CN112911428A - Rapid performance optimization method and device based on multi-wavelength path and electronic equipment - Google Patents
Rapid performance optimization method and device based on multi-wavelength path and electronic equipment Download PDFInfo
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Abstract
The invention discloses a rapid performance optimization method based on a multi-wavelength path, which comprises the following steps: traversing according to a plurality of wavelength paths selected by a user to realize model construction, and abstracting to be a light multiplexing section path sequence; associating the single wavelength with the corresponding optical multiplexing section path, and constructing an optical multiplexing section adjusting sequence and a dependency relation linked list based on the single wavelength path; integrating the adjustment sequence and the dependency relationship linked list of the optical multiplexing section based on the single wavelength path into a global optical multiplexing section adjustment relationship graph; selecting an optical multiplexing section without a dependence requirement from the global optical multiplexing section adjustment relation graph, and preferentially starting parallel adjustment; modifying the dependency relationship and the adjustment state of each optical multiplexing section according to the adjustment result; and substituting the global optical multiplexing section adjustment relation graph into the first two steps until all optical multiplexing sections in the global optical multiplexing section adjustment relation graph are adjusted and have no dependency relation. The invention also provides a corresponding multi-wavelength path-based rapid performance optimization device and electronic equipment.
Description
Technical Field
The invention belongs to the technical field of optical communication, and particularly relates to a method and a device for optimizing rapid performance based on a multi-wavelength path and electronic equipment.
Background
With the vigorous development of broadband infrastructure at home and abroad, the corresponding network scale is continuously increased, and the network scale is from the first dozens of sites to hundreds of sites, and meanwhile, the maintenance difficulty of the network is correspondingly increased by the introduced new technology under the drive of continuously improving the service quality and the network performance appeal.
In an optical transmission network, attenuation indexes of cables among stations and flatness indexes of power in a wavelength division system are key factors for measuring network quality, and the original passive manual network optimization maintenance mode cannot meet the increasing network complexity and the requirement of a client on quick telecommunication service opening, and the requirement of the client on quick and intelligent operation and maintenance of the network is more urgent.
Disclosure of Invention
Aiming at the problem that the existing adjustment mode for single-wavelength path serial performance optimization consumes time, the invention aims to provide an adjustment scheme for rapid performance optimization based on a multi-wavelength path, and the problem that the multi-wavelength path consumes long time for performance optimization is solved by analyzing a multi-wavelength path model, aggregating an optical multiplexing section model and comprehensively controlling the performance optimization sequence of each device.
To achieve the above object, according to an aspect of the present invention, there is provided a method for fast performance optimization based on a multi-wavelength path, the method including:
s1, traversing according to a plurality of wavelength paths selected by a user to realize model construction, and abstracting to be a light multiplexing section path sequence;
s2, associating the single wavelength with the corresponding optical multiplexing section path, and constructing an optical multiplexing section adjusting sequence and a dependency relation linked list based on the single wavelength path;
s3, integrating the single wavelength path-based optical multiplexing segment adjustment sequence and the dependency relationship linked list into a global optical multiplexing segment adjustment relationship graph;
s4, selecting an optical multiplexing section without a dependence requirement from the global optical multiplexing section adjustment relation graph, and preferentially starting parallel adjustment;
s5, according to the adjustment result of the step S4, the dependency relationship and the adjustment state of each optical multiplexing section are modified, so as to update the global optical multiplexing section adjustment relationship graph;
and S6, substituting the global multiplexing segment adjustment relation graph into the step S4 and the step S5 until all the multiplexing segments in the global multiplexing segment adjustment relation graph are adjusted and have no dependency relationship.
In one embodiment of the present invention, in the optical multiplexing segment path sequence in step S1:
each wavelength path is made up of one or more optical multiplexing sections, each of which may traverse multiple wavelength paths.
In an embodiment of the present invention, associating a single wavelength with a corresponding optical multiplexing segment path in the step S2 includes:
for a single wavelength, traversing a set of ordered optical multiplexing segment paths; for a single optical multiplexing section, one wavelength information and the dependency of each optical multiplexing section on the wavelength path are associated.
In an embodiment of the present invention, the step S3 includes: for a single optical multiplexing section, a set of wavelength information and dependent individual optical multiplexing section information are associated, and one optical multiplexing section may depend on a plurality of optical multiplexing sections, or may be depended on by a plurality of optical multiplexing sections.
In an embodiment of the present invention, the step S4 includes: the unit of adjustment is an optical multiplexing section, and optical power adjustment is performed for the associated wavelength in the optical multiplexing section.
In an embodiment of the present invention, the step S5 includes: and after the adjustment of the single optical multiplexing section is finished, modifying the adjustment state of the current optical multiplexing section, and removing the dependency relationship from all the dependency relationships depending on the optical multiplexing section.
According to another aspect of the present invention, there is also provided a fast performance optimization apparatus based on a multi-wavelength path, including an optical multiplexing segment path sequence construction module, a single-wavelength optical multiplexing segment relation linked list construction module, a global optical multiplexing segment adjustment relation graph construction module, an optical multiplexing segment adjustment module, a global optical multiplexing segment adjustment relation graph update module, and an iteration adjustment module, wherein:
the optical multiplexing section path sequence construction module is used for traversing according to a plurality of wavelength paths selected by a user to realize model construction and abstracting to an optical multiplexing section path sequence;
the single-wavelength optical multiplexing section relation linked list construction module is used for associating a single wavelength with a corresponding optical multiplexing section path and constructing an optical multiplexing section adjusting sequence and a dependency linked list based on the single wavelength;
the global optical multiplexing section adjusting relationship diagram building module is used for integrating the single-wavelength path optical multiplexing section adjusting sequence and the dependency relationship table built by the single-wavelength optical multiplexing section relationship linked list building module into a global optical multiplexing section adjusting relationship diagram;
the optical multiplexing section adjusting module is used for selecting an optical multiplexing section without a dependence requirement from a global optical multiplexing section adjusting relation graph and preferentially starting parallel adjustment;
the global optical multiplexing section adjustment relation graph updating module is used for modifying the dependency relation and the adjustment state of each optical multiplexing section according to the adjustment result obtained by the optical multiplexing section adjustment module so as to update the global optical multiplexing section adjustment relation graph constructed by the global optical multiplexing section adjustment relation graph construction module;
the iteration adjusting module is used for substituting the global optical multiplexing section adjusting relationship graph updated by the global optical multiplexing section adjusting relationship graph updating module into the optical multiplexing section adjusting module and the global optical multiplexing section adjusting relationship graph updating module until all the optical multiplexing sections in the global optical multiplexing section adjusting relationship graph are adjusted and have no dependency relationship.
In one embodiment of the invention, in the sequence of optical multiplex section paths: each wavelength path is composed of one or more optical multiplexing sections, and each optical multiplexing section can pass through a plurality of wavelength paths;
associating a single wavelength with a corresponding optical multiplex section path, comprising: for a single wavelength, traversing a set of ordered optical multiplexing segment paths; for a single optical multiplexing section, one wavelength information and the dependency of each optical multiplexing section on the wavelength path are associated.
In an embodiment of the present invention, the optical multiplexing section adjusting module is configured to associate a set of wavelength information and each piece of dependent optical multiplexing section information with respect to a single optical multiplexing section, where one optical multiplexing section may depend on a plurality of optical multiplexing sections, and may also be depended on by a plurality of optical multiplexing sections.
According to another aspect of the present invention, there is also provided an electronic apparatus including:
at least one processor; and the number of the first and second groups,
a memory communicatively coupled to the at least one processor; wherein,
the memory stores instructions executable by the at least one processor to enable the at least one processor to perform the multi-wavelength path based fast performance optimization method described above.
Generally, compared with the prior art, the technical scheme of the invention has the following beneficial effects:
the invention provides a rapid performance optimization method based on a multi-wavelength path, which is characterized in that on the basis of the existing OTN transmission network, the current network operation state is analyzed by loading network data, network problems are found in advance, the multi-wavelength path automatic optimization is provided, operators can be effectively helped to reduce the operation and maintenance labor input, the network state analysis and maintenance time is shortened, and the operation and maintenance efficiency is improved; the competitiveness of equipment supplier enterprise products is enhanced, and the user satisfaction is improved.
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FIG. 1 is a schematic flow chart of a multi-wavelength path-based fast performance optimization method according to the present invention;
FIG. 2 is a schematic diagram of a multi-wavelength path networking in an embodiment of the invention;
FIG. 3 is a diagram illustrating a relationship between a single wavelength path class diagram and an optical multiplexing section class diagram according to an embodiment of the present invention;
FIG. 4 is a schematic diagram of a multi-wavelength path fast performance optimization process according to an embodiment of the present invention;
fig. 5 is a schematic structural diagram of a multi-wavelength path-based fast performance optimization apparatus according to an embodiment of the present invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention. In addition, the technical features involved in the embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.
When the performance of the multi-wavelength path is optimized in the existing network management system, the performance optimization of each optical device in the single-wavelength path must be completed based on the upstream device, so that the performance optimization of the optical devices in the single-wavelength path must be optimized and adjusted according to the sequence of the path. However, the multi-wavelength paths may have a common path, a single sweep device in the same path cannot execute multiple commands simultaneously, and the parallel optimization adjustment also has a problem of mutual interference, so that the parallel optimization adjustment cannot be directly performed according to the wavelength paths. Currently, a single wavelength path serial mode is adopted for performance optimization. However, the serial mode may prolong the time of the whole performance optimization process, which may cause the failed wavelength path to be unable to be repaired quickly, thereby affecting the user experience.
As shown in fig. 1, the present invention provides a method for fast performance optimization based on multi-wavelength path, which includes:
s1, traversing according to a plurality of wavelength paths selected by a user to realize model construction, and abstracting to be a light multiplexing section path sequence;
specifically, in the optical multiplex section path sequence: each wavelength path is composed of one or more optical multiplexing sections, and each optical multiplexing section can pass through a plurality of wavelength paths;
s2, associating the single wavelength with the corresponding optical multiplexing section path, and constructing an optical multiplexing section adjusting sequence and a dependency relation linked list based on the single wavelength;
associating a single wavelength with a corresponding optical multiplex section path, comprising: for a single wavelength, traversing a set of ordered optical multiplexing segment paths; for a single optical multiplexing section, associating one wavelength information and the dependency relationship of each optical multiplexing section on the wavelength path;
the multi-wavelength path networking diagram in this step is shown in fig. 2. There are 3 wavelength paths in the figure, each wavelength path passing through multiple network elements. A segment of optical multiplexing segment path is formed between two adjacent network elements, and each optical multiplexing segment path can bear a plurality of wavelength paths.
The single wavelength path class diagram constructed in this step is shown in fig. 3, and the single wavelength path contains the wavelength information of the wavelength path and the path information of all the optical multiplexing sections that have passed through. For example, in fig. 2, a wavelength path 1 includes wavelength information λ 1, and 5 optical multiplexing segment paths (network element 1 — network element 4, network element 4 — network element 6, network element 6 — network element 7, network element 7 — network element 8, and network element 8 — network element 10);
the dependency chain table refers to a data structure, such as an array or a queue, and is not limited herein.
S3, integrating the single wavelength path optical multiplexing section adjusting sequence and the dependency relationship table constructed in the step S2 into a global optical multiplexing section adjusting relationship diagram;
the optical multiplexing segment class diagram constructed in the above step is shown in fig. 3, and each optical multiplexing segment path includes all the carried wavelength information, for example, the optical multiplexing segment 2 in fig. 2 carries three wavelength data λ 1, λ 2, λ 3; each optical multiplexing segment path contains information of a dependent optical multiplexing segment, for example, in fig. 2, an optical multiplexing segment 2 (network element 4-network element 6) depends on information of three preceding optical multiplexing segments (network element 1-network element 4, network element 2-network element 4, and network element 5-network element 4); each optical multiplex section path contains the current adjustment state.
S4, selecting an optical multiplexing section without a dependence requirement from the global optical multiplexing section adjustment relation graph, and preferentially starting parallel adjustment;
s5, according to the adjustment result in the step S4, modifying the dependency relationship and the adjustment state of each optical multiplexing section so as to update the global optical multiplexing section adjustment relationship diagram constructed in the step S3;
and S6, substituting the global multiplexing segment adjustment relation graph updated in the step S5 for executing the step S4 and the step S5 until all the multiplexing segments in the global multiplexing segment adjustment relation graph are adjusted and have no dependency relationship.
After step S5, some objects that need to depend on other multiplexing segments are updated to be independent, and the independent objects are continuously selected for starting and adjusting when the operations are executed in a recycling manner S4.
The method for optimizing the rapid performance of a multi-wavelength path according to the present invention is described below with reference to a specific embodiment, a schematic flow chart is shown in fig. 4, and the specific implementation flow includes the following steps:
s601, acquiring a waveChannelList needing to be adjusted, traversing the list, and generating a global optical multiplexing segment data list GlobalOmsInfoList after all traversal is completed;
s602, judging whether all wavelength paths in the WavecChannelList are analyzed, if so, executing S606, otherwise, executing S603;
s603, a wavelength path is taken, the wavelength information WaveInfo of the wavelength path is obtained, the optical multiplexing section list OmsInfoList corresponding to the wavelength path is obtained, the list is traversed, and the generated data are placed into the Global OmsInfoList.
S604, judging whether the analysis of the multiplex section in the OmsInfoList is finished, if so, executing S602, otherwise, executing S605;
s605, generating optical multiplexing segment data OmsInfo, recording corresponding wavelength information WaveInfo, setting the adjustment state to be unadjusted, taking an optical multiplexing segment Oms [ i-1] before the optical multiplexing segment Oms [ i ] in the OmsInfoList as a dependent optical multiplexing segment, and if the current segment is a first segment optical multiplexing segment, having no dependent information; after the execution is finished, S604 is continuously executed for traversing; adding the generated optical multiplexing segment data OmsInfo into a global optical multiplexing segment data list Globalal OmsInfoList;
s606, generating a global optical multiplexing segment data list GlobalOmsInfoList, and traversing the list to adjust the optical multiplexing segment;
s607, judging whether the GlobalmsInfoList is empty, if so, indicating that the adjustment is successful, ending the process, otherwise, executing the step S608;
s608, acquiring all unadjusted optical multiplexing segment data lists PreAdjustmInfoList without dependency information in the lists;
s609, judging whether the PreAdjussOmsInfoList is empty or not, if the list is empty, indicating that the adjustment is not successful, and ending the process; if not, executing S610;
s610, according to the adjustable optical multiplexing segment data obtained in the step S609, starting multithreading to analyze and adjust the optical multiplexing segment in the PreAdjust OmsInfoList list;
s611, judging whether the adjustment result of the single optical multiplexing section is successful, if so, executing S612, otherwise, executing S614;
s612, removing the optical multiplexing section which is successfully adjusted from the global optical multiplexing section list;
s613, updating the adjustment state of the successfully adjusted optical multiplexing segment into adjusted state, searching an object depending on the optical multiplexing segment from the global optical multiplexing segment list, and removing the optical multiplexing segment from the dependency relationship; continuing to execute S607;
s614, updating the adjustment state of the optical multiplexing section with failed adjustment into failed adjustment; execution continues with S607.
Further, as shown in fig. 5, the present invention provides a fast performance optimization device based on a multi-wavelength path, which includes an optical multiplexing segment path sequence construction module, a single-wavelength optical multiplexing segment relation linked list construction module, a global optical multiplexing segment adjustment relation graph construction module, an optical multiplexing segment adjustment module, a global optical multiplexing segment adjustment relation graph update module, and an iteration adjustment module, wherein:
the optical multiplexing section path sequence construction module is used for traversing according to a plurality of wavelength paths selected by a user to realize model construction and abstracting to an optical multiplexing section path sequence;
the single-wavelength optical multiplexing section relation linked list construction module is used for associating a single wavelength with a corresponding optical multiplexing section path and constructing an optical multiplexing section adjusting sequence and a dependency linked list based on the single wavelength;
the global optical multiplexing section adjusting relationship diagram building module is used for integrating the single-wavelength path optical multiplexing section adjusting sequence and the dependency relationship table built by the single-wavelength optical multiplexing section relationship linked list building module into a global optical multiplexing section adjusting relationship diagram;
the optical multiplexing section adjusting module is used for selecting an optical multiplexing section without a dependence requirement from a global optical multiplexing section adjusting relation graph and preferentially starting parallel adjustment;
the global optical multiplexing section adjustment relation graph updating module is used for modifying the dependency relation and the adjustment state of each optical multiplexing section according to the adjustment result obtained by the optical multiplexing section adjustment module so as to update the global optical multiplexing section adjustment relation graph constructed by the global optical multiplexing section adjustment relation graph construction module;
the iteration adjusting module is used for substituting the global optical multiplexing section adjusting relationship graph updated by the global optical multiplexing section adjusting relationship graph updating module into the optical multiplexing section adjusting module and the global optical multiplexing section adjusting relationship graph updating module until all the optical multiplexing sections in the global optical multiplexing section adjusting relationship graph are adjusted and have no dependency relationship.
Further, the present invention also provides an electronic device, comprising:
at least one processor; and the number of the first and second groups,
a memory communicatively coupled to the at least one processor; wherein,
the memory stores instructions executable by the at least one processor to enable the at least one processor to perform the multi-wavelength path based fast performance optimization method described above.
It will be understood by those skilled in the art that the foregoing is only a preferred embodiment of the present invention, and is not intended to limit the invention, and that any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the present invention.
Claims (10)
1. A method for fast performance optimization based on multi-wavelength paths, the method comprising:
s1, traversing according to a plurality of wavelength paths selected by a user to realize model construction, and abstracting to be a light multiplexing section path sequence;
s2, associating the single wavelength with the corresponding optical multiplexing section path, and constructing an optical multiplexing section adjusting sequence and a dependency relation linked list based on the single wavelength path;
s3, integrating the single wavelength path-based optical multiplexing segment adjustment sequence and the dependency relationship linked list into a global optical multiplexing segment adjustment relationship graph;
s4, selecting an optical multiplexing section without a dependence requirement from the global optical multiplexing section adjustment relation graph, and preferentially starting parallel adjustment;
s5, according to the adjustment result of the step S4, the dependency relationship and the adjustment state of each optical multiplexing section are modified, so as to update the global optical multiplexing section adjustment relationship graph;
and S6, substituting the global multiplexing segment adjustment relation graph into the step S4 and the step S5 until all the multiplexing segments in the global multiplexing segment adjustment relation graph are adjusted and have no dependency relationship.
2. The multi-wavelength path-based fast performance optimization method according to claim 1, wherein in the sequence of optical multiplex section paths in the step S1:
each wavelength path is made up of one or more optical multiplexing sections, each of which may traverse multiple wavelength paths.
3. The multi-wavelength path-based fast performance optimization method according to claim 1 or 2, wherein associating a single wavelength with a corresponding optical multiplexing segment path in the step S2 comprises:
for a single wavelength, traversing a set of ordered optical multiplexing segment paths; for a single optical multiplexing section, one wavelength information and the dependency of each optical multiplexing section on the wavelength path are associated.
4. The multiwavelength path-based fast performance optimization method of claim 1 or 2, wherein the step S3 comprises:
for a single optical multiplexing section, a set of wavelength information and dependent individual optical multiplexing section information are associated, and one optical multiplexing section may depend on a plurality of optical multiplexing sections, or may be depended on by a plurality of optical multiplexing sections.
5. The multiwavelength path-based fast performance optimization method of claim 1 or 2, wherein the step S4 comprises: the unit of adjustment is an optical multiplexing section, and optical power adjustment is performed for the associated wavelength in the optical multiplexing section.
6. The multiwavelength path-based fast performance optimization method of claim 1 or 2, wherein the step S5 comprises: and after the adjustment of the single optical multiplexing section is finished, modifying the adjustment state of the current optical multiplexing section, and removing the dependency relationship from all the dependency relationships depending on the optical multiplexing section.
7. A rapid performance optimization device based on a multi-wavelength path is characterized by comprising an optical multiplexing section path sequence building module, a single-wavelength optical multiplexing section relation chain table building module, a global optical multiplexing section adjusting relation graph building module, an optical multiplexing section adjusting module, a global optical multiplexing section adjusting relation graph updating module and an iteration adjusting module, wherein:
the optical multiplexing section path sequence construction module is used for traversing according to a plurality of wavelength paths selected by a user to realize model construction and abstracting to an optical multiplexing section path sequence;
the single-wavelength optical multiplexing section relation linked list construction module is used for associating a single wavelength with a corresponding optical multiplexing section path and constructing an optical multiplexing section adjusting sequence and a dependency linked list based on the single wavelength;
the global optical multiplexing section adjusting relationship diagram building module is used for integrating the single-wavelength path optical multiplexing section adjusting sequence and the dependency relationship table built by the single-wavelength optical multiplexing section relationship linked list building module into a global optical multiplexing section adjusting relationship diagram;
the optical multiplexing section adjusting module is used for selecting an optical multiplexing section without a dependence requirement from a global optical multiplexing section adjusting relation graph and preferentially starting parallel adjustment;
the global optical multiplexing section adjustment relation graph updating module is used for modifying the dependency relation and the adjustment state of each optical multiplexing section according to the adjustment result obtained by the optical multiplexing section adjustment module so as to update the global optical multiplexing section adjustment relation graph constructed by the global optical multiplexing section adjustment relation graph construction module;
the iteration adjusting module is used for substituting the global optical multiplexing section adjusting relationship graph updated by the global optical multiplexing section adjusting relationship graph updating module into the optical multiplexing section adjusting module and the global optical multiplexing section adjusting relationship graph updating module until all the optical multiplexing sections in the global optical multiplexing section adjusting relationship graph are adjusted and have no dependency relationship.
8. The multi-wavelength path-based fast performance optimization apparatus of claim 7,
in the optical multiplex section path sequence: each wavelength path is composed of one or more optical multiplexing sections, and each optical multiplexing section can pass through a plurality of wavelength paths;
associating a single wavelength with a corresponding optical multiplex section path, comprising: for a single wavelength, traversing a set of ordered optical multiplexing segment paths; for a single optical multiplexing section, one wavelength information and the dependency of each optical multiplexing section on the wavelength path are associated.
9. The apparatus for fast performance optimization based on multiple wavelength paths according to claim 8, wherein the optical multiplexing segment adjusting module is configured to associate a set of wavelength information and each dependent optical multiplexing segment information for a single optical multiplexing segment, and a single optical multiplexing segment may depend on or may be depended on multiple optical multiplexing segments.
10. An electronic device, comprising:
at least one processor; and the number of the first and second groups,
a memory communicatively coupled to the at least one processor; wherein,
the memory stores instructions executable by the at least one processor to enable the at least one processor to perform the method for multi-wavelength path based fast performance optimization of any one of claims 1-6.
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