CN113938303A - Network detection and network management platform based on multi-mode network - Google Patents

Abstract

The invention discloses a network detection and network management platform based on a multi-mode network, which comprises: the network application comprises a content network mode, an identity network identification mode, an information mode, a subdivision network mode, a diversified network support and a plurality of transmission media, wherein the side surface of the network application is connected with diversified network data equipment, and a distributed mode control system is installed in the diversified network data equipment. The invention carries out information comprehensive statistics and specific data display based on the existing network equipment, searches equipment and checks specific operation details through information such as equipment name, ip address, MAC address and the like, carries out data analysis by monitoring network transmission protocols among the equipment, provides an optimization scheme, and carries out configuration modification on the transmission protocols, thereby improving the energy efficiency.

Description

Network detection and network management platform based on multi-mode network

Technical Field

The invention relates to the technical field of multi-modal networks, in particular to a network detection and network management platform based on a multi-modal network.

Background

Based on the existing internet technology, unified management and monitoring are carried out on the access state, the running state, the data reporting and other behaviors of the equipment in the network, and the flexibility and the energy efficiency of the equipment are expanded by taking hardware, software, application and bearing as basic research models. The network communication protocol technology is used as a research basis, and the multimode function presentation, the full-service bearing, the intelligent management control and the protocol programming are used as main research directions, so that the network protocol can be matched and switched with high freedom according to different service scenes, and the efficiency, the safety, the stability and the flexibility of network transmission are greatly improved.

Diversified addressing and routing modes are required for diversified network applications.

1. IPv4/IPv6 based addressing and routing. The method adopts technologies such as a hierarchical address mode, automatic address configuration, source authentication and the like, and has strong flexibility and rapid processing capability.

2. Content identification based addressing and routing. The mode changes the network communication mode from attention to 'where' to 'what' and considers all data contents in the network as transmittable information, thereby realizing the direct content interconnection mode instead of the host interconnection.

3. Identity based addressing and routing. The method comprehensively and effectively solves the problems of safety, mobility, expandability, user experience and the like through identity and position separation, resource and position separation and access and core separation.

4. Addressing and routing centered on a spatial coordinate location identifier. The method carries out network position coding based on the earth subdivision grid, can realize direct mapping of the network space and the real space position, and provides support for improving network application efficiency.

Two, stateless address autoconfiguration

The node constructs various IPv6 addresses by combining the address prefix with an identification derived from the node's MAC address or a user-specified interface identification. These prefixes include the local link prefix (fe80:: 10) and the prefix of length 64 advertised by the local IPv6 router (if present).

Before assigning an address to an interface, the node performs duplicate address detection to verify its uniqueness. The node sends a neighbor solicitation query to the new address and waits for a response. If the node does not receive a response, then the address is assumed to be unique. If the node receives a response in the neighbor advertisement format, then the address is already in use. If the node determines that its attempted IPv6 address is not unique, then the automatic configuration will cease and require manual configuration of the interface.

The existing network architecture has the defects of rigid structure, single IP bearing, difficulty in restraining unknown threats, low support capability on quality, safety, fusion, expansion, manageability, controllability, efficiency, mobility and the like, and can not dynamically and flexibly meet the requirements of various types and layers of users on intelligent, diversified, personalized, high and stubborn health, high-efficiency and high-quality network experience under the ubiquitous scene through limited resources. Therefore, a new technical solution needs to be provided.

Disclosure of Invention

The invention aims to provide a multi-mode network-based network detection and network management platform, which solves the problems that the existing network architecture has rigid structure, single IP bearing, difficulty in inhibiting unknown threats, low support capability on quality, safety, fusion, expansion, manageability and controllability, efficiency, mobility and the like, and can not dynamically and flexibly meet the requirements of various types and levels of users on intelligent, diversified, personalized, high-toughness, high-efficiency and high-quality network experience under the ubiquitous scene through limited resources.

In order to achieve the purpose, the invention provides the following technical scheme: a multimodal network-based network probing and network management platform, comprising: the network application comprises a content network mode, an identity network identification mode, an information mode, a subdivision network mode, a diversified network support and a plurality of transmission media, wherein the side surface of the network application is connected with diversified network data equipment, and a distributed mode control system is installed in the diversified network data equipment.

As a preferred embodiment of the present invention, the distributed mode control system includes an IP, a new IP network, an identity network, a content-centric network, and a content-subdivision network.

As a preferred embodiment of the present invention, the control method of the distributed mode control system includes the steps of:

step 1: device and network management

S1: acquiring the data of the existing network equipment, uniformly managing the data, acquiring the information of the corresponding network equipment and the running state information according to the specific data, wherein the information mainly comprises equipment models, IP addresses, support modes, online states and the like;

s2: according to the current equipment information, when network interaction occurs, information such as an equipment flow table, flow table matching, link transmission rate and the like is observed, and the current interaction is supervised and controlled;

s3: and configuring, modifying, enabling and disabling the protocol according to the current running state and the service scene, and observing under the current service scene. The data indexes shown by different protocols are used for judging the most suitable network protocol scheme under the current situation;

s4: the network management can focus some network domains through specific conditions, realize the tracing and management of the equipment in the current network domain, and collect the current data;

step 2: protocol management

S1: based on the existing protocol, data are sorted and displayed, a corresponding protocol is retrieved through specific conditions, and protocol configuration is carried out on equipment which accords with certain service scenes according to the past data;

s2: aiming at the equipment in the special service scene, the protocol configuration can be carried out through the editing and uploading of the custom protocol;

and step 3: burst and alarm

S1: acquiring detailed data of network flow;

s2: based on the flow data, whether the matching data reaches an alarm or burst detection level;

s3: sending an alarm and implementing alarm information transmission and feedback through the Internet or a communication form;

and 4, step 4: scenario and protocol model analysis

S1: performing multiple protocol matching tests by designating a certain specific scene, performing comparative analysis after obtaining data, selecting an optimal scheme for recording, and solidifying a matching model;

s2: and by designating a certain specific protocol, carrying out matching tests of various scenes, carrying out comparative analysis after data is obtained, selecting an optimal scheme for recording, and solidifying a matching model.

Compared with the prior art, the invention has the following beneficial effects:

the invention carries out information comprehensive statistics and specific data display based on the existing network equipment, searches equipment and checks specific operation details through information such as equipment name, ip address, MAC address and the like, carries out data analysis by monitoring network transmission protocols among the equipment, provides an optimization scheme, and carries out configuration modification on the transmission protocols, thereby improving the energy efficiency. And the self-defined editing and uploading of the protocol can be provided aiming at special service scenes, and the coverage and the selectivity of the protocol are improved. According to the network domain and the operation condition of the backbone network, equipment alarm information uploading and burst detection information uploading are realized, and the system can monitor the on-network equipment in a regular round inspection mode, so that problems can be found in time, and the processing efficiency is improved. Based on different service scenes, different transmission protocols are formulated, protocol efficiency under certain scenes is contrastively analyzed, matching optimization of the different transmission protocols and the different service scenes is improved, and energy efficiency and safety of a network are improved; by monitoring the running state of the network equipment, matching the service scene of the equipment with a communication protocol model and modifying the current network transmission protocol, the uploading rate, the downloading rate and the link stability among the equipment are obviously improved. The method comprises the steps of monitoring network operation state data, equipment alarm data and burst reported data, analyzing and planning relevant models such as key areas, key time periods, high-frequency burst areas and the like, and meanwhile implementing a system polling monitoring mechanism, greatly shortening problem discovery time and processing period, improving alarm and burst processing efficiency and enhancing network operation stability. According to different scenes that different network equipment can be in, scene modes are collected and sorted, and according to monitoring data of different protocols in certain specific scenes, protocol editing, uploading and matching use are carried out, so that switching of a multi-mode network and intercommunication among multiple protocols are realized, the management cost of personnel on the network is reduced, and the management efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of a diversified network application architecture of the present invention;

fig. 2 is a schematic flow chart of a distributed mode control system according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-2, the present invention provides a technical solution: a multimodal network-based network probing and network management platform, comprising: the network application comprises a content network mode, an identity network identification mode, an information mode, a subdivision network mode, a diversified network support and a plurality of transmission media, wherein the side surface of the network application is connected with diversified network data equipment, and a distributed mode control system is installed in the diversified network data equipment. The distributed mode control system comprises an IP, a novel IP network, an identity identification network, a content center network and a content subdivision network, information comprehensive statistics and specific data display are carried out based on the existing network equipment, equipment is searched and specific operation details are checked through information such as equipment names, IP addresses and MAC addresses, data analysis is carried out through monitoring network transmission protocols among the equipment, an optimization scheme is provided, the transmission protocols are configured and modified, and the energy efficiency is improved. And the self-defined editing and uploading of the protocol can be provided aiming at special service scenes, and the coverage and the selectivity of the protocol are improved. According to the network domain and the operation condition of the backbone network, equipment alarm information uploading and burst detection information uploading are realized, and the system can monitor the on-network equipment in a regular round inspection mode, so that problems can be found in time, and the processing efficiency is improved.

Further improved, as shown in fig. 2: the control method of the distributed mode control system comprises the following steps:

step 1: device and network management

S1: acquiring the data of the existing network equipment, uniformly managing the data, acquiring the information of the corresponding network equipment and the running state information according to the specific data, wherein the information mainly comprises equipment models, IP addresses, support modes, online states and the like;

s2: according to the current equipment information, when network interaction occurs, information such as an equipment flow table, flow table matching, link transmission rate and the like is observed, and the current interaction is supervised and controlled;

s3: and configuring, modifying, enabling and disabling the protocol according to the current running state and the service scene, and observing under the current service scene. The data indexes shown by different protocols are used for judging the most suitable network protocol scheme under the current situation;

s4: the network management can focus some network domains through specific conditions, realize the tracing and management of the equipment in the current network domain, and collect the current data;

step 2: protocol management

S1: based on the existing protocol, data are sorted and displayed, a corresponding protocol is retrieved through specific conditions, and protocol configuration is carried out on equipment which accords with certain service scenes according to the past data;

s2: aiming at the equipment in the special service scene, the protocol configuration can be carried out through the editing and uploading of the custom protocol;

and step 3: burst and alarm

S1: acquiring detailed data of network flow;

s2: based on the flow data, whether the matching data reaches an alarm or burst detection level;

s3: sending an alarm and implementing alarm information transmission and feedback through the Internet or a communication form;

and 4, step 4: scenario and protocol model analysis

S1: performing multiple protocol matching tests by designating a certain specific scene, performing comparative analysis after obtaining data, selecting an optimal scheme for recording, and solidifying a matching model;

s2: and by designating a certain specific protocol, carrying out matching tests of various scenes, carrying out comparative analysis after data is obtained, selecting an optimal scheme for recording, and solidifying a matching model.

The invention carries out information comprehensive statistics and specific data display based on the existing network equipment, searches equipment and checks specific operation details through information such as equipment name, ip address, MAC address and the like, carries out data analysis by monitoring network transmission protocols among the equipment, provides an optimization scheme, and carries out configuration modification on the transmission protocols, thereby improving the energy efficiency. And the self-defined editing and uploading of the protocol can be provided aiming at special service scenes, and the coverage and the selectivity of the protocol are improved. According to the network domain and the operation condition of the backbone network, equipment alarm information uploading and burst detection information uploading are realized, and the system can monitor the on-network equipment in a regular round inspection mode, so that problems can be found in time, and the processing efficiency is improved. Based on different service scenes, different transmission protocols are formulated, protocol efficiency under certain scenes is contrastively analyzed, matching optimization of the different transmission protocols and the different service scenes is improved, and energy efficiency and safety of a network are improved; by monitoring the running state of the network equipment, matching the service scene of the equipment with a communication protocol model and modifying the current network transmission protocol, the uploading rate, the downloading rate and the link stability among the equipment are obviously improved. The method comprises the steps of monitoring network operation state data, equipment alarm data and burst reported data, analyzing and planning relevant models such as key areas, key time periods, high-frequency burst areas and the like, and meanwhile implementing a system polling monitoring mechanism, greatly shortening problem discovery time and processing period, improving alarm and burst processing efficiency and enhancing network operation stability. According to different scenes that different network equipment can be in, scene modes are collected and sorted, and according to monitoring data of different protocols in certain specific scenes, protocol editing, uploading and matching use are carried out, so that switching of a multi-mode network and intercommunication among multiple protocols are realized, the management cost of personnel on the network is reduced, and the management efficiency is improved.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (3)

1. a network detection and network management platform based on multimodal network, is characterized in that: comprise: network application, in described network application, comprises content network mode, identity network identification mode, information mode, earth dissection Network mode, diversified network support and multiple transmission media, the side of the network application is connected with a diversified network data device, and a distributed mode control system is installed in the diversified network data device. 2. a kind of network detection and network management platform based on multimodal network according to claim 1, is characterized in that: described distributed modal control system comprises IP, new type IP network, identity network, content center Network and Content Segmentation Network. 3. A kind of network detection and network management platform based on multimodal network according to claim 2, is characterized in that: also comprises the control method of distributed modal control system, and described control method comprises the steps: Step 1: Device and Network Management S1: Obtain existing network device data, manage the data in a unified manner, and obtain the corresponding network device information and operating status information according to specific data, mainly including device model, IP address, support mode, online status, etc.; S2: According to the current device information, observe the device flow table, flow table matching, link transmission rate and other information when network interaction occurs, and supervise and control the current interaction; S3: Configure, modify, enable, and disable the protocol according to the current operating state and business scenario, and observe the current business scenario. Data indicators displayed by different protocols, so as to judge the most suitable network protocol scheme in the current situation; S4: Using network management, you can focus on certain network domains through specific conditions, and realize the traceability and management of devices in the current network domain, and collect current data; Step 2: Protocol Management S1: Organize and display data based on existing protocols, retrieve corresponding protocols through specific conditions, and configure protocols for devices that meet certain business scenarios based on past data; S2: For devices in special business scenarios, the protocol configuration can be performed by editing and uploading custom protocols; Step 3: Bursts and Alerts S1: Get detailed data of network traffic; S2: Based on the traffic data, whether the matching data reaches the alarm or burst detection level; S3: Issue an alarm and implement alarm information transmission and feedback through the Internet or communication; Step 4: Scenario and Protocol Model Analysis S1: By specifying a specific scenario, carry out a variety of protocol matching tests, after obtaining the data, carry out comparative analysis, select the optimal solution for recording, and solidify the matching model; S2: By specifying a specific protocol, the matching test of various scenarios is carried out, and the data is obtained for comparative analysis, the optimal solution is selected for recording, and the matching model is solidified.

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