CN118803952B - Communication resource scheduling method and system for wireless communication network - Google Patents

Abstract

The invention discloses a communication resource scheduling method and a system for a wireless communication network, which relate to the technical field of wireless communication networks and comprise a control center, wherein the control center is connected with a communication acquisition module, an information processing module, a resource analysis module and an intelligent regulation module; collecting communication resource data through a communication collecting module; performing information conversion and performance capture on the communication resource data in an information processing module to obtain discrete resource coefficients; generating a resource variation diagram in a resource analysis module, and carrying out preset use on the communication subelement according to the resource variation diagram to obtain preset allocation resource data; the intelligent regulation and control module monitors the consumption of the communication subelement and judges the threshold value to obtain surplus preset resources, and the resource surplus adjustment is carried out on the deficiency subelement according to the surplus preset resources to obtain the traffic subelement; the dynamic scheduling of communication resources is realized, the adaptability of a communication system is enhanced, the communication requirements under different scenes are met, and the user experience is improved.

Description

Communication resource scheduling method and system for wireless communication network

Technical Field

The invention relates to the technical field of wireless communication networks, in particular to a communication resource scheduling method and a communication resource scheduling system for a wireless communication network.

Background

A wireless communication network refers to a network that realizes communication by propagation of electromagnetic waves in space, which does not require physical connection, but realizes data transmission by propagation of electromagnetic waves in air or vacuum.

Communication resource scheduling refers to the process of reasonably allocating and scheduling network resources in a communication system to optimize system performance and improve resource utilization. In a wireless communication network, reasonable scheduling of communication resources is critical to guaranteeing user communication quality and improving network resource utilization. The existing communication resource scheduling method is often based on fixed priority allocation, and cannot adapt to dynamically-changed network environments and user demands.

Along with the continuous expansion of the scale of the communication network, the number of users increases dramatically, how to effectively schedule communication resources, and improve the performance and efficiency of the communication system, which is a current problem to be solved urgently; therefore, there is a need for a communication resource scheduling method with dynamic priority adjustment to achieve efficient and intelligent resource management, and a communication resource scheduling method and system for a wireless communication network are now provided.

Disclosure of Invention

The invention aims to provide a communication resource scheduling method and a system for a wireless communication network.

The aim of the invention can be achieved by the following technical scheme:

The communication resource scheduling system for the wireless communication network comprises a control center, wherein the control center is connected with a communication acquisition module, an information processing module, a resource analysis module and an intelligent regulation and control module;

the process of the communication acquisition module for acquiring the communication resource data comprises the following steps:

Acquiring, arranging and controlling a wireless communication network to obtain a wireless network space, and carrying out matching marking on the wireless communication network in the wireless network space to obtain a communication sub-element;

And setting a wireless acquisition end according to the communication sub-element, and acquiring data of a communication network through the wireless acquisition end to obtain communication resource data.

The process of obtaining the conversion stage number comprises the following steps:

information conversion is carried out on the communication resource data to obtain a resource use signal, and characteristic extraction is carried out on the resource use signal to obtain signal characteristics;

setting a middle section frequency filtering coefficient, and carrying out section transformation on the middle section frequency filtering coefficient to obtain transformation parameters;

Carrying out section statistics on the middle section frequency filtering coefficient according to the conversion parameter to obtain a section interval;

and carrying out series judgment on the middle section frequency filtering coefficient according to the signal characteristics, the conversion parameters and the section intervals to obtain a conversion series.

The process of obtaining discrete resource coefficients includes:

intercepting the middle section frequency filtering coefficient by converting the series to obtain a segmented frequency filtering coefficient;

Uploading the segmented frequency-filtering coefficient to a resource using signal, and capturing the performance of the resource using signal through the segmented frequency-filtering coefficient to obtain a discrete resource coefficient.

The process of obtaining the standard resource code matrix comprises the following steps:

performing code element conversion on the obtained discrete resource data to obtain a discrete resource code element stream, and performing distribution combination on the discrete resource code element stream to obtain a standard resource code matrix;

and constructing an element resource library according to the obtained standard resource code matrix, and associating the obtained element resource library with a corresponding communication sub-element.

The process of obtaining pre-allocated resource data includes:

generating a resource variation graph according to the discrete resource coefficients, and performing curve marking on the obtained resource variation graph to obtain resource coefficient spectral lines;

Setting a monitoring period according to the obtained resource variation graph, and collecting the resource coefficient spectral lines periodically based on the monitoring period to obtain a periodic consumption coefficient;

Carrying out resource pre-adjustment on the communication sub-element according to the periodic consumption coefficient to obtain the expected resource quantity of the element;

and carrying out pre-adjustment on the communication subelement according to the expected resource quantity of the element, and carrying out monitoring and acquisition on the pre-adjustment communication subelement through a wireless acquisition terminal to obtain pre-adjustment allocation resource data.

The process of obtaining the pre-adjusted usage degree comprises the following steps:

performing homologous conversion on the pre-allocated resource data to obtain discrete pre-allocated coefficients, and performing secondary conversion on the discrete pre-allocated coefficients to obtain pre-allocated code segments;

monitoring the consumption of the communication sub-element according to the element resource library to obtain a matched element resource;

carrying out state discrimination on the monitoring matching codes to obtain matching element codes and unused element codes;

And carrying out distribution and investigation on the communication sub-elements according to the matched element codes and the unused element codes to obtain the preset usage degree.

The process of obtaining the pass sub-element includes:

Critical judgment is carried out on the preset usage degree, and a defect quantum element is obtained;

setting a use threshold according to the preset use schedule, and judging the preset use schedule by using the threshold to obtain qualified preset resources and surplus preset resources;

Obtaining an activity adjustable resource according to the obtained surplus preset resource;

and carrying out resource surplus allocation and resource supplementation on the ullage subelement through the control center to obtain the traffic subelement.

Based on the above communication resource scheduling system for the wireless communication network, the invention also provides a communication resource scheduling method for the wireless communication network, comprising the following steps:

Step one: collecting communication resource data;

Step two: performing information conversion on communication resource data to obtain a resource use signal, performing section conversion and series judgment on the set middle section frequency-filtering coefficient to obtain a conversion series, performing series interception on the middle section frequency-filtering coefficient according to the conversion series to obtain a segmented frequency-filtering coefficient, and performing performance capture on the resource use signal through the segmented frequency-filtering coefficient to obtain a discrete resource coefficient;

Step three: performing code element conversion and distribution combination on discrete resource data to obtain a standard resource code matrix, constructing an element resource library according to the standard resource code matrix, generating a resource variation graph according to discrete resource coefficients, periodically collecting the resource variation graph to obtain periodic consumption coefficients, performing resource pre-adjustment on communication sub-elements through the periodic consumption coefficients to obtain element expected resource quantity, and performing pre-adjustment on the communication sub-elements according to the element expected resource quantity to obtain pre-adjustment distribution resource data;

Step four: performing homologous conversion and secondary conversion on the pre-allocated resource data to obtain a pre-allocated code segment, monitoring the consumption of the communication subelement according to an element resource library to obtain matched element resources, performing allocation and investigation on the monitored matched codes to obtain pre-allocated usage, setting a usage threshold according to the pre-allocated usage, performing threshold judgment on the pre-allocated usage by using the threshold to obtain surplus pre-allocated resources, and performing resource surplus mobilization on the ullage subelement according to the surplus pre-allocated resources to obtain the traffic subelement.

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

Performing data conversion on the acquired communication resource data to generate a resource variation diagram, and performing preset use on the communication sub-element according to the resource variation diagram to obtain preset allocation resource data; the acquired resource data in different formats is converted into a dynamic graph, so that the resource use condition of the communication element is obtained, and the fine management of the resource is realized;

the method comprises the steps of monitoring the consumption of a communication sub-element and judging a threshold value to obtain surplus preset resources, and performing resource surplus mobilization on the shortage sub-element according to the surplus preset resources to obtain the traffic sub-element; the dynamic scheduling of communication resources is realized, the resource utilization rate of the communication system is improved, the communication delay is reduced, and the adaptability of the communication system is enhanced.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic diagram of the present invention.

Detailed Description

The technical solutions of the present invention will be clearly and completely described in connection with the embodiments, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1, a communication resource scheduling system for a wireless communication network comprises a control center, wherein the control center is connected with a communication acquisition module, an information processing module, a resource analysis module and an intelligent regulation module;

the communication acquisition module is used for acquiring communication resource data, and the specific process comprises the following steps:

Acquiring, arranging and controlling a wireless communication network to obtain a wireless network space, and carrying out matching marking on the wireless communication network in the wireless network space to obtain a communication sub-element;

Further, the collection and control means to collect and check components and subsystems in the wireless communication network, and virtually convert the internal components into a wireless communication network layout in a virtual space, namely a wireless network space; the communication sub-element is a virtual element formed according to one-to-one correspondence between components and subsystems in the wireless communication network, for example, user equipment, a base station, a transmission network, a wireless controller and the like in the wireless communication network, and the communication sub-element is generated according to the user equipment, the base station, the transmission network, the wireless controller and the like in the wireless communication network; in particular, the linking mode in the wireless network space is identical to that of a real wireless communication network;

Setting a wireless acquisition end according to the communication sub-element, and uploading the set wireless acquisition end to a wireless network space to obtain a wireless collection point;

further, the wireless acquisition end is used for acquiring resource data used by each component of the wireless communication network, so that the setting position of the corresponding wireless collection point can acquire the resource data of the corresponding communication subelement;

The wireless acquisition terminal acquires data of the communication network to obtain communication resource data;

it should be further noted that, in the implementation process, the communication resource data includes a radio spectrum resource, a base station resource, a user equipment resource, a network channel resource, and a network capacity resource;

the obtained communication resource data is associated with the corresponding wireless aggregation point.

The information processing module is used for carrying out information conversion and performance capture on the communication resource data to obtain discrete resource coefficients, and the specific process comprises the following steps:

Performing information conversion on the obtained communication resource data to obtain a resource use signal;

Further, the information conversion means converting the communication resource data into a signal form; in particular, according to the radio spectrum resources, the base station resources, the user equipment resources, the network channel resources and the network capacity resources included in the communication resource data, the resource usage signals include radio spectrum signals, base station signals, user equipment signals, network channel signals and network capacity signals;

Extracting characteristics of the obtained resource using signals to obtain signal characteristics;

The characteristic extraction means extracting signal characteristics of the resource usage signal to obtain signal characteristics, wherein the signal characteristics comprise signal period and duration;

setting a middle section filter frequency coefficient;

The representation form of the middle section frequency filtering coefficient is in a functional form and is set on the basis of a wavelet basis function, wherein the wavelet basis function comprises a Haar wavelet, a Morlet wavelet and a Daubechies wavelet;

Performing section transformation on the obtained middle section frequency filtering coefficient to obtain transformation parameters, wherein the transformation parameters comprise scale parameters and translation parameters, the obtained scale parameters are marked as a, and the frequency shift parameters are marked as b;

The section transformation representation controls the middle section frequency-filtering coefficient to stretch and translate in the time dimension and the frequency dimension, marks the stretch distance of the middle section frequency-filtering coefficient in the time dimension as a scale parameter, and marks the translation distance of the middle section frequency-filtering coefficient in the frequency dimension as a translation parameter;

Carrying out section statistics on the middle section frequency filtering coefficient according to the conversion parameter to obtain a section interval;

the section statistics is carried out on the interval between two adjacent conversion parameters in the middle section frequency filtering coefficient to obtain a section interval;

performing series judgment on the middle section frequency filtering coefficient according to the obtained signal characteristics, conversion parameters and section intervals to obtain a conversion series, marking the obtained conversion series as ZH, wherein, M represents the signal length of the resource usage signal,Representing the interval of the segments, e representing the number of intervals of the segments,Representing signal periods in signal characteristics, said ""Means calculated outAnd (3) rounding downwards after the result of the step (a);

Performing series interception on the middle section frequency-filtering coefficient according to the obtained conversion series to obtain a segmented frequency-filtering coefficient;

Further, the series interception represents equal interception of the middle section filter frequency coefficient according to the number of conversion series, and the equal section filter frequency coefficient is obtained;

uploading the obtained segmented frequency-filtering coefficient to a resource using signal, and capturing the performance of the resource using signal through the segmented frequency-filtering coefficient to obtain a discrete resource coefficient;

It should be further noted that, in the specific implementation process, the performance capturing means uploading the obtained segment filter frequency coefficient to the resource using signal according to the order of series interception, and convolving the segment filter frequency coefficient with the corresponding position of the resource using signal to obtain the discrete resource coefficient;

further, according to the radio spectrum signal, the base station signal, the user equipment signal, the network channel signal and the network capacity signal included in the resource usage signal, the resource discrete coefficient includes a radio spectrum coefficient, a base station coefficient, a user equipment coefficient, a network channel coefficient and a network capacity coefficient.

The resource analysis module is used for generating a resource variation diagram, and pre-adjusting the communication subelement according to the resource variation diagram to obtain pre-adjusting allocation resource data, and the specific process comprises the following steps:

Performing code element conversion on the obtained discrete resource data to obtain a discrete resource code element stream;

Further, the symbol conversion means converting the discrete resource data into a data stream composed of binary symbols at random, namely a discrete resource symbol stream;

carrying out distribution combination on the discrete resource code element streams to obtain a standard resource code matrix;

It should be further noted that, in the implementation process, the process of allocating the combination includes:

carrying out stream segment grouping on the obtained discrete resource code element stream to obtain a resource code stream segment;

the stream segment grouping means grouping according to 7 binary code elements in a discrete resource code element stream to obtain a resource code stream segment, and if the last group is less than 7 binary code elements, performing forward complement until 7 binary code elements are met;

performing block combination on the obtained resource code stream segments to obtain a resource code matrix, and marking the obtained resource code matrix as D;

The resource code matrix representation takes three resource code stream segments as a group according to the sequence of stream segment grouping to form a resource code matrix, and if the last group is less than three resource code stream segments, the resource code matrix representation is supplemented forward until the three resource code stream segments are satisfied;

Performing intra-group variation on the obtained resource code matrix to obtain a standard resource code matrix;

The intra-group variation indicates that the first four columns of binary symbols are marked as communication codes in a resource code matrix, the last three columns of binary symbols are marked as identity codes, a matrix formed by the communication codes of the first three rows and the fourth columns in the resource code matrix is marked as a communication code group, and a matrix formed by the identity codes of the last three rows and the third columns in the resource code matrix is marked as an identity code group;

the communication code group is marked as P, the identity code group is marked as Q, and the resource code matrix is expressed as D= [ P ¦ Q ];

adding a row module 2 in the resource code matrix until the identity code group becomes an identity matrix, recording the communication code group at the same time, forming a standard resource code matrix together, and marking the obtained standard resource code matrix as D1;

constructing an element resource library according to the obtained standard resource code matrix, uploading the obtained standard resource code matrix to the element resource library according to the sequence of allocating and combining discrete resource code element streams, and associating the obtained element resource library with a corresponding communication sub-element;

further, one communication sub-element is correspondingly associated with an element resource library, and the element resource library contains information of all used communication resources of the communication sub-element;

generating a resource variation graph according to the obtained discrete resource coefficients, and associating the obtained resource variation graph with a corresponding wireless aggregation point;

performing curve marking on the obtained resource variation graph to obtain a resource coefficient spectral line;

Further, the obtained resource coefficient spectral line is a transformation curve generated according to discrete resource coefficients, and is marked as a resource coefficient spectral line in a resource variation graph, wherein the resource coefficient spectral line comprises a wireless spectrum coefficient line, a base station coefficient line, a user equipment coefficient line, a network channel coefficient line and a network capacity coefficient line;

Setting a monitoring period according to the obtained resource variation graph, and collecting the resource coefficient spectral lines periodically based on the monitoring period to obtain a periodic consumption coefficient;

The obtained periodic usage coefficient is denoted as ZY, wherein, ，Indicating the start time of the monitoring period,Indicating the end time of the monitoring period,The spectrum line of the resource coefficient is represented, dt represents the differentiation of t, and t represents the time node corresponding to the transverse axis in the spectrum line of the resource coefficient;

Carrying out resource pre-adjustment on the communication sub-element according to the obtained periodic consumption coefficient to obtain the expected resource quantity of the element;

it should be further noted that, in the implementation process, the resource pre-adjustment process includes:

Setting a base threshold amount, and marking the obtained base threshold amount as Y0, wherein, y*β，Y represents an average threshold amount based on the amount of communication resources used by all communication sub-elements in the wireless network space, and β represents a base threshold value for the amount of communication resources used;

Pre-allocating the communication resource amount used by the communication sub-element according to the periodic usage coefficient and the basic threshold usage, wherein the allocated communication resource amount is the element expected resource amount, and marking the obtained element expected resource amount as R, The obtained element expected resource amount is the resource amount pre-allocated by the communication sub-element, and the allocated element expected resource amount is adjusted to the corresponding communication sub-element;

The communication sub-elements are subjected to pre-adjustment according to the expected resource quantity of the elements, and the communication sub-elements subjected to pre-adjustment are subjected to monitoring and acquisition through the wireless acquisition terminal, so that pre-adjustment allocation resource data are obtained;

Further, the pre-allocated resource data is obtained by allocating the expected resource amount of the element to the communication sub-element for use and monitoring a process of using the expected resource amount of the element, and the pre-allocated resource data is used for representing a corresponding part of the expected resource amount of the element used by the communication sub-element.

The intelligent regulation and control module is used for carrying out quantity monitoring and threshold judgment on the communication sub-element to obtain surplus preset resources, carrying out resource surplus adjustment on the ullage sub-element according to the surplus preset resources to obtain the traffic sub-element, and the specific process comprises the following steps:

performing homologous conversion on the obtained pre-allocated resource data to obtain a discrete pre-allocation coefficient;

The homologous transformation process comprises the following steps:

information conversion is carried out on the obtained pre-allocated resource data, and a pre-allocated signal is obtained;

Uploading the obtained segmented frequency-filtering coefficient to a pre-adjustment signal, and capturing the performance of the pre-adjustment signal through the segmented frequency-filtering coefficient to obtain a discrete pre-adjustment coefficient;

Performing secondary conversion on the obtained discrete preset coefficients to obtain preset distribution code segments;

Further, the secondary conversion process includes:

Performing code element conversion on the obtained discrete preset coefficients to obtain preset distribution code element streams;

carrying out stream segment grouping on the obtained pre-allocated code element stream to obtain a pre-allocated code segment;

Marking the obtained pre-allocated code segments as I represents the number of the pre-allocated resource data corresponding to the discrete pre-allocation coefficient, j represents the code of the pre-allocated code segment in the discrete pre-allocation coefficient, i-j represents the j-th pre-allocated code segment of the i-th discrete pre-allocation coefficient, i=1, 2,3, … …, v1, v1 is a positive integer, j=1, 2,3, … …, v2, v2 is a positive integer;

Constructing a preset resource library according to the obtained preset distribution code segments, and uploading the obtained preset distribution code segments to the preset resource library according to the sequence of performing secondary conversion on the discrete preset coefficients;

performing usage monitoring on the communication sub-element according to the obtained element resource library to obtain a matched element resource;

Further, the usage monitoring process includes:

Extracting the matrix of the preset distribution code segment in the preset resource library and the standard resource code matrix in the element resource library to obtain a monitoring matching code, and marking the obtained monitoring matching code as Wherein, the method comprises the steps of, wherein,，Representing a transpose of the standard resource code matrix;

particularly, the sequence of extracting the matrix of the preset allocation code segments in the preset resource library and the standard resource code matrix in the element resource library is extracted in a one-to-one correspondence manner in the preset resource library and the element resource library, and is carried out according to the storage sequence;

carrying out state discrimination on the monitoring matching codes to obtain matching element codes and unused element codes;

Further, when the monitored matching code is [000], it indicates that the pre-allocated code segment is successfully matched with the element resource library, and marks the pre-allocated code segment as a matched element code, which indicates that the expected element resource amount used by the communication sub-element has a matching part with the communication resource data, that is, the allocated expected element resource amount actually used by the communication sub-element, the using position of the expected element resource amount used by the communication sub-element can be located according to the matched element code, and the using position of the expected element resource amount used by the communication sub-element can be located according to the monitored matching code Obtaining a corresponding use position;

When the monitored matching code is [001], [011], [100], [101], [110], [111] or [010], the pre-allocated code segment is not matched with the element resource library, and the successfully matched pre-allocated code segment is marked as an unused element code, the communication sub-element does not use the expected resource quantity of the element at the corresponding position, namely, the communication resource of the corresponding quantity is allocated, and the communication sub-element does not use the communication resource;

Carrying out distribution and investigation on the communication sub-elements according to the obtained matching element codes and unused element codes to obtain a preset usage degree;

It should be further noted that, in the implementation process, the allocation and collaboration process includes:

counting the number of all the monitoring matching codes of the communication subelement to obtain the number of the matching codes and the number of unused codes;

The number statistics shows that the states of the monitoring matching codes obtained after the element expected resource quantity is distributed to the communication subelement in the communication subelement for use are counted, and the numbers of the matching element codes and the unused element codes are counted respectively to obtain the number of the matching codes and the number of the unused codes;

carrying out use statistics according to the obtained matched code number and the unused code number to obtain a preset use degree, marking the obtained preset use degree as F, wherein, ；

Critical judgment is carried out on the preset usage degree, and a defect quantum element is obtained;

Further, the critical determination process includes:

If f=1, it indicates that there is no unused element code in the communication subelement, it indicates that the expected resource amount of the element allocated to the communication subelement is used, and there is no remaining communication resource amount, then the obtained communication subelement is marked as a full subelement, and resource re-monitoring needs to be performed on the full subelement, it determines whether the communication subelement just meets the resource usage amount or the allocated expected resource amount of the element is not enough to be used by the full subelement, and the control center performs resource re-monitoring on the full subelement, if the full subelement still performs communication operation in the next monitoring period, new communication resource is needed, the full subelement is marked as an empty subelement, and if the communication operation is stopped, no signal communication resource is needed, that is, other communication resources do not need to be invoked;

setting a use threshold value for the preset use schedule, and judging the preset use schedule by using the threshold value to obtain qualified preset resources and surplus preset resources;

further, when the usage threshold value > (1-F), marking the obtained preset usage degree as qualified preset resources, wherein the expected resource quantity of the element allocated to the communication sub-element is in a proper range, and resource waste caused by excessive allocation of communication resources is avoided;

When the usage threshold value is less than or equal to (1-F), marking the obtained preset usage degree as surplus preset resources, wherein the expected resource quantity of the elements allocated to the communication sub-elements exceeds a proper range, and excessive communication resources are allocated to the communication sub-elements, so that the communication resources in the past of scheduling are remained, and the resource waste is caused;

Obtaining an activity adjustable resource according to the obtained surplus preset resource;

the movable adjustable resource represents that the expected resource quantity of the element corresponding to the unused element code is marked as the movable adjustable resource, and then the part of the resource can be randomly mobilized through the control center and mobilized to other communication sub-elements again;

The control center is used for carrying out resource surplus allocation on the ullage subelement, and carrying out resource supplementation on the ullage subelement to obtain a traffic subelement, wherein the traffic subelement indicates that communication work can be continued by utilizing the allocated movable adjustable resource, and communication work is not suspended due to shortage of communication resource;

further, the resource surplus allocation means that the distances of communication subelements which are near the ullage subelements and contain the movable adjustable resources are firstly ordered according to the order from small to large, the adjustable resource ordering is obtained, the movable adjustable resources at the communication subelements with the first ordering are allocated to the ullage subelements preferentially, the utilization statistics is carried out on the ullage subelements again, and the pre-allocation utilization scheduling is monitored;

If F=1, the resource is required to be re-monitored through the control center, if the resource is still an scarce sub-element, the movable adjustable resource at the next communication sub-element is called according to the sequence of the adjustable resource sequencing until the F not equal to 1 of the scarce sub-element is met, the resource mobilized by the scarce sub-element is mobilized, the mobilization is completed, the mobilization is not required to be performed again, the communication resource lacking by the scarce sub-element is made up, the reasonable scheduling of the communication resource is realized, and the resource allocation is optimized;

Particularly, if the preset use degree is the surplus preset resource when F is not equal to 1, generating an active adjustable resource according to the surplus preset resource, and carrying out resource scheduling again to be distributed to the rest of the ullage subelements so as to realize efficient and economical resource distribution.

Based on the above communication resource scheduling system for the wireless communication network, the invention also provides a communication resource scheduling method for the wireless communication network, comprising the following steps:

Step one: collecting communication resource data;

Step two: performing information conversion on communication resource data to obtain a resource use signal, performing section conversion and series judgment on the set middle section frequency-filtering coefficient to obtain a conversion series, performing series interception on the middle section frequency-filtering coefficient according to the conversion series to obtain a segmented frequency-filtering coefficient, and performing performance capture on the resource use signal through the segmented frequency-filtering coefficient to obtain a discrete resource coefficient;

Step three: performing code element conversion and distribution combination on discrete resource data to obtain a standard resource code matrix, constructing an element resource library according to the standard resource code matrix, generating a resource variation graph according to discrete resource coefficients, periodically collecting the resource variation graph to obtain periodic consumption coefficients, performing resource pre-adjustment on communication sub-elements through the periodic consumption coefficients to obtain element expected resource quantity, and performing pre-adjustment on the communication sub-elements according to the element expected resource quantity to obtain pre-adjustment distribution resource data;

Step four: performing homologous conversion and secondary conversion on the pre-allocated resource data to obtain a pre-allocated code segment, monitoring the consumption of the communication subelement according to an element resource library to obtain matched element resources, performing allocation and investigation on the monitored matched codes to obtain pre-allocated usage, setting a usage threshold according to the pre-allocated usage, performing threshold judgment on the pre-allocated usage by using the threshold to obtain surplus pre-allocated resources, and performing resource surplus mobilization on the ullage subelement according to the surplus pre-allocated resources to obtain the traffic subelement.

The preferred embodiments of the invention disclosed above are intended only to assist in the explanation of the invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best understand and utilize the invention. The invention is limited only by the claims and the full scope and equivalents thereof.

Claims (9)

1. The communication resource scheduling system for the wireless communication network comprises a control center, and is characterized in that the control center is connected with a communication acquisition module, an information processing module, a resource analysis module and an intelligent regulation and control module;

The communication acquisition module is used for acquiring communication resource data;

The information processing module is used for carrying out information conversion on communication resource data to obtain a resource use signal, carrying out section conversion and series judgment on the set middle section frequency-filtering coefficient to obtain a conversion series, carrying out series interception on the middle section frequency-filtering coefficient according to the conversion series to obtain a segmented frequency-filtering coefficient, and carrying out performance capture on the resource use signal through the segmented frequency-filtering coefficient to obtain a discrete resource coefficient;

the resource analysis module is used for carrying out code element conversion and distribution combination on discrete resource data to obtain a standard resource code matrix, constructing an element resource library according to the standard resource code matrix, generating a resource variation graph according to discrete resource coefficients, carrying out periodic collection on the resource variation graph to obtain a periodic consumption coefficient, carrying out resource pre-adjustment on a communication sub-element through the periodic consumption coefficient to obtain an element expected resource amount, and carrying out pre-adjustment on the communication sub-element according to the element expected resource amount to obtain pre-adjustment distribution resource data;

The intelligent regulation and control module is used for carrying out homologous conversion and secondary conversion on the pre-allocated resource data to obtain a pre-allocated code segment, carrying out usage monitoring on the communication subelement according to the element resource library to obtain matched element resources, carrying out allocation and investigation on the monitored matched codes to obtain pre-allocated usage, setting a usage threshold according to the pre-allocated usage, carrying out threshold judgment on the pre-allocated usage by the usage threshold to obtain surplus pre-allocated resources, and carrying out resource surplus mobilization on the ullage subelement according to the surplus pre-allocated resources to obtain the traffic subelement.

2. The communication resource scheduling system for a wireless communication network of claim 1, wherein the process of the communication acquisition module acquiring communication resource data comprises:

Acquiring, arranging and controlling a wireless communication network to obtain a wireless network space, and carrying out matching marking on the wireless communication network in the wireless network space to obtain a communication sub-element;

And setting a wireless acquisition end according to the communication sub-element, and acquiring data of a communication network through the wireless acquisition end to obtain communication resource data.

3. A communication resource scheduling system for a wireless communication network according to claim 2 wherein the process of obtaining the number of conversion stages comprises:

information conversion is carried out on the communication resource data to obtain a resource use signal, and characteristic extraction is carried out on the resource use signal to obtain signal characteristics;

setting a middle section frequency filtering coefficient, and carrying out section transformation on the middle section frequency filtering coefficient to obtain transformation parameters;

Carrying out section statistics on the middle section frequency filtering coefficient according to the conversion parameter to obtain a section interval;

and carrying out series judgment on the middle section frequency filtering coefficient according to the signal characteristics, the conversion parameters and the section intervals to obtain a conversion series.

4. A communication resource scheduling system for a wireless communication network according to claim 3 wherein the process of obtaining discrete resource coefficients comprises:

intercepting the middle section frequency filtering coefficient by converting the series to obtain a segmented frequency filtering coefficient;

Uploading the segmented frequency-filtering coefficient to a resource using signal, and capturing the performance of the resource using signal through the segmented frequency-filtering coefficient to obtain a discrete resource coefficient.

5. The communication resource scheduling system for a wireless communication network of claim 4, wherein the process of obtaining the standard resource code matrix comprises:

performing code element conversion on the obtained discrete resource data to obtain a discrete resource code element stream, and performing distribution combination on the discrete resource code element stream to obtain a standard resource code matrix;

and constructing an element resource library according to the obtained standard resource code matrix, and associating the obtained element resource library with a corresponding communication sub-element.

6. A communication resource scheduling system for a wireless communication network according to claim 5 wherein the process of obtaining pre-allocated resource data comprises:

generating a resource variation graph according to the discrete resource coefficients, and performing curve marking on the obtained resource variation graph to obtain resource coefficient spectral lines;

Setting a monitoring period according to the obtained resource variation graph, and collecting the resource coefficient spectral lines periodically based on the monitoring period to obtain a periodic consumption coefficient;

Carrying out resource pre-adjustment on the communication sub-element according to the periodic consumption coefficient to obtain the expected resource quantity of the element;

and carrying out pre-adjustment on the communication subelement according to the expected resource quantity of the element, and carrying out monitoring and acquisition on the pre-adjustment communication subelement through a wireless acquisition terminal to obtain pre-adjustment allocation resource data.

7. The communication resource scheduling system for a wireless communication network of claim 6, wherein the process of obtaining the pre-set usage degree comprises:

performing homologous conversion on the pre-allocated resource data to obtain discrete pre-allocated coefficients, and performing secondary conversion on the discrete pre-allocated coefficients to obtain pre-allocated code segments;

monitoring the consumption of the communication sub-element according to the element resource library to obtain a matched element resource;

carrying out state discrimination on the monitoring matching codes to obtain matching element codes and unused element codes;

And carrying out distribution and investigation on the communication sub-elements according to the matched element codes and the unused element codes to obtain the preset usage degree.

8. A communication resource scheduling system for a wireless communication network according to claim 7 wherein the process of obtaining a pass sub-element comprises:

Critical judgment is carried out on the preset usage degree, and a defect quantum element is obtained;

setting a use threshold according to the preset use schedule, and judging the preset use schedule by using the threshold to obtain qualified preset resources and surplus preset resources;

Obtaining an activity adjustable resource according to the obtained surplus preset resource;

and carrying out resource surplus allocation and resource supplementation on the ullage subelement through the control center to obtain the traffic subelement.

9. A communication resource scheduling method for a communication resource scheduling system of a wireless communication network according to any one of claims 1 to 8, comprising the steps of:

Step one: collecting communication resource data;

Step two: performing information conversion on communication resource data to obtain a resource use signal, performing section conversion and series judgment on the set middle section frequency-filtering coefficient to obtain a conversion series, performing series interception on the middle section frequency-filtering coefficient according to the conversion series to obtain a segmented frequency-filtering coefficient, and performing performance capture on the resource use signal through the segmented frequency-filtering coefficient to obtain a discrete resource coefficient;

Step three: performing code element conversion and distribution combination on discrete resource data to obtain a standard resource code matrix, constructing an element resource library according to the standard resource code matrix, generating a resource variation graph according to discrete resource coefficients, periodically collecting the resource variation graph to obtain periodic consumption coefficients, performing resource pre-adjustment on communication sub-elements through the periodic consumption coefficients to obtain element expected resource quantity, and performing pre-adjustment on the communication sub-elements according to the element expected resource quantity to obtain pre-adjustment distribution resource data;

Step four: performing homologous conversion and secondary conversion on the pre-allocated resource data to obtain a pre-allocated code segment, monitoring the consumption of the communication subelement according to an element resource library to obtain matched element resources, performing allocation and investigation on the monitored matched codes to obtain pre-allocated usage, setting a usage threshold according to the pre-allocated usage, performing threshold judgment on the pre-allocated usage by using the threshold to obtain surplus pre-allocated resources, and performing resource surplus mobilization on the ullage subelement according to the surplus pre-allocated resources to obtain the traffic subelement.