A system for operating a train having one or more locomotive consists with each locomotive consist comprising one or more locomotives, the system including a locator element to determine a location of the train, a track characterization element to provide information about a track, a sensor for measuring an operating condition of the locomotive consist, a processor operable to receive information from the locator element, the track characterizing element, and the sensor, and an algorithm embodied within the processor having access to the information to create a trip plan that optimizes performance of the locomotive consist in accordance with one or more operational criteria for the train.

Embodiments of the application provide a trackside device, a track starlink system and a train operation control system, which relate to a technical field of traffic trackside intelligent devices and are used to overcome a problem of a limited sensing range of existing on-board intelligent devices. The trackside device includes: a collection module configured to collect detection information at a side of a track; a processing module configured to process the detection information to obtain a processing result; a trackside resource control module configured to drive and control a trackside resource when a trackside resource request is received from a target train and the trackside resource is in a released state, wherein the trackside resource control module is further configured to monitor a state of the trackside resource; and a communication module configured to communicatively connect with a ground center and the target train.

A system includes an engine and a controller. The engine is capable of multiple operating modes, and each mode has a relatively different fuel ratio such that as the engine is changed from a first operating mode having a first ratio of a first fuel to a second fuel to a second operating mode having a second ratio of the first fuel to the second fuel. The controller is operable to change the engine from one operating mode to another operating mode.

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 method for determining an actual geometry of a track by a track inspection vehicle which is movable on the track, wherein reference points positioned in a lateral environment of the track are automatically recorded by a non-contacting recording system arranged on the track inspection vehicle and their respective actual distance from the track is determined. A three-dimensional trajectory of the track is recorded by an inertial measuring system arranged on the track inspection vehicle, wherein the trajectory is divided by a computing unit into trajectory sections each having a section starting point related to a first reference point and a section end point related to a second reference point, wherein a virtual longitudinal chord is defined for each trajectory section in relation to the assigned reference points, and wherein actual distances between the trajectory and the respectively defined longitudinal chord are calculated for each trajectory section.

A rail position measurement device that measures a three-dimensional position of a rail using a measurement vehicle includes: a position posture measurement device to measure a position and a posture of the measurement vehicle; and a laser scanner that is a sensor installed on the measurement vehicle so as to be capable of irradiating at least a web and a bottom of a side surface of the rail with laser light and used for measuring the three-dimensional position of the rail.

A railcar security system that includes a railcar, a first sensor having a first sensor type and a first sensor location with respect to the railcar, a second sensor having a second sensor type and a second sensor location with respect to the railcar, a first lighting group linked with the first sensor, a second lighting group linked with the second sensor, and a controller. The controller is configured to receive an arming signal, receive a trigger signal indicating a sensor of the plurality of sensors has been triggered, determine a sensor type and a sensor location for the sensor based on the trigger signal, activate the first lighting group when the determined sensor type and the determined sensor location correspond with the first sensor, and activate the second lighting group when the determined sensor type and the determined sensor location correspond with the second sensor.

A railroad locomotive monitoring system configuration system for a plurality of trains comprising: a monitoring system, and an on-board computer programmed or configured to: determine or receive railroad locomotive data; determine or receive railroad operation data; determine or receive configuration data; and based at least partially on at least a portion of the railroad locomotive data, at least a portion of the railroad operation data, and at least a portion of the configuration data, automatically configure at least one setting of the at least one component of the monitoring system.

A communication system includes communication units onboard a vehicle system. A first unit receives satellite positioning data and correction data based on phase measurements of satellite signals. A second unit receives the satellite positioning data. One or more processors determine a first geographical position of the first unit based on the position correction data and the satellite positioning data. The processors communicate the position correction data or a copy thereof to the second unit. The processors determine second geographical position data of the second unit based on the position correction data and the satellite positioning data. The one or more processors communicate the second geographical position data that is determined to the first communication unit.

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.