A movable vehicle includes an access point functional unit that includes an antenna and functions as an access point by wirelessly communicating with a terminal device around the vehicle, and a notifier that notifies the surroundings that the vehicle is functioning as an access point.

A movable vehicle includes an access point functional unit that includes an antenna and functions as an access point by wirelessly communicating with a terminal device around the vehicle, and a notifier that notifies the surroundings that the vehicle is functioning as an access point.

A light source module for an atmosphere light and an ambient glass are provided. The light source module is disposed at an edge of a light-guiding glass. The light source module includes multiple light-guiding blocks and light-emitting diode (LED) particles. The multiple light-guiding blocks are arranged along a side edge of the light-guiding glass to constitute a curved light-guiding structure, and the curved light-guiding structure has a radian matching the side edge of the light-guiding glass. The LED particles are disposed at at least one end of the curved light-guiding structure, and lights emitted by the LED particles are uniformly dispersed by the light-guiding structure to be incident into the light-guiding glass.

A light source module for an atmosphere light and an ambient glass are provided. The light source module is disposed at an edge of a light-guiding glass. The light source module includes multiple light-guiding blocks and light-emitting diode (LED) particles. The multiple light-guiding blocks are arranged along a side edge of the light-guiding glass to constitute a curved light-guiding structure, and the curved light-guiding structure has a radian matching the side edge of the light-guiding glass. The LED particles are disposed at at least one end of the curved light-guiding structure, and lights emitted by the LED particles are uniformly dispersed by the light-guiding structure to be incident into the light-guiding glass.

A vehicle interior component includes a first surface, a second surface that is adjacent to the first surface, an edge disposed between the first surface and the second surface, and an operating element where an item of operating information can be input by the operating element. The operating element is disposed adjacent to the edge on the first surface and/or on the second surface and the operating element is nonvisible in an inoperative state and is visible in an operative state.

A vehicle interior component includes a first surface, a second surface that is adjacent to the first surface, an edge disposed between the first surface and the second surface, and an operating element where an item of operating information can be input by the operating element. The operating element is disposed adjacent to the edge on the first surface and/or on the second surface and the operating element is nonvisible in an inoperative state and is visible in an operative state.

An anti-motion sickness device fitted to a motor vehicle including a triaxial accelerometer to detect the vehicle accelerations along three axes and to emit a corresponding acceleration signal; a display component of light markers to form at least one first and second artificial horizon lines at first and second inner surface, respectively of the motor vehicle. The device includes a control unit for receiving the acceleration signals and for driving the display wherein the artificial horizon lines are aligned in a horizontal plane perpendicular or substantially perpendicular to the gravity vector regardless of vehicle accelerations. The control unit is configured to process the acceleration signals, prior to the control of the display to determine in real time an acceleration frequency according to each of the accelerometer axes and to drive the display only when the acceleration frequency is below a threshold frequency, below which the motion sickness likely occurs.

An anti-motion sickness device fitted to a motor vehicle including a triaxial accelerometer to detect the vehicle accelerations along three axes and to emit a corresponding acceleration signal; a display component of light markers to form at least one first and second artificial horizon lines at first and second inner surface, respectively of the motor vehicle. The device includes a control unit for receiving the acceleration signals and for driving the display wherein the artificial horizon lines are aligned in a horizontal plane perpendicular or substantially perpendicular to the gravity vector regardless of vehicle accelerations. The control unit is configured to process the acceleration signals, prior to the control of the display to determine in real time an acceleration frequency according to each of the accelerometer axes and to drive the display only when the acceleration frequency is below a threshold frequency, below which the motion sickness likely occurs.

A fire extinguishing system is provided for a tire of a vehicle. The fire extinguishing system includes fire extinguishing injectors filled with fire extinguishing chemicals and installed in the vehicle to be able to inject the fire extinguishing chemical to the tire. A fire detection line is installed to connect between the fire extinguishing injectors. Each of the fire extinguishing injectors is configured to inject the fire extinguishing chemical when a fire of the tire is detected through the fire detection line.

A vehicle is provided to analyze a signal received by a communicator and identify a first electronic device that transmits the received signal and a second electronic device that will transmit the received signal. The vehicle identifies a lighting algorithm that corresponds to an analysis result of the received signal and sequentially turns on a plurality of lighting devices based on the identified lighting algorithm.