CN110366056B

CN110366056B - Method, device, equipment and storage medium for realizing ASON business model

Info

Publication number: CN110366056B
Application number: CN201810309505.4A
Authority: CN
Inventors: 田琪; 朱帆; 朱玺; 杨明杰
Original assignee: ZTE Corp
Current assignee: ZTE Corp
Priority date: 2018-04-09
Filing date: 2018-04-09
Publication date: 2021-12-24
Anticipated expiration: 2038-04-09
Also published as: WO2019196844A1; CN110366056A

Abstract

The invention discloses a method, a device, equipment and a storage medium for realizing an ASON service model, relating to the field of telecommunication equipment, wherein the method comprises the following steps: acquiring physical resource information configured to a current network element from a network management terminal; generating a logic rule and a structure corresponding to the physical resource according to the physical resource information; and generating an ASON service model required by the configuration service according to the logic rule and the structure, and sending the ASON service model to each network element of the ASON network. The embodiment of the invention generates a controllable model view by abstracting the resources in the equipment, and the control plane schedules and manages the resources of the whole network element through the view, thereby achieving the purposes of reasonably and fully utilizing the resources and uniformly managing.

Description

Method, device, equipment and storage medium for realizing ASON business model

Technical Field

The present invention relates to the field of telecommunication equipment, and in particular, to a method, an apparatus, a device, and a storage medium for implementing an ASON (automatic Switched Optical Network) service model.

Background

With the arrival of the 5G era of information explosion, the network structure is complicated, the network scale is increasingly expanded, the traffic borne by the network is increased rapidly in a geometric level, and the characteristics all put higher requirements on the processing capacity and the operation and maintenance mode of network equipment.

An OTN (Optical Transport Network) device finishes automatic switching and connection control by a control plane by loading an ASON component, so that service scheduling is not limited to a manual configuration mode any more, and the device can dynamically allocate resources according to the idle state of Network resources under the intelligent control of the ASON, thereby ensuring the reliable operation of the Network and the full use of the resources.

In the software architecture of the traditional ASON, a user side or a network manager dynamically initiates a service request, and functions such as service establishment and service protection are realized through signaling control, but with the increase of service boards with different functions, service configuration and management flow become complicated, and equipment can only be managed through a network management terminal, so that engineering use scenes are limited, and great inconvenience is brought to user operation.

Disclosure of Invention

The embodiment of the invention provides a method, a device, equipment and a storage medium for realizing an ASON business model, and solves the problem of high complexity of business configuration and management.

According to the method for realizing the ASON business model provided by the embodiment of the invention, the method comprises the following steps:

acquiring physical resource information configured to a current network element from a network management terminal;

generating a logic rule and a structure corresponding to the physical resource according to the physical resource information;

and generating an ASON service model required by the configuration service according to the logic rule and the structure, and sending the ASON service model to each network element of the ASON network.

Preferably, the generating a logic rule and a structure corresponding to the physical resource according to the physical resource information includes:

analyzing the physical resource information, and determining the type of the physical resource configured to the current network element;

if the type is determined to be the port resource, performing logic port abstraction processing on the physical resource to obtain a logic port type corresponding to the physical resource;

and if the type is determined to be the optical fiber resource, performing logic path abstract processing on the physical resource to obtain a logic relationship of a connection path corresponding to the physical resource.

Preferably, the generating, according to the logic rule and the structure, an ASON service model required for configuring a service, and sending the ASON service model to each network element of an ASON network includes:

allocating a designated storage format for the logic port type corresponding to the physical resource and/or the logic relationship of the connection path corresponding to the physical resource to obtain the ASON service model;

and sending the ASON business model to each network element of the ASON network in a flooding mode.

Preferably, after the generating, according to the logic rule and the structure, an ASON service model required for configuring a service and sending the ASON service model to each network element of an ASON network, the method further includes:

splitting a network element level configuration message for service configuration from the network management terminal to obtain single board level service configuration information;

updating the ASON business model by using the single board level business configuration information to obtain an updated ASON business model;

and generating a single-board level configuration message for service configuration by using the updated ASON service model, and sending the single-board level configuration message to each single board of the current network element.

Preferably, the splitting the network element level configuration message for service configuration from the network management terminal to obtain the single board level service configuration information includes:

determining a configured service type and a node type of the service according to the network element level configuration message for service configuration;

and splitting the network element level configuration message into the single board level service configuration information according to the service type and the node type.

Preferably, the splitting the network element level configuration packet into the single board level service configuration information according to the service type and the node type includes:

if the service type is data service and the node type is a head-to-tail node, splitting the network element level configuration message into access layer information;

if the service type is data service and the node type is an intermediate node, splitting the network element level configuration message into client layer information;

if the service type is an OTN service and the node type is a head-to-tail node, splitting the network element level configuration message into optical layer electrical layer information;

and if the service type is an OTN service and the node type is an intermediate node, splitting the network element level configuration message into optical layer information.

According to an embodiment of the present invention, an apparatus for implementing an ASON service model includes:

the resource extraction module is used for acquiring physical resource information configured to the current network element from the network management terminal;

the resource abstraction module is used for generating a logic rule and a structure corresponding to the physical resource according to the physical resource information;

and the model processing module is used for generating an ASON service model required by the configuration service according to the logic rule and the structure and sending the ASON service model to each network element of the ASON network.

Preferably, the apparatus further comprises:

the service analysis module is used for splitting the network element level configuration message used for service configuration from the network management terminal to obtain single board level service configuration information;

the model updating module is used for updating the ASON business model by utilizing the single-board level business configuration information to obtain an updated ASON business model;

and the configuration processing module is used for generating a single-board level configuration message for service configuration by using the updated ASON service model, and sending the single-board level configuration message to each single board of the current network element.

According to an embodiment of the present invention, an apparatus for implementing an ASON service model includes: a processor, and a memory coupled to the processor; the memory stores an implementation program of the ASON business model that can run on the processor, and the implementation program of the ASON business model implements the steps of the implementation method of the ASON business model when being executed by the processor.

According to an embodiment of the present invention, a storage medium is provided, on which an implementation program of an ASON service model is stored, and the implementation program of the ASON service model implements the steps of the implementation method of the ASON service model described above when being executed by a processor.

The technical scheme provided by the embodiment of the invention has the following beneficial effects:

the embodiment of the invention schedules and manages the resources of the whole network element through the controllable service model obtained by abstracting the resources in the equipment, can fully and reasonably utilize the resources and uniformly manage the resources, and reduces the complexity of service configuration and management.

Drawings

Fig. 1 is a schematic flowchart of an implementation method of an ASON service model according to an embodiment of the present invention;

fig. 2 is a schematic flow chart of ASON service configuration provided in an embodiment of the present invention;

fig. 3 is a schematic block diagram of an apparatus for implementing an ASON service model according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of a first configuration of an apparatus according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a second configuration of the apparatus according to the embodiment of the present invention;

FIG. 6 is a schematic flow diagram of an embodiment of the apparatus of FIG. 4;

fig. 7 is a schematic flow chart of an implementation of the apparatus of fig. 5.

Detailed Description

The preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings, and it should be understood that the preferred embodiments described below are only for the purpose of illustrating and explaining the present invention, and are not to be construed as limiting the present invention.

Fig. 1 is a schematic flow diagram of a method for implementing an ASON service model according to an embodiment of the present invention, where as shown in fig. 1, the method includes:

step S101: and acquiring the physical resource information configured to the current network element from the network management terminal.

And acquiring the physical resource information configured to the current network element from the message for resource configuration from the network management terminal. As an implementation manner, the messages from the network management terminal are classified to obtain messages for resource configuration, and the messages for resource configuration are analyzed to obtain physical resource information configured to the current network element. The physical resource information includes attribute information of a board port of the current network element, optical fiber connection relation information, and the like.

Step S102: and generating a logic rule and a structure corresponding to the physical resource according to the physical resource information.

Analyzing the physical resource information, determining the type of the physical resource configured to the current network element, if the type is determined to be a port resource, performing logical port abstraction on the physical resource according to the attribute of the physical resource, for example, the port is an optical port or an electrical port, a home client side or a line side, and the like, to obtain a logical port type corresponding to the physical resource, and if the type is determined to be an optical fiber resource, performing logical path abstraction on the physical resource to obtain a logical relationship of a connection path corresponding to the physical resource, for example, after a port a performs logical path abstraction through an optical fiber connection port b, obtaining a connection path from the port a to the port b and a connection path from the port b to the port a.

Step S103: and generating an ASON service model required by the configuration service according to the logic rule and the structure, and sending the ASON service model to each network element of the ASON network.

And allocating a designated storage format for the logic port type corresponding to the physical resource and/or the logic relationship of the connection path corresponding to the physical resource to obtain the ASON service model, and sending the ASON service model to each network element of the ASON network in a flooding manner.

In this embodiment, a controllable ASON service model is obtained by abstracting resources inside a network element.

After step S103 is executed, a step of configuring a service is further included, fig. 2 is a schematic flow chart of ASON service configuration provided in the embodiment of the present invention, and as shown in fig. 2, the following steps S104 to S106 are included:

step S104: and splitting the network element level configuration message for service configuration from the network management terminal to obtain single board level service configuration information.

The method comprises the steps of classifying messages from a network management terminal to obtain network element level configuration messages for service configuration, determining configured service types and service node types according to the network element level configuration messages for service configuration, and splitting the network element level configuration messages into single-board level service configuration information according to the service types and the node types.

Wherein the service types include data service and OTN service.

The node types comprise head and tail nodes and intermediate nodes.

The single-board service configuration information comprises access layer information, client layer information, optical layer electrical layer information and optical layer information.

If the service type is data service and the node type is a head-to-tail node, splitting the network element level configuration message into access layer information; if the service type is data service and the node type is an intermediate node, splitting the network element level configuration message into client layer information; if the service type is an OTN service and the node type is a head-to-tail node, splitting the network element level configuration message into optical layer electrical layer information; and if the service type is an OTN service and the node type is an intermediate node, splitting the network element level configuration message into optical layer information.

Step S105: and updating the ASON service model by using the single board level service configuration information, namely updating the single board level service configuration information to the ASON service model to obtain an updated ASON service model.

Step S106: and generating a single-board level configuration message for service configuration by using the updated ASON service model, and distributing the single-board level configuration message to each single board of the current network element.

In the embodiment, by using the ASON service model, the resources of the whole network element are scheduled and managed, thereby reducing the complexity of service configuration and management.

It will be understood by those skilled in the art that all or part of the steps in the method for implementing the above embodiments may be implemented by hardware related to instructions of a program, and the program may be stored in a computer readable storage medium. Furthermore, the present invention may also provide a storage medium, on which an implementation program of the ASON service model is stored, and when being executed by a processor, the implementation program of the ASON service model implements the steps of the implementation method of the ASON service model. The storage medium may include ROM/RAM, magnetic disk, optical disk, and U disk.

Fig. 3 is a schematic block diagram of an apparatus for implementing an ASON service model according to an embodiment of the present invention, and as shown in fig. 3, the apparatus includes:

the resource extraction module 201 is configured to obtain physical resource information configured to the current network element from the network management terminal. Specifically, the resource extraction module 201 classifies the messages from the network management terminal to obtain messages for resource configuration, and analyzes the messages for resource configuration to obtain physical resource information configured to the current network element.

And the resource abstraction module 202 is configured to generate a logic rule and a structure corresponding to the physical resource according to the physical resource information. Specifically, the resource abstraction module 202 analyzes the physical resource information, determines a type of a physical resource configured to the current network element, performs logical port abstraction on the physical resource to obtain a logical port type corresponding to the physical resource if the type is determined to be a port resource, and performs logical path abstraction on the physical resource to obtain a logical relationship of a connection path corresponding to the physical resource if the type is determined to be an optical fiber resource.

And the model processing module 203 is configured to generate an ASON service model required by the configuration service according to the logic rule and the structure, and send the ASON service model to each network element of the ASON network. Specifically, the model processing module 203 allocates a designated storage format to the logical port type corresponding to the physical resource and/or the logical relationship of the connection path corresponding to the physical resource, obtains the ASON service model, and sends the ASON service model to each network element of the ASON network in a flooding manner.

The device further comprises:

the service analysis module 204 is configured to split the network element level configuration message for service configuration from the network management terminal to obtain single board level service configuration information. Specifically, the service analysis module 204 classifies the messages from the network management terminal to obtain a network element level configuration message for service configuration, determines the configured service type and the node type of the service according to the network element level configuration message for service configuration, and splits the network element level configuration message into single board level service configuration information according to the service type and the node type.

The model updating module 205 is configured to update the ASON service model by using the single board level service configuration information, that is, update the single board level service configuration information to the ASON service model to obtain an updated ASON service model.

A configuration processing module 206, configured to generate a board-level configuration packet for service configuration by using the updated ASON service model, and send the packet to each board of the current network element.

The embodiment provides an implementation device of an ASON service model, where the device includes: a processor, and a memory coupled to the processor; the memory stores an implementation program of the ASON business model that can run on the processor, and the implementation program of the ASON business model implements the steps of the implementation method of the ASON business model when being executed by the processor.

By introducing a service model, the embodiment of the invention ensures that the equipment main control software does not simply adapt and forward any more, and simultaneously also undertakes the functions of equipment management, service management and the like of network elements. Based on the service management model (namely, the service model), a user can conveniently carry out unified access and support on the ASON through a control plane view, and the connection management capability and the operation and maintenance flexibility of the equipment are enhanced.

The embodiment of the invention provides a method and a device for realizing a service module, which particularly comprises the following steps that a plurality of specific service processing devices are added:

fig. 4 is a schematic diagram of a first structure of the apparatus according to the embodiment of the present invention, as shown in fig. 4, including the following newly added modules:

the device 301 is a resource configuration device, and is configured to send, by a terminal, configuration message information to a service model device, where the configuration message information includes messages such as a single board plug board and optical fiber connection information.

The device 302 is a resource extraction device, and is configured to receive various configuration messages sent by the terminal, classify all the messages, extract messages of resource configuration, and send the messages to the resource abstraction device.

The device 303 is a resource abstraction device (equivalent to the resource extraction module 201 and the resource abstraction module 202), and is configured to analyze the delivered resource configuration and generate various rules and logical structures in the service model.

The device 304 is a business model device, and is configured to allocate a specific storage format to rules and structures abstracted by the resource abstraction device, generate various business models, and use the models in subsequent business configuration.

Device 305 is a resource uploading device that is used to flood (flood) the various models generated by the business model device to the entire network, informing each node in the network.

The functions of the resource extraction module 201 and the resource abstraction module 202 of FIG. 3 may be implemented by the means 302 and the means 303; the model generation function of the model processing module 203 of fig. 3 may be implemented by the device 304, and the model transmission function may be implemented by the device 305.

Fig. 5 is a schematic diagram of a second structure of the apparatus according to the embodiment of the present invention, as shown in fig. 5, including the following newly added apparatuses:

the device 401 is a service configuration device, and is used for a terminal to send a service configuration message to a service model device;

the device 402 is a service extraction device, and is configured to receive various configuration messages sent by a terminal, classify all the messages, extract service configuration messages, and send the messages to a service analysis device;

the device 403 is a service analysis device, configured to analyze the content of the service configuration packet, split the delivered network element level configuration packet into a single board level granularity, and send the split result to the service model device;

the device 404 is a service model device, and is configured to perform model checking and information query on a service configuration packet split by the service analysis device, and send the integrated packet to a configuration issuing device;

the device 405 is a configuration issuing device, and is configured to distribute a single board level configuration packet output by the service model device to each single board.

The functions of the fig. 3 traffic analysis module 204 may be implemented by the means 402 and the means 403, the functions of the fig. 3 model update module 205 may be implemented by the means 404, and the functions of the fig. 3 configuration processing module 206 may be implemented by the means 404 and the means 405.

Fig. 6 is a schematic flow chart of an implementation of the apparatus in fig. 4, and as shown in fig. 6, the detailed steps of generating the business model are as follows:

step 501, device 301 configures resource information such as board attribute information and optical fiber connection relation of the current network element;

step 502, the device 302 distinguishes the received message, separates out the configuration message related to the physical resource, and delivers the configuration message to the device 303 for processing;

step 503, the device 303 abstracts the attribute of the port on the board, and generates a logical relationship of the attribute information;

step 504, the device 303 abstracts the optical fiber connection relationship of the ports on the board to generate a logical relationship of the connection path;

505, the device 304 allocates a certain storage format to various rules and logic structures abstracted by the device 303, and generates a corresponding resource model and a corresponding service model;

at step 506, device 305 floods the entire network with the various models newly generated in device 304 so that each node in the network knows the topology of the entire network.

After the above processing steps, the resource model and the service model required for configuring the service are generated.

Fig. 7 is a schematic implementation flow diagram of the apparatus in fig. 5, and as shown in fig. 7, the detailed steps of configuring different services after the service model is generated are as follows:

step 601, the device 401 configures end-to-end service configuration information;

step 602, the device 402 distinguishes the received message, separates out the service configuration message, and gives it to the device 403 for processing;

step 603, the device 403 determines the configured service type, if the service type is a data service, the step 604 is performed, and if the service type is an OTN service, the step 607 is performed;

step 604, the device 403 judges the node type of the service, if the node type is an intermediate node, step 605 is performed, and if the node type is a head-to-tail node, step 606 is performed;

step 605, the device 403 splits the service configuration packet, generates client layer information, and sends the client layer information to the device 404;

step 606, the device 403 splits the service configuration packet, generates access layer information, and sends the access layer information to the device 404;

step 607, the device 403 determines the node type of the service, if the node type is an intermediate node, the step 608 is performed, and if the node type is a head-to-tail node, the step 609 is performed;

step 608, the device 403 splits the service configuration packet, generates optical layer information, and sends the optical layer information to the device 404;

step 609, the device 403 splits the service configuration message, generates optical layer electrical layer information, and sends the optical layer electrical layer information to the device 404;

step 610, the device 404 updates the various model information split by the device 403 into the business model;

in step 611, the device 405 distributes the service configuration packet at the board level output by the device 404 to each board.

In summary, the embodiments of the present invention have the following technical effects:

the embodiment of the invention generates a controllable resource model and a service model view by abstracting the service resources in the equipment, and the control plane schedules and manages the resources of the whole network element through the view, thereby achieving the purposes of reasonably and fully utilizing the resources and uniformly managing.

Although the present invention has been described in detail hereinabove, the present invention is not limited thereto, and various modifications can be made by those skilled in the art in light of the principle of the present invention. Thus, modifications made in accordance with the principles of the present invention should be understood to fall within the scope of the present invention.

Claims

1. A method for implementing an ASON service model, the method comprising:

performing logic path abstract processing on the physical resource with the type of the optical fiber resource to obtain a logic relationship of a connection path corresponding to the physical resource with the type of the optical fiber resource;

and generating an ASON service model required by the configuration service according to the logical relationship of the connection path corresponding to the physical resource of which the type is the optical fiber resource, and sending the ASON service model to each network element of the ASON network.

2. The method of claim 1, further comprising:

performing logical port abstraction processing on the physical resource of which the type is the port resource to obtain a logical port type corresponding to the physical resource of which the type is the port resource;

and allocating a specified storage format for the logic port type corresponding to the physical resource of which the type is the port resource, or allocating a specified storage format for the logic relationship between the logic port type corresponding to the physical resource of which the type is the port resource and the connection path corresponding to the physical resource of which the type is the optical fiber resource, so as to obtain an ASON service model, and sending the ASON service model to each network element of the ASON network.

3. The method of claim 1, wherein the generating, according to the logical relationship of the connection path corresponding to the physical resource, an ASON service model required for configuring a service, and sending the ASON service model to each network element of an ASON network comprises:

and allocating a designated storage format to the logical relationship of the connection path corresponding to the physical resource to obtain the ASON service model, and sending the ASON service model to each network element of the ASON network in a flooding manner.

4. The method according to any of claims 1-3, wherein after generating the ASON service model required for configuring the service and sending the ASON service model to each network element of the ASON network, the method further comprises:

5. The method according to claim 4, wherein the splitting the network element level configuration packet for service configuration from the network management terminal to obtain a single board level service configuration information comprises:

6. The method of claim 5, wherein the monolithic service configuration information comprises access stratum information, client stratum information, optical stratum information, and wherein splitting the network element level configuration packet into the monolithic service configuration information according to the service type and the node type comprises:

if the service type is an Optical Transport Network (OTN) service and the node type is a head-to-tail node, splitting the network element level configuration message into optical layer electrical layer information;

7. An apparatus for implementing an ASON service model, the apparatus comprising:

the resource abstraction module is used for analyzing the physical resource information and determining the type of the physical resource configured to the current network element; performing logic path abstract processing on the physical resource with the type of the optical fiber resource to obtain a logic relationship of a connection path corresponding to the physical resource with the type of the optical fiber resource;

and the model processing module is used for generating an ASON service model required by the configuration service according to the logical relationship of the connection path corresponding to the physical resource of which the type is the optical fiber resource, and sending the ASON service model to each network element of the ASON network.

8. The apparatus of claim 7,

the resource abstraction module is further configured to perform logical port abstraction processing on the physical resource of which the type is the port resource to obtain a logical port type corresponding to the physical resource of which the type is the port resource;

correspondingly, the model processing module is further configured to allocate a specified storage format to the logical port type corresponding to the physical resource of which the type is the port resource, or allocate a specified storage format to a logical relationship between the logical port type corresponding to the physical resource of which the type is the port resource and the connection path corresponding to the physical resource of which the type is the optical fiber resource, so as to obtain an ASON service model, and send the ASON service model to each network element of the ASON network.

9. The apparatus of claim 7 or 8, further comprising:

10. An apparatus for implementing an ASON service model of an automatically switched optical network, the apparatus comprising: a processor, and a memory coupled to the processor; the memory stores an implementation program of the ASON business model, which is executable on the processor, and when executed by the processor, the implementation program of the ASON business model implements the steps of the method for implementing the ASON business model according to any one of claims 1 to 6.

11. A storage medium storing an implementation program of an ASON business model, the implementation program of the ASON business model implementing the steps of the method for implementing an ASON business model according to any one of claims 1 to 6 when executed by a processor.