An antireflection structure includes an antireflection film provided on a front surface of a substrate. The antireflection film has a plurality of holes that are spatially and periodically arranged and pass through front and back surfaces of the antireflection film. A thickness and a relative dielectric constant of the antireflection film are set according to a relative dielectric constant and a thickness of the substrate and an incident angle of an electromagnetic wave. The thickness and the relative dielectric constant of the antireflection film are set for an electromagnetic wave incident at the angle so that, for example, an electromagnetic wave reflected by the antireflection film provided on the front surface of the substrate and an electromagnetic wave reflected by a back surface of the substrate deviate from each other by a half wavelength and cancel each other.

A head-up display device includes a casing provided inside an instrument panel. The casing includes an upper case constituting an upper part of the casing and provided with a fragile portion that is configured to be broken when an impact load is input to the casing from an upper side in a vehicle up-down direction, and a lower case constituting a lower part of the casing, provided with a light source unit configured to emit image information, and having a rigidity higher than that of the upper case.

To provide a transparent substrate with excellent appearance and with high visibility when observed from a predetermined direction, and a process for producing it. A transparent substrate comprising a substrate having a curved surface on at least a part of its front surface, and an antiglare layer formed on the center region and the edge region of the curved surface, wherein the absolute value of the difference between the 60 specular glossiness at the center region and the 60 specular glossiness at the edge region is higher than 20%.

A vehicular control system includes a forward viewing camera disposed at an in-cabin side of a windshield of a vehicle and viewing forward of the vehicle. Road curvature of a road along which the vehicle is traveling is determined responsive at least in part to processing by an image processor of image data captured by the camera. Responsive at least in part to processing of captured image data, a traffic lane of the road along which the vehicle is traveling is determined. Responsive at least in part to processing of captured image data, another vehicle present on the road and forward of the vehicle may be detected. Responsive at least in part to processing of captured image data, the system may determine that the detected other vehicle is travelling in a traffic lane to the left or to the right of the traffic lane along which the vehicle is traveling.

Disclosed is a vehicle display system (1) for displaying an image of surroundings of a vehicle. The vehicle display system (1) includes: a display (18a) configured to display an image thereon; a camera (4, 6, 8, 10) mounted on the vehicle and configured to image surroundings of the vehicle; and a display control unit (20) configured to subject an image captured by the camera to mask processing, using a mask image (MR, MF) including a semi-transparent portion (M3, M4, M14, M16) corresponding to a vehicle body, and a portion (M8, M18, M19) corresponding to a window of the vehicle and having a transmittance lower than that of the portion corresponding to the vehicle body, to generate a masked image (D), and cause the masked image to be displayed on the display.

There is provided with a moving body control apparatus. An image capturing unit captures a periphery of a moving body through a transmitting portion. A heater is capable of heating the transmitting portion. An air-conditioning unit switches an air-conditioning state in the moving body between an inside air circulation state and an outside air introduction state. A control unit controls the heater. The control unit increases an output of the heater during the operation in the case in which the air-conditioning state is set to the inside air circulation state so that the output of the heater will be larger than the output of the heater in the case in which the air-conditioning state is set to the outside air introduction state.

There is provided with a shooting system for a mobile object. A first shooting unit shoots surroundings of a mobile object via a first transmissive portion. A second shooting unit shoots surroundings of the mobile object via a second transmissive portion. A first heater is capable of heating the first transmissive portion. A second heater is capable of heating the second transmissive portion. A notification unit notifies a passenger of information. A control unit determines a malfunction of the first heater and the second heater, and causes the notification unit to give notification regarding an occurrence of the malfunction. The control unit suppresses the notification by the notification unit when it is determined that the second heater has malfunctioned compared to when it is determined that the first heater has malfunctioned.

A wiper system for a vehicle includes: a glass wiper disposed on a window glass of a vehicle; a motor providing driving power to the glass wiper; a camera capturing images of surroundings of the vehicle; and a camera wiper disposed on a camera lens of the camera and connected to the motor by a linkage to operate in association with the glass wiper such that the camera wiper swings back and forth over the camera lens while the glass wiper swings back and forth over the window glass.

A rear-view sensor system for a motor vehicle includes at least one sensor in the form of at least one of a rear-view camera and a lidar sensor positioned in the motor vehicle interior between a bodywork roof and a rear window, and a position-changing apparatus which moves the at least one sensor back and forth between a rest position and at least one operating position, where the at least one sensor is arranged in a recess in the rest position and is arranged right behind an upper part of the rear window in the at least one operating position.

A front quarter glass includes a window plate, a frame-like black ceramic layer on a peripheral portion of an interior side surface, and an anti-fogging film provided in a region excluding an entire peripheral portion of the window plate. A boundary is between the regions where the anti-fogging film is provided and not provided, has no perspective distortion, and has a boundary line of 10-200 m that is visually recognized by scattering of incoming light. An outer periphery of the anti-fogging film is located is located 8 mm (0.31 inch) inside from an inner periphery of the black ceramic layer in a first region. The first region is to less than 50% of an entire inner periphery including a lower front portion. The outer periphery of the anti-fogging film is located 8-35 mm (0.31-1.38 inches) inside the inner periphery of the black ceramic layer in a second region excluding the first region.