Abstract: An autonomous vehicle comprising an integrated on-vehicle system having a queue management system configured to manage a queue of passenger waypoints, wherein the integrated on-vehicle system is configured to assign the passenger waypoints to a virtual driver system (VDS) of the autonomous vehicle.

Abstract: An autonomous vehicle comprising an integrated on-vehicle system having a queue management system configured to manage a queue of passenger waypoints, wherein the integrated on-vehicle system is configured to assign the passenger waypoints to a virtual driver system (VDS) of the autonomous vehicle.

Abstract: The trailer backup assist system has a human machine interface coupled to a controller having a setup module, a calibration module, an activation module and a control module configured to receive trailer measurements, apply trailer measurements, activate and control vehicle systems to calibrate and implement a curvature control algorithm that controls the reverse movement of the vehicle-trailer combination in a manner consistent with a driver request.

Abstract: A system includes a processor configured to receive a trailer image. The processor is also configured to identify an axle in the trailer image and identify a tongue-end in the trailer image. Further, the processor is configured to receive a tire image, including a wheel diameter provided on a tire. The processor is additionally configured to retrieve the wheel diameter from the tire image. The processor is also configured to identify a wheel, having an indentified diameter corresponding to the wheel diameter, in the first image. Additionally, the processor is configured to calculate a distance from the axle to the tongue-end using the identified diameter.

Abstract: A system and method for configuring a trailer backup assist system. The system and method communicates predetermined trailer parameters, which are embedded on a tag attached to the trailer, to a controller in the trailer backup assist system. A trailer backup assist system is configured using the predetermined trailer parameters and the configured trailer backup assist system is activated to operate using the trailer parameters.

Abstract: A vehicle system includes at least one autonomous driving sensor that detects a location of a target vehicle, a communication device that receives infrastructure information from an infrastructure device, and a processing device that controls operation of at least one vehicle subsystem according to the infrastructure information. An exemplary method includes determining a location of a target vehicle, receiving infrastructure information from an infrastructure device, and controlling operation of at least one vehicle subsystem according to the infrastructure information.

Abstract: A system and method for configuring a trailer backup assist system. The system and method communicates predetermined trailer parameters, which are embedded on a tag attached to the trailer, to a controller in the trailer backup assist system. A trailer backup assist system is configured using the predetermined trailer parameters and the configured trailer backup assist system is activated to operate using the trailer parameters.

Abstract: A method and system for estimating hitch angle between a vehicle and a trailer coupled thereto. The system has a wireless receiver on the vehicle located a predetermined distance from a trailer mount, a wireless transmitter located at an end of the trailer opposite the trailer mount, and a controller for monitoring power returns of a signal transmitted from the transmitter to the receiver and for estimating a distance between the transmitter and the receiver as a function of a path loss propagation of the transmitted signal. The bitch angle is estimated using the estimated distance, the predetermined distance and a trailer length.

Abstract: A system includes a processor configured to receive a trailer image. The processor is also configured to identify an axle in the trailer image and identify a tongue-end in the trailer image. Further, the processor is configured to receive a tire image, including a wheel diameter provided on a tire. The processor is additionally configured to retrieve the wheel diameter from the tire image. The processor is also configured to identify a wheel, having an indentified diameter corresponding to the wheel diameter, in the first image. Additionally, the processor is configured to calculate a distance from the axle to the tongue-end using the identified diameter.

Abstract: A vehicle has a wireless receiver located a predetermined distance from a trailer mount. A wireless transmitter on the trailer is located at an end of the trailer opposite the end that attaches to a trailer mount on the vehicle and communicates with the wireless receiver on the vehicle. A controller on the vehicle monitors the power returns of the signal transmitted between the transmitter and the receiver. A hitch angle monitoring system monitors hitch angle over time. The controller monitors power returns of a signal transmitted from the transmitter to the receiver and estimates a distance between the transmitter and the receiver as a function of a path loss propagation of the transmitted signal. The trailer length is equal to the distance estimated by the controller at times when the hitch angle is zero minus the predetermined distance.

Abstract: The trailer backup assist system has a human machine interface coupled to a controller having a setup module, a calibration module, an activation module and a control module configured to receive trailer measurements, apply trailer measurements, activate and control vehicle systems to calibrate and implement a curvature control algorithm that controls the reverse movement of the vehicle-trailer combination in a manner consistent with a driver request.

Abstract: A vehicle control system includes one or more driver intent detection devices to detect at least a curve-negotiating intention of a driver. The system also includes one or more curvature detection devices, to detect or otherwise determine a road curvature. The system further includes one or more overspeed control devices, to, based at least in part on data received from the one or more curvature detection devices and data received from the one or more driver intent detection devices, cause braking to one or more vehicle tires and/or reducing engine torque to keep a vehicle accurately negotiating the curved road for the current driving condition.

Abstract: A system and method are provided to determine the collision status of a nearby vehicle or vehicles. If a nearby vehicle has been in a collision, responsive systems may be triggered automatically. Responses may include warning the driver of the host vehicle and/or warning drivers of other vehicles or centralized networks by, among other methods, V2V or V2I communications. Responses may also include automatically triggering countermeasures in the host vehicle.

Abstract: A system and method are provided to determine the side-impact collision status of a nearby vehicle or vehicles. If a nearby vehicle has been in a collision, responsive systems may be triggered automatically. Responses may include warning the driver of the host vehicle and/or warning drivers of other vehicles or centralized networks by, among other methods, V2V or V2I communications. Responses may also include automatically triggering countermeasures in the host vehicle.

Abstract: A vehicle control system includes one or more driver intent detection devices to detect at least a curve-negotiating intention of a driver. The system also includes one or more curvature detection devices, to detect or otherwise determine a road curvature. The system further includes one or more overspeed control devices, to, based at least in part on data received from the one or more curvature detection devices and data received from the one or more driver intent detection devices, cause braking to one or more vehicle tires and/or reducing engine torque to keep a vehicle accurately negotiating the curved road for the current driving condition.