CN113505184B - Method for automatically generating information relation graph between systems and storage medium - Google Patents

Abstract

The invention discloses an automatic generation method of an intersystem information relationship diagram and a storage medium. The method comprises the following steps: 1) according toDrawing a tree diagram of the composition structure of the target system by using the composition structure of the target system; 2) generating a two-dimensional information interaction relation matrix according to exchange information among subsystems related in a composition structure tree diagram of the target system and among the subsystems and other related systems except the target system; wherein the elements in the first row of the information interaction relationship matrix are the source systems of the information interaction relationship, the elements in the first column are the destination systems of the information interaction relationship, and if the source systems in the jth column have data to transmit to the destination systems in the ith row, the elements a in the ith row and the jth column of the information interaction relationship matrix are_ijFilling corresponding interactive information in; 3) importing the information interaction relation matrix into a general design tool to generate an information interaction relation table; 4) and generating an information interaction relation graph of the system according to the generated information interaction relation table.

Description

Method for automatically generating information relation graph between systems and storage medium

Technical Field

The invention belongs to the field of information-based construction and complex information system architecture design, and particularly relates to an automatic generation method of an intersystem information relationship diagram and a storage medium.

Background

With technological progress, especially with the vigorous development and popularization of information technology, a large number of systems which are large-scale, complex, independent and interdependent become important supports for social operations. The systems form a complex information system with extremely complex system composition and information relationship, and can be scientifically, continuously and healthily developed only by planning, designing, researching and developing, integrating, deploying and optimizing and expanding according to objective rules of system engineering. The architecture design is an effective method for developing the top-level design of a complex information system, and the information relation design is the core of the architecture design. At present, some methods and tools can support and develop The design work of The information system Architecture, for example, The national Defense Architecture Framework (DoDAF) is a mature method in The field of military information systems, and The Open Group Architecture Framework (TOGAF) is a mature method in The field of civil information systems.

However, the existing information system architecture design methods are very complicated, the tool automation capability is insufficient, and the design of a complex information relationship is difficult to support well. For example, the DoDAF2.0 carries out architecture design through 52 models with 8 types of visual angles such as the overall situation, data and information, standards, capabilities, battles, services, systems and projects, the TOGAF9.0 carries out architecture design through 49 models with 4 types of architectures such as services, data, applications and technologies, the design content is extremely complex and tedious, and the emphasis point is lacked. The traditional system structure design tool can not automatically generate an information relation graph and can not simply represent the information relation, so that the system information relation is unclear and the usability is poor. Therefore, the above method has difficulty in solving the overall design problem of the complex information system.

The design of information relationship is the central importance of the overall design of a complex information system, and aims to describe the interface relationship and the action mechanism among all systems within a certain boundary range. The interconnection relationship among all the components is determined through the overall design, the research and development construction of all the components can be rigidly restricted, and the effective integration of all the components can be ensured. The method can automatically generate the information relation graph between any systems, and can liberate informatization construction workers from repeated and heavy information relation carding, graph drawing and other works, so that powerful support is provided for the existing system information relation carding and newly-built system information relation design in the complex information system construction process, the design efficiency is greatly improved, and the reusability and the expandability of design results are improved.

Disclosure of Invention

The invention provides an automatic generation method of an information relation diagram between systems aiming at the problems of the structural design of a complex information system, which automatically generates the information relation diagram between subsystems in the system or between the system and the subsystem and an external system thereof on the premise of the known system composition structure and the mutual information between every two systems, can flexibly and freely screen and combine the systems according to the requirements, automatically generates the corresponding information relation diagram and supports and forms the overall design methodology of the complex information system based on the information relation.

The technical scheme of the invention is as follows:

a method for automatically generating an information interaction relationship graph among systems comprises the following steps:

1) drawing a tree diagram of the composition structure of the target system according to the composition structure of the target system;

2) generating a two-dimensional information interaction relation matrix according to interaction information among subsystems related in a composition structure tree diagram of the target system and among the subsystems and other related systems except the target system; the cell represents the interactive information content transmitted from the source system corresponding to the column to the destination system corresponding to the row;

3) importing the information interaction relation matrix into a general design tool to generate an information interaction relation table; then, automatically laying out the system and the interactive relation connecting line by adopting an automatic layout algorithm to generate an information interactive relation graph; the automatic layout algorithm comprises the following steps:

a) the overall design tool analyzes the row header of the information interaction relation table, circulates row header data and creates system objects with the same name; then analyzing the list head of the information interaction relation list, circulating the list head data, excluding the created system object according to the name, and creating the system object which is not matched with the name;

b) the overall design tool sets the coordinate points of the first system object and the length and width of the system object; then sequentially determining the ordinate = the ordinate + of the last system object + of a fixed value, and the abscissa = the abscissa + of the last system object + of a fixed value;

c) the overall design tool analyzes the cells of the information interaction relation table, judges whether the cells have data or not, if so, creates an information interaction relation line, sets a source and a target of the current information interaction line according to a source system and a target system corresponding to the current cells, and otherwise, circularly judges the data condition of the next cell; the starting point of the information interaction relationship line represents a source system, the system indicated by the arrow is a target system, and the online display content corresponds to the interaction information between the two systems;

d) setting a source reference point and a target reference point for each information interaction relation line according to the positions of a source system and a target system connected with the information interaction relation line; then, according to the source reference point and the target reference point, determining a break point of the information interaction relation line, wherein the abscissa of the break point = the abscissa of the target reference point + the abscissa of the target system, and the ordinate of the break point = the ordinate of the source reference point + the ordinate of the source system;

e) acquiring a source connecting line and a target connecting line on each system object; sequencing the source connecting lines and the system objects to ensure that the connecting lines of the same target system or the same source system cannot be displayed in a crossed manner; the source connecting line on the system object is a connecting line of the system object as a starting point of the information interaction relation line, and the target connecting line on the system object is a connecting line pointed by an arrow of the system object as the information interaction relation line;

f) and recalculating the positions of the source reference point and the target reference point, and uniformly arranging all information interaction relationship lines to obtain an information interaction relationship diagram of the target system.

Furthermore, if there are multiple interactive messages between two systems corresponding to a cell element, the different messages in the cell element are separated by a semicolon.

Further, the overall design tool sets a background color for the corresponding system according to the background color of the system in the "system composition description" of the overall design tool.

Further, the length and the width of each system object are the same.

Further, if the source system is above the destination system, the source reference point is (width, height/2), the destination reference point is (width/2, 0), if the source system is below the destination system, the source reference point is (0, height/2), the destination reference point is (width/2, height); wherein height is the height of the system object and width is the width of the system object.

Further, the overall design tool edits the information interaction relation table, and then automatically synchronizes the edited content to the corresponding elements of the information interaction relation chart.

Furthermore, the overall design tool screens the systems according to the needs of the users, and automatically generates an information interaction relation table among the screened systems after screening, wherein the method comprises the following steps:

1) clearing a row table head, a list table head and cell data of the information interaction relation table;

2) analyzing the selected row data after the data screening; judging whether the line data is marked as full selection; if yes, the row header presents all system objects; if the name is not the same as the system name in the system, circulating the data, matching the data with the system name in the system according to the name, if the data is matched, displaying the data in a row table header, and if the data is not matched, not displaying the data;

3) analyzing the selected column data after data screening; judging whether the column data is marked as full selection; if yes, the list head presents all system objects; if the name is not matched with the system name in the system, the circular column data is matched with the system name in the system, if the name is matched with the system name, the circular column data is displayed in the head of the list, and if the name is not matched with the system name, the circular column data is not displayed;

4) analyzing the information interaction relation in the circulating system, and analyzing a source object and a target object of the information interaction relation; then judging whether the name of the target object is matched with the head name of the row table in the table; if not, continuing the next cycle; if the names of the source objects are matched with the names of the list heads in the list, judging whether the names of the source objects are matched with the names of the list heads in the list, if not, continuing the next circulation, and if so, displaying the corresponding interactive information in the information interactive relation in the cells corresponding to the list heads and the list heads.

Further, the target system is a court information system; the system object is a parent system, a subsystem or other related system outside the target system in the target system composition structure tree.

Further, firstly integrating a plurality of subsystems in the target system into a new subsystem, and then generating the information interaction relation table; the method comprises the following steps:

1) acquiring system data of each subsystem to be integrated;

2) inputting a subsystem name D generated after integration;

3) verifying whether the subsystem D is repeated with the existing subsystem name or not, and if so, automatically generating the subsystem name D in a form of adding a 'copy'; if not, generating a new subsystem D;

4) acquiring all information interaction relation data in a target system;

5) circulating the first information interaction relation data M to obtain a source system and a target system of the information interaction relation data;

6) verifying whether each subsystem to be merged contains a source system and a target system of the information interaction relationship data at the same time, if so, continuing to circulate next information interaction relationship data, otherwise, verifying whether each subsystem to be merged is the source system of the information interaction relationship data, if so, copying M to generate new information interaction relationship data N, setting the source system of N as a subsystem D, otherwise, verifying whether each subsystem to be merged contains the target system of M, if so, copying M to generate new information interaction relationship data N, setting the target system of N as a subsystem D, otherwise, continuing to circulate next information interaction relationship data;

7) circulating the newly generated information interaction relationship data N, verifying whether more than 1 information interaction relationship source system and target system are completely consistent, and if so, merging the corresponding information interaction relationship data of the completely consistent source system and target system to generate new information interaction relationship data;

8) and generating interactive relation table data according to the new information interactive relation data.

A computer-readable storage medium storing a computer program comprising instructions for performing the steps of any of the methods described above.

The invention provides an automatic generation method of an information interaction relation graph between systems, which mainly relates to a 'two-graph one-table', wherein the two graphs refer to a system composition graph and the information interaction relation graph, and the one-table refers to the information interaction relation table. The information interaction relation graph is automatically generated according to the system composition graph and the information interaction relation table.

The method for automatically generating the information interaction relationship graph among the systems comprises the following specific steps:

the method comprises the following steps: and drawing a tree diagram of the composition structure of the system according to the composition structure of the court information system.

Step two: and generating an information interaction relation matrix between the system and the subsystem thereof related in the system composition structure tree diagram and other systems in the Excel table, taking the first row of the table as a source system of the information interaction relation, taking the first column as a target system of the information interaction relation, and expressing the interaction information content transmitted from the source system corresponding to the column to the target system corresponding to the row.

Step three: and importing the information interaction relation matrix in the step two into a general design tool to generate an information interaction relation table as shown in table 1.

TABLE 1 information interaction relation table

Batch information editing, system addition and deletion can be carried out in the information relation table, and the membership of the system can be selected when the system is added. The first row of the information interaction relation table represents a source system, the first column represents a destination system, the information in the corresponding cell represents the interaction data information transmitted to the destination system by the source system, and if a plurality of interaction information exist between two systems corresponding to a certain cell, the interaction information is separated by using a division number. The source system and the destination system represented by the cells on the diagonal are the same system, and are not filled items, and the rest of the cells without interaction relationship are represented by blank tables.

Step four: according to the information interaction relation table generated in the third step, an information interaction relation graph of the system can be automatically generated, as shown in fig. 1. The method has the advantages that the data display form conversion between the table and the graph is realized according to the function of automatically generating the information interaction relation graph from the table to the graph, the information interaction relation graph adopts an automatic layout algorithm to automatically layout a system and an interaction relation connecting line, the layout of the system adopts a diagonal downward equidistant arrangement algorithm, all systems in the graph are arranged in a diagonal form, an arrow on the upper half part of the diagonal points downwards, and an arrow on the lower half part of the diagonal points upwards; the layout of the system interactive relation connecting line adopts an endpoint uniform arrangement algorithm, the systems at two ends of the connecting line have interactive relation, the starting point of the connecting line represents a source system, the system indicated by an arrow is a target system, the on-line display content is interactive information between the systems, can be interface names or interactive data, and the interactive information on the connecting line and the on-line can move along with the on-line display content when the system is dragged. The general flow of the automatic layout algorithm is as follows:

1) analyzing the information interaction relation table row header;

2) circulating header data to create system objects with the same name;

3) setting a background color according to the background color of the system in the system composition description;

4) analyzing a list head of the information interaction relation list;

5) circulating the list head data, excluding the created system objects according to the names, and creating the system objects which are not matched with the names;

6) setting a coordinate point of a first system object and the length and width of the system object;

7) the length and width of the coordinate point Y = the previous system object Y + fixed value, and the coordinate point X = the previous system object X + fixed value are consistent with those of the first system, and finally an oblique diagonal effect is formed;

8) analyzing the cells of the information interaction relation table, judging whether the cells have data, if so, performing the next step, otherwise, circularly judging the data condition of the next cell;

9) establishing an information interaction relationship line, and setting a source system and a target system of the line;

10) setting a reference point for a connecting line, comparing the positions of a source system and a target system, wherein the source system is above the target system, the source reference point is (width, height/2), the target reference point is (width/2, 0), the source system is below the target system, the source reference point is (0, height/2), and the target reference point is (width/2, height);

11) setting a break point for the connecting line, wherein a coordinate point X of the break point = a target reference point X + a target object X, and a coordinate Y of the break point = a source reference point Y + a source object Y;

12) acquiring a source connecting line and a target connecting line on each system object;

13) sequencing the source connecting lines and the system objects to ensure that the connecting lines of the same target system or the same source system cannot be displayed in a crossed manner;

14) and recalculating the positions of the source reference point and the target reference point, and uniformly arranging all the connecting lines.

The detailed flow chart of this function is shown in fig. 2, where X is the abscissa relative to the top left corner of the editor, Y is the ordinate relative to the top left corner of the editor, height is the height of the system object, and width is the width of the system object.

The space boundary of the information interaction relation graph obtained by adopting the automatic layout algorithm is large enough, and a system in the graph can adjust the position to ensure that interaction information on a connecting line cannot be shielded, so that the whole information interaction relation graph is presented in a reasonable and visual form.

And editing information in the information interaction relation table, wherein the edited content can be automatically synchronized to corresponding elements of the information interaction relation graph. The information interaction relation table can also be used for screening the systems according to the needs of users, the information interaction relation table among the screened systems can be automatically generated after screening, and then an information interaction relation graph among the screened systems is automatically generated by utilizing an automatic layout algorithm. The system elements may be parent systems or subsystems in a system composition structure tree, or may be a mixture of parent systems in the system structure tree and subsystems in other system structure trees. When the user selects only one system, the system automatically generates an information interaction relation table and an information interaction relation graph between the system and all other systems. The data screening function of the information interaction relation table can freely display the data of the information interaction relation table, and the information interaction relation table can only display the data interaction condition between a specific source system and a specific target system according to the screening result of the user. The general flow is as follows:

1) clearing a row table head, a list table head and cell data of the information interaction relation table;

2) analyzing the selected row data after the data screening;

3) judging whether the line data is marked as full selection;

4) if yes, the row header presents all system objects;

5) if the data is 'no', circularly performing data matching according to the name and the system name in the system, if the data is matched, displaying the data in a row table header, and if the data is not matched, not displaying the data;

6) analyzing the selected column data after data screening;

7) judging whether the column data is marked as full selection;

8) if yes, the list head presents all system objects;

9) if the name is not matched with the system name in the system, the circular column data is matched with the system name in the system, if the name is matched with the system name, the circular column data is displayed in the head of the list, and if the name is not matched with the system name, the circular column data is not displayed;

10) information interaction relation in the circulating system;

11) analyzing a source object and a target object of the information interaction relation;

12) judging whether the name of the target object is matched with the head name of the row table in the table;

13) if no, continuing the next cycle;

14) if yes, judging whether the name of the source object is matched with the list head name in the list;

15) if no, continuing the next cycle;

16) if yes, displaying the interface exchange elements in the information interaction relationship in the cells corresponding to the row table head and the column table head.

The specific process of data screening is shown in fig. 3.

By adopting the method for automatically generating the information interaction relationship graph among the systems, one or more systems are newly added through the system composition graph or the information interaction relationship table, and after the corresponding information interaction relationship is supplemented, a new information interaction relationship general graph can be automatically generated. In addition, when a plurality of systems in the system structure tree are integrated into one system, a new information interaction relationship general graph can be automatically generated, and information interaction relationships between the integrated systems and between other systems can be inherited and integrated.

The invention also provides a system integration function, and the system integration function realizes that customers can freely combine two or more systems according to requirements, thereby combining information interaction elements on the systems. The specific process of the system integration function is shown in fig. 4, and assuming that A, B, C three systems in the target system need to be integrated into a system D, the system integration method can be described as follows:

1) acquiring A, B, C three system data;

2) inputting a system name D generated after integration;

3) verifying whether the system D is repeated with the existing system name or not, and if so, automatically generating the system name D in a form of adding a copy; if not, generating a new system D;

4) acquiring all information interaction relation data in a target system;

5) circulating the first information interaction relation data M to obtain a source system and a target system of the information interaction relation data;

6) verifying A, B, C whether the three systems simultaneously contain the source system and the destination system of the information interaction relationship data, if yes, continuing to circulate next information interaction relationship data, if no, verifying A, B, C whether the three systems are the source system of the information interaction relationship data, if yes, copying M to generate new information interaction relationship data N, setting the source system of N as a system D, if no, verifying A, B, C whether the three systems contain the destination system of M, if yes, copying M to generate new information interaction relationship data N, setting the destination system of N as a system D, and if no, continuing to circulate next information interaction relationship data;

7) circulating the newly generated information interaction relationship data N, verifying whether more than 1 information interaction relationship source system and target system are completely consistent, and if so, merging the corresponding information interaction relationship data of the completely consistent source system and target system to generate new information interaction relationship data;

8) and reloading the data of the information interaction relation table.

The beneficial effects of the invention include:

(1) the automatic generation method of the inter-system information interaction relationship diagram provides an effective method for clearing the interaction relationship among the systems in the top-level design of the smart court, and has an important role in solving the problems that the system development is restricted and the subsequent planning construction is influenced due to the lack of top-level planning and unclear system interaction relationship in the system design of the smart court.

(2) According to the method for automatically generating the information interaction relationship diagram, interaction data or butt joint interface information between internal systems of any courts and between the internal systems and external systems or units can be automatically screened according to needs only by combing the system interaction relationship once under the condition that the system composition structure is known, the automation degree is high, the situation that a user repeatedly draws the system interaction relationship diagram or repeatedly combs the system interaction relationship is avoided, the workload of related workers is reduced, and the reuse rate of the general design knowledge of the intelligent courts and the working efficiency of the general design are improved.

(3) The information interaction relation graph generated by the method is displayed to the user in a reasonable and visual mode, the systems are arranged in a diagonal mode, interaction information among the systems is not hidden due to more systems or more interaction information, and the user can intuitively and quickly know the interaction relation among the systems on the interaction relation graph.

(4) According to the automatic generation method of the information interaction relation graph, the system composition relation graph, the information interaction relation graph and the information interaction relation graph have automatic association relations, the information interaction relation graph and the information interaction relation graph can automatically change along with the change of the content in the system composition structure tree, the information interaction relation graph can also change along with the change of the content in the system composition relation graph and the information interaction relation graph, and the working efficiency and the intelligent degree of the design work of the intelligent court are greatly improved.

It should be noted that the system composition structure diagram is the core basis of the present invention, and the information in the system composition structure diagram does not change with the change of the information interaction relationship table and the content in the information interaction relationship diagram, which can effectively prevent the loss and the error change of the main information content such as the system information and the system composition relationship caused by the error operation.

Drawings

FIG. 1 is a diagram of an information interaction relationship between systems;

FIG. 2 is a flow chart of automatic generation of an information interaction relationship diagram;

FIG. 3 is a flowchart of generating an information interaction relationship table after data screening;

FIG. 4 is a flowchart of the system integration followed by the generation of an information interaction relationship table;

FIG. 5 is a block diagram of the overall design system of the highest civil court;

FIG. 6 is a diagram of information interaction between the complaint system and other systems;

FIG. 7 is a diagram of the information interaction between the highest court litigation service network and the national court big data management and service platform;

FIG. 8 is a diagram of the information interaction between the top people's court litigation service network, people's court big data management and service platform, and other systems;

FIG. 9 is a diagram of the information interaction between the highest people's court litigation service network and other systems;

FIG. 10 is a diagram of information interaction relationships for a highest people's court litigation service network (after integrating a people's court executive information management system, a highest people's court visiting information management system, and a highest people's court archive management system into a people's court information management system);

fig. 11 is a diagram showing the information interaction relationship between the complaint service system and other systems after the chinese official document network is deleted.

Detailed Description

The invention is described in detail below by way of example with reference to the accompanying drawings.

Example (b):

the embodiment provides an automatic generation method of an information interaction relationship diagram of a highest people court general design system, and describes the automatic generation method of the information interaction relationship diagram of the complaint service system in detail.

At present, the highest people court relies on various business application systems, direct support is provided for litigation service, trial execution, judicial management and clean judicial, the initial scale of three types of information resources including trial execution, judicial personnel and judicial government affairs realizes breakthrough in centralized data management, and a good foundation is laid for comprehensive construction of the smart court.

Based on the highest people's court informationized construction achievement, the main construction target of the intelligent court is to apply a system engineering method, develop the overall system design, clarify the construction current situation, form a reusable and expandable overall design achievement, comb the highest people's court information system current situation from the aspects of system functions, system interaction relations and the like, form overall design data and files, get through ' information islands ' and eliminate ' data barriers ', make up for the short intelligent capability board, and further improve the highest people's court informationized construction level.

In order to achieve the above object, the present invention provides an automatic generation method of an information interaction diagram between design systems, which comprises the following specific implementation steps:

the method comprises the following steps: and drawing a composition structure tree diagram of the overall design system of the highest people's court according to the composition relation of the information system of the highest people's court, as shown in the attached figure 5.

Step two: and generating an information interaction relation matrix between the complaint system and other systems (court systems or external systems) in the highest national court overall design composition structure tree in an Excel table, taking a first row of the table as a source system and a first column as a destination system, and expressing interactive information contents transmitted to the destination system corresponding to the row by the source system corresponding to the column in which the cell is located.

Step three: and D, importing the information interaction relation matrix between the complaint service system and other systems generated in the step two into a general design tool, and generating an information interaction relation table between the complaint service system and other systems.

Step four: and automatically generating an information interaction relation chart between the complaint service system and other systems according to the information interaction relation table between the complaint service system and other systems generated in the third step, as shown in fig. 6.

The method for automatically generating the information interaction relation graph supports the data screening function, the screened data can be one or more, and the information interaction relation graph related to the screened data can be automatically generated after screening. For example, screening two system data, namely "people's court big data management and service platform" and "highest people's court litigation service network", can automatically generate an information interaction relationship table and an information interaction relationship diagram between the two systems, and an information interaction relationship diagram between the two systems and other systems, which are respectively shown in table 2, fig. 7 and fig. 8; when screening data of a system, such as the "highest people court litigation service network" in the complaint system, an information interaction relation table and an information interaction relation graph between the system and other systems are automatically generated, which are respectively shown in table 3 and fig. 9.

TABLE 2 information interaction relation table between the highest people's court litigation service network and people's court big data management and service platform

TABLE 3 information interaction relation table between the highest people court litigation service network and other systems

The automatic generation method of the information interaction relation graph supports the system integration function, the new system generated after integration automatically inherits and integrates the information interaction relation between the integrated system and other systems, and a new information interaction relation table and an information interaction relation graph are automatically generated. For example, after "the people's court execution information management system", "the highest people's court visiting information management system", and "the highest people's court archive management system" are integrated into the "people's court information management system", the information interaction relationship table and the information interaction relationship chart between the highest people's court litigation service network and the other system are automatically generated, as shown in table 4 and fig. 10, respectively.

TABLE 4 information interaction relation table between the highest people's court litigation service network and other systems (integration of people's court execution information management system, highest people's court visiting information management system and highest people's court archive management system into people's court information management system)

The method for automatically generating the information interaction relationship chart supports the system editing function, and the latest information interaction relationship chart can be automatically generated after the system is edited. For example, by deleting the "chinese referee document network" from the complaint system, a new information interaction relationship table and information interaction relationship diagram between the complaint system and other systems can be automatically generated, as shown in fig. 11.

Similarly, other systems in the overall design of the highest people's court, such as trial, execution, management and collaboration systems, can also obtain corresponding information interaction relationship diagrams according to the same method.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A method for automatically generating an information relationship graph between systems comprises the following steps:

1) drawing a tree diagram of the composition structure of the target system according to the composition structure of the target system;

2) generating a two-dimensional information interaction relation matrix according to interaction information among subsystems related in a composition structure tree diagram of the target system and among the subsystems and other related systems except the target system; the cell represents the interactive information content transmitted from the source system corresponding to the column to the destination system corresponding to the row;

3) importing the information interaction relation matrix into a general design tool to generate an information interaction relation table; then, automatically laying out the system and the interactive relation connecting line by adopting an automatic layout algorithm to generate an information interactive relation graph; the automatic layout algorithm comprises the following steps:

a) the overall design tool analyzes the row header of the information interaction relation table, circulates row header data and creates system objects with the same name; then analyzing the list head of the information interaction relation list, circulating the list head data, excluding the created system object according to the name, and creating the system object which is not matched with the name;

b) the overall design tool sets the coordinate points of the first system object and the length and width of the system object; then sequentially determining the ordinate = the ordinate + of the last system object + of a fixed value, and the abscissa = the abscissa + of the last system object + of a fixed value;

c) the overall design tool analyzes the cells of the information interaction relation table, judges whether the cells have data or not, if so, creates an information interaction relation line, sets a source and a target of the current information interaction line according to a source system and a target system corresponding to the current cells, and otherwise, circularly judges the data condition of the next cell; the starting point of the information interaction relationship line represents a source system, the system indicated by the arrow is a target system, and the online display content corresponds to the interaction information between the two systems;

d) setting a source reference point and a target reference point for each information interaction relation line according to the positions of a source system and a target system connected with the information interaction relation line; then, according to the source reference point and the target reference point, determining a break point of the information interaction relation line, wherein the abscissa of the break point = the abscissa of the target reference point + the abscissa of the target system, and the ordinate of the break point = the ordinate of the source reference point + the ordinate of the source system;

e) acquiring a source connecting line and a target connecting line on each system object; sequencing the source connecting lines and the system objects to ensure that the connecting lines of the same target system or the same source system cannot be displayed in a crossed manner; the source connecting line on the system object is a connecting line of the system object as a starting point of the information interaction relation line, and the target connecting line on the system object is a connecting line pointed by an arrow of the system object as the information interaction relation line;

f) and recalculating the positions of the source reference point and the target reference point, and uniformly arranging all information interaction relationship lines to obtain an information interaction relationship diagram of the target system.

2. The method of claim 1, wherein if there are multiple interactive messages between two systems corresponding to a cell element, different messages in the cell element are separated by a semicolon.

3. The method of claim 1 or 2, wherein the overall design tool sets the background color for the corresponding system according to the background color of the system in the "system composition description" of the overall design tool.

4. The method of claim 3, wherein the length and width of each of the system objects are the same.

5. The method of claim 1, wherein if the source system is above the destination system, the source reference point is (width, height/2), the destination reference point is (width/2, 0), if the source system is below the destination system, the source reference point is (0, height/2), the destination reference point is (width/2, height); wherein height is the height of the system object and width is the width of the system object.

6. The method of claim 1, wherein the global design tool performs information editing on the information interaction relationship table, and then automatically synchronizes the edited content to corresponding elements of the information interaction relationship graph.

7. The method of claim 1, wherein the global design tool screens systems according to user requirements, and automatically generates the information interaction relation table between the screened systems after screening, and the method comprises:

1) clearing a row table head, a list table head and cell data of the information interaction relation table;

2) analyzing the selected row data after the data screening; judging whether the line data is marked as full selection; if yes, the row header presents all system objects; if the name is not the same as the system name in the system, circulating the data, matching the data with the system name in the system according to the name, if the data is matched, displaying the data in a row table header, and if the data is not matched, not displaying the data;

3) analyzing the selected column data after data screening; judging whether the column data is marked as full selection; if yes, the list head presents all system objects; if the name is not matched with the system name in the system, the circular column data is matched with the system name in the system, if the name is matched with the system name, the circular column data is displayed in the head of the list, and if the name is not matched with the system name, the circular column data is not displayed;

4) analyzing the information interaction relation in the circulating system, and analyzing a source object and a target object of the information interaction relation; then judging whether the name of the target object is matched with the head name of the row table in the table; if not, continuing the next cycle; if the names of the source objects are matched with the names of the list heads in the list, judging whether the names of the source objects are matched with the names of the list heads in the list, if not, continuing the next circulation, and if so, displaying the corresponding interactive information in the information interactive relation in the cells corresponding to the list heads and the list heads.

8. The method of claim 1, wherein the target system is a court information system; the system object is a parent system, a subsystem or other related system outside the target system in the target system composition structure tree.

9. The method of claim 1, wherein a plurality of subsystems in a target system are integrated into a new subsystem, and then the information interaction relation table is generated; the method comprises the following steps:

1) acquiring system data of each subsystem to be integrated;

2) inputting a subsystem name D generated after integration;

3) verifying whether the subsystem D is repeated with the existing subsystem name or not, and if so, automatically generating the subsystem name D in a form of adding a 'copy'; if not, generating a new subsystem D;

4) acquiring all information interaction relation data in a target system;

5) circularly acquiring the information interaction relation data, and acquiring a source system and a target system of the information interaction relation data M for the currently acquired information interaction relation data M;

6) verifying whether each subsystem to be merged contains a source system and a destination system of the information interaction relationship data M at the same time, if so, continuing to circulate next information interaction relationship data, otherwise, verifying whether each subsystem to be merged contains the source system of the information interaction relationship data M, if so, copying the information interaction relationship data M to generate new information interaction relationship data N, setting the source system of the information interaction relationship data N as a subsystem D, otherwise, verifying whether each subsystem to be merged contains the destination system of the information interaction relationship data M, if so, copying the information interaction relationship data M to generate new information interaction relationship data N, setting the destination system of the N as a subsystem D, otherwise, continuing to circulate to obtain the next information interaction relationship data;

7) circulating the newly generated information interaction relationship data N, verifying whether more than 1 information interaction relationship source system and target system are completely consistent, and if so, merging the corresponding information interaction relationship data of the completely consistent source system and target system to generate new information interaction relationship data;

8) and generating interactive relation table data according to the new information interactive relation data.

10. A computer-readable storage medium, in which a computer program is stored, the computer program comprising instructions for carrying out the steps of the method according to any one of claims 1 to 9.

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