CN112612544B

CN112612544B - Data generation method of railway signal monitoring and maintenance system and operation terminal thereof

Info

Publication number: CN112612544B
Application number: CN202011548684.0A
Authority: CN
Inventors: 高雄; 涂鹏飞; 余亮星; 魏盛昕
Original assignee: Casco Signal Ltd
Current assignee: Casco Signal Ltd
Priority date: 2020-12-24
Filing date: 2020-12-24
Publication date: 2022-08-02
Anticipated expiration: 2040-12-24
Also published as: CN112612544A

Abstract

The invention discloses a data generation method of a railway signal monitoring and maintaining system, which comprises the following steps: and establishing interface configuration of the station according to the configuration information of the station of which the data is to be generated, and establishing equipment configuration, alarm configuration and graphical configuration which have association with each other by adopting the association between the objects, thereby automatically generating the configuration data of the railway signal centralized monitoring and maintaining system. The invention adopts the association among the objects to establish the association among the interface, the equipment, the alarm and the imaging, when a certain attribute of the interface or the equipment needs to be modified, the modified attribute can be synchronously modified in the alarm configuration and the imaging configuration, the interface, the equipment, the alarm and the imaging configuration do not need to be established again, and the accuracy and the efficiency of the system configuration data production are greatly improved.

Description

Data generation method of railway signal monitoring and maintenance system and operation terminal thereof

Technical Field

The invention relates to a railway signal centralized monitoring and maintaining system, in particular to a data generation method of a railway signal monitoring and maintaining system.

Background

With the development of national railways, the times of high-speed rail have come, so that the requirements on the stability and the safety of signal equipment are higher and higher, railway signal monitoring and maintenance systems are updated, and meanwhile, data needing to be collected are more and more complicated.

Disclosure of Invention

The invention provides a data generation method of a railway signal monitoring and maintenance system and an operation terminal thereof, which are used for realizing the automatic generation of configuration data of the railway signal monitoring and maintenance system and improving the accuracy and efficiency of system configuration data production.

In order to achieve the above object, the present invention provides a data generating method of a railway signal monitoring and maintaining system, including: and establishing interface configuration of the station according to the configuration information of the station of which the data is to be generated, and establishing equipment configuration, alarm configuration and graphical configuration which have association with each other by adopting the association between the objects, thereby automatically generating the configuration data of the railway signal centralized monitoring and maintaining system.

Further, the stations comprise newly-built stations and modified stations; if the station for generating data is a newly-built station, the configuration information of the station needs to be input; and if the station for generating the data is the reconstructed station, directly reading the configuration information of the station.

Further, the method for creating the interface configuration of the station includes:

adding or deleting interfaces of the station according to needs;

modifying the interface configuration of the station as required;

if a station interface is added, selecting a self-acquisition interface or an external interface as required;

if the interface configuration is modified, checking whether the interface is a self-acquisition interface or an external interface, and if the interface is the self-acquisition interface, directly configuring a standard data source on the interface and executing the standard data source; if the interface is an external interface, converting the data source on the interface into a data source which can be identified by the system, and then configuring the data source.

Further, the method for creating the device configuration includes: and automatically supplementing the equipment data acquired by different interfaces, extracting and analyzing the acquired data of the same equipment by different interfaces, thereby obtaining the association relationship between the equipment and the interfaces.

Further, the interfaces include, but are not limited to: the system comprises a communication extension interface, an interlocking interface, a ZPW2000A interface, a train control interface and a communication interface; such devices include, but are not limited to: switch machine equipment, track equipment, semaphore equipment and coding equipment.

Furthermore, if the device is a turnout switch device, relevant acquisition information is searched in the communication extension interface to judge the specific type of the turnout switch device, and then the relay state acquired by the interlocking interface is acquired by what type of turnout switch machine; if the equipment is track equipment, searching acquisition contents belonging to the track at a communication extension interface, an interlocking interface, a ZPW2000A interface and a train control interface, and then collecting the acquisition contents under different track equipment; if the device is a signal machine device, searching acquisition contents belonging to the signal machine in a communication extension interface and a filament interface, and then collecting the acquisition contents under different signal machine devices; if the device is a coding device, the content of the collection belonging to coding is searched in the communication extension interface and the ZPW2000A interface, and then the collections are gathered under different coding devices.

Furthermore, the equipment has the attribute of associating the interface to acquire data, the data acquired by different interfaces for the same equipment is extracted and filled into the attribute of the data acquired by the lower associated interface of the equipment to be associated, and the association relationship between the equipment and the interface can be obtained.

Further, the method for creating the device configuration further includes: modifying the equipment information as required; when modifying the device information, the device attributes are directly modified in the table of the device.

Further, the method for creating the alarm configuration comprises the following steps: and establishing alarm configuration by equipment configuration according to the configuration rule, and screening alarm logic rules as required so as to obtain the association relationship between the equipment and the alarm.

Further, the configuration rule is: alarm logic rules are correspondingly arranged on the equipment and the associated interfaces thereof, alarm configuration can be established by equipment configuration according to the configuration rules, and the association relationship between the equipment and the alarm is established.

Further, the method for creating the graphical configuration comprises the step of matching the graphic primitives and the equipment in the graphical configuration by adopting a regular expression, so as to obtain the association relationship between the equipment and the graphics.

Further, the method for creating the graphical configuration further comprises adding a new primitive as required; and when a new primitive needs to be added, exporting the new primitive to the csv file and then importing the new primitive to the system.

The invention also provides an operation terminal of the railway signal monitoring and maintaining system, which comprises a processor, a memory and a computer program stored on the memory and capable of being operated on the processor, wherein the processor executes the computer program to realize the data generation method.

The invention has the following advantages:

the invention adopts the association among the objects to establish the association among the interface, the equipment, the alarm and the imaging, when a certain attribute of the interface or the equipment is modified and then the configuration file is generated, the modified attribute can be synchronously modified in the alarm configuration and the imaging configuration without establishing the interface, the equipment, the alarm and the imaging configuration again, thereby greatly improving the accuracy and the efficiency of the system configuration data production.

Drawings

Fig. 1 is a flowchart of a data generation method of a railway signal monitoring and maintenance system provided by the invention.

Fig. 2 is a detailed flowchart of a data generation method of a railway signal monitoring and maintenance system provided by the present invention.

Detailed Description

The invention is described in further detail below with reference to the figures and specific examples. Advantages and features of the present invention will become apparent from the following description and from the claims. It is to be noted that the drawings are in a very simplified form and are all used in a non-precise ratio for the purpose of facilitating and distinctly aiding in the description of the embodiments of the invention.

The invention provides a data generation method of a railway signal monitoring and maintenance system, which comprises the following steps: the method comprises the steps of establishing interface configuration of a station according to configuration information of the station of which data is to be generated, and establishing equipment configuration, alarm configuration and graphical configuration which are related to each other by adopting the association between objects, so that the operation data of the railway signal centralized monitoring and maintaining system is automatically generated, and the verification and error correction functions are realized.

The invention adopts railway signal monitoring and maintenance system tool software (tool for short) as a manufacturing software tool of system data so as to provide a uniform user interaction interface to realize the standardized manufacturing process of system configuration data.

As shown in fig. 1, the data generating method of the railway signal maintenance system specifically includes the following steps:

1. selecting a station for generating data, and reading configuration information of the station; if the station is a newly built station, the user needs to input basic configuration information of the newly built station; if the station is a modified station, the tool automatically reads existing configuration information of the modified station.

In particular, in a railway signal monitoring and maintenance system, stations are usually represented by three-digit telegraph codes composed of letters or numbers, and configuration information of the stations is also placed under files named by the station telegraph codes. When selecting a station for generating data, a user can select according to the telegram code of the station, and if the station is a newly-built station, the user needs to input basic configuration information of the newly-built station; and if the station is a modified station, directly reading the file named by the station telegraph.

2. The user adds each interface matched with the station according to the actual situation on site and creates interface configuration data; the user can add or delete the interface of the station on the tool according to the requirement, and can configure the configuration data of different interfaces by importing an interface point table on the tool or inputting data on the tool interface; the interfaces include, but are not limited to: communication extension interface, interlock interface, ZPW2000A interface, train control interface and communication interface.

3. And automatically supplementing the equipment data collected by different interfaces to create equipment configuration and acquiring the association relationship between the equipment and the interfaces.

Further, the data collected by the interface can be split into seven main types according to different protocol analysis rules, wherein the main types are as follows: the switching value, the multi-state quantity, the analog quantity, the curve, the binary quantity, the counting quantity and the testing quantity are enumerated out as different sub-types by positive integers according to different purposes or meanings under each main type. Similarly, the devices can be divided into various main types, including intra-station sections, interval frequency shift, tracks, intra-station coding, turnouts, signal machines, power supply screens, external power grids, axle counters, shielding doors and the like, and the various main types of the devices are also subdivided into different sub-types according to different physical structures. The device also has attributes associated with the interface to collect data. When the equipment data collected by different interfaces is automatically supplemented, the interface collected data with the same equipment name and equipment main type in the data collected by all the interfaces are put together and filled into the attribute of the collected data of the lower related interface of the equipment to be related, and the association relation between the equipment and the interfaces can be obtained. Interface acquisition data describing the subtype of the device is found from the interface data, and the subtype of the device can be obtained to create the device configuration.

Specifically, for turnout switch equipment, the tool searches relevant acquisition information in the communication extension interface to judge the specific type (alternating current or direct current) of the turnout switch equipment, and further obtains the type of turnout switch machine which is used for acquiring the relay state acquired by the interlocking interface; for the rail equipment, the tool searches acquisition contents belonging to the rail in interfaces such as a communication extension interface, an interlocking interface, a ZPW2000A interface, a train control interface and the like, and then collects the acquisition contents to different rail equipment; for signal equipment, the tool searches for acquisition contents belonging to the signal in the communication extension interfaces and the filament interfaces, and then collects the acquisition contents to different signal equipment; for the coding device, the tool looks up the coded acquisition content in the communication extension interface and the ZPW2000A interface, and then aggregates the acquisition under different coding devices.

4. After the equipment is established, alarm configuration is automatically established by the equipment configuration according to the configuration rule, and the logic rule is screened as required to obtain the association relationship between the equipment and the alarm.

Further, the configuration specification is as follows: the railway signal monitoring and maintaining system is provided with an alarm template, wherein the alarm template lists a device type (comprising a device main type and a device sub type) corresponding to each alarm logic rule and a type (comprising a main type and a device sub type) of interface acquisition data associated with the device. The alarm logic of each device can be obtained according to the configuration rule, and on the basis, the alarm logic rule can be further manually screened according to needs, so that the alarm configuration is automatically established, and the association relationship between the devices and the alarm is established. The alarm configuration has associated device attributes to establish an association between a device and an alarm.

5. And creating graphical configuration, matching the graphic elements and the equipment in the graphical configuration by adopting a regular expression, and obtaining the association relation between the equipment and the graphics.

Further, the template in the tool lists the names of most primitives and the types and the matching rules of the names of the equipment, wherein the names of the primitives and the names of the equipment are described by regular expressions, so that the primitives and the equipment in the graphical configuration are matched, and the association relationship between the equipment and the graphics can be obtained. The graphical configuration has associated device attributes to establish an association between the device and the alarm.

Specifically, the graphical configuration comprises a plurality of primitives, when a new primitive is required, the new primitive is drawn through graphical editing software and exported to the csv file, and then the csv file is imported to the tool, so that the number of the primitives in the graphical configuration is matched with that of the equipment. When the primitive and the equipment are matched, if one equipment exists and the equipment type and the equipment name corresponding to the equipment and the primitive name are both accordant, the primitive and the equipment can be automatically associated, and then the primitive and the equipment are automatically associated, and if the primitive and the equipment cannot be automatically associated, the primitive and the equipment are manually associated. In the embodiment, the hmiMaker software is adopted to draw the station site primitives and the equipment primitives, all the primitives can be exported to the csv file, and when the csv file is imported into the tool, the tool can automatically filter repeated primitives.

6. Verifying the correctness of the configuration and generating configuration data of the system; and if the configuration verification is correct, directly generating the configuration data of the system, otherwise, returning to a certain step for correction according to the prompt information until the configuration verification is correct.

The interface configuration can be modified, if the interface configuration needs to be modified, the type of the interface is checked firstly, and if the interface is a self-acquisition interface, a standard data source is directly configured on a tool interface and executed; if the interface is an external interface, the data source on the interface is firstly converted into a data source which can be identified by the tool on the tool, and then the converted standard data source is imported and executed. The device configuration can also be modified, and when the device configuration is modified, the device attribute can be directly modified in the table of the device. In the invention, the correlation among the objects is adopted among the interfaces, the equipment, the alarms and the primitives, so any attribute in the interface configuration or the equipment configuration is modified, and then when the configuration file is generated, the modified attribute can be synchronously modified in the alarm configuration and the graphical configuration without establishing the interfaces, the equipment, the alarms and the graphical configuration again.

In addition, most of the names of the devices are written by users, and the name writing modes of different users for the same device are different, so that the requirements on the names of the devices are strict when the devices are associated with the graphics. The invention adopts the regular expression to describe the association relation between the graphics and the equipment, and developers only need to summarize the equipment naming modes of different users regularly, so that the maximum automatic association can be realized.

Further, as shown in fig. 2, the above steps 1 to 6 are specifically described as follows:

(001) starting, starting the tool;

(100) selecting a catalogue of a station;

(101) if the station is a modified station, selecting the existing configuration information of the modified station as an imported station directory;

(102) if the station is a newly built station, filling basic information of the newly built station, and generating a basic configuration directory of the newly built station as an imported station directory after the completion of the filling of the basic information;

(103) reading the configuration of the imported station directory;

(201) viewing the interface configuration;

(202) judging whether an interface needs to be added or deleted according to the actual situation on site; if so, executing step (203) or (204); otherwise, executing step (205);

(203) if a new interface needs to be added, selecting to add a self-acquisition interface or an external interface, and then returning to the step (202);

(204) if the existing interface needs to be deleted, the interface is selected for direct deletion, and then the step (202) is returned;

(205) judging whether the interface configuration needs to be modified or not according to the actual situation on site; if so, executing the step (206), otherwise, executing the step (301);

(206) selecting an interface needing to be modified and checking the classification of the interface, and if the interface is a self-acquisition interface, directly configuring a standard data source on the interface and executing the standard data source; if the interface is an external interface, converting the data source on the interface into a data source which can be identified by a tool, importing the converted standard data source, and executing the data source which can be identified by the system for reconfiguration; thereby generating interface configuration data, and then returning to step (205);

(301) viewing the device configuration;

(302) judging whether equipment needs to be updated or not; if so, executing step (303); otherwise, executing step (304);

(303) extracting and analyzing the collected information of the same equipment by all the interfaces to cover the existing equipment information, and then returning to the step (302);

(304) judging whether the equipment information needs to be modified or not; if so, executing the step (305); otherwise, executing step (401);

(305) modifying the device attributes directly in the device table, and then returning to step (304);

(401) checking alarm configuration;

(402) automatically or manually screening alarm logic;

(501) viewing the graphical configuration;

(502) judging whether a new primitive needs to be added or not; if so, executing the step (503), otherwise, executing the step (504);

(503) drawing the primitives by using graphical editing software, exporting all the primitives to a csv file, importing the csv file into a tool, and returning to the step (502);

(504) judging whether correlation imaging is needed; if so, executing the step (505), otherwise, executing the step (601);

(505) matching the associated graphics primitives with the equipment by adopting a regular expression;

(601) checking the correctness of the configuration, if the configuration is correct, executing a step (602), otherwise, returning to a certain step according to a prompt;

(602) generating system configuration data;

(002) and (6) ending.

The invention also provides an operation terminal of the railway signal monitoring and maintaining system, which comprises a processor, a memory and a computer program stored on the memory and capable of operating on the processor, wherein the processor executes the computer program to realize the data generation method.

It will be appreciated by those skilled in the art that embodiments of the present invention may be provided as a method or computer program product. Accordingly, the present invention may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present invention may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

The present invention is described with reference to flowchart illustrations and/or block diagrams of methods and computer program products according to embodiments of the invention. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

While the present invention has been described in detail with reference to the preferred embodiments, it should be understood that the above description should not be taken as limiting the invention. Various modifications and alterations to this invention will become apparent to those skilled in the art upon reading the foregoing description. Accordingly, the scope of the invention should be determined from the following claims.

Claims

1. A data generation method of a railway signal monitoring and maintenance system is characterized by comprising the following steps: interface configuration of the station is established according to configuration information of the station of which data is to be generated, and then, associated equipment configuration, alarm configuration and graphical configuration are established by adopting the association between objects, so that configuration data of the railway signal centralized monitoring and maintaining system are automatically generated;

the device configuration creating method comprises the following steps: automatically supplementing equipment data acquired by different interfaces, extracting and analyzing the acquired data of the same equipment by different interfaces, thereby obtaining the association relationship between the equipment and the interfaces;

the method for creating the alarm configuration comprises the following steps: establishing alarm configuration by equipment configuration according to the configuration rule, and screening alarm logic rules as required so as to obtain the association relationship between the equipment and the alarm;

the graphical configuration creating method comprises the step of matching a graphic element and equipment in the graphical configuration by adopting a regular expression so as to obtain the association relationship between the equipment and the graphics.

2. The data generation method of claim 1, wherein the stations include newly built stations and modified stations; if the station for generating data is a newly-built station, the configuration information of the station needs to be input; and if the station for generating the data is the reconstructed station, directly reading the configuration information of the station.

3. The data generating method of claim 1, wherein the method for creating the interface configuration of the station comprises:

adding or deleting interfaces of the station according to needs;

modifying the interface configuration of the station as required;

4. The data generation method of claim 1, wherein the method of creating the device configuration further comprises: modifying the equipment information as required; when modifying the device information, the device attributes are directly modified in the table of the device.

5. The data generating method of claim 1, wherein the method for extracting and analyzing the collected data of different interfaces for the same device comprises: the equipment has the attribute of associating the interface to acquire data, the data acquired by different interfaces for the same equipment are extracted and filled into the attribute of the data acquired by the lower associating interface of the equipment to be associated, and then the association relation between the equipment and the interface can be obtained.

6. The data generation method of claim 1, wherein the configuration rule is: alarm logic rules are correspondingly arranged on the equipment and the associated interfaces thereof, alarm configuration can be established by equipment configuration according to the configuration rules, and the association relationship between the equipment and the alarm is established.

7. An operation terminal of a railway signal monitoring and maintenance system, which comprises a processor, a memory and a computer program stored on the memory and operable on the processor, wherein the processor executes the computer program to realize the data generation method according to any one of claims 1 to 6.