A system and method are provided for efficiently estimating vehicle tire wear. Vehicle kinetics (first) data are provided via one or more sensors associated with the vehicle and/or at least one associated tire. The vehicle kinetics data are locally processed to compress or otherwise generate second data as a reduced subset thereof, said second data representative of the first data and comprising any one or more predetermined wear-specific features extracted therefrom. The second data are selectively transmitted via a communications network to a remote computing system, which processes the second data to estimate a wear characteristic for the at least one tire. Alternatively, the second data processed to generate third data as a reconstruction of the first data, and the third data and the any one or more extracted features are processed to estimate a wear characteristic for the at least one tire.

Received acceleration or motion information are analyzed and when the analysis of this information indicates that motion or acceleration is detected, received burst patterns from the other sensors are analyzed. Based upon analyzing the detected burst patterns from the other sensors, a first burst pattern is selectively altered to transmit according to a single communication format, the single format being for a single vehicle manufacturer.

A wear amount estimation method calculates a shearing force of each rib based on an average grounding pressure of each rib of an aircraft tire; calculates a wear energy of the aircraft tire based on the shearing force; and estimates the wear amount of the aircraft tire based on the wear energy and a wear resistance showing a relationship between a predetermined wear amount. The information related to the aircraft includes an internal pressure of the aircraft tire. The average grounding pressure of each rib is calculated based on the internal pressure and a wheel load applied to the aircraft tire.

An electrical connection system for connecting two electrical devices, including at least one elastic contact integral with a first electrical device and in elastic abutment against a second electrical device so as to form an electrical connection. The at least one elastic contact being able to deform in a deformation plane. At least one wall placed so that the elastic contact is placed between the wall and the second electrical device in the deformation plane. The at least one elastic contact, the at least one wall, and the second electrical device being coated in a protective material after assembly.

A tool device for use with a motor vehicle tire pressure monitoring system (TPMS) operable to send and receive signals to a TPMS tire pressure sensor and a radio frequency identification (RFID) tag positioned in a vehicle tire. In one example, the tool is operable to communicate with the RFID tag to receive information from the RFID tag through an ultra-high frequency communication module and send that received RFID tag information to the tire pressure sensor for storage on the tire pressure sensor. The tool may then retrieve the tire pressure sensor information and associated RFID tag information from the sensor and transmit that information to the motor vehicle on-board computer.

A tire pressure monitoring system interface comprising: a receiver configured to receive tire pressure signals from each of a plurality of tire pressure sensors of a corresponding plurality of vehicle wheels; an alerting device; an electronic input/output device configured to display at least one menu with data selections of tire pressure related data and receive manually inputted instructions; and an electronic controller having electronic memory and being electronically connected to the receiver, the alerting device and the electronic input/output device, the electronic controller being configured to: operate the electronic memory to access data that defines a first tire pressure and a second tire pressure for each of the plurality of wheels, the first tire pressure being for on-road driving conditions and the second tire pressure being for off-road driving conditions, display the at least one menu via the electronic input/output device, receive at least one of data input, data selection and operation instructions, the instructions including requesting off-road driving conditions; monitor tire pressure in each of the plurality of vehicle wheels; determining wheel by wheel whether or not the change in tire pressure in each of the plurality of wheels has been manually achieved by a person manually changing the tire pressure outside of the vehicle; and operating the alerting device to alert the person manually changing the tire pressure that the change in tire pressure has been achieved for each wheel, wheel by wheel.

A tire pressure monitoring device includes a display, a receiver, a memory, and a processor. The receiver is configured to receive a first signal from a first sensor and a second signal from a second sensor. The memory stores a first and second communication protocols corresponding to the first and second sensors, respectively. The processor is in communication with the display, the receiver, and the memory and is configured to perform operations. The operations include selecting the first and second communication protocols based on the first and second signals, respectively, converting the first and second signals into first and second sets, respectively, of at least one of temperature data or pressure data corresponding to a first tire, and transmitting the first set and the second set of at least one of temperature data or pressure data to the display.

A method of synchronising a plurality of aircraft tire monitoring devices, wherein the method includes providing a synchronisation signal, and synchronising the plurality of aircraft tire monitoring devices such that each of the plurality of aircraft tire monitoring devices is available to connect to a remote device in a same time interval.

An aircraft tire monitoring device including a wireless communication interface and configured to operate in a first mode in which the wireless communication interface is periodically activated and available for connection to a remote device with a first interval between activations, and a second mode in which the wireless communication interface is periodically activated and available for connection to the remote device with a second interval between activations. The second interval between activations is different to the first interval between activations.

A method of performing a configuration procedure for first and second tire pressure monitoring devices. The method includes loading the first tire pressure monitoring device with first configuration data, and subsequently transmitting, from the first tire pressure monitoring device, a first configuration data signal which encodes the first configuration data. The method includes subsequently loading the second tire pressure monitoring device with second configuration data, and subsequently ending the configuration procedure without transmitting a second configuration data signal which encodes the second configuration data.