A heating system for a vehicle is provided. In order to permit provision of efficient heating of a vehicle window pane of an electric vehicle, the system has two at least mainly transparent panes, wherein an outer pane is arranged on the outside of the vehicle and an inner pane is arranged on the inside of the outer pane to form an intermediate space, and at least one controllable infrared source is configured to irradiate infrared radiation into the intermediate space so that the infrared radiation at least partially irradiates the outer pane.

A device and method for protecting an optical sensor of a vehicle are disclosed, wherein the sensor is protected from environmental pollutants which may adhere to an optical surface of the sensor if the sensor is exposed to them, and wherein the environmental pollutants are kept away from the sensor by an ultrasonic cleaning of the sensor surface using an ultrasonic field. The ultrasonic field of the ultrasonic cleaning is emitted by a protection device into the air to provide a protection zone around the optical surface of the sensor such that a contact of the optical surface with the environmental pollutants is avoided, wherein the environmental pollutants are moved and/or destroyed in the air away from the sensor if they enter the protection zone), and wherein the protection zone provides a contactless cleaning of the sensor.

An apparatus includes an exterior surface including an aperture, a sensor defining a field of view oriented through the aperture, a nozzle shell on the exterior surface and including a nozzle panel facing the aperture, and a heating element disposed in or on the nozzle panel. The nozzle panel includes a nozzle.

In some embodiments, a LIDAR system may include at least one processor configured to control at least one light source for projecting light toward a field of view and receive from at least one first sensor first signals associated with light projected by the at least one light source and reflected from an object in the field of view, wherein the light impinging on the at least one first sensor is in a form of a light spot having an outer boundary. The processor may further be configured to receive from at least one second sensor second signals associated with light noise, wherein the at least one second sensor is located outside the outer boundary; determine, based on the second signals received from the at least one second sensor, an indicator of a magnitude of the light noise; and determine, based on the indicator the first signals received from the at least one first sensor and, a distance to the object.

In some embodiments, a LIDAR system may include at least one processor configured to control at least one light source for projecting light toward a field of view and receive from at least one first sensor first signals associated with light projected by the at least one light source and reflected from an object in the field of view, wherein the light impinging on the at least one first sensor is in a form of a light spot having an outer boundary. The processor may further be configured to receive from at least one second sensor second signals associated with light noise, wherein the at least one second sensor is located outside the outer boundary; determine, based on the second signals received from the at least one second sensor, an indicator of a magnitude of the light noise; and determine, based on the indicator the first signals received from the at least one first sensor and, a distance to the object.

The invention relates to a cleaning device (20) for a lens glass (10) in particular of a vehicle, with an optically transparent lens glass (10), with a hydrophobic and dirt-repelling, optically transparent coating (25), which is applied on an outer side (11) of the lens glass (10), with at least one vibration element (21), which is coupled with the lens glass (10), wherein the at least one vibration element (21) can be activated by a control device (40), and with an optically transparent anti-fog device (30), which is arranged at an inner side (12) of the lens glass (10). Furthermore, a vehicle with at least one cleaning device (20) is specified within the scope of the invention.

The invention relates to a cleaning device (20) for a lens glass (10) in particular of a vehicle, with an optically transparent lens glass (10), with a hydrophobic and dirt-repelling, optically transparent coating (25), which is applied on an outer side (11) of the lens glass (10), with at least one vibration element (21), which is coupled with the lens glass (10), wherein the at least one vibration element (21) can be activated by a control device (40), and with an optically transparent anti-fog device (30), which is arranged at an inner side (12) of the lens glass (10). Furthermore, a vehicle with at least one cleaning device (20) is specified within the scope of the invention.

The invention relates to a cleaning device (10) for cleaning at least one cover glass (2) of a headlamp, in particular a vehicle headlamp (1), wherein the cover glass (2) comprises on its outer side (3) a hydrophobic and dirt-repelling coating (20) and at least one vibration element (11) is fastened to the at least one cover glass (2), wherein the at least one vibration element (11) can be activated by a control device (30). The scope of the invention further includes a headlamp, in particular a vehicle headlamp (1), with a cleaning device (10).

A device (1) for eliminating deposits and/or precipitation on a substrate (10, 110) comprises at least one transducer (20, 120) captively connected to the substrate (10, 110) by a connection layer (30), wherein the connection layer (30) is arranged between the substrate (10, 110) and the transducer (20, 120). The invention provides for the connection layer (30) to comprise a connection material (31) and a filling material (32). Furthermore, an optical system for environment monitoring comprising an optical monitoring device comprising a lens and/or an observation window and the above device is provided, wherein the lens or the observation window is formed by the substrate.

The present disclosure relates to a portable, hand held and/or mountable control device for remote controlling at least one device provided by a vehicle. The control device comprises one or more control applications and indicator icons on a touch sensitive display and one or more motion and orientation detection sensors. The control application provided as keys on the display is selected based on user input and based on the user selected control application the device to be controlled can be controlled wirelessly by voice, steering tilt or motion based operation of the control device. Additionally, the control device can determine a fault or a correct completion of controlling by monitoring the devices. The present disclosure also provides a method for remote controlling the at least one device provided by the vehicle.