A system for implementing adaptive light distributions for an autonomous vehicle (comprises the autonomous vehicle, a control device, and a headlight associated with the autonomous vehicle. The control device receives sensor data from sensors of the autonomous vehicle, where the sensor data comprises an image of one or more objects on a road traveled by the autonomous vehicle. The control device determines that a light condition level on a particular portion of the image is less than a threshold light level. The control device adjusts the headlight to increase illumination on a particular part of the road that is shown in the particular portion of the image.

A first pixel with a first pixel sidewall is disclosed. A second pixel with a second pixel sidewall facing the first pixel sidewall is also disclosed. A first dynamic optical isolation material between the first pixel sidewall and the second pixel sidewall and configured to change an optical state based on a state trigger such that a light behavior at the first pixel sidewall for a light emitted by one of the first pixel and the second pixel is determined by the optical state, is also disclosed.

The vehicle lamp includes a first lamp unit and a second lamp unit each including a first light source configured to emit an emission beam (visible light), a second light source configured to emit infrared light for sensing having a peak wavelength different from that of the first light source, and a light receiving unit configured to detect an intensity of reflected light of the infrared light emitted from the second light source. The light distribution control is performed on the light emitted from the first light source in accordance with the intensity of the reflected light detected by the light receiving unit, and the peak wavelength of the light emitted from the second light source of the first lamp unit and the peak wavelength of the light emitted from the second light source of the second lamp unit are different from each other.

The vehicle lamp includes a first lamp unit and a second lamp unit each including a first light source configured to emit an emission beam (visible light), a second light source configured to emit infrared light for sensing having a peak wavelength different from that of the first light source, and a light receiving unit configured to detect an intensity of reflected light of the infrared light emitted from the second light source. The light distribution control is performed on the light emitted from the first light source in accordance with the intensity of the reflected light detected by the light receiving unit, and the peak wavelength of the light emitted from the second light source of the first lamp unit and the peak wavelength of the light emitted from the second light source of the second lamp unit are different from each other.

The optical unit includes a light source, an electromagnetic wave generator, a first reflector configured to reflect emitted light emitted from the light source and electromagnetic waves emitted by the electromagnetic wave generator in a first reflection region whose reflection direction is changed periodically, and a second reflector configured to reflect first reflected light reflected by the first reflector and first electromagnetic waves again in a second reflection region whose reflection direction is changed periodically. The first reflector is configured to scan the second reflection region with the first reflected light and the first electromagnetic waves. The second reflector is configured to form a light distribution pattern by performing scanning with second reflected light, and to detect a surrounding object by performing scanning with second electromagnetic waves.

A light module for motor vehicles, having a first laser arrangement (L.sub.S), which contains at least one laser light source (L1, L2, L3, L4) which can be modulated, the laser beam(s) (b1, b2, b3, b4) of which is/are directed to a pivotable micromirror (6) controlled by a mirror control (8) and from there to a light-converting means (7), and having a lighting optics (9) for projecting the illumination pattern generated by the light-converting means (10) into the traffic space/roadway, as a lighting system, and having a second laser arrangement (V.sub.L), which contains at least one laser light source (H1, H2, H3), the laser beam/laser beams (c1, c2, c3) of which is/are sent to the pivotable micromirror (6) controlled by the mirror control (8) and from there into the traffic space/roadway via a LIDAR exit optics (21), as well as having a LIDAR entry optics (14), which sends light of the second laser arrangement reflected in the exterior space to a detector (15), as a LIDAR system.

A light module for motor vehicles, having a first laser arrangement (L.sub.S), which contains at least one laser light source (L1, L2, L3, L4) which can be modulated, the laser beam(s) (b1, b2, b3, b4) of which is/are directed to a pivotable micromirror (6) controlled by a mirror control (8) and from there to a light-converting means (7), and having a lighting optics (9) for projecting the illumination pattern generated by the light-converting means (10) into the traffic space/roadway, as a lighting system, and having a second laser arrangement (V.sub.L), which contains at least one laser light source (H1, H2, H3), the laser beam/laser beams (c1, c2, c3) of which is/are sent to the pivotable micromirror (6) controlled by the mirror control (8) and from there into the traffic space/roadway via a LIDAR exit optics (21), as well as having a LIDAR entry optics (14), which sends light of the second laser arrangement reflected in the exterior space to a detector (15), as a LIDAR system.

An apparatus can include a lens that can shape light emerging from a light emitting diode (LED). The emergent light from the LED can be substantially centered around an LED axis. An incident surface of the lens can be positioned to face the LED. The incident surface can include a concave portion. The concave portion can be substantially smooth, so as not to substantially scatter light that strikes the concave portion. The concave portion can be substantially centered around a concave portion axis that is non-coaxial with the LED axis. The incident surface can include a scattering portion, positioned away from the concave portion, which can be textured so as to scatter light that strikes the scattering portion. An exiting surface of the lens can optionally include a generally planar portion that at least partially surrounds a substantially smooth convex portion.

A vehicle infrared lamp system mounted on a vehicle equipped with an infrared camera includes: an infrared light source; a rotating reflector; an other-vehicle position acquisition unit configured to acquire position information of another vehicle; and a control unit configured to control a lighting state of the infrared light source based on the position information of the other vehicle acquired by the other-vehicle position acquisition unit such that a dimming region where radiant intensity of infrared light is lower than radiant intensity of any other region is formed on at least a part of the other vehicle.

A headlight is disclosed, comprising a headlight body, a temperature sensor, an IR module, a low beam module, and a controller. The headlight body has a housing and a lampshade. The lampshade has a light-absorbing and heating layer. The temperature sensor is configured inside the headlight body, to detect the temperature of the lamp. The IR module is a wide-angle LED lamp, positioned inside the headlight body, and It directly irradiates toward the lampshade. The low beam module is configured inside the headlight body, emitting toward the lampshade, and an emitting direction of the low beam module crosses an irradiating direction of the IR module. The controller is electrically connected to the IR module and the temperature sensor, and turns on/off the IR module based on the temperature of the lamp.