Abstract: An imaging system and method generate image data within a field of view that includes a cab of the vehicle and a portion of a route being traveled on and/or wayside devices disposed along the route. The cab includes a space where an operator of the vehicle is located. The image data generated by the camera is examined to identify route damage, a deteriorating condition of the route, and/or a condition of the wayside devices. The condition of the wayside devices can include damage to the wayside devices, a missing wayside device, deterioration of the wayside devices, or a change in terrain.

Abstract: An imaging system includes a camera and a controller. The camera is configured to be disposed on a first vehicle system or at a wayside location along a route to generate image data within a field of view of the camera. The controller is configured to monitor a data rate at which the image data is provided from the camera. The controller also is configured to identify a stimulus event within the field of view of the camera based on a change in the data rate at which the image data is generated by the camera.

Abstract: An image management system includes a controller and one or more analysis processors. The controller is configured to receive search parameters that specify at least one of operational data or a range of operational data of one or more vehicle systems. The one or more analysis processors are configured to search remotely stored image data based on the search parameters to identify matching image data. The remotely stored image data was obtained by one or more imaging systems disposed onboard the one or more vehicle systems, and are associated with the operational data of the one or more vehicle systems that was current when the remotely stored image data was acquired. The one or more analysis processors also are configured to obtain the matching image data having the operational data specified by the search parameters and to present the matching image data to an operator.

Abstract: A system includes a first communication module and a second communication module. The first communication module is configured to be disposed onboard a first vehicle of a vehicle consist, and the second communication module is configured to be disposed onboard a second vehicle of the vehicle consist. The first and second communication modules are communicatively coupled by first and second communication paths. The first and second communication modules are configured to communicate first information over the first communication path and second information over the second communication path. At least a portion of the first information includes a first command corresponding to a first operation of at least one of the first or second vehicles. At least a portion of the second information includes a second command corresponding to the first operation.

Abstract: A communication system includes a router transceiver unit and a bandwidth module. The router transceiver unit includes a network adapter module and a signal modulator module. The network adapter module is configured to receive high bandwidth network data from one or more data sources disposed on board a vehicle. The signal modulator module is configured for electrical connection to a wired connection, and to convert the high bandwidth network data into modulated network data in a form suitable for transmission over the wired connection. The bandwidth module is configured to allocate different portions of a data communication bandwidth of the wired connection to the modulated network data. The allocation is based on categories representing at least one of the one or more data sources or contents of the high bandwidth network data.

Abstract: An aerial camera system includes an aerial device disposed onboard a non-aerial vehicle as the non-aerial vehicle moves along a route. The aerial device also can be configured to fly above the route during movement of the vehicle along the route. The camera unit is configured to be disposed onboard the aerial device and to generate image data during flight of the aerial device. The one or more image analysis processors are configured to examine the image data and to identify a hazard disposed ahead of the non-aerial vehicle along a direction of travel of the non-aerial vehicle based on the image data. A method for identifying route-related hazards using image data obtained from a camera unit on an aerial device.

Abstract: A system, in a vehicle consist including at least a fuel car operably connectable to a powered vehicle via a fuel distribution path, includes a communication module and a determination module. The communication module is configured to communicate via a first channel and a second channel. The second channel is associated with the fuel distribution path and is configured to communicate a status signal. The determination module is configured to associate the fuel distribution path with the powered vehicle based at least in part on at least one of the status signal or an acknowledgment message indicating receipt of the status signal.

Abstract: A system includes a router transceiver unit that is configured to be disposed on-board a vehicle system. The vehicle system may have at least a source vehicle and a separate linked vehicle that are communicatively linked with each other through a system network of the vehicle system. The router transceiver unit is configured to be communicatively coupled to a requesting operational component of the source vehicle and the system network. The router transceiver unit is also configured to receive a local data packet from the requesting operational component that is directed toward a target operational component of the linked vehicle. The router transceiver unit includes an encapsulation module that is configured to transform the local data packet into an in-tunnel data packet, wherein the local and in-tunnel data packets have different packet formats.

Abstract: A camera system and method capture image data with a camera, a data storage device electrically connected to the camera and configured to store the video data and/or a communication device electrically connected to the camera and configured to communicate the image data to a system receiver located remote from the camera. The system receiver may be located onboard a vehicle such that an operator can carry the camera off board the vehicle and communicate the image data back to the vehicle, when performing, for example, work on the vehicle or inspecting the vehicle or the environs of the vehicle.

Abstract: A system includes a router transceiver unit that is configured to be disposed on-board a vehicle system. The vehicle system may have at least a source vehicle and a separate linked vehicle that are mechanically linked with each other to travel together along a route and that are communicatively linked with each other through a system network of the vehicle system. The router transceiver unit is configured to be communicatively coupled to a requesting operational component of the source vehicle and the system network. The router transceiver unit is also configured to receive a local data packet from the requesting operational component that is directed toward a target operational component of the linked vehicle. The router transceiver unit includes an encapsulation module that is configured to transform the local data packet into an in-tunnel data packet, where the local and in-tunnel data packets have different packet formats.

Abstract: A method includes determining a state of operational devices in a second group coupled with a second router onboard a second vehicular unit of a vehicle consist, registering an operational device in the second group based on the determined state, and transmitting a data message from an operational device in a first group of operational devices to the second router via a first router and a communication pathway of the vehicle consist. The first group is coupled with the first router onboard a first vehicular unit. The operational devices in the first and second groups perform functions of the respective first vehicular unit and second vehicular unit. The first and second routers are connected with each other by the communication pathway. The method also includes communicating the data message to the at least one of the operational devices in the second group that are registered with the second router.

Abstract: A communication system for a vehicle consist includes a control module that interfaces with at least one of a first router transceiver pair or a redundant router transceiver pair. Each of the router transceiver pairs can communicate network data between vehicles of the consist over a cable bus of the vehicle consist. The control module includes a monitor module and a switch module. The monitor module monitors operation of at least one of the first router transceiver pair or the redundant router transceiver pair. The switch module is operably coupled with the monitor module and controls the first router transceiver pair or the redundant router transceiver pair to communicate the network data over the cable bus if the other of the first router transceiver pair or the redundant router transceiver pair enters a failure condition for being unable to communicate the network data over the cable bus.

Abstract: A system includes a first communication module and a first ordering determination module. The first communication module is configured to be disposed onboard a first vehicle of a vehicle consist and to communicate individual messages that are targeted for communication with respective individual second vehicles of the vehicle consist. The first ordering determination module is configured to be disposed onboard the first vehicle of the vehicle consist, and to determine an order of the first vehicle and one or more of the second vehicles in the consist using message characteristic information. The message characteristic information corresponds to a transmission characteristic of the individual messages.

Abstract: A sensing system includes a leading sensor, a trailing sensor, and a route examining unit. The leading sensor is onboard a first vehicle of a vehicle system that is traveling along a route. The leading sensor measures first characteristics of the route as the vehicle system moves along the route. The trailing sensor is disposed onboard a second vehicle of the vehicle system. The trailing sensor measures second characteristics of the route as the vehicle system moves along the route. The route examining unit is disposed onboard the vehicle system and receives the first characteristics of the route and the second characteristics of the route to compare the first characteristics with the second characteristics. The route examining unit also identifies a segment of the route as being damaged based on a comparison of the first characteristics with the second characteristics.

Abstract: A system includes a first communication module and a second communication module. The first communication module is configured to be disposed onboard a first vehicle of a vehicle consist, and the second communication module is configured to be disposed onboard a second vehicle of the vehicle consist. The first and second communication modules are communicatively coupled by first and second communication paths. The first and second communication modules are configured to communicate first information over the first communication path and second information over the second communication path. At least a portion of the first information includes a first command corresponding to a first operation of at least one of the first or second vehicles. At least a portion of the second information includes a second command corresponding to the first operation.

Abstract: A railway communication system (10) includes a transmitter (12) receiving an input and producing a communication signal (18). The communication signal (18) includes at least two different portions (20,22) for separately encoding respective indications (38,40) of the input. The system also includes a receiver (14) coupled to a controlled device, the receiver (14) extracting at least one of the respective indications (38,40) from the communication signal (18). The receiver controls the device responsive to the at least one extracted indications (38,40).

Abstract: A control system includes an energy management system and an isolation control system. The energy management system generates a trip plan that designates operational settings of a vehicle system having powered units that generate tractive effort to propel the vehicle system. The energy management system determines a tractive effort capability of the vehicle system and a demanded tractive effort of a trip. The energy management system identifies a tractive effort difference between the tractive effort capability of the vehicle system and the demanded tractive effort of the trip and selects at least one of the powered units based on the tractive effort difference. The isolation module remotely turns the selected powered unit to an OFF mode such that the vehicle system is propelled along the route during the trip by the powered units other than the selected powered unit.

Abstract: A method includes receiving, at a data hub onboard an asset, a new configuration file, a service program, and a software update of a software application of the asset from a remote location. The data hub includes a current configuration file that indicates a current configuration state of the software application. The new configuration file indicates an updated configuration state of the software application with the software update. The service program includes work instructions for applying the updated configuration state to the software application. The method includes displaying the current configuration file and the new configuration file onboard the asset using the data hub. The method also includes updating the software application with the updated configuration state according to the work instructions of the service program using the data hub.

Abstract: A method includes determining a state of operational devices in a second group coupled with a second router onboard a second vehicular unit of a vehicle consist, registering an operational device in the second group based on the determined state, and transmitting a data message from an operational device in a first group of operational devices to the second router via a first router and a communication pathway of the vehicle consist. The first group is coupled with the first router onboard a first vehicular unit. The operational devices in the first and second groups perform functions of the respective first vehicular unit and second vehicular unit. The first and second routers are connected with each other by the communication pathway. The method also includes communicating the data message to the at least one of the operational devices in the second group that are registered with the second router.

Abstract: A method for establishing a network across a plurality of locomotives in a consist includes designating one locomotive of the plurality of locomotives as a network lead locomotive and designating the other of the plurality of locomotives as network trail locomotives.