An automotive light comprising a lighting assembly which is located inside the rear body, is adapted to backlight a corresponding transparent or semi-transparent sector of the front half-shell, and comprises: a pair of light-guide bars made of photoconductive material, which extend toward each other inside the rear body, while remaining both substantially grazing the front half-shell, and have their respective proximal ends adjacent and aligned to one another; and a pair of electrically-powered light sources that are located within the rear body each adjacent to the distal end of a respective light-guide bar, and are oriented so as to direct the light produced inside the body of the facing light-guide bar; the proximal ends of both light-guide bars being shaped so as to form respective plate-like heads that are locally substantially coplanar to each other and are arranged inside the rear body one spaced beside the other, so as to form/delimit therebetween a small transversal slot, which is substantially straight and is inclined with respect to the local longitudinal axis of the same light-guide bars.

The present disclosure relates generally to measuring and testing circuits of towed vehicles. Testing circuits of towed vehicles for proper function is required for safe use of the vehicle. Instruments that currently exist are expensive, the instruments are large in size, use outdated technology to perform the test and do not provide a means to reliably and effectively test braking systems.

Provided are a lamp apparatus of a vehicle and a control method thereof. The lamp apparatus includes: a first integrated lamp installed at either the front or rear of a vehicle and having a plurality of lamps, one or more of which being turned on according to a lighting mode; a second integrated lamp installed at a position different from the installation position of the first integrated lamp and having a plurality of lamps, one or more of which being turned on; a travel direction input unit that receives a travel direction; a driving signal input unit that receives driving signals for turning on and off the lamps; and a lamp control unit that receives the travel direction to set the lighting modes of the first and second integrated lamps, and drives one or more of the plurality of lamps included in each of them.

Provided are a lamp apparatus of a vehicle and a control method thereof. The lamp apparatus includes: a first integrated lamp installed at either the front or rear of a vehicle and having a plurality of lamps, one or more of which being turned on according to a lighting mode; a second integrated lamp installed at a position different from the installation position of the first integrated lamp and having a plurality of lamps, one or more of which being turned on; a travel direction input unit that receives a travel direction; a driving signal input unit that receives driving signals for turning on and off the lamps; and a lamp control unit that receives the travel direction to set the lighting modes of the first and second integrated lamps, and drives one or more of the plurality of lamps included in each of them.

Systems, devices, and methods for an inductive coupling platform system comprising: an inductive coupling lift gate platform comprising: a first segment; a second segment; at least one primary inductive coupling component disposed in at least a portion of the first segment; and at least one receiver inductive coupling component disposed in at least a portion of the second segment; where inductive contact is provided between the at least one primary inductive coupling component and the at least one receiver inductive coupling component in an unfolded position; and where power or data is transmitted via the inductive contact between the at least one primary inductive coupling component and the at least one receiver inductive coupling component in the unfolded position.

A vehicle includes a rear lamp, a side surface, and a rear surface. The rear lamp is disposed on a rear end and an upper end of a lower side surface and a rear end and a side end of the vehicle, and includes a lamp body extending in a front-rear direction of the vehicle. The side surface includes the lower side surface bulging toward a vehicle-width-direction outer side with respect to the rear lamp at a front side of a height position overlapping with the rear lamp. The rear surface includes an extending surface extending toward the vehicle-width-direction outer side with respect to the lamp body in a top view of the vehicle from a lower portion of the lamp body. A side surface airflow is directed toward a vehicle-width-direction inner side through the extending surface and the generation of a large trailing vortex is suppressed.

A vehicle includes a rear lamp, a side surface, and a rear surface. The rear lamp is disposed on a rear end and an upper end of a lower side surface and a rear end and a side end of the vehicle, and includes a lamp body extending in a front-rear direction of the vehicle. The side surface includes the lower side surface bulging toward a vehicle-width-direction outer side with respect to the rear lamp at a front side of a height position overlapping with the rear lamp. The rear surface includes an extending surface extending toward the vehicle-width-direction outer side with respect to the lamp body in a top view of the vehicle from a lower portion of the lamp body. A side surface airflow is directed toward a vehicle-width-direction inner side through the extending surface and the generation of a large trailing vortex is suppressed.

A rear vehicle-body structure separates air flowing on a side of the vehicle so as not to flow around to a rear of the vehicle, to ensure aerodynamic performance. The disclosed rear vehicle-body structure has a rear combi lamp mounted on a vehicle-width-direction outer side face of a vehicle rear portion, and a rear bumper mounted under the rear combi lamp. The rear combi lamp includes, on the vehicle-width-direction outer side face, a curved portion that is curved from a vehicle-width-direction outer side forwardly inward in a vehicle width direction in a vehicle plan view. The curved portion has a curvature increasing toward a lower side of the vehicle. A protruding portion protruding toward the vehicle-width-direction outer side as going to a rear of the vehicle is provided at a front portion of the curved portion.

A rear vehicle-body structure separates air flowing on a side of the vehicle so as not to flow around to a rear of the vehicle, to ensure aerodynamic performance. The disclosed rear vehicle-body structure has a rear combi lamp mounted on a vehicle-width-direction outer side face of a vehicle rear portion, and a rear bumper mounted under the rear combi lamp. The rear combi lamp includes, on the vehicle-width-direction outer side face, a curved portion that is curved from a vehicle-width-direction outer side forwardly inward in a vehicle width direction in a vehicle plan view. The curved portion has a curvature increasing toward a lower side of the vehicle. A protruding portion protruding toward the vehicle-width-direction outer side as going to a rear of the vehicle is provided at a front portion of the curved portion.

An adaptor for connecting an LED lighting unit to a vehicle CAN-bus. The adaptor has a connector connectable to a corresponding connector on a vehicle, to receive a lighting current from the CAN-bus of the vehicle. A wireless power transmitter of the adaptor wirelessly transmits power to the LED lighting unit at a first level, typically suited to LED operation. The adaptor further includes one or more resistors connected between the connector and transmitter and arranged to draw power from the connector at a second power level higher than the first power level, which second power level is suitably equivalent to that for halogen or filament lighting.