A light bar has a circuit board positioned within a housing and having a plurality of light emitting diodes (LEDs) or a thin-film-transistor liquid-crystal display (TFT LCD) is configured to transmit light. The housing has wiring electrically connected to a controller. The controller is configured to receive signals from the electrical system of the vehicle, interpret the signals received from the electrical system of the vehicle, and in response automatically control illumination of independently controllable segments of the vehicle light bar. The controller is initially programmed to perform specific function(s) and/or strobe according to specific patterns and is thereafter at least partially restricted from being reprogrammed by a user to serve other function(s), either by restricting the emission of light in at least one color and/or preventing specific strobing pattern(s).

An automotive lighting control system is provided. A light-emitting diode (LED) system of an at least partially autonomous vehicle can include a first group of LEDs including cyan and amber LEDs, a second group of LEDs including cyan and at least one of red or amber LEDs, a third group of LEDs including cyan LEDs, and a controller configured to receive a first control signal indicating whether the at least partially autonomous vehicle is in autonomous drive mode or manual drive mode and cause the cyan LEDs of the first, second, and third groups LEDs to provide perceived cyan light when and only when the autonomous vehicle is in the autonomous drive mode.

A lighting system for a vehicle and a corresponding motor vehicle is implemented with personalized or individualizable lighting functions. A part of a lighting device is reserved for implementing main lighting functions in accordance with legal requirements and another part of the lighting device is reserved for generating individualizable lighting functions. The part for individualizable lighting functions can be freely programmed and actuated via a user interface, such as a smartphone, within the scope of the technical power limitations of the individual lighting devices while taking into consideration legal requirements.

An automated driving enabled vehicle includes a travel controller, an automated driving indicator lamp, and a lamp controller. The travel controller controls travel of the vehicle while switching a travel control state between automated driving and manual driving. The automated driving indicator lamp is switched on perceptibly from outside the vehicle on the occasion of the automated driving. The lamp controller makes a control to switch on the automated driving indicator lamp to indicate that the travel control state is the automated driving, during execution of the automated driving in which the travel controller controls the travel of the vehicle by the automated driving. The lamp controller changes, during the execution of the automated driving, a lighting state of the automated driving indicator lamp in response to a change in the travel control state or a change in travel environment, or both.

An automated driving enabled vehicle includes a travel controller, an automated driving indicator lamp, and a lamp controller. The automated driving indicator lamp is switched on perceptibly from outside the vehicle on the occasion of automated driving. The lamp controller acquires, during the execution of the automated driving, attribute information regarding a place being traveled by the vehicle. The lamp controller makes a lighting control of the automated driving indicator lamp during the execution of the automated driving, in accordance with the place being traveled by the vehicle executing the automated driving.

A control system includes a joystick and a computer. The joystick includes a joystick body, a cover hingedly coupled to the joystick body and movable between an open position and a closed position, and an input located on the joystick body. The input is exposed by the cover when the cover is in the open position and concealed by the cover when the cover is in the closed position. The computer is programmed to enter a first mode in response to the cover moving from the open position to the closed position, to enter a second mode in response to both the cover moving from the closed position to the open position and the input being activated, and to remain in a same of the first and second modes in response to the cover moving from the closed position to the open position without the input being activated.

Provided is a beam-steering mechanism, comprising a lens and a light source positioned in a focal plane of the lens. One of the light source and the lens moves relative to the other of the light source and the lens. The light source outputs a light beam at the lens which forms an illumination spot on a surface from the light beam. The illumination spot moves in a direction in response to a movement of one of the light source and the lens.

A luggage transport cart with a cabin made primarily out of a polymer. In some embodiments, the luggage cart includes an inwardly sloping floor and shelf to help contain the luggage. The floor and shelf may further include ribs and grooves to reduce drag on items disposed thereon, as well as to assist in draining away incident precipitation. The ribs and grooves may be inclined toward the centers of the floor and shelf, with reliefs formed at the junction of inclined surfaces to channel precipitation liquid out of the luggage cart. In some embodiments, the cabin includes backlit panels for enhanced display effects during ambient darkness or semi-darkness. The backlit panels may be sourced by a battery that recharges during daylight hours via a solar panel.

A control system includes a joystick and a computer. The joystick includes a joystick body, a cover hingedly coupled to the joystick body and movable between an open position and a closed position, and an input located on the joystick body. The input is exposed by the cover when the cover is in the open position and concealed by the cover when the cover is in the closed position. The computer is programmed to enter a first mode in response to the cover moving from the open position to the closed position, to enter a second mode in response to both the cover moving from the closed position to the open position and the input being activated, and to remain in a same of the first and second modes in response to the cover moving from the closed position to the open position without the input being activated.

A light bar for a motor vehicle has a plurality of lights mounted to an elongated support member is rotatably connected to opposing end walls of a rectangular frame. An offset cam is connected to the support member and moved by an actuating mechanism between a first and second position which cause the support member and lights to rotate about an axis to corresponding first and second positions. When the support frame and lights are in a first position they are shielded by and substantially enclosed by the sides and ends of the rectangular frame, and when in a second position the lights extend above and generally parallel to the rectangular frame to shine above and forward of the rectangular frame. A power switch energizes the actuating mechanism to move the lights and support member between the first and second positions.