The present invention relates to a train travel prediction device and a train travel prediction method.
In the past, as a technique of predicting an operation status of a train in future, there has been a technique of performing a precise prediction by calculating a train moving state on the basis of a signal condition or a technique of performing a prediction by simply adding a station-to-station required time and an arrival-departure time interval. In the former technique, prediction precision is high, but a calculation time is long. In the latter technique (the unit of station prediction), prediction precision is low, but a calculation time is short.
In the unit of station prediction, a station-to-station travel time and a station stop time are sequentially added to a departure time and an arrival time from a prior side in terms of time so as to calculate an arrival time and a departure time of the next station. For example, when a departure time of a precedent train is delayed, a time obtained by adding a last station departure time of a subsequent train to a minimum travel time between the stations is compared with a time obtained by adding a next station departure time of the precedent train to a minimum arrival-departure time interval and a calculation is performed while the later time is set as a next station arrival time of the subsequent train.
Patent Literature 1: Japanese Patent No. 2715647
However, according to the above-described related art, the train moving state is not accurately considered.
For that reason, since the minimum arrival-departure time interval is determined as a predetermined value, a problem arises in that an error may occur in accordance with an operation of an actual train.
The present invention is made in view of the above-described circumstances and an object of the present invention is to obtain a train travel prediction device and a train travel prediction method capable of improving operation prediction precision by a prediction performed by the unit of station without causing an increase in calculation time.
To solve the above described problem and achieve the object, a train travel prediction device according to the present invention includes: a required time storage unit that records a required timetable created in advance between stations and indicating a relation of a time difference between a last station departure time of a target train and a next station departure time of a precedent train with respect to a required time of the target train to a next station by the use of a train simulation on the basis of a train moving condition; and an operation prediction unit that creates a prediction schedule on the basis of information of a required time acquired for each target train during a prediction period by referring to the required timetable recorded in the required time storage unit on the basis of information of a train schedule and a train arrival-departure time.
According to the present invention, there is an effect in which the operation prediction precision can be improved by the prediction performed by the unit of station prediction without causing an increase in calculation time.
Hereinafter, an embodiment of a train travel prediction device and a train travel prediction method according to the present invention will be described in detail with reference to the drawings. Further, the present invention is not limited to the embodiment.
In the train travel prediction device 10, the operation prediction unit 11: refers to the required time DB 12 on the basis of a train schedule acquired from the operation management system 20 and an arrival-departure record of a train to each station until a current time point; acquires a required time corresponding to a departure time difference of a station of a target train from the required timetable stored in the required time DB 12; predicts the operation of the train after the current time point; creates a prediction result (a prediction schedule); and outputs the prediction result to the operation management system 20.
The operation management system 20 traces the position information detected by the position detection device 40 and creates the arrival-departure record of the train to and from the station. The operation management system 20 receives a predetermined train schedule from the train schedule DB 30 and corrects or changes an arrival-departure order if necessary.
The train schedule DB 30 is a database which stores a train schedule of a target track in the operation management system 20.
The position detection device 40 detects a train position by a track circuit or the like from an actual train system and notifies the operation management system 20 of the train position information.
Subsequently, a train travel prediction method which is performed by the unit of station prediction using the train travel prediction device 10 will be described.
In order to clarify a difference between the present invention and the related art, the prediction performed by the unit of station prediction of the related art will be described first and the principle of the prediction performed by the unit of station prediction of the present embodiment will be described next.
B on the assumption that a train 1 indicates a precedent train and a train 2 indicates a subsequent train. As described in the background art, when the departure time of the train 1 as the precedent train at the station B is delayed, a time obtained by adding a minimum travel time between the station A and the station B to the departure time of the train 2 as the subsequent train at the station A is compared with a time obtained by adding a minimum arrival-departure time interval to the departure time of the precedent train and a calculation is performed while the later time is set as the arrival time of the train 2 as the subsequent train at the station B. However, in this method, since the minimum arrival-departure time interval is uniform, an error occurs in accordance with the operation of the actual train.
In the present embodiment, the operation of the train is calculated in advance with high precision in consideration of a train moving condition, a signal condition, and the like and a table (a required timetable) representing a relation between the departure time difference and the minimum arrival-departure time interval is created. Accordingly, it is possible to obtain a more accurate train operation prediction result by obtaining an appropriate minimum arrival-departure time interval from the departure time difference of the station when the prediction is performed by the unit of station prediction later. Further, when the prediction is performed by the unit of station prediction, only the previously created table (the required timetable) may be referred to without causing an increase in calculation time.
As illustrated in
In the required time DB 12, the same station-to-station required timetable is prepared in at least every station-to-station zone. However, a plurality of the station-to-station required timetables may be prepared in the same station-to-station zone in response to, for example, a speed limit between the stations, a travel pattern, a train performance, and the like. In the operation prediction unit 11, an appropriate station-to-station required timetable may be selected and referred to, from the station-to-station required timetables between the stations in response to a set speed limit between the stations, a travel pattern, a train performance, and the like.
When there is a train which departs from the station A, passes through the station B, and arrives at the station C, the required timetable between the station A to the station C may be prepared. Otherwise, the required timetable between the train departs from the station A and passes through the station B may be prepared; or the required timetable between the train passes passing through the station B and arrives at the station C may prepared. In this case, the operation prediction unit 11 uses a combination of the required timetable between the train departs from the station A and passes through the station B, and the required timetable between the train passes passing through the station B and arrives at the station C.
In the present embodiment, the required timetable for every station-to-station is created in advance and is stored in the required time DB 12. As the operation prediction unit 11 acquires the information of the required time from the required time DB 12 on the basis of the arrival-departure record and the train schedule acquired from the operation management system 20, the information of the required time of the target train (the subsequent train) to the next station can be obtained with high precision.
Although not illustrated in
The operation prediction unit 11 starts the prediction by using the arrival-departure time of the station of the target train at the current time of the prediction start time point. However, when the prediction period is long, the prediction is continued by using the information of the required time of each train predicted by the own device.
In the operation prediction unit 11, as illustrated in
The operation management system 20 can show an operator, who handles the operation management system 20, the influence of the disordered schedule and the way how the disordered schedule is restored when the train schedule is in disorder by obtaining the prediction result (the prediction schedule) from the operation prediction unit 11. The operator can take countermeasures against the disordered schedule by obtaining the prediction schedule predicted with high precision in a short time.
Further, when the information of the train schedule is output from the operation management system 20 to the operation prediction unit 11, for example, information representing a change in train operation order may be output on purpose. Accordingly, the operation prediction unit 11 can create and output the prediction schedule in response to the request from the operation management system 20.
As described above, according to the present embodiment, the train travel prediction device 10 includes the required time DB 12 which records the required timetable created in advance between the stations and indicating a relation of the time difference between the last station departure time of the target train and the next station departure time of the precedent train with respect to the required time of the target train to the next station by the use of a train simulation on the basis of the train moving condition. Then, the operation prediction unit 11: refers to the required timetable recorded in the required time DB 12 on the basis of the information of the train arrival-departure time and the train schedule acquired from the operation management system; acquires the station-to-station required time corresponding to the departure time difference of the station of the target train from the station-to-station required timetable; and creates the prediction schedule on the basis of the information of the required time acquired for each target train during the prediction period. Accordingly, the prediction can be performed by the unit of station prediction for the train at a high speed with high precision.
As described above, the train travel prediction device and the train travel prediction method according to the present invention are useful to manage the operation of the train and are suitably used particularly when the train schedule is in disorder.
10 train travel prediction device, 11 operation prediction unit, 12 required time database (DB), 20 operation management system, 30 train schedule database (DB), 40 position detection device.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2014/061181 | 4/21/2014 | WO | 00 |