A rail-bound track section is equipped with an automatic train protection system. The train protection system is a combined train protection system with the functionality of a first automatic train protection system and the functionality of a second automatic train protection system. The combined train protection system takes trains equipped with the second train protection system in the track section into account during a control of trains equipped with the first train protection system, and also takes trains equipped with the first train protection system in the track section into account during a control of trains equipped with the second train protection system. A method for operating a rail-bound track section equipped with an automatic train protection system is also provided.

A rail-bound track section is equipped with an automatic train protection system. The train protection system is a combined train protection system with the functionality of a first automatic train protection system and the functionality of a second automatic train protection system. The combined train protection system takes trains equipped with the second train protection system in the track section into account during a control of trains equipped with the first train protection system, and also takes trains equipped with the first train protection system in the track section into account during a control of trains equipped with the second train protection system. A method for operating a rail-bound track section equipped with an automatic train protection system is also provided.

A method and system for managing traffic of guided vehicles over a railway network include a first ATS system for regulating traffic of guided vehicles over a first regulation domain of the network and a second ATS system configured for regulating traffic of guided vehicles over a second regulation domain. The regulation domains have a common boundary and at least one track connects a first position within the first regulation domain to a second position within the second regulation domain. The second ATS system detects limited traffic capacity at the second position and automatically computes, as a function of the detected limited traffic capacity, a target headway between two successive guided vehicles crossing the common boundary for entering the second regulation domain. The first ATS system automatically determines, from the received target headway, a reference timetable, complying with the received target headway, for the first regulation domain.

A method and system for managing traffic of guided vehicles over a railway network include a first ATS system for regulating traffic of guided vehicles over a first regulation domain of the network and a second ATS system configured for regulating traffic of guided vehicles over a second regulation domain. The regulation domains have a common boundary and at least one track connects a first position within the first regulation domain to a second position within the second regulation domain. The second ATS system detects limited traffic capacity at the second position and automatically computes, as a function of the detected limited traffic capacity, a target headway between two successive guided vehicles crossing the common boundary for entering the second regulation domain. The first ATS system automatically determines, from the received target headway, a reference timetable, complying with the received target headway, for the first regulation domain.

A test support method includes a step of obtaining a pre-change image and a post-change image to be displayed on a monitoring and control system, a step of extracting, from the post-change image, multiple symbols that have changed from corresponding symbols in the pre-change image, a step of adding order information to the multiple symbols extracted, and a step of outputting a test image in which the order information is added to the multiple symbols.

Various methods and systems are provided for a railyard system. In one example, a method for managing a railyard comprises, within the railyard, positioning a cargo unit on a multi-directional pad and moving the pad multi-directionally based on a requested order for the cargo unit relative to other cargo units, where the requested order corresponds to an order of cargo units on railcars of an outbound train. The multi-directional pad may operate within an arena, where the arena includes a concrete surface depressed into the ground such that a surface of the pad is level with a surface of the ground surrounding the arena, thereby allowing railcars to be pushed onto the pad by a locomotive of a train.

Various methods and systems are provided for a railyard system. In one example, a method for managing a railyard comprises, within the railyard, positioning a cargo unit on a multi-directional pad and moving the pad multi-directionally based on a requested order for the cargo unit relative to other cargo units, where the requested order corresponds to an order of cargo units on railcars of an outbound train. The multi-directional pad may operate within an arena, where the arena includes a concrete surface depressed into the ground such that a surface of the pad is level with a surface of the ground surrounding the arena, thereby allowing railcars to be pushed onto the pad by a locomotive of a train.

A method for operating rail vehicles in an operational area of a traffic network that is shared with traffic participants other than the rail vehicles. The rail vehicles communicate with line elements arranged in the operational area. Here, the rail vehicles and the line elements use a V2X standard for communication between each other within the shared operational area. In an operational area that is reserved for the rail vehicles, the rail vehicles communicate with the line elements via a communication standard that is different from the V2X standard.