A system for implementing strobing of existing vehicle hazard lights including an interface to a vehicle wiring harness configured to receive input to an existing vehicle flasher module, and a strobing circuit that responds to an activation signal from the vehicle wiring harness that is indicative of a hazard flasher deployment event by producing an electrical output through the interface to the vehicle wiring harness that causes a strobing of existing vehicle hazard lamps.

A system for implementing strobing of existing vehicle hazard lights including an interface to a vehicle wiring harness configured to receive input to an existing vehicle flasher module, and a strobing circuit that responds to an activation signal from the vehicle wiring harness that is indicative of a hazard flasher deployment event by producing an electrical output through the interface to the vehicle wiring harness that causes a strobing of existing vehicle hazard lamps.

A lighting assembly for vehicles, having a number of light sources and light guide elements for generating different light functions, with a number of scattering optical elements assigned to the light exit side of the light guide elements for scattering the light. A headlamp lens is arranged at a distance in front of the light guide elements. The first light sources and the second light sources are arranged alternately in the direction of extension of the linear light signature. The scattering optical elements and/or the distance of the headlamp lens to the scattering optical elements and/or a distance in between adjacent first light sources running in the direction of extension are designed such that first light beams exiting in each case from the scattering optical elements assigned to the adjacent first light sources and adjacent in the direction of extension.

The present invention is provided with: an outer housing configured from a housing having an opening, and a translucent cover closing the opening; a substrate disposed inside of the outer hosing; a camera module, which has an image pickup element, and is disposed on the substrate; and a light emitting element, which is provided as a light source, and is disposed on the substrate. Consequently, since the camera module and the light emitting element are disposed on the substrate that is disposed inside of the outer housing, the number of configuration components is small, thereby achieving reduction of the number of components, and size reduction.

A method comprising optically detecting optical output states of a plurality of light sources of an optical device over a test interval; for each light source, optically detecting that the output state of the light source has changed from a first optical condition to a second optical condition; for each light source, optically detecting that the output state of the light source has changed from the second optical condition to a third optical condition; for each light source, determining a first time interval representative of the first optical condition; for each light source, determining a second time interval representative of the second optical condition; for each light source, determining a third time interval representative of the third optical condition; determining a test result for the device based on a comparison of the first, second and third time intervals with pre-stored time intervals.

A door handle providing a superior visibility from both front and rear directions of a vehicle is provided. The door handle includes: an operating portion that bulges from a door outer surface, defining a space between the door outer surface and the operating portion, allowing a user to insert his or her hand into the space; a fixation portion arranged adjacent to the operating portion, including a lens as a translucent member; an outer surface provided in the lens, the outer surface having such a region that a vehicle rear side of the region is positioned outward as compared to a vehicle front side thereof; and a lighting body serving as a direction indicator allowing a transmissive illumination to be made from the inner surface side of the lens. Thus, the lens can be made visible not only from the vehicular lateral side but from the vehicular front side.

A door handle providing a superior visibility from both front and rear directions of a vehicle is provided. The door handle includes: an operating portion that bulges from a door outer surface, defining a space between the door outer surface and the operating portion, allowing a user to insert his or her hand into the space; a fixation portion arranged adjacent to the operating portion, including a lens as a translucent member; an outer surface provided in the lens, the outer surface having such a region that a vehicle rear side of the region is positioned outward as compared to a vehicle front side thereof; and a lighting body serving as a direction indicator allowing a transmissive illumination to be made from the inner surface side of the lens. Thus, the lens can be made visible not only from the vehicular lateral side but from the vehicular front side.

This vehicle lamp system, which is used together with a vehicle control unit that controls the travel state of a vehicle, comprises an ID lamp which is mounted on the vehicle and which lights up when the vehicle control unit controls the travel state of the vehicle, and a lamp control unit which controls the ID lamp. The vehicle control unit is configured to output to the lamp control unit an advance warning signal that indicates a travel state change prior to making said change, and the lamp control unit is configured to control the ID lamp to switch between a first mode carried out when the vehicle control unit maintains a prescribed travel state without changing the travel state, and a second mode carried out when an advance warning signal has been inputted from the vehicle control unit.

Systems and methods for an aircraft lighting system (ALS) are provided. The method includes co-locating a central light source subsystem including a blue light generator, red light generator, and green light generator, and a light generating control unit (LGCU) comprising a processor, and distributing a plurality of passive light-heads around an external surface of the aircraft. Each passive light-head of the plurality of passive light-heads is operationally coupled to a first side of a respective light switch of a respective plurality of light switches, the light switch being coupled on a second side to a light emitting output of the central light source subsystem. Controlling and actuating the light generators and the light switches in accordance with a load profile is performed by a light generating control unit (LGCU).

Systems and methods for an aircraft lighting system (ALS) are provided. The method includes co-locating a central light source subsystem including a blue light generator, red light generator, and green light generator, and a light generating control unit (LGCU) comprising a processor, and distributing a plurality of passive light-heads around an external surface of the aircraft. Each passive light-head of the plurality of passive light-heads is operationally coupled to a first side of a respective light switch of a respective plurality of light switches, the light switch being coupled on a second side to a light emitting output of the central light source subsystem. Controlling and actuating the light generators and the light switches in accordance with a load profile is performed by a light generating control unit (LGCU).