A heating plate 10 includes: a pair of glass plates 11, 12; a conductive pattern 40, 70 disposed between the pair of glass plates 11, 12 and defining a plurality of opening areas 43, 73; and a joint layer 13, 14 disposed between the conductive pattern 40, 70 and at least one of the pair of glass plates 11, 12; wherein the conductive pattern 40, 70 includes a plurality of connection elements 44, 74 that extend between two branch points 42, 72 to define the opening areas 43, 73; and a total value of lengths of straight line segments connecting the two branch points 42, 72 is less than 20% of a total value of the plurality of connection elements 44, 74.

A sensor lens cleaning system for a cylindrical sensor having a sensor lens surface includes an extended member having a first end coupled to the cylindrical sensor and a second end opposite the first end, a nozzle coupled to the second end of the extended member, an actuator coupled to the extended member and configured to control the extended member, and a controller in electronic communication with the actuator and configured to communicate an actuator control signal to the actuator. The nozzle generates an air stream directed at the sensor lens surface.

A foreign object detecting system and a method are provided. A control circuit controls a light transmitter and a light receiver. The light transmitter is disposed adjacent to a detected object and emits a light signal toward the detected object. The light receiver is disposed adjacent to the detected object in a path along which the light signal reflected by the detected object travels. The light receiver receives the light signal reflected to the light receiver. In a pre-operation, the control circuit defines the light signal received by the light receiver when the foreign object is not on the detected object as a first reflected light signal. In a detection operation, the control circuit determines that a difference exists between the light signal currently received by the light receiver and the first reflected light signal, the control circuit determines that the foreign object is on the detected object.

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.

One general aspect includes a system having one or more heat pads installed at a vehicle, the one or more heat pads configured to provide infrared energy transmissions to a vehicle component to defrost, defog, or both defrost and defog a surface of the vehicle component. The system may also carry out the following steps: (a) determining that ice or fog or both ice and fog has accumulated on the surface of the vehicle component; and (b) based on the determination made in step (a), activating the one or more heat pads to defrost, defog, or both defrost and defog a surface of the vehicle component.

A unitary defroster system for a motor vehicle windshield comprises an instrument panel substrate, an HVAC supply source, and an air supply plenum in fluid communication with the HVAC supply source and terminating in a plurality of individually configured defroster nozzle ducts conjoined with the instrument panel substrate and aligned in a substantially linear row parallel to and proximate an interior surface of the windshield. The unitary defroster system is formed by an additive manufacturing process and at least two of the ducts are configured and arranged to deliver a different air flow to the interior surface of the windshield.

A camera assembly for a vision system for a vehicle includes a camera module configured to be disposed at an exterior portion of the vehicle so as to have a field of view exterior of the vehicle. The camera module includes a housing and a lens barrel supporting a lens. A heating device is configured to attach at an exterior of the lens barrel. The heating device includes a heating element that at least partially circumscribes the lens barrel when the heating device is attached at the lens barrel. The heating device includes an electrical lead configured to electrically connect to an electrical connector of the vehicle when the camera module is disposed at the exterior portion of the vehicle.

There is disclosed a valve assembly for washing cameras or sensors of an autonomous vehicle. The valve assembly includes a single fluid injector having a fluid inlet, a fluid outlet, and a fluid passage in fluid communication with the fluid inlet and the fluid outlet. A cup is disposed over an upstream portion of the fluid injector, relative to a direction of fluid flow through the fluid injector. A lower housing is disposed over and surrounds a downstream portion of the fluid injector, relative to the direction of fluid flow therethrough. A bracket member extends from the lower housing. The bracket member is configured for connecting to an anchor member for attachment within the autonomous vehicle. In this way, the valve assembly may be easily secured within a vehicle for providing a desired amount of fluid to the lens of the vehicle camera or sensor.

There is disclosed a valve assembly for washing cameras or sensors of an autonomous vehicle. The valve assembly includes a single fluid injector having a fluid inlet, a fluid outlet, and a fluid passage in fluid communication with the fluid inlet and the fluid outlet. A cup is disposed over an upstream portion of the fluid injector, relative to a direction of fluid flow through the fluid injector. A lower housing is disposed over and surrounds a downstream portion of the fluid injector, relative to the direction of fluid flow therethrough. A bracket member extends from the lower housing. The bracket member is configured for connecting to an anchor member for attachment within the autonomous vehicle. In this way, the valve assembly may be easily secured within a vehicle for providing a desired amount of fluid to the lens of the vehicle camera or sensor.

The disclosure relates to a hydrophobic mirror. The hydrophobic mirror includes a support; a mirror body set in the support; and a hydrophobic film located on a surface of the mirror body. The hydrophobic film comprises a flexible substrate and a hydrophobic layer. The flexible substrate comprises a flexible base and a patterned first bulge layer located on a surface of the flexible base. The hydrophobic layer located on the surface of the patterned first bulge layer.