The present disclosure relates to an illumination system for a motor vehicle for illuminating a carriageway section. The aim is to illuminate the carriageway section in such a way that irritations for other road users are avoided as far as possible. The illumination system includes an information system for providing or detecting a stopping point, an illumination device for projecting a calculated light distribution onto the carriageway section, and a control unit for calculating a light distribution, wherein the calculated light distribution is a one-piece area. The one-piece area begins from a predetermined starting section, which constitutes a proximal lighting section relative to the motor vehicle and does not extend beyond the stopping point. This leads to a shortening of a lane light of the motor vehicle, so that said lane light does not illuminate the lane beyond the stopping point. This is advantageous in particular for crossroads.

Example adaptive vehicle headlights are disclosed. An example system includes a photodetector, an illumination source configured to generate first light during a first operating mode, a spatial light modulator (SLM), and a dichroic filter optically coupled to the illumination source and to the SLM, wherein the dichroic filter is configured to direct the first light to the SLM, and the SLM is configured to direct second light to the dichroic filter during a second operating mode, wherein the dichroic filter is configured to direct the second light having a first color to the photodetector, and direct the first light during the first operating mode.

An apparatus for mobile machinery includes a sensor module configured for detachable fitment to mobile machinery, and a control module configured to interface with a control system of the mobile machinery. The sensor module includes an orthogonal sensor arrangement for sensing obstacles in three-dimensional space, an orthogonal indicator arrangement configured to provide a gradient proximity indication of an obstacle, and a wireless transceiver arranged in signal communication with the sensor and indicator arrangements. The control module includes a control wireless transceiver for communicating with the wireless transceiver of the sensor module, and a processor in signal communication with the control wireless transceiver, the processor configured to program, via the wireless transceiver of each sensor module, the sensor and indicator arrangements and with predetermined thresholds of obstacle proximity. If a sensed obstacle proximity exceeds a maximum threshold, the processor overrides the control system to facilitate situational awareness of an operator.

A system, a method, and a computer program product may be provided for user guidance. In an example, the system includes an image projection device configured to project traffic patterns on a surface, at least one non-transitory memory configured to store computer program code, and a processor configured to execute the computer program code to control operation of the image projection device. For example, sensor data from one or more sensors onboard a vehicle is obtained. The sensor data is associated with a state of operation of the vehicle, and proximate movement associated with the vehicle. Based on the sensor data, one or more traffic patterns for projection is determined. Further, an image projection device is controlled to project the one or more traffic patterns in one or more direction of the vehicle.

A vehicular apparatus includes: a housing that is configured to be attached to a vehicle; and a first light source and a second light source that are provided in the housing to emit light having main wavelengths in mutually different wavelength ranges. The first light source emits light having a main wavelength in 490 nm-498 nm while the vehicle is being automatically driven.

A lighting device for a motor vehicle includes a cavity, at least one illumination source arranged in the cavity, and at least one detection system which is arranged in the cavity and includes an emitter and/or a receiver designed to transmit and receive electromagnetic waves in a predetermined wavelength range. The lighting device includes a trim arranged in the cavity and behind which the emitter and/or the receiver of the detection system are arranged. The trim includes an interference filter which is transparent in transmission at wavelengths in the predetermined wavelength range and is reflective for the wavelengths transmitted in the visible spectrum.

A detection device includes a Light Detection and Ranging (LiDAR) device enclosed in housing with a glass cover that has a mean transmittance at the LiDAR operating wavelength of at least 80%, to an IR-radiation in the wavelength range from 750 to 1650 nm. The glass cover is laminated and includes at least one glass sheet laminated with at least one thermoplastic interlayer. The thermoplastic interlayer has a mean transmittance at the LiDAR operating wavelength of at least 80%, to an IR-radiation in the wavelength range from 750 to 1650 nm, and has a light transmission in the visible range of less than 10% of the incident light.

Disclosed are PBS-based ADB function adjustment method and an intelligent vehicle light module therefor. A light source system and a light control element constitute an intelligent illumination light control system. One part of light rays emitted by the intelligent illumination light control system penetrate through a PBS to form an illumination light shape, and the other part of the light rays emitted by the intelligent illumination light control system are reflected by the PBS in a direction opposite to a photosensitive chip integrated circuit. Ambient light enters an imaging lens group in a direction opposite to an illumination light path, and one part of the ambient light is reflected by the PBS to the photosensitive chip integrated circuit to form an information source for dynamic control of the light control system.

The present disclosure relates to optical systems, vehicles, and methods that are configured to illuminate and image a wide field of view of an environment. An example optical system includes a camera having an optical axis and an outer lens element disposed along the optical axis. The optical system also includes a plurality of illumination modules, each of which includes at least one light-emitter device configured to emit light along a respective emission axis and a secondary optical element optically coupled to the at least one light-emitter device. The secondary optical element is configured to provide a light emission pattern having an azimuthal angle extent of at least 170 degrees so as to illuminate a portion of an environment of the optical system.

Vehicle exterior lighting systems may be equipped with fascia mounted lamp assemblies. The proposed systems are capable of controlling a fascia lamp assembly to reveal the lamp assembly within the vehicle fascia and then produce various lighting effects based on sensed vehicle conditions. Exemplary fascia lamp assemblies may include a conductive lens that can be charged in order to reveal the lamp assembly within the vehicle fascia.