A method, system and non-transitory computer readable medium for suppressing autonomous vehicle external human machine interface (eHMI) notifications to prevent confusion or distraction of a road user. The suppression conditions are based on situations where the eHMI notification is redundant, not necessary, can be simplified or should be modified due to weather or light intensity. The eHMI notifications can be suppressed on selected displays and enhanced on others. The eHMI notifications can include text and icons, flashing lights, color or light patterns, which can be modified or suppressed based on the determination that the eHMI notification will confuse or distract the road user. At a four-way stop intersection, the eHMI notification can be suppressed until the autonomous vehicle has the right-of-way. The autonomous vehicle can form a mesh network with connected vehicles at the intersection and broadcast a group eHMI while requesting that the connected vehicles suppress their eHMIs.

A cooperative adaptive lighting system for motor vehicles in which a vehicle transmits its geographic coordinates and receives similar coordinates from other vehicles, pedestrians, and stationary warning devices. Using the coordinates, the vehicle computes distances, and relative position more specifically, to those entities. When the distances become sufficiently small, indicating that the entities fall within headlight range, the vehicle alters its headlight beams to either (1) throw more light on an entity, (2) reduce light reaching the entity as appropriate, or (3) change a lighting pattern as appropriate.

A lighting control system for a vehicle includes a controller configured to be disposed at a vehicle so as to connect with or communicate with at least one light of the vehicle. The controller, responsive to at least one input, adjusts a color of the at least one light of the vehicle and an intensity of the at least one light of the vehicle. The input may include one or more of (i) a driver attentiveness input and (ii) a driver age input, and optionally a time of day input, an ambient light input, a weather condition input, and/or a navigation input.

A method, system and non-transitory computer readable medium for suppressing autonomous vehicle external human machine interface (eHMI) notifications to prevent confusion or distraction of a road user. The suppression conditions are based on situations where the eHMI notification is redundant, not necessary, can be simplified or should be modified due to weather or light intensity. The eHMI notifications can be suppressed on selected displays and enhanced on others. The eHMI notifications can include text and icons, flashing lights, color or light patterns, which can be modified or suppressed based on the determination that the eHMI notification will confuse or distract the road user. At a four-way stop intersection, the eHMI notification can be suppressed until the autonomous vehicle has the right-of-way. The autonomous vehicle can form a mesh network with connected vehicles at the intersection and broadcast a group eHMI while requesting that the connected vehicles suppress their eHMIs.

A headlight control system controls a headlight of a moving object. The moving object includes the headlight including a plurality of light emission units, and an imaging unit configured to capture images of circumstances in front. The headlight control system includes an irradiation pattern controller configured to perform control for changing at least one of presence or absence of light emission and a degree of light emission of each of the light emission units to change an irradiation pattern of the headlight to one of a plurality of irradiation patterns, an imaging controller configured to perform control such that the imaging unit captures the images of the circumstances in front for each of the irradiation patterns to acquire captured images, and a learning unit configured to learn an irradiation pattern suitable for the circumstances in front based on captured images captured for each of the irradiation patterns.

A method is provided that includes projecting a hybrid headlight frame into a scene in front of a vehicle by a digital micromirror device (DMD) headlight, wherein the hybrid headlight frame includes a structured light pattern and a high beam headlight pattern, and capturing an image of the scene by a camera included in the vehicle while the structured light pattern is projected.

A vehicular lighting control system includes a controller configured to be disposed at a vehicle and operable to control interior lighting of the vehicle, with the interior lighting including (i) an interior light of the vehicle and/or (ii) a backlighting light of a display of the vehicle. The controller adjusts color of the interior lighting for different driving conditions. During daytime, the controller adjusts color of the interior lighting of the vehicle to follow a daytime color scheme. Responsive to a navigation input, the controller determines if an input destination has an estimated arrival time of the vehicle after daytime. Responsive to determination that the estimated arrival time of the vehicle is after daytime, the controller maintains the daytime color scheme for the interior lighting of the vehicle until the vehicle arrives at the input destination after daytime.

A vehicular lighting control system includes a controller configured to be disposed at a vehicle and operable to control interior lighting of the vehicle, with the interior lighting including (i) an interior light of the vehicle and/or (ii) a backlighting light of a display of the vehicle. The controller adjusts color of the interior lighting for different driving conditions. During daytime, the controller adjusts color of the interior lighting of the vehicle to follow a daytime color scheme. Responsive to a navigation input, the controller determines if an input destination has an estimated arrival time of the vehicle after daytime. Responsive to determination that the estimated arrival time of the vehicle is after daytime, the controller maintains the daytime color scheme for the interior lighting of the vehicle until the vehicle arrives at the input destination after daytime.

The active lighting device of a bicycle includes a first optical system with a first light source for long-distance illumination, controlled by a control unit, and a second optical system with a second light source for short-distance illumination, controlled by the control unit. It includes a light sensor for determining the light intensity of a location in which the bicycle is situated and allows the control unit to adapt the light intensity of the light sources, if they are activated and if the ambient light intensity is below a determined light threshold. Moreover, a speed sensor is provided for determining the speed of the bicycle in use on a path, so that the control unit controls the activation of the first light source from at least one determined speed threshold. An orientation detector is provided for orienting the light sources depending on a curve travelled by the bicycle in use.

A lighting control system for a vehicle includes a controller configured to be disposed at a vehicle so as to connect with or communicate with at least one light of the vehicle. The controller, responsive to at least one input, adjusts a color of the at least one light of the vehicle and an intensity of the at least one light of the vehicle. The input may include one or more of (i) a driver attentiveness input and (ii) a driver age input, and optionally a time of day input, an ambient light input, a weather condition input, and/or a navigation input.