A system for monitoring tire pressure of at least one vehicle tire of a utility vehicle includes a pressure sensor for detecting an internal tire pressure of the at least one vehicle tire and an electrically controllable tire inflation system for varying the internal tire pressure. The system also includes a monitoring unit disposed in communication with the pressure sensor and the tire inflation system. The monitoring unit identifies a defect-induced loss of pressure in the at least one vehicle tire based on the detected internal tire pressure, determines a temporal progression of the detected defect-induced loss of pressure, calculates a volume flow necessary for continuous compensation of the pressure loss based on the temporal progression, and controls the volume flow into the at least one vehicle tire via the tire inflation system.

An electronic monitor displays a tire position for each of a plurality of tires on a motor vehicle and provides a warning if a pressure reading received from any of the tires is outside a selected range of the baseline tire pressure value established for that tire position. The tire position and baseline tire pressure value are established by using navigation keys and a pair of control keys on the monitor. In an earlier method of establishing one or more baseline tire pressure values, the baseline value was entered on a tire-by-tire basis. The present improvement enables the operator to enter a baseline value globally for all tire positions. First a tire selection mode is entered, and a tire position is selected. Next, a baseline tire pressure selection mode is entered and a baseline tire pressure value is selected. The baseline tire pressure value is then assigned and saved to all of the tire positions by simultaneously engaging the pair of control keys.

An on-board head up display (HUD) includes a housing, a support member rotatably connected to the housing, a display screen being transparent and flat, and a side of the display screen is fixed to the support member, and a control device located in the housing and configured to obtain traveling information from an on-board automatic diagnostic system, and the control device is further connected to the display screen and configured to display the traveling information on the display screen, and the control device is connected to the support member and configured to drive the support member to rotate with respect to the housing.

A tire pressure monitoring system monitors the pressure in at least one tire supporting a vehicle. The system includes at least one sensor mounted on the tire for measuring a pressure and a temperature of the tire. Transmission means transmit the measured pressure data and temperature data to a processor, and a tire pressure model is executed on the processor. The tire pressure model includes a driving event extractor to extract cold pressure data from the measured pressure data, and a temperature compensator to generate a compensated cold tire pressure from the cold pressure data. A noise filter filters sensor noise and generates a filtered cold tire pressure from the compensated cold tire pressure. A detection module receives the filtered cold tire pressure and determines an air pressure leak rate of the tire, and a leak notification corresponding to the air pressure leak rate is generated.

A method is for monitoring tire states and/or sensor states. The method includes the steps: a) capturing whether at least one tire sensor module for measuring tire states and/or sensor states is present in a monitoring region; b) determining whether the captured tire sensor module is unknown; c) evaluating data messages from the at least one captured and unknown tire sensor module, the evaluation including at least comparing at least one tire state transmitted via the data message with a limit value therefor and/or monitoring a sensor state of the tire sensor module transmitted via the data message; and, d) outputting a warning signal if a tire state exceeds or undershoots the respective limit value in order to indicate that a tire state of a tire assigned to the at least one unknown tire sensor module is critical and/or if a critical sensor state is detected.

A sensor transceiver is kept in a state capable of receiving LF waves. Upon receiving LF waves indicating a start command from the vehicle-body system, the sensor transceiver is caused to be in a state capable of receiving RF waves accordingly. Upon receiving an instruction command from the vehicle-body system under the state capable of receiving RF waves, the sensor transceiver notifies the vehicle-body system of data on tire pressure.

The tire pressure monitoring system repeatedly acquires the internal pressure value of the pneumatic tire and activates the timer when the internal pressure value falls below the warning threshold. The tire pressure monitoring system stops the output of the warning information associated with the warning threshold even if the internal pressure value falls below the warning threshold again until the timer expires. The tire pressure monitoring system newly activates the timer when the internal pressure value exceeds the warning threshold after falling below the warning threshold or the danger threshold in the period until the timer expires.

An electronic monitor displays a tire position for each of a plurality of tires on a motor vehicle and provides a warning if a pressure reading received from any of the tires is outside a selected range of the baseline tire pressure value established for that tire position. The tire position and baseline tire pressure value are established by using navigation keys and a pair of control keys on the monitor. In an earlier method of establishing one or more baseline tire pressure values, the baseline value was entered on a tire-by-tire basis. The present improvement enables the operator to enter a baseline value globally for all tire positions. First a tire selection mode is entered, and a tire position is selected. Next, a baseline tire pressure selection mode is entered and a baseline tire pressure value is selected. The baseline tire pressure value is then assigned and saved to all of the tire positions by simultaneously engaging the pair of control keys.

A tire air pressure monitoring system for a vehicle is disclosed. The tire air pressure monitoring system includes a detector configured to detect tire air pressures of tires of the vehicle; and a processing device. The processing device is configured to output a first notification that is an alarm representing a reduced tire air pressure state based on at least one of the tire air pressures less than or equal to a first threshold, detect a predetermined opportunity at which the tires can be filled with air, and output a second notification, differently from the first notification, based on a detection of the predetermined opportunity and at least one of the tire air pressures less than or equal to a second threshold but greater than the first threshold, the second threshold being greater than the first threshold.

Aspects of the present disclosure are generally related to one or more systems, methods, and devices for providing an integrated tire inflation system, mounted on each tire, wheel, rim, axle, or structure of the vehicle, that communicates with a remote device (e.g., communication device located in the cab of the vehicle and/or a remote network entity) and obtains an optimal tire pressure from the network entity that is calculated to maximize fuel economy, tread life, load, or an environmental condition. In some examples, the integrated telematics system may periodically measure and transmit data associated with the tire to the communication device in the cab and/or to a network entity that may calculate the optimal tire pressure for each tire on the vehicle. The integrated telematics system may receive the optimal tire pressure information from the communication device and/or the network entity and automatically adjust the tire pressure accordingly.