A communication system for a vehicle comprises a mechanism for sensing a change in speed of the vehicle and a control device for sending a signal to a headlight activation circuit to modulate the vehicle's headlights based upon the change in speed. In particular, a headlight of the vehicle is able to be modulated as the vehicle reduces speed and/or is decelerating as it approaches an intersection. Additionally, the headlight of the vehicle is able to be modulated as the vehicle accelerates from a stopped position or reaches a certain traveling speed. The headlight activation circuit is able to modulate the headlight between an on position and an off position or modulate the headlight between a high beam position and a low beam position. Consequently, the vehicle is better seen as it approaches likely congestion areas such as intersections and slowing or stopped traffic and attempts to enter traffic.

A safety lighting system for vehicles. A safety lighting system may include a display cover including a first portion, a second portion, and a third portion. The safety lighting system may further include at least one light source configured to selectively illuminate the first, second, and third portions of the display cover. The safety lighting system may further include a controller configured receive at least one of acceleration/deceleration information, braking information or throttle control information relating to the vehicle, and to responsively cause illumination of the first portion upon at least one of acceleration or operation of the throttle of the vehicle, to cause illumination of the second portion upon at least one of relatively low deceleration of the vehicle or deceleration of the vehicle without braking, and to cause illumination of the third portion upon at least one of relatively high deceleration or braking of the vehicle.

A system for displaying contextually-sensitive braking information on a surface of a vehicle is presented. The system may include a transceiver, one or more memories, an electronic display disposed on the surface, and one or more processors. The one or more processors may be configured to detect a braking event of the vehicle, wherein the braking event has an associated braking force. The one or more processors may compare the braking force to a predetermined threshold braking force to determine whether the braking force exceeds the threshold braking force. The one or more processors may further cause the electronic display to display a braking indication having an intensity that is proportional to the braking force, wherein the braking indication may include a braking rationale corresponding to the braking event in response to determining that the braking force exceeds the threshold braking force.

The condition responsive vehicular taillight is a safety device. The condition responsive vehicular taillight incorporates a vehicle and a control circuit. The control circuit mounts in the vehicle. The control circuit senses changes in the momentum of the vehicle. The control circuit generates a visual indication of the changes in the momentum of the vehicle. The visual indication is visible from the exterior of the vehicle. The visual indication is visible when viewed from the rear side of the vehicle.

A system for implementing strobing of existing vehicle hazard lights including an interface to a vehicle wiring harness configured to receive input to an existing vehicle flasher module, and a strobing circuit that responds to an activation signal from the vehicle wiring harness that is indicative of a hazard flasher deployment event by producing an electrical output through the interface to the vehicle wiring harness that causes a strobing of existing vehicle hazard lamps.

A notifying method includes detecting an object existing in a periphery of a vehicle and determining a type of the object existing in the periphery of the vehicle. The notifying method further includes emitting a visible light to irradiate at least a part of the periphery of the vehicle with an irradiation pattern. The irradiation pattern includes an icon pattern indicating the type of the object.

Personal mobility vehicles, their various components, methods and systems for controlling, using, tracking, and/or interacting with personal mobility vehicles, and methods and systems for integrating personal mobility vehicles within dynamic transportation networks so that a personal mobility vehicle (PMV) can be used in combination with a vehicle of a transportation provider to efficiently complete a transportation request are discussed. For example, a PMV may be used in combination with a lane-constrained vehicle to improve travel time between two locations in situations where the time it may take for a lane-constrained vehicle to reach the starting location may be affected by traffic congestion at the starting location. The PMV may transport a transportation requestor from a starting location to an intermediate location away from the traffic congestion to then transfer to a lane-constrained vehicle for the remainder of the trip.

A vehicle lamp may include a first light image forming unit configured to form a first light image, a second light image forming unit configured to form a second light image, and a controller configured to control the first light image forming unit and the second light image forming unit in response to an input operation command. In particular, the controller is configured to control the first light image forming unit to cause a luminous intensity of the first light image to be increased in response to a target operation command for a target operation of the second light image forming unit being input in a state in which the first light image forming unit forms the first light image.

A system for displaying contextually-sensitive braking information on a surface of a vehicle is presented. The system may include a transceiver, one or more memories, an electronic display disposed on the surface, and one or more processors. The one or more processors may be configured to detect a braking event of the vehicle, wherein the braking event has an associated braking force. The one or more processors may compare the braking force to a predetermined threshold braking force to determine whether the braking force exceeds the threshold braking force. The one or more processors may further cause the electronic display to display a braking indication having an intensity that is proportional to the braking force, wherein the braking indication may include a braking rationale corresponding to the braking event in response to determining that the braking force exceeds the threshold braking force.

A lighting system enables a lighting pattern to be displayed on a vehicle when the vehicle is in motion. A lighting pattern may include lights that fluctuate (with respect to luminosity) or lights that stay on at the same luminosity. The length of time that a light, such as an LED lamp, is powered on may vary. Similarly, the amount of time between two adjacent lights are powered off and powered on may also vary. As such, the lighting sequence is flexible and can be customized so that all lights are not on for the same length of time and the time between two lights being powered may vary. A vehicle front alert system allows for improved perception of speed of an approaching vehicle, human, or object.