A puddle light system projects content-bearing images onto a ground surface adjacent a vehicle using a puddle light projector unit having a multicolor light source configured to project the content-bearing images using at least one selected color from a plurality of available colors. An image sensor directed at the ground surface and mounted on the vehicle is configured to capture colored images. A controller is configured to (A) construct one of the content-bearing images as an image representation with an illumination region to be projected onto the ground, (B) analyze a first colored image of the ground surface with the light source deactivated to identify a dominant surface color, (C) select a complementary color relative to the dominant surface color, (D) colorize the illumination region using the selected complementary color, and (E) command the puddle light projector unit to project the image representation using the colorized illumination region.

A system, a method, and a computer program product may be provided for user guidance. In an example, the system includes an image projection device configured to project traffic patterns on a surface, at least one non-transitory memory configured to store computer program code, and a processor configured to execute the computer program code to control operation of the image projection device. For example, sensor data from one or more sensors onboard a vehicle is obtained. The sensor data is associated with a state of operation of the vehicle, and proximate movement associated with the vehicle. Based on the sensor data, one or more traffic patterns for projection is determined. Further, an image projection device is controlled to project the one or more traffic patterns in one or more direction of the vehicle.

Flood damage information at the position of the autonomous vehicle and a flood index representing the likelihood of flooding at the position of the automatically driving vehicle are acquired. Based on the flood damage information and the flood index, a predicted flood water level at the position of the autonomous vehicle is obtained. A predicted flood water level is displayed in the form of a height position from the road surface on a display mounted on the autonomous vehicle so that it can be visually recognized from the outside of the autonomous vehicle.

A vehicle illumination system provided in a vehicle capable of traveling around a corner by inclining a vehicle body toward a turning direction includes: a headlamp mounted on a front portion of the vehicle; a communication lamp disposed on the vehicle body in a region adjacent to the head lamp so as to be visible from ahead of the vehicle; and an illumination control unit configured to change a lighting mode of the communication lamp depending on a state of the vehicle.

Systems and methods for alerting a pedestrian of the density of automated vehicles to non-automated vehicles in an area by broadcasting a visual signal representing a group mode status of automated vehicles travelling towards or within a roadway intersection. The group mode status may be broadcast as a percentage of automated vehicles to total vehicles or can be broadcast as a ratio of automated vehicles to non-automated vehicles on an external mode indicator of a subject automated vehicle. The visual signal may be broadcast as a pattern of lighting, a change in light intensity, a change in colors or a change in text. The group mode status may also be broadcast to a pedestrian equipped with a wireless device via vehicle-to-infrastructure communications. The group status may also be broadcast to and displayed on infrastructure component, such as a street light, display post, crosswalk sign, or building display configured to receive signals.

Aspects of the present disclosure involve projecting an interactive scene onto a surface from a projecting object. In one particular embodiment, the interactive scene is projected from a vehicle and may be utilized by the vehicle to provide a scene or image that a user may interact with through various gestures detected by the system. In addition, the interactive scene may be customized to one or more preferences determined by the system, such as user preferences, system preferences, or preferences obtained through feedback from similar systems. Based on one or more user inputs (such as user gestures received at the system), the projected scene may be altered or new scenes may be projected. In addition, control over some aspects of the vehicle (such as unlocking of doors, starting of the motor, etc.) may be controlled through the interactive scene and the detected gestures of the users.

A vehicle illumination system provided in a vehicle capable of traveling around a corner by inclining a vehicle body toward a turning direction includes: a headlamp mounted on a front portion of the vehicle; a communication lamp disposed on the vehicle body in a region adjacent to the head lamp so as to be visible from ahead of the vehicle; and an illumination control unit configured to change a lighting mode of the communication lamp depending on a state of the vehicle.

The present disclosure provides a blocked information displaying method and system for use in an autonomous vehicle. The method comprises obtaining information about a road ahead the autonomous vehicle and information about a rear vehicle; determining road information blocked by the autonomous vehicle, according to a positional relationship between the autonomous vehicle and the rear vehicle; displaying the road information blocked by the autonomous vehicle to the rear vehicle. The present disclosure is used to solve problems in the prior art that the autonomous vehicle blocks road surface information and causes limitation to the field of vision of the rear vehicle, and that real-time display of the images of the road ahead the autonomous vehicle is prone to cause confusion, and can effectively improve the safety of the travel of the rear vehicle.

A display device controlled via a smart phone (preferably using an TNC App) to display content selected by a requesting rider (e.g., code, symbol, the rider name, or a photo) in a clear and visible way to the waiting rider is a convenient method to identify the rider's designated vehicle instead of trying to search through model, color, and license plates of approaching vehicles as they enter a pickup area (e.g., airport designated area). The selected content is displayed on a display unit on the designated vehicle, and is transmitted to the display unit via a server associated with the designated vehicle using a secure protocol.

A rearview safety warning device of a vehicle has a rearview mirror assembly, a display unit, a wireless transmission unit, and a processing unit. The rearview mirror assembly has a mirror having a mirror-surface area and a display area. The display unit displays a warning information through the display area of the mirror. The wireless transmission unit communicates with a mobile device via a wireless communication technique. The processing unit is signally connected to the display unit and the wireless transmission unit. The processing unit receives a traffic data from the mobile device via the wireless transmission unit and activates the display unit to display the warning information according to the traffic data.