CN111092749B - Region grid division method and device for full service - Google Patents

Abstract

The invention discloses a regional grid division method and a device facing to full service, wherein the method comprises the steps of determining service parameters of a plurality of service requirements of a certain region; calculating the target network resource requirement of each basic resource of a certain area based on the service parameter of each service requirement; acquiring the current network resource demand and resource use condition corresponding to each basic resource; and determining a network construction scheme of a certain area in a predetermined planning period according to the target network resource requirement, the current network resource requirement and the resource use condition corresponding to each basic resource. Therefore, the network resources of the area can be reasonably distributed according to the actual situation, when the service demand of the area is larger, the network resources of the area are increased, and when the service demand of the area is smaller, the network resources of the area are reduced, so that the network resources are fully utilized, the utilization rate of the network resources is improved, and the use experience of users on the network resources is improved.

Description

Region grid division method and device for full service

Technical Field

The present invention relates to the field of network communication technologies, and in particular, to a method and an apparatus for dividing area grids for full service.

Background

With the development of network communication technology and the dependence of people on network communication, network communication plays a crucial role in the aspects of life, work and the like of people. At present, network construction mainly lays out and constructs business-intensive areas and key areas around user complaints, key scenes, competitor benchmarks and the like, and few networks are deployed in non-business-intensive areas (such as counties and towns). However, although this kind of network construction can guarantee a specific area, the area is not exactly the same as the user, the user has mobility, and when a large number of users flow into a non-traffic-intensive area from a traffic-intensive area and a key area (for example, the user returns from a large city to a county city during the past year), the network resources of the traffic-intensive area and the key area are wasted, and the network resources of the non-traffic-intensive area are difficult to meet the user's demand for the network resources. Therefore, how to reasonably allocate the network resources is important to improve the utilization rate of the network resources.

Disclosure of Invention

The technical problem to be solved by the present invention is to provide a method and an apparatus for dividing a full-service-oriented area grid, which can realize the full utilization of network resources by reasonably allocating the network resources.

In order to solve the above technical problem, a first aspect of an embodiment of the present invention discloses a method for dividing area grids for full services, where the method includes:

determining a plurality of service requirements of a certain area, and determining a service parameter of each service requirement, wherein all the service requirements comprise at least one of 5G service requirements, 4G service requirements, 3G service requirements, 2G service requirements, home broadband service requirements and customer collecting service requirements;

calculating a target network resource requirement corresponding to each basic resource of the certain area based on each service requirement and a service parameter of the service requirement, wherein the basic resource comprises an optical communication resource, a communication equipment resource and an optical cable resource, and the target network resource requirement at least comprises the required quantity of each basic resource;

acquiring the current network resource requirement corresponding to each basic resource and the predetermined resource use condition corresponding to each basic resource in a certain area;

and determining a network construction scheme of the certain area in a predetermined planning period according to the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource and the resource use condition corresponding to each basic resource.

As an optional implementation manner, in the first aspect of the embodiment of the present invention, the service parameter includes a fixed parameter and a variable parameter;

the fixed parameters are parameters which cannot be changed after the certain area is set;

the variable parameter is a parameter which changes with the resource allocation strategy of the certain area;

and, said determining a service parameter for each of said service requirements comprises:

receiving a service parameter aiming at each service requirement sent by a management department, wherein the management department comprises at least one of an engineering construction department, a network maintenance department and a planning department; alternatively, the first and second electrodes may be,

and screening the service parameters of each service requirement from a pre-established network resource database.

As an optional implementation manner, in the first aspect of the embodiment of the present invention, before determining a network construction scheme of the certain area in a predetermined planning period according to a target network resource requirement corresponding to each of the basic resources, a current network resource requirement corresponding to each of the basic resources, and a resource usage situation corresponding to each of the basic resources, the method further includes:

collecting regional information of the certain region, wherein the regional information comprises at least one of geographic area, population density and economic density;

inputting the region information into a predetermined region scene classification model, obtaining a classification result output by the region scene classification model as a grid region scene type of a certain region, and determining the distribution dense condition of each service requirement in the grid region scene type;

the determining a network construction scheme of the certain area in a predetermined planning period according to the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource, and the resource use condition corresponding to each basic resource includes:

and determining a network construction scheme of the certain area in a predetermined planning period according to the distribution density condition of each service demand in the scene type of the grid area, the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource and the resource use condition corresponding to each basic resource.

As an optional implementation manner, in the first aspect of the embodiment of the present invention, the acquiring a presence network resource corresponding to each of the basic resources includes:

and determining the current resource occupation condition corresponding to each basic resource, and calculating the residual resource condition of the basic resource based on the total resource condition of each basic resource and the current resource occupation condition of the basic resource to be used as the current network resource requirement corresponding to the basic resource.

As an optional implementation manner, in the first aspect of the embodiment of the present invention, before determining a network construction scheme of the certain area in a predetermined planning period according to a target network resource requirement corresponding to each of the basic resources, a current network resource requirement corresponding to each of the basic resources, and a resource usage situation corresponding to each of the basic resources, the method further includes:

judging whether the business requirements needing to be adjusted exist in all the business requirements, and triggering and executing the operation of determining the network construction scheme of a certain area in a predetermined planning period according to the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource and the resource use condition corresponding to each basic resource when the business requirements needing to be adjusted do not exist in all the business requirements.

As an optional implementation manner, in the first aspect of the embodiment of the present invention, when it is determined that the service requirement to be adjusted exists in all the service requirements, a resource adjustment condition of each service requirement in a certain predetermined future time period is determined based on predetermined network system data and/or a predetermined service record for each service requirement, where the resource adjustment condition includes a resource occupation condition or a resource rollback condition;

the determining a network construction scheme of the certain area within a predetermined planning period according to the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource, and the resource usage condition corresponding to each basic resource includes:

and determining a network construction scheme of the certain area in a predetermined planning period according to the resource adjustment condition of each service requirement, the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource and the resource use condition corresponding to each basic resource.

As an optional implementation manner, in the first aspect of the embodiment of the present invention, the network construction scheme includes a communication device network construction scheme, an optical cable network construction scheme, and an optical cross-connect network construction scheme;

the communication equipment network construction scheme comprises a PTN communication equipment network construction scheme, an OLT communication equipment network construction scheme and a BNG communication equipment network construction scheme;

the optical cable network construction scheme comprises a distribution optical cable network construction scheme and a trunk optical cable network construction scheme;

the optical traffic network construction scheme comprises a primary optical traffic network construction scheme and a secondary optical traffic network construction scheme.

The second aspect of the embodiment of the invention discloses a region meshing device facing to full service, which comprises:

the system comprises a determining module, a service processing module and a service processing module, wherein the determining module is used for determining a plurality of service requirements of a certain area, and all the service requirements comprise at least one of 5G service requirements, 4G service requirements, 3G service requirements, 2G service requirements, home broadband service requirements and customer service requirements;

the determining module is further configured to determine a service parameter of each service requirement;

a calculating module, configured to calculate, based on each service requirement and a service parameter of the service requirement, a target network resource requirement corresponding to each basic resource of the certain area, where the basic resource includes an optical communication resource, a communication device resource, and an optical cable resource, and the target network resource requirement at least includes a required quantity of each basic resource;

an obtaining module, configured to obtain a current network resource requirement corresponding to each basic resource and a resource usage condition of the certain area corresponding to each predetermined basic resource;

the determining module is further configured to determine a network construction scheme of the certain area within a predetermined planning period according to the target network resource demand corresponding to each of the basic resources, the current network resource demand corresponding to each of the basic resources, and the resource usage condition corresponding to each of the basic resources.

As an optional implementation manner, in the second aspect of the embodiment of the present invention, the service parameter includes a fixed parameter and a variable parameter;

the fixed parameters are parameters which cannot be changed after the certain area is set;

the variable parameter is a parameter which changes with the resource allocation strategy of the certain area;

and the mode of determining the service parameter of each service requirement by the determining module is specifically as follows:

receiving a service parameter aiming at each service requirement sent by a management department, wherein the management department comprises at least one of an engineering construction department, a network maintenance department and a planning department; alternatively, the first and second electrodes may be,

and screening the service parameters of each service requirement from a pre-established network resource database.

As an optional implementation manner, in the second aspect of the embodiment of the present invention, the apparatus further includes:

the acquisition module is used for acquiring regional information of a certain region before the determination module determines a network construction scheme of the certain region in a predetermined planning period according to a target network resource demand corresponding to each basic resource, a current network resource demand corresponding to each basic resource and a resource use condition corresponding to each basic resource, wherein the regional information comprises at least one of a geographic area, population density and economic density;

the input module is used for inputting the region information into a predetermined region scene classification model to obtain a classification result output by the region scene classification model, and the classification result is used as a grid region scene type of a certain region;

the determining module is further configured to determine a dense distribution condition of each service requirement in the grid area scene type;

the mode that the determining module determines the network construction scheme of the certain area in the predetermined planning period according to the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource and the resource use condition corresponding to each basic resource is specifically as follows:

and determining a network construction scheme of the certain area in a predetermined planning period according to the distribution density condition of each service demand in the scene type of the grid area, the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource and the resource use condition corresponding to each basic resource.

As an optional implementation manner, in the second aspect of the embodiment of the present invention, a manner of the obtaining module obtaining the presence network resource corresponding to each of the basic resources is specifically:

and determining the current resource occupation condition corresponding to each basic resource, and calculating the residual resource condition of the basic resource based on the total resource condition of each basic resource and the current resource occupation condition of the basic resource to be used as the current network resource requirement corresponding to the basic resource.

As an optional implementation manner, in the second aspect of the embodiment of the present invention, the apparatus further includes:

a determining module, configured to determine whether a service requirement that needs to be adjusted exists in all the service requirements before the determining module determines a network construction scheme of the certain area within a predetermined planning period according to a target network resource requirement corresponding to each of the basic resources, a current network resource requirement corresponding to each of the basic resources, and a resource usage condition corresponding to each of the basic resources;

the determining module is further configured to determine, when the determining module determines that the service demand to be adjusted does not exist in all the service demands, a network construction scheme of the certain area within a predetermined planning period according to a target network resource demand corresponding to each of the basic resources, a current network resource demand corresponding to each of the basic resources, and a resource usage situation corresponding to each of the basic resources.

As an optional implementation manner, in the second aspect of the embodiment of the present invention, the determining module is further configured to, when the determining module determines that the service requirement to be adjusted exists in all the service requirements, determine, based on predetermined network system data and/or predetermined service records for each service requirement, a resource adjustment condition of each service requirement in a certain predetermined future time period, where the resource adjustment condition includes a resource occupation condition or a resource rollback condition;

the mode that the determining module determines the network construction scheme of the certain area within the predetermined planning period according to the target network resource demand corresponding to each of the basic resources, the current network resource demand corresponding to each of the basic resources, and the resource usage condition corresponding to each of the basic resources is specifically as follows:

and determining a network construction scheme of the certain area in a predetermined planning period according to the resource adjustment condition of each service requirement, the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource and the resource use condition corresponding to each basic resource.

As an optional implementation manner, in the second aspect of the embodiment of the present invention, the network construction scheme includes a communication device network construction scheme, an optical cable network construction scheme, and an optical cross-connect network construction scheme;

the communication equipment network construction scheme comprises a PTN communication equipment network construction scheme, an OLT communication equipment network construction scheme and a BNG communication equipment network construction scheme;

the optical cable network construction scheme comprises a distribution optical cable network construction scheme and a trunk optical cable network construction scheme;

the optical traffic network construction scheme comprises a primary optical traffic network construction scheme and a secondary optical traffic network construction scheme.

The third aspect of the present invention discloses another area meshing device for full services, which includes:

a memory storing executable program code;

a processor coupled with the memory;

the processor calls the executable program code stored in the memory to execute the area meshing method facing the full service disclosed by the first aspect of the invention.

The fourth aspect of the present invention discloses a computer-readable storage medium, where the computer-readable storage medium stores computer instructions, and when the computer instructions are called, the computer instructions are used to execute the area meshing method for full services disclosed in the first aspect of the present invention.

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

the embodiment of the invention discloses a region meshing method and a device facing to full service, wherein the method comprises the steps of determining a plurality of service requirements of a certain region and determining a service parameter of each service requirement; calculating a target network resource requirement corresponding to each basic resource of a certain area based on each service requirement and the service parameter of the service requirement; acquiring the current network resource requirement corresponding to each basic resource and the predetermined resource use condition corresponding to each basic resource in a certain area; and determining a network construction scheme of a certain area in a predetermined planning period according to the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource and the resource use condition corresponding to each basic resource. Therefore, by implementing the embodiment of the invention, the network resource requirement of each basic resource is calculated through the service parameters of a plurality of service requirements, and the network construction scheme is planned for the area by combining the current network resource requirement of each basic resource and the resource use condition, the network resources of the area can be reasonably distributed according to the actual condition, when the service requirement amount of the area is larger, the network resources of the area are increased, and when the service requirement amount of the area is smaller, the network resources of the area are reduced, so that the full utilization of the network resources is realized, the utilization rate of the network resources is improved, and the use experience of the network resources by users is improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings required to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic flowchart of a full-service-oriented area meshing method disclosed in an embodiment of the present invention;

fig. 2 is a schematic flow chart of another full-service-oriented area meshing method disclosed in the embodiment of the present invention;

fig. 3 is a schematic structural diagram of a full-service-oriented area meshing device disclosed in an embodiment of the present invention;

fig. 4 is a schematic structural diagram of another full-service-oriented area meshing device disclosed in the embodiment of the present invention;

fig. 5 is a schematic structural diagram of another area meshing device for full services according to the embodiment of the present invention;

fig. 6 is a scene schematic diagram of an application scenario of the area grid planning disclosed in the embodiment of the present invention;

FIG. 7 is a schematic view of an application scenario of another area grid planning disclosed in an embodiment of the present invention;

fig. 8 is a scene diagram of an application scenario of another area grid planning disclosed in the embodiment of the present invention;

fig. 9 is a scene schematic diagram of an application scenario of another area grid planning disclosed in the embodiment of the present invention.

In the examples of the present invention, the abbreviations that appear are explained as follows:

an optical line terminal: optical Line Terminal, OLT;

fiber to the home: fiber To The Home, FTTH;

a packet transport network: packet Transport Network, PTN;

fiber distribution frame: optical Distribution Frame, ODF;

passive optical network: passive Optical Network, PON.

Detailed Description

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

The terms "first," "second," and the like in the description and claims of the present invention and in the above-described drawings are used for distinguishing between different objects and not for describing a particular order. Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, method, apparatus, article, or communication device that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or communication device.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the invention. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

The invention discloses a regional grid dividing method and a device facing to full service, which can calculate the network resource demand of each basic resource through the service parameters of a plurality of service demands, plan a network construction scheme for the region by combining the current network resource demand and the resource use condition of each basic resource, reasonably distribute the network resources of the region according to the actual condition, increase the network resources of the region when the service demand of the region is larger, and reduce the network resources of the region when the service demand of the region is smaller, thereby realizing the full utilization of the network resources, improving the utilization rate of the network resources and improving the use experience of users on the network resources. The following are detailed below.

Example one

Referring to fig. 1, fig. 1 is a schematic flow chart illustrating a full-service-oriented area meshing method according to an embodiment of the present invention. The area meshing method for full service described in fig. 1 may be applied to a computer, a server, and other network devices with a data processing capability function, and the embodiment of the present invention is not limited thereto. As shown in fig. 1, the area meshing method for full service may include the following operations:

101. the network device determines a number of service requirements for an area and determines a service parameter for each service requirement.

In this embodiment of the present invention, the certain region may include only one region, or may include a plurality of sub-regions.

In this embodiment of the present invention, all service requirements may include at least one of a 5G service requirement, a 4G service requirement, a 3G service requirement, a 2G service requirement, a home broadband service requirement (home broadband service requirement), and a customer service requirement, which is not limited in this embodiment of the present invention. Wherein, the collector is a user/client formed by a group, such as: and if the customer is the industrial and commercial bank, the customer collecting service requirement is the broadband required by the industrial and commercial bank.

In this embodiment of the present invention, as an optional implementation manner, the determining, by a network device, a service parameter of each service requirement may include:

the network device receives a service parameter for each service requirement sent by a management department, where the management department includes at least one of an engineering construction department, a network maintenance department, and a planning department, and the embodiment of the present invention is not limited.

In this embodiment of the present invention, as another optional implementation manner, the determining, by the network device, the service parameter of each service requirement may include:

the network device screens the service parameters of each service requirement from a pre-established network resource database.

Therefore, in the optional embodiment, the management department or the pre-established network resource database is used for acquiring the service parameters of the service requirements, so that the acquisition of the service parameters of the service requirements can be realized, the acquisition modes of the service parameters of the service requirements can be enriched, and the acquisition flexibility of the service parameters of the service requirements is improved.

In an optional embodiment, before performing step 101, the method for area meshing oriented to full services may further include the following operations:

the network equipment judges whether a certain area meets the predetermined network construction scheme determining condition;

when judging that a certain area meets the predetermined network construction scheme determining condition, the network equipment triggers and executes the step 101;

and when judging that a certain area does not meet the predetermined network construction scheme determining condition, the network equipment ends the process.

In this optional embodiment, as an optional implementation manner, the determining, by the network device, whether a certain area meets a predetermined network construction scheme determination condition may include:

the method comprises the steps that network equipment obtains the population flow of a certain area and judges whether the population flow is not in a predetermined population flow range or not;

and when the determined population flow is not in the predetermined population flow range, the network equipment determines that a certain area meets the predetermined network construction scheme determination condition.

Therefore, in the optional embodiment, by acquiring the population flow of the area and comparing the population flow with the determined population flow range, the network construction scheme determination condition of the area can be quickly judged.

In this optional embodiment, as another optional implementation, the determining, by the network device, whether a certain area meets a predetermined network construction scheme determination condition may include:

the network equipment acquires a current date and judges whether the current date is a certain date in a predetermined date set;

and when the current date is judged to be a certain date in the predetermined date set, the network equipment determines that a certain area meets the predetermined network construction scheme determination condition.

Therefore, in the alternative embodiment, the judgment of the determination condition of the network construction scheme of the area can be realized by acquiring the current date of the area and comparing the current date with the determined date set.

It can be seen that, in the optional embodiment, before determining the service requirement of the area, it is determined whether the area meets the network construction scheme determination condition, and when the area meets the network construction scheme determination condition, the subsequent network construction scheme determination step is continuously executed, so that the occurrence of the situation that the area does not meet the network construction scheme determination condition but executes the subsequent network construction scheme determination operation can be reduced, thereby reducing the occurrence of the situation of network resource misallocation, reducing the power consumption of network equipment, and improving the service life of the network equipment; and whether the area meets the judgment of the network construction scheme determination condition is determined in various modes, so that the judgment that the area meets the network construction scheme determination condition can be intelligently determined, and the judgment flexibility of the network construction scheme determination condition can be improved.

102. The network equipment calculates the target network resource requirement corresponding to each basic resource of a certain area based on each service requirement and the service parameter of the service requirement.

In the embodiment of the present invention, the service parameter may include a fixed parameter and a variable parameter. The fixed parameter is a parameter that does not change after being set in a certain area. The variable parameter is a parameter that varies with a resource allocation policy of the certain area. The fixed parameters may include at least one of OLT slot positions, the number of device ports, the configuration of the light-splitting distinguishing ports, the utilization rate of the ports, the reserved fiber core ratio, and the like. The variable parameter may include at least one of home width permeability, guest collection permeability, FTTH ratio, home width splitter splitting ratio, guest collection service circuit lease ratio, guest collection splitter splitting ratio, number of PTN slots of each device access layer, number of ports of the PTN slots of each device access layer, port occupied by a secondary optical cross-connect end of a base station access optical cable, port occupied by a secondary optical cross-connect end of a guest collection access optical cable, port occupied by a secondary optical cross-connect end of a home width access optical cable, ratio of an access optical cable to be newly established for base station access service, ratio of an access optical cable to be newly established for home width access service, and ratio of an access optical cable to be newly established for guest collection access service, which is not limited in the embodiments of the present invention. Therefore, the more contents contained in the variable parameters, the more the total resource demand can be estimated, the calculation accuracy and the reliability of the total resource demand can be improved, and the division accuracy of the network resources can be improved.

In the embodiment of the present invention, the basic resource may include at least one of an optical communication resource, a communication device resource and an optical cable resource, and the target network resource requirement at least includes a required quantity of each basic resource. The optical traffic resource may include a primary optical traffic resource and a secondary optical traffic resource, and the communication device resource may include at least one of a PTN device resource, an OLT device resource, a BNG device resource, and an ODF of an integrated access room, which is not limited in the embodiment of the present invention. The cable resources may include at least one of distribution cable core resources and distribution cable length resources, and embodiments of the present invention are not limited thereto.

103. The network equipment acquires the current network resource requirement corresponding to each basic resource and the predetermined resource use condition corresponding to each basic resource in a certain area.

In this embodiment of the present invention, as an optional implementation manner, the obtaining, by a network device, a presence network resource corresponding to each basic resource may include:

the network equipment determines the current resource occupation situation corresponding to each basic resource, and calculates the residual resource situation of each basic resource based on the total resource situation of each basic resource and the current resource occupation situation of the basic resource, and the residual resource situation is used as the current network resource requirement corresponding to the basic resource.

As can be seen, in the optional embodiment, by calculating the remaining resource condition of each basic resource as the current network resource requirement of the basic resource, the network resource in a use state can be cleared, which is beneficial to preferentially meeting the current service requirement through the remaining resource, thereby reducing the possibility of network resource waste.

104. The network equipment determines a network construction scheme of a certain area in a predetermined planning period according to the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource and the resource use condition corresponding to each basic resource.

In the embodiment of the present invention, the network construction scheme may include each service requirement, resource requirement information (for example, device port, optical cable, optical cross-connect, etc.) of each basic resource, and a location of a certain area.

In this embodiment of the present invention, the predetermined planning period (for example, 2019.11.10-2020.01.30) may be a planning period that is automatically determined by the network device according to the detected data, or may be a planning period that is input by the staff to the network device, which is not limited in this embodiment of the present invention. Wherein the data includes all historical data contained in the business requirements.

In the embodiment of the present invention, the network construction scheme may include at least one of a communication device network construction scheme, an optical cable network construction scheme, and an optical cross-connect network construction scheme. The communication equipment network construction scheme may include at least one of a PTN communication equipment network construction scheme, an OLT communication equipment network construction scheme, a BNG communication equipment network construction scheme, and an ODF construction scheme of an integrated access room. The optical cable network construction scheme comprises at least one of a distribution optical cable network construction scheme and a trunk optical cable network construction scheme. The optical traffic network construction scheme includes at least one of a primary optical traffic network construction scheme and a secondary optical traffic network construction scheme, and the embodiment of the present invention is not limited.

In the embodiment of the present invention, a method for determining each sub-network construction scheme included in a network construction scheme specifically includes:

PTN communication equipment network construction scheme:

the network device calculates the requirements of the ports of the PTN communication device according to the following formula:

the PTN port construction requirement is base station access port requirement + guest circuit tenant port requirement, where the base station includes at least one of a 5G base station, a 4G base station, a 3G base station, and a 2G base station, and it should be noted that when there are multiple base stations, a base station with better network communication may be considered preferentially, that is, considered in the order of the 5G base station, the 4G base station, the 3G base station, and the 2G base station.

The PTN board card construction requirement (PTN port requirement-PTN remaining port number)/the number of ports that the single board card can provide. The port requirement comprises the quantity of base station service requirements, and the residual port quantity is the removal of the ports in use.

And (3) confirmation of construction scale: when the construction requirement of the PTN board card is less than the current residual slot position on the PTN board card, the capacity of the PTN board card is expanded; and when the construction requirement of the PTN board card is more than the current residual slot position on the PTN board card, adding the PTN board card.

Secondly, an OLT communication equipment network construction scheme:

the network equipment calculates the PON port construction requirement of the OLT communication equipment according to the following formula:

the required number of PON ports is equal to the required number of home-wide PON ports plus the required number of the guest-collecting non-circuit renting PON ports;

the required number of PON board card construction (the required number of PON ports-the number of PON surplus ports)/the number of ports which can be provided by the single board card is determined, and whether the required number of PON port construction required by the PON port construction is more than or equal to the number of the PON port surplus slot positions under the current situation is determined;

and (3) confirmation of construction scale: when the situation that the port requirement of the PON board card is not more than or equal to the current PON remaining slot position is judged, the capacity of the PON board card is expanded; and when the port requirement of the PON board card is more than or equal to the current residual slot position of the PON, adding OLT equipment.

Further, an architecture mode of the OLT communication equipment network construction is determined according to the scene of the certain area, wherein the architecture mode comprises a rack OLT or a box OLT. Specifically, when the certain area is a business district and is a dense population area, the OLT communication equipment network construction scheme is a rack OLT, and when the certain area is a rural area and is a sparse population area, the OLT communication equipment network construction scheme is a box OLT.

Construction scheme of BNG equipment:

the network device obtains the number of home width access users in the certain area, and judges whether the utilization rate of the average peak value of the link corresponding to the BNG device is larger than or equal to a predetermined utilization rate threshold value or not during the network resource utilization peak period, and judges whether the home width quantity bound by the router unidirectional link corresponding to the BNG device is larger than or equal to a predetermined home width quantity threshold value or not.

And (3) confirmation of construction scale: when the number of home wide access users is more than or equal to 2 ten thousand, BNG equipment is added; when the utilization rate of the average peak value of the link corresponding to the BNG equipment in the network resource utilization peak period is judged to be more than or equal to a utilization rate threshold (for example: 50%) determined in advance, the capacity of the BNG equipment is expanded; and when judging that the home width number bound by the router one-way link corresponding to the BNG device is larger than or equal to a predetermined home width number threshold (for example, 6 links of 10 GE), adjusting the home width number bound by the router one-way link corresponding to the BNG device to 1 home width of 100 GE.

Fourthly, the construction scheme of the fiber core of the distribution cable is as follows:

the network equipment calculates the required quantity of the fiber cores of the distribution optical cables corresponding to all the service requirements according to the following formula:

the required quantity of the fiber cores of the distribution optical cables is equal to the required quantity of the fiber cores of the 4G base station distribution optical cables (for example, PTN (partial TransFlash network) ring forming and remote pulling), the required quantity of the fiber cores of the optical distribution optical cables of the optical concentrator and the required quantity of the fiber cores of the optical distribution optical cables of the home-wide optical splitters, and whether the required quantity of the fiber cores of the distribution optical cables is more than or equal to the quantity of the fiber cores of the remaining optical cables under the condition that the fiber cores of the distribution optical cables are not less than the quantity of the fiber cores of the remaining optical cables;

and (3) confirmation of construction scale: when the required number of the fiber cores of the distribution cable is judged to be not more than or equal to the number of the fiber cores of the current residual optical cable (for example, 10), utilizing the current residual fiber cores of the distribution cable; and when the required quantity of the fiber cores of the distribution cable is judged to be more than or equal to the quantity of the fiber cores of the current residual cables (for example, 10), newly building the distribution cable according to the required quantity of the fiber cores of the distribution cable and the quantity of the fiber cores of the current residual cables.

A second-level light traffic construction scheme:

the network equipment calculates the quantity of the secondary optical cross port requirements of all the service requirements according to the following formula:

the required number of the secondary optical cross ports is equal to the required number of the formed ends of the distribution optical cables, the required number of the formed ends of the base station access optical cables, the required number of the formed ends of the home-wide access optical cables and the required number of the formed ends of the collecting access optical cables. And judging whether the required quantity of the secondary optical cross ports is more than or equal to the required quantity of the residual ports under the condition of the secondary optical cross.

And (3) confirmation of construction scale: when the required quantity of the secondary optical cross ports is judged to be not more than or equal to the required quantity of the secondary optical cross remaining ports, continuing to use the secondary optical cross remaining ports; and when the required quantity of the secondary optical cross-connection ports is judged to be more than or equal to the required quantity of the residual ports under the condition that the required quantity of the secondary optical cross-connection ports is larger than or equal to the required quantity of the secondary optical cross-connection ports, newly building optical cross-connection. The end forming requirement of the base station access optical cable further comprises that the base station access optical cable is formed inside the optical cross connecting box and generally occupies 24 cores; the requirement of the home width and the integrated end of the visitor-collecting access optical cable also comprises that the home width and the integrated end of the visitor-collecting access optical cable are arranged in the optical cross connecting box and generally occupy 6 cores.

Sixthly, an ODF construction scheme for comprehensive access to a machine room:

the network equipment calculates ODF port requirements of access rooms corresponding to all service requirements according to the following formula:

the required number of the ODF ports of the machine room is equal to the required number of the finished ends of the distribution optical cables + the required number of the finished ends of the access optical cables +5G of the required number of the finished ends of the related fiber cores. And judging whether the required number of the ports accessed to the machine room ODF is more than or equal to the current residual port number corresponding to the machine room ODF.

And (3) confirmation of construction scale: when the required number of the ports accessed into the machine room ODF is judged to be not more than or equal to the current residual port number corresponding to the machine room ODF, utilizing the current residual port number corresponding to the machine room ODF; and when the required number of the ports of the access machine room ODF is judged to be more than or equal to the number of the current residual ports corresponding to the machine room ODF, newly building the machine room ODF.

Seventhly, the length construction scheme of the distribution optical cable is as follows:

the network equipment determines the effective coverage area of the distribution cable required by all services according to the following formula: the method comprises the steps of obtaining the effective coverage area of the distribution optical cable (length of the distribution optical cable), the bending degree of the distribution optical cable and the transverse coverage capacity of the distribution optical cable (non-overlapping rate of the distribution optical cable), obtaining the total area of the certain area and the original coverage area of the distribution optical cable, and calculating the distribution coverage rate of the certain area in a predetermined planning period corresponding to all business requirements based on the following formula, wherein the distribution coverage rate (length of the distribution optical cable, bending coefficient of the distribution optical cable, transverse coverage capacity of the distribution optical cable + original coverage area of the distribution optical cable) (non-overlapping rate)/total area of the certain area.

And (3) confirmation of construction scale: the distribution cable length is calculated in conjunction with the distribution cable construction strategy (e.g., achieving a same-side 50M network communication rate for the customer), the distribution cable effective coverage area distribution coverage, and the cable is constructed for the distribution cable length.

In another optional embodiment, before performing step 104, the full-service oriented area meshing method may further include the steps of:

the network device determines whether there is a service requirement that needs to be adjusted in all service requirements, and triggers to execute step 104 when it is determined that there is no service requirement that needs to be modified in all service requirements.

It can be seen that, in the optional embodiment, before determining the network resource construction scheme of the area, it is determined whether all current service requirements have service requirements that need to be adjusted (modified), and if not, the subsequent network resource construction scheme of the area is executed, which can reduce the occurrence of the situation that the network resource scheme needs to be re-determined due to the fact that the service requirements need not be adjusted, and can save the determination time of the network resource construction scheme.

In yet another optional embodiment, the full-service oriented area meshing method may further include the steps of:

when it is determined that the service requirement needing to be modified exists in all the service requirements, the network device determines, based on predetermined network system data and/or predetermined service records for each service requirement, a resource adjustment condition for each service requirement within a certain predetermined future time period (for example, if the current date is 2019.11.01, the future time period may be 2019.11.17-2020.01.19), where the resource adjustment condition includes a resource occupation condition or a resource fallback condition.

In this embodiment of the present invention, as an optional implementation manner, the determining, by a network device, a network construction scheme of a certain area in a predetermined planning period according to a target network resource requirement corresponding to each basic resource, a current network resource requirement corresponding to each basic resource, and a resource usage situation corresponding to each basic resource, by a network device, may include:

and the network equipment determines a network construction scheme of a certain area in a predetermined planning period according to the resource adjustment condition of each service requirement, the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource and the resource use condition corresponding to each basic resource.

In this optional embodiment, the network system data may include at least one of network management data, traffic data, and zongzi data, which is not limited in this optional embodiment. The business record is the field record situation of the staff (for example, the survey staff) for each business requirement.

Therefore, when the optional embodiment judges that the service requirement needing to be adjusted exists, the adjustment condition of the service requirement is obtained, the network resource construction scheme is determined by combining the adjustment condition of the service requirement, the determination accuracy and the reliability of the network resource construction scheme can be improved, the utilization rate of the network resource is further improved, the requirement of a user for the network resource is met, and the user experience is improved.

It can be seen that the area grid partitioning method for the full service described in fig. 1 can calculate the network resource demand of each basic resource through the service parameters of a plurality of service demands, and plan a network construction scheme for the area in combination with the current network resource demand of each basic resource and the resource usage condition, and can reasonably allocate the network resources of the area according to the actual situation, when the service demand of the area is large, the network resources of the area are increased, and when the service demand of the area is small, the network resources of the area are reduced, thereby achieving the full utilization of the network resources, increasing the utilization rate of the network resources, and improving the usage experience of the network resources by the user. In addition, the method can enrich the acquisition mode of the service parameters of the service requirements and improve the acquisition flexibility of the service parameters of the service requirements; the determination time of the network resource construction scheme can be saved; the method and the device can also improve the accuracy and reliability of the determination of the network resource construction scheme, thereby further being beneficial to fully improving the utilization rate of the network resources, meeting the requirements of users for the network resources and improving the experience of the users.

Example two

Referring to fig. 2, fig. 2 is a schematic flowchart of another area meshing method for full service according to an embodiment of the present invention. The area meshing method for the full service described in fig. 2 may be applied to a computer, a server, and other network devices with a data processing capability function, and the embodiment of the present invention is not limited thereto. As shown in fig. 2, the area meshing method for full service may include the following operations:

201. the network device determines a number of service requirements for an area and determines a service parameter for each service requirement.

202. The network equipment calculates the target network resource requirement corresponding to each basic resource of a certain area based on each service requirement and the service parameter of the service requirement.

203. The network equipment acquires the current network resource requirement corresponding to each basic resource and the predetermined resource use condition corresponding to each basic resource in a certain area.

204. The network device collects area information of a certain area.

In this embodiment of the present invention, the area information includes at least one of a geographic area, a population density, and an economic density, which is not limited in this embodiment of the present invention.

205. The network equipment inputs the area information into a predetermined area scene classification model to obtain a classification result output by the area scene classification model, the classification result is used as a grid area scene type of a certain area, and the distribution dense condition of each service requirement in the grid area scene type is determined.

It should be noted that step 204 and step 205 may occur after step 201 and before step 202, or may occur simultaneously with step 201, and the embodiment of the present invention is not limited.

In this embodiment of the present invention, the grid area scene type may include any one of a dense urban area type (e.g., a business area type), a non-dense urban area type (e.g., a shop along a street type), a non-dense urban area type (e.g., a village in a city type), a non-dense urban area type (e.g., a factory area type), and the like, which is not limited in this embodiment of the present invention. The area corresponding to the urban area dense type is an area with the economic density being greater than or equal to a predetermined economic density threshold value and the population density being greater than or equal to a predetermined population density threshold value; the area corresponding to the non-dense land type of the urban area is an area with the economic density more than or equal to a predetermined economic density threshold value and the population density less than a predetermined population density threshold value; the area corresponding to the non-urban area dense land type is an area with the economic density smaller than a predetermined economic density threshold value and the population density larger than or equal to a predetermined population density threshold value; the area corresponding to the non-urban non-dense land type is an area with the economic density smaller than a predetermined economic density threshold value and the population density larger than or equal to a predetermined population density threshold value.

Therefore, the embodiment of the invention can quickly determine the type of the grid area scene corresponding to the area by inputting the information of the area into the predetermined area scene classification model, thereby being beneficial to improving the determination rate of the grid construction scheme of the area.

206. The network equipment determines a network construction scheme of a certain area in a predetermined planning period according to the distribution density condition of each service requirement in the scene type of the grid area, the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource and the resource use condition corresponding to each basic resource.

In this embodiment of the present invention, the network construction scheme may further include at least one of an optical cable layout diagram and a layout diagram description, which is not limited in this embodiment of the present invention.

In an optional embodiment, after the performing 206, the method for full-service oriented area meshing may further include the following operations:

the network equipment sends a network construction prompt to a network planning department, wherein the network construction prompt comprises a network construction scheme and is used for reminding workers of the network planning department to plan network resources of a certain area according to the network construction scheme.

It can be seen that, after the network construction scheme of the area is determined, the optional embodiment further sends the network construction prompt to the network planning department, and can prompt a worker of the network planning department to plan the network resource layout of the area in time according to the network construction scheme, so that the planning efficiency of the network resources of the area is improved, the reasonable allocation rate of the network resources is further improved, and the utilization rate of the network resources is further improved.

In the embodiments of the present invention, in order to make the present invention more clear to those skilled in the art, the description is given by way of example.

When it is determined that the certain area is an area (e.g., a business area) that is uniformly distributed and relatively dense, the optical cable line resource layout of the network construction scheme is as follows, as shown in fig. 6, where the service points are points that need to handle the network, for example: company, user.

And secondly, when the certain area is judged to be an area (such as a factory area) with a concentrated part of the distributed part scattered, the optical cable line resource layout of the network construction scheme is distributed around the whole area as much as possible, as shown in fig. 7.

Thirdly, when the certain area is judged to be a regularly and densely distributed area (for example, a shop area along a street), the optical cable line resource layout of the network construction scheme is as distributed around the whole area as much as possible, as shown in fig. 8.

And when the certain area is judged to be a densely distributed and concentrated area (for example, a rural area in a city), the cable line resource layout of the network construction scheme is arranged around the whole area as much as possible, as shown in fig. 9.

In the embodiment of the present invention, please refer to the related description of steps 101 to 104 in the first embodiment for the detailed description of steps 201 to 203 and step 206, which is not repeated herein.

It can be seen that the area grid division method for full service described in fig. 2 can calculate the network resource demand of each basic resource through the service parameters of a plurality of service demands, plan a network construction scheme for the area in combination with the current network resource demand and the resource usage condition of each basic resource, and reasonably allocate the network resources of the area according to the actual situation, when the service demand of the area is large, increase the network resources of the area, and when the service demand of the area is small, reduce the network resources of the area, thereby achieving the full utilization of the network resources, improving the utilization rate of the network resources, and improving the experience of users on the network resources. In addition, the scene type of the grid area corresponding to the area can be quickly determined, so that the determination rate of the grid construction scheme of the area is favorably improved; and the planning efficiency of the regional network resources is also improved, so that the reasonable distribution rate of the network resources is further improved, and the utilization rate of the network resources is further improved.

EXAMPLE III

Referring to fig. 3, fig. 3 is a schematic flowchart of a full-service-oriented area meshing device according to an embodiment of the present invention. The area meshing device for full service described in fig. 3 may be applied to a computer, a server, and other network devices with a data processing capability function, and the embodiment of the present invention is not limited thereto. As shown in fig. 3, the full service oriented area meshing device includes a determining module 301, a calculating module 302, and an obtaining module 303, where:

the determining module 301 is configured to determine a plurality of service requirements of a certain area, where all the service requirements include at least one of a 5G service requirement, a 4G service requirement, a 3G service requirement, a 2G service requirement, a home broadband service requirement, and a customer service requirement.

The determining module 301 is further configured to determine a service parameter of each service requirement.

A calculating module 302, configured to calculate, based on each service requirement and a service parameter of the service requirement, a target network resource requirement corresponding to each basic resource of a certain area, where the basic resource includes an optical communication resource, a communication device resource, and an optical cable resource, and the target network resource requirement at least includes a required quantity of each basic resource.

An obtaining module 303, configured to obtain a current network resource requirement corresponding to each basic resource and a resource usage situation of a certain area and corresponding to each predetermined basic resource.

The determining module 301 is further configured to determine a network construction scheme of a certain area in a predetermined planning period according to the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource, and the resource usage condition corresponding to each basic resource.

In the embodiment of the invention, the network construction scheme comprises a communication equipment network construction scheme, an optical cable network construction scheme and an optical traffic network construction scheme. The communication equipment network construction scheme comprises a PTN communication equipment network construction scheme, an OLT communication equipment network construction scheme and a BNG communication equipment network construction scheme; the optical cable network construction scheme comprises a distribution optical cable network construction scheme and a main optical cable network construction scheme; the optical cross-network construction scheme comprises a primary optical cross-network construction scheme and a secondary optical cross-network construction scheme.

It can be seen that the area grid dividing apparatus for full service described in fig. 3 can calculate the network resource demand of each basic resource through the service parameters of a plurality of service demands, and plan a network construction scheme for the area in combination with the current network resource demand of each basic resource and the resource usage condition, and can reasonably allocate the network resources of the area according to the actual situation, when the service demand of the area is large, the network resources of the area are increased, and when the service demand of the area is small, the network resources of the area are reduced, thereby achieving the full utilization of the network resources, increasing the utilization of the network resources, and improving the usage experience of the network resources by the user.

In an alternative embodiment, as shown in fig. 3, the service parameters include fixed parameters and variable parameters; the fixed parameters are parameters which cannot be changed after being set in a certain area; the variable parameter is a parameter that varies depending on the resource allocation policy of a certain area.

The mode for determining the service parameter of each service requirement by the determining module 301 specifically includes:

receiving a service parameter aiming at each service requirement sent by a management department, wherein the management department comprises at least one of an engineering construction department, a network maintenance department and a planning department; alternatively, the first and second electrodes may be,

and screening the service parameters of each service requirement from a pre-established network resource database.

It can be seen that the area grid dividing apparatus for full service described in fig. 3 can also obtain the service parameters of the service requirements through a management department or a pre-established network resource database, which not only can achieve the obtaining of the service parameters of the service requirements, but also can enrich the obtaining modes of the service parameters of the service requirements, and improve the obtaining flexibility of the service parameters of the service requirements.

In another optional embodiment, the area meshing device for full service may further include an acquisition module 304 and an input module 305, at this time, a schematic structural diagram of the area meshing device for full service may be as shown in fig. 4, where fig. 4 is a schematic structural diagram of another area meshing device for full service, where:

the acquiring module 304 is configured to acquire area information of a certain area before the determining module 301 determines a network construction scheme of the certain area within a predetermined planning period according to the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource, and the resource usage condition corresponding to each basic resource, where the area information includes at least one of a geographic area, a population density, and an economic density.

An input module 305, configured to input the region information into a predetermined region scene classification model, and obtain a classification result output by the region scene classification model, where the classification result is used as a mesh region scene type of a certain region.

The determining module 301 is further configured to determine a dense distribution of each service requirement in the grid area scene type.

In this optional embodiment, as an optional implementation manner, the determining module 301 specifically determines, according to the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource, and the resource usage condition corresponding to each basic resource, a network construction scheme of a certain area within a predetermined planning period, as follows:

and determining a network construction scheme of a certain area in a predetermined planning period according to the distribution density condition of each service requirement in the scene type of the grid area, the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource and the resource use condition corresponding to each basic resource.

It can be seen that the area grid dividing apparatus for the full service described in fig. 4 can input the information of the area into the predetermined area scene classification model, and can quickly determine the type of the grid area scene corresponding to the area, thereby being beneficial to improving the determination rate of the grid construction scheme of the area.

In yet another alternative embodiment, as shown in fig. 4, the manner for the obtaining module 303 to obtain the presence network resource corresponding to each basic resource specifically includes:

and determining the current resource occupation condition corresponding to each basic resource, and calculating the residual resource condition of each basic resource based on the total resource condition of each basic resource and the current resource occupation condition of the basic resource to be used as the current network resource requirement corresponding to the basic resource.

It can be seen that the area grid dividing apparatus for full service described in fig. 4 can calculate the remaining resource condition of each basic resource as the current network resource requirement of the basic resource, and can clear the network resource in a use state, which is beneficial to preferentially meeting the current service requirement through the remaining resource, thereby reducing the possibility of network resource waste.

In yet another alternative embodiment, as shown in fig. 4, the area meshing device for full service may further include a determining module 306, where:

a determining module 306, configured to determine whether there is a service requirement that needs to be adjusted in all service requirements before the determining module 301 determines a network construction scheme of a certain area within a predetermined planning period according to the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource, and the resource usage condition corresponding to each basic resource.

The determining module 301 is further configured to, when the determining module 306 determines that there is no service demand that needs to be adjusted in all the service demands, determine a network construction scheme of a certain area in a predetermined planning period according to the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource, and the resource usage corresponding to each basic resource.

It can be seen that the area grid dividing apparatus for full service described in fig. 4 can also determine whether all current service requirements have service requirements that need to be adjusted (modified) before determining the network resource construction scheme of the area, and if not, execute the network resource construction scheme of the subsequent area, so as to reduce the occurrence of the situation that the network resource scheme needs to be re-determined due to the fact that the service requirements do not need to be adjusted, and save the determination time of the network resource construction scheme.

In yet another alternative embodiment, as shown in fig. 4, the determining module 301 is further configured to, when the determining module 306 determines that there is a service demand that needs to be adjusted in all service demands, determine a resource adjustment condition of each service demand in a certain predetermined future time period based on predetermined network system data and/or a predetermined service record for each service demand, where the resource adjustment condition includes a resource occupation condition or a resource rollback condition.

In this optional embodiment, as an optional implementation manner, the manner that the determining module 301 determines, according to the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource, and the resource usage condition corresponding to each basic resource, the network construction scheme of a certain area in a predetermined planning period is specifically:

and determining a network construction scheme of a certain area in a predetermined planning period according to the resource adjustment condition of each service requirement, the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource and the resource use condition corresponding to each basic resource.

It can be seen that the area grid dividing apparatus for full service described in fig. 4 can also obtain the adjustment condition of the service requirement when it is determined that there is a service requirement that needs to be adjusted, and determine the network resource construction scheme according to the adjustment condition of the service requirement, so as to improve the accuracy and reliability of determining the network resource construction scheme, thereby further facilitating to fully improve the utilization rate of the network resource, satisfying the requirement of the user for the network resource, and improving the experience of the user.

In yet another alternative embodiment, as shown in fig. 4, the judging module 306 is further configured to judge whether a certain area meets a predetermined network construction scheme determining condition before the determining module 301 determines a plurality of service requirements of the certain area.

The determining module 301 is further configured to determine a plurality of service requirements of a certain area when the determining module 306 determines that the certain area meets the predetermined network construction scheme determining condition.

In this optional embodiment, as an optional implementation manner, the manner for the determining module 306 to determine whether a certain area meets the predetermined network construction scheme determination condition is specifically:

acquiring the population flow of a certain area, and judging whether the population flow is not in a predetermined population flow range;

and when the determined population flow is not in the predetermined population flow range, determining that a certain area meets the predetermined network construction scheme determination condition.

Therefore, in the alternative embodiment, the determination condition of the network construction scheme of the area can be judged by acquiring the population flow of the area and comparing the population flow with the determined population flow range. Alternatively, the first and second electrodes may be,

acquiring a current date, and judging whether the current date is a certain date in a predetermined date set;

and when the current date is judged to be a certain date in the predetermined date set, determining that a certain area meets the predetermined network construction scheme determination condition.

Therefore, in the alternative embodiment, by acquiring the current date of the area and comparing the current date with the determined date set, the judgment of the determination condition of the network construction scheme of the area can be realized.

It can be seen that the area meshing device for the full service described in fig. 4 can also determine whether the area meets the network construction scheme determination condition before determining the service requirement of the area, and when the area meets the network construction scheme determination condition, continue to execute the subsequent network construction scheme determination step, so as to reduce the occurrence of the situation that the area does not meet the network construction scheme determination condition but executes the subsequent network construction scheme determination operation, reduce the power consumption of the network device, and improve the service life of the network device; and whether the area meets the judgment of the network construction scheme determination condition is determined in various modes, so that the judgment that the area meets the network construction scheme determination condition can be intelligently determined, and the judgment flexibility of the network construction scheme determination condition can be improved.

In yet another alternative embodiment, as shown in fig. 4, the area meshing device for full service may further include a sending module 307, where:

a sending module 307, configured to send a network construction prompt to the network planning department after the determining module 301 determines the network construction scheme of a certain area within a predetermined planning period according to the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource, and the resource usage condition corresponding to each basic resource, where the network construction prompt includes the network construction scheme, and the network construction prompt is used to prompt a worker of the network planning department to plan the network resource of the certain area according to the network construction scheme.

It can be seen that the area grid partitioning device for the full service described in fig. 4 can further send the network construction prompt to the network planning department after determining the network construction scheme of the area, and can prompt a worker of the network planning department to plan the network resource layout of the area in time according to the network construction scheme, so that the planning efficiency of the network resources of the area is improved, the reasonable allocation rate of the network resources is further improved, and the utilization rate of the network resources is further improved.

Example four

Referring to fig. 5, fig. 5 is a schematic diagram illustrating another area meshing device for full service according to an embodiment of the present invention. As shown in fig. 5, the full service oriented area meshing device may include:

a memory 501 in which executable program code is stored;

a processor 502 coupled to a memory 501;

the processor 502 calls executable program code stored in the memory 501 for performing the steps in the full service oriented area meshing method described in embodiment one or embodiment two.

EXAMPLE five

The embodiment of the invention discloses a computer-readable storage medium which stores a computer program for electronic data exchange, wherein the computer program enables a computer to execute the steps in the area meshing method for full service described in the first embodiment or the second embodiment.

Example six

An embodiment of the present invention discloses a computer program product, which comprises a non-transitory computer-readable storage medium storing a computer program, and the computer program is operable to cause a computer to execute the steps in the full-service oriented area meshing method described in the first or second embodiment.

The above-described embodiments of the apparatus are merely illustrative, and the modules described as separate components may or may not be physically separate, and the components shown as modules may or may not be physical modules, may be located in one place, or may be distributed on a plurality of network modules. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of this embodiment. One of ordinary skill in the art can understand and implement it without inventive effort.

Through the above detailed description of the embodiments, those skilled in the art will clearly understand that the embodiments may be implemented by software plus a necessary general hardware platform, and may also be implemented by hardware. Based on such understanding, the above technical solutions may be embodied in the form of a software product, which may be stored in a computer-readable storage medium, where the storage medium includes a Read-Only Memory (ROM), a Random Access Memory (RAM), a Programmable Read-Only Memory (PROM), an Erasable Programmable Read-Only Memory (EPROM), a One-time Programmable Read-Only Memory (OTPROM), an Electrically Erasable Programmable Read-Only Memory (EEPROM), a Compact Disc-Read-Only Memory (CD-ROM), or other disk memories, CD-ROMs, or other magnetic disks, A tape memory, or any other medium readable by a computer that can be used to carry or store data.

Finally, it should be noted that: the area meshing method and apparatus for full service disclosed in the embodiments of the present invention are only the preferred embodiments of the present invention, and are only used to illustrate the technical solution of the present invention, not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art; the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (9)

1. A method for area meshing for full service, the method comprising:

determining a plurality of service requirements of a certain area, and determining a service parameter of each service requirement, wherein all the service requirements comprise at least one of 5G service requirements, 4G service requirements, 3G service requirements, 2G service requirements, home broadband service requirements and customer collecting service requirements;

calculating a target network resource requirement corresponding to each basic resource of the certain area based on each service requirement and a service parameter of the service requirement, wherein the basic resource comprises an optical communication resource, a communication equipment resource and an optical cable resource, and the target network resource requirement at least comprises the required quantity of each basic resource;

acquiring the current network resource requirement corresponding to each basic resource and the predetermined resource use condition corresponding to each basic resource in a certain area;

determining a network construction scheme of the certain area in a predetermined planning period according to a target network resource requirement corresponding to each basic resource, a current network resource requirement corresponding to each basic resource and a resource use condition corresponding to each basic resource;

the acquiring of the present network resource requirement corresponding to each of the basic resources includes:

and determining the current resource occupation condition corresponding to each basic resource, and calculating the residual resource condition of the basic resource based on the total resource condition of each basic resource and the current resource occupation condition of the basic resource to be used as the current network resource requirement corresponding to the basic resource.

2. The full-service oriented area meshing method according to claim 1, wherein the service parameters include fixed parameters and variable parameters;

the fixed parameters are parameters which cannot be changed after the certain area is set;

the variable parameter is a parameter which changes with the resource allocation strategy of the certain area;

and, said determining a service parameter for each of said service requirements comprises:

receiving a service parameter aiming at each service requirement sent by a management department, wherein the management department comprises at least one of an engineering construction department, a network maintenance department and a planning department; alternatively, the first and second electrodes may be,

and screening the service parameters of each service requirement from a pre-established network resource database.

3. The method according to claim 1 or 2, wherein before determining the network construction scheme of the certain area in a predetermined planning period according to the target network resource requirement corresponding to each of the basic resources, the current network resource requirement corresponding to each of the basic resources, and the resource usage situation corresponding to each of the basic resources, the method further comprises:

collecting regional information of the certain region, wherein the regional information comprises at least one of geographic area, population density and economic density;

inputting the region information into a predetermined region scene classification model, obtaining a classification result output by the region scene classification model as a grid region scene type of a certain region, and determining the distribution dense condition of each service requirement in the grid region scene type;

the determining a network construction scheme of the certain area within a predetermined planning period according to the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource, and the resource usage condition corresponding to each basic resource includes:

and determining a network construction scheme of the certain area in a predetermined planning period according to the distribution density condition of each service demand in the scene type of the grid area, the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource and the resource use condition corresponding to each basic resource.

4. The method for area meshing for full services according to claim 1 or 2, wherein before determining the network construction scheme of the certain area within a predetermined planning period according to the target network resource requirement corresponding to each of the basic resources, the current network resource requirement corresponding to each of the basic resources, and the resource usage corresponding to each of the basic resources, the method further comprises:

judging whether the business requirements needing to be adjusted exist in all the business requirements, and triggering and executing the operation of determining the network construction scheme of a certain area in a predetermined planning period according to the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource and the resource use condition corresponding to each basic resource when the business requirements needing to be adjusted do not exist in all the business requirements.

5. The full-service oriented region meshing method according to claim 4, further comprising:

when the service requirement needing to be adjusted exists in all the service requirements, determining a resource adjustment condition of each service requirement in a certain predetermined future time period based on predetermined network system data and/or predetermined service records aiming at each service requirement, wherein the resource adjustment condition comprises a resource occupation condition or a resource rollback condition;

the determining a network construction scheme of the certain area within a predetermined planning period according to the target network resource demand corresponding to each basic resource, the current network resource demand corresponding to each basic resource, and the resource usage condition corresponding to each basic resource includes:

and determining a network construction scheme of the certain area in a predetermined planning period according to the resource adjustment condition of each service requirement, the target network resource requirement corresponding to each basic resource, the current network resource requirement corresponding to each basic resource and the resource use condition corresponding to each basic resource.

6. The full-service oriented regional meshing method according to claim 1, 2 or 5, wherein the network construction scheme includes a communication equipment network construction scheme, an optical cable network construction scheme and an optical cross-connect network construction scheme;

the communication equipment network construction scheme comprises a PTN communication equipment network construction scheme, an OLT communication equipment network construction scheme and a BNG communication equipment network construction scheme;

the optical cable network construction scheme comprises a distribution optical cable network construction scheme and a trunk optical cable network construction scheme;

the optical traffic network construction scheme comprises a primary optical traffic network construction scheme and a secondary optical traffic network construction scheme.

7. An apparatus for full service oriented area meshing, the apparatus comprising:

the system comprises a determining module, a service processing module and a service processing module, wherein the determining module is used for determining a plurality of service requirements of a certain area, and all the service requirements comprise at least one of 5G service requirements, 4G service requirements, 3G service requirements, 2G service requirements, home broadband service requirements and customer service requirements;

the determining module is further configured to determine a service parameter of each service requirement;

a calculating module, configured to calculate, based on each service requirement and a service parameter of the service requirement, a target network resource requirement corresponding to each basic resource of the certain area, where the basic resource includes an optical communication resource, a communication device resource, and an optical cable resource, and the target network resource requirement at least includes a required quantity of each basic resource;

an obtaining module, configured to obtain a current network resource requirement corresponding to each basic resource and a resource usage condition of the certain area corresponding to each predetermined basic resource;

the determining module is further configured to determine a network construction scheme of the certain area within a predetermined planning period according to a target network resource demand corresponding to each of the basic resources, a current network resource demand corresponding to each of the basic resources, and a resource usage situation corresponding to each of the basic resources;

the manner for the obtaining module to obtain the present network resource requirement corresponding to each of the basic resources specifically includes:

and determining the current resource occupation condition corresponding to each basic resource, and calculating the residual resource condition of the basic resource based on the total resource condition of each basic resource and the current resource occupation condition of the basic resource to be used as the current network resource requirement corresponding to the basic resource.

8. An apparatus for full service oriented area meshing, the apparatus comprising:

a memory storing executable program code;

a processor coupled with the memory;

the processor calls the executable program code stored in the memory to perform the full service oriented area meshing method according to any one of claims 1 to 6.

9. A computer storage medium storing computer instructions for performing a full service oriented area meshing method according to any one of claims 1 to 6 when invoked by a processor.

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