A vehicular driver monitoring system includes an interior prismatic rearview mirror assembly and a camera disposed at the interior prismatic rearview mirror assembly behind and viewing through a prismatic mirror reflective element into the interior cabin of the vehicle. Supplemental sources of near infrared illumination are disposed at the mirror assembly that are operable to emit near infrared light to illuminate at least the driver-side front seating area within the interior cabin of the vehicle. Presence of the camera behind the prismatic mirror reflective element is not readily apparent to an occupant of the vehicle. The camera at least (a) views the driver-side front seating area of the vehicle and (b) views a passenger-side front seating area of the vehicle. The driver of the equipped vehicle is monitored via processing at the processor of image data captured by the camera.

A vehicle safety system that provides a clear view of blind spots, approaching motor vehicles in oncoming and peripheral lanes when attempting to pass on a two-lane highway consists of a pair of side mirror-mounted cameras, a split viewing screen/monitor, a plurality of controls, and a microcontroller. The visual data received from the pair of side mirror-mounted cameras is displayed on the split viewing screen/monitor. Thus, the user can view oncoming motor vehicles. Preferably, the split viewing screen/monitor is mounted adjacent to a rear-view mirror of a motor vehicle. The plurality of controls allows the user to control the content displayed on the split viewing screen/monitor. When front-facing cameras and rear-facing cameras are available, the user is provided with information regarding obstacles surrounding the motor vehicle. The pair of front-facing cameras and the pair of rear-facing cameras are especially beneficial when backing out of parking spaces and driving through intersections.

A vehicular interior rearview mirror assembly includes a mirror reflective element having a glass substrate with a planar front surface and a circumferential edge along the periphery of the glass substrate. A mounting element is disposed at the rear of the mirror reflective element and includes a pivot element that is configured to pivotally mount the mirror reflective element at the vehicle. A plastic molding receives the mirror reflective element therein such that a portion of the plastic molding is circumferentially disposed about the circumferential edge of the glass substrate without overlapping onto the front surface of the glass substrate. The portion of the plastic molding provides a curved rounded transition from the front surface of the glass substrate to a side surface of the plastic molding. The plastic molding includes at least a portion of a mirror housing of the interior rearview mirror assembly.

A vehicular control system includes a camera having an exterior field of view at least rearward of the vehicle and operable to capture image data. A trailer is attached to the vehicle and image data captured by the camera includes image data captured when the vehicle is maneuvered with the trailer at an angle relative to the vehicle. The vehicular control system determines a trailer angle of the trailer and is operable to determine a path of the trailer responsive at least to a steering angle of the vehicle and the determined trailer angle of the trailer. The vehicular control system determines an object present exterior of the vehicle and the vehicular control system distinguishes a drivable surface from a prohibited space, and the vehicular control system plans a driving path for the vehicle that neither impacts the object nor violates the prohibited space.

A vision system for a vehicle includes a forward viewing camera. Responsive at least in part to processing by an image processor of image data captured by the forward viewing camera, at least one road characteristic of a road along which the vehicle is traveling is detected. Responsive at least in part to processing by the image processor of image data captured by the forward viewing camera, other vehicles exterior the equipped vehicle are detected. Responsive at least in part to processing by the image processor of image data captured by the forward viewing camera, road curvature of the road along which the vehicle is traveling is determined. Data derived from image data captured by the forward viewing camera may be wirelessly communicated from the vehicle to a remote data receiver located remote from the vehicle.

A motor vehicle includes a left side view camera attached to the left lateral side of the body and having a field of view in a rearward direction. A right side view camera is attached to the right lateral side of the body and has a field of view in a rearward direction. There is a right back up camera and a left back up camera. An optics module receives resulting video signals and produces light fields such that the light fields are reflected off of windows of the motor vehicle and are then visible to a driver of the motor vehicle as virtual images.

Provided is an electronic device whose display quality is independent of environment light. The electronic device is provided with an optical sensor, an acceleration sensor, and the like so that information including the brightness of external light, the angle of external light incident on the electronic device, and the orientation of the display portion in the electronic device is obtained, and the luminance and color tone of the display portion in the electronic device are corrected on the basis of the information. As the correcting method, calculation using a neural network is performed using the luminance and color tone meeting the preference of the user as teacher data and the obtained information as input data. The calculation result is reflected on the luminance and color tone of the display portion in the electronic device, whereby an image with display quality that suits the user's preference can be displayed.

A vehicular camera system includes a camera module having an imager assembly, a main circuit board and a camera housing. The imager assembly includes (i) an imager disposed on an imager circuit board and (ii) a lens holder having a lens assembly that includes a lens barrel accommodating a lens. The imager assembly includes a flexible ribbon cable that electrically connects to an electrical connector at a multilayered PCB of the main circuit board. The camera housing includes an upper cover and a lower cover and includes a forward portion and a rearward portion. The main circuit board is accommodated within the forward and rearward portions, and the imager is disposed at the rearward portion and is not disposed at the forward portion of the camera housing. The lens holder is attached at the upper cover of the camera housing.

Disclosed is a convenience equipment pull-out device for a vehicle. The convenience equipment pull-out device includes: a housing mounted on a headliner of the vehicle, a body which is mounted on the housing and coupled to a movable driving portion and to a plurality of movement guides. In particular, the body slides along the movement guides when the driving portion is driven. The device further includes a pull-out portion rotatably coupled to the body and selectively pulled out towards the interior of the vehicle while a hinge region connected to the body slides along a guide rail member of the housing.

The disclosure generally pertains to a visor system of a vehicle. The visor system may include a multifunctional visor having a multilayer stack. A first layer of the multilayer stack may include a material whose optical transmittance is modifiable in response to a control signal provided by a controller, a second layer containing a material whose optical reflectance is modifiable in response to another control signal provided by the controller, and a third layer, which is interposed between the first layer and the second layer and includes a display system that turns optically transparent in response to another control signal provided by the controller. An occupant of the vehicle can make a selection to place the multifunctional visor in any of various states, such as a mirror state, a visor state, or a display state (for displaying images such as a speedometer and/or a GPS route map).