A railway turnout control method comprises: constructing a data space corresponding to a railway turnout area (101); adding a virtual railway turnout, in the data space, to an area in which a target turnback stopping point is located (102); adding the virtual railway turnout to a railway turnout list corresponding to a route along which a train drives into the area (103); and not releasing claim of the virtual railway turnout when the train stops at the turnback stopping point (104); Also provided is a railway turnout control system. The method and system can solve problems of deadlock of a turnback area and insufficient safety protection of crossed routes.

A railway turnout control method comprises: constructing a data space corresponding to a railway turnout area (101); adding a virtual railway turnout, in the data space, to an area in which a target turnback stopping point is located (102); adding the virtual railway turnout to a railway turnout list corresponding to a route along which a train drives into the area (103); and not releasing claim of the virtual railway turnout when the train stops at the turnback stopping point (104); Also provided is a railway turnout control system. The method and system can solve problems of deadlock of a turnback area and insufficient safety protection of crossed routes.

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.

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.

A route control program generation device constructs a group of a plurality of environment models with different states in which the states of the plurality of environment models are changed in various manners. The environment model is constituted by a first moving body that is a control target and is present on a track divided into a plurality of sections, and a second moving body other than the control target, and searches for a state transition order where it is possible to achieve a request for causing the first moving body to move to a prescribed section by causing the first moving body to move to a destination while causing a state of one environment model to transition to a state of another environment model in response to the request. The route control program generation device constructs the group to match a prescribed restriction condition based on the restriction condition.

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.

In the present invention, a resource management device receives transmission of a reservation request for a block section to be reserved from among a plurality of block sections included in a track traveled by a vehicle on the basis of track information which indicates the plurality of block sections and the connection relationships of the block sections. In a case where the block section to be reserved, as indicated by the reservation request, has not already been reserved by a vehicle other than the vehicle that transmitted the reservation request at the point in time when such reservation request was received, the following is recorded in a management table: that the block section to be reserved as indicated by the reservation request and a connection boundary between that block section and another block section are objects reserved for the vehicle that transmitted the reservation request.

A collision avoidance system obtains movement indicative data of plural vehicles included in separate vehicle systems. The movement indicative data can be obtained from sensors onboard the vehicles. The system determines an identification of which of the vehicles are included in the separate vehicle systems based on the movement indicative data that are obtained and determines a collision risk between two or more vehicle systems of the separate vehicle systems based on the movement indicative data that are obtained and the identification of which of the vehicles are in the separate vehicle systems. The system automatically changes movement of at least one of the two or more vehicle systems responsive to determining the collision risk.

A collision avoidance system obtains movement indicative data of plural vehicles included in separate vehicle systems. The movement indicative data can be obtained from sensors onboard the vehicles. The system determines an identification of which of the vehicles are included in the separate vehicle systems based on the movement indicative data that are obtained and determines a collision risk between two or more vehicle systems of the separate vehicle systems based on the movement indicative data that are obtained and the identification of which of the vehicles are in the separate vehicle systems. The system automatically changes movement of at least one of the two or more vehicle systems responsive to determining the collision risk.

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.