Abstract: A gesture recognition system for hands-free access to a vehicle includes a set of vehicle ultra-wideband (UWB) transceivers comprising at least three UWB transceivers and a controller configured to detect a presence of a vehicle-authorized mobile device in possession of an authorized user, determine a set of defined zones proximate to the vehicle and associated with hands-free vehicle access, communicate between the set of vehicle UWB transceivers and a device UWB transceiver of the mobile device to monitor a location of the mobile device, monitor a movement routine of the mobile device relative to the set of defined zones over a period, and in response to determining a match with one of a set of predefined movement routines associated with hands-free vehicle access, command one of a set of access actuators of the vehicle to grant hands-free vehicle access corresponding to the matched predefined movement routine.

Abstract: Computer-implemented methods include detecting a device ultra-wideband (UWB) transceiver of a mobile device and a set of vehicle UWB transceivers of a vehicle, determining a defined driver zone within the vehicle, the defined driver zone indicating a set of relative positions within the vehicle, communicating between the device UWB transceiver and the set of vehicle UWB transceivers to determine a position of the mobile device within the vehicle, and automatically enabling a driver mode of the mobile device whereby operation of the mobile device is limited when the determined position of the mobile device is within the defined driver zone and the vehicle is moving.

Abstract: A gesture recognition system for hands-free access to a vehicle includes a set of vehicle ultra-wideband (UWB) transceivers comprising at least three UWB transceivers and a controller configured to detect a presence of a vehicle-authorized mobile device in possession of an authorized user, determine a set of defined zones proximate to the vehicle and associated with hands-free vehicle access, communicate between the set of vehicle UWB transceivers and a device UWB transceiver of the mobile device to monitor a location of the mobile device, monitor a movement routine of the mobile device relative to the set of defined zones over a period, and in response to determining a match with one of a set of predefined movement routines associated with hands-free vehicle access, command one of a set of access actuators of the vehicle to grant hands-free vehicle access corresponding to the matched predefined movement routine.

Abstract: A gesture recognition system for hands-free access to a vehicle includes a set of vehicle ultra-wideband (UWB) transceivers comprising at least three UWB transceivers and a controller configured to detect a presence of a vehicle-authorized mobile device in possession of an authorized user, determine a set of defined zones proximate to the vehicle and associated with hands-free vehicle access, communicate between the set of vehicle UWB transceivers and a device UWB transceiver of the mobile device to monitor a location of the mobile device, monitor a movement routine of the mobile device relative to the set of defined zones over a period, and in response to determining a match with one of a set of predefined movement routines associated with hands-free vehicle access, command one of a set of access actuators of the vehicle to grant hands-free vehicle access corresponding to the matched predefined movement routine.

Abstract: A detection device includes at least one detection module communicatively coupled with a communication device. The detection module includes a controller circuit communicatively coupled with a first antenna. The first antenna receives first electromagnetic signals from a first plurality of antennae located within an interior of a first vehicle. The first antenna receives second electromagnetic signals from a second plurality of antennae located and within an interior of a second vehicle. The controller circuit determines a position of the communication device within the interior of the first vehicle relative to locations of the first plurality of antennae based on the first electromagnetic signals received by the first antenna. The controller circuit determines a position of the communication device within the interior of the second vehicle relative to locations of the second plurality of antennae based on the second electromagnetic signals received by the first antenna.

Abstract: A detection device includes at least one detection module communicatively coupled with a communication device. The detection module includes a controller circuit communicatively coupled with a first antenna. The first antenna receives first electromagnetic signals from a first plurality of antennae located within an interior of a first vehicle. The first antenna receives second electromagnetic signals from a second plurality of antennae located and within an interior of a second vehicle. The controller circuit determines a position of the communication device within the interior of the first vehicle relative to locations of the first plurality of antennae based on the first electromagnetic signals received by the first antenna. The controller circuit determines a position of the communication device within the interior of the second vehicle relative to locations of the second plurality of antennae based on the second electromagnetic signals received by the first antenna.

Abstract: A detection device includes at least one detection module communicatively coupled with a communication device. The detection module includes a controller circuit communicatively coupled with a first antenna. The first antenna receives first electromagnetic signals from a first plurality of antennae located within an interior of a first vehicle. The first antenna receives second electromagnetic signals from a second plurality of antennae located and within an interior of a second vehicle. The controller circuit determines a position of the communication device within the interior of the first vehicle relative to locations of the first plurality of antennae based on the first electromagnetic signals received by the first antenna. The controller circuit determines a position of the communication device within the interior of the second vehicle relative to locations of the second plurality of antennae based on the second electromagnetic signals received by the first antenna.

Abstract: A gesture recognition system for hands-free access to a vehicle includes a set of vehicle ultra-wideband (UWB) transceivers comprising at least three UWB transceivers and a controller configured to detect a presence of a vehicle-authorized mobile device in possession of an authorized user, determine a set of defined zones proximate to the vehicle and associated with hands-free vehicle access, communicate between the set of vehicle UWB transceivers and a device UWB transceiver of the mobile device to monitor a location of the mobile device, monitor a movement routine of the mobile device relative to the set of defined zones over a period, and in response to determining a match with one of a set of predefined movement routines associated with hands-free vehicle access, command one of a set of access actuators of the vehicle to grant hands-free vehicle access corresponding to the matched predefined movement routine.

Abstract: Computer-implemented methods include detecting a device ultra-wideband (UWB) transceiver of a mobile device and a set of vehicle UWB transceivers of a vehicle, determining a defined driver zone within the vehicle, the defined driver zone indicating a set of relative positions within the vehicle, communicating between the device UWB transceiver and the set of vehicle UWB transceivers to determine a position of the mobile device within the vehicle, and automatically enabling a driver mode of the mobile device whereby operation of the mobile device is limited when the determined position of the mobile device is within the defined driver zone and the vehicle is moving.

Abstract: A detection device includes at least one detection module communicatively coupled with a communication device. The detection module includes a controller circuit communicatively coupled with a first antenna. The first antenna receives first electromagnetic signals from a first plurality of antennae located within an interior of a first vehicle. The first antenna receives second electromagnetic signals from a second plurality of antennae located and within an interior of a second vehicle. The controller circuit determines a position of the communication device within the interior of the first vehicle relative to locations of the first plurality of antennae based on the first electromagnetic signals received by the first antenna. The controller circuit determines a position of the communication device within the interior of the second vehicle relative to locations of the second plurality of antennae based on the second electromagnetic signals received by the first antenna.

Abstract: A positioning system includes a plurality of antennae, a detection module, a communication device, and controller circuit. The plurality of antennae are located within an interior of a vehicle. The plurality of antennae are configured to broadcast electromagnetic signals from a transmitter. The detection module is communicatively coupled with the communication device. The detection module is configured to receive the electromagnetic signals from the plurality of antennae. The controller circuit is communicatively coupled with the detection module and the communication device. The controller circuit is configured to determine a position of the communication device within the interior of the vehicle relative to locations of the plurality of antennae based on the electromagnetic signals. The controller circuit is further configured to restrict a function of the communication device based on the position.

Abstract: A system includes a host-transceiver, a radar-sensor, and a controller. The host-transceiver is installed in a host-vehicle and detects a signal from a mobile-transceiver. The radar-sensor detecting movement of one or more body parts of a person proximate to the host-vehicle. The controller is in communication with the host-transceiver and the radar-sensor. The controller activates the radar-sensor in accordance with a determination that the mobile-transceiver is within a distance-threshold of the host-vehicle. The controller provides access to the host-vehicle in accordance with a determination that the movement of the one or more body parts corresponds to one or more predetermined gestures.

Abstract: A system for positioning a vehicle over a wireless charging station. The system includes a plurality of ultra wideband transceivers (UWBX) installed on the vehicle and the wireless charging station, and a controller configured to determine various distances between the various UWBXs.

Abstract: A sensor system and seat assembly includes a sensor assembly configured to detect a seating force exerted on a portion of a seat cushion of a seat. The sensor assembly includes a base, a force transducer configured to output a signal indicative of the seating force, and a lever pivotably coupled to the base. The lever defines a sensing end configured to be disposed proximate to the portion of the seat cushion such that the seating force operates on the sensing end. The lever also defines an actuating end configured to apply an actuation force to the force transducer. The sensor assembly may comprise a plurality of levers. Each sensing end of each lever may be disposed in a separate location within the portion of the seat cushion. The sensor assembly may be configured to detect a child exerting a seating force on a portion of the seat cushion.

Abstract: A passive entry passive start (PEPS) vehicle security system configured to activate a vehicle function when an activation signal is received. The system includes a nomadic device configured to detect a change of a magnetic field relative to the nomadic device, and emit an activation signal only if the change corresponds to walking by an operator carrying the nomadic device.

Abstract: A system for positioning a vehicle over a wireless charging station. The system includes a plurality of ultra wideband transceivers (UWBX) installed on the vehicle and the wireless charging station, and a controller configured to determine various distances between the various UWBXs.

Abstract: A passive entry passive start (PEPS) vehicle security system configured to thwart a relay attack on the system. The system includes one or more ultra wideband transceivers (UWBX) installed on a vehicle and configured to transmit a request pulse at a request time. A mobile UWBX, possibly installed in a nomadic device such as a smart phone, is configured to transmit a reply pulse in response to the request pulse. A controller is configured to determine a distance between each UWBX and the mobile UWBX based on a time interval between the request time and a time that corresponds to when the reply pulse is received by the each UWBX. The controller may also be configured to unlock doors of the vehicle only if the distance is less than an unlock threshold.

Abstract: A method of operating a tire pressure monitor system on a vehicle to determine a wheel location of wheels equipped with pressure sensors. The method includes equipping a plurality of wheels with a pressure sensor, determining a plurality of pressure values from each pressure sensor, detecting a variation of the pressure values from a plurality of pressure sensors, and determining a wheel location based on a comparison of the variations of the pressure values. Variations useful for determining wheel location may include running over an object such as a rumble strip or pot-hole on the roadway, or the vehicle executing a turn.

Abstract: A passive entry passive start (PEPS) vehicle security system configured to thwart a relay attack on the system. The system includes one or more ultra wideband transceivers (UWBX) installed on a vehicle and configured to transmit a request pulse at a request time. A mobile UWBX, possibly installed in a nomadic device such as a smart phone, is configured to transmit a reply pulse in response to the request pulse. A controller is configured to determine a distance between each UWBX and the mobile UWBX based on a time interval between the request time and a time that corresponds to when the reply pulse is received by the each UWBX. The controller may also be configured to unlock doors of the vehicle only if the distance is less than an unlock threshold.

Abstract: A passive entry passive start (PEPS) vehicle security system configured to activate a vehicle function when an activation signal is received. The system includes a nomadic device configured to detect a change of a magnetic field relative to the nomadic device, and emit an activation signal only if the change corresponds to walking by an operator carrying the nomadic device.