The invention relates to a method for self-tracking of a data acquisition sensor equipping a wheel including a tire on a vehicle comprising a plurality of wheels (200) and being equipped with a system comprising an electronic unit (300) for a data acquisition sensor placed in each tire equipped with a radio-frequency transmitter for the purpose of the wireless transmission of said data to a central transmission and reception module (100) placed on the axle or frame of the vehicle, with the central transmission and reception module (100) receiving and decoding the information signals issued by the transmitters of each wheel, each electronic unit (300) being equipped to measure acceleration. The method is remarkable in that it consists of determining the front and rear of a tire by measuring the acceleration.

Embodiments provide a pressure sensitive foil, a tire pressure sensor module, a tire, a method and a computer program for determining information related to deformations of a tire. A pressure sensitive foil configured to determine information related to deformations of a tire. The pressure sensitive foil comprises an interface configured to provide the information related to the deformations of the tire to a control device. A tire pressure sensor module is configured to provide information related to deformations of a tire to a control device. The tire pressure sensor module comprises an interface configured to determine the information related to the deformations of the tire from a pressure sensitive foil.

Embodiments provide a fail-safe device, a tire pressure measurement system, a vehicle, a tire, a method and a computer program for monitoring a first sensor of a tire pressure monitoring system. The fail-safe device includes a first input for a first signal from the first sensor. The first signal indicates a first physical quantity. The fail-safe device includes a second input for a second signal from a second sensor. The second signal indicates a second physical quantity. The fail-safe device further includes a control module to verify the first signal based on the second signal and a physical relation between the first and the second physical quantities.

Disclosed is a method of locating a plurality of electronic measuring modules mounted in the wheels of a motor vehicle. The method includes the steps of determination (E1) by each electronic measuring module of a set of proximity scores with respect to the other modules, sending (E2) by each module of the set of proximity scores to the electronic control unit, reception (E3) by an electronic control unit of the sets of proximity scores sent, and location (E4) of each module from the sets of proximity scores received.

The invention relates to a wheel monitoring device (D) of the type comprising a housing (100) formed from a hollow core (101) containing different components including an electronic board (500) and a power supply battery (600) for said board (500), said housing (100) being positioned inside the tire and fixed to the internal portion (220) of the valve (200) fitted on the wheel, a polymer material fills in the free volume.

The device is remarkable in that the housing (100) is preformed so as to provide at least two different superposed parallel installation planes (P1, P2) on which the different components are distributed, said housing (100) being preformed with a lateral opening to enable the different components to slide laterally into their appropriate installation plane (P1, P2).

Provided is a tire manufacturing feature in which even when an electronic component is embedded in a tire, damage due to impact load during traveling on the road surface is inhibited and the durability of the tire is prevented from deteriorating. A pneumatic tire provided with: a bead reinforcing layer provided in the tire-axial-direction outer side of the carcass of a bead part the bead reinforcing layer reinforcing the bead part from the outer side of the carcass; a clinch member provided on the tire-axial-direction outer side of the bead reinforcing layer; and an electronic device. The clinch member has a rigidity lower than that of the bead reinforcing layer, and the electronic component is embedded between the bead reinforcing layer and the clinch member.

The dynamic footprint of a tire is received and the dynamic footprint is determined by and received from a tire pressure monitoring (TPM) sensor. A weight or load of the secondary vehicle attached to the primary vehicle is calculated based at least in part on the footprint. Instructions to alter the operation of the braking system of the secondary vehicle based on the calculated weight or load are transmitted to the secondary vehicle.

A device for measuring and/or monitoring tire-related variables of a vehicle, having a sensor unit for transmitting, receiving and processing signals, wherein a transmission signal is emitted by an antenna unit of the sensor unit in the direction of an object being measured and wherein a reflection signal reflected by the object being measured is received and analyzed, the sensor unit having a transceiver device, via which a reflection factor, formed as the quotient from the reflection signal reflected by the object being measured and the transmission signal, is measured and via which a resonance frequency and/or a phase difference between the transmission signal and the reflection signal is determined, wherein the transceiver unit comprises a vector network analyzer and an analysis unit, so that a distance to the object being measured is established by detecting the phase difference between the transmission signal and the reflection signal.

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.

The present invention relates to a wireless tire monitoring device for a vehicle. Accordingly, the wireless tire monitoring device (100) includes: a) a tire pressure/temperature signal transmitting device (110); b) at least one sensor unit (130) for measuring or detecting at least one parameter relating to the conditions of the tire (200); c) an antenna (150) for transmitting signal corresponding to the tire conditions; wherein the wireless tire monitoring device (100) is detachably mounted to a valve stem (210) of the tire (200) and being served as a cap for the valve stem (210); wherein the antenna (150) includes at least one curvature strip (151) configured at same axis (Z-Z) with the valve stem (210) so that it center axis aligns with the valve stem (210) of the tire (200); and wherein the antenna (150) and valve stem (210) share a common axis (X-X) of a tire wheel (230) and adapted to be revolved about the common axis (X-X) of the tire wheel (230).