CN114845326A

CN114845326A - Wireless network resource configuration method and device, electronic equipment and storage medium

Info

Publication number: CN114845326A
Application number: CN202210460787.4A
Authority: CN
Inventors: 盛莉莉; 顾伟; 赵煜; 周奕昕; 于洋; 谷俊江; 祝海亮; 张燕; 王新
Original assignee: China United Network Communications Group Co Ltd
Current assignee: China United Network Communications Group Co Ltd
Priority date: 2022-04-28
Filing date: 2022-04-28
Publication date: 2022-08-02

Abstract

The application provides a wireless network resource configuration method, a wireless network resource configuration device, electronic equipment and a storage medium, wherein the method comprises the following steps: acquiring the maximum connection user quantity of Radio Resource Control (RRC) of a base station; acquiring the current RRC configuration user number of the base station according to the current RRC configuration parameters of the base station, wherein the current RRC configuration parameters of the base station comprise RRC permitted configuration quantity and dimension values corresponding to various dimensions; calculating and obtaining the quantity of the RRC users needing to be increased or decreased according to the quantity of the RRC maximum connection users and the current quantity of the RRC configuration users of the base station; and adjusting the current RRC configuration parameters of the base station according to the quantity of the RRC users needing to be increased or decreased. And calculating the quantity of the RRC users to be adjusted according to the maximum RRC connection user quantity of the base station to be adjusted and the configuration parameters, and further obtaining the number of the allowed quantity to be adjusted so as to realize reasonable distribution of wireless network resources.

Description

Wireless network resource configuration method and device, electronic equipment and storage medium

Technical Field

The present application relates to the field of communications, and in particular, to a method and an apparatus for configuring wireless network resources, an electronic device, and a storage medium.

Background

The Radio Resource Control (RRC) connection number is one of the resources of the Radio network. The data of the access users allowed by the cell is limited by the RRC user connection license, and when the number of the access users exceeds the upper limit of the number of the users allowed by the RRC connection license, the users cannot access the cell.

At present, the RRC user connection license of the network usually adopts static configuration, that is, fixed RRC configuration parameters are set according to the maximum configurable condition. Inevitably, the use of the radio resources is uneven, and the scheme of static configuration cannot realize reasonable allocation of the radio network resources.

Disclosure of Invention

The application provides a wireless network resource allocation method, a wireless network resource allocation device, electronic equipment and a storage medium, so as to realize reasonable allocation of wireless network resources.

In a first aspect, the present application provides a method for configuring wireless network resources, including:

acquiring the maximum connection user quantity of Radio Resource Control (RRC) of a base station;

acquiring the current RRC configuration user number of the base station according to the current RRC configuration parameters of the base station, wherein the current RRC configuration parameters of the base station comprise RRC permitted configuration quantity and dimension values corresponding to various dimensions;

calculating to obtain the quantity of the RRC users needing to be increased or decreased according to the quantity of the RRC maximum connection users and the current quantity of the RRC configuration users of the base station; and adjusting the current RRC configuration parameters of the base station according to the quantity of the RRC users needing to be increased or decreased.

Optionally, the calculating, according to the maximum RRC connection user amount and the current number of RRC-configured users of the base station, to obtain the number of RRC users that need to be increased or decreased includes:

obtaining the estimated RRC user quantity by calculating the product of the redundancy coefficient and the maximum RRC connection user quantity;

and acquiring the RRC user quantity needing to be increased or decreased according to the difference between the RRC estimated user quantity and the RRC configured user quantity.

Optionally, before obtaining the RRC estimated user quantity by calculating a product of the redundancy coefficient and the RRC maximum connection user quantity, the method further includes:

setting the redundancy coefficient as a first coefficient in response to the fact that the maximum RRC connection user quantity is larger than the RRC configuration user quantity;

setting the redundancy coefficient as a second coefficient in response to the fact that the maximum RRC connection user quantity is not larger than the RRC configuration user quantity; wherein the first coefficient is less than the second coefficient.

Optionally, the adjusting the current RRC configuration parameter of the base station according to the RRC user amount that needs to be increased or decreased includes:

obtaining the number of the first licenses to be increased or decreased by calculating the ratio of the RRC user quantity to be increased or decreased to a predetermined dimension value of a first dimension; wherein the first permitted dimension is the first dimension;

adjusting the current RRC configuration parameters of the base station according to the number of the first permissions to be increased or decreased; the adjusting includes increasing or decreasing a configuration parameter of the first license.

Optionally, if the RRC user amount needs to be decreased, before adjusting the current RRC configuration parameter of the base station according to the RRC user amount that needs to be increased or decreased, the method further includes:

obtaining the decrement amount of the first license by calculating the difference according to the configuration amount of the first license and the actual usage amount of the first license in the current configuration parameters of the base station;

the adjusting the current RRC configuration parameters of the base station according to the RRC user quantity needing to be increased or decreased comprises the following steps:

and if the number of the first licenses needing to be reduced is not more than the reducible amount of the first licenses, adjusting the current RRC configuration parameters of the base station according to the number of the first licenses needing to be reduced.

Optionally, after obtaining the reducible amount of the first license by subtracting according to the configuration amount of the first license and the actual usage amount of the first license in the current configuration parameters of the base station, the method further includes:

if the number of the first licenses needing to be reduced is larger than the reducible amount of the first licenses, aiming at a second dimension except the first dimension in each dimension, calculating the ratio of the RRC user quantity needing to be increased or reduced to the dimension value of the second dimension to obtain the number of the second licenses needing to be reduced; wherein the second permitted dimension is the second dimension;

and adjusting the current RRC configuration parameters of the base station according to the number of the second licenses needing to be reduced.

Optionally, the number of the base stations is multiple; the method further comprises the following steps:

calibrating the priorities of the base stations according to the RRC connection establishment failure times of the base stations and alarm information;

the acquiring the maximum connection user quantity of the radio resource control RRC of the base station comprises the following steps:

and acquiring the maximum connection user quantity of the radio resource control RRC of the base station aiming at the base station which is not adjusted and has the highest current priority in the plurality of base stations.

In a second aspect, the present application provides a wireless network resource configuration apparatus, including:

a user quantity obtaining module, configured to obtain a maximum connection user quantity of radio resource control RRC of the base station;

a configuration quantity obtaining module, configured to obtain a current number of RRC configured users of the base station according to a current RRC configuration parameter of the base station, where the current RRC configuration parameter of the base station includes an RRC-allowed configuration quantity and a dimension value corresponding to each dimension;

the adjustment amount calculation module is used for calculating and obtaining the quantity of the RRC users needing to be increased or decreased according to the quantity of the RRC maximum connection users and the current quantity of the RRC configuration users of the base station; and adjusting the current RRC configuration parameters of the base station according to the quantity of the RRC users needing to be increased or decreased.

Optionally, the adjustment amount calculation module includes:

the estimated user quantity calculation unit is used for calculating the product of the redundancy coefficient and the RRC maximum connection user quantity to obtain the RRC estimated user quantity;

and the adjustment amount calculation unit is used for obtaining the RRC user amount needing to be increased or decreased according to the difference between the RRC estimated user amount and the RRC configured user amount.

Optionally, the adjustment amount calculating module further includes a redundancy coefficient setting unit, configured to:

Optionally, the adjustment amount calculation module includes:

a license number calculation unit for obtaining the number of the first licenses to be increased or decreased by calculating a ratio of the number of the RRC users to be increased or decreased to a predetermined dimension value of a first dimension; wherein the first permitted dimension is the first dimension;

an adjusting unit, configured to adjust a current RRC configuration parameter of the base station according to the number of the first grants that need to be increased or decreased; the adjusting includes increasing or decreasing a configuration parameter of the first license.

Optionally, the adjustment amount calculating module is further configured to:

the adjusting unit is specifically configured to: and if the number of the first licenses needing to be reduced is not more than the reducible amount of the first licenses, adjusting the current RRC configuration parameters of the base station according to the number of the first licenses needing to be reduced.

Optionally, the adjustment amount calculating module is further configured to:

Optionally, the number of the base stations is multiple; the device further comprises:

the priority calibration module is used for calibrating the priorities of the base stations according to the RRC connection establishment failure times of the base stations and the alarm information;

the user quantity obtaining module is configured to:

In a third aspect, the present application provides an electronic device, comprising:

at least one processor; and

a memory communicatively coupled to the at least one processor; wherein the content of the first and second substances,

the memory stores instructions executable by the at least one processor to enable the at least one processor to perform the method of the first aspect.

In a fourth aspect, the present application provides a computer-readable storage medium having stored thereon computer-executable instructions for implementing the method according to the first aspect when executed by a processor.

The application provides a wireless network resource configuration method, a wireless network resource configuration device, electronic equipment and a storage medium, wherein the method comprises the following steps: acquiring the maximum connection user quantity of radio resource control RRC of a base station; acquiring the current RRC configuration user number of the base station according to the current RRC configuration parameters of the base station, wherein the current RRC configuration parameters of the base station comprise RRC permitted configuration quantity and dimension values corresponding to various dimensions; calculating to obtain the quantity of the RRC users needing to be increased or decreased according to the quantity of the RRC maximum connection users and the current quantity of the RRC configuration users of the base station; and adjusting the current RRC configuration parameters of the base station according to the quantity of the RRC users needing to be increased or decreased. And calculating the quantity of the RRC users to be adjusted according to the maximum RRC connection user quantity of the base station to be adjusted and the configuration parameters, and further obtaining the number of the allowed quantity to be adjusted so as to realize reasonable distribution of wireless network resources.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present application and together with the description, serve to explain the principles of the application.

Fig. 1 is a schematic view of an application scenario provided in the present application;

fig. 2 is a flowchart illustrating a method for configuring wireless network resources according to an embodiment of the present application;

fig. 3 is a flowchart illustrating a method for configuring wireless network resources according to an embodiment of the present application;

fig. 4 is a flowchart illustrating a method for configuring wireless network resources according to a second embodiment of the present application;

fig. 5 is a flowchart illustrating another method for configuring wireless network resources according to a second embodiment of the present application;

fig. 6 is a flowchart illustrating a method for configuring wireless network resources according to a third embodiment of the present application;

fig. 7 is a flowchart illustrating another method for configuring wireless network resources according to a third embodiment of the present application;

fig. 8 is a flowchart illustrating another method for configuring wireless network resources according to a third embodiment of the present application;

fig. 9 is a schematic structural diagram of a wireless network resource allocation apparatus according to a fourth embodiment of the present application;

fig. 10 is a schematic structural diagram of another wireless network resource allocation apparatus according to a fourth embodiment of the present application;

fig. 11 is a schematic structural diagram of an electronic device according to a fifth embodiment of the present application.

With the above figures, there are shown specific embodiments of the present application, which will be described in more detail below. These drawings and written description are not intended to limit the scope of the inventive concepts in any manner, but rather to illustrate the inventive concepts to those skilled in the art by reference to specific embodiments.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present application. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the present application, as detailed in the appended claims.

The number of RRC connections is one of the resources of the radio network. The data of the access users allowed by the cell is limited by the RRC user connection license, and when the number of the access users exceeds the upper limit of the number of the users allowed by the RRC connection license, the users cannot access, so that the user perception is seriously influenced. At present, the RRC user connection license of the network usually adopts static configuration, the investment cost of license calculation and distribution is high, the current network resources are not fully utilized, and large-scale adjustment cannot be implemented.

However, the existing RRC connection License deployment adopts a static configuration method, and if each base station is configured according to the peak value of the number of users, the configuration cost is too high. The tide effect of the network causes the situation that the wireless cells are busy and idle unevenly, the situation that the wave crests and the wave troughs exist in the user access numbers of different cells in different time periods of a day, and wireless resources are not effectively utilized. In practical application, although a manual deployment mode is adopted, the method has low efficiency, alarm inquiry and deployment operation needs to be carried out manually, and the deployment operation needs to be carried out interactively on a special system and a server, so that only small-batch operation can be carried out, and large-scale operation of the whole network cannot be implemented.

Fig. 1 is a schematic view of an application scenario provided by the present application, in which a local area network is served by a plurality of base stations similar to base station a, and the number of RRC connected users of base station a is determined by the allocated number of grants. For the base station a as shown in the figure, 5 licenses with a sales dimension of 10, 7 licenses with a sales dimension of 20 and 4 licenses with a sales dimension of 40 are pre-allocated, the number of users that the base station a can provide access is 5 × 10+7 × 20+4 × 40 — 350, in other words, when the number of RRC access users exceeds 350, a problem occurs in the base station. Generally, the access failure of the base station has two problems of RRC connection establishment failure caused by the limitation of user data specification and overuse permitted by the base station, and a network element capable of being allocated and a license list capable of being reduced and adjusted can be automatically acquired through an algorithm, so that the dynamic allocation of the RRC connection licenses at any time and any frequency can be realized.

The technical means of the present application and the technical means of the present application will be described in detail below with specific examples. The following several specific embodiments may be combined with each other, and details of the same or similar concepts or processes may not be repeated in some embodiments. In the description of the present application, unless otherwise explicitly specified and defined, each term should be understood broadly in the art. Embodiments of the present application will be described below with reference to the accompanying drawings.

Example one

Fig. 2 is a flowchart illustrating a method for configuring wireless network resources according to an embodiment of the present application, as shown in fig. 2, the method includes:

s101, acquiring the maximum connection user quantity of Radio Resource Control (RRC) of a base station;

s102, acquiring the current RRC configuration user number of the base station according to the current RRC configuration parameters of the base station;

s103, calculating and obtaining the quantity of the RRC users needing to be increased or decreased according to the quantity of the RRC maximum connection users and the current quantity of the RRC configuration users of the base station;

and S104, adjusting the current RRC configuration parameters of the base station according to the RRC user quantity needing to be increased or decreased.

The present embodiment is exemplarily described with reference to specific application scenarios: there are two main reasons for access failure of the base station, RRC connection establishment failure due to the limitation of the user data specification, or over-utilization permitted by the base station. Therefore, for a failed base station, the allowed allocation from other base stations is required to meet the required data specification of the failed base station, and firstly, a list of base stations which need to be allocated and a list of base stations which can be allowed to be allocated should be obtained, and further, calculation of the allowed decrement or required increment is performed.

Specifically, firstly, acquiring the maximum connection user quantity of radio resource control RRC of a base station, wherein the base station refers to a base station to be allocated, namely a base station with a limited user data specification or a redundant problem; obtaining the number of the current RRC configuration users of the base station according to the current RRC configuration parameters of the base station, wherein the current RRC configuration parameters of the base station comprise RRC permitted configuration quantity and dimension values corresponding to various dimensions, for various sales dimensions, the configuration quantity and the dimension values can be multiplied, and the obtained results are summed to obtain the number of the RRC configuration users; then, according to the maximum RRC connection user quantity and the current RRC configuration user quantity of the base station, calculating to obtain the RRC user quantity needing to be increased or decreased; and adjusting the current RRC configuration parameters of the base station according to the RRC user quantity needing to be increased or decreased, wherein the user quantity generally needs to be converted into the allowed quantity for allocation.

Fig. 3 is a flowchart illustrating a further method for configuring radio network resources according to an embodiment of the present application, where the number of the base stations is multiple, and as shown in fig. 3, S101 specifically includes:

s105, aiming at the base station which is not adjusted and has the highest current priority in the plurality of base stations, acquiring the maximum connection user quantity of the radio resource control RRC of the base station:

before S101, the method further includes:

s106, according to the RRC connection establishment failure times of the base stations and the alarm information, calibrating the priorities of the base stations.

Firstly, the priorities of the base stations can be calibrated according to the number of times of RRC connection establishment failures of the base stations and alarm information. The alarm information includes the permitted overuse and the corresponding base station information, in other words, according to the degree and duration of the two types of faults, the priority can be calculated and sequenced through an algorithm, and the execution of the wireless network resource allocation is optimized. And acquiring the maximum connection user quantity of the radio resource control RRC of the base station aiming at the base station which is not adjusted and has the highest current priority in the plurality of base stations, wherein the user quantity can be used for the subsequent allocating work from S102 to S104. The calibration of the base station wireless resource allocation priority is carried out through the fault type and the alarm information, and the allocation work is carried out according to the priority, so that the efficiency of wireless network resource allocation can be improved, and the reasonable allocation of the wireless network resources is realized.

The embodiment provides a wireless network resource configuration method, which comprises the following steps: acquiring the maximum connection user quantity of Radio Resource Control (RRC) of a base station; acquiring the current RRC configuration user number of the base station according to the current RRC configuration parameters of the base station, wherein the current RRC configuration parameters of the base station comprise RRC permitted configuration quantity and dimension values corresponding to various dimensions; calculating to obtain the quantity of the RRC users needing to be increased or decreased according to the quantity of the RRC maximum connection users and the current quantity of the RRC configuration users of the base station; and adjusting the current RRC configuration parameters of the base station according to the quantity of the RRC users needing to be increased or decreased. And calculating the quantity of the RRC users to be adjusted according to the maximum RRC connection user quantity of the base station to be adjusted and the configuration parameters, and further obtaining the number of the allowed quantity to be adjusted so as to realize reasonable distribution of wireless network resources.

Example two

Fig. 4 is a flowchart illustrating a radio network resource configuration method according to a second embodiment of the present application, as shown in fig. 4, based on any embodiment, S103 includes:

s201, obtaining an RRC estimated user quantity by calculating a product of a redundancy coefficient and the RRC maximum connection user quantity;

s202, obtaining the RRC user quantity needing to be increased or decreased according to the difference between the RRC estimated user quantity and the RRC configured user quantity.

The present embodiment is exemplarily described with reference to specific application scenarios: for the RRC user quantity to be adjusted, the calculation of the RRC estimated user quantity can be carried out after the maximum RRC connection user quantity of the base station and the current RRC configuration parameters of the base station in a period of time are obtained. The RRC estimated user amount may be the RRC maximum connection user amount, or the RRC maximum connection user amount is multiplied by a redundancy coefficient to ensure that the base station does not have a new failure after the adjustment. Generally, the redundancy factor is greater than 1, meaning that the estimated amount of RRC users that the base station needs to carry is a multiple of the maximum connected amount of RRC users in a future period. And then, obtaining the RRC user quantity needing to be increased or decreased according to the difference between the RRC estimated user quantity and the RRC configured user quantity, and converting the RRC user quantity into a permission number for allocation. By introducing the redundancy coefficient, the maximum load during the use period of the base station can be estimated, the faults caused by factors such as fluctuation of user quantity and the like can be avoided, a margin is reserved for the adjustment of the permission number, and the repeated occurrence of the faults of the base station after the adjustment can be avoided under the condition of ensuring the resource waste as less as possible.

Fig. 5 is a flowchart illustrating a further method for configuring wireless network resources according to a second embodiment of the present application, as shown in fig. 5, before S201, the method further includes:

s203, responding to the situation that the maximum RRC connection user quantity is larger than the RRC configuration user quantity, and setting the redundancy coefficient as a first coefficient;

s204, responding to the situation that the maximum RRC connection user quantity is not larger than the RRC configuration user quantity, and setting the redundancy coefficient as a second coefficient.

According to the relation between the maximum RRC connection user quantity and the RRC configuration user quantity, a redundancy coefficient can be set, and the redundancy quantities which should be set in practical application of the two situations are different. Setting the redundancy coefficient as a first coefficient in response to the fact that the maximum RRC connection user quantity is larger than the RRC configuration user quantity; and setting the redundancy coefficient as a second coefficient in response to the fact that the maximum RRC connection user quantity is not larger than the RRC configuration user quantity.

When the maximum number of connected users of the RRC is not greater than the number of configured users of the RRC, the base station's license is to be called in practical application, and not only the fluctuation of the working condition of the base station itself needs to be estimated, but also it should be ensured that the number of licenses of the base station itself can still be used by the base station after the license is called, so that the base station will not have a connection problem after the base station is called. A larger amount of redundancy should be left than for the base station to be tuned in, i.e. the first coefficient should be smaller than the second coefficient.

For example, the base station B is a base station to be tuned in for admission, wherein the maximum RRC connection user amount of the base station B is 80, and the RRC configured user amount is 70; the base station C and the base station D are base stations for which permission is to be called, the maximum RRC connection user quantity of the base station C is 56, and the RRC configuration user quantity is 160; the maximum RRC connected user amount of base station D is 56, and the RRC configured user amount is 70. For base station B, its redundancy factor may be set to 1.2, and for base stations C and D, its redundancy factor may be set to 1.5. At this time, the RRC estimated user amount of the base station B is 96, and the RRC estimated user amounts of the base stations C and D are 84, so that the RRC user amounts to be increased or decreased of the base stations B, C and D can be calculated to be 26, -76 and 14, respectively. Wherein, the positive number represents that the number of users needs to be increased, the negative number represents that the number of users can be reduced, and the number of users needs to be converted into corresponding permission for deployment. Through setting of redundancy coefficients under different conditions, future loads and working conditions before and after adjustment are estimated, and it is ensured that the base station does not have corresponding connection faults after adjustment.

The embodiment provides a wireless network resource configuration method, which includes that the estimated user quantity of RRC is obtained by calculating the product of a redundancy coefficient and the maximum connection user quantity of RRC; and acquiring the RRC user quantity needing to be increased or decreased according to the difference between the RRC estimated user quantity and the RRC configured user quantity. By introducing the redundancy coefficient, the maximum load of the base station during the use period can be estimated, a margin is reserved for the adjustment of the permission number, and the repeated occurrence of the base station fault after the adjustment is avoided under the condition of ensuring the resource waste as less as possible.

EXAMPLE III

Fig. 6 is a flowchart illustrating a method for configuring wireless network resources according to a third embodiment of the present application, as shown in fig. 6, based on any embodiment, S104 specifically includes:

s301, obtaining the number of first grants needing to be increased or decreased by calculating the ratio of the RRC user number needing to be increased or decreased to a predetermined dimension value of a first dimension;

s302, adjusting the current RRC configuration parameters of the base station according to the number of the first permissions needing to be increased or decreased.

The present embodiment is exemplarily described with reference to specific application scenarios: and the quantity of the RRC users needing to be increased or decreased needs to be converted into the allowable quantity, and the RRC configuration parameters of the base station are adjusted according to the allowable quantity. Specifically, first, the number of first grants to be increased or decreased is obtained by calculating a ratio of the number of RRC users to be increased or decreased to a predetermined dimension value of a first dimension; the first allowable dimension is the first dimension, if the ratio is not an integer, then corresponding rounding operation is required, for the reducible allowable number, the obtained ratio should be rounded down, and for the allowable number to be increased, the obtained ratio should be rounded up. Then, according to the number of the first permission needing to be increased or decreased, adjusting the current RRC configuration parameters of the base station; the adjusting includes increasing or decreasing a configuration parameter of the first license.

For example in the second embodiment, the obtained value may be divided by the sales dimension of the license to be adjusted and rounded up to obtain the adjustment amount of the license, and when the adjustment amount is less than or equal to-1, it represents that the base station may still perform the license call of the corresponding value. If the license with the sales dimension of 40 is taken as the target license, the base station B needs to add 1 license, the base station C can subtract 1 license, and the base station D originally belongs to a base station with redundant configuration user amount and can call out the license, but because the estimated value of the user amount minus the configuration user amount is divided by the sales dimension and rounded up, the called-out condition is not met, the base station D is not deployed, and in some cases, the base station D even needs to call in the license.

Fig. 7 is a flowchart of another radio network resource configuration method according to a third embodiment of the present application, and as shown in fig. 7, if the RRC user amount needs to be reduced, before S302, the method further includes:

s303, obtaining the decrement allowed by the first license by calculating the difference according to the configuration quantity of the first license and the actual usage quantity of the first license in the current configuration parameters of the base station;

at this time, the S302 specifically includes:

s304, if the number of the first licenses needing to be reduced is not more than the reducible amount of the first licenses, adjusting the current RRC configuration parameters of the base station according to the number of the first licenses needing to be reduced.

For the base station that can subtract the grant, before performing the deployment, the decrementable amount of the first grant can be obtained by subtracting the actual usage amount of the first grant from the configuration amount of the first grant in the current configuration parameters of the base station, that is, the first grant actually available for deployment by the base station is obtained. And then comparing the decrement with the number of the first licenses needing to be decremented, and if the number of the first licenses needing to be decremented is not more than the decrement of the first licenses, adjusting the current RRC configuration parameters of the base station according to the number of the first licenses needing to be decremented. By means of calculation with decrement, the base station with permission to be reduced at present is ensured to have enough permission for allocation, and corresponding failure or access failure caused by allocation work after allocation is avoided.

Fig. 8 is a flowchart illustrating a further method for configuring wireless network resources according to a third embodiment of the present application, as shown in fig. 8, after S303, the method further includes:

s305, if the number of the first licenses needing to be reduced is larger than the reducible amount of the first licenses, aiming at a second dimension except the first dimension in each dimension, calculating the ratio of the RRC user quantity needing to be increased or reduced to the dimension value of the second dimension to obtain the number of the second licenses needing to be reduced;

s306, adjusting the current RRC configuration parameters of the base station according to the number of the second licenses needing to be reduced.

The base station usually allocates more than one type of license, and when the corresponding user amount cannot be met after a certain license amount is called out completely, other licenses can be allocated to perform equivalent replacement. That is, after the calculation of the decrementable amount, if the number of first grants to be decreased is greater than the decrementable amount of the first grants, for a second dimension other than the first dimension in the dimensions, the number of second grants to be decreased is obtained by calculating the ratio of the number of RRC users to be increased or decreased to the dimension value of the second dimension, and then the current RRC configuration parameter of the base station is adjusted according to the number of second grants to be decreased. For example, if the base station E needs to call up the licenses corresponding to 80 user quantities, the dimension of the first license is 40, but the base station E only has one license with the dimension of 40 available for allocation, but there is enough licenses with the dimension of 20 available for allocation, and then two licenses with the dimension of 20 can be called up to meet the user quantity requirement. Through the conversion among different dimensions, the resources of the license can be fully utilized, the allocation algorithm is simplified, and the waste of the resources is avoided.

The embodiment provides a method for configuring radio network resources, which includes calculating a ratio of an RRC user amount to be increased or decreased to a predetermined dimension value of a first dimension, to obtain a first allowed amount to be increased or decreased; wherein the first permitted dimension is the first dimension; adjusting the current RRC configuration parameters of the base station according to the number of the first permissions to be increased or decreased; the adjusting includes increasing or decreasing a configuration parameter of the first license. By converting the user amount into the allowable amount for allocation, the waste of resources can be avoided, the fault caused by the adjustment work can be prevented, and the effectiveness of the adjustment work can be ensured.

Example four

The fourth embodiment of the present application further provides a wireless network resource configuration device to implement the foregoing method.

Fig. 9 is a schematic structural diagram of a wireless network resource configuration device according to a fifth embodiment of the present application, where the device includes:

a user quantity obtaining module 41, configured to obtain a maximum connection user quantity of radio resource control RRC of the base station;

a configuration quantity obtaining module 42, configured to obtain, according to a current RRC configuration parameter of the base station, a current RRC configuration user quantity of the base station, where the current RRC configuration parameter of the base station includes an RRC-allowed configuration quantity and a dimension value corresponding to each dimension;

an adjustment amount calculating module 43, configured to calculate and obtain an RRC user amount that needs to be increased or decreased according to the RRC maximum connection user amount and the current RRC configured user amount of the base station; and adjusting the current RRC configuration parameters of the base station according to the quantity of the RRC users needing to be increased or decreased.

Firstly, a user quantity obtaining module 41 obtains the maximum connection user quantity of the radio resource control RRC of a base station, where the base station refers to a base station to be allocated, that is, a base station with a problem of limited user data specification or redundancy; then, the configuration quantity obtaining module 42 obtains the current number of RRC configured users of the base station according to the current RRC configuration parameter of the base station, where the current RRC configuration parameter of the base station includes an RRC-allowed configuration quantity and a dimension value corresponding to each dimension, and for various sales dimensions, the configuration quantity and the dimension value may be multiplied, and the obtained results are summed to obtain the number of RRC configured users; then, the adjustment amount calculating module 43 calculates and obtains the amount of RRC users to be increased or decreased according to the maximum RRC connection user amount and the current number of RRC-configured users of the base station; and adjusting the current RRC configuration parameters of the base station according to the RRC user quantity needing to be increased or decreased, wherein the user quantity generally needs to be converted into the allowed quantity for allocation.

Fig. 10 is a schematic structural diagram of another wireless network resource configuration device according to a fifth embodiment of the present application, which is used to illustrate a structure of the adjustment amount calculation module 43. The adjustment amount calculation module 43 specifically includes:

a predicted amount calculation unit 401, configured to obtain an RRC predicted user amount by calculating a product of a redundancy coefficient and the RRC maximum connection user amount;

an adjustment amount calculating unit 402, configured to obtain the RRC user amount to be increased or decreased according to a difference between the RRC estimated user amount and the RRC configured user amount.

The estimated amount calculation unit 401 may be configured to obtain the RRC estimated user amount by calculating a product of the redundancy coefficient and the RRC maximum connection user amount. The RRC estimated user amount may be the RRC maximum connection user amount, or the RRC maximum connection user amount is multiplied by a redundancy coefficient to ensure that the base station does not have a new failure after the adjustment. Generally, the redundancy factor is greater than 1, meaning that the estimated amount of RRC users that the base station needs to carry is a multiple of the maximum connected amount of RRC users in a future period. Then, the adjustment amount calculating unit 402 obtains the RRC user amount to be increased or decreased according to the difference between the RRC estimated user amount and the RRC configured user amount, and converts the RRC estimated user amount and the RRC configured user amount into a license number for deployment.

By introducing the redundancy coefficient, the maximum load of the base station during the use period can be estimated, a margin is reserved for the adjustment of the permission number, and the repeated occurrence of the base station fault after the adjustment is avoided under the condition of ensuring the resource waste as less as possible.

A redundancy coefficient setting unit 403 for:

According to the relation between the maximum RRC connection user quantity and the RRC configuration user quantity, a redundancy coefficient can be set, and the redundancy quantities which should be set in practical application of the two situations are different. The redundancy coefficient setting unit 403 is configured to set the redundancy coefficient as a first coefficient in response to the maximum RRC connection user amount being greater than the RRC configured user amount; and setting the redundancy coefficient as a second coefficient in response to the fact that the maximum RRC connection user quantity is not larger than the RRC configuration user quantity.

When the maximum number of connected users of the RRC is not greater than the number of configured users of the RRC, the base station's license is to be called in practical application, and not only the fluctuation of the working condition of the base station itself needs to be estimated, but also it should be ensured that the number of licenses of the base station itself can still be used by the base station after the license is called, so that the base station will not have a connection problem after the base station is called. Therefore, a greater amount of redundancy should be left than for the base station to be tuned in, i.e. the first coefficient should be smaller than the second coefficient.

Through setting of redundancy coefficients under different conditions, future loads and working conditions before and after adjustment are estimated, and it is ensured that the base station does not have corresponding connection faults after adjustment.

A grant number calculation unit 404 for obtaining the number of the first grants to be increased or decreased by calculating a ratio of the number of the RRC users to be increased or decreased to a predetermined dimension value of a first dimension; wherein the first permitted dimension is the first dimension;

an adjusting unit 405, configured to adjust a current RRC configuration parameter of the base station according to the number of the first grants that need to be increased or decreased; the adjusting includes increasing or decreasing a configuration parameter of the first license.

Firstly, the ratio of the RRC user amount to be increased or decreased to a predetermined dimension value of a first dimension is calculated by a permission amount calculation unit 404, so as to obtain the number of first permissions to be increased or decreased; the first allowable dimension is the first dimension, if the ratio is not an integer, then a corresponding rounding operation needs to be performed, for a reducible allowable quantity, the obtained ratio should be rounded down, and for an allowable quantity that needs to be increased, the obtained ratio should be rounded up. Then, the adjusting unit 405 adjusts the current RRC configuration parameter of the base station according to the number of the first grants that need to be increased or decreased; the adjusting includes increasing or decreasing a configuration parameter of the first license.

By converting the user amount into the allowable amount for allocation, the waste of resources can be avoided, the fault caused by the adjustment work can be prevented, and the effectiveness of the adjustment work can be ensured.

An example, the adjustment amount calculation module 43 is further configured to:

the adjusting unit 405 is specifically configured to:

For the base station that can subtract the grant, before performing the deployment, the adjustment amount calculation module 43 may obtain the reducible amount of the first grant by subtracting according to the configuration amount of the first grant and the actual usage amount of the first grant in the current configuration parameters of the base station, that is, obtain the first grant that the base station can actually provide for deployment. Then, the decrementable amount is compared with the aforementioned amount of the first grant to be decremented by the adjusting unit 405, and if the amount of the first grant to be decremented is not greater than the decrementable amount of the first grant, the current RRC configuration parameter of the base station is adjusted according to the amount of the first grant to be decremented.

By means of calculation with decrement, the base station with permission to be reduced at present is ensured to have enough permission for allocation, and corresponding failure or access failure caused by allocation work after allocation is avoided.

the adjusting unit 405 is further configured to:

The base station usually allocates more than one type of license, and when the corresponding user amount cannot be met after a certain license amount is called out completely, other licenses can be allocated to perform equivalent replacement. Through the adjustment amount calculating module 43, after the foregoing reducible amount calculation, if the number of first grants to be reduced is greater than the reducible amount of the first grants, for a second dimension other than the first dimension in the dimensions, the number of second grants to be reduced is obtained by calculating a ratio of the number of RRC users to be increased or reduced to a dimension value of the second dimension, and then, through the adjusting unit 405, the current RRC configuration parameter of the base station is adjusted according to the number of second grants to be reduced.

Through the conversion among different dimensions, the resources of the license can be fully utilized, the allocation algorithm is simplified, and the waste of the resources is avoided.

In one example, the number of the base stations is plural; the device further comprises:

a priority calibration module 44, configured to calibrate priorities of the multiple base stations according to the number of times of RRC connection establishment failures of the multiple base stations and the alarm information;

a user quantity obtaining module 41, configured to:

A priority calibration module 44, configured to calibrate the priorities of the multiple base stations according to the number of times of RRC connection establishment failures of the multiple base stations and the alarm information. The alarm information includes the permitted overuse and the corresponding base station information, in other words, according to the degree and duration of the two types of faults, the priority can be calculated and sequenced through an algorithm, and the execution of the wireless network resource allocation is optimized. Then, the user quantity obtaining module 41 obtains the maximum connection user quantity of the RRC for subsequent deployment for the base station with the highest priority without adjustment among the plurality of base stations.

The base station wireless resource allocation priority is calibrated through the fault type and the alarm information, and allocation work is carried out according to the priority, so that the wireless network resource allocation efficiency can be improved, and reasonable allocation of wireless network resources is realized. The embodiment provides a wireless network resource configuration device, including: a user quantity obtaining module, configured to obtain a maximum connection user quantity of radio resource control RRC of the base station; a configuration quantity obtaining module, configured to obtain a current number of RRC configured users of the base station according to a current RRC configuration parameter of the base station, where the current RRC configuration parameter of the base station includes an RRC-allowed configuration quantity and a dimension value corresponding to each dimension; the adjustment amount calculation module is used for calculating and obtaining the quantity of the RRC users needing to be increased or decreased according to the quantity of the RRC maximum connection users and the current quantity of the RRC configuration users of the base station; and adjusting the current RRC configuration parameters of the base station according to the quantity of the RRC users needing to be increased or decreased. And calculating the quantity of the RRC users to be adjusted according to the maximum RRC connection user quantity of the base station to be adjusted and the configuration parameters, and further obtaining the number of the allowed quantity to be adjusted so as to realize reasonable distribution of wireless network resources.

EXAMPLE five

Fig. 11 is a schematic structural diagram of an electronic device according to a fifth embodiment of the present application, and as shown in fig. 11, the electronic device includes:

a processor (processor)291, the electronic device further including a memory (memory) 292; a Communication Interface 293 and bus 294 may also be included. The processor 291, the memory 292, and the communication interface 293 may communicate with each other via the bus 294. Communication interface 293 may be used for the transmission of information. Processor 291 may call logic instructions in memory 294 to perform the methods of the embodiments described above.

Further, the logic instructions in the memory 292 may be implemented in software functional units and stored in a computer readable storage medium when sold or used as a stand-alone product.

The memory 292 is a computer-readable storage medium for storing software programs, computer-executable programs, such as program instructions/modules corresponding to the methods in the embodiments of the present application. The processor 291 executes the functional application and data processing by executing the software program, instructions and modules stored in the memory 292, so as to implement the method in the above method embodiments.

The memory 292 may include a program storage area and a data storage area, wherein the program storage area may store an operating system, an application program required for at least one function; the storage data area may store data created according to the use of the terminal device, and the like. Further, the memory 292 may include a high speed random access memory and may also include a non-volatile memory.

The embodiment of the present application further provides a computer-readable storage medium, in which computer-executable instructions are stored, and when the computer-executable instructions are executed by a processor, the computer-readable storage medium is configured to implement the method described in any embodiment.

Other embodiments of the present application will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. This application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the application and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the application being indicated by the following claims.

It will be understood that the present application is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the application is limited only by the appended claims.

Claims

1. A method for configuring wireless network resources, comprising:

calculating to obtain the quantity of the RRC users needing to be increased or decreased according to the quantity of the RRC maximum connection users and the current quantity of the RRC configuration users of the base station; and adjusting the current RRC configuration parameters of the base station according to the RRC user quantity needing to be increased or decreased.

2. The method of claim 1, wherein the calculating the number of RRC users to be increased or decreased according to the maximum RRC connection user number and the current number of RRC-configured users of the base station comprises:

3. The method of claim 2, wherein before obtaining the RRC estimated user amount by calculating a product of the redundancy factor and the RRC maximum connected user amount, further comprising:

4. The method of claim 1, wherein the adjusting the current RRC configuration parameters of the base station according to the quantity of RRC users to be increased or decreased comprises:

5. The method according to claim 4, wherein before adjusting the current RRC configuration parameters of the base station according to the quantity of RRC users to be increased or decreased if the quantity of RRC users is to be decreased, further comprising:

6. The method of claim 5, wherein after obtaining the reducible amount of the first grant by subtracting according to the configuration amount of the first grant and the actual usage amount of the first grant in the current configuration parameters of the base station, the method further comprises:

7. The method according to any of claims 1-6, wherein the number of base stations is plural; the method further comprises the following steps:

8. A wireless network resource configuration apparatus, comprising:

the adjustment amount calculation module is used for calculating and obtaining the quantity of the RRC users needing to be increased or decreased according to the quantity of the RRC maximum connection users and the current quantity of the RRC configuration users of the base station; and adjusting the current RRC configuration parameters of the base station according to the RRC user quantity needing to be increased or decreased.

9. The apparatus of claim 8, wherein the adjustment calculation module comprises:

10. The apparatus of claim 9, wherein the adjustment amount calculation module further comprises: a redundancy coefficient setting unit configured to:

11. The apparatus of claim 8, wherein the adjustment calculation module comprises:

12. The apparatus of claim 11, wherein the adjustment calculation module is further configured to:

the adjusting unit is specifically configured to:

13. The apparatus of claim 12, wherein the adjustment amount calculating module is further configured to:

14. The apparatus according to any of claims 8-13, wherein the number of base stations is plural; the device further comprises:

and the user quantity obtaining module is used for obtaining the maximum connection user quantity of the radio resource control RRC of the base station aiming at the base station which is not adjusted and has the highest current priority in the base stations.

15. An electronic device, comprising:

at least one processor; and

the memory stores instructions executable by the at least one processor to enable the at least one processor to perform the method of any one of claims 1-7.

16. A computer-readable storage medium having computer-executable instructions stored therein, which when executed by a processor, are configured to implement the method of any one of claims 1-7.