A particularly flexible method for automatically calibrating a wheel sensor includes using the wheel sensor to determine that a calibration must be carried out. The wheel sensor determines a point in time suitable for carrying out the calibration and the calibration itself is carried out by the wheel sensor at the determined point in time. A wheel sensor for carrying out the method is also provided.

A method and a system determine a subsequent number of guided vehicles occupying a track section of a railway network. The system has a trackside device configured for controlling and managing a movement authority of a guided vehicle for a track section and at least one neighboring trackside device. Each neighboring trackside device is configured for controlling and managing a movement authority for a directly neighboring track section. The trackside device is configured for calculating the subsequent number of guided vehicles from a number of guided vehicles occupying the track section previously determined by the trackside device and information received from each neighboring trackside device regarding a number of guided vehicles entering, from the track section. The directly neighboring track section is controlled by the neighboring trackside device and a number of guided vehicles leaving the directly neighboring track section for the track section.

Provided is a wheel detector for detecting a wheel of a rail vehicle, including two detector channels. Each channel includes a coil unit which is connected with a measurement and feeding module for feeding the coil unit with an output signal of the measurement and feeding module. A decision module of the respective channel is bi-directionally connected to the measurement and feeding module. The measurement and feeding module of each channel includes a temperature measurement module and/or a module for measurement of mechanical vibration, that is/are connected with an input/inputs of a decision module of the channel. The decision modules are connected via a bidirectional digital interface. The decision module of one channel is connected via a bidirectional digital interface with a data transmission module for communication with a supervisory system via a data transmission line.

A particularly flexible method for automatically calibrating a wheel sensor includes using the wheel sensor to determine that a calibration must be carried out. The wheel sensor determines a point in time suitable for carrying out the calibration and the calibration itself is carried out by the wheel sensor at the determined point in time. A wheel sensor for carrying out the method is also provided.

A method and a system determine a subsequent number of guided vehicles occupying a track section of a railway network. The system has a trackside device configured for controlling and managing a movement authority of a guided vehicle for a track section and at least one neighboring trackside device. Each neighboring trackside device is configured for controlling and managing a movement authority for a directly neighboring track section. The trackside device is configured for calculating the subsequent number of guided vehicles from a number of guided vehicles occupying the track section previously determined by the trackside device and information received from each neighboring trackside device regarding a number of guided vehicles entering, from the track section. The directly neighboring track section is controlled by the neighboring trackside device and a number of guided vehicles leaving the directly neighboring track section for the track section.

Provided is a wheel detector for detecting a wheel of a rail vehicle, including two detector channels. Each channel includes a coil unit which is connected with a measurement and feeding module for feeding the coil unit with an output signal of the measurement and feeding module. A decision module of the respective channel is bi-directionally connected to the measurement and feeding module. The measurement and feeding module of each channel includes a temperature measurement module and/or a module for measurement of mechanical vibration, that is/are connected with an input/inputs of a decision module of the channel. The decision modules are connected via a bidirectional digital interface. The decision module of one channel is connected via a bidirectional digital interface with a data transmission module for communication with a supervisory system via a data transmission line.

The invention relates to a method for controlling the circulation of vehicles in a network controlled by a control system managing the circulation of communicating vehicles according to a first mode, the first mode managing the movement of the communicating vehicle toward the end terminal of a first section in which a non-communicating vehicle has been detected by implementing a discrimination step eliminating any protection zone located the moving vehicle, when a distance between the communicating vehicle and said end terminal is smaller than a threshold, the method comprising switching into a second mode, when the communicating vehicle enters the first section, the second mode inhibiting the implementation of the discrimination step at least in the first section.

A method for operating an axle counter system for monitoring the occupation status of a track section being limited by counting positions which have at least one detection point and at least one counting position a set of redundant detection points, includes the steps of: (a) incrementing or decrementing axle counter values in dependence of the moving direction of a passing axle; (b) transmitting the axle counter value to an axle counter evaluator; (c) determining the number of remaining axles within the track section; and (d) outputting a track occupation status. Prior to step (c) for each counting position exactly one detection point is selected for further processing independent of the selection at any other counting position. In step (c) the counter values of the selected detection points are used for determining the number of remaining axles and the counter values of the non-selected redundant detection points are ignored.