A method of assisting a driver of a vehicle with visualization of an ambient environment comprises generating a mirror image signal corresponding to a field of view of a traditional driving mirror. A surround image signal corresponding to a field of view of an ambient environment adjacent the vehicle is generated. A vehicle speed signal is generated. The mirror image signal, the surround image signal, and the vehicle speed signal are received, and at least one of a driver mirror signal and a driver surround signal is responsively produced. A video image corresponding to at least one of the driver mirror signal and the driver surround signal is selectively displayed to the driver. A frame rate of at least one of the mirror image signal and the surround image signal is adjusted by the signal processor responsive to the vehicle speed signal. A drive assist system is also provided.

To clear the line-of-sight (LOS) on a window in a lidar system within a vehicle, ultrasonic transducers are physically attached to the interior surface of the window to remove debris. When debris is detected at the window, the ultrasonic transducers are directed to vibrate at an ultrasonic frequency thereby generating an ultrasonic wave which causes the debris to bounce off the window. In some scenarios, the ultrasonic transducers vibrate with a particular phase shift to generate a travelling wave that causes the debris to sweep across the window. Additionally, windshield wipers, spray from a nozzle, and/or a hydrophobic or oleophobic coating may be used in combination with the ultrasonic transducers to remove the debris from the window.

To clear the line-of-sight (LOS) on a window in a lidar system within a vehicle, ultrasonic transducers are physically attached to the interior surface of the window to remove debris. When debris is detected at the window, the ultrasonic transducers are directed to vibrate at an ultrasonic frequency thereby generating an ultrasonic wave which causes the debris to bounce off the window. In some scenarios, the ultrasonic transducers vibrate with a particular phase shift to generate a travelling wave that causes the debris to sweep across the window. Additionally, windshield wipers, spray from a nozzle, and/or a hydrophobic or oleophobic coating may be used in combination with the ultrasonic transducers to remove the debris from the window.

To clear the line-of-sight (LOS) on a window in a lidar system within a vehicle, ultrasonic transducers are physically attached to the interior surface of the window to remove debris. When debris is detected at the window, the ultrasonic transducers are directed to vibrate at an ultrasonic frequency thereby generating an ultrasonic wave which causes the debris to bounce off the window. In some scenarios, the ultrasonic transducers vibrate with a particular phase shift to generate a travelling wave that causes the debris to sweep across the window. Additionally, windshield wipers, spray from a nozzle, and/or a hydrophobic or oleophobic coating may be used in combination with the ultrasonic transducers to remove the debris from the window.

Infant observation minor assembly with temperature display for attachment to a top portion of a rear vehicle seat includes a main panel having opposed front and rear surfaces and a minor embedded in the front surface thereof. The mirror assembly further includes a temperature display section defined on the front surface of the main panel. A positioning base is coupled to the rear surface of the main panel. The main panel is pivotably attached to the positioning base for allowing rotation about a horizontal axis and a vertical axis. A mounting harness attaches to the positioning base. The mounting harness removably attaches to the top portion of the rear vehicle seat to hold the minor assembly in a selected lateral and vertical position on the rear vehicle seat.

The present application relates to a method and apparatus for generating a graphical user interface indicative of a vehicle underbody view including a LIDAR operative to generate a depth map of an off-road surface, a camera for capturing an image of the off-road surface, a chassis sensor operative to detect an orientation of a host vehicle, a processor operative to generate an augmented image in response to the depth map, the image and the orientation, wherein the augmented image depicts an underbody view of the host vehicle and a graphic representative of a host vehicle suspension system, and a display operative to display the augmented image to a host vehicle operator. A static and dynamic model of the vehicle underbody is compared vs the 3-D terrain model to identify contact points between the underbody and terrain are highlighted.

A driver-assisting system for an industrial vehicle comprising: a first camera mounted on a vehicle cab for viewing an area in front of the vehicle; an image processing unit operatively connected to said first camera for receiving image data from said first camera; a display unit operatively connected to said image processing unit for displaying image to a user based on said image data; a control unit operatively connected to said first camera for modifying operating parameters of said first camera; wherein the first camera is adapted to provide a wide-angle field of vision, and in that the field of vision of said first camera relative to the vehicle can be adjusted by the control unit.

A vehicular vision system includes a camera disposed at the vehicle and a video display device disposed in the vehicle. Image data captured by the camera is provided to an ECU of the vehicle. A first portion of a scene that is within the field of view of the camera is not viewable by a driver of the vehicle and a second portion of the scene exterior of the vehicle that is within the field of view of the camera is viewable by the driver. Responsive at least in part to processing at the ECU of image data captured by the camera, the vehicular vision system determines an augmented reality overlay. Responsive to processing at the ECU of image data captured by the camera, the video display screen displays video images of the exterior scene. The video display device displays the augmented reality overlay at the displayed video images.

A shading device comprises: a shading member formed using a dimming glass plate capable of changing light transmittance, the shading member having a plate shape; a display apparatus being capable of transmitting light and disposed on a surface of the shading member, the surface being to face an operator during use of the shading member, in such a manner that a display portion faces the operator; an image pickup device to pick up, as an image, a region which an opposite surface of the surface faces, and generate image pickup data; a data processing circuit to generate display image data to be displayed on the display portion during use of the shading member, based on the image pickup data generated by the image pickup device; and a switch to change light transmittance of the dimming glass plate.

A shading device comprises: a shading member formed using a dimming glass plate capable of changing light transmittance, the shading member having a plate shape; a display apparatus being capable of transmitting light and disposed on a surface of the shading member, the surface being to face an operator during use of the shading member, in such a manner that a display portion faces the operator; an image pickup device to pick up, as an image, a region which an opposite surface of the surface faces, and generate image pickup data; a data processing circuit to generate display image data to be displayed on the display portion during use of the shading member, based on the image pickup data generated by the image pickup device; and a switch to change light transmittance of the dimming glass plate.