A tire monitor includes a sensor generating tire data and a plurality of control modules having phase locked loop circuits. The control modules generate output signals carrying the tire data. A first of the control modules is configured to generate first output signals having a first frequency and according to a first protocol. A second of the control modules is configured to generate second output signals having a second frequency and according to a second protocol. In examples, the output signal can be transmitted in parallel to different computing systems.

A tire anti-theft system includes a transmitter attached to a tire and configured to transmit tire ID information; a first database configured to store vehicle ID information and tire ID information of a tire mounted on the vehicle; a second database configured to store the tire ID information and tire status information indicating whether or not the tire identified with the tire ID information is stolen tire; and a vehicle control apparatus, in which the vehicle control apparatus includes a reader configured to perform near field communication with the transmitter attached to the tire mounted on a vehicle to be controlled and acquire the tire ID information, and a controller configured to, in a case where the reader acquires the tire ID information, restrict operation of the vehicle to be controlled if information indicating that the tire is stolen tire is stored in association with the tire ID information.

A method and device may be used for scanning communication protocols for a sensor of a motor vehicle electronic tire pressure monitoring system. The method may include selecting a make and a model of a motor vehicle. The method may include transmitting one or more activation signals. The one or more activation signals may be transmitted in sequential order according to a scanning protocol. The scanning protocol may be based on a predefined parameter. Each of the one or more activation signals may be associated with a different communication protocol. The method may include stopping the transmission of the one or more activation signals on a condition that a signal from a sensor is received.

Embodiments included herein are directed towards systems and methods for tire pressure monitoring. Embodiments may include transmitting a first Bluetooth Low Energy (“BLE”) event at a Phase Auto-Location (“PAL”) block associated with a vehicle electronic control unit (“ECU”). Embodiments may further include generating a random number to be used for an inter-event delay associated with a BLE system, wherein the inter-event delay includes a fixed time and a randomized delay. Embodiments may also include calculating a time for the randomized delay and adding the time to an encoded Look Back Time (“LBT”) from the first BLE event to generate frame contents. Embodiments may further include providing the frame contents and the random number to a stack for transmission.

Methods, apparatus, systems, and computer program products for tire pressure monitoring system (TPMS) sensor authentication are disclosed. In a particular embodiment, an electronic control unit (ECU) of a vehicle receives a first radio frequency (RF) transmission that includes TPMS data and a first signature value. In this particular embodiment, the ECU uses a key value to generate a second signature value and determines whether the second signature value corresponds with the first signature value. In this example embodiment, the ECU uses a determination of whether the second signature value corresponds with the first signature value to determine whether the first RF transmission is from a particular TPMS sensor authenticated to the key value.

Secure vehicular part communication is described herein. An example apparatus can include a processing resource, a memory having instructions executable by the processing resource, and a vehicular communication component coupled to the processing resource. The vehicular communication component can be configured to, in response to receiving a part public key and a part signature from a part communication component associated with a vehicular part, verify an identity of the vehicular part based on the part signature. The vehicular communication component can be configured to, in response to verifying the identity, generate a vehicular public key. The vehicular communication component can be configured to encrypt vehicular data using the part public key. The vehicular communication component can be configured to provide the vehicular public key and the vehicular data to the part communication component. The vehicular communication component can be configured to receive, from the part communication component, part data encrypted using the vehicular public key.

A sensor transceiver transitions into a first state that is capable of receiving RF waves intermittently. Upon starting to receive a burst signal on RF waves from a vehicle-body system under the first state, the sensor transceiver transitions into a second state that is capable of receiving RF waves continuously. Upon receiving a request signal on RF waves from the vehicle-body system under the second state, the sensor transceiver transmits data on tire pressure to the vehicle-body system.

A tire pressure monitoring unit is for mounting on a vehicle wheel, having a sensor for measuring the tire pressure, a transmitter and a receiver for wireless data transmission, a memory for storing tire data, and a controller connected to the sensor, the transmitter, the receiver and the memory. The controller writes this tire data into the memory on receipt of tire data received via the receiver and assigns a value to a variable, the value marking this tire data as valid. It is provided that a necessary condition for the variable to be assigned a value which marks the tire data as invalid is that the controller detects a pressure increase that exceeds a predetermined threshold value. In addition, a corresponding method for managing tire data in a data memory of a tire pressure monitoring unit is described.

Approaches are provided where direct communications between tire pressure sensors are provided. One sensor may act as a teacher while other sensors may act as students and learn from the teacher sensor.

This application relates to a tire sensor configuring device and a smart tire system including the same. In one aspect, the tire sensor configuring device includes a transceiver receiving a communication module identification code of a communication module provided in a vehicle to communicate with a smart tire management server, tire identification codes of a plurality of tires mounted to the vehicle, and sensor identification codes of sensor modules respectively attached to the plurality of tires. The tire sensor configuring device may also include a controller configured to arrange the communication module identification code, the tire identification codes, and the sensor identification codes according to a protocol previously created in association with the smart tire management server to form a packet. The transceiver transmits the packet to the communication module.