A device for dispensing liquid onto a target area of a vehicle surface is described, and includes a mixing valve that is in communication with a pressurized fluidic supply system via a fluidic distribution system, and a controller. The mixing valve includes an outlet orifice that is disposed proximal to the target area, and the mixing valve includes first and second valve conduits that are fluidly connected to the outlet orifice via a mixing portion. The first valve conduit includes a first control valve, and the second valve conduit includes a second control valve. The fluidic distribution system includes a first fluidic conduit and a second fluidic conduit. The controller is operatively connected to the fluidic supply system, and the first and second control valves.

A vehicle imaging apparatus includes an imaging device capable of imaging an imaging side thereof; a transparent heater that is provided at least in a range of an angle of view of the imaging device at the imaging side of the imaging device, that generates heat by being energized, and that heats an imaging side of the imaging device; and a resistance member that is provided at an electrical circuit including the heater, and that generates heat by being energized, an electrical resistance value of the resistance member is increased along with increase in temperature of the resistance member due to heat generation such that a current value of current that flows to the heater is decreased.

A vehicle imaging apparatus includes an imaging device capable of imaging an imaging side thereof; a transparent heater that is provided at least in a range of an angle of view of the imaging device at the imaging side of the imaging device, that generates heat by being energized, and that heats an imaging side of the imaging device; and a resistance member that is provided at an electrical circuit including the heater, and that generates heat by being energized, an electrical resistance value of the resistance member is increased along with increase in temperature of the resistance member due to heat generation such that a current value of current that flows to the heater is decreased.

A method comprising: (a) heating a light module of a vehicle with a heater; (b) monitoring a temperature of the light module; (c) activating a communication sequence; and (d) performing the communication sequence so that a message is conveyed between a controller of the light module and a controller of the vehicle.

A vehicle monitoring apparatus including: a camera disposed in a vehicle lamp; a guide duct configured to guide outside air introduced into the vehicle; and a nozzle connected to the guide duct and configured to discharge the air to a front side of the camera, thereby improving stability and reliability.

A sensor assembly includes a housing including a first chamber and a second chamber fluidly connected to the first chamber, a first sensor disposed in the second chamber and including a first sensor window facing outward from the second chamber, and a second sensor outside and fixed relative to the first chamber and the second chamber. The second sensor includes a second sensor window. The housing includes an intake from an exterior environment to the first chamber, a first outlet from the second chamber to the exterior environment, and a second outlet from the second chamber to the exterior environment. The first outlet is positioned to direct air across the first sensor window, and the second outlet is positioned to direct air across the second sensor window.

The disclosure provides for a wiper system for cleaning a surface of a sensor housing, such as a sensor housing positioned on top of a vehicle. The wiper system includes a plurality of windows spaced around a sensor housing, and a plurality of wipers positioned around the sensor housing, each of the wipers includes a wiper blade configured to clean a corresponding window of the plurality of windows. The wiper system further includes a drive system including a moveable part coupled to a motor. The motor is configured to drive the drive system to simultaneously rotate the plurality of wipers around the sensor housing such that the plurality of wipers remove debris from the plurality of windows.

The disclosure provides for a wiper system for cleaning a surface of a sensor housing, such as a sensor housing positioned on top of a vehicle. The wiper system includes a plurality of windows spaced around a sensor housing, and a plurality of wipers positioned around the sensor housing, each of the wipers includes a wiper blade configured to clean a corresponding window of the plurality of windows. The wiper system further includes a drive system including a moveable part coupled to a motor. The motor is configured to drive the drive system to simultaneously rotate the plurality of wipers around the sensor housing such that the plurality of wipers remove debris from the plurality of windows.

Provided herein is a headlamp assembly comprising a housing that encloses: a sensor that acquires data associated with a surrounding environment; a light source that illuminates a field of view comprising a portion of the surrounding environment; and one or more processors that analyze the acquired data and determine a direction, field of view, power, or an intensity of the illumination of the portion based on the analyzed data.

A vehicle wash system includes a manifold having pump compartments separated by dividers. The manifold is constructed of an electrically conductive material to shield electromagnetic fields. A pump is disposed within each compartment and configured to generate the electromagnetic fields when activated. A power connector is coupled to the manifold. The power connector is configured to power each pump and is a common ground for the manifold. An upper level sensor is proximate to the manifold. A lower level sensor is proximate to the manifold. The upper level sensor and the lower level sensor are configured to sense fluid level in a washer bottle.