A method for operating a parking assistance function of a motor vehicle is described, wherein the motor vehicle comprises at least one sensor for detecting the road surrounding the motor vehicle. The method includes the following steps: Finding and specifying a free parking space; Determining a trajectory for parking the motor vehicle in the parking space and a sequence of an at least partially automated parking process; Determining at least one outer boundary line of the road surface required for parking along the identified trajectory; Detecting at least one road user approaching the determined outer boundary line on the road by means of at least one sensor; Determining the distance of the road user approaching the determined outer boundary line from the outer boundary line; if the determined distance falls below a specified first threshold, outputting a warning signal to the approaching road user.

A reflective substrate removably connected to at least a portion of at least one of a headlight and a tail light of a vehicle, the reflective substrate including a main body, including a reflective layer disposed on at least a portion of a first side of the main body to reflect an external light illuminated thereon and away therefrom in at least one angular direction toward at least one of a side, a top, and a bottom of the vehicle, and a transparent layer disposed on at least a portion of a second side of the main body opposite with respect to the first side to pass a beam of light from at least one of the headlight and the tail light through the transparent layer to the reflective layer, and a vehicle fastener disposed on at least a portion of the main body to removably connect the main body to at least one of the headlight and the tail light.

A tire state monitoring system includes: tire state acquisition devices installed on tires of a host vehicle, each of the tire state acquisition devices being configured to acquire a tire state quantity; a monitoring device configured to receive an output signal from each of the tire state acquisition devices and perform predetermined processing; and an alerting device configured to issue an alert to a following vehicle. In addition, the monitoring device causes the alerting device to operate when a predetermined abnormality has arisen in the tire state quantity.

A beacon provides an image projected onto a roadway at a distance from the vehicle to alert other vehicles as to the presence and speed and/or the deceleration (braking) of the vehicle. The beacon can include a laser that projects an image onto the roadway at a distance behind the vehicle. The laser is able to project this image through fog or other low visibility conditions. The image projected onto the roadway can be a recognizable image such as a universally recognized warning symbol. Alternatively, or additionally, a beacon can be mounted to a front of a vehicle which can alert a moving leading vehicle as to the presence of a moving trailing vehicle in low visibility conditions. The beacon can also be used to alert the driver of inadvertent crossing the roadway lane divider markings either visibly or electronically, in low visibility conditions.

The present disclosure relates to an active rear collision avoidance apparatus and method. The apparatus includes a sensor for acquiring information by detecting at least one of a preceding vehicle, a vehicle at risk of collision or other vehicles; and a controller for determining a possibility of collision between the vehicle at risk of collision and the host vehicle, determining a direction of avoidance preferentially from where an avoidable area exists in response to the driving of the vehicle at risk of collision, if the possibility of collision is higher than or equal to a threshold point, controlling the host vehicle to drive to avoid in the determined direction of avoidance, and controlling the host vehicle to drive to avoid a possible collision in response to a response to the transmitted avoidance request signal from the preceding vehicle and/or the other vehicle.

An autonomous driving control system and a method thereof are provided. The autonomous driving control system includes a strategy performing device that generates and performs a stop strategy of a vehicle on the basis of a target stop location, when a critical situation occurs during autonomous driving, a behavior controller that controls a behavior of the vehicle depending on the stop strategy, and an emergency module controller that runs a predetermined emergency module, when the critical situation occurs.

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.

The invention concerns a signaling device adapted to display pictograms, notably for a motor vehicle. The device is configured to implement at least one signaling function of a motor vehicle. The device includes display means including a display zone intended to be disposed on the vehicle, the display means being adapted to display pictograms in the display zone, each pictogram emitting a light beam having at least in part the statutory photometric characteristics of at least one of said at least one signaling functions.

A safety light system on an excavator or parked vehicle that is manually operated by the excavator operator. The unit is typically controlled by a single button located in the excavator cab. The excavator operator presses the button. A green LED, or other green light, projects a green beam of light toward the rear of the truck. This signals the truck driver that he can begin backing toward the excavator. At a predetermined distance, the excavator operator again pushes the button. The unit switches to an orange light. Finally, in a final position, the excavator operator again presses the button to project a red light. As the truck driver backs toward the excavator, he first sees green, then orange and finally red. Upon seeing red, he knows to stop backing. A fourth push can again project a green light signaling a safe condition for drive-away.

Various systems and methods for implementing a reverse-facing anti-collision mechanism are described herein. An anti-collision system for a lead vehicle to provide an alert to a trailing vehicle behind the lead vehicle, includes a vehicle controller subsystem to receive from a sensor array interface, sensor data from a rear-facing sensor incorporated into the lead vehicle; determine, using a processor, from the sensor data that the trailing vehicle is a collision risk; and initiate, via a light controller, a visual alert to the trailing vehicle, the visual alert in addition to or in place of brake lights on the lead vehicle.