A sensor system senses one or more characteristics of vehicles in a vehicle system with sensors disposed onboard the vehicles and communicate data representative of the one or more characteristics from the sensors to one or more of a controller or a control system of the vehicle system. The data communicated from the sensors onboard the same vehicle can be synchronously communicated with respect to the sensors onboard the same vehicle and asynchronously communicated with respect to the sensors disposed onboard one or more other vehicles in the vehicle system. The systems and methods can direct components disposed onboard a vehicle system to change operations, monitor data output by sensors operatively connected with the components, and determine which of the sensors are operatively connected with which of the components based on the operations of the components that are changed and the data that is output by the sensors.

An embodiment of the present disclosure provides a route resource controlling method, intelligent vehicle on-board controller and object controller. The method comprises: determining a route search extension distance of a train based on current location and speed of the train, wherein the current route search extension distance is the farthest distance in front of the train that is currently expected to be safe for operation based on current speed of the train; determining the currently required link and route resource contained thereof; determining the target authority of the route resource.

An example automated locomotive spotting system includes a locomotive having a tractive effort mechanism for moving the locomotive along a track, and a locomotive controller configured to control the tractive effort mechanism to move the locomotive along the track. The locomotive controller includes an odometer configured to monitor a distance traversed by the locomotive along the track. The locomotive controller is configured to receive a requested spotting distance value, and initiate movement of the locomotive along the track via the tractive effort mechanism. The locomotive controller is also configured to monitor, by the odometer, the distance traversed by the locomotive along the track, and inhibit movement of the locomotive in response to the monitored odometer distance indicating the locomotive has traversed the requested spotting distance.

A system includes one or more processors that are configured to obtain a constraint on movement for a first vehicle system along a route. The constraint is based on movement of a separate second vehicle system that is concurrently traveling along the same route. The processor(s) are configured to determine a speed profile that designates speeds for the first vehicle system according to at least one of distance, location, or time based on the constraint such that the first vehicle system maintains a designated spacing from the second vehicle system along the route.

A system includes a location determining circuit configured to acquire position information of a vehicle system moving along a route. The system also includes a controller circuit having one or more processors. The controller circuit is configured to calculate curvatures of the route, based at least in part on the position information, to form a curvature waveform. The controller circuit is further configured to generate a route map based on the curvature waveform.

A method for operating a railroad vehicle without reference to physical railroad signs placed along a railroad track includes determining a current location of the railroad vehicle along the railroad track based on the determined current location of the railroad vehicle, automatically selecting a virtual railroad sign from one or more databases containing a plurality of virtual railroad signs, each of the plurality of virtual railroad signs stored in the one or more databases being associated with (i) a location along the railroad track and (ii) a message, and displaying, on an electronic display device a railroad track indicia representative of a segment of the railroad track, a railroad vehicle indicia representative of at least a portion of the railroad vehicle, and an indicia representative of the associated message of the selected virtual railroad sign.

A device for attachment to a train having a lead locomotive or control car and a rear car in a track network having a plurality of tracks is disclosed. The device may include at least one sensor. The sensor(s) may be disposed with the rear car. The sensor(s) may be configured to generate sensor data associated with at least one of a heading of the rear car of the train or a distance between the rear car of the train and an object in the track network. A communication interface may be configured to transmit the sensor data to at least one receiver. The receiver(s) may provide at least one indication based on the sensor data. A device for use onboard the train, a control system, a method for operating the device(s), and a method for coupling the train to a separate car are also disclosed.

A vehicle communication system includes a lead communication device wirelessly communicating command messages to remote communication devices onboard a vehicle system during a messaging cycle. The lead device receives reply messages from the remote devices during the messaging cycle in response to the command messages. The lead device receives a status signal from at least one of the remote devices during a guard interval that follows completion of the messaging cycle. The lead device communicates the command message and receives the reply messages using analog modulation or digital modulation. The lead communication device also receives the status signal using the other of the analog modulation or the digital modulation. The command messages, the reply messages, and the status signal are communicated using a designated frequency channel.

A vehicle control system determines a predicted location of wheel slip for an upcoming trip of a vehicle system by comparing a vehicle characteristic, route characteristic, and/or weather characteristic associated with the upcoming trip with a vehicle characteristic, route characteristic, and/or weather characteristic associated with a previous detection of wheel slip. Movement of the vehicle system is controlled during the upcoming trip by reducing tractive effort generated by a leading vehicle of the vehicle system relative to a trailing vehicle of the vehicle system during movement over the predicted location, reducing tractive effort generated by a leading axle in a vehicle of the vehicle system relative to a trailing axle of the vehicle during movement over the predicted location, and/or directing an adhesion modifying device to automatically dispense an adhesion modifying substance onto the predicted location.

A device which is configured for controlling a vehicle drive (40) for traction of a vehicle has a drive control apparatus and a monitoring apparatus. In order to ensure a high degree of safety when using the vehicle drive during rapid deceleration of the vehicle, the monitoring apparatus provides a traction release control signal value to the drive control apparatus, under the effect of which the drive control apparatus is enabled to control the vehicle drive, if, in addition to a traction release request signal value due to a rapid deceleration request and an additional traction lock request signal value due to a traction lock request, an additional traction release request signal value due to a traction release condition has effect on the monitoring apparatus. There is also described a vehicle with such a device and to a method for controlling a vehicle drive for traction of a vehicle.