A movable body has a monitoring device that monitors a surrounding environment of the movable body through a window member. The movable body includes a heating device that heats a portion of the window member within a monitoring area of the monitoring device, an air conditioning device, and a control device. The monitoring device includes a detector that detects the surrounding environment, and a base member that faces an inner wall of the window member and is disposed such that a detection surface of the detector is located within a space between the base member and the window member. The space is in communication with the inside of the movable body, and the control device sets the driving force of the air conditioning device to be greater when a decrease in heating performance of the heating device is detected.

An air-conditioning unit includes an air-conditioning case including an opening through which air flows, a cooler disposed in the air-conditioning case to cool air flowing to the opening, a heater disposed in the air-conditioning case to heat air flowing to the opening, and an adjusting member disposed to cover the opening and adjusting airflow passing through the opening. The adjusting member is produced separately from the air-conditioning case and includes a first region and a second region. The second region includes a high resistance member giving higher resistance to the airflow than the first region. The first region includes a low resistance member giving lower resistance to the airflow than the second region. The low resistance member is a partition dividing the first region into plural air passing parts through which air flows. The high resistance member is a plate member including a part to interfere the airflow.

Energy management techniques for heating or cooling a surface of a component of a vehicle comprise determining a heating lag time indicative of a lag time for a surface element of the vehicle component to heat to a first target temperature in response to a power on-off or power off-on modulation of a heat transfer component, determining a cooling lag time indicative of a lag time for the surface element to cool to a second target temperature in response to a power on-off or power off-on modulation of the heat transfer component, and controlling power-on and power-off times of the heat transfer component based on the determined heating and cooling lag times so as to not require a temperature sensor for feedback-based temperature control.

An entertainment system for a vehicle, the system including: a sound emitting module including multiple sound emitting units, wherein the sound emitting module is adapted to be arranged such that the multiple sound emitting units are distributed along the transverse extension of a windshield of the vehicle and to emit sound towards the windshield, and a display device arranged between the sound emitting module and an occupant seating position, wherein the display device is arranged to cover the sound emitting module as seen from the occupant seating position. The disclosed entertainment system provides the advantage of integrating a more advanced sound system in the form of a sound emitting module including multiple sound emitting units.

An anti-fogging film, an anti-fogging component, an adjustment method therefor and a vehicle-mounted device, the anti-fogging film including: a conversion film layer and an excitation film layer, which is located on the conversion film layer; the conversion film layer carries out reversible conversion between a hydrophilic state and a hydrophobic state according to characteristic parameters of the excitation film layer.

A roof module for forming a vehicle roof on a motor vehicle, the roof module may have a panel component whose outer surface at least partially forms the roof skin of the vehicle roof, the roof module having at least one environment sensor configured to send and/or receive electromagnetic signals for detecting the vehicle environment. At least one reflector element at which the electromagnetic signals can be reflected is associated with the environment sensor.

An air conditioning system for motor vehicles designed to blow an air toward a glass window at the time of entry into a defrosting mode. The air conditioning system includes a rear seat controller configured to independently control a temperature and a volume of an air blown toward a rear seat region of a vehicle room, and a control unit configured to, at the time of entry into the defrosting mode, stop cooling or heating of the rear seat region and cause the rear seat controller to display a specific symbol indicating that the cooling or heating of the rear seat region is stopped due to the entry into the defrosting mode.

A vehicle air-conditioning device is a heat pump type vehicle air-conditioning device including an external heat exchanger that performs heat exchange between refrigerant flowing the inside thereof and outside air. With the vehicle air-conditioning device, a controller functions as a temperature-difference calculation unit that calculates the temperature difference ΔT between the refrigerant in a refrigerant flow path on the exit side of the external heat exchanger and the outside air, and in addition, the controller functions as a frost formation determination unit that determines that frost formation is caused on the external heat exchanger on the basis of the elapsed time to of a state in which the temperature difference ΔT is equal to or larger than a frost-formation temperature difference at which the frost formation may be caused on the external heat exchanger.

An apparatus comprising a camera sensor and a processor. The camera sensor may be configured to generate a video signal based on a targeted view in a vehicle. The processor may be configured to receive one or more status signals from one or more sensors. The processor may be configured to detect a type of obstruction of a window of the vehicle visible in the video signal based on (i) a classification of information in the video signal and (ii) one or more of the status signals.

The present invention provides a windowpane defogging device for a motor vehicle which, upon generation of a fog on a windowpane, comes into a defogging mode to remove the fog generated on the windowpane. The windowpane defogging device includes a relative humidity detecting unit configured to detect a windowpane relative humidity of a driver seat view field region of the windowpane and a windowpane relative humidity of a passenger seat view field region of the windowpane, and a control unit configured to control entry into the defogging mode by determining the generation or non-generation of the fog on the windowpane based on the windowpane relative humidity of the driver seat view field region and the windowpane relative humidity of the passenger seat view field region inputted from the relative humidity detecting unit.