A reflector unit may behave as a retroreflector to reflect light of a selected color. The reflector unit may comprise a first reflector having a first color, a second reflector having a second color, and a mask that either allows incoming light to reach the first reflector and not the second reflector or allows incoming light to reach the second reflector and not the first reflector. An active light unit may emit light of a particular color in response to receiving light. In this fashion, the active light unit may simulate the operation of a reflector. The reflector unit and the active light unit may operate on a bi-directional vehicle.

An exemplary automotive vehicle includes a first actuator configured to control acceleration and braking of the automotive vehicle, a second actuator configured to control steering of the automotive vehicle, a vehicle sensor configured to generate data regarding the presence, location, classification, and path of detected features in a vicinity of the automotive vehicle and a controller in communication with the vehicle sensor, and the first and second actuators. The controller is configured to selectively control the first and second actuators in an autonomous mode along a first trajectory according to an automated driving system. The controller is also configured to receive the data regarding the detected features from the vehicle sensor, determine a predicted vehicle maneuver from the data regarding the detected features, map the predicted vehicle maneuver with an indication symbol, and generate a control signal to display the indication symbol.

A system for adaptive lights for use in a vehicle includes a headlight configured to generate light to be at least partially directed away from the vehicle to illuminate a portion of an environment of the vehicle. The system further includes a sensor configured to detect data corresponding to an environmental condition in the environment of the vehicle. The system further includes an electronic control unit (ECU) coupled to the headlight and the sensor and configured to determine the environmental condition based on the detected data and to adjust an intensity and an orientation of the light generated by the headlight based on the environmental condition.

This light-emitting element drive control device (100) comprises: a drive logic unit (113) which performs a drive control of a switch output stage (N1, D1, L1) for dropping an input voltage (VIN) to an output voltage (VOUT) and supplying a light-emitting element therewith; a charge-pump power supply unit (a) which generates a step-up voltage (CP) higher than the input voltage (VIN); and a current detecting comparator (114) which receives a supply of the step-up voltage (CP) and the output voltage (VOUT) as power supply voltages, and generates control signals (SET, RST) for the drive logic unit (113) by directly comparing a current detection signal (Vsns) corresponding to an inductor current (IL) of the switch output stage with a peak detection value (Vsns_pk) and a bottom detection value (Vsns_bt).

A display device for a movable object includes: a display unit provided such that it is visible from outside a movable object; and a controller that causes the display unit to display information indicating a status of the movable object. The controller changes a display mode of the information displayed on the display unit in accordance with variation in the status of the movable object.

A visual deceleration indicator signals to pedestrians and other vehicles that a vehicle is slowing down or coming to a stop. Illuminating devices, such as LEDs, contained in a license plate frame located in the front of the car or otherwise, are activated when the vehicle decelerates. An accelerometer or other sensory device detects deceleration and sends a signal to illuminate the LEDs, thereby letting others know the vehicle is slowing down. The license plate frame may be connected directly to a rear brake light component without the use of accelerometers or other sensors. When the brake is applied, the LEDs in the license plate frame are illuminated. The LEDs may be contained in other forms and located in different positions on the front or side of the car. The indicator might be one color to indicate braking and another color to indicate it is on, but not braking.

A vehicle frontal illumination system includes a bracket attached to a front of a vehicle, where the bracket includes a light receiving surface that faces the front of the vehicle. The system also includes one or more lights attached to the light receiving surface of the bracket such that the one or more lights face the front of the vehicle. The system further includes a control system in communication with the light, where the control system is configured to turn the one or more lights on to illuminate the front of the vehicle to reduce the likelihood of an animal vehicle collision.

Provided is a vehicular lighting device (1) attached to a motorbike (100) that is capable of traveling around corners due to the vehicle body being tilted toward the direction for turning, wherein the vehicular lighting device (1) comprises at least two lamps and a sensor (7) for detecting the surrounding environment toward the rear of the vehicle. The vehicular lighting device (1) comprises a left lighting unit (2L) and a right lighting unit (2R) as the at least two lamps. The sensor (7) is disposed between the left lighting unit (2L) and the right lighting unit (2R) as viewed from rearward of the vehicle.

A trailer lighting activation system includes a vehicle light sensor, an ambient light sensor, and a microcontroller. The vehicle light sensor is removably attached to a towing vehicle light to detect a light output of the towing vehicle light, and to provide a vehicle light sensor output signal in response to the light output of the towing vehicle light. The ambient light sensor can detect an ambient light level and provide an output signal in response to the ambient light level. The microcontroller is coupled to the vehicle light sensor output and to the ambient light sensor and has an output for energizing a trailer light in response to the ambient light sensor output signal and the vehicle light sensor output signal. An overcurrent monitor is coupled to the trailer light and to monitor current drawn by the trailer lighting activation system.

A trailer hitch cover assembly, which includes an inflatable object capable of withstanding about 2000 pounds per square inch internal pressure, a first attachment plate disposed within the inflatable object, a second attachment plate disposed in physical contact with but external to the inflatable object, a housing comprising a plurality of threaded apertures extending therethrough and dimensioned to be received by a trailer hitch receiver, where a corresponding plurality of threaded members are attached to the first attachment plate, extend outwardly from the first attachment plate through a surface of the inflatable object, extend through the second attachment plate, and intermesh with the plurality of threaded apertures.