Methods and systems for notifying a driver of a first vehicle of obstacles discouraging passing of a second vehicle in front of the first vehicle. The system includes a sensor of the second vehicle configured to detect spatial data in proximity of the second vehicle. The system also includes an electronic control unit (ECU) of the first vehicle. The ECU is configured to receive the spatial data from a transceiver of the second vehicle. The ECU is also configured to determine obstacle data based on the spatial data, the obstacle data identifying a presence of obstacles ahead of the second vehicle discouraging passing of the second vehicle by the first vehicle. The ECU is also configured to provide a notification to the driver of the first vehicle when the obstacle data indicates the presence of obstacles ahead of the second vehicle.

An electronic parking brake control system and method for controlling a parking brake of a vehicle. The system includes an electronic parking brake variable switch configured to produce an application signal based on an amount or an amount of time the switch is pulled upward or pushed downward. The system also includes an indicator configured to indicate an amount of application of the parking brake based on the application signal. The system also includes an electronic brake unit coupled to the electronic parking brake variable switch. The electronic brake unit is configured to receive the application signal, and transmit a rear brake signal to a plurality of rear brake actuators to apply a plurality of rear brakes based on the application signal when a speed of the vehicle is below a threshold speed or the vehicle is in a low gear.

A functional interior trim part for a vehicle is disclosed. The trim part includes a layered structure having at least a base support, a functional layer and a haptic layer. The functional interior trim part includes an electrical shielding layer. The electrical shielding layer leads to a selective sensor field expression in the direction of an operating half-space. The electrical shielding layer is arranged on a side of the functional layer facing away from the haptic layer. A method for manufacturing the interior trim part is also disclosed.

A functional interior trim part for a vehicle is disclosed. The trim part includes a layered structure having at least a base support, a functional layer and a haptic layer. The functional interior trim part includes an electrical shielding layer. The electrical shielding layer leads to a selective sensor field expression in the direction of an operating half-space. The electrical shielding layer is arranged on a side of the functional layer facing away from the haptic layer. A method for manufacturing the interior trim part is also disclosed.

A method for detecting whether a motor vehicle is located within a section of a roadway, comprising the following steps: detecting roadway markings of a roadway on which the motor vehicle is located, detecting whether the motor vehicle is located within a section of the roadway, wherein the section is defined by section boundaries, and then outputting a warning if the motor vehicle is not located within the section, wherein the section boundaries are defined depending on a marking distance of the roadway markings from one another.

A method for detecting whether a motor vehicle is located within a section of a roadway, comprising the following steps: detecting roadway markings of a roadway on which the motor vehicle is located, detecting whether the motor vehicle is located within a section of the roadway, wherein the section is defined by section boundaries, and then outputting a warning if the motor vehicle is not located within the section, wherein the section boundaries are defined depending on a marking distance of the roadway markings from one another.

The present disclosure relates to an autonomous emergency braking system and a method. More specifically, the autonomous emergency braking system according to the present disclosure includes: a sensor that includes a gravity sensor detecting a force of gravity applied to a host vehicle and a vehicle-speed sensor detecting a vehicle speed of the host vehicle; an inclination determiner that determines an inclination of a road surface on which the host vehicle is traveling based on the vehicle speed of the host vehicle and the force of gravity; and a controller that adjusts an AEB warning time based on the determined inclination of the road surface.

A method for directionally warning as to a target object behind a vehicle acquires images of environment surrounding the vehicle. Objects in the environment images are identified and high-risk target object or objects from all the objects is labeled. A relative direction and a relative location of the target object with the transportation are confirmed. A warning device is adjusted based on the relative direction and the relative location. The warning device gives directional warning as to the target object. A collision risk warning system and a transportation applying the method are also disclosed.

A getting-off support device of a vehicle continues to issue an alarm for a predetermined time when a physical body condition indicating that a physical body that obstructs getting-off of an occupant in the vehicle exists around the vehicle and a getting-off condition indicating that the occupant in the vehicle intends to get off the vehicle are satisfied, and prolongs the time of issuing the alarm when both of the physical body condition and the getting-off condition are further satisfied while the issuing of the alarm is continued.

A system comprising a client device and a quiet vehicle proximity alert device. The quiet vehicle proximity alert device is associated with a vehicle and configured to broadcast a set of data with respect to a status of the vehicle. The client device is configured to issue a first notification on receiving the set of data if one or more data from the set of data is found to match one or more pre-specified conditions. A second notification is issued by the quiet vehicle proximity alert device on receiving a request for the second notification transmitted by the client device. The second notification comprises an acoustic notification and a driver alert notification. The acoustic notification is dynamically adjusted in real-time by the quiet vehicle proximity alert device corresponding to the status of the vehicle and a status of the client device.