TW201931227A - Interface system of virtual and physical integrated network with resources topology - Google Patents

Abstract

The present invention provides an interface system of virtual and physical integrated network with resources topology. The system uses IT languages and information models to describe virtual and physical network resources topologies at the same time, to achieve universal resources dispatch and service component assembly. The system further employs programmable information models to establish data communication configurations and model templates in a dynamical hierarchy. Through the container standardization life-cycle management, information description format specifications can be shared among multivariant heterogeneous information systems, and complicated and multivariant resources in virtual and physical networks can be exchanged quickly and accurately.

Description

Interface system for virtual and real network resources topology

The present invention relates to a technology for integrating heterogeneous systems, and more particularly to an interface system for virtual and real network resources.

In the face of the volatility and diversified product applications of the current IoT network service assembly, there is an urgent need for a fast and flexible multi-heterogeneous architecture platform collaborative network scheduling process and autonomous sensing service mechanism management, which is sufficient to drive different purposes. Sexually diverse new products, among them, how to make virtual and real network integration service supply and improve the use of intelligent management and control mechanism is the main key.

In the current heterogeneous multi-network environment, each system or device may not be able to quickly establish relationships due to specifications or vendor issues. This leads to a lot of manpower and time to integrate different sources when changing or adding new systems or functional modules. Equipment, network environment, execution configuration, information model, communication specifications and its architecture, that is to say, there is no control mechanism for intelligent learning intelligent services when integrating, and if there is a problem, there is no common description information model based on heterogeneous devices. Therefore, there is currently no single service-oriented service that can't cross heterogeneous multi-network environments. There is still room for improvement, and it is not possible to flexibly and rapidly develop the current changes and rapid diversification of IoT cross-platform architecture assembly services.

It can be seen from the above that if a technology for integrating heterogeneous system architecture can be found, especially for heterogeneous systems and devices, a common description information model can be provided, so that different source objects and hierarchical associations can know each other's parameter setting and relationship, and there will be It facilitates the establishment, change and coordination of resource scheduling and flexible and expandable service assembly between heterogeneous systems, which is also the goal of the current technical personnel in the pursuit of solutions.

The object of the present invention is to provide a general IT language network topology information model description, and at the same time, to describe a virtual and real network resource topology, which comprises a multi-layer hybrid continuous optical copper network composite network environment, to be more efficient and Flexible assembly method to realize the exchange and analysis of multi-dimensional heterogeneous network environment resource information model between different application information systems.

The invention provides a virtual reality network resource topology interface system, which comprises: a general-purpose configuration architecture management module, which establishes a general-purpose network device execution configuration through a layer-by-step recursive manner to enable virtual and real network devices, The general-purpose network device execution configuration and scheduling resource components are described in the same architecture framework; the information model topology management module is connected to the general-purpose configuration architecture management module for modularization and specification standardization. The virtual real network device in the same framework, the configuration of the universal network device, and the composition of the scheduling resource, and the parsing and translating through the file description of the information template, so that the configuration data of the virtual and real network device is converted into a hierarchical Dependent association description file; micro-service assembly and construction planning management module, through assembly and construction planning program, Sequentially calling the micro service group and establishing the sequential link and output/input between the processes of each node, thereby obtaining the detailed action of the service program assembly and the before and after association of each node in the process execution, so that the service program is assembled into an information template; The cloud data management module uses a snowflake data structure method to store the program process in the process execution and the translation message, relay message, operation message or digital analysis message generated by the operation process of the information template; and business rule driving The process analysis processing engine is connected to the universal configuration architecture management module, the information model topology management module, the micro service assembly construction plan management module, and the cloud data management module, and the business rule driving process The analytic processing engine dynamically adjusts and controls each step of the execution of the process, and performs a series of sequential call and response connections for subsequent scheduling of resources and services and cooperation and exchange of micro services.

In an embodiment, the hierarchical dependent association description file includes a multi-level information model, an information template, and a description file.

The virtual reality network resource topology interface system further comprises a container connection service component connected to the business rule-driven process analysis processing engine to form a lifecycle management module, which is a standardized flexible container autonomous process through abstract programming and standardized container management mechanism. The stack assembly structure is used for recycling various heterogeneous interface systems, and each step of the process execution is controlled by the business rule-driven process analysis processing engine dynamically adjusting the lifecycle management module through the container connection service component.

In addition, the container connection service component component lifecycle management module utilizes a unified framework of abstraction, standardization, and generalization to complete service establishment, deployment, release, subscription, delivery, racking and publishing, and subscription management, and Released in an open standard specification.

The virtual reality network resource topology interface system further includes a massive data prediction analysis module that links the business rule-driven process analysis processing engine, and is used for analyzing the huge composite communication network engineering traffic response and various user usage behaviors. This inductive analysis and prediction of the trend of subsequent network service trends.

The virtual reality network resource topology interface system further comprises a dynamic aggregation dashboard device connected to the business rule-driven process analysis processing engine, which is used for presenting the data exploration analysis algorithm and the data used by the massive data prediction analysis module. The trend of this subsequent network service trend. In addition, the dynamic aggregation type instrument panel device is used for interactive operation and information feedback in the field, and the dynamic aggregated instrument panel device includes a plurality of display blocks, each of which is associated with other display blocks to provide different Dimensional large-scale data cross-operation analysis and inductive diagnosis derivation prediction.

The virtual reality network resource topology interface system further comprises a gesture voice operation terminal device connected to the business rule-driven process analysis processing engine, which is provided for the field terminal personnel to immediately obtain the operation state of the process and return the data information.

In another embodiment, the business rule-driven process analysis processing engine is an instant collection of various data sources and trigger events generated during the execution of the network service process, and separate management and operation of the data.

In another embodiment, the general-purpose network device performs configuration including an execution environment, detailed action settings, an interface specification interface, a deployment application interface, and an operational configuration.

Compared with the prior art, the present invention adopts a new generation standard specification hierarchical description network environment and a scheduling execution configuration information model, and configures the components required for the multi-heterogeneous network and the network execution environment through the technology of the present invention. In order to achieve comprehensive software definition operation and intelligent management and control mechanism, in addition, through machine learning, artificial intelligence, massive data mining and exploration, big data analysis and forecasting technology and snowflake information storage architecture, resource scheduling and service component process details Control and intelligently improve operations, thereby achieving the end-to-end overall intelligent service control mechanism that cannot be completed by current technologies.

1‧‧‧Virtual and real network resource topology interface system

11‧‧‧Common configuration architecture management module

12‧‧‧Information Model Topology Management Module

13‧‧‧Container Linking Service Components Form Lifecycle Management Module

14‧‧‧Micro Service Assembly and Construction Planning Management Module

15‧‧‧ Massive Data Prediction and Analysis Module

16‧‧‧Cloud Data Management Module

17‧‧‧ gesture voice operation terminal device

18‧‧‧Business rules-driven process analysis processing engine

19‧‧‧Dynamic polymeric instrument panel device

1001‧‧‧ Service Template

1002‧‧‧Top template

1003‧‧‧Project Process

1004‧‧‧node type

1005‧‧‧ script

1006‧‧‧ relationship type

1 is a system architecture diagram of a virtual reality network resource topology interface system; FIG. 2 is a schematic diagram of an information model topology template used in the present invention; and FIG. 3 is an information model topology management module of the present invention; The group is applied to describe the resource service configuration diagram; FIG. 4 is a flow chart of the network resource composition scheduling and the service assembly execution plan of the micro service assembly and construction planning management module of the present invention; A flow chart of a specific implementation of the invention; FIG. 6 is a flow chart of a specific embodiment of a virtual reality network resource topology interface of the present invention; and FIG. 7 is a virtual reality network resource topology interface system of the present invention. A flow chart of another embodiment.

The following describes the technology of the present invention by way of specific embodiments. Those skilled in the art will readily appreciate the advantages and benefits of the present invention from the teachings herein. The invention may be embodied or applied by other different embodiments.

Please refer to FIG. 1 , which is a system architecture diagram of a virtual reality network resource topology interface system of the present invention. As shown in the figure, the virtual reality network resource topology interface system 1 of the present invention includes a general-purpose configuration architecture management module 11, an information model topology management module 12, and a container connection service component to form a lifecycle management module. The micro service assembly construction plan management module 14, the massive data prediction analysis module 15, the cloud data management module 16, the gesture voice operation terminal device 17, the business rule driving process analysis processing engine 18, and the dynamic aggregated instrument panel device 19 .

The universal configuration architecture management module 11 and the information model topology management module 12 of the present invention include circuit configuration, circuit name, communication communication at both ends of the circuit, circuit rate, total circuit bandwidth and upper circuit resources. After the information model topology management module 12 is driven by the process, the automatic scanning detection and analysis automatic configuration management module is immediately included, which includes the resource topology common common database, the information model and the template, the topology associated file, and the execution configuration. , environmental configuration and connection details, providing optical copper equipment core wire connection engineering and connection procedures, obstacle location detection, multiple traffic induction analysis.

The general-purpose configuration architecture management module 11 is used to establish a network architecture established by the physical network device and the virtual network device, and uses a hierarchical method to establish a universal network device line core execution environment configuration, and the virtual reality network The devices are described in the same framework. The virtual network devices described herein refer to physical network devices and virtual network devices. The network architecture can be, for example, the location of the computer room. The backup resources are established, and the equipment is connected with the location of the equipment room. In addition, when the equipment is built, the network resources such as the brand, model, rack, frame, card board, communication port, network management system, and own loop are also included. configuration.

The information model topology management module 12 uses a new generation of information model description technology to convert configuration data such as equipment, circuits, and services into hierarchical dependent description files, so that information systems for different fields and different purposes can be automatically called. Let the heterogeneous multi-information system automatically synchronize the exchange format specifications.

The container connection service component composition lifecycle management module 13 standardizes the container management mechanism through abstract programming, and implements the establishment, deployment, distribution, subscription, delivery, racking and publishing of the service in a unified framework of abstraction, standardization and generalization. And subscription management, wherein the container and the container are mutually substructured. The standardized container management mechanism enables seamless execution of the required execution environment, core and dependent components and configurations from the bottom to the top of the microservices package.

In specific implementation, the general configuration architecture management module 11 resources, services, operations, management, configuration, and deployment of the Internet of Things (IOT), Internet Protocol Television (IPTV), and Information and Communication Technology (ICT) cloud services. , publishing, delivery, etc., through modularization and standardization of common frameworks, and using the information model to describe and translate the information template of the information template to complete a complex and diverse network topology environment. The container connection service component composition lifecycle management module 13 is produced and released in an open standard specification, and a universal elastic autonomous process stack assembly structure is built for recycling various heterogeneous interface systems. The invention can be described in the configuration of the resource scheduling service across the heterogeneous network, which greatly saves the development difficulty and time compared with the traditional method, and the demand for the diverse types is varied. In the hybrid configuration of the network and the physical network defined by the SDN (Software Defined Network)/NFV (Network Function Virtuialization) software, the general configuration can be used when transmitting messages between the heterogeneous heterogeneous information systems. Quickly resolve the resources and service architecture of a heterogeneous network.

The container connection service component component lifecycle management module 13 uses a new generation of digital convergence technology of the Cloud Service Clustering Application and Flow Orchestration Composition to focus on the Hybrid hybrid virtual reality network service. Initialize and establish between, and use the open standard technology Data Modeling Language for the Network Configuration Protocol to carry out the exchange, exchange, initialization, authentication and signal synchronization between the service component and the service component. Through the exchange and high-heavy to accelerate the integration and rapid deployment between the cross-platform cloud virtualization service collaboration, the process orchestration allows the end users to flexibly arrange for heterogeneous and diverse types of services to be arranged and rapidly deployed. The subordinate services are implemented in various data types, such as data centers, servers, general host or mobile phone devices, and IoT devices, to obtain core algorithms that can be used in various computing types.

The business rule-driven process analysis processing engine 18 connects and parses the processing to drive other main modules to visualize the business process management BPM (Business Process Management) intelligent control flow, so that each module can be flexibly and quickly connected. Therefore, through the general-purpose configuration architecture management module 11 to establish data exchange and analysis between the information modules, applied to the basic network service Service rate or service routing, through the virtual and integrated network point-to-point circuit configuration architecture, using the concept of point, line, and surface, the point-to-point circuit across the virtual network, establish a general-purpose circuit configuration, according to this, the architecture After the service configuration architecture is established, the virtual and real network integration services can be used to establish an open, standardized, more flexible and fast virtual and universal service configuration.

The Microservices Assembly and Construction Plan Management Module 14 uses the Orchestration logic of the workflow to operate the Service Build Plan to create a manageable assembly process that can be reused through a variety of diverse heterogeneous virtual network resources and services. Assembled by the assembly, the high-security general-purpose virtual and integrated service API (Secured REST Hybrid Service API) virtual and real-purpose interface is produced and released as a cloud application, providing various heterogeneous systems with different kinds of different sources of data exchange and transportation. The microservices assembly and construction plan management module 14 will be described in detail later.

The massive data predictive analysis module 15 can analyze the huge composite communication network engineering traffic response and the complex and varied user usage behavior, and at the same time summarize and analyze the trend of the short-term and long-term network service trends, such as analyzing the spindle cable loop, The status and response of the split cable, the user cable and the copper cable are transmitted instantaneously, and the dimensional analysis information is immediately fed back to the dynamic aggregated instrument panel device 19, and the multi-layer instrument panel can be disassembled one by one to monitor the network service network in an aggregate manner. The dimensions of each dimension and the response status of resource utilization. The massive data prediction analysis module 15 further predicts the trend of the network element information and user usage behavior and the network service through the multi-dimensional data-oriented continuous activity and timing comparison monitoring, and launches the corresponding event to trigger the corresponding step earlier. deal with.

The invention can provide a highly visual interactive terminal operation and simultaneously use the standardized module general information model interface specification, so that the end user can quickly and utilize the network topology resource through the self-service self-service service through the dragging and combination of the primitive block. Network service process and service execution plan. The mass data predictive analysis module 15 can analyze the packet quality, degradation, obstacles, bottleneck points, and signal loss of the ODN (Optical Distribution Network)/OLT (Optical Line Terminal)/ONU (Optical Network Unit) and the optical splitter through the data analysis. Compared with the prior art, the cross-analysis of the detailed multi-dimensional data and the information model real-time computing data generated by the data digitization intelligent analysis process process, through the multi-dimensional multi-level and neighborhood analysis cross-matching, the early step-by-step insight into the details of the detailed process of the prediction process Then, the process bottleneck point and the process degradation degree or the power loss phenomenon interference proportion are found, and are analyzed and summarized by the quantitative data intelligent processing, and then transmitted to the dynamic aggregation type instrument panel device 19 to provide on-site remote interactive operation application.

Compared with the prior art, the method for finding the cause of the problem can be found through another network element network management instruction. The present invention provides a new intelligent intelligent control machine manufacturing method and the root cause data analysis artificial intelligence which are more suitable for the field of Internet of Things communication, and can further provide The terminal user inputs an interactive operation with a voice gesture, that is, the gesture voice operation terminal device 17. The massive data prediction analysis module 15 calculates the serial process resource service data, and uses the real-time data analysis algorithm operation to summarize and analyze the usage behavior and its changing trend, and finally the data can be transmitted to the cloud data management module 16 for storage management and further independent operations. .

Please refer to FIG. 2, which is a schematic diagram of an information model topology template used in the present invention. As shown in the figure, the present invention utilizes a repeatable combination-connected topology template to further use a node type and relationship type (Device Type) and relationship type (device type, route, wiring box, and machine room location) in a hierarchical recursive manner. Type) defines the stack topology association based on the service application network topology, layer-level association extension, and the package is built into the integrated standardized universal container image network for configuration, with reusable multiple use and fast application. , partial replacement, dynamic adjustment, external connection and other characteristics.

The topology template can be a physical network resource IPV6 video device, and the topology template 2 can be a software defined L2 (Software Defined L2) virtual switching device, but not limited thereto, it can be cut into multiple virtual subnets. Through the digital information model and IT configuration language description of the transmission and exchange attributes and their connected information models, the various resource equipment lines are connected under the cross-platform portable shared resource information framework, and the cross-platform standardized specification template is used to describe the neighborhood multiple. The node and the complex and diverse point, line and surface space are combined and used, and the cloud data management module 16 is used to store and store the data in at least one remote cloud storage device to maintain the synchronization node update of the data.

Using the modular and standardized information model description described by the IT language, the configuration execution file can be dynamically, quickly and flexibly parsed through file naming, logic, configuration, setting, and association rules, thereby automatically executing the virtualized cloud service. The purpose of construction, deployment, management, subscription, etc.

The provision of virtual and integrated hybrid network services, if traditional services are used alone, can not build a universal service across heterogeneous multi-network environments. This is the advantage of the invention in the application of communication, more suitable for the Internet of Things era. Service delivery framework. For the classification, supply, and lifecycle management of services and the evolution of providing time-to-time, the framework of the invention can be further flexibly expanded to expand the content of the information model module to quickly add new changes, which can meet the needs of the diversified development of communication and communication. application.

Please refer to FIG. 3, which is a schematic diagram of the information model topology management module applied to describe the resource service configuration. As shown in the figure, the information model topology management module 12 describes that the resource service configuration service (Service Active File) includes one or more service templates 1001, and each service template 1001 may include one or more topology templates 1002. In the topology template 1002, descriptions of various resource topologies and scalability enhancements can be performed, including MetaData, Deployment Artifact, Implementation Artifact, Definition Schema. , Plan, Script, node type, relationship type, etc. In addition, the node type 1004 is defined by a plurality of properties. The relationship type 1006 is composed of a plurality of interfaces (Interfaces) format, which can be driven by the remote execution instruction set script 1005, and the execution plan flow (Build Plan Flow). The 1003 process engine performs process program element layout, component serialization, and sequential drive, thereby stacking and linking the topologies and recursively to form a larger range of topologies to facilitate more complex composites. Network topology tasks.

Please refer to FIG. 4 , which is a flowchart of the network resource composition scheduling and the service assembly execution plan of the micro service assembly and construction planning management module of the present invention. As shown in the figure, the micro-service assembly and construction plan management module 14 can establish various heterogeneous systems for data exchange and transportation, and the information model topology management module 12 can be updated to topology node type and topology relationship. Type and provide for repeated use or change of the work program. The invention proposes to dynamically capture related topology files (Topology Files) for different purposes, to implement various virtual and real hybrid (hybrid) end-to-end network resource scheduling network element composition and setting, opening, including various types of brands, models, The network resource configuration of the rack, the frame, the card slot, the card board, the communication port, the network management system, and the own loop are shared by the common aggregated information service platform and the international standard, and the standardized specifications are derived. Telecommunications service resource scheduling interface.

The micro-service assembly and construction plan management module 14 can operate the logic block and the hierarchical structure of the overall service of the elastic change arrangement by using the primitive abstraction mechanism and the high-order visual drag-and-drop primitive logical association connection mode. Sequential stacking and component assembly, through the use of primitive drag and drop combination of connections, interaction and orchestration to complete the overall framework, as well as change the interface and order adjustment of the service. Through various execution planning processes and primitive process orchestration, the logical partitions of the operation are managed in a highly visualized graphical layout, allowing terminal operators and field operators to quickly interact through the dynamic aggregated dashboard device 19. The operation then grasps the state of the program, and interprets the root cause of the problem and the scope of the problem.

Figure 4 illustrates the network resource composition scheduling and service assembly execution plan construction process of the micro service assembly and construction plan management module 14 by configuring all end-to-end execution programs and their network parameters and environment configuration. Set up to quickly establish the cloud service network configuration and service assembly detailed action execution environment. Furthermore, through the parameter setting of the operating system layer and the IT language description information model, the detailed parameters of the assigned operating system operation and the action setting are set one by one. The network service server and its execution environment configuration parameter settings are established in sequence, and finally the topology template configuration and deployment are completed. In addition, the container type and its parameters and configuration are set, and the deployment of the composite module included in the module is completed, and the configuration of the REST API terminal access point and its detailed action parameter deployment are completed. During the above process, the virtualization computing cluster device is simultaneously mobilized, and the standardized container bearer is further used, and the execution package is packaged into a container and then deployed as a virtualized application in the cloud. The configuration information model terminal access point is completed by setting the cloud virtualization storage device and setting its parameters. After the completion of the above two execution processes, the terminal deployment of the action module and the Secured REST API terminal access point release are completed simultaneously to complete the process operation procedure. In summary, the micro-service assembly and construction plan management module 14 provides different application service type REST API terminal access point release deployment and a multi-heterogeneous system open universal and virtual integrated network service REST API interface, so the system can Implement a common virtual and real network integration topology of cross-platform virtual and real resource network collaboration services.

The container connection service component composition lifecycle management module 13 further utilizes the information model topology management module 12 to further drive the business through the pre-pre-software-defined virtual and entity hybrid resource topology association rules. The rule-driven process analysis processing engine 18 and the steps of dynamically adjusting the control flow by the container connection service component to form the lifecycle management module 13, such as service racking, service delivery, service provisioning, service stop, service transaction, service cancellation, service suspension, Service recovery, etc. When the information communication service is put on the shelf, the service topology (Servcie Template) is established first, and the network resource configuration and service detailed action parameters are built on the service topology, and then the information model topology management module 12 generates the topology template. Placed in the service topology and through the IT data model language to increase the network face-to-face service interface handover association description, the micro-service component steps are based on the source requirements and the data analysis judgment results, and the change process is generated, and the process generates the information feedback process details. Passed to the massive data predictive analysis module 15 and maintain the latest state operation during the execution of the service process. Multi-dimensional oriented repetitive data exploration and machine learning training prediction and verification, thereby improving the accuracy of the computational inference, and can be used for subsequent engineering calls and calls. .

The container connection service component component lifecycle management module 13 encapsulates the entire integrated service activity topological template (Servie Active Topolog Template) and the IT information model description language by a business rule driven by a standardized and standardized loop link association method. The process parsing processing engine 18 performs a series of sequential call and response connections, and then performs subsequent resource and service scheduling and micro service cooperation and mutual transport. In other words, through the pre-built network to perform environmental configuration and service assembly detailed action parameters, as well as the establishment of open standardized specifications recyclable stacking containers, using a centralized instruction set to manage hundreds of container assembly, based on containers With the stacking, interface connection and order control of each other, the microservices for the cloud subscription service can be completed. In addition, the remote range of the instruction set transmitted through the far end Operation and visual interaction process program element layout, further flexibly control the combination and cooperation between different types of containers and containers, and implement layered stacking Multi-Layering to realize incremental virtual and physical network and service integration. Build, dispatch, publish, manage, rack, and subscribe, that is, deploy the virtual image file through the package to speed up its speed and operate flexibly across platforms.

The general-purpose configuration architecture management module 11 has an efficient and flexible management heterogeneous multi-virtual inter-network information model, its information template exchange benchmark, and uses IT communication telecommunication language to complete attribute, parameter and link association description from bottom to top level. The package is a standard container object use unit, which can further deploy and release through the operation of the container. The Hybrid general network service configuration is used to further describe the SDN/NFV complex packet and process intelligent management operation and complete the construction of the information model. Compared with the prior art single task target single deployment release service, the present invention is more flexible to provide control of various heterogeneous SDN controllers and NFV components, such as L2, L3 switches and routers, and virtualized network devices, which can solve the problem in the past. The problem of the application of the label link interface.

Please refer to FIG. 5, which is a schematic diagram of the process of the specific implementation of the present invention. As shown in the figure, the flow of the logic logic operation program of the IoT application service subscription request and the output and input relationship of each module of the present invention are illustrated. A service subscription request is first subjected to the analysis and induction algorithm in the general configuration architecture management module 11 to group and adjust the type and application context, and the clustering algorithm is used to cut the service request logic block to further perform intelligent classification and shunt control. Mapping the network resource topology through the information model topology management module 12 To complete the production and output of various resource utilization topology information models, to execute the virtual reality network environment topology and its related setting parameters and detailed operations in the execution environment, and then to perform network resource topology node and device association scheduling The general virtual and real hybrid network topology resources and connection associations required for the output assignment are driven to drive the virtual and entity individual resources and their execution configuration.

Then, the virtual common resource topology template is used to generate an output universal resource topology template, which is suitable for virtualizing network resources, and forms a lifecycle management module 13 and a virtualized package processor through the container connection service component to generate a plurality of generalized The container carries the resources, and by reading the image file for the hierarchical network configuration and its network element and subnet element, then constructing the plan management module 14 through the micro service assembly construction plan and opening the application. The program interface processor reads the image file to provide a network topology application interface set, through the network element node associated computing computing processor, the process information analysis feedback processor, the programmable container dispatching processor to cooperate and recover The program of the action recovery processor recurs the loop until the network resource topology component configuration of all the end-to-end optical copper networks is completed, and the application interface cluster can be generated after all the configuration settings have been completed. A multi-heterogeneous end-to-end network service configuration that provides uninterrupted load. During the execution of the process program of the present invention, the various trigger events, the context change response, the subnet element connection operation, and the specific purpose calculation information generated in the snowflake data structure are also synchronously transmitted to the cloud data management module 16 and stored in at least A virtual machine data storage device ensures that trigger events and context transitions in the process are stored in the snowflake data structure in time series.

The above process uses a network element node associated operation processor to perform device lines. Road correlation calculation, various kinds of network topology information module data in the operation flow, can call the cloud data management module 16 to control the virtual machine data storage device to access the real-time information for the process execution operation, and the process information analysis feedback processing The data analysis and feedback transmission are performed, and the information of the data model that completes the virtual operation is transferred to the programmable container delivery deployment processor.

As described above, in the process of assembling the assembly, the process interface processor outputs a large amount of flow program operation information to at least one virtual machine data storage device, and further activates the nonlinear supervision mode through the massive data prediction analysis module 15. The multi-dimensional learning algorithm runs into the cross-analysis data, recursively explores the data mining program and uses the training set data to train and analyze the process trend trend, and then input the operation result into at least one programmable container dispatch deployment process. Device.

After confirming that all the modules in the call flow are completed, and all the executions are correct, no exception occurs. Then, the micro-service assembly and construction plan management module 14 performs service encapsulation, service delivery and deployment, and responds to the processing execution result. The message packet is sent to the source of the caller, and the change of the transaction data is triggered by the cloud data management module 16 to control the virtual machine data storage device. The operation storage device continuously updates and keeps the operation data in the process. During the above operation, the business rule driven process parsing processing engine 18 continuously pushes the pre-alarm event or the run event delivery data to the dynamic aggregated dashboard device 19. Through the gesture voice operation terminal device 17, the field terminal personnel can interact with the mobile cross-platform device to instantly understand the process operation status and generate response messages or digital information, and transmit them back through the feedback message package. The business rules drive the process resolution processing engine 18 for the next process.

Taking the IPV6 video and video streaming service on the ultra-wideband dedicated virtual network as an example, the information model topology management module 12 cuts the service sub-component dependent resource layer logic into a virtual real module component and performs configuration operation, and at the same time The optical cable spindle circuit, the copper twisted pair connection, the OLT, the ONU, the ODN component, the passive optical component, the actinic transfer box, the cabinet, the card magazine and the Splitter module are sequentially operated and managed, and the micro service assembly is performed. The construction plan management module 14 flexibly assembles and deploys various types of services and their associated sub-services, and arranges the serial connection and connection association in the order of the primitives. The general-purpose configuration architecture management module 11 uses information standardization. The telecommunications network element digitization, the implementation of the configuration of the general specification IT language information model and information template, fast serial connection to form a micro-service, to simultaneously meet the Hybrid hybrid resource scheduling and service components of the composite virtual and physical network resources The need for assembly. The container connection service component component lifecycle management module 13 provides a lifecycle intelligent management mechanism, and the pre-established virtual path is completed according to the general-purpose configuration architecture management module 11 information model and the information template, and the end-to-end of the virtual path is checked. Whether the required equipment, network element, line, device and connection connection resources are available can be supplied to determine whether the subsequent nodes of the subsequent network element can be started and related connection settings are enabled.

In the case of a scheduling controller, there are a number of different scheduling algorithms for starting a scheduling algorithm. First check the composition of the microservices and the dependencies of the resource topology and its connection hierarchy, then check the microservice type and its execution priority. The priority call with the highest priority in the same group is enabled, and the second is entered into the front. Buffering device, buffer delay processing, if the same priority, continue to compare network network elements and resource topology execution weights and in-place status, and so on, recursive hierarchical network subnet resource topology control management In order to avoid the execution of the process, the knot is in a loop waiting situation.

Due to the complex operation platform and equipment types of the ultra-wideband exclusive virtual network IPV6 video and video streaming service, including the ORCA platform, OMP platform, MSTV platform and next-generation IPTV platform, the evolution of the architecture will continue to be extended over time. The use of operational requirements and picture quality bandwidth requirements, but the network topology used by each platform is very different, the present invention can describe a network of multi-heterogeneous heterogeneous types of network-related devices through a general framework information model. The invention integrates different use design resource combination scheduling and service component integration information model description through open standard specification to quickly establish open general service specifications of industrial field service, and integrates full software definition through resource composition and service component specification integration. Service/Resource Orchestration is used to achieve end-to-end multi-heterogeneous brand-name device integration, flexible, fast, dynamic On Demand resources, scheduling service flexible and rapid assembly, and improve the efficiency of the overall service rack application, greatly improving the current communication service platform Poor supply performance and limited application areas.

When the process program is running, if a sub-process change is required, the business rule-driven process analysis processing engine 18 provides an information exchange model and information that dynamically increases the enterprise-level virtual network sub-service after detecting the event. The template is formed by the container connection service component. The lifecycle management module 13 uses the standardized container association technology to link and carry the above-mentioned process of building the ultra-wideband video and audio stream to become another enterprise-level virtual network. The process of deploying the ultra-wideband audio and video video stream is deployed, and then the container connection service component is composed of the lifecycle management module 13 to perform the release and management of the service component execution process event and the life cycle operation, thereby achieving the supply, change, change, and partial cancellation of the service. , delivery, shelf-up and subscription and cross-platform collaboration development.

Please refer to FIG. 6, which is a flowchart of a specific embodiment of a virtual reality network resource topology interface system of the present invention. As shown in the figure, a light-copper hybrid virtual reality network integration execution environment central office to the building total box network connection and resource topology is illustrated, wherein the optical switch of the central exchange office to the main box is connected, and the description can be completed by the invention. Light, copper, cable, and virtual and physical network mixed complex multi-network environment, including the informational model of spindle cable, divergent cable, optical junction box, copper cable, DJ box and its adjacent neighbor device line model.

Information Model Topology Management Module 12 Dynamic Resource Topology Scheduling Rules Dynamic Arrangement Locking Handover and Transmission Intra-office room, measuring station, transmission equipment, manhole connection, transfer box, user building, main box, mainframe, end point construction area The sequenced nickname and the connection line are mapped to an effective multi-route through the call path to support the load dispersion. The invention uses the software definition virtual reality information modeling modeling program to improve the network resource composition and the service component assembly quality and the smart data virtual Resource security and stable isolation, the at least one virtual software network resource provides the resource topology connection and service component integration in the life cycle of the service process, and the instant QOS feedback and execution output to the continuous situation through the execution process program Dependent cross-network protocol signaling is used to move across heterogeneous types of services across platforms, and contextually perceives operations In the range of device performance toleration time, the line signal signaling control of the optical, copper, and cable equipment and the data model set matrix are smoothly shifted across the network element devices of different types of transmitters/recipients.

Through the gesture voice operation terminal device 17 (for example, the mobile terminal device) is responsible for receiving different types of device execution commands and transmitting the generated interactive responses, and the field personnel or terminal personnel can operate the terminal device 17 through the gesture voice through the output/input interface. The remote remote intelligent control mechanism is connected to the system module, and thematic data analysis is performed to predict the instant information message, and the voice or multimedia message is parsed and converted into executable operation signaling to control the detailed logical reaction action.

Copper, optical, divergent or incoming cable and its connection scheduling Internet service information topology model can be built separately by means of information model description, or can be combined with another ultra-wideband video and video streaming process information module Description to build, based on the optical cable broadband access to the network of ultra-wideband video and video streaming process template, and then copper access to the network and can be used by multiple bundled copper twisted pair technology, set configuration execution, execution The profile and the advanced parameters form an end-to-end network element architecture information model one by one, and operate in a step-by-step manner through stacking and returning to the hierarchical structure until all network topology network element parameters, execution configuration, program setting, The dependency component, the supply command, the profile parameter, and the information model package are all described by the information model topology management module 12, that is, the network element and the network element are connected to each other to complete the information topology total completion body.

Please refer to FIG. 7, which is a flowchart of another specific embodiment of the interface system of the virtual reality network resource topology of the present invention. As shown in the figure, an application is illustrated The embodiment completes the assembly process of the IoT dynamic communication network video streaming service, and uses the full software definition virtualized network and various types of mobile terminal devices to complete the real-time video and audio information streaming service completion service resource scheduling. , on-board, set-up and multi-heterogeneous platform device delivery and intelligent awareness control, enterprise-level virtual network IPV6 video streaming service cross-platform collaboration intelligent application based on TLS protocol virtual and real network integration.

The process is performed by the call program 101 to analyze and execute the tasks of each sub-item of the IoT dynamic communication network video streaming service worksheet, and call the information model topology management module 12 to complete the information model of the spindle navigation. After the deployment is completed, the information model of the ODN network is completed through the calling program 102, and the completed information model is written to the cloud data management module 16. In addition, the program 103 completes the model construction of the VPN virtual network. The program 104 completes the model construction of the optical divergence connection, and then further uses the general-purpose configuration architecture management module 11 and the container connection service component to form the lifecycle management module 13 to call the program 105 to complete the ONU network information model establishment. The program 106 completes the construction of the dispatching construction, and the program 107 completes the information model and the digital specification construction of the IP video stream. At this time, all the data feedback in the process is written into the cloud data management module 16, and the information model is maintained. Instant synchronization and data instant analysis event intelligent interpretation control and transmission to the dynamic aggregation dashboard device 19, will return The results of the analysis are shown in the at least one predicted speech input type remote hand-operated movable device, such as a voice gesture operation terminal apparatus 17, it can be voice operated means 17 via gestures to operate and interact with the terminal.

The invention provides a more flexible, efficient and stable and scalable network Execution environment configuration topology and common standardized interface specifications, applied to the ultra-high-speed broadband network service industry and the Internet of Things new industry, important broadband, switching, transmission, aggregation, access, gateway network service process configuration, scheduling, Analyze actuarial, supply, maintenance, inspection, warning, and cross-domain application of hierarchical multi-dimensional weights cross-operation analysis, a single secure portal interface access point, and further enhance the digitization of the telecom field product service network convergence Service integration and maintenance, quality barrier analysis and evaluation of induction performance, it can further save considerable character and face problems and deal with problems, especially suitable for heterogeneous multi-virtual network environment Road service assembly and convergence are integrated.

The network resource scheduling service management process architecture proposed by the invention establishes a network architecture established by a physical network device and a virtual network device, and uses a hierarchical recursion to describe an information model one by one to establish a universal network device. The topology and configuration enable the virtual and real network device execution environment to be described in the same framework, which allows the information system to automatically synchronize the information exchange format specifications in a complex multi-network execution environment. In addition, through the network service assembly management process architecture, the use of cross-platform standardized container specification technology deployment and release services, and the automatic deployment of the release after the assembly process is completed, can achieve on-site terminal operator autonomous process changes and perceived process change feedback And the end user can define the component assembly service through the full software and quickly go online.

The invention further utilizes the big data analysis management data mining exploration algorithm, and adopts the state state supervision induction analysis to improve the intelligent management mechanism. The invention uses the Business Process Management Engine in the service operation to instantly collect the generated processes during the execution of the service. Type information, through mining of algorithmic data mining, to further summarize process trends and rules, and to predict process execution bottlenecks and degradation in advance. Compared with existing technologies, the system can only slowly find possible causes of problems through network management instructions. The intelligent control mechanism that was previously lacking in the skill of the art handles the ability to respond.

In summary, the present invention is suitable for use in banking financial derivative products, vehicle network automobile automation, ICT integrated product services, smart city Internet of Things IOT field, and key network equipment disaster warning field, and provides a new generation of digital convergence and innovation. Domain product service applications. The invention comprehensively modularizes and standardizes the resource composition, service component, module operation and process management of the composite ICT communication, the Internet of Vehicles and the Internet of Things service, and provides a plurality of multi-heterogeneous interface systems through the template of the general information model. The call is called, which saves the cross-platform cooperation and inter-transportation translation communication time compared with the traditional technology. It has flexible cooperation and cross-heterogeneous platform operation efficiency, and is more suitable for integrated use in IPV6 video streaming and TLS technology to play a stronger role. Cross-platform integration and collaboration.

The above embodiments are merely illustrative of the principles and effects of the invention and are not intended to limit the invention. Modifications and variations of the above-described embodiments can be made by those skilled in the art without departing from the spirit and scope of the invention. Therefore, the scope of protection of the present invention should be as set forth in the scope of the claims described below.

Claims (10)

A virtual and real network resource topology interface system, comprising: a general-purpose configuration architecture management module, which establishes a general-purpose network device execution configuration through a layer-by-step recursive manner to enable virtual and real network devices, the universal network The road device execution configuration and scheduling resource composition are described in the same architecture framework; the micro service assembly and construction plan management module is to assemble the plan program, sequentially call the micro service group and establish the process between each node. Linking and outputting/inputting, respectively, to obtain detailed operations of the service program assembly and before and after the nodes in the process execution, so that the service program is assembled into an information template; the information model topology management module is connected to the universal type Configuring an architecture management module for modularizing and standardizing the virtual reality network device in the same framework, performing configuration of the universal network device, and configuring the scheduling resource, and parsing the file description through the information template Translation, so that the configuration data of the virtual and real network device is converted into a hierarchical dependent association description file; the cloud data management module is utilized The snowflake data structure mode stores the translation message, the relay message, the operation message or the digital analysis message generated by the process template and the information template; and the business rule-driven process analysis processing engine is linked to the general-purpose configuration architecture Management module, the information model topology management module, the micro service assembly and construction plan management module, and the cloud data management The module, the business rule-driven process analysis processing engine dynamically adjusts and controls each step of the execution of the process, and performs a series of sequential call and response connections for subsequent resource and service scheduling and micro-service cooperation and mutual transportation. For example, the virtual reality network resource topology interface system described in claim 1 is characterized in that the hierarchical dependent association description file includes a multi-level information model, an information template, and a description file. For example, the virtual reality network resource topology interface system described in claim 1 further includes a container connection service component that links the business rule-driven process analysis processing engine to form a lifecycle management module, and standardizes the container through abstract programming. The management mechanism establishes a general flexible and autonomous process stack assembly structure for recycling various heterogeneous interface systems, and each step of the process execution is composed of the business rule-driven process analysis processing engine to form a life cycle through the container connection service component The management module is dynamically adjusted and controlled. For example, the virtual reality network resource topology interface system described in claim 3, wherein the container connection service component constitutes a lifecycle management module, and the service framework is completed by using a unified framework of abstraction, standardization, and generalization. , deployment, publishing, subscription, delivery, racking and publishing, and subscription management, and release in an open standard format. For example, the interface system of the virtual and real network resource topology described in the first application of the patent scope includes the link to the business process-driven process analysis department. The massive data predictive analysis module of the engine is used to analyze the large-scale composite communication network engineering traffic response and various user behaviors, thereby summarizing the trend of analyzing and predicting the trend of subsequent network services. The interface system of the virtual reality network resource as described in claim 5, further comprising a dynamic aggregated instrument panel device connected to the business rule-driven process analysis processing engine, which is used for presenting the massive data prediction analysis module. The data exploration analysis algorithm used and the trend of the subsequent network service trends generated. The interface system of the virtual reality network resource as described in claim 6, wherein the dynamic aggregated instrument panel device is used for interactive operation and information feedback in the field, and the dynamic aggregated instrument panel device includes multiple Display blocks, each of which is associated with other display blocks, thereby providing a large amount of data cross-operation analysis and inductive diagnosis derivation prediction for different dimension-oriented dimensions. The interface system for virtual and real network resources as described in claim 1 of the patent application, further comprising a gesture voice operation terminal device connected to the business rule-driven process analysis processing engine, which is used by the field terminal personnel to obtain the operation state of the process in real time. And returning data information. For example, the virtual reality network resource topology interface system described in claim 1 is characterized in that the business rule-driven process analysis processing engine is an instant collection of various data sources and trigger events and data generated during the execution process of the network service. Separation management and transportation Work. The virtual network resource topology interface system according to claim 1, wherein the general network device execution configuration includes an execution environment, detailed action setting, interface specification interface, deployment application interface, and operation group. state.