LED illuminates at least a portion of the desired field of view. A controller is in communication with the image capture unit and the IR LED and select at least first and second regions of interest (ROI) from the captured image. The first ROI is indicative of an amount of ambient light. The controller determines a luminance of each of said first and second ROIs. The controller regulates an IR LED state of the IR LED based upon the first ROI luminance, and adjusts the IR LED state based upon the second ROI luminance.

A camera monitor system includes a camera arm that has a camera with an image capture unit that is configured to capture an image of a desired field of view. A display is configured to display the desired field of view, and an IR LED illuminates at least a portion of the desired field of view. A controller is in communication with the image capture unit and the IR LED and select at least first and second regions of interest (ROI) from the captured image. The first ROI is indicative of an amount of ambient light. The controller determines a luminance of each of said first and second ROIs. The controller regulates an IR LED state of the IR LED based upon the first ROI luminance, and adjusts the IR LED state based upon the second ROI luminance.

An occupant monitoring system for a vehicle comprises: a first light source to generate first infrared (IR) light illuminating at least part of the body of an occupant of a vehicle, wherein the first light source is time modulated with a duty cycle; an IR reflective surface to reflect second IR light reflected from the body of the occupant; and a first IR camera to receive at least part of the second IR light reflected by the IR reflective surface, wherein the first IR camera is time modulated with the duty cycle of the first light source.