A movable body comprising a monitoring device configured to monitor a surrounding environment of the movable body through a window member, a heating device configured to heat a portion of the window member within a monitoring area of the monitoring device, an air conditioning device, and a control device, wherein operation modes of the control device include a first mode in which both the heating device and the air conditioning device are driven, and a second mode in which the driving force of the air conditioning device is smaller than that in the first mode, and the control device evaluates the degree of fog on the portion of the window member and determines one of the operation modes based on the result of evaluation.

An HVAC case configured to heat airflow for a vehicle HVAC system. The HVAC case has a defrost outlet, a primary demist outlet, a secondary demist outlet, and an airflow control door. The airflow control door is configured to control airflow through each one of the defrost outlet, the primary demist outlet, and the secondary demist outlet.

An apparatus for heating a window of a vehicle comprises an electrical storage unit configured to store an electrical charge and a plurality of heating circuits disposed on a window of the vehicle. The apparatus further comprises a controller configured to monitor the electrical charge of the electrical storage unit and selectively activate one or more of the heating circuits based on the electrical charge.

A side mirror system for a vehicle is provided. The side mirror system includes a camera disposed outside a vehicle and capturing a peripheral area of the vehicle, an electronic side mirror including a mirror panel and a display panel, a moving device moving the electronic side mirror to an inside or an outside of the vehicle, and at least one control circuit electrically connected to the camera, the electronic side mirror, and the moving device, wherein the at least one control circuit controls the electronic side mirror such that the electronic side mirror outputs an image obtained by the camera through the display panel or the peripheral area of the vehicle is reflected by the mirror panel and controls the moving device such that the electronic side mirror moves from the outside of the vehicle to the inside of the vehicle, when a specified condition is satisfied.

A side mirror system for a vehicle is provided. The side mirror system includes a camera disposed outside a vehicle and capturing a peripheral area of the vehicle, an electronic side mirror including a mirror panel and a display panel, a moving device moving the electronic side mirror to an inside or an outside of the vehicle, and at least one control circuit electrically connected to the camera, the electronic side mirror, and the moving device, wherein the at least one control circuit controls the electronic side mirror such that the electronic side mirror outputs an image obtained by the camera through the display panel or the peripheral area of the vehicle is reflected by the mirror panel and controls the moving device such that the electronic side mirror moves from the outside of the vehicle to the inside of the vehicle, when a specified condition is satisfied.

The camera module has a lens assembly comprising a body and a heating element with an optically transparent coating applied to the body for heating it as electric current flows for removing water-based obstructions. The module includes a power supply for supplying electric current to the optically transparent coating through conductors, and a lens barrel (for receiving the body comprising a passageway for the conductors extending within the lens barrel towards the lens body. The method comprises applying to the lens body, high- and low-refractive index layers and an aluminium-doped zinc oxide layer.

An imaging device according to the present disclosure includes a housing, a lens unit, a heater, an imaging unit, a temperature sensor, and a heater control unit. The lens unit is attached to the housing. The heater is provided in the lens unit. The imaging unit, the temperature sensor, and the heater control unit are housed in the housing. The imaging unit outputs an optical image formed by a light flux transmitted through the lens unit as an image signal. The heater control unit controls the heater in accordance with a temperature detection value by the temperature sensor.

A method for identifying a cause of blockage in a sequence of images provided by a camera of a vehicle, the method comprising iteratively: S10) acquiring an image of the camera; successively acquired images forming a sequence of images; S20) detecting a blockage in last images of the sequence of images; S60) determining whether it is day-time or night-time based on time information; if it is determined that it is night-time: S82) determining whether toggling front light(s) of the vehicle on/off causes a change in images acquired by the camera; and S84) in this case, determining that for the current iteration, the cause of the blockage is presumably the road being dark. A computer program for performing said method, a computer-readable recording medium containing such computer program, a driving assistance system capable of executing said method.

A plastic window includes a plastic window body, a conductive portion, a first bus bar, and a second bus bar. The window body is formed in a plate shape and has a first surface and a second surface on both sides thereof. The conductive portion and the first bus bar are made of a conductive material and disposed on the second surface of the window body. The first bus bar is electrically connected to the conductive portion. The second bus bar is made of a conductive metal strip and disposed to be electrically connected to the first bus bar. The second bus bar has a main body, first fixing portions, and second fixing portions. The first fixing portions fix the main body to the second surface. The second fixing portions extend from the main body along the second surface and are attached to the first bus bar.

In an embodiment, the present disclosure is directed to an assembly for preventing condensation on a surface of an object. The assembly includes a condensation mitigation device, an ambient temperature sensor, a humidity sensor, and a processor. The processor determines dewpoint temperatures for different times, the determination being based on the ambient temperature and the humidity. The processor then determines a regression for the determined dewpoint temperatures. A control signal for activating the condensation mitigation device is transmitted based on the regression for the determined dewpoint temperatures.