The disclosure relates to a method for illuminating a road area by a motor vehicle having the following steps: determining a trajectory relating to a future movement of the motor vehicle on a road, calculating a light distribution for a headlamp of the motor vehicle as a function of the determined trajectory in such a manner that a course of the trajectory is projected onto the road as part of the light distribution, and emitting a brightness distribution corresponding to the light distribution by the headlamp onto the road. In order to facilitate an improved overview of the driving of the motor vehicle, the light distribution is additionally calculated as a function of the determined trajectory in such a manner that, based on the light distribution in addition to the trajectory, an acceleration of the motor vehicle parallel to its longitudinal direction is also symbolized.

A variable beam pattern lamp system for a driver provides an input device that receives personal information of the driver, a lamp driving device that drives an indoor or outdoor lamp of a vehicle to output a beam pattern matched to the driver, based on the personal information of the driver, the personal information being input through the input device, and a vehicle controller that determines whether the personal information is registered driver information or unregistered driver information, when the personal information of the driver is input through the input device, and controls the lamp driving device to drive the indoor or outdoor lamp of the vehicle using beam patterns respectively corresponding to that the personal information is the registered driver information and that the personal information is the unregistered driver information.

This disclosure details illuminating vehicle closure member systems for selectively producing various exterior lighting effects. Exemplary closure member systems may include a closure member and a discrete illuminating section secured relative to the closure member and including a lighting module that is configured to produce at least one of a beltline lighting effect, a motion path lighting effect, or an operation status lighting effect at or near the closure member. A control module may control the various lighting effects emitted by the illuminating closure member system.

The disclosure relates to a method for illuminating a road area by a motor vehicle having the following steps: determining a trajectory relating to a future movement of the motor vehicle on a road, calculating a light distribution for a headlamp of the motor vehicle as a function of the determined trajectory in such a manner that a course of the trajectory is projected onto the road as part of the light distribution, and emitting a brightness distribution corresponding to the light distribution by the headlamp onto the road. In order to facilitate an improved overview of the driving of the motor vehicle, the light distribution is additionally calculated as a function of the determined trajectory in such a manner that, based on the light distribution in addition to the trajectory, an acceleration of the motor vehicle parallel to its longitudinal direction is also symbolized.

The present disclosure relates to methods and apparatus to provide a vehicle force indicator responsive to one or more of: an amount of tilt of a motor vehicle, an amount of acceleration and/or deceleration of the motor vehicle and a correlation of tilt and speed with location of the motor vehicle.

A vehicle capable of operating in a self-driving mode includes a self-driving indicator lamp and a controller. The self-driving indicator lamp can turn on so as to be visually recognized from an outside of the vehicle in the self-driving mode. The controller controls a lighting state of the self-driving indicator lamp. The self-driving indicator lamp includes a right indicator lamp and a left indicator lamp respectively disposed in right and left parts of the vehicle. Lighting states of the right indicator lamp and the left indicator lamp can be controlled independently. When the vehicle starts to move in the self-driving mode from a parked or stopped state, the lighting states of the right indicator lamp and the left indicator lamp which have turned off during when the vehicle has been parked or stopped, in a manner similar to each other so as to indicate a frontward or rearward starting direction.

Techniques are disclosed for systems and methods to provide lighted vehicle beaconing, particularly for micro-mobility fleet vehicles. A lighted vehicle beaconing system includes a vehicle light assembly configured to be coupled to and/or integrated with a micro-mobility fleet vehicle and a logic device configured to communicate with the vehicle light assembly. The vehicle light assembly includes a programmable light element configured to receive a lighting control sequence and generate a multicolored and/or animated lighting sequence corresponding to the received lighting control sequence. The logic device is configured to determine the lighting control sequence and to generate the multicolored and/or animated lighting sequence by providing the lighting control sequence to the programmable light element of the vehicle light assembly.

Aspects of the present disclosure may include a vehicle having one or more tires, a body, and an occupant compartment including: a rotatable platform, a central pod seat and one or more companion pod seats disposed on the rotatable platform, and one or more rear seats, wherein the rotatable platform is configured to rotate the central pod seat and the one or more companion pod seats toward a front of the vehicle in a first mode and toward a rear of the vehicle in a second mode, and wherein the central pod seat is further configured to translate linearly away from a center of the rotatable platform into a first position and toward the center of the rotatable platform into a second position.

A mountable automobile light fixture is configured to receive signals from a user controllable wireless controller, interpret the signals received from the user controllable wireless controller, and in response automatically control illumination of the mountable automobile light fixture, in both color and intensity. A processor of the mountable automobile light fixture is initially programmed to perform specific function(s) and/or strobe according to specific patterns. Thereafter, a user can select said specific function(s) for a scheduled and/or real-time performance. In some embodiments, the intelligent control is at least partially restricted from being reprogrammed by the user to serve other function(s), either by restricting the emission of light in at least one color and/or preventing specific strobing pattern(s).

A vehicle computing system may implement techniques to dynamically modify warning signals from a vehicle to ensure that an object (e.g., dynamic object) is notified of the vehicle operation. A vehicle computing system may emit a first warning signal including an audio and/or visual signal and may detect an object reaction to the first warning signal. Based on a determination that the object reaction does not substantially alter the ability for the vehicle to overcome the object, the vehicle computing system may modify a frequency, volume, luminosity, color, shape, motion, etc. of the first warning signal to emit a second warning signal. The vehicle computing system may continually modify warning signals until the object reacts according to an expected reaction or becomes irrelevant to the vehicle.