A system, method, and computer program product for determining ancillary subdivision/districts may include obtaining route data associated with one or more vehicle network operators operating one or more subdivisions/districts over which the vehicle group may travel, determining an ancillary subdivision/district of the one or more subdivisions/districts that are not included in the route data by any of the one or more vehicle network operators, receiving route data for the vehicle network operator associated with the ancillary subdivision/district, and communicating with one or more wayside interface units in the ancillary subdivision/district based on the route data.

A system for vehicle management includes a control signal interface subsystem and a vehicle-mounted subsystem. Each of these subsystems includes an ultra-wideband (UWB) communications component. The subsystems communicate with each other through the UWB components. The vehicle mounted subsystem interfaces with a braking system of the vehicle. The vehicle mounted subsystem determines the distance between it and the control signal interface subsystem based on the time-of-flight of at least one communication between the subsystems. The vehicle-mounted subsystem can cause the braking system of the vehicle to activate if the distance between the vehicle-mounted subsystem and the control signal interface subsystem is less than a threshold.

A system configured to be disposed onboard a vehicle includes a communication unit and a processing unit. The communication unit is configured to obtain first trip information including first location-based operational information. The first trip information includes commands for a positive train control (PTC) system. The communication unit is also configured to obtain second trip information including second location-based operational information. The second trip information includes trip profile information for performing a mission by the vehicle. The processing unit is configured to obtain the first trip information and the second trip information from the communication unit, and to determine combined trip information using the first trip information and the second trip information. The processing unit is also configured to develop control information using the combined trip information.

A system and method are provided for determining a position of a vehicle traversing a constrained path via cooperating communications equipment installed at fixed points along a known route and onboard the vehicle. The disclosed schemes leverage certain commonly-installed communications nodes to provide positioning information for participating vehicles when those vehicles are specifically limited in their movement to a particular path, including a train track. Signal analysis between cooperating nodes provides localization information, including timing information, that is sufficient, given the physical constraints of the participating vehicles to a particular track, lane or the like, to quickly resolve a positional localization for the vehicles. Common wireless transceiver connectivity is used to support a backup position locating system that has an appropriate fidelity to provide a required modicum of safety without stopping movement of all vehicles in a vicinity of a particular location with which other communications may have broken down.

A system and a method for monitoring route devices in a transportation network includes one or more processors to receive sensed traffic control device information from first vehicle systems in a transportation network formed from interconnected routes. The sensed traffic control device information indicates states of traffic control devised at intersections between the routes in the transportation network. The one or more processors determine whether the sensed traffic control device information conflicts with stored traffic control device information stored in a database accessible by the one or more processors. The one or more processors send one or more bulletins to one or more second vehicle systems to change movement of the one or more second vehicle systems responsive to determining that the sensed traffic control device information conflicts with the stored traffic control device information.

The present invention relates to a CTC3.0-based implementation method for route handling of a regional centralized control station. The method is based on a CTC3.0 technology, and includes the following steps: step (1): generating multi-station train and shunting plans according to a multi-station planning terminal, and executing steps (2) and (4) at the same time; step (2): sending the train plan to an autonomous computer to generate a train route sequence, and executing step (3); step (3): sending, by the autonomous computer, the train route sequence to a regional centralized control route handling terminal; step (4): compiling, by the multi-station planning terminal, an automatically generated shunting route sequence in the shunting plan, and executing step (5); and step (5): synchronizing, by a center service, the shunting route sequence to the regional centralized control route handling terminal. Compared with the prior art, the present invention has the advantages of wide applications, safety, convenience, capability of effectively realizing multi-station management of a regional centralized control station, and the like.

A method and an apparatus for a train control system are disclosed, and are based on virtualization of train control logic and the use of cloud computing resources. A train control system is configured into two main parts. The first part includes physical elements of the train control system, and the second part includes a virtual train control system that provides the computing resources for the required train control application platforms. The disclosed architecture can be used with various train control technologies, including communications based train control, cab-signaling and fixed block, wayside signal technology. Further, the disclosure describes methodologies to convert cab-signaling and manual operations into distance to go operation.

A system for automatically updating route information to a locomotive that includes a route computer and voice radio encoder that merges data representing temporary changes in a route with a voice radio call placed by a dispatcher to a locomotive engineer. A voice radio decoder coupled to the locomotive cab voice radio extracts the data representing the temporary changes from the voice radio signal and provides the data directed to the energy management system so that there is no need for the engineer to manually enter the temporary data.

Example implementations relate to receiving vibration notifications from vibration sensors. In example implementations, a subset of a plurality of vibration sensors from which vibration notifications are expected may be identified based on a position of a train along a track. The plurality of vibration sensors may be arranged in a predetermined order on the track. Whether vibration notifications have not been received from consecutive, with respect to the predetermined order, vibration sensors in the subset may be determined.

The present disclosure relates to a CPU module for processing railway signals, and more specifically to a CPU module for processing railway signals that controls operation timing of a first comparator, a signal processing unit and a second comparator.