CN104168138A - Electric power communication network system centralized topology generation and display method - Google Patents

Abstract

The invention relates to a centralized topology generation and display method for a power communication network system, belonging to the technical field of data exchange networks. The power communication network is composed of multiple heterogeneous networks. The heterogeneous network includes one or more sub-networks. Each sub-network includes one or more network managers. The network management includes one or more sets of network elements, and the network elements are composed of one or more devices. , the device includes a virtual machine and a physical machine, and the steps of the method are as follows: 1) By traversing the power communication network; 2) Screening out and deleting duplicate connections; 3) Generating a topology map; 4) Adding to the generated topology map Repeat the connection relationship to complete the network topology display of the power communication network. This method completes the generation of the full topology map, and adopts different map scales, so that the entire topology map can be scaled according to a specific scale; all kinds of functional equipment are displayed on one map, so this topological map can also be used for The management and planning service of the electric power communication network can achieve real-time feedback and follow-up step by step.

Description

A centralized topology generation display method for power communication network system

technical field

The invention relates to a method for generating and displaying a topology, belonging to the technical field of data exchange networks.

Background technique

The power communication network is divided into several heterogeneous networks according to the technology adopted or the services provided. These heterogeneous networks include PLC network, wireless public network, wireless private network, wireless access network, industrial Ethernet switching network, etc. The data information in this communication network is generally stored in the main server or the servers of various heterogeneous networks. And each heterogeneous network will be subdivided into multiple sub-networks. Each sub-network is not independent, but interacts with each other. Not only that, each heterogeneous network also cooperates with each other to provide users with various business services. Most of the subnet management systems (Subnet Management System, SNMS or Element Management System, EMS) of heterogeneous networks can only perform vertical management, and are only responsible for the management of the subnetwork.

In actual use, various services in the communication network generally span multiple heterogeneous networks, and the whole process of end-to-end management refers to the management of the entire process of communication services across heterogeneous networks from the start of the communication service to the end of the service end. . However, because the existing manufacturer's network management can only confirm the devices in the heterogeneous network according to the topological relationship of each heterogeneous network, and the topological relationship between the heterogeneous networks is difficult to know, it is difficult to directly and effectively manage it. In the case of equipment maintenance, since the manufacturers, technical systems, and communication systems of each access equipment are different, it is easy to cause blind spots in information exchange. Moreover, a complete device integrates various functions, usually presented in the form of a virtual machine, and these functions are different. It is not enough to display only the model name of the complete device, but it is not conducive to the maintenance and management of the device.

Contents of the invention

The technical problem to be solved by the present invention is to propose a method for generating and displaying a centralized topology of a power communication network system to completely integrate the power communication network system on a topological map.

The technical solution proposed by the present invention to solve the above technical problems is: a centralized topology generation and display method for a power communication network system, the power communication network is composed of multiple heterogeneous networks, and the heterogeneous network includes one or more sub-networks, Each sub-network contains one or more network managers, and the network manager contains one or more network element sets, and the network elements are composed of one or more devices, and the devices include virtual machines and physical machines. The method steps are as follows:

1) Invoke the first connection line and first information between the network managers, the second connection line and second information between the network elements, and the third connection between the devices from the database of the power communication network. connecting lines and third information;

The first information includes the name of the network manager and the actual coordinates of the network manager, the second information includes the name of the network element and the actual coordinates of the network element, and the third information includes the name of the device and the actual coordinates of the device;

The first connection line is a physical connection line between network managers; the second line is a physical connection line between network elements; the third connection line includes a physical connection line and/or a logical connection line;

2) Screening the first connecting line, the second connecting line, and the third connecting line, finding and deleting the repeated connecting lines among the first connecting line, the second connecting line, and the third connecting line;

3) First, on a blank map, the coordinates on each network management map are converted according to the first map scale according to the actual coordinates of each network management system, and the name of each network management system is marked on the coordinates of each network management map. A connection line connects the coordinates on the map of all network management to complete the generation of the first topology map;

Then, with the coordinates on the map of each network manager as the relative center, divide the first topology map into several equal-area and disjoint large areas, determine the large areas where each network element is located according to the actual coordinates of each network element, and then according to each The actual coordinates of the network elements are calculated according to the second map scale in the large area where each network element is located, and the coordinates on each network element map are converted, and the name of each network element is marked on the coordinates of each network element map. The second connection line connects the coordinates on all network element diagrams to complete the generation of the second topology diagram;

Finally, take the coordinates on the map of each network element as the relative center, divide several equal-area and non-intersecting cells in the large area where each network element is located, determine the cell where each device is located according to the actual coordinates of each device, and then according to the coordinates of each device by The third map scale converts the coordinates on each equipment map in the district where each equipment is located, marks the equipment name of each equipment at the coordinates on each equipment map, and performs all coordinates on the equipment map according to the third connection line that has been deleted. Connect to complete the generation of the third topology map;

said first scale is smaller than said second scale, said second scale is smaller than said third scale;

4) Add the repeated connection lines screened in step 2) to the third topology diagram to complete the centralized topology display of the power communication network system.

The beneficial effect of adopting the above-mentioned technical solution in the present invention is: since the existing network management cannot centrally display such a large-scale equipment access information (or it is called the power communication network system), at most it only It is shown separately that when an emergency alarm occurs, managers often need to compare the cross-relationships between the networks to make a correct judgment.

Therefore, this method centrally displays each component of the electric power communication network, so that a large amount of information can be displayed centrally on a topological map. And because of the use of different scales, the entire topology map can be scaled according to a specific ratio, and the display in the map will not be too cramped and unclear due to the relative location of the devices, making the whole map clearer and easier to use. This method finally displays all kinds of functional equipment on one map, so this topological map can also serve the management and planning of the power communication network well, and achieve real-time feedback and step-by-step tracking. In addition, different scales are used for conversion, so that the information distributed on the entire topological map is neither too scattered nor too cramped, making it easy to find.

The improvement of the above technical solution is: the physical connection line refers to the actual connection line between each network management, each network element, and each device, and the logical connection line is between each virtual machine and the physical machine in the network element and/or Or connect lines between virtual machines.

The improvement of the above technical solution is that for the equipment that can only obtain the third connection line in step 1), use the following method to obtain its third information and add it to the centralized topology display diagram of the power communication network system: Use a handheld GPS positioning device to obtain the third information The GIS coordinates of the device, and then convert the cell coordinates of the device in its corresponding cell with the third scale, and add the device to the centralized topology display diagram of the power communication network system according to the cell coordinates.

The beneficial effect of adopting the above-mentioned technical solution in the present invention is that in the power communication network system, many devices not only realize a single function, but more often integrate functions, and integrate multiple virtual devices based on one host. machines to meet different functional requirements. Moreover, because the power communication network system needs to realize many functions and complicated services, the network system itself is bulky and there are many access devices, it is difficult to guarantee that the devices will not be used due to one or another reason (among them, as mentioned in the background technology). mentioned situation) and cannot communicate with each other, resulting in a waste of equipment idle resources.

Therefore, this method adds network management, network elements, physical machines and virtual machines, and physical and/or logical connection lines between them in the topology map, and displays the virtual machines in the topology map. And for some devices that can only obtain the third connection line but not the third connection information, this method provides an obtaining method, and adds the obtained information into the figure, so that the devices that cannot be displayed before are also included in the It is shown in the figure, which is convenient for management personnel to understand the complete regional equipment access situation, and is conducive to the overall management and rational use of resources by relevant personnel.

The improvement of the above technical solution is: the third information also includes the area number, substation site number, machine room number, cabinet number, frame number, slot number, board number and port number related to the device.

The improvement of the above technical solution is: the blank drawing is a blank drawing.

The improvement of the above technical solution is: the blank picture is an LED liquid crystal display panel.

The beneficial effect of adopting the above-mentioned technical solution in the present invention is: in order to fully display the electric power communication network system, the third information of this method can be further improved, and when using the further improved topology map to query equipment, a more comprehensive equipment-related information can be obtained from it. Information, at the same time, this method can make topological maps by hand, and can also make topological maps by machine.

Description of drawings

The present invention will be further described below in conjunction with accompanying drawing:

Fig. 1 is a schematic diagram of the production service network of Baixia Road and Baixia Road power grid in this embodiment.

Fig. 2 is a schematic diagram of the production and service network of Baixia Road and Yunnan Road power grids in this embodiment.

Detailed ways

Example

In this embodiment, a method for generating and displaying a centralized topology of a power communication network system, the power communication network is composed of a plurality of heterogeneous networks, and the heterogeneous network includes one or more sub-networks, and each sub-network contains one or more network managers , the network management includes one or more sets of network elements, the network elements are composed of one or more devices, and the devices include virtual machines and physical machines. The steps of the method are as follows:

1) Invoke the first connection line and first information between the network managers, the second connection line and second information between the network elements, and the third connection between the devices from the database of the power communication network. connecting lines and third information;

The first information includes the name of the network manager and the actual coordinates of the network manager, the second information includes the name of the network element and the actual coordinates of the network element, and the third information includes the name of the device and the actual coordinates of the device;

The first connection line is a physical connection line between network managers; the second line is a physical connection line between network elements; the third connection line includes a physical connection line and/or a logical connection line;

2) Screening the first connecting line, the second connecting line, and the third connecting line, finding and deleting the repeated connecting lines among the first connecting line, the second connecting line, and the third connecting line;

3) First, on a blank map, the coordinates on each network management map are converted according to the first map scale according to the actual coordinates of each network management system, and the name of each network management system is marked on the coordinates of each network management map. A connection line connects the coordinates on the map of all network management to complete the generation of the first topology map;

Then, with the coordinates on the map of each network manager as the relative center, divide the first topology map into several equal-area and disjoint large areas, determine the large areas where each network element is located according to the actual coordinates of each network element, and then according to each The actual coordinates of the network elements are calculated according to the second map scale in the large area where each network element is located, and the coordinates on each network element map are converted, and the name of each network element is marked on the coordinates of each network element map. The second connection line connects the coordinates on all network element diagrams to complete the generation of the second topology diagram;

Finally, take the coordinates on the map of each network element as the relative center, divide several equal-area and non-intersecting cells in the large area where each network element is located, determine the cell where each device is located according to the actual coordinates of each device, and then according to the coordinates of each device by The third map scale converts the coordinates on each equipment map in the district where each equipment is located, marks the equipment name of each equipment at the coordinates on each equipment map, and performs all coordinates on the equipment map according to the third connection line that has been deleted. Connect to complete the generation of the third topology map;

said first scale is smaller than said second scale, said second scale is smaller than said third scale;

4) Add the repeated connection lines screened in step 2) to the third topology diagram to complete the centralized topology display of the power communication network system.

The physical connection line in this embodiment refers to the actual connection line between each network manager, each network element, and each device, and the logical connection line is between each virtual machine and physical machine in the network element and/or each virtual machine. Inter-machine connection lines.

This embodiment is aimed at devices that can only obtain the third connection line but cannot obtain the third information in step 1) (there are various reasons for this situation, one of which is as mentioned in the background technology because of various Manufacturers provide equipment standard differences), use the following method to obtain the third information and add it to the centralized topology display diagram of the power communication network system: use a handheld GPS positioning device to obtain the GIS coordinates of the equipment, and then use the third scale to convert the The cell coordinates of the device in its corresponding cell, and add the device to the centralized topology display diagram of the power communication network system according to the cell coordinates.

The third information in this embodiment also includes the area number, substation site number, machine room number, cabinet number, frame number, slot number, board number and port number related to the device.

In this embodiment, the above steps can be completed in a blank drawing, or a PC and other tools can be used to finally generate the topology map on the LED liquid crystal display panel.

Figure 1 is the power grid production and business network in Nanjing. The topological diagram between Baixia Road and Baixia Road is displayed on the third scale. In the figure, two Baixia Substation OLTs (192.18.254.253) of the same level are connected, and they are connected to each other. It is connected to several network element sets under it, and some devices are also connected to the network element set.

Figure 2 is the power grid production and business network in Nanjing. The topological map between Baixia Road and Yunnan Road is displayed on the third scale. In the figure, Yunnan Road Substation OLT (192.18.254.253) is connected to Baixia Road Substation OLT (192.18.254.252) , and each of them is connected to a number of network element sets under it, and some devices are also connected to the network element set.

Figure 1 and Figure 2 can be displayed on a topological map by the second scale, but only Yunnan Road Transformer OLT (192.18.254.253) and Baixia Road Transformer OLT (192.18 .254.253), Baixia Road Substation OLT (192.18.254.252) or other road-level substations, but will not display the network element set connected under it or the equipment under the network element set.

The topological map displayed at the first scale will not show Yunnan Road to OLT (192.18.254.253), Baixia Road to OLT (192.18.254.253), Baixia Road to OLT (192.18.254.252) or other roads Level substations are replaced by displaying higher-level or higher-level connection relationships. Finally, through this layer-by-layer relationship, nationwide coverage and display can be realized. Of course, at this stage, city-level display is realized. In the future, the provincial display and regional display will be gradually completed.

Specifically, the first, second, and third scales can be set individually according to the area of the city, or a unified scale can be set. The third scale of this embodiment is 1:5000, that is, 1 centimeter on the figure represents the actual 50 meters, the second scale is 1:20000, that is, 1 centimeter on the figure represents the actual 200 meters, and the third scale is 1:200000, that is, on the figure 1 centimeter represents the actual 2 kilometers.

This embodiment is based on the IBM Ilog engine, and on the basis of its functions, it has been expanded for actual application requirements to display a variety of different network elements and topologies with different graphic elements, which are icons corresponding to devices when the topology diagram is displayed; The group set based on the IBM Ilog engine can be expanded or contracted by double-clicking. After expansion and contraction, the graphics can be dynamically re-layouted according to the change of the size of the primitive. When the group shrinks, the topological connections from the outside of the group to the elements in the group will be automatically connected to the group to ensure that the entire network topology remains unchanged.

The entire network display system also implements graphics services for managing graphics and graphic element data in the background service through Java. The main functions of the graphics service are as follows:

(1) Realize the graphical import of graphic elements such as network elements and groups, so that various network elements and groups can be displayed with different icons in the topology diagram;

(2) Automatic graphing: Read the network elements, topology connections and groups contained in the whole network topology from the database, display them in the whole network topology and graph, and automatically layout the graph elements in the topology graph according to the specified algorithm ;

(3) To realize the storage of graphics, the entire graphics data can be serialized and compressed through the defined interface, stored in the database, and the graphics saved in the database can be read, deserialized and sent to the front desk for display;

(4) Graphics service also supports the saving and extraction of historical versions. If the user is not satisfied with the modified graphic style, he can restore the previously saved version.

Through the description of the above embodiments, those skilled in the art can clearly understand that the present invention can be realized by means of software plus necessary general-purpose hardware, and of course also by hardware, but in many cases the former is a better embodiment . Based on this understanding, the essence of the technical solution of the present invention or the part that contributes to the prior art can be embodied in the form of a software product, and the computer software product is stored in a readable storage medium, such as a floppy disk of a computer , a hard disk or an optical disk, etc., including several instructions for enabling a computer device (which may be a personal computer, server, or network device, etc.) to execute the methods described in various embodiments of the present invention.

The above is only a specific embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Anyone skilled in the art can easily think of changes or substitutions within the technical scope disclosed in the present invention. Should be covered within the protection scope of the present invention. Therefore, the protection scope of the present invention should be based on the protection scope of the claims.

Claims (6)

1. A method for generating and displaying a centralized topology of a power communication network system, the power communication network is composed of a plurality of heterogeneous networks, and the heterogeneous network includes one or more sub-networks, each sub-network contains one or more network managers, so The network management includes one or more sets of network elements, and the network elements are composed of one or more devices, and the devices include virtual machines and physical machines. It is characterized in that the steps of the method are as follows: 1) Invoke the first connection line and first information between the network managers, the second connection line and second information between the network elements, and the third connection between the devices from the database of the power communication network. connecting lines and third information; The first information includes the name of the network manager and the actual coordinates of the network manager, the second information includes the name of the network element and the actual coordinates of the network element, and the third information includes the name of the device and the actual coordinates of the device; The first connection line is a physical connection line between network managers; the second line is a physical connection line between network elements; the third connection line includes a physical connection line and/or a logical connection line; 2) Screening the first connecting line, the second connecting line, and the third connecting line, finding and deleting the repeated connecting lines among the first connecting line, the second connecting line, and the third connecting line; 3) First, on a blank map, the coordinates on each network management map are converted according to the first map scale according to the actual coordinates of each network management system, and the name of each network management system is marked on the coordinates of each network management map. A connection line connects the coordinates on the map of all network management to complete the generation of the first topology map; Then, with the coordinates on the map of each network manager as the relative center, divide the first topology map into several equal-area and disjoint large areas, determine the large areas where each network element is located according to the actual coordinates of each network element, and then according to each The actual coordinates of the network elements are calculated according to the second map scale in the large area where each network element is located, and the coordinates on each network element map are converted, and the name of each network element is marked on the coordinates of each network element map. The second connection line connects the coordinates on all network element diagrams to complete the generation of the second topology diagram; Finally, take the coordinates on the map of each network element as the relative center, divide several equal-area and non-intersecting cells in the large area where each network element is located, determine the cell where each device is located according to the actual coordinates of each device, and then according to the coordinates of each device by The third map scale converts the coordinates on each equipment map in the district where each equipment is located, marks the equipment name of each equipment at the coordinates on each equipment map, and performs all coordinates on the equipment map according to the third connection line that has been deleted. Connect to complete the generation of the third topology map; said first scale is smaller than said second scale, said second scale is smaller than said third scale; 4) Add the repeated connection lines screened in step 2) to the third topology diagram to complete the centralized topology display of the power communication network system. 2. The centralized topology generation and display method of electric power communication network system according to claim 1, characterized in that: said physical connection line refers to the actual connection line between each network management, each network element, and each device, and said logical connection The line is a connection line between each virtual machine and a physical machine and/or between each virtual machine in the network element. 3. The centralized topology generation and display method of the power communication network system according to claim 1 or 2, characterized in that, for the equipment that can only obtain the third connection line in step 1), use the following method to obtain its third information and add Go to the centralized topology display diagram of the power communication network system: use a handheld GPS positioning device to obtain the GIS coordinates of the device, then use the third scale to convert the cell coordinates of the device in its corresponding cell, and add the device to the The centralized topology of the power communication network system is shown in the figure. 4. The method for generating and displaying the centralized topology of an electric power communication network system according to claim 3, wherein the third information further includes the area number, substation site number, machine room number, cabinet number, and frame number related to the device. number, slot number, board number, and port number. 5. The method for generating and displaying centralized topology of an electric power communication network system according to claim 4, wherein the blank diagram is a blank drawing. 6. The centralized topology generation and display method of the electric power communication network system according to claim 4, characterized in that: the blank image is an LED liquid crystal display panel.