A number of frames in a burst is adjusted such that a first optimal number of first frames from a first manufacturer are included in the burst, the first optimal number of frames chosen to enable the detection of the burst by first receivers that are tuned to receive the first frames from the first manufacturer. The number of frames in the burst is adjusted such that a second optimal number of second frames from a second manufacturer are included in the burst, the second optimal number of frames chosen to enable detection of the burst by second receivers that are tuned to receive the second frames from the second manufacturer. The number of frames in the burst maintains a configuration compliant with government regulations regarding one or more of a burst length and a power emission.

A tire condition telemetrics system. The system includes a vehicle having an onboard computer and one or more wheel assemblies with one or more tires with a tire tread. A prediction as to when said tire tread will fall below a minimum tread depth in performed. The prediction is based on an amount of distance said wheel assemblies experience said wheel slip condition, a distance said wheel assemblies drive over said one or more road materials, a distance said wheel assemblies drive in rain and snow, a distance one or more loads are on said vehicle, an amount of braking force applied by one or more braking systems to said wheel assemblies and a speed of said vehicle when said braking force is applied.

The present invention relates generally to a tire pressure and temperature measuring system. More specifically, the system is comprised of an ergonomic and durable tire pressure and temperature gauge that does not require any external buttons, displays, or indicia, and that is capable of measuring the internal pressure and air temperature of a tire. The system is further comprised of an accompanying mobile application or computer-based software program that allows the collected pressure and/or temperature data to be wirelessly transmitted and formatted into a report that is accessible via a user interface on a remote device. The system is also capable of making recommendations to the user based on the collected pressure and/or temperature data.

A tire theft alarming system includes a vehicular device mounted to a vehicle and a mobile device carried by a user of the vehicle. When a main power supply of the vehicle is in an OFF state, the vehicular device transmits a radio wave including a first alarm based on having a variation in air pressure or acceleration of a tire, which is mounted to the vehicle, detected by a sensor transmitter for detecting and transmitting the air pressure of the tire or the acceleration applied to the tire. The mobile device carries out a warning notification to a user based on having reception of a radio wave including a first alarm transmitted by the vehicular device.

A transmitter is configured to be attached to each of wheel assemblies provided in a vehicle and execute a process in accordance with a command included in a trigger signal. The transmitter includes a battery, which serves as a power source for the transmitter, a condition detecting section, which is configured to detect a condition of a tire, a trigger receiving section, which is configured to receive, as the trigger signal, an unmodulated wave having a received signal strength indication greater than or equal to a predetermined received signal strength indication, a transmitting section, which is configured to transmit a signal, and a controlling section, which is configured such that, when the trigger receiving section receives the unmodulated wave, the controlling section causes the transmitting section to transmit the signal in response to the unmodulated wave. The controlling section is configured to execute an accumulation process to accumulate reception time of the unmodulated wave from a starting point in time, and shift into a restriction state to restrict a response to the unmodulated wave when the accumulated reception time reaches a predetermined time.

A method for adapting a tire inflation pressure of an agricultural vehicle includes ascertaining a current vehicle position by a navigation system, correlating the current vehicle position by a control unit with a cartographically captured field boundary, detecting a travel-induced entry into a cultivation region surrounded by a field boundary, and selecting a set tire inflation pressure designated for field cultivation from a database by the control unit. The method further includes applying the selected set tire inflation pressure to at least one tire of the agricultural vehicle by a tire-pressure regulating system.

A method via which tire modules can be associated with tire positions on a vehicle includes: inputting vehicle data and tire information via a mobile detecting device; analyzing the input information via the detecting device; providing an instruction to the user of the detecting device indicating the first tire for performing a first tire module identification; positioning the detecting device near the first tire which is specified by the detecting device; activating an inquiry signal having a transmission frequency specified by the detecting device and a specified signal amplitude to a tire module arranged in the tire, wherein the tire module includes at least one sensor for tire-pressure monitoring; capturing a response signal from the tire module, wherein the response includes the identification data of the tire module; and, evaluating the response signal of the tire module and associating the identified tire module with a tire position.

Method for the configuration of a tyre pressure sensor (10) for a vehicle (100), comprising the following steps: production of a data communication connection (20) between a mobile radio device (30) and a tyre pressure sensor (10), selection of at least one specific sensor parameter (40) for the vehicle (100) via a mobile radio device (30), activation of the at least one selected sensor parameter (40) in the tyre pressure sensor (10).

A vehicle operational diagnostics and condition response system includes at least an axle supporting a cargo transport unit frame, a suspension disposed between and secured to each the cargo transport unit frame and the axle, a load detection device interacting with the suspension and communicating with a system controller, wherein the system controller is supported by the cargo transport unit frame, and a cargo transport unit health status system supported by the cargo transport unit and configured to communicate with the system controller. The cargo transport unit health status system provides state status information for monitored operational elements of the cargo transport unit.

A transmitter is coupled to each of a plurality of wheel assemblies included in a vehicle. The transmitter is configured to function in one of a plurality of formats that are selectable by a command from a trigger device. The transmitter includes a pressure sensor configured to detect the tire pressure, a memory that stores an ID code, a transmission unit configured to transmit a signal, a controller configured to control the transmitter, and a trigger reception unit configured to receive a trigger signal including the command from the trigger device. The controller is configured so that when the trigger reception unit receives a trigger signal including a command designating a format of the transmitter, the controller has the transmitter function in the designated format and has the transmission unit transmit the signal including the ID code to register the ID code to an in-vehicle receiver.