Abstract: Techniques are provided for operating a vehicle in a first vehicle mode; operating at least one component of the vehicle in a first component mode; detecting a first change in operation of the vehicle from the first vehicle mode to a second vehicle mode different from the first vehicle mode; based on the detected the first change in the operation of the vehicle, predicting a second change in operation of the vehicle; in response to predicting the second change in operation of the vehicle, operating the at least one component in a second component mode different from the first component mode prior to the predicted second change in operation of the vehicle.

Abstract: A system for adjusting vehicle driver settings includes vehicle nodes configured to receive signals from a key fob or other portable wireless device, and a processing system for evaluating height information of the keyfob or other device. The processing system is configured to receive the height information and evaluate whether the wireless device is likely being carried within an article of clothing of the driver. A vehicle settings controller system accesses a settings database to obtain vehicle settings related to a particular wireless device height and implements initial vehicle settings upon a driver approaching the vehicle.

Abstract: A system includes a first transceiver and a controller circuit. The first transceiver is configured to transmit first radio frequency (RF) signals. The first transceiver is further configured to output the first RF signals at a first transmission level corresponding to a first transmission range. The controller circuit is communicatively coupled with the first transceiver. The controller circuit is configured to attenuate the first RF signals to transfer the first RF signals at a second transmission level lower than the first transmission level. The second transmission level corresponds to a shorter transmission range than the first transmission range. The controller circuit detects a presence of at least one second transceiver within the shorter transmission range using the first RF signals transmitted at the second transmission level.

Abstract: Techniques are provided for operating a vehicle in a first vehicle mode; operating at least one component of the vehicle in a first component mode; detecting a first change in operation of the vehicle from the first vehicle mode to a second vehicle mode different from the first vehicle mode; based on the detected the first change in the operation of the vehicle, predicting a second change in operation of the vehicle; in response to predicting the second change in operation of the vehicle, operating the at least one component in a second component mode different from the first component mode prior to the predicted second change in operation of the vehicle.

Abstract: Techniques are provided for operating a vehicle in a first vehicle mode; operating at least one component of the vehicle in a first component mode; detecting a first change in operation of the vehicle from the first vehicle mode to a second vehicle mode different from the first vehicle mode; based on the detected the first change in the operation of the vehicle, predicting a second change in operation of the vehicle; in response to predicting the second change in operation of the vehicle, operating the at least one component in a second component mode different from the first component mode prior to the predicted second change in operation of the vehicle.

Abstract: A system includes a first transceiver and a controller circuit. The first transceiver is configured to transmit first radio frequency (RF) signals. The first transceiver is further configured to output the first RF signals at a first transmission level corresponding to a first transmission range. The controller circuit is communicatively coupled with the first transceiver. The controller circuit is configured to attenuate the first RF signals to transfer the first RF signals at a second transmission level lower than the first transmission level. The second transmission level corresponds to a shorter transmission range than the first transmission range. The controller circuit detects a presence of at least one second transceiver within the shorter transmission range using the first RF signals transmitted at the second transmission level.

Abstract: A vehicle safety system includes at least one detector positioned to monitor at least a portion of an interior of a vehicle and a processor/communication system configured to receive inputs from the at least one detector and to communicate with brought-in devices located within the vehicle. The processor/communication system determines a location of the brought-in device based on visible/IR signals generated by the brought-in device and detected by the at least one detector, wherein the processor/communication system communicates restrictions/permissions to the brought-in device based on the determined location.

Abstract: A system includes a first transceiver and a controller circuit. The first transceiver is configured to transmit first radio frequency (RF) signals. The first transceiver is further configured to output the first RF signals at a first transmission level corresponding to a first transmission range. The controller circuit is communicatively coupled with the first transceiver. The controller circuit is configured to attenuate the first RF signals to transfer the first RF signals at a second transmission level lower than the first transmission level. The second transmission level corresponds to a shorter transmission range than the first transmission range. The controller circuit detects a presence of at least one second transceiver within the shorter transmission range using the first RF signals transmitted at the second transmission level.

Abstract: A vehicle safety system includes at least one detector positioned to monitor at least a portion of an interior of a vehicle and a processor/communication system configured to receive inputs from the at least one detector and to communicate with brought-in devices located within the vehicle. The processor/communication system determines a location of the brought-in device based on visible/IR signals generated by the brought-in device and detected by the at least one detector, wherein the processor/communication system communicates restrictions/permissions to the brought-in device based on the determined location.

Abstract: A system for adjusting vehicle driver settings includes vehicle nodes configured to receive signals from a key fob or other portable wireless device, and a processing system for evaluating height information of the keyfob or other device. The processing system is configured to receive the height information and evaluate whether the wireless device is likely being carried within an article of clothing of the driver. A vehicle settings controller system accesses a settings database to obtain vehicle settings related to a particular wireless device height and implements initial vehicle settings upon a driver approaching the vehicle.

Abstract: Techniques are provided for operating a vehicle in a first vehicle mode; operating at least one component of the vehicle in a first component mode; detecting a first change in operation of the vehicle from the first vehicle mode to a second vehicle mode different from the first vehicle mode; based on the detected the first change in the operation of the vehicle, predicting a second change in operation of the vehicle; in response to predicting the second change in operation of the vehicle, operating the at least one component in a second component mode different from the first component mode prior to the predicted second change in operation of the vehicle.

Abstract: An illustrative example vehicle to everything (V2X) system includes at least one V2X antenna and a V2X transceiver coupled with the V2X antenna. The V2X transceiver is configured to communicate using a first frequency band. A receiver is configured to receive communications on at least a second frequency band that is different than the first frequency band. A controller is configured to selectively cause the receiver to be configured to receive communications on the first frequency band and determine a condition of at least one of the V2X transceiver and the V2X antenna based on an indication from the receiver regarding any communication received by the receiver on the first frequency band from the V2X transceiver and the V2X antenna.

Abstract: An illustrative example vehicle to everything (V2X) system includes at least one V2X antenna and a V2X transceiver coupled with the V2X antenna. The V2X transceiver is configured to communicate using a first frequency band. A receiver is configured to receive communications on at least a second frequency band that is different than the first frequency band. A controller is configured to selectively cause the receiver to be configured to receive communications on the first frequency band and determine a condition of at least one of the V2X transceiver and the V2X antenna based on an indication from the receiver regarding any communication received by the receiver on the first frequency band from the V2X transceiver and the V2X antenna.

Abstract: A system includes a first transceiver and a controller circuit. The first transceiver is configured to transmit first radio frequency (RF) signals. The first transceiver is further configured to output the first RF signals at a first transmission level corresponding to a first transmission range. The controller circuit is communicatively coupled with the first transceiver. The controller circuit is configured to attenuate the first RF signals to transfer the first RF signals at a second transmission level lower than the first transmission level. The second transmission level corresponds to a shorter transmission range than the first transmission range. The controller circuit detects a presence of at least one second transceiver within the shorter transmission range using the first RF signals transmitted at the second transmission level.

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 transceiver system and method determining a voltage standing wave ratio (VSWR) is provided. The system includes at least one amplifier, a filter bank, a plurality of detectors, and at least one processor. The at least one amplifier receives an input signal. The filter bank is in electrical communication with the at least one amplifier. The plurality of detectors are in electrical communication with the filter bank, where a first detector of the plurality of detectors is in electrical communication with a first portion of the filter bank, and a second detector of the plurality of detectors is in electrical communication with a second portion of the filter bank. The at least one processor is in electrical communication with the plurality of detectors, and estimates a VSWR based upon voltages detected by the first and second detectors.

Abstract: A mobile receiver, located within a vehicle, exhibits improved signal processing in the presence of multi-path distortion. Initially, the speed of the vehicle is determined. Next, signal information on a selected signal received by the mobile receiver is collected. The collected signal information provides an indication of the quality of the received signal. Then, at least one time constant associated with the processing of the collected signal information is modified responsive to the determined speed.