KR101521272B1 - Method for measuring communication service quality and apparatus therefor - Google Patents

Abstract

The present invention relates to a communication service quality measuring method and apparatus for calculating a load factor and a data transmission rate of a base station based on the number of users of a base station and a wireless environment. A method for measuring quality of a mobile communication service in a quality measurement system according to the present invention includes: checking the number of concurrent users of a base station; Receiving a measured CQI from a plurality of mobile communication terminals located in coverage of the base station from each mobile communication terminal; And calculating an average of the received CQIs and calculating a data transmission rate of the base station using an average of the calculated CQIs and the number of concurrent users identified.

Description

[0001] METHOD FOR MEASURING COMMUNICATION SERVICE QUALITY AND APPARATUS THEREFOR [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method for measuring the quality of a communication service, and more particularly, to a method for measuring a communication service quality and a device for the same that calculates a load factor and a data transmission rate of a base station based on the number of users .

The mobile communication service is a service that continuously provides telephone, text message, internet and the like in the mobile communication. Unlike the fixed communication service, the quality of the service is changed. Further, the load factor of the base station constructed in the mobile communication system is changed from time to time depending on the installation area. Accordingly, mobile communication operators analyze data collected from mobile communication networks to identify and manage the network load ratio by region. The following patent documents disclose a performance and load inspection system of a mobile communication system.

However, the mobile communication service providers use the resource share of the base station only to check the network load ratio and fail to measure the quality of the mobile communication service experienced by the subscriber. That is, the mobile communication providers only grasp the load factor of the base station only, and can not accurately grasp the communication quality provided to subscribers who are the final consumers.

Korean Patent Publication No. 10-2007-0117397

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve such conventional problems, and it is an object of the present invention to provide a communication service quality measuring method for measuring a service quality of each base station by calculating a data transmission rate of a base station based on a CQI (Channel Quality Indicator) And an apparatus therefor.

Other objects and advantages of the present invention will become apparent from the following description, and it will be understood by those skilled in the art that the present invention is not limited thereto. It will also be readily apparent that the objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.

According to a first aspect of the present invention, there is provided a method for measuring quality of a mobile communication service in a quality measurement system, comprising: checking the number of concurrent users of a base station; Receiving a measured CQI from a plurality of mobile communication terminals located in coverage of the base station from each mobile communication terminal; And calculating an average of the received CQIs and calculating a data transmission rate of the base station using an average of the CQIs thus calculated and the number of concurrent users identified.

Preferably, the calculating step calculates a transmission rate inversely proportional to the number of concurrent users and proportional to the average of the CQIs, and places a larger weight on the average of the CQIs than the number of concurrent users.

More preferably, the step of calculating includes: determining a constant a, a number-of-contacts weight b, and a CQI weight c, which are applied according to the model of the base station, to the following equation; And calculating the data transmission rate by substituting the average number of concurrent users and the average of the CQIs into the following equation.

a: constant

b: Weight of users

c: CQI weight

The method of measuring quality of a mobile communication service in the quality measurement system may include: checking the number of GBR service users and the number of non-GBR service users of the base station; And measuring the load factor of the base station by substituting the number of GBR service users and the number of non-GBR service users into the following equation.

According to a second aspect of the present invention, there is provided a quality measuring apparatus comprising: a radio environment collector for receiving a CQI measured by a plurality of mobile communication terminals located in coverage of a base station from each mobile communication terminal; And a transmission rate measurement unit configured to calculate an average of the CQIs received by the radio environment collector and to measure a data transmission rate of the base station based on an average of the CQIs and the number of concurrent users identified, And the like.

The present invention has an advantage that a service quality experienced by a subscriber can be more accurately grasped by measuring a data transmission rate of a base station based on reported radio environment information of the mobile communication terminal and the number of concurrent users of the base station.

Further, the present invention has an effect of improving the quality of a mobile communication service by inducing a communication service provider to add a network device in a place where the service quality is deteriorated by grasping a data transmission rate and a load rate for each base station.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention. And shall not be construed as limited to such matters.
1 is a diagram illustrating a configuration of a communication quality measuring system according to an embodiment of the present invention.
2 is a diagram illustrating a configuration of a quality measurement server according to an embodiment of the present invention.
3 is a flowchart illustrating a method of measuring a communication service quality of a base station in a communication quality of service measurement system, according to an embodiment of the present invention.
4 is a diagram illustrating an electronic map in which a base station load factor is output according to an embodiment of the present invention.

The foregoing and other objects, features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, in which: There will be. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise. Also, the terms "part,"" module, "and the like, which are described in the specification, refer to a unit for processing at least one function or operation, and may be implemented by hardware or software or a combination of hardware and software.

1 is a diagram illustrating a configuration of a communication quality measuring system according to an embodiment of the present invention.

1, a communication service quality measuring system according to an embodiment of the present invention includes a plurality of mobile communication terminals 100-N and a quality measurement server 200. [

The mobile communication core network 300 includes an LTE (Long Term Evolution) core network, a WCDMA core network, a Code Division Multiple Access (CDMA) core network, a Wibro (Wireless Broadband) The mobility management of the mobile communication terminal 100-N, the establishment of the radio link, and the control of the transmission rate. In particular, the mobile communication core network 300 includes a base station 310 that performs wireless communication with the mobile communication terminal 100-N.

The base station 310 is a base station forming a cell of the mobile communication core network 300 and performs initial connection, inter-sector handover, and QoS control functions of the mobile communication terminal 100-N, 100-N, and transmits the radio signal to a destination. In addition, the base station 310 periodically broadcasts a radio signal including its identification information, thereby guiding the connection of the mobile communication terminal 100-N.

The mobile communication terminal 100-N is an apparatus capable of communicating with the mobile communication core network 300. The mobile communication terminal 100-N acquires identification information of the base station 310 and measures a CQI (Channel Quality Indicator) at the current location. 310 and the CQI to the quality measurement server 200. The CQI is measured from 0 to 15, and the higher the number of CQI is measured, the stronger the reception strength of the radio signal of the mobile communication terminal 100-N is. The mobile communication terminal 100-N includes a tablet computer, a WCDMA terminal, a CDMA terminal, an LTE terminal, a Wibro terminal, a smart phone, etc. and communicates with the quality measurement server 200 through the mobile communication core network 300 Possible devices are not limited and can be adopted.

The quality measuring server 200 measures and monitors the quality of the communication service for each region in which each base station is installed as a quality measuring device.

2 is a diagram illustrating a configuration of a quality measurement server according to an embodiment of the present invention.

2, the quality measurement server 200 according to an exemplary embodiment of the present invention includes a transmission / reception unit 210, a storage unit 220, a data management unit 230, a wireless environment acquisition unit 240, A measurement unit 250, and a transmission rate measurement unit 260.

The transceiver unit 210 performs a function of communicating with the mobile communication terminal 100-N through the mobile communication core network 300. [

The storage unit 220 stores the number of concurrent users currently connected to each base station 310 for each base station. Preferably, the storage unit 220 stores the number of users (referred to as 'GBR service users' hereinafter) and non-GBR (Non-GBR users) that are provided with GBR (Guaranteed Bit Rate) (Hereinafter referred to as "number of non-GBR service users") that are provided with Guaranteed Bit Rate-based services. Here, the GBR-based service is a service that is guaranteed a certain bandwidth, and is typically a voice call service. In addition, non-GBR-based services are services that are not guaranteed bandwidth, and services for transmitting and receiving wireless data packets, such as wireless Internet services and file transmission and reception services, are included.

The storage unit 220 stores base station identification information and mapped base station model information, and stores weights and constants applied to each base station model. In addition, the storage unit 220 stores the maximum number of GBR service recipients and the maximum number of non-GBR service recipients for each base station model.

The data management unit 230 manages the data stored in the storage unit 220. The data management unit 230 updates the number of simultaneous users of the base station 310 stored in the storage unit 220 when the number of concurrent users connected to the base station 310 varies. If the number of non-GBR service users or the number of GBR service users changes in the specific base station 310, the data management unit 230 stores the number of GBR or non-GBR service users of the corresponding base station 310 stored in the storage unit 220 Update.

The data management unit 230 can check the number of subscribers, the number of GBR service users, and the number of non-GBR service users connected to each base station 310 in cooperation with the mobile communication core network 300. For example, the data management unit 230 may be connected to each of the base stations 310 in cooperation with an HSS (Home Subscriber Server), an HLR (Home Location Register), and the like for taking charge of location registration of the mobile communication terminal 100- The data of the storage unit 220 can be updated by confirming the number of connected subscribers, the number of GBR service users, and the number of non-GBR service users. Alternatively, the data management unit 230 can periodically or real-time receive the number of concurrent users, GBR service users, and non-GBR service users from the base station 310 and update the data in the storage unit 220.

The radio environment acquiring unit 240 requests radio environment data from the mobile communication terminal 100-N connected to the specific base station 310 through the transceiver 210 and transmits the radio environment data to each mobile communication terminal 100-N And receives radio environment data including CQI and base station identification information.

The load-ratio measuring unit 250 measures the load factor of each base station 310. Specifically, the load factor measuring unit 250 checks the number of GBR service users and non-GBR service users of the base station 310 in the storage unit 220, and determines the number of GBR service users and the number of non-GBR service users And the load factor of the corresponding base station 310 is measured.

Here, the maximum number of GBR service recipients means the maximum number of users who can simultaneously provide the GBR-based service to the base station 310, and the maximum number of non-GBR service recipients indicates that the base station 310 is non- And the maximum number of users who can simultaneously provide services. The maximum number of GBR service recipients and the maximum number of non-GBR service recipients are set in the storage unit 210 according to the model of the base station. In addition, the load factor is measured between 0 and 200%. For example, the load factor measurement unit 250 may determine that the maximum number of GBR service recipients is 200, the maximum number of Non-GBR service recipients is 5, the number of GBR service users is 20 in the storage unit 220, , The load factor of the base station 310 is measured to be 30%.

Preferably, the load factor measuring unit 250 displays the measured load factor of the base station 310 on the electronic map on which the installation location of the base station 310 is recorded, and allows the manager to recognize the load factor of the base station 310 . More specifically, the load factor measurement unit 250 maps the measurement time, the measured load factor, and the identification information of the base station to be measured, and stores the mapped information in the storage unit 220. Based on the time- It is possible to analyze the load rate trend of each base station by time slot and output it to the monitor.

The transmission rate measuring unit 260 calculates the average data transmission rate of each base station 310 based on the radio environment data acquired by the radio environment acquiring unit 240. Specifically, the transmission rate measuring unit 260 collects the CQI values of a plurality of mobile communication terminals 100-N connected by the specific base station 310 using the radio environment acquiring unit 240, The average of the values is calculated. In addition, the base station management server 200 confirms the number of concurrent connected users connected to the specific base station 310 in the storage unit 220, and calculates the average of the concurrent connected users and the calculated CQI value by the following equation (2) And the average data transmission rate of the base station is measured. Preferably, the transmission rate measurer 260 checks the CQI weight, the number of connected users, and the constant applied in accordance with the model of the specific base station 310 in the storage unit 220, and applies the CQI weight, The CQI weight stored in the storage unit 220 is stored in the storage unit 210 so that the CQI weight value is inversely proportional to the number of concurrent users and is proportional to the size of the CQI. It is bigger. Here, the connection number weight (i.e., b in Equation 1) exceeds 0 and has a range of less than 1, and the CQI weight (c in Equation 1) is a real number exceeding '1'.

a: constant

b: Weight of users

c: CQI weight

The transmission rate measuring unit 260 displays an average data transmission rate of the measured base station 310 on an electronic map showing the installation location of the base station 310 to allow the manager to recognize the load factor of the base station 310 . More specifically, the transmission rate measuring unit 260 maps the measurement time, the measured data transmission rate, and the identification information of the base station to be measured to the storage unit 220, and transmits the time- It is possible to analyze the transmission rate fluctuation trend of each base station according to the time zone and to output it to the monitor.

3 is a flowchart illustrating a method of measuring a communication service quality of a base station in a communication quality of service measurement system, according to an embodiment of the present invention.

Referring to FIG. 3, the load factor measuring unit 250 checks the number of GBR service users and non-GBR service users of the base station 310, which is the load factor measurement target, in the storage unit 220, (S301). The load factor measuring unit 250 checks the model of the BS 250 and checks the maximum number of GBR service adopters and the maximum number of non-GBR service users applied in the storage unit 210 according to the model of the BS 250 .

Then, the load factor measuring unit 250 substitutes the number of GBR service users, non-GBR service users, maximum GBR service users, and maximum non-GBR service users into the equation (1) The load factor is measured (S303). Then, the load factor measuring unit 250 displays the measured load factor of the base station 310 on an electronic map showing the installation location of the base station 310 to allow the manager to recognize the load factor of the base station 310 (S305) .

4 is a diagram illustrating an electronic map in which a base station load factor is output according to an embodiment of the present invention.

As shown in Fig. 4, the load factor of each base station on the electronic map is output to the base station installation point. In FIG. 4, circles of different colors are output to the base station installation point according to the numerical value of the load factor of the base station. For example, the green circle indicates that the base station load ratio is less than 60% and is more than 30%, and the blue circle may indicate that the base station load ratio is less than 30%.

Next, the transmission rate measuring unit 260 instructs the radio environment obtaining unit 240 to collect the CQI of the mobile communication terminal 100-N being connected to the base station 310. [ The radio environment acquiring unit 240 broadcasts a CQI measurement request through the base station 310 and transmits a CQI value measured by each mobile communication terminal 100-N connected to the base station 310 And acquires the CQI value, which is the radio environment information of each mobile communication terminal 100-N, by receiving it to each mobile communication terminal 100-N (S307).

When the wireless environment acquisition unit 240 collects one or more CQI values, the transmission rate measurement unit 260 calculates the average of the collected CQI values (S309). Next, the transmission rate measurer 260 confirms the model of the base station 310 and confirms constants and weights applied to the model in the storage unit 220 and applies the constants and the weights to Equation 2 (S311). That is, the transmission rate measurer 260 checks the constants a, the number of connected users b, and the CQI weight c applied in accordance with the model of the base station 310 in the storage unit 220, A, b, and c are substituted into a, b, and c in Equation (2), respectively. Preferably, the transmission rate measurer 260 calculates the transmission rate weight b and the CQI weight c, which are inversely proportional to the number of concurrent users of the base station 310 and proportional to the size of the CQI, . More preferably, the transmission rate measurer 260 applies the CQI weight c, which is larger than the number-of-connections weight b, to Equation (2).

Next, the transmission rate measuring unit 260 checks the number of concurrent users connected to the base station 310 in the storage unit 220, and substitutes the number of concurrent users and the calculated average CQI into the equation (2) The average data transmission rate of the base station is measured (S313). Then, the transmission rate measuring unit 260 outputs the average data transmission rate of the measured base station 310 on the electronic map on which the installation location of the base station 310 is displayed, and allows the manager to determine whether the load rate of the base station 310 is (S315). At this time, the transmission rate measurer 260 can output numerical information indicating the average data transmission rate of each base station to the base station installation point on the electronic map. Alternatively, the transmission rate measuring unit 260 may output, on the electronic map, preference information indicating the average data rate of each base station to the installation point of the base station. For example, when the average data transmission rate of the base station 310 is less than 2 Mbps and is 1 Mbps or more, the transmission rate measurement unit 260 may output a yellow triangle to a point where the base station 310 is installed, If the average data transmission rate is less than 200 Kbps, a red triangle may be output to the point where the base station 310 is installed.

As described above, the communication service quality measuring system according to the present invention calculates and monitors the data transmission rate of the base station based on the CQI, which is the reported radio environment information of the mobile communication terminal 100-N, and the number of concurrent users of the base station, And more accurately grasps the service quality that the subscriber is experiencing. In addition, the communication service quality measurement system can determine the data transmission rate and the load rate for each base station, thereby enabling the communication service provider to increase the capacity of the network device in a place where the service quality is deteriorated.

While the specification contains many features, such features should not be construed as limiting the scope of the invention or the scope of the claims. In addition, the features described in the individual embodiments herein may be combined and implemented in a single embodiment. Conversely, various features described in the singular < Desc / Clms Page number 5 > embodiments herein may be implemented in various embodiments individually or in combination as appropriate.

Although the operations have been described in a particular order in the figures, it should be understood that such operations are performed in a particular order as shown, or that all described operations are performed to obtain a sequence of sequential orders, or a desired result . In certain circumstances, multitasking and parallel processing may be advantageous. It should also be understood that the division of various system components in the above embodiments does not require such distinction in all embodiments. The above-described program components and systems can generally be implemented as a single software product or as a package in multiple software products.

The method of the present invention as described above can be implemented by a program and stored in a computer-readable recording medium (CD-ROM, RAM, ROM, floppy disk, hard disk, magneto optical disk, etc.). Such a process can be easily carried out by those skilled in the art and will not be described in detail.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. The present invention is not limited to the drawings.

100: mobile communication terminal 200: quality measurement server
210: Transmitting / receiving unit 220:
230: Data management unit 240: Wireless environment acquisition unit
250: load ratio measuring unit 260: transmission rate measuring unit
300: mobile communication core network 310: base station

Claims (9)

A method for measuring quality of a mobile communication service in a quality measurement system,
Confirming the number of concurrent users of the base station;
Receiving a measured CQI from a plurality of mobile communication terminals located in coverage of the base station from each mobile communication terminal; And
Calculating an average of the received CQIs and calculating a data transmission rate of the base station using an average of the calculated CQIs and the number of concurrent users identified,
The calculating step
Wherein the data transmission rate is calculated by applying a CQI weight which is a real number exceeding 1 and a connection number weight which is a real number of more than 0 and less than 1. delete A method for measuring quality of a mobile communication service in a quality measurement system,
Confirming the number of concurrent users of the base station;
Receiving a measured CQI from a plurality of mobile communication terminals located in coverage of the base station from each mobile communication terminal; And
Calculating an average of the received CQIs and calculating a data transmission rate of the base station using an average of the CQIs thus calculated and the number of concurrent users identified;
Wherein the calculating step comprises:
Determining a constant a, a number-of-contacts weight b, and a CQI weight c, which are applied according to the model of the base station, to the following Equation 3; And
And calculating the data transmission rate by substituting the number of concurrent users and the average of the CQIs into the following equation (3).
(3)

a: constant
b: Weight of users
c: CQI weight A method for measuring quality of a mobile communication service in a quality measurement system,
Confirming the number of concurrent users of the base station;
Receiving a measured CQI from a plurality of mobile communication terminals located in coverage of the base station from each mobile communication terminal;
Calculating an average of the received CQIs and calculating a data transmission rate of the base station using an average of the CQIs thus calculated and the number of concurrent users identified;
Confirming the number of GBR service users and the number of non-GBR service users of the base station; And
And measuring the load factor of the base station by substituting the number of confirmed GBR service users and the number of non-GBR service users into Equation (4) below.
(4)

5. The method of claim 4,
And outputting the calculated data transmission rate of the base station or the measured load factor of the base station to a map on which the installation point of the base station is displayed. A radio environment collector for receiving CQIs measured by a plurality of mobile communication terminals located in a coverage of the base station from each mobile communication terminal; And
A transmission rate measurement unit for measuring the data transmission rate of the base station based on the average of the CQIs and the number of concurrent users identified by checking the number of concurrent users of the base station, ; ≪ / RTI >
The transmission rate measuring unit
And a CQI weight which is a real number exceeding 1 and a real number exceeding 1, to calculate the data transmission rate. delete A radio environment collector for receiving CQIs measured by a plurality of mobile communication terminals located in a coverage of the base station from each mobile communication terminal; And
A transmission rate measurement unit for measuring the data transmission rate of the base station based on the average of the CQIs and the number of concurrent users identified by checking the number of concurrent users of the base station, Lt; / RTI >
Wherein the transmission rate measuring unit comprises:
The number of concurrent users and the average of the CQIs are applied to Equation (5) as follows: " (5) " And measures the data transmission rate.
(5)

a: constant
b: Weight of users
c: CQI weight A radio environment collector for receiving CQIs measured by a plurality of mobile communication terminals located in a coverage of the base station from each mobile communication terminal;
A transmission rate measurement unit for measuring the data transmission rate of the base station based on the average of the CQIs and the number of concurrent users identified by checking the number of concurrent users of the base station, ; And
A load factor measuring unit for measuring the load factor of the base station by checking the number of GBR service users and non-GBR service users of the base station and substituting the number of confirmed GBR service users and non-GBR service users into Equation (6) And a quality measuring device
(6)

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