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 priority control circuit for the operation of vehicle lamps. The priority control circuit includes a first circuit and a second circuit. The first circuit includes a first PNP transistor, a first NPN transistor having a gate connected to a collector of the first PNP transistor, and a first output port connected to a collector of the first NPN transistor. When a first lamp turn-on signal for turning on a first lamp is input, the first circuit turns on a second lamp and a third lamp. The second circuit includes a second NPN transistor, a second PNP transistor having a gate connected to a collector of the second NPN transistor, and a second output port connected to a collector of the second PNP transistor. The second circuit controls priorities for the operation of the second lamp and the third lamp.

A plastic glazing of a window of a vehicle having a light feature includes a first vehicle window glazing component, a second vehicle window glazing component molded onto the first vehicle window glazing component, and a light unit configured to produce light for the light feature. The light unit being integrated with at least one of the following: the first vehicle window glazing component and the second vehicle window glazing component. The light unit further configured to direct the light for the light feature through or from at least one of the following: the first vehicle window glazing component and the second vehicle window glazing component. The plastic glazing is a one-piece molded plastic construction. At least one of the first vehicle window glazing component and the second vehicle window glazing component is translucent or transparent

In a turn signal cancelation system for a two-wheeled vehicle, a controller is adapted to automatically cancel the turn signal of the vehicle upon: (a) a determined distance traveled by the vehicle after an occurrence of the predetermined operation of the vehicle exceeding a first distance threshold and a determined yaw angle traversed by the vehicle after the occurrence of the predetermined operation of the vehicle exceeding a yaw angle threshold; and (b) the determined distance traveled by the vehicle after the occurrence of the predetermined operation of the vehicle exceeding a second distance threshold, different from the first distance threshold, independent of the determined yaw angle traversed by the vehicle after the occurrence of the predetermined operation of the vehicle.

In a turn signal cancelation system for a two-wheeled vehicle, a controller is adapted to automatically cancel the turn signal of the vehicle upon: (a) a determined distance traveled by the vehicle after an occurrence of the predetermined operation of the vehicle exceeding a first distance threshold and a determined yaw angle traversed by the vehicle after the occurrence of the predetermined operation of the vehicle exceeding a yaw angle threshold; and (b) the determined distance traveled by the vehicle after the occurrence of the predetermined operation of the vehicle exceeding a second distance threshold, different from the first distance threshold, independent of the determined yaw angle traversed by the vehicle after the occurrence of the predetermined operation of the vehicle.

A wireless lighting system used with demountable equipment, including truck-mounted forklifts (TMFL). The system includes a transmitter installed in a lighting harness or trailer lighting socket on a transporting vehicle. When the transporting vehicle's notification lights or signals (turn signals, tail lights, brake lights, clearance lights, reverse lights) are activated, a wireless signal is transmitted to a wireless receiver located on the TMFL, and a corresponding light or lights are activated on the TMFL. The system utilizes the power source of the TMFL to power the notification lights of the TMFL while being transported. Further, when the forklift is dismounted and in operation, the wireless lighting system is disabled until the forklift is returned to the transport position on the transport vehicle. This prevents actuation of the lights on the forklift unless the forklift is on the transport vehicle.

A wireless lighting system used with demountable equipment, including truck-mounted forklifts (TMFL). The system includes a transmitter installed in a lighting harness or trailer lighting socket on a transporting vehicle. When the transporting vehicle's notification lights or signals (turn signals, tail lights, brake lights, clearance lights, reverse lights) are activated, a wireless signal is transmitted to a wireless receiver located on the TMFL, and a corresponding light or lights are activated on the TMFL. The system utilizes the power source of the TMFL to power the notification lights of the TMFL while being transported. Further, when the forklift is dismounted and in operation, the wireless lighting system is disabled until the forklift is returned to the transport position on the transport vehicle. This prevents actuation of the lights on the forklift unless the forklift is on the transport vehicle.

Devices, systems and methods for controlling an exterior and dashboard lights of an autonomous vehicle are described. One example of a method for controlling one or more exterior lights includes receiving, from an autonomous driving system (ADS) of the vehicle, an input to control one or more exterior lights that are part of a lighting system of the vehicle, and transmitting, based on the input, a message to a controller area network (CAN) bus of the lighting system, the message being further based on a driver command upon a determination that a driver-initiated message is received. In an example, the lighting system of the vehicle further comprises a plurality of dashboard lights.

Devices, systems and methods for controlling an exterior and dashboard lights of an autonomous vehicle are described. One example of a method for controlling one or more exterior lights includes receiving, from an autonomous driving system (ADS) of the vehicle, an input to control one or more exterior lights that are part of a lighting system of the vehicle, and transmitting, based on the input, a message to a controller area network (CAN) bus of the lighting system, the message being further based on a driver command upon a determination that a driver-initiated message is received. In an example, the lighting system of the vehicle further comprises a plurality of dashboard lights.

In one embodiment, a method includes receiving, using one or more sensors of a first vehicle, sensor data associated with an environment surrounding the first vehicle. The method includes detecting, using the sensor data, a second vehicle in the environment surrounding the first vehicle. The method includes determining, based on the sensor data, a first movement context associated with the first vehicle and a second movement context associated with the second vehicle. The method includes coordinating, via a ride matching system, movements between the first vehicle and the second vehicle based on the first movement context associated with the first vehicle and the second movement context associated with the second vehicle.