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.

A system includes an optical fiber embedded in a windshield. The system includes a reflector embedded in the windshield and oriented to reflect light to a first end of the optical fiber. The system includes a sensor oriented to receive light from a second end of the optical fiber.

A system includes an optical fiber embedded in a windshield. The system includes a reflector embedded in the windshield and oriented to reflect light to a first end of the optical fiber. The system includes a sensor oriented to receive light from a second end of the optical fiber.

Asymmetric sectioned mirrors are presented. The mirrors include, for example, constant radius of curvature sections that are selected to increase the sizes and improve the definitions of images, for example images of children milling, walking and/or standing about either the front or alongside regions of a school bus. The mirrors may be asymmetric in either or both the horizontal and vertical directions. The mirrors may include a mounting system capable of using both ball mounts and tunnel mounts.

Asymmetric sectioned mirrors are presented. The mirrors include, for example, constant radius of curvature sections that are selected to increase the sizes and improve the definitions of images, for example images of children milling, walking and/or standing about either the front or alongside regions of a school bus. The mirrors may be asymmetric in either or both the horizontal and vertical directions. The mirrors may include a mounting system capable of using both ball mounts and tunnel mounts.

A vehicle having no wiper, wherein an image displaying section is provided at a forward portion of a driving seat of the vehicle, a capturing means to capture road conditions of a vehicle forward direction is provided in front of the vehicle, an image display surface of the image displaying section is located in interior side of the vehicle, a captured image captured by the capturing means is displayed on the image display surface, and a driver drives while viewing the captured image displayed on the image display surface.

A vehicle having no wiper, wherein an image displaying section is provided at a forward portion of a driving seat of the vehicle, a capturing means to capture road conditions of a vehicle forward direction is provided in front of the vehicle, an image display surface of the image displaying section is located in interior side of the vehicle, a captured image captured by the capturing means is displayed on the image display surface, and a driver drives while viewing the captured image displayed on the image display surface.

A display device includes a light collector including a camera unit having a camera and a window unit having a window, an optical unit that controls a path of light received from the window unit, and a transparent display panel including at least one pixel area that displays an image based on an image captured by the camera unit and at least one transmissive area that displays an image received from the optical unit.

A cross-view mirror for a vehicle includes a mirror assembly having a convex mirror lens providing a field of view for a driver of the vehicle and a support affixed to said mirror lens. The mirror lens includes a reflective portion reflecting light from outside of the mirror lens and a transparent portion configured to allow light to pass through the mirror lens to an area outside of the mirror lens. A light source is mounted to the mirror assembly to emit light through the transparent portion of the mirror lens. The light source is configured to illuminate the field of view provided by said mirror lens. In some embodiments, a sensor or camera detects/captures movement/images in front of the vehicle or to a side/rear of the vehicle.

A cross-view mirror for a vehicle includes a mirror assembly having a convex mirror lens providing a field of view for a driver of the vehicle and a support affixed to said mirror lens. The mirror lens includes a reflective portion reflecting light from outside of the mirror lens and a transparent portion configured to allow light to pass through the mirror lens to an area outside of the mirror lens. A light source is mounted to the mirror assembly to emit light through the transparent portion of the mirror lens. The light source is configured to illuminate the field of view provided by said mirror lens. In some embodiments, a sensor or camera detects/captures movement/images in front of the vehicle or to a side/rear of the vehicle.