The invention relates to a method of utilizing a system for monitoring the temperature and/or the pressure of the tires of a vehicle (C) comprising one or more rolling sub-assemblies (100, 200), noteworthy in that it consists in installing on each rolling sub-assembly (100, 200), an additional storage and communication module (300) comprising: a data storage means in which are recorded, during a learning phase, the set of unique identifiers and the locations of each measurement and communication pick-up module (300) of said rolling sub-assembly (100, 200), a means of communication at least with the reception and transmission modules (400) and installed on the rolling sub-assembly, a means of storing energy for the purposes of powering the communication means, so that said storage and communication module (300) can retain in memory the set of identifiers and associated locations of the same sub-assembly (100, 200) and can communicate it instantaneously. The invention also relates to the device allowing the method to be implemented. Applications: utilization of a system for monitoring tires.

A tire wear state estimation system estimates forces and sliding velocity generated in a tire contact patch, determines frictional energy from the tire force and sliding velocity, and generates an estimate of tire wear state based upon the frictional work done by the tire. A tire wear estimate, pursuant to the system and methodology, is made by determining the amount of frictional work performed by the tire through the integrated use of tire-mounted, GPS sourced, and vehicle-mounted sensor information.

An auto-location method for sensors in or on vehicles, in particular TPMS sensors. The method includes: establishing a bidirectional communication between a central unit and at least one sensor; ascertaining trigger data for the auto-location of the at least one sensor on the basis of vehicle state data which are provided to the central unit by at least one other vehicle unit; transmitting the trigger data to the at least one sensor; initiating the auto-location by means of the central unit on the basis of the trigger data, wherein the sensor ascertains sensor data for the auto-location; and ascertaining the position of the at least one sensor on the basis of the ascertained sensor data.

The present disclosure relates to programming tire sensors mounted to a tire of a vehicle. An identification tag device (e.g., radio frequency identification (RFID) tag) stores tire information data and/or other data that is unique to a given tire. The identification tag device can be attached to or otherwise contained within a tire-integrated sensor mount configured to support a sensor. The identification tag device transmits tire identification data and/or other data stored by the identification tag device to a sensor when the sensor is attached to or otherwise supported by the tire-integrated sensor mount. The sensor can obtain the tire identification data associated with the tire on which the sensor is mounted, thereby allowing the sensor to associate collected sensor data (e.g., pressure, temperature, etc.) with the tire identification data that is unique to the tire.

A road classification system for determining a road surface condition includes a model having as an input changes in the measured axle vertical acceleration of the vehicle. The model further uses a sensor-measured tire inflation pressure and a tire construction type ascertained from a tire-based identification tag.

A wheel assembly position identifying apparatus includes transmitters, each of which is provided in one of wheel assemblies and includes a transmission section and a control section, and a receiver, which includes a receiving section, a measuring section, and a wheel assembly position identifying section. The wheel assembly position identifying section is configured to detect, more than once, a rotational position of each wheel assembly at which the RSSI has an extreme value, for each position detecting signal received during one rotation of the wheel assembly, and identify the position of the wheel assembly in which the corresponding transmitter is provided based on variation of the rotational position of the wheel assembly at which the RSSI has the extreme value.

A handling machine performs a method for updating a database for managing a fleet of vehicles, during replacement of a tire on a vehicle that includes a plurality of predetermined spatial zones. The database includes a tire identifier for each tire of the vehicle and a zone identifier for each predetermined spatial zone. Each of the tire identifiers is associated with a corresponding one of the zone identifiers in the database. A zone identifier of a spatial zone containing a tire is determined when first predetermined conditions are met, and a tire identifier of the tire is determined when second predetermined conditions are met. An association in the database between a zone identifier and a tire identifier is updated if at least the first and second predetermined conditions are met simultaneously at least once.

A tire pressure detection apparatus includes: a transmitter at each of a plurality of wheels with a tire; and a receiver at a vehicle body. The transmitter has: a sensing device having a pressure sensor outputting a detection signal related to a tire pressure of each of the plurality of wheels and an acceleration sensor detecting an acceleration including a centrifugal acceleration caused by rotation of the wheel and a gravitational acceleration; a first controller performing signal processing on the detection signal of the pressure sensor and creating a frame storing data related to the tire pressure; and a radio wave transmitter transmitting the frame. The receiver has: a radio wave receiver receiving the frame; and a second controller detecting a tire pressure based on the data related to the tire pressure stored in the received frame.

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.

A standalone tire identification tag and standalone sensor module are mounted to a tire and configured to share and store tire identification and tire parameter-measuring sensor data through a common data sharing interface.