A motor vehicle includes a projection device to project a light distribution for driver information in the longitudinal direction of the motor vehicle onto the ground in front of the motor vehicle. The light function of the projected light distribution is different from a low beam and a high beam light. During operation of the projection device within a predefined interval of the vehicle speed in the forward direction of the motor vehicle, an increase in the extent of the light distribution in the longitudinal direction of the motor vehicle occurs as the vehicle speed increases. The extent of the light distribution at each vehicle speed is thereby greater than or equal to the extent at lower vehicle speeds.

A motor vehicle includes a projection device to project a light distribution for driver information in the longitudinal direction of the motor vehicle onto the ground in front of the motor vehicle. The light function of the projected light distribution is different from a low beam and a high beam light. During operation of the projection device within a predefined interval of the vehicle speed in the forward direction of the motor vehicle, an increase in the extent of the light distribution in the longitudinal direction of the motor vehicle occurs as the vehicle speed increases. The extent of the light distribution at each vehicle speed is thereby greater than or equal to the extent at lower vehicle speeds.

A first LED lamp bracket is provided that can be fixed to an interior portion of a front grille section that is part of an engine hood assembly of a motorized vehicle. The LED lamps are located on the LED lamp bracket such that they are clearly visible through the engine hood front grille assembly. The LED lamp bracket assembly is designed such that it takes advantage of the spacing of the grille openings such that the LED lamps are visible when the LED lamp bracket is attached to the motorized vehicle. The first LED lamp bracket can be used with a 2014 Ford F150 truck. According to further aspects of the embodiments, a second LED lamp bracket assembly is provided that includes substantially identical design features, but which is fitted to a 2015 Ford F150 truck.

A light-emitting device, notably a lighting and/or signaling device for a motor vehicle, including at least one first light source intended to emit a first modulated light beam coding information; at least one second light source intended to emit a second modulated light beam coding information; a control device adapted: to determine, on receiving information to be transmitted via the light-emitting device, if a first light beam intended to be emitted by the first source should be modulated to code the information to be transmitted and/or if a second beam intended to be emitted by the second source should be modulated to code the information to be transmitted, the determination depending on information relating to the local solar illumination; as a function of the determination, to modulate the first light beam and/or the energization second light beam to code the information to be transmitted.

A lighting device of a vehicle includes at least one lighting device for a road scene in front of the vehicle arranged to form a first light beam defined by a first lighting. A device for generating a second light beam defined by a second lighting is configured to superimpose the second beam on the first light beam. A sum of the first lighting and of the second lighting is greater than the first lighting, the second light beam forms driving assistance information.

Systems, methods, and computer-readable media for configuring automotive lamp illumination control are provided. One example method includes, at a computing device, generating a graphical user interface for configuring at an automotive lamp illumination pattern. The graphical user interface includes user input elements and is displayed by way of a display device. An input command is received by way of at least one of the plurality of user input elements. The input command corresponds to the at least one of the user input elements. A message is transmitted to an automotive lamp control device by way of a communication path including a first communication port of the computing device and a second communication port of the automotive lamp control device, based on the received input command. The message is received at the automotive lamp control device, and an action is performed in response to receiving the message.

Systems, methods, and computer-readable media for configuring automotive lamp illumination control are provided. One example method includes, at a computing device, generating a graphical user interface for configuring at an automotive lamp illumination pattern. The graphical user interface includes user input elements and is displayed by way of a display device. An input command is received by way of at least one of the plurality of user input elements. The input command corresponds to the at least one of the user input elements. A message is transmitted to an automotive lamp control device by way of a communication path including a first communication port of the computing device and a second communication port of the automotive lamp control device, based on the received input command. The message is received at the automotive lamp control device, and an action is performed in response to receiving the message.

A cooperative adaptive lighting system for motor vehicles in which a vehicle transmits its geographic coordinates and receives similar coordinates from other vehicles, pedestrians, and stationary warning devices. Using the coordinates, the vehicle computes distances, and relative position more specifically, to those entities. When the distances become sufficiently small, indicating that the entities fall within headlight range, the vehicle alters its headlight beams to either (1) throw more light on an entity, (2) reduce light reaching the entity as appropriate, or (3) change a lighting pattern as appropriate.

An object detection apparatus includes a light emission unit including a light source to emit light, a light receiving unit including a light detector to receive light reflected from an object, a signal processing unit including a signal detector to be input with an output signal of the light detector or a signal acquired by processing the output signal of the light detector, and a control unit to set at least one area in a light emission region of the light emission unit as a target area, and to set at least one of a light emission condition of the light emission unit and a processing condition of the signal processing unit such that the at least one of the light emission condition and the processing condition are different between when the light is emitted to the target area and when the light is emitted to a background area.

An object detection apparatus includes a light emission unit including a light source to emit light, a light receiving unit including a light detector to receive light reflected from an object, a signal processing unit including a signal detector to be input with an output signal of the light detector or a signal acquired by processing the output signal of the light detector, and a control unit to set at least one area in a light emission region of the light emission unit as a target area, and to set at least one of a light emission condition of the light emission unit and a processing condition of the signal processing unit such that the at least one of the light emission condition and the processing condition are different between when the light is emitted to the target area and when the light is emitted to a background area.