A steering wheel attachment device removably connected to at least a portion of a steering wheel of a vehicle, the steering wheel attachment device including a main body, and a pressure dissemination unit disposed within at least a portion of the main body to provide a pressured sensation to the steering wheel corresponding to a touch by a user.

A vehicular trailering assist system includes a camera and an image processor operable to process image data captured by the camera. The vehicular trailering assist system iteratively predicts a plurality of predicted trailer angles based on a corresponding plurality of potential trailer beam lengths ranging between an upper dimension above a baseline trailer beam length and a lower dimension below the baseline trailer beam length and selects a trailer angle from the plurality of predicted trailer angles that least deviates from a current trailer angle determined via processing by the image processor of image data captured by the camera. The potential trailer beam length that corresponds to the selected trailer angle that least deviates from the determined current trailer angle is used in determining trailer angles for that trailer during future drives of the vehicle when towing that particular trailer.

A steering wheel includes a steering hub portion, a wheel portion and a spoke portion. The spoke portion extends from the steering hub portion and is connected with the wheel portion. The wheel portion includes a core metal and a cover layer. The core metal circles around the steering wheel. The cover layer covers the core metal. A vibrator housing portion is provided at a part in a circling direction of the core metal. The core metal includes a U-shaped cross section in the vibrator housing portion in a radial direction of the wheel portion. A partition wall is provided inside of the core metal to divide and form the vibrator housing portion. A case is attached to the core metal to cover the vibrator housing portion. The vibrator is disposed in the vibrator housing portion between the core metal and the case. The vibrator is attached to the case.

A guidance system for aligning a vehicle entering or leaving a structure, the structure having a front wall having an inner surface and an outer surface with an opening therein, the guidance system comprising a left photoelectric diffuse sensor operatively arranged to detect lateral movement of the vehicle, providing a left input signal, a right photoelectric diffuse sensor operatively arranged to detect movement of the vehicle, providing a right input signal, a left visual indicator operatively arranged to display an alert when the vehicle deviates from leftwardly alignment, a right visual indicator operatively arranged to display an alert when the vehicle deviates from rightwardly alignment and, a control center operatively arranged to receive the left and right input signals, calculate the leftwardly and rightwardly alignment, and cause the left and right visual indicators to display alerts when the vehicle deviates from leftwardly and/or rightwardly alignment by predetermined amounts.

A system for a vehicle includes a sensor configured to sense information associated with the vehicle's surroundings, environment and/or condition and output a sensor signal based on the sensed information, a processor configured to receive the sensor signal, determine haptic feedback for the system to display based on the sensor signal, and output a haptic control signal, and a haptic output device configured to receive the haptic control signal from the processor and generate the haptic feedback to a driver of the vehicle based on the haptic control signal.

Disclosed is a system comprising a vehicle, a trailer, and a display screen. The system includes a trailer angle between a centerline of the vehicle and a centerline of the trailer. At least one time step after the vehicle is driven backward such that the trailer angle increases beyond a threshold value, a steering warning icon is displayed on the display screen. When the trailer angle decreases below the threshold value, the steering warning icon is removed from the display screen.

A vehicle driver warning device includes: a steering angle sensor (SAS) producing steering signals representative of a real time angle of rotation of a steering column (RTARSC), a control unit receiving said signals and generating a timer activation signal (TAS) when an absolute value of the RTARSC is equal to a maximum value and a timer deactivation signal (TDS) when the absolute value is less than the maximum value after being equal to the maximum value, a timer receiving the TAS and starting a preset period of time countdown and interrupting said countdown if the TDS is received before the countdown ends, an alarm module generating an alarm perceptible to the driver upon receiving an alarm activation signal (AAS), wherein the control unit generates and communicates the AAS to the alarm module at the end of the preset period of time if the countdown has not been interrupted.

The invention relates to a lane change assistant for a vehicle comprising a sensor arrangement for calculating information relating to lanes and other road users. Provided is an arithmetic and logic unit for calculating movement paths for a first lane change and a subsequent second lane change to the original lane. The vehicle driver can accept or initiate the calculated lane changes. An actuator unit can then execute the lane changes calculated by the arithmetic and logic unit and initiated by the vehicle driver upon receipt of a signal from the arithmetic and logic unit.

A system and method for navigating a vehicle automatically from a current location to a destination location without a human operator is disclosed. The method includes identifying a vehicle location using global positioning system (GPS) data regarding the vehicle. Also included is identifying that the vehicle location is near or at a parking location. Then, using mapping data defined for the parking location. The mapping data at least in part is used to find a path at the parking location to avoid a collision of the vehicle with at least one physical structure when the vehicle is automatically moved at the parking location. The method includes instructing the electronics of the vehicle to proceed with controlling the vehicle to automatically move from the current location to the destination location at the parking location. The electronics use as input at least part of the mapping data and sensor data collected from around the vehicle by at least two vehicle sensors. The path is configured to be updatable dynamically based on changes in the destination location or changes along the path. The destination location is a parking spot for the vehicle at the parking location.

A tire (100) rolls on a surface (105). A method (600) for providing maximum traction coefficient between the tire (100) and the surface (105) include steps for detecting a momentary slip of the tire (100) on the surface (105); detecting a momentary traction coefficient; forming a tuple (410, 510) from the slip and the current traction coefficient; choosing a characteristic curve (205, 305) from a number of predetermined characteristic curves (205, 305) on the basis of the tuple (410, 510), whereby each characteristic curve (205, 305) describes a traction behavior of the tire (100) or a corresponding characteristic pitch; determining the maximum traction coefficient on the basis of the selected characteristic curves (205, 305); and thus providing the maximum traction coefficient.