A radiofrequency transponder comprises a radiating antenna consisting of a single-strand helical spring having an axis, a median plane, a pitch and a diameter for a given wire diameter, and an electronic portion located inside the radiating antenna. The electronic portion comprises an electronic chip electrically connected to a primary antenna that is electromagnetically coupled to the radiating antenna. The primary antenna has an axis parallel to the axis of the radiating antenna and a median plane superposed with the median plane of the radiating antenna. The primary antenna is circumscribed by a cylinder the diameter of which is larger than one third of the inside diameter of the radiating antenna. The radiofrequency transponder is characterized in that, in a first region of the radiating antenna, in which the latter is not located plumb with the electronic portion, the inside diameter of the radiating antenna is smaller than the inside diameter of the radiating antenna that does not form part of this first region.

A heavy goods vehicle tire has a radial carcass reinforcement, made up of a single layer of metal reinforcing elements anchored in each of the beads by a turn-up around a bead wire. The turn-up of the carcass reinforcement layer and the main part of the carcass reinforcement layer are coupled, and a radiofrequency communication module is placed in the coupling region at the interface between the turn-up of the carcass reinforcement layer and axially outwardly adjacent layer of rubber compound.

A reader system for a tire with an integrated radio frequency identification (RFID) and tire pressure monitoring system (TPMS) sensor, in which the integrated RFID and TPMS sensor is mounted on the tire, is provided. The reader system includes at least one antenna that is external to the tire. The at least one antenna is mounted on a vehicle on which the tire is mounted in a location proximate the tire. The at least one antenna is in electronic communication with the integrated RFID and TPMS sensor. A reader is mounted on the vehicle and is also in electronic communication with the at least one antenna. The at least one antenna relays a signal from the integrated RFID and TPMS sensor to the reader. A display device is in electronic communication with the reader to receive and display data from the integrated RFID and TPMS sensor.

A tire is equipped with a radiofrequency communication module with a carcass reinforcement comprising two carcass plies such that the communication module is positioned in the bead axially on the outside of and against the second carcass ply.

Tire mounted sensors have controlled orientation with respect to a direction of vehicle travel when fitted to a tire of the vehicle. The tire mounted sensor includes a sensor housing containing a pressure and/or other type of sensor and electronic components which is inserted into a sensor mount attached to the tire. Controlling the orientation of the orientation-sensitive components relative to the direction of travel of the vehicle is achieved by indicating the direction of travel of the vehicle on the sensor mount. Controlling the orientation of the sensor housing within the sensor mount, preferably in all six axes of freedom, is achieved by an orientation key or asymmetrical feature on the sensor mount that corresponds to a mating feature on the sensor housing.

An encapsulated sensor unit is embedded in a tire. The encapsulated sensor unit includes a sensor portion and an antenna portion. A first encapsulating layer is disposed about the sensor portion, and not about the antenna portion. A second encapsulating layer is disposed about the first encapsulating layer and the antenna portion. A third encapsulating layer is disposed about the second encapsulating layer.

A method of localizing a TPMS sensor module includes transmitting, by the TPMS sensor module, a TPMS signal; and localizing, by a localization module, the TPMS sensor module based on receiving the TPMS signal at a phase array antenna including a plurality of reception antennas each configured to receive the TPMS signal at a different phase, where the plurality of reception antennas include a reference reception antenna and at least one additional reception antenna. Localizing the TPMS sensor module includes measuring a reference phase of the TPMS signal received at the reference reception antenna, measuring a respective shifted phase of the TPMS signal received at each of the at least one additional reception antenna, determining a respective phase shift between the reference phase and each respective shifted phase, and determining a location of the TPMS sensor module based on each determined respective phase shift corresponding to the TPMS signal.

A tire monitoring system electronic unit suitable for being mounted either on the tire inflation valve or on the internal surface of the tire. The system includes electronics for managing the electronic unit including sensors for measuring parameters of the tire, a microprocessor and a supply battery, and an antenna configured to be mountable on the management electronics; a way of securing the antenna and the electronic managing device to each other; the management electronics thus forming a common base capable of being used with an antenna that can be adapted to the intended location of the electronic unit, either on the tire inflation valve or on the internal surface of the tire.

An apparatus for tire pressure monitoring comprises a case, a gas nozzle unit movably connected to the outside of the case, and a structure for tire pressure monitoring which is received in a receiving space in the case. The structure for tire pressure monitoring comprises a main body, a signal processing unit, a sensing unit connected to the signal processing unit, and a power unit to provide power. The main body has a first part and a second part. The first part is disposed on a top side of the second part; the first and the second parts are not on the same plane. The signal processing unit and the sensing unit are disposed on one side of the first part and on the top side of the second part, respectively. The power unit is disposed on a bottom side of the second part.

The present invention provides a tire pressure sensor, including a housing, a PCBA installed within the housing, a power supply device installed within the housing and electrically connected to the PCBA, and an antenna connected to the PCBA. The antenna is wrapped around the PCBA, and at least one turn of the antenna is wrapped around the PCBA. The antenna is wrapped around the PCBA, and a length of the antenna may be increased within a limited internal space of the tire pressure sensor. An effective space of the antenna may be particularly enlarged by wrapping the antenna around the PCBA, thereby improving efficiency of the antenna, increasing a signal transmitting distance of the antenna, and enhancing signal transmission stability and anti-interference capability of the antenna, so that an automobile receiver can stably receive, in real time, information such as internal pressure and a temperature of the tire detected by the PCBA, better implementing real-time monitoring of the air pressure, the temperature, and the like within the tire.