WO2020037493A1 - Data processing method and server - Google Patents

Abstract

Provided by embodiments of the present application are a data processing method and a server, which are used for a server calculating an uplink experience blocking index (EBI) and uplink experience blocking traffic (EBT) of each grid, and a downlink EBI and downlink EBT of each grid among at least two grids of a target cell. The server calculates uplink traffic of each grid and downlink traffic of each grid among the at least two grids, wherein the at least two grids comprise all of the areas covered by the target cell, and areas that are comprised in each grid and that correspond to the target cell do not overlap; the server calculates uplink EBT of each grid and downlink EBT of each grid; the server calculates an uplink EBI of each grid according to the uplink traffic of each grid and the uplink EBT of each grid, and calculates a downlink EBI of each grid according to the downlink traffic of each grid and the downlink EBT of each grid. The method provided by the present embodiments may be applied to a communication system, such as V2X, LTE-V, V2V, the Internet of Vehicles, MTC, IoT, LTE-M, M2M, the Internet of Things, and so on.

Description

Data processing method and server Technical field

The present application relates to communication technologies, and in particular, to a data processing method and a server.

Background technique

With the rapid development of data services, data service traffic is growing rapidly, so how to measure the user experience in data services is very important.

At present, the experience blocking EBI model is used to calculate the experience blocking index (EBI) EBI and experience blocking traffic (EBT) of each cell in the network through traffic statistics. The EBI of each cell and the EBT of each cell are displayed on a map to visually display the distribution of experience blockages.

However, because the EBI model currently calculates cell-level EBI and cell-level EBT, and the statistical granularity of cell-level EBI and cell-level EBT is relatively coarse, it is difficult to accurately display the specific experience congestion inside each cell, which cannot meet the current There is a need for the network to monitor the internal blockage of the cell and network analysis.

Summary of the Invention

An embodiment of the present application provides a data processing method and a server, configured to calculate an uplink EBI, an uplink EBT, and a downlink EBI and a downlink EBT of each grid of the at least two grids. The two grids include the entire area covered by the target cell. The areas corresponding to the target cell included in each of the at least two grids do not overlap. The grid and the target cell form a two-dimensional matrix, so that each grid is obtained. The grid's experience congestion data is convenient to analyze the degree of experience congestion within the target cell area and the traffic loss caused by experience congestion, and it is convenient to monitor and quantitatively evaluate the experience congestion situation of the target cell.

A first aspect of the embodiments of the present application provides a data processing method, which includes:

In a communication network, a user establishes a connection with a base station in a target cell through a terminal device, and performs data service transmission and the like. In the communication process, network traffic such as data services will generate corresponding traffic. In the case of network congestion, traffic transmission will be suppressed, that is, when the current transmission rate does not reach the desired rate, the user can experience the congestion in the corresponding period according to the expected rate minus the current rate. flow. In the network, the entire area covered by the target cell is divided into at least two grids, and the areas corresponding to the target cell included in each grid of the at least two grids do not overlap, and the server may calculate the at least two The uplink traffic of each grid in the grid and the amount of downlink traffic of each grid; the server then calculates the uplink EBT of each grid in the at least two grids and the downlink EBT of each grid, and then calculates Calculate the uplink EBI of each grid and the uplink EBT of each grid, and calculate the downlink EBI of each grid based on the downlink traffic of each grid and the downlink EBT of each grid. .

In this embodiment, the server calculates the uplink EBT and uplink EBI of each grid in at least two grids of the target cell, and the downlink EBT of each grid and the downlink EBI of each grid, the at least two grids. Including all areas of the target cell, and each grid including the corresponding area of the target cell does not overlap. Therefore, the grid-level EBI calculated by this application has a finer granularity than the existing cell-level EBI, which is convenient for analyzing the target. The degree of experience congestion within the cell range and the loss of traffic due to network congestion facilitate monitoring and quantitative evaluation of the experience congestion situation of the target cell.

In a possible implementation manner, each grid may include a target area corresponding to each of the N cells, where N is a positive integer; the server calculates the uplink traffic and The downlink traffic of each grid may include: first, the server may calculate the uplink traffic weight of the target area corresponding to each cell in the N cells and the downlink traffic weight of the target area corresponding to each cell; then, the server may The uplink traffic weight of the target area corresponding to each cell and the uplink traffic corresponding to each cell are used to calculate the uplink traffic of the target area corresponding to each cell, and the downlink traffic weight of the target area corresponding to each cell and the The downlink traffic corresponding to each cell calculates the downlink traffic of the target area corresponding to each cell; finally, the server can calculate the uplink traffic of each grid based on the uplink traffic of the target area corresponding to each cell, and according to the The downlink traffic of the target area corresponding to each cell is used to calculate the downlink traffic of each grid. In this possible implementation manner, a specific server is provided to calculate the uplink traffic of each grid and the downlink traffic of each grid. In practical applications, it improves the implementability and practicability of the solution. .

In another possible implementation manner, the server calculates the uplink traffic weight of the target area corresponding to each cell in the N cells and the downlink traffic weight of the target area corresponding to each cell may include: first, the server determines N Number of measurement reports (MR) of each cell in each cell; then the server determines that the number of MRs of each cell is greater than or equal to a preset threshold, and the server can then calculate the MR account of the target area corresponding to each cell Ratio and the uplink experience rate of the target area corresponding to each cell to calculate the uplink traffic weight of the target area corresponding to each cell, and according to the MR ratio of the target area corresponding to each cell and the target corresponding to each cell The downlink experience rate of the area calculates the downlink traffic weight of the target area corresponding to each cell. In this possible implementation manner, the server calculates the traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the experience rate, and provides a specific calculation of the target corresponding to each cell. The calculation method of regional traffic weights improves the implementability and integrity of the solution in practical applications.

In another possible implementation manner, the server calculates the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the uplink experience rate of the target area corresponding to each cell. Calculating the downlink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the downlink experience rate of the target area corresponding to each cell may include: First, the server may determine the The MR ratio of the target area corresponding to each cell, the uplink experience rate of the target area corresponding to each cell, and the downlink experience rate of the target area corresponding to each cell; then the server may The MR ratio and the uplink experience rate of the target area corresponding to each cell are used to calculate the total uplink grid weight of each cell, and according to the MR ratio of the target area corresponding to each cell in the N cells, and each The downlink experience rate of the target area corresponding to the cell calculates the total downlink grid weight of each cell; service The uplink traffic weight of the target area corresponding to each cell may be calculated according to the MR ratio of the target area corresponding to each cell, the uplink experience rate of the target area corresponding to each cell, and the total uplink grid weight, and according to The MR ratio of the target area corresponding to each cell, the downlink experience rate of the target area corresponding to each cell, and the total downlink grid weight are used to calculate the downlink traffic weight of the target area corresponding to each cell. In this possible implementation manner, another specific server is provided to calculate the uplink traffic weight and the downlink traffic weight of the target area corresponding to each cell. In practical applications, the solution's realizability and Diversity.

In another possible implementation manner, the server calculates the uplink traffic weight of the target area corresponding to each cell and the downlink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell. : First, the server can determine the MR ratio of the target area corresponding to each cell, and then the server can calculate the total uplink grid weight of each cell and the downlink grid of each cell according to the MR of the target area corresponding to each cell. Grid total weight; then the server can calculate the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the total uplink grid weight, and according to the target corresponding to each cell The MR ratio of the area and the total weight of the downlink grid calculate the downlink traffic weight of the target area corresponding to each cell. In this possible implementation manner, another specific calculation method for calculating a traffic weight of a target area corresponding to each cell is provided. In practical applications, the realizability and diversity of the solution are improved.

In another possible implementation manner, the server calculates the uplink traffic weight of the target area corresponding to each cell in the N cells and the downlink traffic weight of the target area corresponding to each cell may include: first, the server may determine the The number of MRs of each cell in the N cells; then the server determines that the number of MRs is greater than zero and less than a preset threshold; then, the server can calculate the MR of each cell according to the MR ratio of the target area corresponding to each cell The total uplink grid weight and the total downlink grid weight of each cell; the server may calculate the corresponding value of each cell according to the target area MR ratio corresponding to each cell and the total uplink grid weight and total downlink grid weight. The uplink traffic weight of the target area and the downlink traffic weight of the target area corresponding to each cell. In this possible implementation manner, the server calculates the traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell, and provides another specific calculation of the target area corresponding to each cell. The calculation method of the traffic weight improves the realizability and diversity of the scheme in practical applications.

In another possible implementation manner, each grid includes a target area corresponding to each of the N cells, where N is a positive integer; and the server calculates uplink traffic of each of the at least two grids. The downlink traffic of each grid may include: First, the server determines the total number of grids corresponding to each cell in the N cells, and the total number of grids is located in all areas corresponding to each cell. The number of grids of the grid; then, based on the uplink traffic of each cell and the total number of grids corresponding to each cell, calculate the uplink traffic of the target area corresponding to each cell, and according to each cell And the total number of grids corresponding to each cell to calculate the downlink traffic of the target area corresponding to each cell; and then calculate the uplink of each grid based on the uplink traffic of the target area corresponding to each cell And calculate the downlink traffic of each grid according to the downlink traffic of the target area corresponding to each cell. In this possible implementation manner, another calculation manner in which the server calculates the uplink traffic of each grid and the downlink traffic of each grid is provided. In practical applications, the diversity and practicability of the solution are improved.

In another possible implementation manner, before the server determines the total number of grids corresponding to each of the N cells, the method may further include: the server determines that the number of MRs of each cell is zero. In this possible implementation manner, before using the calculation method according to the average distribution of traffic, if it is determined that the number of MRs is zero, the server selects the calculation method according to the average distribution of traffic, thereby realizing the calculation of the traffic of each grid .

In another possible implementation manner, each grid may include a target area corresponding to each of the N cells, where N is a positive integer; the server calculates an uplink EBT of each grid and each grid The downlink EBT may include: first, the server may calculate the uplink EBT weight of the target area corresponding to the N cells and the downlink EBT weight of the target area corresponding to each cell; when the uplink EBT weight is not zero, the server may The uplink EBT weight of the target area corresponding to each cell and the total uplink EBT of each cell calculate the uplink EBT of the target area corresponding to each cell; the server may calculate the uplink EBT of the target area corresponding to each cell The uplink EBT of each grid; when the downlink EBT weight is not zero, the server calculates the corresponding value of each cell according to the downlink EBT weight of the target area corresponding to each cell and the total downlink EBT of each cell The downlink EBT of the target area; the server calculates the downlink EBT of each grid according to the downlink EBT of the target area corresponding to each cell. In this possible implementation manner, a specific server is provided for calculating the uplink EBT of each grid and the downlink EBT of each grid. In actual applications, the solution's realizability and Practicality.

In another possible implementation manner, the server calculating the uplink EBT weight of the target area corresponding to each cell in the N cells and the downlink EBT weight of the target area corresponding to each cell may include: the server may calculate the corresponding per cell When the uplink restoration EBT in the target area of the target area and the downlink restoration EBT in the target area corresponding to each cell are not zero, the server may perform the uplink restoration EBT in the target area corresponding to each cell and the The uplink total restoration EBT of each cell calculates the uplink EBT weight of the target area corresponding to each cell; when the downlink restoration EBT is not zero, the server according to the downlink restoration EBT of the target area corresponding to each cell and the each The downlink total restoration EBT of the cell calculates the downlink EBT weight of the target area corresponding to each cell. In this possible implementation manner, a specific calculation is provided for calculating the uplink EBT weight of the target area corresponding to each cell and the downlink EBT weight of the target area corresponding to each cell. In practical applications, the implementation of the solution is improved. Sex and practicality.

In another possible implementation manner, the server calculating the uplink restoration EBT of the target area corresponding to each cell and the downlink restoration EBT of the target area corresponding to each cell may include: first, the server may determine that the Whether the uplink experience rate of the target area is greater than or equal to the first target experience rate, and whether the downlink experience rate of the target area corresponding to each cell is greater than or equal to the second target experience rate; if so, the server determines The uplink restore EBT of the target area is zero, and it is determined that the downlink restore EBT of the target area corresponding to each cell is zero; if not, the server may use the uplink experience rate of the target area corresponding to each cell, the first The target experience rate and the uplink traffic of the target area corresponding to each cell calculate the uplink restored EBT of the target area corresponding to each cell, and according to the downlink experience rate of the target area corresponding to each cell, the second target experience rate, and Calculate the downlink traffic of the target area corresponding to each cell Downstream region should target the reduction EBT. In this possible implementation manner, a specific method is provided for a specific server to calculate an uplink restoration EBT of a target area corresponding to each cell and a downlink restoration EBT of a target area corresponding to each cell. In practical applications, it improves The realization and practicability of the scheme.

In another possible implementation manner, when the uplink EBT weight is zero and the downlink EBT weight is zero; the method may further include: the server may calculate the MR according to the MR ratio of the target area corresponding to each cell The uplink EBT weight of the target area corresponding to each cell and the downlink EBT weight of the target area corresponding to each cell; then, the server may calculate the corresponding per cell based on the uplink EBT weight and the total uplink EBT of each cell. The uplink EBT of the target area of the target, and the downlink EBT of the target area corresponding to each cell according to the downlink EBT weight and the total downlink EBT of each cell; finally, the server may perform the uplink of the target area corresponding to each cell EBT calculates the uplink EBT of each grid, and calculates the downlink EBT of each grid according to the downlink EBT of the target area corresponding to each cell. In this possible implementation manner, when the uplink EBT weight is zero, and the downlink EBT weight is zero, a specific server is provided to calculate the uplink EBT of each grid and the specific calculation method of the downlink EBT of each grid. In practice, it improves the implementability and integrity of the solution.

In another possible implementation manner, when the uplink EBT weight is zero and the downlink EBT weight is zero; the method may further include: first, the server may determine the total number of grids corresponding to each cell, The total number of grids is the number of grids of the grids in which all areas corresponding to each cell are located; then, the server may calculate the number of cells based on the total uplink EBT of each cell and the total number of grids. The uplink EBT of the target area corresponding to each cell, and the downlink EBT of the target area corresponding to each cell are calculated according to the total downlink EBT of each cell and the total number of the grid. In this possible implementation manner, when the uplink EBT weight is zero and the downlink EBT weight is zero, another specific server is provided to calculate specific uplink EBT of each grid and specific calculation of downlink EBT of each grid. The method, in practical applications, improves the diversity and practicability of the scheme.

The second aspect of the embodiments of the present application provides a server. The server has a function for realizing the server behavior of the first aspect. The function may be implemented by hardware, or may be implemented by hardware executing corresponding software. The hardware or software includes one or more modules corresponding to the above functions.

A third aspect of the embodiments of the present application provides a server. The server includes: a processor, a memory, an input-output device, and a bus; the processor, the memory, and an input-output device are respectively connected to the bus, and a computer is stored in the memory. Instructions; when the processor executes the computer instructions in the memory, the memory stores the computer instructions; when the processor executes the computer instructions in the memory, the processor is configured to implement any implementation manner as in the first aspect.

A fourth aspect of the embodiments of the present application provides a chip system. The chip system includes a processor, and is configured to support a network device to implement the functions involved in the first aspect, for example, sending or processing data involved in the foregoing method. And / or information. In a possible design, the chip system further includes a memory, and the memory is configured to store program instructions and data necessary for the network device. The chip system may be composed of chips, and may also include chips and other discrete devices.

A fifth aspect of the embodiments of the present application provides a computer program product including instructions, which is characterized in that when it is run on a computer, the computer is caused to execute an implementation manner as in any of the first aspect.

A sixth aspect of the embodiments of the present application provides a computer-readable storage medium, which is characterized by including instructions, and when the instructions are run on a computer, the computer is caused to execute any implementation manner as in the first aspect.

In the technical solution provided in the embodiment of the present application, the server calculates the uplink traffic of each grid in at least two grids and the downlink traffic of each grid, the at least two grids include all areas of the target cell, and the The areas corresponding to the target cells included in each grid do not overlap; then the server calculates the uplink EBT of each grid and the downlink EBT of each grid; the server can calculate the uplink traffic of each grid and each The uplink EBT of the grid calculates the uplink EBI of each grid and the downlink EBI of each grid is calculated based on the downlink traffic of each grid and the downlink EBT of each grid. In the technical solution of the present application, the server calculates the uplink EBT and uplink EBI of each grid in at least two grids of the target cell, and the downlink EBT of each grid and the downlink EBI of each grid, the at least two The grid includes the entire area of the target cell, and the corresponding area of each grid including the target cell does not overlap. Therefore, the grid-level EBI calculated through this application has a finer granularity than the existing cell-level EBI, which is convenient for analyzing the degree of experience congestion within the target cell area and the traffic loss caused by network congestion, and is convenient for monitoring and quantitative evaluation. The target cell experiences congestion.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram of an embodiment of a data processing method according to an embodiment of the present application;

2 is a schematic diagram of another embodiment of a data processing method according to an embodiment of the present application;

3 is a schematic diagram of another embodiment of a data processing method according to an embodiment of the present application;

4 is a schematic diagram of another embodiment of a data processing method according to an embodiment of the present application;

5 is a schematic diagram of another embodiment of a data processing method according to an embodiment of the present application;

6 is a schematic diagram of another embodiment of a data processing method according to an embodiment of the present application;

7 is a schematic diagram of another embodiment of a data processing method according to an embodiment of the present application;

8 is a schematic structural diagram of a server in an embodiment of the present application;

FIG. 9 is another schematic structural diagram of a server in an embodiment of the present application.

detailed description

In the following, the technical solutions in the embodiments of the present application will be clearly and completely described with reference to the drawings in the embodiments of the present application. Obviously, the described embodiments are only a part of the embodiments of the present application, but not all of the embodiments.

The terms "first", "second", "third", "fourth", and the like (if present) in the description and claims of the present application and the above-mentioned drawings are used to distinguish similar objects, and need not be used For describing a particular order or sequence. It should be understood that the data used in this way are interchangeable where appropriate, so that the embodiments described herein can be implemented in an order other than what is illustrated or described herein. Furthermore, the terms "including" and "having" and any of their variations are intended to cover non-exclusive inclusions, for example, a process, method, system, product, or device that includes a series of steps or units need not be limited to those explicitly listed Those steps or units may instead include other steps or units not explicitly listed or inherent to these processes, methods, products or equipment.

An embodiment of the present application provides a data processing method and a server, for the server to calculate an uplink EBI of each grid of the at least two grids, an uplink EBT of each grid, and a downlink EBI of each grid, each Downlink EBT of three grids, the at least two grids include the entire area covered by the target cell, the areas corresponding to the target cell included in each grid of the at least two grids do not overlap, and the grid and the target cell form one A two-dimensional matrix, so as to obtain the experience congestion data of each grid, which is convenient for analyzing the degree of experience congestion within the target cell area and the traffic loss caused by experience congestion, and for monitoring and quantitatively evaluating the experience congestion of the target cell.

In the following, from a server perspective, the data processing method in the embodiment of the present application is received. Referring to FIG. 1, an embodiment of the data processing method in the embodiment of the present application includes:

101. The server calculates uplink traffic of each grid in at least two grids and downlink traffic of each grid.

In a communication network, a user establishes a connection with a base station in a target cell through a terminal device, and then performs data service transmission. During the communication process, network transmission such as data service will generate corresponding traffic. In the case of network congestion, Traffic transmission will be suppressed, that is, the current traffic transmission rate does not reach the expected rate. At this time, the corresponding traffic loss is determined according to the expected rate minus the current traffic transmission rate, that is, EBT; in the network, the target is The area corresponding to the cell is divided into grids. Each grid can include the target area corresponding to each cell in N cells, and N is a positive integer, that is, the area corresponding to each grid can be each cell in multiple cells. The target area of each cell may also be a part of a single cell, which is not limited here. In the embodiment of the present application, the server may calculate the uplink traffic of each grid of the at least two grids and the downlink traffic of each grid, where the at least two grids include all areas covered by the target cell, and The areas corresponding to the target cells included in each grid do not overlap. It can be understood that the at least two grids include the entire area of the target cell, and the at least two grids can also include partial areas of other cells. Each grid includes a corresponding area of the target cell, and this part corresponds to The areas do not overlap, so that for the target cell, the server will calculate the EBI of at least two different areas in the target cell, instead of the individual cell-level EBI.

In this embodiment, each time the server calculates the uplink EBI of each grid of the target cell and the downlink EBI of each grid, it can be calculated once a day, or it can be calculated once within another preset time period, which is not limited in this application. .

It should be noted that the server calculates the uplink traffic of each grid and the downlink traffic of each grid. The corresponding calculation method can be determined according to the number of MRs of each of the N cells. 3 and Figure 4 to introduce in detail:

First, please refer to FIG. 2. FIG. 2 shows the server calculating the uplink traffic of each grid and the downlink traffic of each grid when the server determines that the number of MRs of each of the N cells is greater than a preset threshold. The specific process includes:

201. The server obtains the number of MRs of each of the N cells.

During the network communication, the user equipment will report the MR to the base station during the communication. The server may count the number of MRs sent by the user equipment received by the base station and other devices in each of the N cells.

202. The server determines that the number of MRs is greater than a preset threshold.

Because the number of MRs in each cell can reflect the number of user accesses to a certain extent, when the number of MRs is greater than a preset threshold, the server can determine that the user equipment experience rate in the traffic statistics data is trusted data, and then the server can determine the The two parameters of the reference experience rate and the MR ratio in the traffic weight are subsequently calculated; wherein the preset threshold is a threshold of the confidence of the MR rate data. Among them, the MR data includes the location information of each grid and the coverage information of each cell, and the traffic statistics data includes the uplink traffic (excluding small packet traffic) and downlink traffic (excluding the last transmission time interval) of the corresponding cell, LastTTI) traffic), total uplink EBT, total downlink EBT, uplink experience rate and downlink experience rate of the corresponding cell, etc .;

203. The server calculates the total uplink grid weight of each cell according to the MR ratio of the target area corresponding to each cell in the N cells and the uplink experience rate of the target area corresponding to each cell, and according to the each The MR ratio of the target area corresponding to the cell and the downlink experience rate of the target area corresponding to each cell calculate the total downlink grid weight of each cell.

The server obtains the total number of MRs of each cell from the MR data, and the number of MRs of the target area corresponding to each cell; and the uplink experience rate of the target area corresponding to each cell from the traffic statistics data, and the each cell The downlink experience rate of the corresponding target area. The server may then divide the number of MRs in the target area corresponding to each cell by the total number of MRs in each cell to obtain the MR ratio of the target area corresponding to each cell. Then, the server multiplies the MR ratio of the target area corresponding to each cell by the uplink experience rate of the target area corresponding to each cell, and obtains the uplink grid weight of the target area corresponding to each cell. Multiplying the MR ratio of the target area corresponding to the cell by the downlink experience rate of the target area of each cell to obtain the downlink grid weight of the target area corresponding to each cell. Then, the uplink grid weights of all corresponding target areas of each cell are added, and the downlink grid weights of all corresponding target areas of each cell are added to obtain the total uplink grid weight of each cell and each The total downlink grid weight of the cell. The following table describes the results obtained by the above calculation process:

Please refer to Table 1. Table 1 is a cell grid comparison table obtained by the server. The grid can be associated with the cell through this table. In Table 1, the area in cell cell1 is located in grids Grid1 to Grid10, then It can be known that if cell1 is the target cell for which the grid EBI is to be calculated, it can be known that the server must calculate the EBI of grids Grid1 to Grid10 in order to complete the calculation of the EBI of the grid including the entire area of the target cell; Each includes a corresponding target area for cell1.

As can be seen from Table 1, for example, Grid1 includes target areas corresponding to each of the five cells of cell1 to cell5. As can be seen from the table, the MR ratios of the target areas corresponding to each of the five cells included in Grid1 are It is 0.4, 0.1, 0.1, 0.2, and 0. Grid2 includes the target area corresponding to each of the five cells of cell1 to cell5, and the MR ratios are 0.1, 0, 0.1, 0.3, and 0, respectively. Among them, the MR ratio of each cell is 1.

Table 1

MR ratio	Grid1	Grid2	Grid3	Grid4	Grid5	Grid6	Grid7	Grid8	Grid9	Grid10	Sum
Cell1	0.4	0.1	0.1	0.1	0	0.2	0	0	0	0.1	1
Cell2	0.1	0	0.2	0.3	0.2	0	0.1	0.1	0	0	1
Cell3	0.1	0.1	0.2	0.1	0.2	0.1	0.1	0.1	0	0	1
Cell4	0.2	0.3	0.1	0.1	0.1	0	0.2	0	0	0	1
Cell5	0	0	0.4	0.1	0.1	0.1	0.1	0.1	0.05	0.05	1

Table 2 shows the downlink experience rate of the target area corresponding to each of the five cells included in Grid1 to Grid10 obtained by the server. The downlink traffic is the remaining downlink traffic from which the LastTTI traffic has been removed, and the EBT is the downlink of each cell. Total EBT. For example, it can be known from Table 1 that the downlink experience rate of the target area corresponding to Grid1 including cell1 is 1, and the downlink experience rate of the target area corresponding to Grid1 including cell2 is 3.

Table 2

Then from the above Tables 1 and 2, it can be known that the corresponding areas in all the areas of cell1 are located in Grid1 to Grid10 respectively; and the total uplink grid weight of each cell = sum (grid (i) .MR ratio * grid (i). Uplink experience rate), the total downlink grid weight of each cell = sum (grid (i) .MR ratio * grid (i) .downlink experience rate), where i is a positive integer. Combining Tables 1 and 2, the following table 3 shows the calculated grid weights of the target area corresponding to each of the N cells included in each grid. See Table 3:

table 3

It can be known from Table 3 that the corresponding areas in all the areas of cell1 are located in Grid1 to Grid10, that is, the total weight of the downlink grid of cell1 = 0.4 + 0.3 + 0.4 + 0.6 + 0 + 0.32 + 0 + 0 + 0 + 0.5 = 2.52.

204. The server calculates the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell, the uplink experience rate of the target area corresponding to each cell, and the total uplink grid weight. The MR ratio of the target area corresponding to each cell, the downlink experience rate of the target area corresponding to each cell, and the total downlink grid weight are used to calculate the downlink traffic weight of the target area corresponding to each cell.

After the server determines the total uplink grid weight and the total downlink grid weight, it can multiply the MR ratio of the target area corresponding to each cell by the uplink experience rate of the target area corresponding to each cell to obtain the target corresponding to each cell. The uplink grid weight of the area; and multiplying the MR ratio of the target area corresponding to each cell by the downlink experience rate of the target area corresponding to each cell to obtain the downlink grid weight of the target area corresponding to each cell; then the server Then divide the uplink grid weight of the target area corresponding to each cell by the total uplink grid weight to obtain the uplink traffic weight of the target area corresponding to each cell, and the downlink grid of the target area corresponding to each cell The weight is divided by the total weight of the downlink grid to obtain the downlink traffic weight of the target area corresponding to each cell. The specific formula is the grid (i) of the target area corresponding to each cell. The uplink traffic weight = (grid (i). MR ratio * grid (i). Uplink experience rate) / total uplink grid weight, The grid (i). Downlink traffic weight of the target area corresponding to each cell = (grid (i) .MR ratio * grid (i). Downlink experience rate) / total downlink grid weight; the following table data To describe this step, please refer to Table 4. Table 4 is a schematic table of the calculation results of downlink traffic weights:

Table 4

Traffic weight	Grid1	Grid2	Grid3	Grid4	Grid5	Grid6	Grid7	Grid8	Grid9	Grid10	Sum
Cell1	16%	12%	16%	twenty four%	0%	13%	0%	0%	0%	20%	100%
Cell2	10%	0%	8%	19%	27%	0%	20%	17%	0%	0%	100%
Cell3	6%	17%	17%	1%	29%	12%	15%	2%	0%	0%	100%
Cell4	twenty three%	43%	2%	6%	9%	0%	17%	0%	0%	0%	100%
Cell5	0%	0%	13%	14%	1%	9%	19%	19%	12%	14%	100%

It can be known from Tables 3 and 4 that, for example, the downstream traffic weight of the target area located in Grid1 in cell1 = (0.4 / 2.52) * 100% = 16%; the downstream traffic weight of the target area located in Grid2 in cell2 = (0.3 / 3.01) * 100% = 10%.

205: The server calculates the uplink traffic of the target area corresponding to each cell according to the uplink traffic weight of the target area corresponding to each cell and the total uplink traffic of each cell, and according to the downlink traffic weight and the total downlink of each cell The flow calculates the downlink flow of the target area corresponding to each cell.

The server can multiply the uplink traffic weight of the target area corresponding to each cell by the total uplink traffic of the cell to obtain the uplink traffic of the target area corresponding to each cell; the specific formula can be: grid (i). Uplink traffic = cell Total uplink traffic * (grid (i). Upstream traffic weight), grid (i). Downstream traffic = total downlink cell traffic * (Grid (i). Downstream traffic weight); please refer to Table 5 below, Table 5 Take the calculated downlink traffic of the target area corresponding to each cell of each grid as an example:

table 5

From Table 5, it can be seen that the downlink traffic in the target area of Grid1 in cell1 = 12 * 0.16 = 1.9, the downlink traffic in the target area of Grid1 in cell2 = 10 * 0.1 = 1, and the downlink traffic in the target area of Grid1 in cell3 = 18 * 0.06 = 1, the downlink traffic of the target area in Grid1 in cell4 = 8 * 0.23 = 1.8, and the downlink traffic of the target area in Grid1 in cell5 = 15 * 0 = 0.

206. The server calculates the uplink traffic of each grid according to the uplink traffic of the target area corresponding to each cell, and calculates the downlink traffic of each grid according to the downlink traffic of the target area corresponding to each cell.

The server calculates the uplink traffic of the target area corresponding to each of the N cells and the downlink traffic of the target area corresponding to each of the N cells. Then the server can compare the uplink traffic of the target area corresponding to each cell. Add the uplink traffic of each grid, and add the downlink traffic of the target area corresponding to each cell to obtain the downlink traffic of each grid. For example, the downlink traffic of Grid1 = 1.9 + 1 + 1 + 1.8 + 0 = 5.7.

Please refer to FIG. 3. FIG. 3 shows that when the server determines that the number of MRs of each of the N cells is greater than zero and less than the preset threshold, the server calculates the uplink traffic of each grid and the downlink traffic of each grid. The specific process includes:

301. The server obtains the number of MRs of each of the N cells.

Step 301 is similar to step 201 in FIG. 2 described above, and details are not described herein again.

302. The server determines that the number of MRs is greater than zero and less than a preset threshold.

Because the number of MRs in each cell can reflect the number of current users, when the number of MRs in each cell is greater than zero and less than a preset threshold, the server can not trust the user device's experience rate in the MR data, so the server can When determining the subsequent calculation of the traffic weight, refer to only the MR ratio for calculation. The preset threshold is a threshold of the confidence of the MR rate data.

303. The server calculates the total uplink grid weight of each cell and the total downlink grid weight of each cell according to the MR ratio of each cell in the N cells.

The server may determine the total number of MRs of each cell and the number of MRs of the target area corresponding to each cell from the acquired MR data, and then divide the number of MRs of the target area corresponding to each cell by the The total number of MRs to obtain the MR ratio of the target area corresponding to each cell; then the server adds the MR ratios of all corresponding target areas of each cell to obtain the total uplink grid weight and downlink grid of each cell. The total weight of the grid, the specific formula is: the total uplink grid weight of each cell = sum (grid (i) .MR ratio), the total downlink grid weight of each cell = sum (grid (i) .MR) Ratio), combined with Table 1, we can get Table 6:

Table 6

Grid weights	Grid1	Grid2	Grid3	Grid4	Grid5	Grid6	Grid7	Grid8	Grid9	Grid10	Sum
Cell1	0.4	0.1	0.1	0.1	0	0.2	0	0	0	0.1	1
Cell2	0.1	0	0.2	0.3	0.2	0	0.1	0.1	0	0	1
Cell3	0.1	0.1	0.2	0.1	0.2	0.1	0.1	0.1	0	0	1
Cell4	0.2	0.3	0.1	0.1	0.1	0	0.2	0	0	0	1
Cell5	0	0	0.4	0.1	0.1	0.1	0.1	0.1	0.05	0.05	1

It can be known from Table 6 that the total uplink grid weight of cell1 is equal to the total downlink downlink weight = 0.4 + 0.1 + 0.1 + 0.1 + 0.2 + 0.1 = 1.

304. The server calculates the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the total uplink grid weight, and according to the MR ratio of the target area corresponding to each cell and The downlink grid total weight calculates a downlink traffic weight of a target area corresponding to each cell.

The server may divide the MR ratio of the target area corresponding to each cell by the total weight of the uplink grid to obtain the uplink traffic weight of the target area corresponding to each cell and the MR ratio of the target area corresponding to each cell. Divide the total weight of the downlink grid to obtain the downlink traffic weight of the target area corresponding to each cell; the uplink traffic weight of the target area corresponding to each cell is: grid (i). Uplink traffic weight = (grid (i) .MR ratio) / total uplink grid weight. The downlink traffic weight of the target area corresponding to each of the N cells is: grid (i). Downstream traffic weight = (grid (i). MR ratio) / downlink grid total weight; for example, cell1 is located in the target area corresponding to Grid1 and the uplink traffic weight is 0.4 / 1 = 0.4.

305: The server calculates the uplink traffic of the target area corresponding to each cell according to the uplink traffic weight of the target area corresponding to each cell and the total uplink traffic of each cell, and according to the downlink traffic weight and the downlink of each cell The total traffic is used to calculate the downlink traffic in the target area corresponding to each cell.

The server may multiply the weight of the uplink target traffic corresponding to each cell by the total uplink traffic corresponding to each cell to obtain the uplink traffic of the target area corresponding to each cell; and the downlink of the target area corresponding to each cell The traffic weight is multiplied by the total downlink traffic of each cell to obtain the downlink traffic of the target area corresponding to each cell. An example of the downlink traffic of the target area corresponding to each cell calculated by the server is shown in Table 7 below:

Table 7

It can be known from Table 7 that the downlink traffic corresponding to the target area corresponding to each cell of each grid is shown in Table 7. For example, the uplink traffic of cell1 located in the target area corresponding to Grid1 is 4.8.

306. The server calculates the uplink traffic of each grid according to the uplink traffic of the target area corresponding to each cell, and calculates the downlink traffic of each grid according to the downlink traffic of the target area corresponding to each cell.

The server calculates the uplink traffic of the target area corresponding to each cell and the downlink traffic of the target area corresponding to each cell, and then the server can add the uplink traffic of the target area corresponding to each cell to obtain the uplink traffic of each grid. The downlink traffic of each grid is obtained by adding the downlink traffic of the target area corresponding to each cell. For example, the downlink traffic of Grid1 = 4.8 + 1 + 1.8 + 1.6 + 0 = 9.2.

Please refer to FIG. 4. FIG. 4 is a specific process of calculating the uplink traffic of each grid and the downlink traffic of each grid when the server determines that the number of MRs of each of the N cells is zero, including: :

401. The server obtains the number of MRs of each of the N cells.

Step 401 is similar to step 201 in FIG. 2 described above, and details are not described herein again.

402. The server determines that the number of MRs is zero.

Because the number of MRs in each cell can reflect the number of user accesses to a certain extent, when the server can determine that the number of MRs is zero, the server can determine the subsequent calculation of the uplink traffic of each grid and the downlink traffic of each grid. Calculations.

403. The server determines the total number of grids corresponding to each cell in the N cells.

The server may determine the total number of grids corresponding to each cell in the N cells of each grid, where the total number of grids is the total number of grids in which the corresponding area of each cell is located. For example, from the cell grid comparison table in Table 1, it can be known that the total number of grids in which all areas of cell 1 are located is 10, that is, the grid in the area of cell1 in the first row of table 1 includes Grid1 to Grid10. , So the total number of grids is 10.

404. The server calculates the uplink traffic of the target area corresponding to each cell according to the total uplink traffic of each cell and the total number of grids corresponding to each cell, and according to the total downlink traffic of each cell and each cell's corresponding The total number of grids is used to calculate the downlink traffic of the target area corresponding to each cell.

The server may divide the total uplink traffic of each cell by the total number of grids corresponding to each cell, obtain the uplink traffic of the target area corresponding to each cell, and divide the total downlink traffic of each cell by each The total number of grids corresponding to the cells, to obtain the downlink traffic of the target area corresponding to each cell. For example, if all areas of cell1 are located in 10 grids, and the total downlink traffic of cell1 is 12, then it can be determined that the downlink traffic of the target area corresponding to cell1 is included in Grid1 = 12/10 = 1.2.

405. The server calculates the uplink traffic of each grid according to the uplink traffic of the target area corresponding to each cell, and calculates the downlink traffic of each grid according to the downlink traffic of the target area corresponding to each cell.

Step 405 is similar to step 306 in FIG. 3 described above, and details are not described herein again.

It should be noted that each of the methods for calculating the grid's uplink traffic and grid's downlink traffic in Figure 2, Figure 3, and Figure 4 can be used in combination. The calculation method of the downlink traffic of the corresponding area may be: when the MR number of cell1 is greater than a preset threshold, the server may use the calculation method of FIG. 2 to calculate it; and for the uplink traffic of cell2 in the corresponding area of Grid1 and cell2 The calculation method of the downlink traffic in the corresponding area of Grid1 may be when the MR number of cell2 is greater than zero and less than a preset threshold, at this time the server can use the calculation method of FIG. 3 to calculate, that is, the uplink for a grid During the calculation of the traffic and downlink traffic, the specific conditions of the target area corresponding to each of the N cells included in each grid can be optimized to calculate the most applicable method, so as to obtain the uplink traffic and Downstream traffic.

102. The server calculates an uplink EBT of each grid and a downlink EBT of each grid.

During network transmission, according to different network states, a block may occur in the area corresponding to each of the at least two grids. The server may calculate the uplink EBT of each grid and the downlink EBT of each grid. . Specifically, the service calculates the uplink EBT and downlink EBT of each grid, and can determine the corresponding calculation method according to the uplink experience rate of the target area corresponding to each cell in the N cells and the downlink experience rate of the target area corresponding to each cell. , The following detailed introduction through Figure 5, Figure 6 and Figure 7:

First, please refer to FIG. 5. FIG. 5 shows that when the server determines that the uplink experience rate of the target area corresponding to each cell is less than the first target experience rate, and the downlink experience rate of the target area corresponding to each cell is less than the second target experience rate The specific process of the server calculating the uplink EBT of each grid and the downlink EBT of each grid may include:

501. The server determines that the uplink experience rate of the target area corresponding to each of the N cells is less than the first target experience rate and the downlink experience rate of the target area corresponding to each cell is less than the second target experience rate.

The server may determine the uplink experience rate of the target area corresponding to each of the N cells and the downlink experience rate of the target area corresponding to each cell from the MR data, and the server determines whether the uplink experience rate is less than the first target experience rate And determine whether the downlink experience rate is less than a second target experience rate, where the first target experience rate and the second target experience rate are pre-configured by the server, and can be specifically configured by the average transmission rate of the main service of each cell, The main services of each cell are different, and the specific server can be determined according to the actual situation of the cell. In addition, for the cell used by VIP users, the first target experience rate and the second target experience rate can be set to higher values. When the uplink experience rate is less than the first target experience rate and the downlink experience rate is less than the second target experience rate, then the server may determine a calculation method for calculating the restored EBT corresponding to the target area corresponding to each cell. For example, for a video service, the first target experience rate may be set to 2 Mbps (megabits per second), and the server may determine whether the downlink experience rate of the target area corresponding to each cell is less than 2 Mbps.

502. The server calculates the uplink restoration EBT of the target area corresponding to each cell according to the uplink experience rate of the target area corresponding to each cell, the first target experience rate, and the uplink traffic of the target area corresponding to each cell, and according to each cell The downlink experience rate of the corresponding target area, the second target experience rate, and the downlink traffic of the target area corresponding to each cell calculate the downlink restored EBT of the target area corresponding to each cell.

The server may subtract the first target experience rate from the uplink experience rate of the target area corresponding to the corresponding cell to obtain the uplink experience rate loss ratio, and then multiply the uplink experience rate loss ratio by the uplink traffic of the target area corresponding to the corresponding cell. Obtain the uplink restoration EBT of the target area corresponding to the corresponding cell; and the server may reduce the second target experience rate to the downlink experience rate of the target area corresponding to the corresponding cell, and obtain the downlink experience rate loss ratio of the target area corresponding to the corresponding cell, Then multiplying the downlink experience rate loss ratio by the downlink traffic of the target area corresponding to the corresponding cell to obtain the downlink restored EBT of the target area corresponding to the corresponding cell. That is, the uplink restoration EBT of the target area corresponding to each cell = (first target experience rate-the uplink experience rate of the target area corresponding to each cell) / the uplink experience rate of the target area corresponding to each cell * Upstream traffic in the target area corresponding to each cell; downlink EBT in the target area corresponding to each cell = (second target experience rate-downlink experience rate in the target area corresponding to each cell) / target area corresponding to each cell Downlink experience rate * The downlink traffic of the target area corresponding to each cell. As shown in Table 8 below, assuming that the target cell is cell1, the grid where the target cell area is located is Grid1 to Grid10, and then the downlink reduction EBT of the corresponding target area where cell1 is located in Grid1 to Gird10 is calculated, where cell1 is located in Grid1 The reduction EBT of the target area of the target is (1/1) * 1.9, and the downstream reduction EBT of the target area where cell2 is located on Grid1 is 0.

Table 8

503. The server calculates the total uplink restoration EBT of each cell according to the uplink restoration EBT of the target area corresponding to each cell, and calculates the total downlink restoration EBT according to the downlink restoration EBT of the target area corresponding to each cell.

The server can add the uplink restored EBT of the target area corresponding to each cell to obtain the total uplink restored EBT of each cell; add the downlink restored EBT of the target area corresponding to each cell to obtain the downlink of each cell. Total reduction of EBT. For example, as shown in Table 8, the total downlink EBT of cell1 is 2.29.

504. The server calculates the uplink EBT weight of the target area corresponding to each cell according to the uplink restored EBT of the target area corresponding to each cell and the uplink total restored EBT, and according to the downlink restored EBT of the target area corresponding to each cell, and The downlink total restoration EBT calculates a downlink EBT weight of a target area corresponding to each cell.

The server may divide the uplink restored EBT of the target area corresponding to each cell by the uplink total restored EBT, obtain the uplink EBT weight of the target area corresponding to each cell, and divide the downlink restored EBT of the target area corresponding to each cell. The total EBT is restored with the downlink to obtain the downlink EBT weight of the target area corresponding to each cell. The specific formula is: the uplink EBT weight of the target area corresponding to each cell = the uplink restored EBT / uplink total restored EBT of the target area corresponding to each cell, and the downlink EBT weight of the target area corresponding to each cell = corresponding to each cell Downstream reduction EBT / downlink total reduction EBT in the target area. Table 9 below illustrates the downlink EBT weight of the target area corresponding to each cell calculated by the server.

Table 9

505. The server calculates the uplink EBT of the target area corresponding to each cell according to the uplink EBT weight of the target area corresponding to each cell and the total uplink EBT of each cell, and according to the downlink EBT weight of the target area corresponding to each cell and each The total downlink EBT of the cell calculates the downlink EBT of the target area corresponding to each cell.

The server may multiply the uplink EBT weight of the target area corresponding to each cell by the total uplink EBT of each cell to obtain the uplink EBT of the target area corresponding to each cell and the downlink EBT of the target area corresponding to each cell. The weight is multiplied by the total downlink EBT corresponding to each cell to obtain the downlink EBT of the target area corresponding to each cell; the specific calculation formula is: uplink EBT of the target area corresponding to each cell = target area corresponding to each cell Uplink EBT weight of each cell * total uplink EBT of each cell, and downlink EBT of the target area corresponding to each cell = downlink EBT weight of the target area corresponding to each cell * total downlink EBT of each cell; shown in Table 10 below The service calculates the downlink EBT of the target area corresponding to each cell.

Table 10

Blocking traffic	Grid1	Grid2	Grid3	Grid4	Grid5	Grid6	Grid7	Grid8	Grid9	Grid10	Sum
Cell1	0.83	0	0	0	0	0.17	0	0	0	0	1.00
Cell2	0	0	0.67	0.13	0	0	0	0	0	0	0.80
Cell3	0	0	0	0.67	0	0	0	0.53	0	0	1.20
Cell4	0	0	1.00	0	0	0	0	0	0	0	1.00
Cell5	0	0	1.88	0	0.62	0	0	0	0	0	2.50

506. The server calculates an uplink EBT corresponding to each grid according to the uplink EBT of the target area corresponding to each cell, and calculates a downlink EBT for each grid according to the downlink EBT of the target area corresponding to each cell.

The server adds the uplink EBT of the target area corresponding to each cell to obtain the uplink EBT of each grid, and adds the downlink EBT of the target area corresponding to each cell to obtain the downlink EBT of each grid. For example, as can be seen from the above Table 10, the downlink EBT of Grid1 is 0.83, the downlink EBT of Grid2 is 0, and the downlink EBT of Grid3 is 0.67 + 1 = 1.88.

When the server determines that the uplink experience rate of the target area corresponding to each cell is greater than or equal to the first target experience rate, and the downlink experience rate of the target area corresponding to each cell is greater than or equal to the second target experience rate, the server may determine that each The upstream reduced EBT of the target area corresponding to the cell is zero, and its downstream reduced EBT is also zero. Therefore, the EBT weights calculated by the restored EBT are all zero, and then the calculated grid EBTs are all zero. Therefore, the server calculates the EBT of each grid by referring to the MR ratio of the target area corresponding to each cell, or by averaging EBT to each grid. The following uses 6 and FIG. 7 to describe the case where the uplink experience rate in the target area corresponding to each cell is greater than or equal to the first target experience rate, and the downlink experience rate in the target area corresponding to each cell is greater than or equal to the second target experience rate. The server calculates the specific calculation method of the uplink EBT of each grid and the downlink EBT of each grid:

First, please refer to FIG. 6. FIG. 6 shows the server calculates the EBT weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell, and then calculates the target area corresponding to each cell based on the EBT weight. EBT, and then calculate the EBT of each grid based on the EBT of the target area corresponding to each cell. The specific process can include:

601. The server calculates the total uplink grid weight of each cell according to the MR ratio of the target area corresponding to each cell, and calculates the total downlink grid weight of each cell according to the MR ratio of the target area corresponding to each cell. .

Step 601 is similar to step 303 in FIG. 3 described above, and details are not described herein again.

602. The server calculates the uplink EBT weight of the target area corresponding to each cell according to the total uplink grid weight and the MR ratio of the target area corresponding to each cell, and calculates each The downlink EBT weight of the target area corresponding to the cell.

The server may multiply the total uplink grid weight by the MR ratio of the target area corresponding to each cell to obtain the uplink EBT weight of the target area corresponding to each cell and the downlink EBT weight of the target area corresponding to each cell.

603. The server calculates the uplink EBT of the target area corresponding to each cell according to the uplink EBT weight of the target area corresponding to each cell and the total uplink EBT of each cell, and according to the downlink EBT weight of the target area corresponding to each cell and each The total downlink EBT of each cell calculates the downlink EBT of the target area corresponding to each cell.

604. The server calculates an uplink EBT of each grid according to the uplink EBT of the target area corresponding to each cell, and calculates a downlink EBT of each grid according to the downlink EBT of the target area corresponding to each cell.

Steps 603 to 604 are similar to steps 505 to 506 in FIG. 5 described above, and details are not described herein again.

Please refer to FIG. 7. FIG. 7 shows that the server calculates the uplink EBT and the downlink EBT of each grid in a manner that the EBT is evenly distributed to each grid. The specific process includes:

701. The server calculates the uplink EBT of the target area corresponding to each cell according to the total uplink EBT of each cell and the total number of grids in which each cell is located, and according to the total downlink EBT of each cell and the total number of grids. Calculate the downlink EBT of the target area corresponding to each cell.

The server may divide the total uplink EBT of each cell by the total number of grids in which each cell is located, obtain the uplink EBT of the target area corresponding to each cell, and divide the total downlink EBT of each cell by the each The total number of grids in which each cell is located to obtain the downlink EBT of the target area corresponding to each cell. From the cell grid comparison table in Table 1, we can know that the total downlink EBT of cell1 is 1, and the grid in which the area of cell1 is located. The total number of cells is 10, so the downlink EBT of cell1 in the target area of Grid1 is 0.1.

702. The server calculates an uplink EBT of each grid according to the uplink EBT of the target area corresponding to each cell, and calculates a downlink EBT of each grid according to the downlink EBT of the target area corresponding to each cell.

Step 702 is similar to step 506 in FIG. 5 described above, and details are not described herein again.

It should be noted that, the server shown in FIG. 7 calculates the uplink EBT of each grid and the downlink EBT of each grid can also be used when the server determines that the target cell has no MR data within a preset time period.

In this embodiment, the methods for calculating the uplink EBT of a grid and the downlink EBT of each grid in FIG. 5, FIG. 6, and FIG. 7 can be used in a mixed manner. The calculation method of the downlink EBT in the target area of the target area may be: when the uplink experience rate of the target area of cell1 in Grid1 is greater than the second target experience rate, the uplink EBT of cell1 in the target area of Grid1 may be calculated using the method shown in FIG. When the downlink experience rate of the target area where cell1 is located on Grid1 is less than the first target experience rate, the method shown in Figure 5 can be used to calculate the downlink EBT of the target area where cell1 is located on Grid1; that is, for the same grid The calculation method adopted by the uplink EBT and the downlink EBT of the target area corresponding to the different cells may also be based on the size of the uplink experience rate and the downlink experience rate of the target area to select the most suitable calculation method.

103. The server calculates the uplink EBI of each grid according to the uplink traffic of each grid and the uplink EBT of each grid, and calculates each based on the downlink traffic of each grid and the downlink EBT of each grid. EBI down the grid.

The server can divide the uplink EBT of each grid by the uplink traffic of each grid (remove packets), obtain the uplink EBI of each grid, and divide the downlink EBT of each grid by the downlink of each grid. Traffic (to LastTTI) to get the downlink EBI of each grid, the specific calculation formula is: uplink EBI = uplink EBT of each grid / uplink traffic (go to small packets) of each grid, downlink EBI = each grid Downstream EBT / downstream traffic per grid (to LastTTI traffic). For example, the downlink traffic of each grid calculated by the calculation method of FIG. 2 and the downlink EBT data of each grid calculated by the calculation method of FIG. 5 are used to calculate the downlink EBI of each grid, Grid1 Downlink EBI = 0.83 / (1.9 + 1 + 1 + 1.8 + 0) * 100% = 14.4%, downlink EBI of Grid2 = 0, downlink EBI of Grid3 = (0.67 + 1 + 1.88) / (1.9 + 0.8 + 3.1 + 0.1 + 1.9) * 100% = 44.8%, Grid4's downlink EBI = (0.13 + 0.67) / (1.2 + 3 + 1.8 + 0.8 + 1.5) * 100% = 10.5%, Grid5's downlink EBI = 0.62 / (2 + 3.6 + 0.8 + 1.5) * 100% = 7.0%, Grid6's downlink EBI = 0.17 / (2.4 + 1.8 + 1.5) * 100% = 3.3%; Grid7's downlink EBI = 0; Grid8's downlink EBI = 0.53 / ( 1 + 1.8 + 1.5) * 100% = 11%; the downlink EBI of Grid9 = 0, and the downlink EBI of Grid10 = 0, then the downlink EBI of each grid obtained by the above calculation can be the grid-level downlink EBI of cell 1. These grid-level downlink EBIs can be used to reflect the congestion of various parts within the cell 1.

In the technical solution provided in the embodiment of the present application, the server calculates the uplink traffic of each grid in at least two grids and the downlink traffic of each grid, the at least two grids include all areas of the target cell, and the The areas corresponding to the target cells included in each grid do not overlap; then the server calculates the uplink EBT of each grid and the downlink EBT of each grid; the server can calculate the uplink traffic of each grid and each The uplink EBT of the grid calculates the uplink EBI of each grid and the downlink EBI of each grid is calculated based on the downlink traffic of each grid and the downlink EBT of each grid. In the technical solution of the present application, the server calculates the uplink EBT and uplink EBI of each grid in at least two grids of the target cell, and the downlink EBT of each grid and the downlink EBI of each grid, the at least two The grid includes the entire area of the target cell, and the corresponding area of each grid including the target cell does not overlap. Therefore, the grid-level EBI calculated through this application has a finer granularity than the existing cell-level EBI, which is convenient for analyzing the degree of experience congestion within the target cell area and the traffic loss caused by network congestion, and is convenient for monitoring and quantitative evaluation. The target cell experiences congestion.

The data processing method in the embodiment of the present application has been described above, and a server provided in the embodiment of the present application is described below. Please refer to FIG. 8. An embodiment of the server in the embodiment of the present application includes:

A calculation unit 801 is configured to calculate an uplink traffic of each grid in at least two grids and a downlink traffic of each grid, the at least two grids include all areas covered by the target cell, and each grid The areas corresponding to the included target cells do not overlap;

The calculation unit 801 is configured to calculate an uplink experience blocking traffic EBT of each grid and a downlink EBT of each grid;

The calculation unit 801 is configured to calculate an uplink blocking experience index EBI of each grid according to the uplink traffic of each grid and the uplink EBT of each grid, and according to the downlink traffic of each grid and the The downlink EBT of each grid calculates the downlink EBI of each grid.

In this embodiment, each grid includes a target area corresponding to each of the N cells, where N is a positive integer; the calculation unit 801 is specifically configured to:

Calculating the uplink traffic weight of the target area corresponding to each cell in the N cells and the downlink traffic weight of the target area corresponding to each cell;

Calculating the uplink traffic of the target area corresponding to each cell and the downlink traffic weight of the target area corresponding to each cell according to the uplink traffic weight of the target area corresponding to each cell and the uplink traffic corresponding to each cell, and Calculating the downlink traffic corresponding to each cell for the downlink traffic of the target area corresponding to each cell;

The uplink traffic of each grid is calculated according to the uplink traffic of the target area corresponding to each cell, and the downlink traffic of each grid is calculated according to the downlink traffic of the target area corresponding to each cell.

In this embodiment, the calculation unit 801 is specifically configured to:

Determining the number of MR measurement reports of each of the N cells;

Determine that the number of MRs is greater than or equal to a preset threshold;

Calculate the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the uplink experience rate of the target area corresponding to each cell, and according to the target area corresponding to each cell The MR ratio and the downlink experience rate of the target area corresponding to each cell calculate the downlink traffic weight of the target area corresponding to each cell.

In this embodiment, the calculation unit 801 is specifically configured to:

Determining the MR ratio of the target area corresponding to each cell and the uplink experience rate of the target area corresponding to each cell;

Calculate the total uplink grid weight of each cell according to the MR ratio of the target area corresponding to each cell in the N cells and the uplink experience rate of the target area corresponding to each cell, and according to each of the N cells The MR ratio of the target area corresponding to each cell and the downlink experience rate of the target area corresponding to each cell to calculate the total downlink grid weight of each cell;

Calculate the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell, the uplink experience rate of the target area corresponding to each cell, and the total uplink grid weight, and according to the The MR ratio of the target area corresponding to each cell, the downlink experience rate of the target area corresponding to each cell, and the total downlink grid weight are used to calculate the downlink traffic weight of the target area corresponding to each cell.

In this embodiment, the calculation unit 801 is specifically configured to:

Determine the number of MRs of each of the N cells;

Determine that the number of MRs is greater than zero and less than a preset threshold;

The uplink traffic weight of the target area corresponding to each cell and the downlink traffic weight of the target area corresponding to each cell are calculated according to the target area MR ratio corresponding to each cell.

In this embodiment, the calculation unit 801 is specifically configured to:

Determining the MR ratio of the target area corresponding to each cell;

Calculating the total uplink grid weight of each cell and the total downlink grid weight of each cell according to the MR ratio of the target area corresponding to each cell;

Calculate the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the total uplink grid weight, and according to the MR ratio of the target area corresponding to each cell and the The total downlink grid weight calculates the downlink traffic weight of the target area corresponding to each cell.

In this embodiment, each grid includes a target area corresponding to each of the N cells, where N is a positive integer; the calculation unit 801 is specifically configured to:

Determine the total number of grids corresponding to each of the N cells, and the total number of grids is the number of grids of the grids in which all areas corresponding to each cell are located;

Calculate the uplink traffic of the target area corresponding to each cell according to the uplink traffic of each cell and the total number of grids corresponding to each cell, and according to the downlink traffic of each cell and the corresponding number of each cell The total number of grids to calculate the downlink traffic of the target area corresponding to each cell;

The uplink traffic of each grid is calculated according to the uplink traffic of the target area corresponding to each cell, and the downlink traffic of each grid is calculated according to the downlink traffic of the target area corresponding to each cell.

In this embodiment, the server further includes:

The first determining unit 802 is configured to determine that the number of MRs of each cell is zero.

In this embodiment, each grid includes a target area corresponding to each of the N cells, where N is a positive integer; the calculation unit 801 is specifically configured to:

Calculating the uplink EBT weight of the target area corresponding to each of the N cells and the downlink EBT weight of the target area corresponding to each of the cells;

When the uplink EBT weight is not zero, calculate the uplink EBT of the target area corresponding to each cell according to the uplink EBT weight of the target area corresponding to each cell and the total uplink EBT of each cell;

Calculating the uplink EBT of each grid according to the uplink EBT of the target area corresponding to each cell;

When the downlink EBT weight is not zero, calculate the downlink EBT of the target area corresponding to each cell according to the downlink EBT weight of the target area corresponding to each cell and the total downlink EBT of each cell;

The downlink EBT of each grid is calculated according to the downlink EBT of the target area corresponding to each cell.

In this embodiment, the calculation unit 801 is specifically configured to:

Calculating the uplink restored EBT of the target area corresponding to each cell and the downlink restored EBT of the target area corresponding to each cell;

When the uplink restoration EBT is not zero, calculate the uplink EBT weight of the target area corresponding to each cell according to the uplink restoration EBT of the target area corresponding to each cell and the uplink total restoration EBT of each cell;

When the downlink restored EBT is not zero, the downlink EBT weight of the target area corresponding to each cell is calculated according to the downlink restored EBT of the target area corresponding to each cell and the downlink total restored EBT of each cell.

In this embodiment, the calculation unit 801 is specifically configured to:

Determining whether the uplink experience rate of the target area corresponding to each cell is greater than or equal to the first target experience rate, and determining whether the downlink experience rate of the target area corresponding to each cell is greater than or equal to the second target experience rate;

If yes, determine that the uplink restored EBT of the target area corresponding to each cell is zero, and determine that the downlink restored EBT of the target area corresponding to each cell is zero;

If not, calculating the uplink restored EBT of the target area corresponding to each cell according to the uplink experience rate of the target area corresponding to each cell, the first target experience rate, and uplink traffic of the target area corresponding to each cell, And calculating the downlink restoration EBT of the target area corresponding to each cell according to the downlink experience rate of the target area corresponding to each cell, the second target experience rate, and downlink traffic of the target area corresponding to each cell.

In this embodiment, when the uplink EBT weight is zero and the downlink EBT weight is zero, the calculation unit 801 is further configured to:

Calculating the uplink EBT weight of the target area corresponding to each cell and the downlink EBT weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell;

Calculate the uplink EBT of the target area corresponding to each cell according to the uplink EBT weight and the total uplink EBT of each cell, and calculate the target corresponding to each cell according to the downlink EBT weight and the total downlink EBT of each cell Downward EBT for the region.

In this embodiment, when the uplink EBT weight is zero and the downlink EBT weight is zero, the server further includes:

A second determining unit 803, configured to determine the total number of grids corresponding to each cell, where the total number of grids is the number of grids of a grid in which all regions corresponding to each cell are located;

The calculation unit 801 is further configured to:

Calculate the uplink EBT of the target area corresponding to each cell according to the total uplink EBT of each cell and the total number of the grid, and calculate each The downlink EBT of the target area corresponding to the cell.

In the technical solution provided in the embodiment of the present application, the calculation unit 801 calculates the uplink traffic of each grid of at least two grids and the downlink traffic of each grid, and the at least two grids include all areas of the target cell, And the area corresponding to the target cell included in each grid does not overlap; then the calculation unit 801 calculates the uplink EBT of each grid and the downlink EBT of each grid; the calculation unit 801 may The uplink EBI of each grid and the uplink EBT of each grid are used to calculate the uplink EBI of each grid and the downlink EBI of each grid is calculated based on the downlink traffic of each grid and the downlink EBT of each grid. In the technical solution of the present application, the calculation unit 801 calculates an uplink EBT and an uplink EBI of each grid in at least two grids of the target cell, and a downlink EBT and a downlink EBI of each grid of the target cell. The two grids include the entire area of the target cell, and the corresponding areas of each grid including the target cell do not overlap. Therefore, the grid-level EBI calculated through this application has a finer granularity than the existing cell-level EBI, which is convenient for analyzing the degree of experience congestion within the target cell area and the traffic loss caused by network congestion, and is convenient for monitoring and quantitative evaluation. The target cell experiences congestion.

This application also provides a server 900. Please refer to FIG. 9, an embodiment of the server in the embodiment of this application includes:

A processor 901, a memory 902, an input-output device 903, and a bus 904;

The processor 901, the memory 902, and the input / output device 903 are respectively connected to the bus 904, and the memory stores computer instructions;

The processor 901 is configured to calculate the uplink traffic of each grid of at least two grids and the downlink traffic of each grid, the at least two grids include all areas covered by the target cell, and each grid The areas corresponding to the included target cells do not overlap; the uplink experience blocking traffic EBT of each grid and the downlink EBT of each grid are calculated; according to the uplink traffic of each grid and the uplink of each grid EBT calculates the uplink blocking experience index EBI of each grid, and calculates the downlink EBI of each grid according to the downlink traffic of each grid and the downlink EBT of each grid.

In a possible implementation manner, each grid includes a target area corresponding to each of the N cells, where N is a positive integer; the processor 901 is specifically configured to:

Calculating the uplink traffic weight of the target area corresponding to each cell in the N cells and the downlink traffic weight of the target area corresponding to each cell;

Calculating the uplink traffic of the target area corresponding to each cell and the downlink traffic weight of the target area corresponding to each cell according to the uplink traffic weight of the target area corresponding to each cell and the uplink traffic corresponding to each cell, and Calculating the downlink traffic corresponding to each cell for the downlink traffic of the target area corresponding to each cell;

The uplink traffic of each grid is calculated according to the uplink traffic of the target area corresponding to each cell, and the downlink traffic of each grid is calculated according to the downlink traffic of the target area corresponding to each cell.

In another possible implementation manner, the processor 901 is specifically configured to:

Determining the number of MR measurement reports of each of the N cells;

Determine that the number of MRs is greater than or equal to a preset threshold;

Calculate the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the uplink experience rate of the target area corresponding to each cell, and according to the target area corresponding to each cell The MR ratio and the downlink experience rate of the target area corresponding to each cell calculate the downlink traffic weight of the target area corresponding to each cell.

In another possible implementation manner, the processor 901 is specifically configured to:

Determining the MR ratio of the target area corresponding to each cell and the uplink experience rate of the target area corresponding to each cell;

Calculate the total uplink grid weight of each cell according to the MR ratio of the target area corresponding to each cell in the N cells and the uplink experience rate of the target area corresponding to each cell, and according to each of the N cells The MR ratio of the target area corresponding to each cell and the downlink experience rate of the target area corresponding to each cell to calculate the total downlink grid weight of each cell;

Calculate the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell, the uplink experience rate of the target area corresponding to each cell, and the total uplink grid weight, and according to the The MR ratio of the target area corresponding to each cell, the downlink experience rate of the target area corresponding to each cell, and the total downlink grid weight are used to calculate the downlink traffic weight of the target area corresponding to each cell.

In another possible implementation manner, the processor 901 is specifically configured to:

Determine the number of MRs of each of the N cells;

Determine that the number of MRs is greater than zero and less than a preset threshold;

The uplink traffic weight of the target area corresponding to each cell and the downlink traffic weight of the target area corresponding to each cell are calculated according to the target area MR ratio corresponding to each cell.

In another possible implementation manner, the processor 901 is specifically configured to:

Determining the MR ratio of the target area corresponding to each cell;

Calculating the total uplink grid weight of each cell and the total downlink grid weight of each cell according to the MR ratio of the target area corresponding to each cell;

Calculate the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the total uplink grid weight, and according to the MR ratio of the target area corresponding to each cell and the The total downlink grid weight calculates the downlink traffic weight of the target area corresponding to each cell.

In another possible implementation manner, each grid includes a target area corresponding to each of the N cells, where N is a positive integer; the processor 901 is specifically configured to:

Determine the total number of grids corresponding to each of the N cells, and the total number of grids is the number of grids of the grids in which all areas corresponding to each cell are located;

Calculate the uplink traffic of the target area corresponding to each cell according to the uplink traffic of each cell and the total number of grids corresponding to each cell, and according to the downlink traffic of each cell and the corresponding number of each cell The total number of grids to calculate the downlink traffic of the target area corresponding to each cell;

The uplink traffic of each grid is calculated according to the uplink traffic of the target area corresponding to each cell, and the downlink traffic of each grid is calculated according to the downlink traffic of the target area corresponding to each cell.

In another possible implementation manner, the processor 901 is further configured to:

It is determined that the number of MRs of each cell is zero.

In another possible implementation manner, each grid includes a target area corresponding to each of the N cells, where N is a positive integer; the processor 901 is specifically configured to:

Calculating the uplink EBT weight of the target area corresponding to each of the N cells and the downlink EBT weight of the target area corresponding to each of the cells;

When the uplink EBT weight is not zero, calculate the uplink EBT of the target area corresponding to each cell according to the uplink EBT weight of the target area corresponding to each cell and the total uplink EBT of each cell;

Calculating the uplink EBT of each grid according to the uplink EBT of the target area corresponding to each cell;

When the downlink EBT weight is not zero, calculate the downlink EBT of the target area corresponding to each cell according to the downlink EBT weight of the target area corresponding to each cell and the total downlink EBT of each cell;

The downlink EBT of each grid is calculated according to the downlink EBT of the target area corresponding to each cell.

In another possible implementation manner, the processor 901 is specifically configured to:

Calculating the uplink restored EBT of the target area corresponding to each cell and the downlink restored EBT of the target area corresponding to each cell;

When the uplink restoration EBT is not zero, calculate the uplink EBT weight of the target area corresponding to each cell according to the uplink restoration EBT of the target area corresponding to each cell and the uplink total restoration EBT of each cell;

When the downlink restored EBT is not zero, the downlink EBT weight of the target area corresponding to each cell is calculated according to the downlink restored EBT of the target area corresponding to each cell and the downlink total restored EBT of each cell.

In another possible implementation manner, the processor 901 is specifically configured to:

Determining whether the uplink experience rate of the target area corresponding to each cell is greater than or equal to the first target experience rate, and determining whether the downlink experience rate of the target area corresponding to each cell is greater than or equal to the second target experience rate;

If yes, determine that the uplink restored EBT of the target area corresponding to each cell is zero, and determine that the downlink restored EBT of the target area corresponding to each cell is zero;

If not, calculating the uplink restored EBT of the target area corresponding to each cell according to the uplink experience rate of the target area corresponding to each cell, the first target experience rate, and uplink traffic of the target area corresponding to each cell, And calculating the downlink restoration EBT of the target area corresponding to each cell according to the downlink experience rate of the target area corresponding to each cell, the second target experience rate, and downlink traffic of the target area corresponding to each cell.

In another possible implementation manner, when the uplink EBT weight is zero and the downlink EBT weight is zero; the processor 901 is further configured to:

Calculating the uplink EBT weight of the target area corresponding to each cell and the downlink EBT weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell;

Calculate the uplink EBT of the target area corresponding to each cell according to the uplink EBT weight and the total uplink EBT of each cell, and calculate the target corresponding to each cell according to the downlink EBT weight and the total downlink EBT of each cell Downward EBT for the region.

In another possible implementation manner, when the uplink EBT weight is zero and the downlink EBT weight is zero; the processor 901 is further configured to:

Determining the total number of grids corresponding to each cell, and the total number of grids is the number of grids of a grid in which all areas corresponding to each cell are located;

Calculate the uplink EBT of the target area corresponding to each cell according to the total uplink EBT of each cell and the total number of the grid, and calculate each The downlink EBT of the target area corresponding to the cell.

Those skilled in the art can clearly understand that, for the convenience and brevity of description, the specific working processes of the systems, devices, and units described above can refer to the corresponding processes in the foregoing method embodiments, and are not repeated here.

In another possible design, when the server is a chip in a terminal, the chip includes a processing unit and a communication unit. The processing unit may be, for example, a processor, and the communication unit may be, for example, an input / output interface, Pins or circuits, etc. The processing unit may execute computer execution instructions stored in the storage unit, so that a chip in the terminal executes the data processing method of any one of the first aspects. Optionally, the storage unit is a storage unit in the chip, such as a register, a cache, etc. The storage unit may also be a storage unit in the terminal that is located outside the chip, such as a read-only memory (read -only memory (ROM) or other types of static storage devices that can store static information and instructions, random access memory (RAM), etc.

Among them, the processor mentioned above may be a general-purpose central processing unit (CPU), a microprocessor, an application-specific intergrated circuit (ASIC), or one or more for controlling the above. The first aspect of the data processing method is a program executed by an integrated circuit.

In the above embodiments, it may be implemented in whole or in part by software, hardware, firmware, or any combination thereof. When implemented in software, it may be implemented in whole or in part in the form of a computer program product.

The computer program product includes one or more computer instructions. When the computer program instructions are loaded and executed on a computer, the processes or functions according to the embodiments of the present invention are wholly or partially generated. The computer may be a general-purpose computer, a special-purpose computer, a computer network, or other programmable devices. The computer instructions may be stored in a computer-readable storage medium, or transmitted from one computer-readable storage medium to another computer-readable storage medium, for example, the computer instructions may be from a website site, computer, server, or data center Transmission by wire (for example, coaxial cable, optical fiber, digital subscriber line (DSL)) or wireless (for example, infrared, wireless, microwave, etc.) to another website site, computer, server, or data center. The computer-readable storage medium may be any available medium that can be stored by a computer or a data storage device such as a server, a data center, and the like that includes one or more available medium integration. The available medium may be a magnetic medium (for example, a floppy disk, a hard disk, a magnetic tape), an optical medium (for example, a DVD), or a semiconductor medium (for example, a solid state disk (Solid State Disk (SSD)), and the like.

In the several embodiments provided in this application, it should be understood that the disclosed systems, devices, and methods may be implemented in other ways. For example, the device embodiments described above are only schematic. For example, the division of the unit is only a logical function division. In actual implementation, there may be another division manner. For example, multiple units or components may be combined or Can be integrated into another system, or some features can be ignored or not implemented. In addition, the displayed or discussed mutual coupling or direct coupling or communication connection may be indirect coupling or communication connection through some interfaces, devices or units, which may be electrical, mechanical or other forms.

The units described as separate components may or may not be physically separated, and the components displayed as units may or may not be physical units, may be located in one place, or may be distributed on multiple network units. Some or all of the units may be selected according to actual needs to achieve the objective of the solution of this embodiment.

In addition, each functional unit in each embodiment of the present application may be integrated into one processing unit, or each of the units may exist separately physically, or two or more units may be integrated into one unit. The above integrated unit may be implemented in the form of hardware or in the form of software functional unit.

When the integrated unit is implemented in the form of a software functional unit and sold or used as an independent product, it may be stored in a computer-readable storage medium. Based on this understanding, the technical solution of the present application is essentially a part that contributes to the existing technology or all or part of the technical solution can be embodied in the form of a software product, which is stored in a storage medium. , Including a plurality of instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to perform all or part of the steps of the method described in the embodiments of the present application. The foregoing storage media include: U disk, mobile hard disk, read-only memory (ROM, Read-Only Memory), random access memory (RAM, Random Access Memory), magnetic disks or optical disks and other media that can store program codes .

As mentioned above, the above embodiments are only used to describe the technical solution of the present application, rather than limiting them. Although the present application has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that they can still apply the foregoing The technical solutions described in the embodiments are modified, or some technical features are equivalently replaced; and these modifications or replacements do not deviate the essence of the corresponding technical solutions from the spirit and scope of the technical solutions of the embodiments of the present application.

Claims (26)

1. A data processing method, characterized in that the method includes:

   The server calculates the uplink traffic of each grid of at least two grids and the downlink traffic of each grid, the at least two grids include all areas covered by the target cell, and each grid includes The areas corresponding to the target cells do not overlap;

   Calculating, by the server, the uplink experience blocking traffic EBT of each grid and the downlink EBT of each grid;

   Calculating, by the server, the uplink blocking experience index EBI of each grid according to the uplink traffic of each grid and the uplink EBT of each grid, and according to the downlink traffic and The downlink EBT of each grid is described to calculate the downlink EBI of each grid.
2. The method according to claim 1, wherein each grid includes a target area corresponding to each of the N cells, where N is a positive integer; and the server calculates The uplink traffic of each grid and the downlink traffic of each grid include:

   Calculating, by the server, an uplink traffic weight of a target area corresponding to each of the N cells and a downlink traffic weight of a target area corresponding to each of the cells;

   The server calculates the uplink traffic of the target area corresponding to each cell according to the uplink traffic weight of the target area corresponding to each cell and the uplink traffic corresponding to each cell, and the Calculating the downlink traffic weight of the target area and the downlink traffic corresponding to each cell to calculate the downlink traffic of the target area corresponding to each cell;

   Calculating, by the server, the uplink traffic of each grid according to the uplink traffic of the target area corresponding to each cell, and calculating the downlink of each grid according to the downlink traffic of the target area corresponding to each cell flow.
3. The method according to claim 2, wherein the calculating the uplink traffic weight of the target area corresponding to each cell in the N cells and the downlink traffic weight of the target area corresponding to each cell comprises:

   The server determines the number of MR measurement reports of each of the N cells;

   Determining, by the server, that the number of MRs is greater than or equal to a preset threshold;

   Calculating, by the server, the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the uplink experience rate of the target area corresponding to each cell, and according to the The MR ratio of the target area corresponding to each cell and the downlink experience rate of the target area corresponding to each cell calculate the downlink traffic weight of the target area corresponding to each cell.
4. The method according to claim 3, wherein the server calculates each cell according to the MR ratio of the target area corresponding to each cell and the uplink experience rate of the target area corresponding to each cell The uplink traffic weight of the corresponding target area, and the downlink of the target area corresponding to each cell is calculated according to the MR ratio of the target area corresponding to each cell and the downlink experience rate of the target area corresponding to each cell Traffic weights include:

   Determining, by the server, an MR ratio of a target area corresponding to each cell, an uplink experience rate of the target area corresponding to each cell, and a downlink experience rate of the target area corresponding to each cell;

   Calculating, by the server, the total uplink grid weight of each cell according to the MR ratio of the target area corresponding to each cell in the N cells and the uplink experience rate of the target area corresponding to each cell, and according to Calculating the MR ratio of the target area corresponding to each cell in the N cells and the downlink experience rate of the target area corresponding to each cell to calculate the total downlink grid weight of each cell;

   Calculating, by the server, the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell, the uplink experience rate of the target area corresponding to each cell, and the total uplink grid weight. The uplink traffic weight, and the target corresponding to each cell is calculated according to the MR ratio of the target area corresponding to each cell, the downlink experience rate of the target area corresponding to each cell, and the total downlink grid weight Downstream traffic weight for the region.
5. The method according to claim 2, wherein the calculating the uplink traffic weight of the target area corresponding to each cell in the N cells and the downlink traffic weight of the target area corresponding to each cell comprises:

   Determining, by the server, the number of MRs of each of the N cells;

   Determining, by the server, that the number of MRs is greater than zero and less than a preset threshold;

   The server calculates an uplink traffic weight of the target area corresponding to each cell and a downlink traffic weight of the target area corresponding to each cell according to the target area MR ratio corresponding to each cell.
6. The method according to claim 5, wherein the server calculates the uplink traffic weight of the target area corresponding to each cell and the each cell according to the MR ratio of the target area corresponding to each cell The corresponding downlink traffic weight of the target area includes:

   Determining, by the server, an MR ratio of a target area corresponding to each cell;

   Calculating, by the server, the total uplink grid weight of each cell and the total downlink grid weight of each cell according to the MR ratio of the target area corresponding to each cell;

   Calculating, by the server, the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the total uplink grid weight, and according to the target corresponding to each cell The MR ratio of the area and the total weight of the downlink grid calculate the downlink traffic weight of the target area corresponding to each cell.
7. The method according to claim 1, wherein each grid includes a target area corresponding to each of the N cells, where N is a positive integer; and the server calculates The uplink traffic of each grid and the downlink traffic of each grid include:

   The server determines the total number of grids corresponding to each cell in the N cells, and the total number of grids is the number of grids of the grids in which all areas corresponding to each cell are located;

   The server calculates the uplink traffic of the target area corresponding to each cell according to the uplink traffic of each cell and the total number of grids corresponding to each cell, and according to the downlink traffic of each cell And the total number of grids corresponding to each cell to calculate the downlink traffic of the target area corresponding to each cell;

   Calculating, by the server, the uplink traffic of each grid according to the uplink traffic of the target area corresponding to each cell, and calculating the downlink of each grid according to the downlink traffic of the target area corresponding to each cell flow.
8. The method according to claim 7, wherein before the server determines the total number of grids corresponding to each of the N cells, the method further comprises:

   The server determines that the number of MRs of each cell is zero.
9. The method according to any one of claims 1 to 8, wherein each grid includes a target area corresponding to each of the N cells, where N is a positive integer; and the server calculates The uplink EBT of each grid and the downlink EBT of each grid include:

   Calculating, by the server, the uplink EBT weight of the target area corresponding to each of the N cells and the downlink EBT weight of the target area corresponding to each of the cells;

   When the uplink EBT weight is not zero, the server calculates the uplink of the target area corresponding to each cell according to the uplink EBT weight of the target area corresponding to each cell and the total uplink EBT of each cell. EBT;

   Calculating, by the server, the uplink EBT of each grid according to the uplink EBT of the target area corresponding to each cell;

   When the downlink EBT weight is not zero, the server calculates the downlink of the target area corresponding to each cell according to the downlink EBT weight of the target area corresponding to each cell and the total downlink EBT of each cell. EBT;

   The server calculates the downlink EBT of each grid according to the downlink EBT of the target area corresponding to each cell.
10. The method according to claim 9, wherein the calculating the uplink EBT weight of the target area corresponding to each of the N cells and the downlink EBT weight of the target area corresponding to each cell comprises:

    Calculating, by the server, an uplink restored EBT in a target area corresponding to each cell and a downlink restored EBT in a target area corresponding to each cell;

    When the uplink restoration EBT is not zero, the server calculates the target area corresponding to each cell according to the uplink restoration EBT of the target area corresponding to each cell and the uplink total restoration EBT of each cell. Uplink EBT weights;

    When the downlink restoration EBT is not zero, the server calculates the target area corresponding to each cell according to the downlink restoration EBT of the target area corresponding to each cell and the total downlink restoration EBT of each cell. Downward EBT weights.
11. The method according to claim 10, wherein the calculating the uplink restored EBT of the target area corresponding to each cell and the downlink restored EBT of the target area corresponding to each cell comprises:

    Determining, by the server, whether an uplink experience rate of a target area corresponding to each cell is greater than or equal to a first target experience rate, and determining whether a downlink experience rate of a target area corresponding to each cell is greater than or equal to a second target experience rate;

    If yes, the server determines that the uplink restored EBT of the target area corresponding to each cell is zero, and determines that the downlink restored EBT of the target area corresponding to each cell is zero;

    If not, the server calculates the corresponding value of each cell according to the uplink experience rate of the target area corresponding to each cell, the first target experience rate, and the uplink traffic of the target area corresponding to each cell. The uplink restores the EBT of the target area, and calculates the target corresponding to each cell according to the downlink experience rate of the target area corresponding to each cell, the second target experience rate, and downlink traffic of the target area corresponding to each cell. The downside of the region restores EBT.
12. The method according to claim 9, wherein when the uplink EBT weight is zero and the downlink EBT weight is zero, the method further comprises:

    Calculating, by the server, the uplink EBT weight of the target area corresponding to each cell and the downlink EBT weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell;

    Calculating, by the server, the uplink EBT of the target area corresponding to each cell according to the uplink EBT weight and the total uplink EBT of each cell, and according to the downlink EBT weight and the total downlink EBT of each cell Calculating the downlink EBT of the target area corresponding to each cell;

    Calculating, by the server, the uplink EBT of each grid according to the uplink EBT of the target area corresponding to each cell, and calculating the downlink of each grid according to the downlink EBT of the target area corresponding to each cell EBT.
13. The method according to claim 9, wherein when the uplink EBT weight is zero and the downlink EBT weight is zero, the method further comprises:

    Determining, by the server, the total number of grids corresponding to each cell, where the total number of grids is the number of grids of a grid in which all regions corresponding to each cell are located;

    Calculating, by the server, the uplink EBT of the target area corresponding to each cell according to the total uplink EBT of each cell and the total number of grids, and according to the total downlink EBT of each cell and the gate The total number of grids is used to calculate the downlink EBT of the target area corresponding to each cell.
14. A server, wherein the server includes:

    A computing unit, configured to calculate the uplink traffic of each grid of at least two grids and the downlink traffic of each grid, the at least two grids including all areas covered by the target cell, each of The areas corresponding to the target cells included in the grid do not overlap;

    The calculation unit is configured to calculate an uplink experience blocking traffic EBT of each grid and a downlink EBT of each grid;

    The calculation unit is configured to calculate an uplink blocking experience index EBI of each grid based on the uplink traffic of each grid and the uplink EBT of each grid, and according to the The downlink traffic and the downlink EBT of each grid calculate the downlink EBI of each grid.
15. The server according to claim 14, wherein each grid includes a target area corresponding to each of the N cells, where N is a positive integer; and the calculation unit is specifically configured to:

    Calculating the uplink traffic weight of the target area corresponding to each of the N cells and the downlink traffic weight of the target area corresponding to each of the cells;

    Calculating the uplink traffic of the target area corresponding to each cell according to the uplink traffic weight of the target area corresponding to each cell and the uplink traffic corresponding to each cell, and the The downlink traffic weight and the downlink traffic corresponding to each cell to calculate the downlink traffic of the target area corresponding to each cell;

    Calculate the uplink traffic of each grid according to the uplink traffic of the target area corresponding to each cell, and calculate the downlink traffic of each grid according to the downlink traffic of the target area corresponding to each cell.
16. The server according to claim 15, wherein the computing unit is specifically configured to:

    Determining the number of MR measurement reports of each of the N cells;

    Determine that the number of MRs is greater than or equal to a preset threshold;

    Calculating the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the uplink experience rate of the target area corresponding to each cell, and according to each cell The MR ratio of the corresponding target area and the downlink experience rate of the target area corresponding to each cell calculate the downlink traffic weight of the target area corresponding to each cell.
17. The server according to claim 16, wherein the computing unit is specifically configured to:

    Determining the MR ratio of the target area corresponding to each cell and the uplink experience rate of the target area corresponding to each cell;

    Calculating the total uplink grid weight of each cell according to the MR ratio of the target area corresponding to each cell in the N cells and the uplink experience rate of the target area corresponding to each cell, and according to the N The MR ratio of the target area corresponding to each cell in each cell and the downlink experience rate of the target area corresponding to each cell to calculate the total downlink grid weight of each cell;

    Calculating the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell, the uplink experience rate of the target area corresponding to each cell, and the total uplink grid weight And calculating the downlink of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell, the downlink experience rate of the target area corresponding to each cell, and the total downlink grid weight Traffic weight.
18. The server according to claim 15, wherein the computing unit is specifically configured to:

    Determine the number of MRs of each of the N cells;

    Determine that the number of MRs is greater than zero and less than a preset threshold;

    Calculating the uplink traffic weight of the target area corresponding to each cell and the downlink traffic weight of the target area corresponding to each cell according to the target area MR ratio corresponding to each cell.
19. The server according to claim 18, wherein the computing unit is specifically configured to:

    Determining the MR ratio of the target area corresponding to each cell;

    Calculating the total uplink grid weight of each cell and the total downlink grid weight of each cell according to the MR ratio of the target area corresponding to each cell;

    Calculating the uplink traffic weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell and the total uplink grid weight, and according to the MR of the target area corresponding to each cell The ratio and the total weight of the downlink grid calculate the downlink traffic weight of the target area corresponding to each cell.
20. The server according to claim 14, wherein each grid includes a target area corresponding to each of the N cells, where N is a positive integer; and the calculation unit is specifically configured to:

    Determining the total number of grids corresponding to each of the N cells, where the total number of grids is the number of grids of the grids in which all areas corresponding to each cell are located;

    Calculating the uplink traffic of the target area corresponding to each cell according to the uplink traffic of each cell and the total number of grids corresponding to each cell, and according to the downlink traffic of each cell and the The total number of grids corresponding to each cell calculates the downlink traffic of the target area corresponding to each cell;

    Calculate the uplink traffic of each grid according to the uplink traffic of the target area corresponding to each cell, and calculate the downlink traffic of each grid according to the downlink traffic of the target area corresponding to each cell.
21. The server according to claim 20, wherein the server further comprises:

    The first determining unit is configured to determine that the number of MRs in each cell is zero.
22. The server according to claim 14 to 21, wherein each grid includes a target area corresponding to each of the N cells, where N is a positive integer; and the calculation unit is specifically configured to:

    Calculating the uplink EBT weight of the target area corresponding to each of the N cells and the downlink EBT weight of the target area corresponding to each of the cells;

    When the uplink EBT weight is not zero, calculating the uplink EBT of the target area corresponding to each cell according to the uplink EBT weight of the target area corresponding to each cell and the total uplink EBT of each cell;

    Calculating the uplink EBT of each grid according to the uplink EBT of the target area corresponding to each cell;

    When the downlink EBT weight is not zero, calculating the downlink EBT of the target area corresponding to each cell according to the downlink EBT weight of the target area corresponding to each cell and the total downlink EBT of each cell;

    Calculate the downlink EBT of each grid according to the downlink EBT of the target area corresponding to each cell.
23. The server according to claim 22, wherein the computing unit is specifically configured to:

    Calculating the uplink restored EBT in the target area corresponding to each cell and the downlink restored EBT in the target area corresponding to each cell;

    When the uplink restoration EBT is not zero, calculate the uplink EBT weight of the target area corresponding to each cell according to the uplink restoration EBT of the target area corresponding to each cell and the total uplink restoration EBT of each cell. ;

    When the downlink restoration EBT is not zero, calculate the downlink EBT weight of the target area corresponding to each cell according to the downlink restoration EBT of the target area corresponding to each cell and the total downlink restoration EBT of each cell. .
24. The server according to claim 23, wherein the computing unit is specifically configured to:

    Determining whether the uplink experience rate of the target area corresponding to each cell is greater than or equal to the first target experience rate, and determining whether the downlink experience rate of the target area corresponding to each cell is greater than or equal to the second target experience rate;

    If yes, determine that the uplink restored EBT of the target area corresponding to each cell is zero, and determine that the downlink restored EBT of the target area corresponding to each cell is zero;

    If not, calculate the target area corresponding to each cell according to the uplink experience rate of the target area corresponding to each cell, the first target experience rate, and uplink traffic of the target area corresponding to each cell The uplink restores EBT, and calculates the downlink of the target area corresponding to each cell according to the downlink experience rate of the target area corresponding to each cell, the second target experience rate, and downlink traffic of the target area corresponding to each cell. Restore EBT.
25. The server according to claim 22, wherein when the uplink EBT weight is zero and the downlink EBT weight is zero, the calculation unit is further configured to:

    Calculating the uplink EBT weight of the target area corresponding to each cell and the downlink EBT weight of the target area corresponding to each cell according to the MR ratio of the target area corresponding to each cell;

    Calculate the uplink EBT of the target area corresponding to each cell according to the uplink EBT weight and the total uplink EBT of each cell, and calculate the according to the downlink EBT weight and the total downlink EBT of each cell The downlink EBT of the target area corresponding to each cell.
26. The server according to claim 22, wherein when the uplink EBT weight is zero and the downlink EBT weight is zero, the server further comprises:

    A second determining unit, configured to determine the total number of grids corresponding to each cell, where the total number of grids is the number of grids of a grid in which all regions corresponding to each cell are located;

    The calculation unit is further configured to:

    Calculate the uplink EBT of the target area corresponding to each cell according to the total uplink EBT of each cell and the total number of grids, and according to the total downlink EBT of each cell and the total number of grids And calculating the downlink EBT of the target area corresponding to each cell.

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