Abstract: A control system for a rail vehicle system including a lead powered unit and a remote powered unit is provided. The system includes a user interface, a master isolation module and a slave controller. The user interface is disposed in the lead powered unit and is configured to receive an isolation command to turn on or off the remote powered unit. The master isolation module is configured to receive the isolation command from the user interface and to communicate an instruction based on the isolation command. The slave controller is configured to receive the instruction from the master isolation module. The slave controller causes the remote powered unit to supply tractive force to propel the rail vehicle system when the instruction directs the slave controller to turn on the remote powered unit. The slave controller causes the remote powered unit to withhold the tractive force when the instruction directs the slave controller to turn off the remote powered unit.

Abstract: A method for improving train performance, the method including determining a rail car parameter for at least one rail car to be included in a train, and creating a train trip plan based on the rail car parameter in accordance with one or more operational criteria for the train.

Abstract: A method for operating a train includes: (a) using a processor carried by the train, creating a trip profile which is computed at so as to substantially optimize an operating parameter of the train which depends on multiple operating variables; (b) operating the train along a route at speeds determined by the trip profile; (c) identifying a target location ahead of the train which cannot be cleared in a desired time if the train operates in accordance with the trip profile; and (d) operating the train at a clearing speed substantially faster than determined by the trip profile until the target location is cleared. A computer program product is provided for carrying out the method.

Abstract: A method of communicating data signals includes receiving data from one or more data sources disposed on board a rail vehicle and allocating different portions of a data communication bandwidth to data signals that include the data based on categories of the data. The categories represent at least one of the one or more data sources that provided the data or contents of the data. The data communication bandwidth includes a bandwidth that is available on a communication pathway of the rail vehicle. The method also includes transmitting the data signals through the communication pathway using the portions of the bandwidth that are assigned to the data signals.

Abstract: A communication system includes an electronic component located at a wayside device positioned along a route of a rail vehicle and a router transceiver unit operably coupled to the electronic component. The router transceiver unit is conductively coupled to a power supply conductor that supplies electric current to power at least one of the electronic component of the wayside device or an electronic apparatus other than the electronic component. The router transceiver unit is configured to communicate network data with a remote location through the power supply conductor.

Abstract: A rail sensing and analysis system utilizes a laser sensor 105, 107 to detect displacement of a rail 102, 104 resulting from loads imposed by a passing rail vehicle. Vertical and/or lateral displacements/loads may be sensed. Signatures in the resulting signals are indicative of useful information about the rail vehicle; such as wheel condition, bearing condition, truck condition, degree of bogie hunting, total load, load distribution, etc. The ratio of Lateral over Vertical force (L/V) may be used as an evaluation criterion.

Abstract: A system for controlling a marine vessel includes a processor, a propulsion system, and a directional system. The processor is disposed onboard the marine vessel and obtains a trip plan that includes designated operational settings of the marine vessel for a trip along a waterway. The propulsion system is communicatively coupled with the processor and generates propulsion to move the marine vessel according to the designated operational settings of the trip plan. The directional system is communicatively coupled with the processor and steers the marine vessel according to the designated operational settings of the trip plan. Operating the propulsion system and the directional system according to the designated operational settings of the trip plan reduces at least one of fuel consumed or emissions generated by the marine vessel relative to the marine vessel being propelled or steered according to one or more plans other than the trip plan.

Abstract: A method for operating a train includes: (a) using a processor carried by the train, creating a trip profile which is computed at so as to substantially optimize an operating parameter of the train which depends on multiple operating variables; (b) operating the train along a route at speeds determined by the trip profile; (c) identifying a target location ahead of the train which cannot be cleared in a desired time if the train operates in accordance with the trip profile; and (d) operating the train at a clearing speed substantially faster than determined by the trip profile until the target location is cleared. A computer program product is provided for carrying out the method.

Abstract: A communication system for a rail vehicle consist includes antenna modules, routing modules, and an arbitration module. The antenna modules are disposed at spaced apart locations along the consist and receive network data from an off-board device. The routing modules are communicatively coupled with the antenna modules and receive the network data from the antenna modules. The routing modules are communicatively coupled with a network connection extending along the rail vehicle consist. The arbitration module is communicatively coupled with the network connection. The arbitration module forms a message represented by the network data. One or more of the routing modules transmits the network data received from the off-board device to the arbitration module over the network connection. The arbitration module receives the network data to form the message and transmits the message to one or more powered units of the rail vehicle consist through the network connection.

Abstract: A communication system for a rail vehicle consist includes antenna modules, routing modules, and an arbitration module. The antenna modules are disposed at spaced apart locations and receive a trip profile from an off-board device. The trip profile is related to tractive and/or braking effort supplied by one or more powered units of the rail vehicle consist. The routing modules are disposed on the powered units and are communicatively coupled with the antenna modules. The routing modules are communicatively coupled with a network connection extending along the rail vehicle consist between the powered units. The arbitration module is communicatively coupled with the routing modules by the network connection. The routing modules transmit the received trip profile to the arbitration module. The arbitration module reconstitutes the trip profile into a message that is transmitted to a propulsion subsystem of one or more of the powered units.

Abstract: Systems and methods for controlling a rail vehicle are provided. In one embodiment, a rail vehicle system includes a first version of a travel database including travel information, a communication link to receive a second version of the travel database, and a controller configured to, in response to the second version of the travel database including changes to the travel information that meet predefined override criteria, control operation of the rail vehicle system based on the first version of the travel database; and in response to the changes to the travel information not meeting the predefined override criteria, adjust operation of the rail vehicle system to operate based on the second version of the travel database.

Abstract: Systems and methods for controlling rail vehicle data communication are provided. In one embodiment, a multiple-unit rail vehicle system includes a first rail vehicle including a first wireless network device to detect a wireless network. The wireless network is provided by a wayside device. The rail vehicle further comprises a first communication management system to send, through the wireless network, a data communication to a second rail vehicle of the multiple-unit rail vehicle system.

Abstract: An optimization system is provided for a braking schedule of a powered system traveling along a route. The braking schedule is based on at least one predetermined characteristic of the powered system and is configured to be enacted in a braking region along the route. The optimization system includes a sensor configured to measure a parameter related to the operation of the powered system. Additionally, the system includes a processor coupled to the sensor, to receive parameter data. The processor compares the measured parameter with an expected parameter, which is based on the at least one predetermined characteristic of the powered system. The processor adjusts the at least one predetermined characteristic based on the comparison, and adjusts the braking schedule based on the adjustment to the at least one predetermined characteristic. A method is also provided for optimizing a braking schedule of a powered system traveling along a route.

Abstract: A system is provided for optimizing a path for a marine vessel through a waterway from an initial location to a final location. The system includes a propulsion system and a directional system on the marine vessel, which impart a selective propulsion force on the marine vessel at a selective direction based on a received propulsion command and direction command from a processor. The processor determines an optimal path for the marine vessel, an optimal propulsion command and optimal directional command at a respective incremental location along the optimal path, so to optimize a performance characteristic of the marine vessel. The determination of the optimal path, the optimal propulsion command and the optimal directional command is based on the initial location, the final location, at least one operating parameter, the performance characteristic, and navigational data of the waterway.

Abstract: A method for operating a train includes: (a) using a processor carried by the train, creating a trip profile which is computed at so as to substantially optimize an operating parameter of the train which depends on multiple operating variables; (b) operating the train along a route at speeds determined by the trip profile; (c) identifying a target location ahead of the train which cannot be cleared in a desired time if the train operates in accordance with the trip profile; and (d) operating the train at a clearing speed substantially faster than determined by the trip profile until the target location is cleared. A computer program product is provided for carrying out the method.

Abstract: A control system for a rail vehicle system including a lead powered unit and a remote powered unit is provided. The system includes a user interface, a master isolation module and a slave controller. The user interface is disposed in the lead powered unit and is configured to receive an isolation command to turn on or off the remote powered unit. The master isolation module is configured to receive the isolation command from the user interface and to communicate an instruction based on the isolation command. The slave controller is configured to receive the instruction from the master isolation module. The slave controller causes the remote powered unit to supply tractive force to propel the rail vehicle system when the instruction directs the slave controller to turn on the remote powered unit. The slave controller causes the remote powered unit to withhold the tractive force when the instruction directs the slave controller to turn off the remote powered unit.

Abstract: A method for improving train performance, the method including determining a rail car parameter for at least one rail car to be included in a train, and creating a train trip plan based on the rail car parameter in accordance with one or more operational criteria for the train.

Abstract: In a transportation system (rail system or otherwise), a wayside device potentially operates in a plurality of operational modes. The wayside device is outfitted with an interface system for interfacing the wayside signal device with a vehicle control system. The interface system determines the present operational mode of the wayside device and independently communicates information relating to the determined present operational mode to the vehicle control system. The vehicle control system may control the vehicle based on the information relating to the determined present operational mode. The interface system includes functionality for validating the determined present operational mode prior to transmission of the information to the vehicle control system, to ensure that the vehicle control system is provided with correct and/or current information. The wayside device may be a wayside signal device whose operational modes (as determined by the interface system) are signal aspects conveyed to a vehicle.

Abstract: A system is provided for optimizing a path for a marine vessel through a waterway from an initial location to a final location. The system includes a propulsion system and a directional system on the marine vessel, which impart a selective propulsion force on the marine vessel at a selective direction based on a received propulsion command and direction command from a processor. The processor determines an optimal path for the marine vessel, an optimal propulsion command and optimal directional command at a respective incremental location along the optimal path, so to optimize a performance characteristic of the marine vessel. The determination of the optimal path, the optimal propulsion command and the optimal directional command is based on the initial location, the final location, at least one operating parameter, the performance characteristic, and navigational data of the waterway.

Abstract: A method for communicating on a train that has at least two locomotives, the method including determining when a primary communication path ceases to be available for a specific subsystem of the train, identifying at least one auxiliary communication path to transmit information for the specific subsystem, configuring a message for the specific subsystem which complies with a message format of the at least one auxiliary communication path, and transmitting the message on the at least one auxiliary communication path. A system and a computer software code are further disclosed for providing a communication system for a powered system.