Abstract: A method is provided that can include activating at least two wireless communication channels in parallel, between a first wireless transceiver and a second wireless transceiver. Each of the at least two wireless communication channels can operate at a different radio carrier frequency, and the first wireless transceiver may be part of a first vehicle. The method can also include transmitting, by the first wireless transceiver, common information in parallel on the at least two wireless communication channels to the second wireless transceiver and deactivating the at least two wireless communication channels.

Abstract: A computer-implemented method is provided that includes obtaining a first secret and a first public key, and obtaining a second secret a second public key. The method may also include authenticating the first public key of the first vehicle based on a first private key associated with the first vehicle, and authenticating the second public key of the second vehicle based on a second private key associated with the second vehicle. The method may also include preventing a man-in-the-middle attack, by securing at least one of a first vehicle-to-central office communication, a central office-to-first vehicle communication, or a first vehicle-to-second vehicle, wherein the first vehicle-to-central office communication and the central office-to-first vehicle communication are authenticated based on a determined private key associated with a respective first vehicle on-board computer, and sending a message, with the central office server, to a vehicle associated with a conditional movement authority.

Abstract: A diagnostic system and method obtain a thermal signature for one or more first components of a powered system. The thermal signature represents thermal measurements obtained at different locations of the powered system. The system and method identify an abnormal operating condition of the one or more first components of the powered system or one or more second components of the powered system based on the thermal signature.

Abstract: In one example, a wayside device monitoring system is provided. The system may include a wayside device and a controller. The wayside device may detect one or more operating parameters of a vehicle in a vehicle system moving over a route segment. The controller can receive information from the wayside device regarding at least the one or more operating parameters detected, and can control movement the vehicle directly or indirectly based at least in part on the received information.

Abstract: A vehicle control system includes a controller configured to be operably deployed onboard a first propulsion-generating vehicle of a multi-vehicle system, and a wireless communication unit configured to be electrically coupled to the controller. The controller is configured to control the wireless communication unit to wirelessly communicate first vehicle control signals to a second propulsion-generating vehicle of the multi-vehicle system that is immediately adjacent and mechanically coupled to the first propulsion-generating vehicle, while the first propulsion-generating vehicle and the second propulsion-generating vehicle are in a non-cable-connected state.

Abstract: A computer-implemented method is provided that includes obtaining a first secret and a first public key, and obtaining a second secret a second public key. The method may also include authenticating the first public key of the first vehicle based on a first private key associated with the first vehicle, and authenticating the second public key of the second vehicle based on a second private key associated with the second vehicle. The method may also include preventing a man-in-the-middle attack, by securing at least one of a first vehicle-to-central office communication, a central office-to-first vehicle communication, or a first vehicle-to-second vehicle, wherein the first vehicle-to-central office communication and the central office-to-first vehicle communication are authenticated based on a determined private key associated with a respective first vehicle on-board computer, and sending a message, with the central office server, to a vehicle associated with a conditional movement authority.

Abstract: A system that includes a lead locomotive in communication with one or more remote vehicles, and the lead locomotive including one or more processors configured to execute program instructions to perform functions based on the program instructions. These functions include determining a first characteristic related to the lead locomotive or the one or more remote locomotives, receiving historical data related to the first characteristic, comparing the first characteristic to the historical data to determine a change in first characteristic value, and determining a second characteristic related to the lead locomotive or the one or more remote locomotives. In response to the change in first characteristic value exceeding a threshold percentage, the one or more processors ignore the change in first characteristic value exceeding the threshold percentage based on the second characteristic.

Abstract: A vehicle control system and method determine that a vehicle moving in a manned operative state is approaching a defined zone. The vehicle is controlled based on manual input received from an operator onboard the vehicle while in the manned operative state. The system and method also switch the vehicle from the manned operative state to an unmanned operative state responsive to the vehicle approaching the defined zone and the operator disembarking from the vehicle. The movement of the vehicle is controlled in the unmanned operative state of the vehicle during travel of the vehicle inside the defined zone. The vehicle is autonomously controlled or remotely controlled while in the unmanned operative state.

Abstract: An infrastructure detection and monitoring system includes a remote data storage system that receives and communicates sensor data and signals regarding infrastructure health. The remote data storage system processes and/or stores at least a first sensor data portion and generates advisory signals based on the first sensor data portion. The advisory signals are communicated to a receiver device responsive to the sensor data indicating that the health of the infrastructure indicates imminent failure. Additionally or alternatively, the receiver device can generate one or more control signals responsive to the advisory signals or responsive to the sensor data indicating that the heath of the infrastructure indicates imminent failure of the infrastructure.

Abstract: A system that includes a lead locomotive in communication with one or more remote vehicles, and the lead locomotive including one or more processors configured to execute program instructions to perform functions based on the program instructions. These functions include determining a first characteristic related to the lead locomotive or the one or more remote locomotives, receiving historical data related to the first characteristic, comparing the first characteristic to the historical data to determine a change in first characteristic value, and determining a second characteristic related to the lead locomotive or the one or more remote locomotives. In response to the change in first characteristic value exceeding a threshold percentage, the one or more processors ignore the change in first characteristic value exceeding the threshold percentage based on the second characteristic.