A system mounted on a vehicle for detecting an obstruction on a surface of a window of the vehicle, a primary camera is mounted inside the vehicle behind the window. The primary camera is configured to acquire images of the environment through the window. A secondary camera is focused on an external surface of the window, and operates to image the obstruction. A portion of the window, i.e. window region is subtended respectively by the field of view of the primary camera and the field of view of the secondary camera. A processor processes respective sequences of image data from both the primary camera and the secondary camera.

A window glass anti-fogging structure includes an anti-fogging membrane and a heater. The structure is provided on a view-angle glass surface of a window glass of a vehicle such that the structure covers the view-angle glass surface. The view-angle glass surface is a part of an inner surface of the window glass within a range of an angle of view of a vehicle-installed camera provided in a vehicle interior space for taking images of a view outside of the vehicle through the view-angle glass surface.

A window glass anti-fogging structure includes an anti-fogging membrane and a heater. The structure is provided on a view-angle glass surface of a window glass of a vehicle such that the structure covers the view-angle glass surface. The view-angle glass surface is a part of an inner surface of the window glass within a range of an angle of view of a vehicle-installed camera provided in a vehicle interior space for taking images of a view outside of the vehicle through the view-angle glass surface.

There is provided an electric automobile including: a battery installed beneath a floor of a vehicle cabin; a driving unit provided at either one side, in a vehicle longitudinal direction, with respect to the battery; a high-voltage part disposed at the one side with respect to the battery and further toward a vehicle longitudinal direction inner side than an end portion at the one side of the driving unit and electrically connected to the driving unit; a control unit disposed at the one side with respect to the battery and further toward the vehicle longitudinal direction inner side than the end portion of the driving unit, and that controls autonomous driving of the vehicle; and an accessory part disposed further toward a vehicle longitudinal direction outer side than the end portion of the driving unit and independent from a control system that relates to traveling.

There is provided an electric automobile including: a battery installed beneath a floor of a vehicle cabin; a driving unit provided at either one side, in a vehicle longitudinal direction, with respect to the battery; a high-voltage part disposed at the one side with respect to the battery and further toward a vehicle longitudinal direction inner side than an end portion at the one side of the driving unit and electrically connected to the driving unit; a control unit disposed at the one side with respect to the battery and further toward the vehicle longitudinal direction inner side than the end portion of the driving unit, and that controls autonomous driving of the vehicle; and an accessory part disposed further toward a vehicle longitudinal direction outer side than the end portion of the driving unit and independent from a control system that relates to traveling.

The present invention provides an antifog laminate configured to be attached to an information acquisition region of a windshield that includes a laminated glass that is located opposite to an information acquisition device for acquiring information from the outside of a vehicle by emitting and/or receiving light, at least a portion of the laminated glass being curved, and the laminated glass having at least one information acquisition region through which the light passes, the antifog laminate including an antifog sheet including a sticky layer, a substrate film, and an antifog layer that are layered in this order, a sheet-shaped protective material that removably covers the antifog layer and is larger than the antifog layer, and a first protective sheet that removably covers the sticky layer.

A cleaning device according to an embodiment is a cleaning device that cleans a light transmission member provided on a camera. The cleaning device includes a filamentary member configured to contact the light transmission member and a rotation member configured to rotate the filamentary member such that the filamentary member moves along the surface of the light transmission member with the filamentary member in contact with the light transmission member.

The present disclosure relates to a method, a system, and a non-transitory computer readable medium for cleaning obstructions for the sensors of the autonomous vehicle. The method includes: detecting, via a sensor, obstructions that block the field of views for the sensors; retrieving real-time weather data outside the autonomous vehicle; estimating, based on the real-time weather data, the features of the obstructions; proposing, based on the estimation of the features of the obstructions and, one or more cleaning plans; querying, via a user interface, a selection by a user regarding the proposed cleaning plans; and executing, via a cleaning system for the sensors of the autonomous vehicle, the proposed cleaning plan selected by the user. User interaction may be vehicle-driven or user-driven.

An exemplary system for applying a water-repellent coating to the outside of a window of a vehicle includes at least one reservoir for a hydrophobic fluid, at least one wiper with a wiper blade, and a control device. A first line leads from the reservoir to the wiper. The first line extends at least over part of the length of the wiper and has, in the region of the wiper blade, at least one opening by way of which the hydrophobic fluid can be applied to the window. An exemplary method for applying a water-repellent coating to a window of a vehicle, includes, among other things, determining a status of the water-repellent properties of the window with reference to a threshold value of a quantity of water on the outer-facing surface of the window, transmitting a signal from the control device to initiate a communicating of a hydrophobic fluid from a reservoir to a wiper when the status indicates that the quantity of water on the window has reached the threshold value, communicating hydrophobic fluid from the reservoir to the wiper, distributing hydrophobic fluid on the window by means of a movement of the wiper.

An exemplary system for applying a water-repellent coating to the outside of a window of a vehicle includes at least one reservoir for a hydrophobic fluid, at least one wiper with a wiper blade, and a control device. A first line leads from the reservoir to the wiper. The first line extends at least over part of the length of the wiper and has, in the region of the wiper blade, at least one opening by way of which the hydrophobic fluid can be applied to the window. An exemplary method for applying a water-repellent coating to a window of a vehicle, includes, among other things, determining a status of the water-repellent properties of the window with reference to a threshold value of a quantity of water on the outer-facing surface of the window, transmitting a signal from the control device to initiate a communicating of a hydrophobic fluid from a reservoir to a wiper when the status indicates that the quantity of water on the window has reached the threshold value, communicating hydrophobic fluid from the reservoir to the wiper, distributing hydrophobic fluid on the window by means of a movement of the wiper.