The disclosure relates to a light train control system applied to oversea freight railways. The system integrates automatic block, station turnout control and train operation overspeed protection control and comprises an on-board subsystem, an RBC subsystem and a satellite positioning differential base station management subsystem, wherein the on-board subsystem is respectively connected to the RBC subsystem and the satellite positioning differential base station management subsystem. The light train control system adopts two-way continuous train-ground wireless communication and uses on-board signals as main signals of train operation to control the train operation; meanwhile, the system monitors the train operation, so as to provide an alarm to a driver when the situation changes, and to brake a train when necessary; and the system uses an electronic map to manage line data of a whole line, achieves dynamic configuration of the transport capacity by means of a virtual block technology, and remotely controls basic signaling equipment by means of an RBC. Compared with the prior art, the disclosure has the advantages of efficient system operation and simplified trackside equipment.

A train control network includes a rail, a first communication element and a second communication element, which are to communicate with each other. The first communication element includes a first HF-injector, adapted for injecting HF-signals into the rail. The second communication element includes a HF-receiver, adapted for receiving HF-signals transmitted via the rail. An evaluation unit is provided for analyzing the received HF-signals.

A system and method for monitoring a track and/or rail employs one or more distance measuring imagers mounted to a railcar and directed to image the track and/or rails wherein the images are geo-tagged with location data. Geo-tagged distance measurements are processed to determine at least track gauge and/or at least rail fastener integrity. The system and method may also determine other track and/or rail integrity issues including, e.g., rail profile, rail alignment, center point dip, cross level, rail cant, wheel wear, wheel integrity, rail wear, rail defects, and/or rail temperature. The system and method may also determine when inspection and/or maintenance of the track is indicated, and provide selected records of where and/or when such inspection and/or maintenance is indicated.

An end of train device (EOT) suitable of use on a railway vehicle includes a mounting unit for installation on a car of a railway vehicle, an enclosure housing a plurality of electronic components, and an illumination device configured to illuminate a section of a surrounding area of the railway vehicle, to receive reflected light and to measure time for the reflected light to return to the illumination device for monitoring purposes of the surrounding area. Further, a monitoring system and a monitoring method are described.

An end of train device suitable of use on a railway vehicle includes a tracking device providing location data of a railway vehicle, a protection module with a processor and configured via computer executable instructions to monitor a motion of a part of the railway vehicle utilizing the location data, and initiate an emergency brake application of the part of the railway vehicle in response to a detected state of motion.

An End-of-Train device, a system and a method for signaling events through a visibility marker is provided. The method includes identifying an illumination pattern generated by the visibility marker associated with an End-of-Train device on a leading train, wherein the illumination pattern is identified based on output of one or more secondary sensors on the follower train, and wherein the illumination pattern is indicative of an event affecting an operation of the leading train. Based on the identified illumination pattern one or more instructions to be executed are determined. Further, the one or more instructions are executed for signalling events through the visibility marker associated with the follower train.

A system includes one or more processors configured to identify first location data corresponding to a first location of a first vehicle of a vehicle system when the first vehicle passes a reference object and identify second location data corresponding to a second location of a second vehicle of the vehicle system. The one or more processors are further configured to determine whether the first location and the second location are within a predetermined distance of each other and in response to determining that the first and second locations are within the predetermined distance of each other, and generate a signal related to a condition that the first location and the second location are within the predetermined distance.

A Head-of-Train device suitable for mounting inside a cab of a train is disclosed. The Head-of-Train device includes a memory and a processing unit communicatively coupled to the memory, wherein the processing unit is configured to execute one or more instructions in the memory to synthesize an audio message based on status associated with at least one equipment onboard the train. The Head-of Train device further includes an audio output device configured to output the audio message.

A mid of train (MOT) mobile unit for use with a train is provided. The MOT mobile unit comprises a first hose for mounting the MOT mobile unit between first and second railway cars of the train located near a middle of the train and a radio for communications with an end of train (EOT) unit disposed on one end of the train and for communications with a head of train (HOT) unit disposed on other end of the train. With the first radio, the MOT mobile unit provides a repeater device functionality for communicating between the EOT unit and the HOT unit. The MOT mobile unit is configured to receive a power from a brake line of the train that runs a length of the train, wherein the power is derived from a compressed air in the brake line by means of an air-powered generator that recharges a battery.

An end-of-train device, a system, and a method for monitoring barrier gates are provided. The method includes receiving at least one image associated with a barrier gate from an imaging device mounted on a train. Further, the at least one image is analyzed to determine a current status of the barrier gate. The current status corresponds to a position associated with the barrier gate. Based on the current status of the barrier gate, an action to be performed is identified. Further, one or more instructions for performing the identified action are generated.