A monitoring device receives air pressure signals transmitted from a plurality of detection devices that are respectively provided in tires of a vehicle and wirelessly transmit air pressure signals each including a respective identifier and air pressure information for a respective tire. A storage unit of the monitoring device stores tire positions at which the tires are provided and identifiers of detection devices in correspondence with each other. The monitoring device includes a request signal transmission unit that transmits, a plurality of times, a request signal requesting an identifier to at least one tire position, and an identifier reception unit that receives identifiers that are transmitted from a detection device. The monitoring device specifies the identifier of the detection device provided at the one tire position based on the identifiers that were transmitted in accordance with the request signal, and updates the identifier stored by the storage unit.

A tire condition detecting apparatus includes a transmitting section, a receiving section, a control section, a property detecting section, and a battery, which is a power source for the apparatus. The control section operates in a control mode that is selected from a normal mode and a power saving mode. In the power saving mode, power consumption associated with reception of the wirelessly transmitted signal from the external device is less than that in the normal mode. When the amount of change in the electrical property of a valve stem detected by the property detecting section exceeds a reference change amount, the control section switches the control mode to the normal mode. The control section also switches the control mode to the power saving mode when a termination condition is met in the normal mode

A tire valve registration system including: a plurality of tire valves that are respectively installed on a plurality of tires and on a spare tire and that each transmit a radio signal that includes a valve ID and data on tire air pressure; and a receiver that is provided to a vehicle body and that is capable of receiving the radio signal from each of the plurality of tire valves. The system includes: a spare tire ID collecting unit that collects, as at least one spare tire candidate ID, the valve ID of at least one radio signal received by the receiver; and a spare tire ID confirming unit that confirms the ID of the spare tire.

A tire position learning apparatus for a tire pressure monitoring system, comprising: a plurality of tire module units, each of which is respectively mounted on a tire of the vehicle to detect pressure information and transmit same via an ultra-wide band (UWB) signal; and a vehicle module unit which communicates with the plurality of tire module units via UWB signals so as to detect the individual tire pressures and any tire in which low pressure has occurred.

The present disclosure provides a vehicle control system. The vehicle control system includes a transceiver operating in a sub-GHz frequency band configured to transmit and receive data from a RKE user terminal of the vehicle, a set of TPMS sensors and at least one remote control terminal located outside the vehicle; and an ECU connected to the transceiver and configured to: perform lock or unlock and engine start functions in responding to data from the RKE user terminal, receive tire pressure data from the TPMS sensors and control the remote control terminal in responding to a user action.

A wireless tire pressure monitoring system (TPMS) emulation device for a vehicle and a method of activating the device. The device has a memory, a microcontroller, a radio frequency transmitter, a trigger, an actuator and a power supply. The memory is adapted to have stored thereon a software module. The microcontroller is powered by a power supply, such as a battery, and is connected to the memory. The microcontroller is adapted to control a TPMS transmission signal indicative of an acceptable tire pressure signal, according to the software module. The radio frequency transmitter is connected to the microcontroller and is adapted to transmit the transmission signal. The trigger is connected to the microcontroller and is adapted to activate a TPMS sensor pairing of the emulation device for at least one tire of the vehicle. The actuator is connected to the microcontroller and is adapted to activate the emulation device.

A system for locating a vehicle utilizing a zone posts in known locations that when the vehicle comes within a proximity of the zone post receives an identification signal from the vehicle and sends that identification signal on to a central command center. The identification signal may be provided by a dongle or a tire pressure monitoring system tire pressure sensor. The central command center may be queried with vehicle identifying information, and the location of the zone post that last sent the identification signal is provided as an indication of the location of the vehicle.

A method of operating a Tire Pressure Monitoring System (TPMS) includes executing tire pressure monitoring of at least one tire installed on a vehicle in a first mode, and transmitting frequency signal loss information to a center if a loss of a frequency signal in the first mode occurs in a designated time period.

A system includes sensor modules, each associated with a wheel on a vehicle, and a receiver unit. Each sensor module calculates a rotation period associated with the wheel during turn mode vehicular motion and determines rotation direction of the associated wheel during straight vehicular motion. A data packet that includes a unique identifier for the sensor module, the rotation period, and the rotation direction are transmitted from each sensor module for receipt at the receiver unit. The receiver unit determines the steered wheels and non-steered wheels based on the rotation period, and the receiver unit can determine which wheels are on the right side or the left side of the vehicle based on the rotation direction. Knowledge of the steered and non-steered wheels and the rotation direction of the wheels, enables the receiver unit to assign locations of the sensor modules, and hence positions of the wheels of the vehicle.

A tire position determination system includes a position determination unit that determines a tire position by obtaining axle rotation information when each of tire pressure transmitters reaches a specific position on a tire rotation path of a corresponding tire and specifying a tire that rotates in synchronism with the axle rotation information of each axle. A cycle calculator calculates a rotation cycle of each axle based on the axle rotation information. A validity determination unit determines validity of accuracy of gravity sampling based on the rotation cycle, a gravity sampling interval time of a gravitational component acting on each tire pressure transmitter, and a gravity sampling frequency in the rotation cycle. The position determination unit determines the tire position based on a determination result of the validity determination unit.