Embodiments of the invention relate to a communication system for vehicles and an associated method. A method includes receiving a command message from a first vehicle at a second vehicle, wherein the first vehicle and second vehicle are communicatively coupled to define at least a portion of a vehicle group; receiving a status reply message from the second vehicle at the first vehicle in response to a trigger event; controlling an operation of one or more vehicles in the vehicle group based at least in part on a determined communications status of a communication network comprising at least one communication device with respect to the command message and the status reply message.

A method and system include a vehicle system including a plurality of vehicles. The vehicle system is configured to travel along a route. A plurality of location determination devices are onboard the vehicle system. Each of the plurality of location determination devices is configured to output position data regarding a location of at least one of the plurality of vehicles. A handling unit is in communication with the plurality of location determination devices. The handling unit is configured to receive the position data from the plurality of location determination devices and control separation distances between the plurality of vehicles based on the position data.

A method and system include a vehicle system including a plurality of vehicles. The vehicle system is configured to travel along a route. A plurality of location determination devices are onboard the vehicle system. Each of the plurality of location determination devices is configured to output position data regarding a location of at least one of the plurality of vehicles. A handling unit is in communication with the plurality of location determination devices. The handling unit is configured to receive the position data from the plurality of location determination devices and control separation distances between the plurality of vehicles based on the position data.

A locomotive assembly including an auxiliary power unit and a method of providing auxiliary power to a locomotive are disclosed. The locomotive assembly includes a locomotive having a power bus, a primary power source electrically coupled to the power bus, and a locomotive controller programmed to control the primary power source and transmit a first command signal to a power unit that is electrically coupled to the power bus. The power unit includes an auxiliary engine-generator set, a power interface electrically coupling the auxiliary engine-generate set to the power bus, and an auxiliary controller electrically coupled to the locomotive controller. The auxiliary controller is programmed to receive the command signal from the locomotive controller indicating a desired amount of power, control the auxiliary engine-generator set to produce at least the desired amount of power, and control the power interface to deliver the desired amount of power to the power bus.

A locomotive assembly including an auxiliary power unit and a method of providing auxiliary power to a locomotive are disclosed. The locomotive assembly includes a locomotive having a power bus, a primary power source electrically coupled to the power bus, and a locomotive controller programmed to control the primary power source and transmit a first command signal to a power unit that is electrically coupled to the power bus. The power unit includes an auxiliary engine-generator set, a power interface electrically coupling the auxiliary engine-generate set to the power bus, and an auxiliary controller electrically coupled to the locomotive controller. The auxiliary controller is programmed to receive the command signal from the locomotive controller indicating a desired amount of power, control the auxiliary engine-generator set to produce at least the desired amount of power, and control the power interface to deliver the desired amount of power to the power bus.

A travel unit travels in a curved section in an orientation in which a target wheel comes into contact with a target rail, a guide wheel comes into contact with a guide rail, and a non-target wheel does not come into contact with a non-target rail. The control unit changes the rotational speed of a first wheel and a second wheel in the curved section relative to the rotational speed of the first wheel and the second wheel in a straight section in accordance with the ratio of a second length, which is the length of the target rail along a travel path, to a first length, which is the length of the curved section along the travel path at a center portion in a widthwise direction of the travel path.

A travel unit travels in a curved section in an orientation in which a target wheel comes into contact with a target rail, a guide wheel comes into contact with a guide rail, and a non-target wheel does not come into contact with a non-target rail. The control unit changes the rotational speed of a first wheel and a second wheel in the curved section relative to the rotational speed of the first wheel and the second wheel in a straight section in accordance with the ratio of a second length, which is the length of the target rail along a travel path, to a first length, which is the length of the curved section along the travel path at a center portion in a widthwise direction of the travel path.

Various embodiments of methods and systems are provided for enhancing engine operation through data-sharing among vehicles. In one embodiment, a method includes determining whether a first value of a first operating parameter produced by a first vehicle is corrupted or unavailable; receiving a second value of the first operating parameter produced by a second vehicle that is proximate to the first vehicle; adjusting the second value by a first adjustment factor, the first adjustment factor based on a first value of a global positioning system (GPS) position of the first vehicle produced by the first vehicle and a second value of a GPS position of the second vehicle produced by the second vehicle; and in response to determining that the first value is corrupted or unavailable, controlling operation of an engine of the first vehicle based on the adjusted second value of the first operating parameter.

Various embodiments of methods and systems are provided for enhancing engine operation through data-sharing among vehicles. In one embodiment, a method includes determining whether a first value of a first operating parameter produced by a first vehicle is corrupted or unavailable; receiving a second value of the first operating parameter produced by a second vehicle that is proximate to the first vehicle; adjusting the second value by a first adjustment factor, the first adjustment factor based on a first value of a global positioning system (GPS) position of the first vehicle produced by the first vehicle and a second value of a GPS position of the second vehicle produced by the second vehicle; and in response to determining that the first value is corrupted or unavailable, controlling operation of an engine of the first vehicle based on the adjusted second value of the first operating parameter.

A control system for remotely facilitating a lead change among a plurality of locomotives in a train is disclosed. The control system may include a user input device, a display device, a communicating device configured to exchange information with the plurality of locomotives, and a controller in electronic communication with the user input device, the display device, and the communicating device. The controller may be configured to generate on the display device a graphical user interface configured to receive a plurality of user inputs in conjunction with the user input device, wherein the plurality of user inputs includes an isolation switch selection, a distributed power selection, and a lead/trail selection. The controller may also be configured to generate configuration commands communicable to the plurality of locomotives via the communicating device based on the user inputs.