In one embodiment, a computer-implemented method includes receiving a transportation request from a transportation requestor device to travel from a first location to a second location. The computer-implemented method also includes determining one or more routes from the first location to the second location and a characteristic associated with each route of the one or more routes. The computer-implemented method also includes selecting, based on the characteristic associated with each route of the one or more routes, a personal mobility vehicle from a fleet of personal mobility vehicles. The fleet of personal mobility vehicles includes different types of personal mobility vehicles. The computer-implemented method also includes providing instructions to a device associated with the personal mobility vehicle to direct the personal mobility vehicle to traverse a particular route of the one or more routes.

A control device includes a brake apparatus configured to operate a braking function of a vehicle and at least one rear lamp configured to output visible light to a rear of the vehicle at least in response to an operation of the brake apparatus. The control device also includes a sensing unit configured to sense information related to at least one of the vehicle or a surrounding of the vehicle, and at least one processor. The at least one processor is configured to, based on the information sensed through the sensing unit corresponding to a preset condition and a first vehicle being sensed at the rear of the vehicle, control the at least one rear lamp to output the visible light to the rear of the vehicle in a state in which the brake apparatus is not operated.

A vehicle illumination apparatus is disclosed. The apparatus comprises at least one light generating layer configured to conform to an outer surface of a panel of the vehicle. The light generating layer comprises a plurality of electrodes having a plurality of LEDs in a semiconductor ink disposed therebetween. The plurality of LEDs is operable to emit a first emission. The apparatus further comprises a controller configured to selectively activate the plurality of LEDs in response to a navigational direction of the vehicle.

A notification device includes: a notification-sound output portion provided in a vehicle and configured to output a notification sound toward the outside of the vehicle; a notification display portion provided in the vehicle and configured to output a notification display toward the outside of the vehicle; a notification controlling portion configured to control the notification sound of the notification-sound output portion and the notification display of the notification display portion; and a stop-state determination portion configured to determine whether the vehicle during the automatic driving enters a stop state or not. When the stop-state determination portion determines that the vehicle during the automatic driving enters the stop state, the notification controlling portion outputs a stop-time notification sound as the notification sound by the notification-sound output portion and outputs a stop-time notification display as the notification display by the notification display portion.

A rear-road surface illumination apparatus is provided which includes: an avoidance determiner 30 to determine whether to provide a display to induce a following vehicle to avoid a vehicle, on the basis of vehicle information; and a controller 9 to cause an illumination light 10 to illuminate a rear road surface with light having illumination information that induces the following vehicle to avoid the vehicle when the avoidance determiner 30 determines to provide a display to induce the following vehicle to avoid the vehicle. Therefore, the rear-road surface illumination apparatus can indicate the existence of the vehicle to the following vehicle, to give the existence of the vehicle prominence, and can also make it easy to notify the driver of the following vehicle about what the driver of the vehicle desires the driver of the following vehicle to do.

A mountable vehicle safety light system for conveying additional information regarding the motion of a vehicle. The mountable vehicle safety light system includes a housing having three rows of uniquely colored lights. The colors may include red, yellow and green. A first row indicates when a vehicle is braking, a second row indicates when a vehicle is neither braking nor accelerating, and a third row indicates when a vehicle is accelerating. Additionally, a first side member placed on a first side of the housing may indicate an upcoming right turn, while a second side member placed on an opposing second side of the housing indicates an upcoming left turn. A fastener is provided to secure the mountable vehicle safety light system to a flat surface, such as a rear windshield of a vehicle, in order to be easily visible to surrounding motorists and pedestrians.

A vehicle may have vehicle controls that are used in steering, braking, and accelerating the vehicle. The vehicle may have sensors that gather information on vehicle speed, orientation, and position. The sensors may also gather information on relative speed between the vehicle and a following vehicle, information on risks of a collision between a vehicle and an external object, and other vehicle status information and vehicle operating environment information. Control circuitry may use light-based devices to display braking information, information on vehicle speed, the relative speed between a vehicle and a following vehicle, autonomous driving mode status information, custom brake light information or other user-selected information, or other information on vehicle status and the operating environment of a vehicle.

A control system for a subject vehicle includes an autonomous braking system, a forward monitoring sensor and a rearward monitoring sensor. The controller monitors a first speed of a first vehicle travelling in front of the subject vehicle and a second speed of a second vehicle travelling to the rear of the subject vehicle. A first gap-closing time is determined based upon the speed of the subject vehicle and the first speed of the first vehicle. A second gap-closing time is determined based upon the speed of the subject vehicle and the second speed of the second vehicle. The controller controls the speed of the subject vehicle based upon the first gap-closing time and the second gap-closing time when one of the first gap-closing time or the second gap-closing time is less than a first threshold time.

Instead of binary brake lights on a car, the present disclosure provides methods and apparatus to provide an indicator of deceleration magnitude of a car, as caused by coasting or engine braking. An accelerometer or other means of approximating the magnitude of a braking force is coupled to a control module, which itself is coupled to auxiliary lights mounted on the car. These auxiliary lights are capable of displaying a pulse, color, or a pattern correlated to the magnitude of the deceleration force. Through a detection system, like lidar or radar, an oncoming obstacle can be anticipated and the auxiliary lights can be similarly actuated. This gives drivers behind the car an indication of how quickly to respond to a decelerating car.

The application relates to a lighting device for a motor vehicle for creating a light animation. The lighting device comprises a light emission device, the light emission device is subdivided into a plurality of segments. The lighting device further has a control unit, which is designed to separately control each of the plurality of segments of the light emission device. The control unit is also configured to control the plurality of segments in a way that a photometric parameter of the lighting device averaged across all segments for the light animation is within a predefined interval.