Disclosed is a fallen object detection apparatus and method for controlling a component to continuously provide a service, provided by a communication device, when the communication device has fallen inside a vehicle. A fallen object detection apparatus inside a vehicle includes: a monitor configured to monitor an inside of the vehicle in which a passenger and an object are present: an identifier configured to identify that the object is a communication device capable of being connected to the component inside the vehicle in response to determination that the object is determined to have fallen on the basis of a monitoring result; and a processor configured to connect the object with the component and control the component to continuously provide a service, provided by the object, when the object is identified to be the communication device.

A device for interior illumination for a vehicle includes an array formed by multiple light sources, with which an ambient illumination and a reading illumination can be generated inside the vehicle, an additional lamp unit with which exclusively an ambient illumination can be generated inside the vehicle, and a control unit for controlling the light sources and the additional lamp unit in three modes. The control unit is designed and configured in such a way that in the first mode the light sources are controlled in such a way that exclusively a reading illumination is generated inside the vehicle; in the second mode the light sources and the additional lamp unit are controlled in such a way that exclusively an ambient illumination is generated inside the vehicle; and in the third mode the control unit simultaneously activates the first and second modes for simultaneously generating an ambient illumination and a reading illumination.

A light emitting device, which includes a plurality of light emitting elements each having a different chromaticity of emission light, to emit mixed light produced by mixing the respective emission light of the plurality of light emitting elements together, includes a receiving section to obtain command information on the mixed light, a driving section to perform a PWM drive on the plurality of light emitting elements on the basis of the command information, and a storing section to store correction information to be set on the basis of measurement results on the respective emission light of the plurality of light emitting elements. The driving section is being configured in such a manner as to, on the basis of the correction information, correct a duty ratio in the PWM drive to be set in accordance with the command information, and perform the PWM drive on the plurality of light emitting elements.

A method for controlling an autonomous vehicle is disclosed. A vehicle control method for controlling a following vehicle that follows a preceding vehicle, according to an embodiment of the present invention, includes receiving target driving state information; projecting a distance marker image forward through a projector provided in a vehicle;

detecting a preceding vehicle and the distance marker image through a camera provided in the vehicle; acquiring actual driving state information of the vehicle on the basis of a positional relation between the preceding vehicle and the distance marker image; calculating an error between the target driving state information and the actual driving state information; and controlling the vehicle such that the error decreases.

One or more of an autonomous vehicle, a user terminal and a server of the present invention can be associated with AI, robots, augmented reality (AR) and virtual reality (VR).

A vehicle interior lighting system includes an illuminating unit provided in an interior of a vehicle, an imaging unit that captures a depth image including a distance to an object person in the interior, an estimating unit that estimates a three-dimensional human body model of an object person from a depth image captured by the imaging unit, a predicting unit that predicts a movement intention of an object person in an interior based on the human body model estimated by the estimating unit, and an operation controller that controls lighting of the illuminating unit according to the movement intention predicted by the predicting unit.

There is provided a vehicular illumination device to be disposed on a ceiling portion in a vehicle passenger compartment includes: a left-row light source unit in which three or more light sources arranged side by side in a front-rear direction of the vehicle is disposed on a left side of a center in a width direction of the vehicle: and a right-row light source unit in which three or more light sources arranged in the front-rear direction of the vehicle is disposed on a right side of the center in the width direction of the vehicle. Optical paths of the light sources are set to be placed in a state where a light irradiation region of the left-row light source unit and a light irradiation region of the right-row light source unit partially overlap with each other on a floor surface in the vehicle passenger compartment.

Methods and systems are provided for managing interior light illumination in a vehicle. Gaze data associated with an occupant of the vehicle is received from at least one gaze data sensor of the vehicle. The gaze direction of the occupant is determined based on the gaze data. A first light zone is identified from a plurality of light zones in the vehicle where the first light zone is in a line of sight associated with the gaze direction of the occupant. Each of the plurality of light zones includes at least one interior light. An illumination intensity level of the at least one interior light in the first light zone is adjusted from a first illumination intensity level to a second illumination intensity level, where the second illumination intensity level is greater than the first illumination intensity level.

A method for vehicle control includes receiving data associated with one or more wearable computing devices. Each of the one or more wearable computing devices are associated with one or more vehicle occupants in the vehicle. The method includes determining a health state of each of the one or more vehicle occupants based on the data and determining a location relative to the vehicle of each of the one or more vehicle occupants based on the data. The method includes controlling one or more vehicle systems based on the health state of each of the one or more vehicle occupants and the location relative to the vehicle of each of the one or more vehicle occupants.

There is provided a lighting system for a vehicle. The lighting system comprises a holographic projector and a light distribution system. The holographic projector comprises a hologram engine and a spatial light modulator. The hologram engine is arranged to output holograms. The spatial light modulator is arranged to display each hologram and spatially-modulate light in accordance with each hologram. The spatially-modulated light forms a holographic reconstruction, corresponding to each hologram, on a replay plane. The light distribution system comprises a plurality of optical fibres. Each optical fibre comprises an input optically-coupled to respective sub-area of the replay plane and an output optically coupled with an illumination sub-system of the vehicle.

An apparatus and system are disclosed and include a vehicle interior lighting system comprising that includes a light engine with a plurality of independently addressable light emitting diode (LED) segments, each independently addressable LED segment including at least one LED, a flexible printed circuit board (PCB) having a base and plurality of legs extending from the base, each leg supporting an independently addressable LED segment, and a light guide plate configured to provide illumination from the plurality of independently addressable LED segments inside the vehicle. A processor may be configured to receive information from a o vehicle sensing system, a vehicle communication system, or a detection system, and may generate a signal. A controller may be configured to provide one or more light control signals to modify at least one light characteristic of at least one of the plurality of independently addressable LED segments based on the signal.