CN110737660A - data processing method, device and computer readable storage medium - Google Patents

Abstract

The embodiment of the invention discloses a data processing method which comprises the steps of obtaining a pre-stored direct current engineering tree structure diagram, obtaining at least visual programs based on the direct current engineering tree structure diagram, wherein the at least visual programs correspond to at least target devices in the direct current engineering tree structure diagram, obtaining data receiving and sending information among nodes in the direct current engineering tree structure diagram from the at least visual programs, creating a target link diagram based on the data receiving and sending information and the direct current engineering tree structure diagram, and sequentially displaying a plurality of views in the target link diagram based on the hierarchy of the direct current engineering tree structure diagram.

Description

data processing method, device and computer readable storage medium

Technical Field

The present invention relates to the field of dc control protection technologies, and in particular, to data processing methods and devices, and a computer-readable storage medium.

Background

However, in the prior art, the research on interfaces, typical loops and links of the direct current control protection system is not carried out, the optimization design and control on a secondary loop are less, so that the state monitoring of the direct current control protection system is not intuitive, and a hierarchical browsing monitoring function is lacked.

Disclosure of Invention

In order to solve the above technical problems, embodiments of the present invention desirably provide data processing methods, apparatuses, and computer readable storage media, so as to solve the problem in the prior art that the optimal design and control of the secondary circuit of the dc-dc protection system are few, enrich the schemes for optimal design and control of the secondary circuit of the dc-dc protection system, and enable visual and multi-level display of the status monitoring of the dc-dc protection system.

The technical scheme of the invention is realized as follows:

, a method of data processing, the method comprising:

acquiring a pre-stored direct current engineering tree structure diagram;

acquiring at least visualization programs based on the direct current engineering tree structure chart, wherein the at least visualization programs correspond to at least target devices in the direct current engineering tree structure chart;

acquiring data transceiving information among nodes in the direct current engineering tree structure diagram from at least visualization programs;

creating a target link diagram based on the data transceiving information and the direct current engineering tree structure diagram;

and sequentially displaying a plurality of views in the target link diagram based on the hierarchy of the direct current engineering tree structure diagram.

Optionally, the acquiring data transmission and reception information between nodes in the direct current engineering tree structure diagram from the at least visualization programs includes:

acquiring data transceiving symbols of nodes in the direct current engineering tree structure diagram from at least visualization programs;

and analyzing the data transceiving symbol to obtain the data transceiving information.

Optionally, the creating a target link map based on the data transceiving information and the dc engineering tree structure diagram includes:

acquiring a subtree of a node at layer in the direct current engineering tree structure diagram, and creating a logic loop index view corresponding to the subtree based on the subtree and a communication type and a communication mode corresponding to the subtree in the data transceiving information;

acquiring the communication relationship between each layer of nodes in the direct current engineering tree structure diagram from the data transceiving information, and creating a communication view corresponding to each layer of nodes based on the communication relationship between each layer of nodes;

acquiring nodes with front-back communication connection relation in the direct current engineering attribute structure diagram, and communication variables and communication ports between the nodes with the front-back communication connection relation from the data transceiving information;

establishing a signal transmission view corresponding to the nodes with the front-back connection relation based on the nodes with the front-back connection relation, communication variables and communication ports among the nodes with the front-back connection relation;

and sequentially setting a logic loop index view corresponding to the subtree, a communication view corresponding to each -layer node and a signal transmission view corresponding to the node with the front-back connection relation according to the hierarchical relation in the direct-current engineering tree structure diagram to obtain the target link diagram.

Optionally, the sequentially displaying a plurality of views included in the target link diagram based on the hierarchy of the direct current engineering tree structure diagram includes:

acquiring a th communication view between nodes at the th layer in the direct current engineering tree structure diagram from the communication view corresponding to each layer of nodes, and displaying a th communication view between nodes at the th layer, wherein the th communication view corresponds to the nodes at the th layer;

receiving a th preset operation aiming at the th communication block in the th communication view, responding to the th preset operation, and displaying a logic loop index view corresponding to the th communication block;

receiving a second preset operation aiming at a second communication block in the th logical loop index view, responding to the second preset operation, and displaying a second communication view corresponding to the second communication block;

receiving a third preset operation aiming at a connecting line of the second communication view, and displaying a signal transmission view corresponding to the second communication view;

receiving a fourth preset operation aiming at a connecting line of the th communication view, responding to the third preset operation, and displaying a third communication view, wherein the second communication view comprises the identifier of the node of the subtree;

and receiving a fifth preset operation aiming at the connecting line of the third communication view, responding to the fifth preset operation, and displaying a signal transmission view corresponding to the third communication view.

Optionally, after creating the target link map based on the data transceiving information and the dc engineering tree structure diagram, the method further includes:

acquiring a pre-stored direct current engineering physical structure diagram, wherein the direct current engineering physical structure diagram is created by a physical model symbol corresponding to each node in the direct current engineering tree structure diagram;

mapping and associating an th sub-physical structure diagram in the direct-current engineering physical structure diagram with the target link diagram, wherein the th sub-physical structure diagram has a corresponding relation with the target link diagram;

receiving a mapping association operation, and performing mapping association on a second sub-physical structure diagram in the direct-current engineering physical structure diagram in response to the mapping association operation to obtain a target direct-current engineering visual diagram, wherein the target direct-current engineering visual diagram is used for realizing cross indexing and jumping between the direct-current engineering physical structure diagram and the target link diagram, and the second sub-physical structure diagram is a physical structure diagram in the direct-current engineering physical structure diagram except the th sub-physical structure diagram.

Optionally, after receiving the mapping association operation and responding to the mapping association operation, performing mapping association on the second sub-physical structure diagram in the direct current engineering physical structure diagram to obtain a target direct current engineering visible view, the method further includes:

inputting a reference variable in the target direct current engineering visual image to perform fault location analysis;

and if the fault exists, outputting fault prompt information at the fault part of the target direct current project visual image.

Optionally, the inputting a reference variable in the target direct current engineering visible view for fault location analysis includes:

receiving an input signal to obtain the reference variable;

obtaining an output result when the reference variable is transmitted in a communication channel or a communication port in the target direct current engineering visual image;

and determining whether the communication channel or the communication port is conducted or not based on the output result to perform the fault location analysis.

Alternatively to this, the first and second parts may,

each node in th layer in the direct current engineering tree structure diagram represents 0 converter stations in direct current engineering, each 1 node in the second layer represents 2 poles in direct current engineering, each 3 node in the third layer represents 4 systems in direct current engineering, each 5 node in the fourth layer represents control protection hosts in direct current engineering, each node in the fifth layer represents input and output IO devices in direct current engineering, the direct current engineering comprises at least two converter stations, each converter station comprises at least two poles, each pole comprises two systems, each system comprises at least control protection hosts, and each control protection host manages the input and output IO devices.

In a second aspect, a data processing apparatus comprising a processor, a memory, and a communication bus, wherein:

the memory to store executable instructions;

the communication bus is used for realizing communication connection between the processor and the memory;

the processor is configured to execute the data processing program stored in the memory to implement the data processing method according to any one of items above.

In a third aspect, computer readable storage media having stored thereon a data processing program which when executed by a processor implements the steps of the data processing method as described above in any of .

Embodiments of the present invention provide data processing methods, devices, and computer-readable storage media, where after a pre-stored dc engineering tree structure diagram is obtained, at least visual programs are obtained based on the dc engineering tree structure diagram, data transceiving information of nodes in the dc engineering tree structure diagram is obtained from at least visual programs, and then a target link diagram is created based on the data transceiving information and the dc engineering tree structure diagram.

Drawings

Fig. 1 is a schematic flow chart of data processing methods according to an embodiment of the present invention;

fig. 2 is a schematic flow chart of another data processing methods according to the embodiment of the present invention;

fig. 3 is a schematic diagram of dc engineering tree structures provided in an embodiment of the present invention;

fig. 4 is a schematic diagram of communication symbols provided by the embodiment of the present invention;

fig. 5 is a schematic diagram of communication symbols provided by an embodiment of the present invention;

fig. 6 is a schematic diagram of another communication symbols provided by an embodiment of the present invention;

FIG. 7 is a schematic diagram of views of inter-station communication according to an embodiment of the present invention;

FIG. 8 is a diagram illustrating an index view of logic loops according to an embodiment of the present invention;

FIG. 9 is a schematic diagram of another views of inter-station communication according to an embodiment of the present invention;

FIG. 10 is a schematic diagram illustrating an exemplary communications view among poles provided in accordance with an embodiment of the present invention;

FIG. 11 is a schematic diagram of views of inter-system communications provided by embodiments of the present invention;

FIG. 12 is a diagram illustrating an inter-host communication view according to an embodiment of the present invention;

FIG. 13 is a diagram illustrating a communication view between hosts and an IO device according to an embodiment of the present invention;

fig. 14 is a schematic diagram of a signal transmission view during signal transmission between hosts according to an embodiment of the present invention;

FIG. 15 is a flow chart illustrating another data processing method according to an embodiment of the present invention;

fig. 16 is a schematic diagram of application scenarios provided in the embodiment of the present invention;

fig. 17 is a schematic diagram of another application scenarios provided in the embodiment of the present invention;

fig. 18 is a schematic diagram of application scenarios provided in the embodiment of the present invention;

fig. 19 is a schematic diagram of dc engineering physical structure diagrams provided in an embodiment of the present invention;

FIG. 20 is a flowchart illustrating another data processing methods according to an embodiment of the present invention;

fig. 21 is a schematic structural diagram of data processing apparatuses according to an embodiment of the present invention.

Detailed Description

The technical solution 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 invention.

An embodiment of the present invention provides data processing methods, and as shown in fig. 1, the method is applied to a data processing apparatus, and the method includes the following steps:

step 101, acquiring a pre-stored direct current engineering tree structure diagram.

Each node in a -th layer in the direct-current engineering tree structure diagram represents 0 converter stations in direct-current engineering, each 1 node in a second layer represents 2 poles in direct-current engineering, each 3 node in a third layer represents 4 systems in direct-current engineering, each 5 node in a fourth layer represents control protection hosts in direct-current engineering, each node in a fifth layer represents input and output IO devices in direct-current engineering, the direct-current engineering comprises at least two converter stations, each converter station comprises at least two poles, each pole comprises two systems, each system comprises at least control protection hosts, and each control protection host manages the input and output IO devices.

In the embodiment of the present invention, the pre-stored dc engineering tree structure diagram may be obtained by a user through design according to a dc control protection engineering design schematic diagram, and a format of the pre-stored dc engineering tree structure diagram may be a picture format, or may be another file storage format that can be recognized by a data processing device.

And 102, acquiring at least visual programs based on the direct current engineering tree structure diagram.

At least visualization programs correspond to at least target devices in the direct current engineering tree structure diagram.

In the embodiment of the invention, at least visual programs are compiled scripts corresponding to visual interfaces which are pre-stored by a user and installed in a data storage device, and the visual programs are mainly applied to a control protection host and an IO device, namely after the visual programs are compiled, the obtained visual interfaces can view the working conditions of the corresponding control protection host and/or the IO device, including working modes, transmitted data and the like, wherein each control protection host corresponds to visual programs, each IO device corresponds to visual programs, several control protection hosts correspond to visual programs, several IO devices correspond to visual programs, or several control protection hosts and several IO devices correspond to visual programs.

And 103, acquiring data transmitting and receiving information among the nodes in the direct current engineering tree structure diagram from at least visualization programs.

In the embodiment of the present invention, the visualization program includes data transmission and reception information for data transmission between all nodes in the direct current engineering tree structure diagram, where the data transmission and reception information includes a communication type, a communication mode, that is, a transmission mode, a fiber channel signal/ethernet port, a host communication address, a variable packet number, a variable name, a variable type, a data length, and the like. The contents of the data transmission and reception information are stored in a predetermined format in the visualization program.

And 104, creating a target link diagram based on the data transmitting and receiving information and the direct current engineering tree structure diagram.

The target link diagram comprises a plurality of views, and the views in the target link diagram are sequentially displayed according to the hierarchy of the direct current engineering tree structure diagram.

Therefore, based on the data interaction relationship and the transmission data between the devices in the data transceiving information, a logic loop index view, a communication view and a logic visual view of the direct current engineering protection system can be created according to the connection relationship between every nodes in the direct current engineering tree structure diagram, and the obtained logic loop index view, communication view and logic visual view are hierarchically arranged according to the hierarchical relationship in the direct current engineering tree structure diagram in the step.

In step 105, a plurality of views in the target link diagram are sequentially displayed based on the hierarchy of the direct current engineering tree structure diagram.

In the embodiment of the invention, the target link diagram is obtained by arranging the views according to the hierarchy based on the hierarchy of the direct current engineering tree structure diagram, so that the target link diagram can be displayed hierarchically, specifically, the target link diagram can be displayed by operating on the view of the upper layer and then displaying the view of the lower layer corresponding to the layer, and thus, the hierarchical display of the target link diagram is realized.

The embodiment of the invention provides data processing methods, which include obtaining at least visual programs based on a direct current engineering tree structure diagram after obtaining a pre-stored direct current engineering tree structure diagram, obtaining data transceiving information of nodes in the direct current engineering tree structure diagram from at least visual programs, and then creating a target link diagram based on the data transceiving information and the direct current engineering tree structure diagram.

Based on the foregoing embodiments, an embodiment of the present invention provides data processing methods, which are applied to a data processing apparatus as shown in fig. 2, and include the following steps:

step 201, obtaining a pre-stored direct current engineering tree structure diagram.

Each node in a -th layer in the direct-current engineering tree structure diagram represents 0 converter stations in direct-current engineering, each 1 node in a second layer represents 2 poles in direct-current engineering, each 3 node in a third layer represents 4 systems in direct-current engineering, each 5 node in a fourth layer represents control protection hosts in direct-current engineering, each node in a fifth layer represents input and output IO devices in direct-current engineering, the direct-current engineering comprises at least two converter stations, each converter station comprises at least two poles, each pole comprises two systems, each system comprises at least control protection hosts, and each control protection host manages the input and output IO devices.

In the embodiment of the invention, a user creates a direct current engineering tree structure diagram according to a converter station, a pole, a system, a control protection host (host for short), an IO device and the like of direct current engineering in a direct current control protection engineering design schematic diagram, wherein in the direct current engineering tree structure diagram, the converter station, the pole and the system can be represented according to numbers in the direct current control protection engineering design schematic diagram, and the control protection host can be represented according to host names in the direct current control protection engineering design schematic diagram. For example, the obtained preset and stored direct current engineering tree structure diagram may be as shown in fig. 3, where the direct current engineering tree structure diagram corresponding to the direct current control protection engineering includes two converter stations, and is represented by a corresponding number station 1 and a corresponding station 2; the station 1 comprises two poles, denoted with the corresponding numbered poles 1 and 2; the pole 1 comprises two systems which are represented by a corresponding numbering system 1 and a corresponding numbering system 2; the system 1 comprises two hosts which are represented by a host PCP1 and a host PPR1 with corresponding host numbers; the host is not set in the system 2; host PCP1 does not manage IO devices; the host PPR1 manages two IO devices, and is represented by corresponding numbers IO1 and IO 2; the station 2 comprises two poles, indicated with the corresponding numbered poles 3 and 4; the pole 3 comprises two systems which are represented by corresponding numbering systems 3 and 4; the system 3 comprises two hosts which are represented by corresponding host numbers PCP2 and PPR 2; the host is not set in the system 4; host PCP2 does not manage IO devices; host PPR2 does not manage IO devices. It should be noted that fig. 3 is only an example, and the number of stations, poles, systems, control protection hosts, and IO devices in the direct current engineering tree structure diagram corresponding to the direct current control protection engineering is specifically determined according to an actual application scenario or a direct current control protection engineering design, and is not limited here.

And 202, acquiring at least visual programs based on the direct current engineering tree structure diagram.

At least visualization programs correspond to at least target devices in the direct current engineering tree structure diagram.

In the embodiment of the invention, at least visual programs are obtained based on the control protection host and the IO device in the direct current engineering tree structure diagram, wherein the control protection host and the IO device can correspond to visual programs, also control protection hosts correspond to visual programs, IO devices correspond to visual programs, the specific situation of the control protection host and the IO device corresponding visual programs can be determined according to the actual situation, and the method is not limited herein.

And step 203, acquiring data transceiving symbols of the nodes in the direct current engineering tree structure diagram from at least visualization programs.

In the embodiment of the present invention, the data transceiving symbol refers to a carrier for information transmission between stations, inter-poles, inter-systems, between control protection hosts, between stations and inter-poles, between poles and systems, between systems and control protection hosts, and between control protection hosts and IO devices of a visualization program. As shown in fig. 4, a is a matched communication symbol pair when inter-stations perform communication, where a1 is a signal transmission (SEND) symbol, a2 is a signal Reception (RECEIVE) symbol, B1 is a communication type, B2 is configuration information, and Com type in the configuration information B2 represents a communication object, which is station in the embodiment of the present invention. C is a corresponding front-back connection relation in the communication page program obtained after compiling the visualization program based on the communication symbol, wherein PIN is a signal input end, AC _ FAULT _ TOSTA is a variable name for receiving and transmitting, and PIN is connected with the data transmitting symbol C1; POUT is a signal output terminal, AC _ FAULT _ TOSTA is a variable name received and transmitted, POUT is connected with a data receiver C2, and the data receiver C2 further comprises an Enable terminal Enable. It should be noted that the inter-station, inter-pole, and inter-system communication transmitting/receiving symbols are the same, and may be specifically distinguished by Com type in the configuration information B2.

The communication symbol between the hosts may be as shown in fig. 5, D represents a communication link setup symbol pair between the hosts, D1 and D2 set pieces of logical link information between the hosts Tx and Rx, D1 and D2 include information such as a Group number (Group) and a MAC address, E represents an inter-host communication symbol pair, E1 represents a host Rx data transmit symbol, E2 represents a host Tx data receive symbol, the host Rx data transmit symbol E1 and the host Tx data receive symbol E2 may set single variable transmit-receive information, and may set a Group number (Grp) and a terminal number (ind), and F represents a corresponding front-back connection relationship in a communication page program obtained by compiling the visualization program based on the inter-host communication symbol pair.

The communication symbol between the control protection host and the IO device may be as shown in fig. 6, where PIN represents a communication port connected to the host, LOUT represents a communication port connected to the optical fiber port, and information such as an IO signal transmission name, a transmission source plug-in, a destination plug-in, and a transmission channel number may be obtained by analyzing configuration information in the G1 communication symbol IO TX and/or the G2 communication symbol IO RX.

And step 204, analyzing the data transceiving symbol to obtain data transceiving information.

The data receiving and transmitting information can be information sets, each information at least comprises two communication objects which are communicated with each other, and the step can also comprise communication variables and the like.

And 205, acquiring a sub-tree of each node in the th layer in the direct current engineering tree structure diagram, and creating a logic loop index view corresponding to the sub-tree based on the communication type and the communication mode corresponding to the sub-tree in the sub-tree and the data transceiving information.

In the embodiment of the present invention, each node in the th layer in the direct current engineering tree structure diagram refers to a node representing a converter station, as in fig. 3, a node in the th layer includes a node station 1 and a station 2, and exemplary nodes constituting a sub-tree corresponding to the node station 1 include a pole 1, a pole 2, a system 1, a system 2, a host PCP, a host PPR, an IO _1, and an IO _ 2.

In other embodiments of the present invention, the step 205 of creating a logical loop index view corresponding to the subtree based on the communication type and communication mode corresponding to the subtree in the subtree and the data transceiving information may be implemented by the following steps a1 to a 3:

step a1, obtaining the communication type and communication mode between each layer nodes in the subtree from the data transmitting and receiving information.

In the embodiment of the present invention, nodes in the direct current engineering tree structure diagram represent devices in direct current commutation control protection systems, each device in the direct current engineering tree structure diagram is represented by identifiers, and the identifiers can be used for identifying each device, and can be identification information of each device, and can also be numbers capable of identifying the devices.

Step a2, based on the communication type and communication mode in the subtree, creating th preset graph in turn.

Wherein the th preset pattern is provided with a communication type and a communication mode.

In the embodiment of the present invention, the th preset graph may be a rectangular box, a square box, a circular box, or the like, and may be specifically set according to user preferences, the th preset graph is created, and a communication type and a communication mode are set, for example, 4 rectangular boxes are created based on the communication type between each layers of the subtree corresponding to the node station 1 in fig. 3, each rectangular box is respectively marked with inter-pole communication, inter-system communication, inter-host communication, and host-IO device communication, and the communication mode is set in a different communication block.

Step a3, according to the layout of the nodes in the subtree, setting a th preset graph in a second preset graph corresponding to each node on the th layer, and obtaining a logic loop index view corresponding to the subtree.

In the embodiment of the present invention, the second preset graph may be a rectangular box, a square box, a circular box, or the like, and may be specifically set according to user preferences, and the second preset rectangular graph may be the same as or different from the th preset graph.

And step 206, acquiring the communication relationship between each layer of nodes in the direct current engineering tree structure diagram from the data transceiving information, and creating a communication view corresponding to each layer of nodes based on the communication relationship between each layer of nodes.

In the embodiment of the present invention, each layer node in the direct current engineering tree structure diagram refers to a node in the same layer in the direct current engineering tree structure diagram, where the communication relationship includes information sending and receiving relationships and communication contents, and the corresponding communication contents mainly refer to communication variables in the embodiment of the present invention, for example, in fig. 3, the station 1 and the station 2 belong to the same layer in the direct current engineering tree structure diagram, and correspondingly acquire the communication relationship and communication variables between the station 1 and the station 2 from data sending and receiving information, the pole 1, the pole 2, the pole 3 and the pole 4 belong to the same layer in the direct current engineering tree structure diagram, and correspondingly acquire the communication relationship and communication variables between the pole 1, the pole 2, the pole 3 and the pole 4 from data sending and receiving information, the system 1, the system 2, the pole 3 and the pole 4 belong to the same layer in the direct current engineering tree structure diagram, and correspondingly acquire the communication relationship and communication variables between the system 1, the system 2, the system 3 and the system 4 from data sending and the host 1, the PPR 4 and the host in the direct current engineering tree structure diagram, and the host 3625, and the host from the PPR2 and the host from the host and the host from the data sending and the host 6855 layers in the direct current engineering tree structure diagram.

The communication view is used for showing that the devices respectively represented by the two nodes have communication relation.

In other embodiments of the present invention, the step 206 of "creating a communication view corresponding to each node level based on the communication relationship between each node levels" may be implemented by the following steps b1 to b 2:

and b1, creating a third preset graph provided with the second equipment identification based on the communication relation between nodes of each layers.

Wherein the second device identification is obtained according to the nodes with the communication relationship.

In the embodiment of the present invention, the third preset pattern may be the same as or different from the th preset pattern or the second preset pattern, which is not limited herein.

And b2, connecting the third preset graph according to the communication relation, and setting the data flow direction based on the corresponding communication relation to obtain a communication view corresponding to each -layer node.

In an embodiment of the present invention, at least two third preset patterns may be connected by using a connection line with arrows, and a corresponding direction of the arrows is used to indicate a data flow direction, for example, as shown in fig. 8 to 13, fig. 8 is a communication view of a station 1 and a station 2 having a communication relationship, fig. 9 is an inter-station communication view, fig. 10 is an inter-electrode communication view, fig. 11 is an inter-system communication view, fig. 12 is an inter-host communication view, and fig. 13 is a communication view between a host and an IO device.

And step 207, acquiring nodes with front-back communication connection relation in the direct current engineering attribute structure diagram, and communication variables and communication ports between the nodes with the front-back communication connection relation from the data transceiving information.

In the embodiment of the present invention, the front-back communication connection relationship may be implemented in a wired communication manner, or may be implemented in a wireless communication manner. The nodes having the front-back communication connection relationship in the direct current engineering attribute structure diagram may be: between stations and poles, between poles and systems, between systems and control protection hosts, and between control protection hosts and IO devices.

And step 208, creating a signal transmission view corresponding to the nodes with the front-back connection relation based on the nodes with the front-back connection relation, the communication variables and the communication ports between the nodes with the front-back connection relation.

The target link diagram comprises signal transmission views corresponding to nodes with a front-back connection relation.

In other embodiments of the present invention, step 208 may be specifically realized by the following steps c 1-c 3:

and c1, creating a fourth preset graph provided with the third equipment identification.

Wherein the third device identifier is obtained from nodes having a front-back communication connection relationship.

In the embodiment of the present invention, the fourth preset pattern may be the same as or different from the th preset pattern, the second preset pattern and/or the third preset pattern.

And c2, connecting a fourth preset graph by using a connecting wire based on the communication port.

And c3, acquiring the communication variables transmitted by the communication port, and setting the communication variables transmitted by the communication port on a connecting line corresponding to the communication port to obtain a signal transmission view corresponding to the node with the front-back connection relation.

In the embodiment of the present invention, as shown in fig. 14, a signal transmission view during signal transmission between hosts is shown.

And 209, sequentially setting a logic loop index view corresponding to the subtree, a communication view corresponding to each -layer node and a signal transmission view corresponding to the node with the front-back connection relation according to the hierarchical relation in the direct current engineering tree structure chart to obtain a target link chart.

In other embodiments of the present invention, step 209 may be implemented by the following steps d 1-d 7:

and d1, acquiring a th communication view among the th layer nodes in the direct current engineering tree structure diagram from the communication view corresponding to each layer node, and setting and displaying a th communication view among the th layer nodes.

The th communication view is obtained according to the identification setting of th level node, and the th communication view is shown in FIG. 8.

And d2, acquiring the logical loop index view corresponding to the communication block in the communication view between the nodes of the th layer from the logical loop index view corresponding to the subtree.

And d3, displaying a logic loop index view corresponding to the th communication block when the th preset operation is performed on the th communication block in the th communication view.

And d4, displaying a second communication view corresponding to the second communication block when a second preset operation is performed on the second communication block in the logic loop index view corresponding to the displayed communication block.

And d5, displaying the signal transmission view corresponding to the second communication view when the third preset operation is performed on the connecting line of the second communication view.

Wherein the second communication view includes an identification of a node of the sub-tree of the level node.

And d6, acquiring a third communication view among nodes at the th layer, and displaying the third communication view when a third preset operation is performed on the connecting line in the th communication view.

And d7, when the third communication view is displayed and a fifth preset operation is performed on the connecting line of the third communication view, displaying the signal transmission view corresponding to the third communication view.

It should be noted that the th preset operation, the second preset operation, the third preset operation, the fourth preset operation, and the fifth preset operation may be the same or different, and may be determined specifically according to actual situations.

For example, if the preset operations such as single-click and double-click are performed on the connection line between the station 1 communication block in fig. 8, or the connection line between the station 1 communication block and the station 2 communication block in fig. 8, or the connection line between the station 1 and the station 2 communication block in fig. 7, the logic loop index view shown in fig. 7 is displayed, if the preset operations such as single-click and double-click are performed on the connection line between the station 1 communication block in fig. 8, or the fifth preset operation is a double-click operation, the logic loop index view shown in fig. 7 is displayed, if the preset operations such as double-click on the connection line between the station 1 communication block in fig. 8, the second preset operation, the third preset operation, the fourth preset operation, and the fifth preset operation are all double-click operations, the communication link between the station 1 communication block in fig. 8 is double-click, the communication link between the station 1 communication block in fig. 8 is displayed, the communication link between the host communication block in fig. 7 communication system is displayed, and the communication link between the host communication block in the communication system is displayed, and the communication link between the communication link view shown in fig. 7 is displayed, and the communication link view shown in fig. 7, the communication link view of the communication system view shown in the communication link view of the communication system view of double-click is displayed, which the communication link view of the communication link between the communication block of the communication system view of the communication link between the communication block of the communication system is displayed, the communication system view of double-click of the communication system view of the host system view of the.

That is, only fig. 8 may be displayed when the target link map is displayed, the corresponding fig. 7 and 9 to 14 are hidden for display, and after the related operations are performed on fig. 8, fig. 7 and 9 to 14 are sequentially displayed, so as to implement hierarchical display.

Step 210, obtaining a th communication view among nodes of the th layer in the direct current engineering tree structure diagram from the communication view corresponding to each layer of nodes, and displaying a th communication view among nodes of the th layer.

Wherein the th communication view corresponds to the th level node.

Step 211, receiving a th preset operation for the th communication block in the th communication view, responding to the th preset operation, and displaying a logic loop index view corresponding to the th communication block.

Step 212, receiving a second preset operation for a second communication block in the th logical loop index view, responding to the second preset operation, and displaying a second communication view corresponding to the second communication block.

Step 213, receiving a third preset operation for the connection line of the second communication view, and displaying a signal transmission view corresponding to the second communication view.

And step 214, receiving a fourth preset operation of the connecting line aiming at the th communication view, responding to the third preset operation, and displaying a third communication view.

Wherein the second communication view includes an identification of a node of the sub-tree.

Step 215, receiving a fifth preset operation of the connection line for the third communication view, responding to the fifth preset operation, and displaying a signal transmission view corresponding to the third communication view.

Based on the foregoing embodiment, as shown in fig. 15, after the data processing apparatus executes step 215, the following steps 216 to 218 may be further executed:

and step 216, acquiring a pre-stored direct current engineering physical structure diagram.

The direct current engineering physical structure diagram is created by physical model symbols corresponding to each node in the direct current engineering tree structure diagram.

In the embodiment of the present invention, the pre-stored physical structure diagram of the dc engineering may be pre-provided by a user, and may be obtained by the user according to pre-provided physical models including a cabinet, a dc protection system chassis, a switch, an optical fiber, a network cable, and the like. For example, the pre-stored physical model may be as shown in fig. 16 to 18, where fig. 16 is a schematic diagram of a panel H1 and a backplane H2 of a dc protection system chassis, a panel H3 and a backplane H4 of a switch, fig. 17 is a schematic diagram of a cabinet provided with a dc protection system chassis and a switch, and fig. 18 is a schematic diagram of a plurality of cabinets connected by optical fibers or network cables. For example, the structure of the direct current engineering physical structure obtained according to fig. 16 to 18 is shown in fig. 19.

And step 217, mapping and associating the th sub-physical structure diagram in the direct current engineering physical structure diagram with the target link diagram.

In the embodiment of the present invention, the th sub-physical structure diagram is a partial direct current engineering physical structure diagram in which the data processing device in the direct current engineering physical structure diagram can automatically perform mapping association according to a target link diagram, where mapping association refers to that when a certain structure in the direct current engineering physical structure diagram is operated, the data processing device can jump to a corresponding link in the target link diagram, and as shown in fig. 19, the direct current engineering physical structure diagram of the station 1 and the direct current engineering physical structure diagram of the station 2 can automatically perform mapping association according to the target link diagram, so as to implement a connected logical link.

And step 218, receiving the mapping association operation, responding to the mapping association operation, and performing mapping association on a second sub-physical structure diagram in the direct current engineering physical structure diagram to obtain a target direct current engineering visual diagram.

The second sub-physical structure diagram is a physical link which cannot be automatically mapped and associated based on the target link diagram in the direct-current engineering physical structure diagram.

In this embodiment of the present invention, the mapping association operation may be sent by the user based on the second sub-physical structure diagram in the direct current engineering physical structure diagram, for example, right-clicking the th link in the second physical structure diagram to select "link association", and the second link in the second physical structure diagram may be selected in the pop-up interface to obtain the mapping association operation, so that the mapping association operation may be performed by jumping from the th link to the second link, so as to implement mapping association of the second sub-physical structure diagram in the direct current engineering physical structure diagram.

Based on the foregoing embodiment, as shown in fig. 20, after the data processing apparatus executes step 218, the following steps may be further executed:

step 219, inputting a reference variable in the target direct current engineering visual image to perform fault location analysis.

In other embodiments of the present invention, step 219 may be specifically realized by the following steps d 1-d 3:

and d1, receiving the input signal to obtain a reference variable.

In the embodiment of the present invention, the input signal may be obtained by connecting a target dc engineering visible view to a host in a dc conversion engineering through a network/serial port, and the reference variable may be obtained by issuing a variable name by double-clicking a connection line in a signal transmission view or a connection line in a visible page as shown in fig. 13.

And d2, obtaining an output result when the communication channel or the communication port in the target direct current engineering visual image is transmitted based on the reference variable.

In an embodiment of the present invention, the output result of the symbol, for example, OK or Error, is monitored according to the channel/port status in the visualization program page.

And d3, determining whether the communication channel or the communication port is conducted or not based on the output result to perform fault location analysis.

In the embodiment of the invention, if the output result is OK, the physical circuit outputting the output result can be determined to be normal; if the output result is Error, it can be determined that the physical loop outputting the output result has a fault.

And step 220, if the fault exists, outputting fault prompt information at the fault position of the target direct current engineering visual image.

In the embodiment of the present invention, when there is a fault, outputting the fault prompting information at the fault location visible in the target dc engineering may be to mark the fault location with red, and specifically, the connection line of the physical circuit of the fault location may be set as a red connection line.

It should be noted that, for the descriptions of the same steps and the same contents in this embodiment as those in other embodiments, reference may be made to the descriptions in other embodiments, which are not described herein again.

The embodiment of the invention provides data processing methods, which includes obtaining at least visual programs based on a DC engineering tree structure diagram after obtaining a pre-stored DC engineering tree structure diagram, obtaining data transceiving information of nodes in the DC engineering tree structure diagram from at least visual programs, and then creating a target link diagram based on the data transceiving information and the DC engineering tree structure diagram, so that the target link diagram with the hierarchical state monitoring function for the DC control protection system is created based on the DC engineering tree structure diagram and the corresponding data transceiving information in at least visual programs, the problems of less optimization design and control of a secondary circuit of the DC control protection system in the prior art are solved, the scheme of optimization design and control of the secondary circuit of the DC control protection system is enriched, the state monitoring function for the DC control protection system can be visually and hierarchically displayed, the target DC engineering visual view is set in the step , and can be identified and utilized by a visual tool, the fault location analysis is realized, the problems of difficult fault location and unintuitive state monitoring in the prior art are solved, and the target DC engineering visual monitoring function can be conveniently performed based on the target DC engineering tree structure diagram.

Based on the foregoing embodiments, an embodiment of the present invention provides data processing apparatuses, which can be applied to the data processing methods provided in the embodiments corresponding to fig. 1-2, 15, and 20, and as shown in fig. 21, the data processing apparatus 3 may include a processor 31, a memory 32, and a communication bus 33, where:

the communication bus 33 is used for realizing communication connection between the processor 31 and the memory 32;

the processor 31 is configured to execute a data processing program stored in the memory 32 to implement the following steps:

acquiring a pre-stored direct current engineering tree structure diagram;

acquiring at least visual programs based on the direct current engineering tree structure chart, wherein at least visual programs correspond to at least target devices in the direct current engineering tree structure chart;

acquiring data transceiving information among nodes in the direct current engineering tree structure chart from at least visualization programs;

creating a target link diagram based on data receiving and transmitting information and the direct current engineering tree structure diagram;

and sequentially displaying a plurality of views in the target link diagram based on the hierarchy of the direct current engineering tree structure diagram.

In other embodiments of the present invention, the processor is further configured to execute the following steps of obtaining data transmission and reception information between nodes in the dc engineering tree structure diagram from at least visualization programs:

acquiring data transceiving symbols of nodes in the direct current engineering tree structure diagram from at least visualization programs;

and analyzing the data transceiving symbol to obtain data transceiving information.

In other embodiments of the present invention, the processor is further configured to create a target link map based on the data transceiving information and the dc engineering tree structure map, so as to implement:

acquiring a subtree of a node at the th layer in the direct current engineering tree structure chart, and creating a logic loop index view corresponding to the subtree based on the communication type and the communication mode corresponding to the subtree in the subtree and data transceiving information;

acquiring the communication relationship between nodes of each layers in the direct current engineering tree structure diagram from data transceiving information, and establishing a communication view corresponding to each layers of nodes based on the communication relationship between the nodes of each layers;

acquiring nodes with a front-back communication connection relation in a direct current engineering attribute structure diagram, and communication variables and communication ports between the nodes with the front-back communication connection relation from data transceiving information;

establishing a signal transmission view corresponding to the nodes with the front-back connection relation based on the nodes with the front-back connection relation, the communication variables and the communication ports between the nodes with the front-back connection relation;

and according to the hierarchical relationship in the direct current engineering tree structure chart, sequentially setting a logic loop index view corresponding to the subtree, a communication view corresponding to each -layer node and a signal transmission view corresponding to the node with the front-back connection relationship to obtain a target link chart.

In other embodiments of the present invention, the processor is further configured to execute a hierarchy based on the dc engineering tree structure diagram, and sequentially display a plurality of views included in the target link diagram, so as to implement the following steps:

acquiring a th communication view between nodes of a th layer in the direct current engineering tree structure diagram from a communication view corresponding to each layer of nodes, and displaying a th communication view between nodes of a th layer, wherein a th communication view corresponds to nodes of an th layer;

receiving a th preset operation aiming at a th communication block in an th communication view, responding to a th preset operation, and displaying a logic loop index view corresponding to a th communication block;

receiving a second preset operation aiming at a second communication block in the th logical loop index view, responding to the second preset operation, and displaying a second communication view corresponding to the second communication block;

receiving a third preset operation of a connecting line aiming at the second communication view, and displaying a signal transmission view corresponding to the second communication view;

receiving a fourth preset operation aiming at a connecting line of the th communication view, responding to the third preset operation, and displaying a third communication view, wherein the second communication view comprises the identification of the node of the subtree;

and receiving a fifth preset operation of the connecting line aiming at the third communication view, responding to the fifth preset operation, and displaying a signal transmission view corresponding to the third communication view.

In other embodiments of the present invention, the processor is further configured to, after creating the target link map based on the data transceiving information and the dc engineering tree structure map, perform the following steps:

acquiring a pre-stored direct current engineering physical structure diagram, wherein the direct current engineering physical structure diagram is created by physical model symbols corresponding to each node in a direct current engineering tree structure diagram;

mapping and associating the th sub-physical structure diagram in the direct-current engineering physical structure diagram with a target link diagram, wherein the th sub-physical structure diagram has a corresponding relation with the target link diagram;

and receiving a mapping association operation, responding to the mapping association operation, and performing mapping association on a second sub-physical structure diagram in the direct current engineering physical structure diagram to obtain a target direct current engineering visual diagram, wherein the target direct current engineering visual diagram is used for realizing cross indexing and jumping between the direct current engineering physical structure diagram and a target link diagram, and the second sub-physical structure diagram is a physical structure diagram in the direct current engineering physical structure diagram except for the th sub-physical structure diagram.

In other embodiments of the present invention, the processor is further configured to execute a receive mapping association operation, perform mapping association on the second sub-physical structure diagram in the direct current engineering physical structure diagram in response to the mapping association operation, and after obtaining the target direct current engineering visual diagram, further execute the following steps:

inputting a reference variable in a visual image of a target direct current project to perform fault location analysis;

and if the fault exists, outputting fault prompt information at the fault position visible in the target direct current project.

In other embodiments of the present invention, the processor is further configured to perform fault location analysis by inputting a reference variable in the target dc engineering visual map, so as to implement the following steps:

receiving an input signal to obtain a reference variable;

obtaining an output result when the reference variable is transmitted in a communication channel or a communication port in the target direct current engineering visual image;

and determining whether the communication channel or the communication port is conducted or not based on the output result to perform fault location analysis.

In other embodiments of the present invention, the dc engineering tree structure stored in the memory comprises:

each node in th layer in the tree structure diagram of the direct current engineering represents 0 converter stations in the direct current engineering, each 1 node in the second layer represents 2 poles in the direct current engineering, each 3 node in the third layer represents 4 systems in the direct current engineering, each 5 node in the fourth layer represents control protection hosts in the direct current engineering, each node in the fifth layer represents input and output IO devices in the direct current engineering, the direct current engineering comprises at least two converter stations, each converter station comprises at least two poles, each pole comprises two systems, each system comprises at least control protection hosts, and each control protection host manages the input and output IO devices.

It should be noted that, for a specific implementation process of the steps executed by the processor in this embodiment, reference may be made to the implementation processes in the data processing method provided in the embodiments corresponding to fig. 1 to 2, 15, and 20, and details are not described here.

The embodiment of the invention provides data processing equipment, which acquires at least visual programs based on a DC engineering tree structure diagram after acquiring a pre-stored DC engineering tree structure diagram, acquires data transceiving information of nodes in the DC engineering tree structure diagram from at least visual programs, and then creates a target link diagram based on the data transceiving information and the DC engineering tree structure diagram, so that the target link diagram with the hierarchical state monitoring function for the DC control protection system is created based on the DC engineering tree structure diagram and the corresponding data transceiving information in at least visual programs, the problem that the optimization design and control of a secondary circuit of the DC control protection system are less in the prior art is solved, the scheme of the optimization design and control of the secondary circuit of the DC control protection system is enriched, the state monitoring of the DC control protection system can be visually and hierarchically displayed, the step of is carried out, the target DC engineering visual view is set, and can be identified and utilized by a visual tool, the fault location analysis is realized, the problem that the fault location is difficult and the state monitoring is not intuitive in the prior art is facilitated, and the target DC engineering visual monitoring function can be conveniently carried out based on the target DC engineering tree structure diagram.

Based on the foregoing embodiments, an embodiment of the present invention provides computer-readable storage media, which can be applied to the methods provided in the embodiments corresponding to fig. 1-2, 15, and 20, and the computer-readable storage media stores or more programs, and the or more programs can be executed by the or more processors to implement the following steps:

acquiring a pre-stored direct current engineering tree structure diagram;

acquiring at least visual programs based on the direct current engineering tree structure chart, wherein at least visual programs correspond to at least target devices in the direct current engineering tree structure chart;

acquiring data transceiving information among nodes in the direct current engineering tree structure chart from at least visualization programs;

creating a target link diagram based on data receiving and transmitting information and the direct current engineering tree structure diagram;

and sequentially displaying a plurality of views in the target link diagram based on the hierarchy of the direct current engineering tree structure diagram.

In other embodiments of the present invention, the processor is further configured to execute the following steps of obtaining data transmission and reception information between nodes in the dc engineering tree structure diagram from at least visualization programs:

acquiring data transceiving symbols of nodes in the direct current engineering tree structure diagram from at least visualization programs;

and analyzing the data transceiving symbol to obtain data transceiving information.

In other embodiments of the present invention, the processor is further configured to create a target link map based on the data transceiving information and the dc engineering tree structure map, so as to implement:

acquiring a subtree of a node at the th layer in the direct current engineering tree structure chart, and creating a logic loop index view corresponding to the subtree based on the communication type and the communication mode corresponding to the subtree in the subtree and data transceiving information;

acquiring the communication relationship between nodes of each layers in the direct current engineering tree structure diagram from data transceiving information, and establishing a communication view corresponding to each layers of nodes based on the communication relationship between the nodes of each layers;

acquiring nodes with a front-back communication connection relation in a direct current engineering attribute structure diagram, and communication variables and communication ports between the nodes with the front-back communication connection relation from data transceiving information;

establishing a signal transmission view corresponding to the nodes with the front-back connection relation based on the nodes with the front-back connection relation, the communication variables and the communication ports between the nodes with the front-back connection relation;

and according to the hierarchical relationship in the direct current engineering tree structure chart, sequentially setting a logic loop index view corresponding to the subtree, a communication view corresponding to each -layer node and a signal transmission view corresponding to the node with the front-back connection relationship to obtain a target link chart.

In other embodiments of the present invention, the processor is further configured to execute a hierarchy based on the dc engineering tree structure diagram, and sequentially display a plurality of views included in the target link diagram, so as to implement the following steps:

acquiring a th communication view between nodes of a th layer in the direct current engineering tree structure diagram from a communication view corresponding to each layer of nodes, and displaying a th communication view between nodes of a th layer, wherein a th communication view corresponds to nodes of an th layer;

receiving a th preset operation aiming at a th communication block in an th communication view, responding to a th preset operation, and displaying a logic loop index view corresponding to a th communication block;

receiving a second preset operation aiming at a second communication block in the th logical loop index view, responding to the second preset operation, and displaying a second communication view corresponding to the second communication block;

receiving a third preset operation of a connecting line aiming at the second communication view, and displaying a signal transmission view corresponding to the second communication view;

receiving a fourth preset operation aiming at a connecting line of the th communication view, responding to the third preset operation, and displaying a third communication view, wherein the second communication view comprises the identification of the node of the subtree;

and receiving a fifth preset operation of the connecting line aiming at the third communication view, responding to the fifth preset operation, and displaying a signal transmission view corresponding to the third communication view.

In other embodiments of the present invention, the processor is further configured to, after creating the target link map based on the data transceiving information and the dc engineering tree structure map, perform the following steps:

acquiring a pre-stored direct current engineering physical structure diagram, wherein the direct current engineering physical structure diagram is created by physical model symbols corresponding to each node in a direct current engineering tree structure diagram;

mapping and associating the th sub-physical structure diagram in the direct-current engineering physical structure diagram with a target link diagram, wherein the th sub-physical structure diagram has a corresponding relation with the target link diagram;

and receiving a mapping association operation, responding to the mapping association operation, and performing mapping association on a second sub-physical structure diagram in the direct current engineering physical structure diagram to obtain a target direct current engineering visual diagram, wherein the target direct current engineering visual diagram is used for realizing cross indexing and jumping between the direct current engineering physical structure diagram and a target link diagram, and the second sub-physical structure diagram is a physical structure diagram in the direct current engineering physical structure diagram except for the th sub-physical structure diagram.

In other embodiments of the present invention, the processor is further configured to execute a receive mapping association operation, perform mapping association on the second sub-physical structure diagram in the direct current engineering physical structure diagram in response to the mapping association operation, and after obtaining the target direct current engineering visual diagram, further execute the following steps:

inputting a reference variable in a visual image of a target direct current project to perform fault location analysis;

and if the fault exists, outputting fault prompt information at the fault position visible in the target direct current project.

In other embodiments of the present invention, the processor is further configured to perform fault location analysis by inputting a reference variable in the target dc engineering visual map, so as to implement the following steps:

receiving an input signal to obtain a reference variable;

obtaining an output result when the reference variable is transmitted in a communication channel or a communication port in the target direct current engineering visual image;

and determining whether the communication channel or the communication port is conducted or not based on the output result to perform fault location analysis.

In other embodiments of the present invention, the dc engineering tree structure stored in the memory comprises:

each node in th layer in the tree structure diagram of the direct current engineering represents 0 converter stations in the direct current engineering, each 1 node in the second layer represents 2 poles in the direct current engineering, each 3 node in the third layer represents 4 systems in the direct current engineering, each 5 node in the fourth layer represents control protection hosts in the direct current engineering, each node in the fifth layer represents input and output IO devices in the direct current engineering, the direct current engineering comprises at least two converter stations, each converter station comprises at least two poles, each pole comprises two systems, each system comprises at least control protection hosts, and each control protection host manages the input and output IO devices.

It should be noted that, in the embodiment of the present invention, the explanation of the steps of the plurality of programs that can be processed by or the plurality of processors may refer to the implementation process in the data processing method provided in the embodiments corresponding to fig. 1 to 2, 15, and 20, and is not described here again.

Furthermore, the present invention may take the form of a computer program product embodied on or more computer-usable storage media (including, but not limited to, disk storage, optical storage, and the like) having computer-usable program code embodied therein.

It is to be understood that each flow and/or block in 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 which can 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 flow diagram 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.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention.

Claims (10)

1, A data processing method, characterized in that the method comprises:

acquiring a pre-stored direct current engineering tree structure diagram;

acquiring at least visualization programs based on the direct current engineering tree structure chart, wherein the at least visualization programs correspond to at least target devices in the direct current engineering tree structure chart;

acquiring data transceiving information among nodes in the direct current engineering tree structure diagram from at least visualization programs;

creating a target link diagram based on the data transceiving information and the direct current engineering tree structure diagram;

and sequentially displaying a plurality of views in the target link diagram based on the hierarchy of the direct current engineering tree structure diagram.

2. The method according to claim 1, wherein said obtaining data transmission and reception information between nodes in said dc engineering tree structure diagram from said at least visualization programs comprises:

acquiring data transceiving symbols of nodes in the direct current engineering tree structure diagram from at least visualization programs;

and analyzing the data transceiving symbol to obtain the data transceiving information.

3. The method according to claim 1 or 2, wherein the creating a target link map based on the data transceiving information and the dc engineering tree structure map comprises:

acquiring a subtree of a node at layer in the direct current engineering tree structure diagram, and creating a logic loop index view corresponding to the subtree based on the subtree and a communication type and a communication mode corresponding to the subtree in the data transceiving information;

acquiring the communication relationship between each layer of nodes in the direct current engineering tree structure diagram from the data transceiving information, and creating a communication view corresponding to each layer of nodes based on the communication relationship between each layer of nodes;

acquiring nodes with front-back communication connection relation in the direct current engineering attribute structure diagram, and communication variables and communication ports between the nodes with the front-back communication connection relation from the data transceiving information;

establishing a signal transmission view corresponding to the nodes with the front-back connection relation based on the nodes with the front-back connection relation, communication variables and communication ports among the nodes with the front-back connection relation;

and sequentially setting a logic loop index view corresponding to the subtree, a communication view corresponding to each -layer node and a signal transmission view corresponding to the node with the front-back connection relation according to the hierarchical relation in the direct-current engineering tree structure diagram to obtain the target link diagram.

4. The method according to claim 3, wherein said sequentially presenting a plurality of views included in the target link map based on the hierarchy of the dc engineering tree structure map comprises:

acquiring a th communication view between nodes at the th layer in the direct current engineering tree structure diagram from the communication view corresponding to each layer of nodes, and displaying a th communication view between nodes at the th layer, wherein the th communication view corresponds to the nodes at the th layer;

receiving a th preset operation aiming at the th communication block in the th communication view, responding to the th preset operation, and displaying a logic loop index view corresponding to the th communication block;

receiving a second preset operation aiming at a second communication block in the th logical loop index view, responding to the second preset operation, and displaying a second communication view corresponding to the second communication block;

receiving a third preset operation aiming at a connecting line of the second communication view, and displaying a signal transmission view corresponding to the second communication view;

receiving a fourth preset operation aiming at a connecting line of the th communication view, responding to the third preset operation, and displaying a third communication view, wherein the second communication view comprises the identifier of the node of the subtree;

and receiving a fifth preset operation aiming at the connecting line of the third communication view, responding to the fifth preset operation, and displaying a signal transmission view corresponding to the third communication view.

5. The method according to claim 1 or 4, wherein after creating a target link map based on the data transceiving information and the DC engineering tree structure map, the method further comprises:

acquiring a pre-stored direct current engineering physical structure diagram, wherein the direct current engineering physical structure diagram is created by a physical model symbol corresponding to each node in the direct current engineering tree structure diagram;

mapping and associating an th sub-physical structure diagram in the direct-current engineering physical structure diagram with the target link diagram, wherein the th sub-physical structure diagram has a corresponding relation with the target link diagram;

receiving a mapping association operation, and performing mapping association on a second sub-physical structure diagram in the direct-current engineering physical structure diagram in response to the mapping association operation to obtain a target direct-current engineering visual diagram, wherein the target direct-current engineering visual diagram is used for realizing cross indexing and jumping between the direct-current engineering physical structure diagram and the target link diagram, and the second sub-physical structure diagram is a physical structure diagram in the direct-current engineering physical structure diagram except the th sub-physical structure diagram.

6. The method according to claim 5, wherein after receiving the mapping association operation and performing mapping association on the second sub-physical structure diagram in the direct current engineering physical structure diagram in response to the mapping association operation to obtain a target direct current engineering visible view, the method further comprises:

inputting a reference variable in the target direct current engineering visual image to perform fault location analysis;

and if the fault exists, outputting fault prompt information at the fault part of the target direct current project visual image.

7. The method according to claim 6, wherein the inputting of the reference variable in the target direct current engineering visual for fault location analysis comprises:

receiving an input signal to obtain the reference variable;

obtaining an output result when the reference variable is transmitted in a communication channel or a communication port in the target direct current engineering visual image;

and determining whether the communication channel or the communication port is conducted or not based on the output result to perform the fault location analysis.

8. The method of claim 1, 6 or 7,

each node in th layer in the direct current engineering tree structure diagram represents 0 converter stations in direct current engineering, each 1 node in the second layer represents 2 poles in direct current engineering, each 3 node in the third layer represents 4 systems in direct current engineering, each 5 node in the fourth layer represents control protection hosts in direct current engineering, each node in the fifth layer represents input and output IO devices in direct current engineering, the direct current engineering comprises at least two converter stations, each converter station comprises at least two poles, each pole comprises two systems, each system comprises at least control protection hosts, and each control protection host manages the input and output IO devices.

A data processing apparatus of the type , comprising a processor, a memory and a communication bus, wherein:

the memory to store executable instructions;

the communication bus is used for realizing communication connection between the processor and the memory;

the processor, configured to execute the data processing program stored in the memory, to implement the data processing method according to any of claims 1 to 8.

10, computer-readable storage medium, characterized in that the storage medium has stored thereon a data processing program which, when executed by a processor, carries out the steps of the data processing method according to any of claims 1 to 8 to .

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