GLOBAL TRAIN-LOCALIZATION SYSTEM

Abstract

The present disclosure relates to a global train-localization system. The system may autonomously send a precise location of a train to effectively cope with train location recognition in a case of various faults or degradations. The localization system includes: a backup localization unit installed on the train and configured to read beacon location information on a track; and a global train-localization system (GTS) server configured to receive, store and convert train localization information sent by the backup localization unit and to perform output and display. Compared to the prior art, the present disclosure has the advantages of effectively coping with system degradation, namely, tracking the location of the train in real time even in a case of complete fault of a signal system, etc.

Description

TECHNICAL FIELD

The present disclosure relates to a train localization system, in particular to a global train-localization system.

BACKGROUND

In most of current communication based train control (CBTC) systems, a system architecture based on axle counter equipment and interlocking equipment is used. There are two ways of train localization as follows:

1) active reporting, where a train calculates its precise location according to a distance of train operation by reading a wayside beacon; and

2) passive detection, where the occupation of the train in a section is detected via a track circuit or axle counter equipment to indirectly obtain the location of the train, it only can be recognized that the train is in a certain section, and the precise location of the train cannot be obtained.

In general, the train actively reports its location. Once active reporting cannot be completed, passive indirect detection may be performed. However, both the active reporting and the passive detection are completed in a case where equipment for location detection has no fault. In a case of the following degradation, the system cannot obtain the location of the train, and once the system cannot determine the location of the train, train operation will be impossible, which causes a greater impact on the operation, where the degradation includes:

1) axle counter equipment has a fault;

2) interlocking equipment has a fault; or

3) main carborne equipment has a fault.

In addition, precise train localization is only limited to single line or some lines with interconnection and interworking conditions. If the train transfers to other line, it cannot send its precise localization information; and engineering trains or special trains also cannot be precisely localized.

SUMMARY

To overcome the above defects existing in the prior art, an objective of the present disclosure is to provide a global train-localization system.

The objective of the present disclosure may be achieved through the following technical solution:

According to one aspect of the present disclosure, a global train-localization system is provided. The system may autonomously send a precise location of a train to effectively cope with train location recognition in a case of various faults or degradations. The localization system includes:

a backup localization unit installed on the train and configured to read beacon location information on a track; and

a global train-localization system (GTS) server configured to receive, store and convert train localization information sent by the backup localization unit and to perform output and display.

As a preferred technical solution, the backup localization unit is a set of localization processing system independent of a carborne system, includes an independent power supply and an independent ring network, and is connected to the GTS server by means of a redundant wireless network.

As a preferred technical solution, the backup localization unit is connected to a beacon antenna to upload the read beacon location information to the GTS server via a train-ground wireless link.

As a preferred technical solution, the uploaded information includes a train number, a beacon number, and a line number.

As a preferred technical solution, the localization system may achieve single-line-level train location tracking and line-network-level train location tracking.

As a preferred technical solution, the single-line-level train location tracking is specifically achieved as follows:

all trains on a single line are equipped with backup localization units to achieve location tracking of all the trains; and

meanwhile a control center is configured with a set of GTS server to receive localization information of the trains and perform real-time display on a display terminal.

As a preferred technical solution, all the trains include electric passenger trains, engineering trains, or special trains.

As a preferred technical solution, the line-network-level train location tracking is specifically achieved as follows: line configuration is set in a unified way at a line network level to achieve the line-network-level train location tracking.

As a preferred technical solution, the setting specifically includes:

setting beacon identities (IDs) of beacons in a unified way according to the number of beacons on different lines;

setting a unified interface protocol;

dividing, by the backup localization unit, different network segments according to the lines, and setting a network address in a unified way; and

cascading single-line-level GTS servers to achieve line-network-level train localization and real-time tracking.

As a preferred technical solution, the setting a unified interface protocol includes: setting a protocol between the backup localization unit and the beacon antenna; setting a protocol between the backup localization unit and the GTS server; and setting a protocol between a beacon message and a code.

Compared to the prior art, the present disclosure has the following advantages:

1) System degradation is effectively coped with, namely, the location of the train can be tracked in real time even in a case of complete fault of a signal system (including an interlocking system, an axle counter or track circuit, a carborne automatic train control (ATC) or automatic train supervision (ATS) system).

2) Interconnection and interworking and carborne equipment, namely, backup localization units (BLUs) are interchanged, which effectively solves the problem that the precise location of the train in transfer operation cannot be obtained.

3) Powerful functions are achieved, and a global dispatching and command platform may achieve unified command of a single line level and a line network level.

4) High redundancy is achieved, and high reliability of the system is achieved by arranging an independent redundant wireless unit, the independent power supply, and the independent ring network.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic structural diagram of the present disclosure;

FIG. 2 is a schematic diagram of single-line-level global train-localization system (GTS) configuration;

FIG. 3 is a schematic diagram of line-network-level GTS configuration; and

FIG. 4 is a schematic diagram of a specific example of the present disclosure.

DETAILED DESCRIPTION OF THE EMBODIMENTS

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present disclosure. Apparently, the described embodiments are part rather than all of the embodiments of the present disclosure. All other embodiments obtained by those of ordinary skill in the art based on the embodiments of the present disclosure without creative efforts should fall within the scope of protection of the present disclosure.

A global train-localization system (GTS) in the present disclosure is configured for line-network-level train localization and tracking. A train equipped with the GTS may autonomously send a precise location of a train to effectively cope with train location recognition in a case of various faults or degradations.

As shown in FIG. 1, the global train-localization system mainly includes the following equipment:

1) a backup localization unit (BLU) that is installed on the train, is a set of localization processing system independent of a carborne system, is connected to a beacon antenna, and is configured to read beacon location information on a track and to upload the information to the ground via a train-ground wireless link, where the uploaded information includes a train number, a beacon number, and a line number; and

2) a global train-localization system (GTS) server configured to receive, store and convert train localization information sent by the BLU and to perform output and display.

The GTS may achieve single-line-level train location tracking and line-network-level train location tracking.

1) As shown in FIG. 2, a single line level is specifically as follows:

all trains on a single line are equipped with GTSs to achieve location tracking of all the trains (including electrical passenger trains, engineering trains, or other special trains); and

a control center is configured with a set of GTS server to receive localization information of the trains and perform real-time display on a GTS display terminal.

2) As shown in FIG. 3, a line network level is specifically as follows: Line configuration is planned in a unified way at the line network level to achieve line-network-level train location tracking. The planning includes the following aspects:

planning identities (IDs) of beacons in a unified way according to the number of beacons on different lines;

unifying interface protocols including a protocol between the BLU and the beacon antenna, a protocol between the BLU and the GTS server, and a protocol between a beacon message and a code;

dividing, by the BLU of the train, different network segments according to the lines, and planning a network address in a unified way; and

cascading single-line-level GTS servers to achieve line-network-level train localization and real-time tracking.

This example is one of application scenarios of the GTS. This scenario is an example where a train A is manually driven, degraded and unserviceable and an axle counter section has a fault.

1) During the manual driving of the train, since the GTS is independent of the carborne system and obtains the location of the train via the beacon, the train sends the localization information in real time under normal circumstances, and the train is between a beacon 1 and a beacon 2.

2) After the train crosses the beacon 2, the system recognizes that the train is between the beacon 1 and a beacon 3, and the axle counter section in the front is occupied due to the fault.

3) After the train enters the faulty axle counter section, the system may recognize that the train is between the beacon 3 and a beacon 4; and in the absence of the GTS, a signal system cannot recognize the specific location of the train, or even whether the train is in the faulty section.

4) The train continues to operate in the faulty section. After the train crosses a beacon 5, the system may recognize that the train is between the beacon 4 and the beacon 5.

The above is only the specific implementation of the present disclosure, but the scope of protection of the present disclosure is not limited thereto. Any of those skilled in the art may easily think of various equivalent modifications or substitutions within the technical scope of the present disclosure, and these modifications or substitutions should be included in the scope of protection of the present disclosure. Therefore, the scope of protection of the present disclosure should be subject to the appended claims.

Claims

1. A global train-localization system, the system being capable of autonomously sending a precise location of a train to effectively cope with train location recognition in a case of various faults or degradations, the localization system comprising: a backup localization unit installed on the train and configured to read beacon location information on a track; anda global train-localization system (GTS) server configured to receive, store and convert train localization information sent by the backup localization unit and to perform output and display.

2. The global train-localization system according to claim 1, wherein the backup localization unit is a set of localization processing system independent of a carborne system, comprises an independent power supply and an independent ring network, and is connected to the GTS server by means of a redundant wireless network.

3. The global train-localization system according to claim 1, wherein the backup localization unit is connected to a beacon antenna to upload the read beacon location information to the GTS server via a train-ground wireless link.

4. The global train-localization system according to claim 3, wherein the uploaded information comprises a train number, a beacon number, and a line number.

5. The global train-localization system according to claim 1, wherein the localization system may achieve single-line-level train location tracking and line-network-level train location tracking.

6. The global train-localization system according to claim 5, wherein the single-line-level train location tracking is specifically achieved as follows: all trains on a single line are equipped with backup localization units to achieve location tracking of all the trains; andmeanwhile a control center is configured with a set of GTS server to receive localization information of the trains and perform real-time display on a display terminal.

7. The global train-localization system according to claim 6, wherein all the trains comprise electric passenger trains, engineering trains, or special trains.

8. The global train-localization system according to claim 5, wherein the line-network-level train location tracking is specifically achieved as follows: line configuration is set in a unified way at a line network level to achieve the line-network-level train location tracking.

9. The global train-localization system according to claim 8, wherein the setting specifically comprises: setting beacon identities (IDs) of beacons in a unified way according to the number of beacons on different lines;setting a unified interface protocol;dividing, by the backup localization unit, different network segments according to the lines, and setting a network address in a unified way; andcascading single-line-level GTS servers to achieve line-network-level train localization and real-time tracking.

10. The global train-localization system according to claim 9, wherein the setting a unified interface protocol comprises: setting a protocol between the backup localization unit and a beacon antenna; setting a protocol between the backup localization unit and the GTS server; and setting a protocol between a beacon message and a code.