The method can include: creating a platoon; maintaining a platoon; responding to a platoon event; and separating a platoon. However, the method can additionally or alternatively include any other suitable elements. The method functions to facilitate cooperative transportation (platooning) of a plurality of payloads by way of the cars.

The system can include a dispatcher and a plurality of cars. However, the system 100 can additionally or alternatively include any other suitable set of components. The system 100 functions to enable platooning of the plurality of cars (e.g., by way of the method S100).

A ground base device includes a schedule timetable storage unit storing a received schedule timetable periodically transmitted from the central control device; a departure-obstructed condition determination unit determining whether a departure-obstructed condition of a train is resolved and outputting departure-obstructed condition cancel signal when the departure-obstructed condition is resolved; a departure time control unit outputting departure-time appropriate signal when current time is departure time based on the schedule timetable upon receiving the departure-obstructed condition cancel signal; a departure interval control unit outputting departure-interval appropriate signal when intervals between the train and preceding and following trains are a threshold value or more upon receiving the departure-time appropriate signal; and a departure instruction signal output unit outputting a departure instruction signal upon receiving the departure-interval appropriate signal, and, when the central control device fails, the departure time control unit uses the schedule timetable received when the central control device is normal.

A ground base device includes a schedule timetable storage unit storing a received schedule timetable periodically transmitted from the central control device; a departure-obstructed condition determination unit determining whether a departure-obstructed condition of a train is resolved and outputting departure-obstructed condition cancel signal when the departure-obstructed condition is resolved; a departure time control unit outputting departure-time appropriate signal when current time is departure time based on the schedule timetable upon receiving the departure-obstructed condition cancel signal; a departure interval control unit outputting departure-interval appropriate signal when intervals between the train and preceding and following trains are a threshold value or more upon receiving the departure-time appropriate signal; and a departure instruction signal output unit outputting a departure instruction signal upon receiving the departure-interval appropriate signal, and, when the central control device fails, the departure time control unit uses the schedule timetable received when the central control device is normal.

In a method for operating a system having first and additional mobile parts and having a stationary controller, and a system for carrying out a method, the system has a connection between the controller and the first mobile part and between the controller and the additional mobile parts. The first mobile part detects and transmits to the controller its position and/or the position of its rear edge, and each additional mobile part detects and transmits to the controller its position and/or the position of its front edge. The controller determines the additional mobile parts most closely adjacent to and following the first mobile part and transmits the position and/or the position of the rear edge of the first mobile part to the additional mobile part. The following mobile part adds its braking distance, to which a safety distance and a safety range are added, to the position and/or to the front edge of the next-closest, following mobile part and monitors this calculated position for collision with the rear edge of the first mobile part.

In a method for operating a system having first and additional mobile parts and having a stationary controller, and a system for carrying out a method, the system has a connection between the controller and the first mobile part and between the controller and the additional mobile parts. The first mobile part detects and transmits to the controller its position and/or the position of its rear edge, and each additional mobile part detects and transmits to the controller its position and/or the position of its front edge. The controller determines the additional mobile parts most closely adjacent to and following the first mobile part and transmits the position and/or the position of the rear edge of the first mobile part to the additional mobile part. The following mobile part adds its braking distance, to which a safety distance and a safety range are added, to the position and/or to the front edge of the next-closest, following mobile part and monitors this calculated position for collision with the rear edge of the first mobile part.

A method and device for the diagnosing and monitoring vehicle components, wherein measurements with respect to a first measuring point, a second measuring point, a third measuring point and a fourth measuring point are performed and a first measured value set, a second measured value set, a third measured value set and a fourth measured value set are formed, where a reference value set is determined with respect to a reference point via the first measured value set, the second measured value set and the third measured value set, where a test value set is formed with respect to the fourth measuring point via the reference value set, and where a fault in or damage to the fourth sensor is detected by comparing the test value set with the fourth measured value set such that a high level of availability when used by a vehicle is achieved.

There is provided a train monitoring system using a train monitoring device that is mounted on a train and uses a plurality of cameras for imaging around the train from different sides. The train monitoring device includes a control unit that is configured to, when the train stops at a station, select one of the plurality of cameras as a rear imaging camera for imaging a rear side in a traveling direction of the train, after the train departs from the station, acquire image data imaged by the rear imaging camera, and transmit the image data to the outside.

There is provided a train monitoring system using a train monitoring device that is mounted on a train and uses a plurality of cameras for imaging around the train from different sides. The train monitoring device includes a control unit that is configured to, when the train stops at a station, select one of the plurality of cameras as a rear imaging camera for imaging a rear side in a traveling direction of the train, after the train departs from the station, acquire image data imaged by the rear imaging camera, and transmit the image data to the outside.

A system for enhancing personnel safety on a railroad track is presented. The system can receive data from sensors and/or a PTC system to determine positions of clients/worker and/or vehicles, and further utilize such data to determine if a vehicle is within a certain proximity of the client/worker location. The system can further generate geofences around clients/vehicles to and determine when such geofences intersect one another. Additionally, the present disclosure can assign severity levels and generate alerts with the assigned severity levels, and such severity levels can indicate how close a vehicle is to a particular location. It is an object of the invention to provide a system for generating alerts to notify personnel when they much retreat to a place of safety.