A vehicle projection control device includes: an occupant detection unit configured to detect an occupant on a vehicle; a traveling information acquisition unit configured to acquire traveling information of the vehicle and information indicating that the vehicle is traveling; a projection control unit configured to, when the occupant detection unit has detected the occupant and the traveling information acquisition unit has acquired the information indicating that the vehicle is traveling, cause a projection unit to project the acquired traveling information, the projection unit being configured to project a video in a direction corresponding to a body of the occupant on the vehicle; and a head detection unit configured to detect a head of the occupant on the vehicle in a projection direction of the projection unit. The projection control unit is configured to change a projection location of the acquired traveling information based on a location of the detected head.

An information processing apparatus comprises a storage configured to store navigation-related information; and a controller configured to execute: predicting a course of a vehicle based on at least the navigation-related information, and projecting a first image related to the predicted course onto a road surface located in front of the vehicle.

A dedicated U-turn signal light system for motor vehicles will be added. This is achieved by introducing a U-turn signal light in the form of a green arc (or an alternative color adhering to the national motor vehicle codes) capping the existing conventional turn signals and activated where a U-turn is allowed. The U-turn arc signal will flash in an animated fashion and simultaneously with the conventional turn signal. This will apply on each direction (left or right). A revised design of the signal lever will be made to accommodate for two additional U-turn positions served by adding two U-turn slots in the signal lever control box. An additional two electrical switches will confirm simultaneous flashing of the conventional turn and U-turn signals.

A dedicated U-turn signal light system for motor vehicles will be added. This is achieved by introducing a U-turn signal light in the form of a green arc (or an alternative color adhering to the national motor vehicle codes) capping the existing conventional turn signals and activated where a U-turn is allowed. The U-turn arc signal will flash in an animated fashion and simultaneously with the conventional turn signal. This will apply on each direction (left or right). A revised design of the signal lever will be made to accommodate for two additional U-turn positions served by adding two U-turn slots in the signal lever control box. An additional two electrical switches will confirm simultaneous flashing of the conventional turn and U-turn signals.

A lamp system includes a road surface drawing lamp that illuminates a road surface with a beam BM, and a lamp controlling unit that controls the road surface drawing lamp and draws, with the beam BM, a pattern PTN on the road surface ahead of a vehicle. The lamp controlling unit draws a first pattern before a start of a predetermined event and draws a second pattern at the start of the event. The first pattern includes first information to be presented in advance to a driver to allow the driver to respond to the event, and the second pattern includes second information corresponding to the event.

To provide a vehicular lamp capable of making a desired light distribution on a light shielding member while having a simple configuration. The vehicular lamp comprises a first and second light source each having a light emitting surface and being arranged in a predetermined parallel direction; a single condenser lens for condensing light emitted from the first and second light source; a light shielding member provided with an irradiation slit through which light condensed by the condenser lens is partially passed; and a projection lens for projecting light passed through the light shielding member to form an irradiation pattern. The first and second light source are arranged with an interval equal to or larger than dimensions in the parallel direction on the light emitting surfaces, the condenser lens makes a light distribution in which a high light quantity area with the highest light quantity is single in the parallel direction.

To provide a vehicular lamp capable of making a desired light distribution on a light shielding member while having a simple configuration. The vehicular lamp comprises a first and second light source each having a light emitting surface and being arranged in a predetermined parallel direction; a single condenser lens for condensing light emitted from the first and second light source; a light shielding member provided with an irradiation slit through which light condensed by the condenser lens is partially passed; and a projection lens for projecting light passed through the light shielding member to form an irradiation pattern. The first and second light source are arranged with an interval equal to or larger than dimensions in the parallel direction on the light emitting surfaces, the condenser lens makes a light distribution in which a high light quantity area with the highest light quantity is single in the parallel direction.

A method and a system can include receiving travel direction information representing a planned driving maneuver of the motor vehicle, detecting at least one road user in a path region of the planned driving maneuver based on an evaluation of at least the travel direction information, determining a lamp operation data set for operating at least one lamp of the motor vehicle based on the evaluation of at least the travel direction information when a road user is detected in the path region, and operating the lamp in accordance with the lamp operation data set.

The vehicle includes an operation switch for manually operating the operation state of the accessories. The vehicle control system includes a first controller that performs an evacuation traveling in response to a decrease in the driver's consciousness level, and a second controller that controls an operation state of the accessories based on a request from the first controller or operation information of the operation switch. The first controller is configured to transmit, to the second controller, a specific operation rejection request for performing a specific operation rejection process of rejecting the control of the accessories based on the specific operation of the operation switch in response to a decrease in the driver's consciousness level. The second controller is configured to perform the specific operation rejection process when the specific operation rejection request is received from the first controller.

A method increases fidelity of a lane localization function aboard a motor vehicle by receiving input signals indicative of a relative position of the vehicle with respect to a roadway. The input signals include GPS and geocoded mapping data, and an electronic turn signal indicative of activation of the turn signal lever. Sensor-specific lane probability distributions are calculated via the lane localization function using the input signals. The various distributions are fused via the localization function to generate a host lane assignment. The host lane assignment corresponds to a lane of the roadway having a highest probability among a set of possible lane assignments. An autonomous steering control action is performed aboard the motor vehicle using an Advanced Driver Assistance System (ADAS) in response to the host lane assignment. A motor vehicle has a controller that performs the method, e.g., by executing instructions from computer-readable media.