KR102349526B1 - Method for managing quality of network - Google Patents

Abstract

A network quality management method according to an embodiment of the present invention includes the steps of installing a network quality measurement tool in a plurality of user terminals connectable to a network; transmitting and receiving packets for network quality measurement between one user terminal among the plurality of user terminals and one or more counterpart user terminals through the network; and statistically processing, by a network quality management apparatus, a result of network quality measurement between the one user terminal and the counterpart user terminal.

Description

METHOD FOR MANAGING QUALITY OF NETWORK

The present invention relates to a network quality management method.

The communication requirements of the 4th industrial revolution and 5G era are characterized by ultra-low latency, ultra-connectivity and ultra-high-capacity transmission. Accordingly, the importance of a highly reliable network quality management system is growing in accelerating business.

In addition, accurate diagnosis of network failures, data reliability, and service level agreement (SLA) evaluation tools are required.

As 5G is being introduced in Korea and the United States while the importance of technology to more stably manage data usage and a wider range of communication services is increasing, the demand for measurement and management of related network quality is expected to increase.

Patent Publication 10-2019-0004970 (published date: January 15, 2019)

A network quality management method according to an embodiment of the present invention is to improve the reliability of network quality and measure the quality of a distributed network.

The task of the present application is not limited to the task mentioned above, and another task that is not mentioned will be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, the method comprising: installing a network quality measurement tool to a plurality of user terminals connectable to a network; transmitting and receiving packets for network quality measurement between one user terminal among the plurality of user terminals and one or more counterpart user terminals through the network; There is provided a network quality management method comprising the step of statistically processing, by a network quality management apparatus, a result of a network quality measurement between the one user terminal and the counterpart user terminal.

The network quality measurement tool of the one user terminal transmits the network quality measurement packet to the counterpart user terminal at a preset time to derive a network quality measurement result, and transmits the network quality measurement result to the network quality management apparatus , and the network quality management apparatus may statistically process the network quality measurement result between the one user terminal and the counterpart user terminal, and display it through the user terminal connected to the network quality management apparatus.

The network quality management apparatus receives the IP address of each of the plurality of user terminals from the network quality measurement tool installed in each of the plurality of user terminals, and receives an ISP (Inernet Service Provider) of the user terminal through the IP address and the statistically processed network quality measurement result for the ISP may be displayed through the user terminal connected to the network quality management device.

The network quality management apparatus receives a dynamic IP address from one or more user terminals among the plurality of user terminals, receives a unique identification code generated by the network quality measurement tool from the one or more user terminals, and the dynamic IP address The address and the unique identification code are matched and stored, and when the dynamic IP address is changed, the unique identification code can be matched with the changed IP address and stored.

The network quality management apparatus may receive a selection command for selecting the counterpart user terminal from the one user terminal, and transmit and receive the network quality measurement packet between the one user terminal and the selected counterpart user terminal. have.

The network quality measurement tool of the one user terminal transmits a packet for network quality measurement corresponding to each of the first upload bandwidth and the second upload bandwidth in the order of size to the counterpart user terminal, and measures the network quality of the counterpart user terminal The tool transmits a packet loss for each packet for network quality measurement corresponding to the first upload bandwidth and a packet for network quality measurement corresponding to the second upload bandwidth to the user terminal or the network quality management device. transmit, wherein the one user terminal or the network quality management device has a packet loss for a packet for network quality measurement corresponding to the first upload bandwidth is less than or equal to a reference value, and for network quality measurement corresponding to the second upload bandwidth If the packet loss for each packet is greater than the reference value, the first upload bandwidth may be determined as the upload bandwidth of the one user terminal.

Network quality management as the network quality measurement tool of the one user terminal transmits a packet for network quality measurement corresponding to each of the first upload bandwidth and the second upload bandwidth in the order of size to the counterpart user terminal at each predetermined bandwidth measurement period The device determines the upload bandwidth of the one user terminal for each bandwidth measurement period, and when the upload bandwidth is determined in the bandwidth measurement period, packet loss without transmitting a network quality measurement packet for upload bandwidth measurement during the bandwidth measurement period can be measured.

The network quality management apparatus may predict the determined upload bandwidth according to the measured packet loss.

The network quality management apparatus may determine the determined upload bandwidth as the download bandwidth of the counterpart user terminal.

The network quality management method according to an embodiment of the present invention can improve the reliability of the network quality and measure the quality of the distributed network by measuring the network quality between user terminals.

The effect of the present application is not limited to the above-mentioned effects, and another effect not mentioned will be clearly understood by those skilled in the art from the following description.

1 and 3 are diagrams for explaining a network quality management method according to an embodiment of the present invention.
2 is a diagram for explaining a general network quality management method.
4 illustrates a result of measuring network quality between one user terminal and a counterpart user terminal.
5 and 6 are diagrams for explaining network quality measurement for an ISP.
7 illustrates an example of a user graphic interface provided by the network quality management apparatus for measuring network quality between a specific user terminal and a counterpart user terminal.
8 shows an example of a user graphic interface for managing a counterpart user terminal.
9 is a diagram for explaining measurement of upload bandwidth among network quality measurement items.
10 is a diagram for explaining correction of upload bandwidth using packet loss.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the accompanying drawings are only described to more easily disclose the contents of the present invention, and those of ordinary skill in the art can easily understand that the scope of the present invention is not limited to the scope of the accompanying drawings. you will know

In addition, the terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise.

In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

1 and 3 are diagrams for explaining a network quality management method according to an embodiment of the present invention. Also, FIG. 2 is a diagram for explaining a general network quality management method.

1 and 3 , the method for managing network quality according to an embodiment of the present invention includes the steps of installing a network quality measuring tool in a plurality of user terminals T1 to T8 connectable to a network, a plurality of Network quality measurement packets between one user terminal (eg, T1 in FIG. 3) and one or more other user terminals (eg, T2 to T8 in FIG. 3) among the user terminals T1 to T8 of the network Transmitting and receiving through , and the network quality management apparatus 100 statistically processing the results of network quality measurement between one user terminal T1 and the other user terminal T2 to T8.

The network quality management apparatus 100 may be a computing device capable of performing server-client communication with the user terminals T1 to T8.

Although eight user terminals T1 to T8 are shown in FIGS. 1 to 3 , this is only an example and the number of user terminals may vary.

In the case of a general network quality management method, as shown in FIG. 2 , an Internet Service Provider (ISP) manages network quality through its own network quality management server 10 .

The ISP's network quality management server 10 transmits a network quality measurement packet to the user terminals T1 to T8 subscribed to the ISP through a predetermined path and receives a response from the user terminals T1 to T8. quality can be measured.

As such, the general network quality management method has a limitation in measuring the network quality more objectively as it is performed through a predetermined path.

In addition, since it is difficult to measure the network quality in the path between the user terminal T1 and the user terminal T3 without going through the network quality management server 10 in the general network quality management method, block chain (BLOCK CHAIN) or bit It is not suitable for measuring the quality of distributed networks such as BIT TORRENT.

On the other hand, in the network quality management method according to the embodiment of the present invention, packets for network quality measurement are transmitted and received between the user terminals T1 to T8 without going through the network quality management apparatus 100 and not on a predetermined path, so that the user terminal T1 A network quality measurement between ~T8) can be performed.

That is, in the general network quality management method, the quality measurement result for a predetermined path can be known and others cannot be known. In the present invention, the network quality between the user terminals T1 to T8 participating in the user participation type can be known.

Accordingly, the network quality management method according to an embodiment of the present invention can perform objective network quality measurement as well as quality measurement on a distributed network.

A packet for network quality measurement transmitted in the network quality management method according to an embodiment of the present invention may satisfy a two-way active measurement protocol (hereinafter, TWAMP: Two-Way Active Measurement Protocol). TWAMP is a protocol for quality measurement of high-speed networks such as 5G mobile communication networks, and can implement precise and real-time network quality measurement.

General quality management performed by ISPs is based on ICMP (Internet Control Message Protocol), and the unit of measurement result according to ICMP is 10 ^-3 seconds, but the unit of measurement result according to TWAMP is 10 ^-6 seconds. do.

A network quality management method according to an embodiment of the present invention includes TWAMP-based packet loss measurement, TWAMP-based packet re-order detection, TWAMP-based duplicate packet detection, and TWAMP-based Packet Delay Variation (PDV). ) measurement, TWAMP-based IP Packet Delay Variation (IPDV) measurement, TWAMP-based upload bandwidth (UPLOAD BANDWIDTH) prediction, and TWAMP-based download bandwidth (DOWNLOAD BANDWIDTH) prediction can be performed.

The user terminals T1 to T8 may be a dedicated network quality measurement device in which the network quality measurement tool is installed in the form of firmware, or may be a desktop computer, a laptop computer, a tablet computer, or a smartphone in which the network quality measurement tool in the form of an application program can be installed. However, the present invention is not limited thereto.

In the network quality management method according to an embodiment of the present invention, each of the user terminals T1 to T8 installed with the network quality measurement tool includes the IP address of the user terminals T1 to T8 and the operating system through a boot strap during the booting process. , MAC address and information on architecture may be transmitted to the network quality management apparatus 100 .

Alternatively, the network quality measurement tool may transmit IP addresses, operating systems, MAC addresses, and architecture information of the user terminals T1 to T8 to the network quality management apparatus 100 .

Information obtained from the user terminals T1 to T8 is not limited to information about an IP address, an operating system, a MAC address, and an architecture.

The network quality management apparatus 100 may store the IP addresses of the user terminals T1 to T8 in which the network quality measurement tool is installed, and transmit at least some of the entire IP addresses to the user terminals T1 to T8.

The network quality measuring tool of the user terminals T1 to T8 may store the at least some of the IP addresses transmitted from the network quality management apparatus 100 in the user terminals T1 to T8. As shown in FIG. 3 , one user terminal T1 among the plurality of user terminals T1 to T8 transmits a packet for network quality measurement to the other user terminals T2 to T8 using the stored IP addresses. can

The network quality measurement tool of the counterpart user terminals T2 to T8 may receive the packet for network quality measurement and transmit the network quality measurement result to the one user terminal T1.

The network quality measurement tool of one user terminal T1 may transmit the network quality measurement result received from the other user terminals T2 to T8 to the network quality management apparatus 100 .

The network quality management apparatus 100 may store the network quality measurement results between one user terminal T1 and each of the other user terminals T2 to T8.

Such a process may be performed for each of the user terminals T2 to T8, and accordingly, the network quality management apparatus 100 checks the network quality measurement result between one user terminal T1 and each of the other user terminals T2 to T8. 4 may be stored.

The network quality measurement results are the previously described TWAMP-based packet loss measurement, TWAMP-based packet re-order detection, TWAMP-based duplicate packet detection, TWAMP-based PDV (Packet Delay Variation) measurement, TWAMP Based on IP Packet Delay Variation (IPDV) measurement, TWAMP-based upload bandwidth (UPLOAD BANDWIDTH) measurement, and TWAMP-based download bandwidth (DOWNLOAD BANDWIDTH) measurement may be, but are not limited thereto.

The user terminals T1 to T8 may access the network quality management apparatus 100 and check the network quality measurement result between one user terminal T1 among T1 to T8 and each other user terminal T2 to T8. .

That is, the general network quality management method only provides the network quality measurement result between the ISP's network quality management server 10 and the user terminal subscribed to the ISP to the user. Therefore, it is difficult for the user to check the network quality measurement result of a user terminal other than his or her own terminal, and accordingly, it is difficult to confirm whether the user is provided with a differentiated network service from other users.

On the other hand, the network quality management method according to the embodiment of the present invention discloses the network quality measurement results between the user terminals T1 to T8 to all users as shown in FIG. 4 , so that users can compare and check each other's network quality. have.

The download of the network quality measurement tool to the user terminals T1 to T8 may be performed by the network quality management apparatus 100, and the network quality management apparatus 100 determines the type of OS and the OS of the user terminals T1 to T8. A network quality measurement tool that satisfies the version may be provided.

On the other hand, the network quality measurement tool of one user terminal (eg, T1 in FIG. 3 ) transmits a packet for network quality measurement to the other user terminal (eg, T2 to T8 in FIG. 3 ) at preset times. Thus, a network quality measurement result may be derived, and the network quality measurement result may be transmitted to the network quality management apparatus 100 .

In this case, the preset time may be 1 minute, 5 minutes, or 10 minutes, but is not limited thereto, and may be larger or smaller than this.

The network quality management apparatus 100 statistically processes the network quality measurement result between one user terminal (eg, T1 in FIG. 3 ) and the other user terminal (eg, T2 to T8 in FIG. 3 ) to perform network quality The display may be performed through the user terminals T1 to T8 connected to the management device 100 . Statistical processing may be an hourly average, a daily average, a weekly average, a monthly average, etc., but is not limited thereto. For example, a standard deviation or variance of the measurement result may be calculated.

As described above, when the network quality management method according to the embodiment of the present invention performs statistical processing, since network quality measurement is performed every preset time, a plurality of result values exist for each network quality item. By statistical processing, a representative value for each network quality item can be provided to the user.

On the other hand, the general network quality method does not automatically measure the network quality periodically, but only measures the network quality when the user wants it. It is difficult for users to trust the measurement results.

Meanwhile, as described above, the network quality management apparatus 100 may receive the IP address of each of the plurality of user terminals T1 to T8 from the network quality measurement tool installed in each of the plurality of user terminals T1 to T8. have. At this time, the network quality management apparatus 100 may check the ISP (Inernet Service Provider) of the user terminals T1 to T8 through the IP address.

The network quality management apparatus 100 may display the statistically processed network quality measurement results for the ISP through the user terminals T1 to T8 connected to the network quality management apparatus 100 .

For example, as shown in FIG. 5 , the ISP to which the user subscribes may be different. It is possible to check the ISP through the IP addresses of the user terminals (T1 to T8). As described above, since the network quality management apparatus 100 collects IP addresses of the user terminals T1 to T8, the network quality management apparatus 100 connects the user terminals T1 to T8 through the collected IP addresses. You can check with one ISP.

In addition, the network quality management apparatus 100 statistically processes the network quality measurement results between one user terminal (eg, T1 in FIG. 3 ) and the other user terminal (eg, T2 to T8 in FIG. 3 ). can

That is, as shown in FIG. 5 , as a result of network quality measurement between ISP A and ISP A providing communication services between T1 and T2 and between T1 and T3, communication services between T1 and T4 and between T1 and T5 are provided. As a result of the network quality measurement of ISPs A and B, the network quality measurement result of ISPs A and ISP C providing communication services between T1 and T6, between T1 and T7, and between T1 and T8 may be derived.

Through this, network quality measurement for each ISP A to ISP C may be derived, and as the number of user terminals T1 to T8 increases, a more objective network quality measurement for the ISP may be possible.

Meanwhile, the network quality management apparatus 100 may receive a floating IP address from one or more of the plurality of user terminals T1 to T8 (eg, T1 to T8 in FIG. 3 ). The user terminals T1 to T8 subscribed to the ISP may be assigned a dynamic IP address, and accordingly, the IP addresses of the user terminals T1 to T8 may change.

Also, the network quality management apparatus 100 may receive the unique identification code generated by the network quality measurement tool from one or more user terminals T1 to T8. In a process in which the network quality measurement tool is installed in the user terminals T1 to T8, a unique identification code for identifying the user terminals T1 to T8 may be generated. Even if the IP addresses of the user terminals T1 to T8 are changed, the unique identification codes of the user terminals T1 to T8 may be constantly maintained.

The network quality management apparatus 100 may match and store the dynamic IP address and the unique identification code, and when the dynamic IP address is changed, match and store the unique identification code with the changed IP address.

That is, the user terminals T1 to T8 may transmit the unique identification code together while transmitting the dynamic IP address to the network quality management apparatus 100 . Accordingly, the user can identify the counterpart user terminals T2 to T8 through the unique identification code even if the IP addresses of the counterpart user terminals T2 to T8 are changed.

For example, as shown in FIG. 7 , the user inputs the IP address of his/her user terminal (eg, T1 in FIG. 3 ) into the network quality management apparatus 100 , and the user wants the other party's user. The IP address of the terminal (eg, T2 in FIG. 3 ) may be input. Then, when the user touches or clicks 'View' by manipulating the input unit (eg, keyboard, mouse, touch screen, etc.) of his/her user terminal T1, the network quality management apparatus 100 controls the user terminal T1. A network quality measurement result between the user terminal T2 and the counterpart user terminal T2 may be provided to the user terminal T1.

In this way, the user can directly input the IP address of the counterpart user terminal T2, and when the IP address of the counterpart user terminal T2 is a dynamic IP address and is changed, between the user terminal T1 and the counterpart user terminal T2. may not be able to measure the network quality of

In this case, the user searches the network quality management apparatus 100 for the changed IP address of the counterpart user terminal T2 through the unique identification code of the counterpart user terminal T2, and inputs the searched changed IP address to the user terminal T1. ) and the network quality measurement between the counterpart user terminal T2 can be checked.

Meanwhile, the network quality management apparatus 100 may receive a selection command for selecting a counterpart user terminal from one user terminal. The other user terminal may be selected from the list of all user terminals, and as shown in FIG. 8, the user clicks or touches 'device registration' through the input unit of the user terminal and inputs the IP address of the other user terminal to select the other user terminal. it might be

Accordingly, a packet for network quality measurement may be transmitted/received between one user terminal and the selected counterpart user terminal.

For example, as shown in FIG. 3 , the network quality management method according to an embodiment of the present invention measures the network quality of one user terminal (eg, T1) and the other user terminals (T2 to T8). It is also possible to perform network quality measurement between one user terminal (eg, T1) and some other user terminals (eg, T2, T3, T5) selected among the other user terminals (T2 to T8). can also be done

That is, when there are many user terminals T1 to T8 registered with IP information, network quality measurement with each user terminal may be excessive. Accordingly, the user selects a desired counterpart user terminal so that the user's desired network quality measurement can be made.

Meanwhile, the network quality measurement tool of one user terminal (eg, T1 in FIG. 3 ) transmits a first upload bandwidth and a second upload bandwidth to the other user terminal (eg, T4 in FIG. 3 ) in order of size. A packet for measuring network quality corresponding to each bandwidth may be transmitted.

For example, as shown in FIG. 9 , one user terminal T1 may transmit a packet for measuring network quality corresponding to 80 Mbps, 90 Mbps, and 100 Mbps to the other user terminal T4.

At this time, the network quality measurement tool of the counterpart user terminal T4 measures a packet loss for each of the packet for network quality measurement corresponding to the first upload bandwidth and the packet for network quality measurement corresponding to the second upload bandwidth. It can be transmitted from the counterpart user terminal T4.

For example, as shown in FIG. 9 , one user terminal T1 transmits a packet for network quality measurement corresponding to 80 Mbps to the other user terminal T4, and the other user terminal T4 transmits the corresponding packet. The loss may be transmitted to the user terminal T1 or the network quality management apparatus 100 .

Subsequently, one user terminal T1 transmits a packet for network quality measurement corresponding to 90 Mbps and 100 Mbps to the other user terminal T4, and the other user terminal T4 calculates the corresponding packet loss to the user terminal T1 or the network. may be transmitted to the quality control device 100 .

The user terminal T1 or the network quality management apparatus 100 has a packet loss for a packet for network quality measurement corresponding to the first upload bandwidth is less than or equal to a reference value, and to each packet for network quality measurement corresponding to the second upload bandwidth. If the packet loss is greater than the reference value, the first upload bandwidth may be determined as the upload bandwidth of one user terminal T1.

For example, as shown in FIG. 9 , if the packet loss for the network quality measurement packet corresponding to 90Mbps is less than or equal to the reference value, and the packet loss for the network quality measurement packet corresponding to 100Mbps is greater than the reference value, the user terminal The upload bandwidth of (T1) may be 100 Mbps.

In the example described above, the upload bandwidth is 80 Mbps to 100 Mbps, but this is only an example and is not limited thereto.

When an ISP and a user sign a contract for a communication service, the ISP can guarantee a certain amount of upload bandwidth to the user. However, since the general network quality measurement method is performed through a predetermined path between the ISP and the user's terminal, the reliability of the measurement result may be reduced.

The network quality management method according to an embodiment of the present invention measures the upload bandwidth between the user terminals T1 to T8 without measuring the upload bandwidth in a predetermined path without the ISP leading it, so that a more reliable measurement result can be derived. have.

As described above, in the case of the network quality management method according to the embodiment of the present invention, since the upload bandwidth is measured without the involvement of the ISP, the upload bandwidth guaranteed by the ISP to each user may not be grasped.

Accordingly, the user terminal T1 may transmit the packet for network quality measurement by gradually increasing the upload bandwidth. If the packet loss is greater than the reference value, it may mean that the network between the user terminals T1 and T4 does not satisfy the upload bandwidth with the large packet loss.

Accordingly, one user terminal T1 or the network quality management apparatus 100 may determine the largest value among the upload bandwidths in which the packet loss is smaller than the reference value as the upload bandwidth of the user terminal T1.

Accordingly, the user can check whether the upload bandwidth contracted to be provided by the ISP is implemented in actual communication. In addition, the user can check how much bandwidth the user wants to upload to the other user's terminal.

Meanwhile, as shown in FIG. 10 , the network quality measurement tool of one user terminal (eg, T1 in FIG. 3 ) is sized to the other user terminal (eg, T3 in FIG. 3 ) every predetermined bandwidth measurement period. In order, packets for measuring network quality corresponding to each of the first upload bandwidth and the second upload bandwidth may be transmitted. Accordingly, the network quality management apparatus 100 may determine the upload bandwidth of one user terminal T1 for each bandwidth measurement period.

In this case, when the upload bandwidth is determined in the bandwidth measurement period, packet loss may be measured during the bandwidth measurement period without transmitting a packet for measuring network quality for upload bandwidth measurement.

For example, when the bandwidth measurement period is 1 day, as shown in FIG. 10 , the upload bandwidth may be determined once a day. If the upload bandwidth once a day is determined, there may be no transmission of a packet for network quality measurement for upload bandwidth measurement until the next upload bandwidth is determined.

The reason for this is that, since the data amount of the packet for measuring the network quality for measuring the upload bandwidth is large, the operation of the user terminal is not normally performed while the packet for measuring the network quality for measuring the upload bandwidth is transmitted (eg, streaming). disconnection, Internet connection speed drop, etc.) may occur. If such an abnormal operation occurs frequently, user dissatisfaction may increase.

Therefore, the upload bandwidth may be determined once during the bandwidth measurement period, and when the upload bandwidth is determined, the packet loss may be measured during the bandwidth measurement period without transmission of a packet for network quality measurement for upload bandwidth measurement. In this case, packet loss may be measured based on TWAMP. Based on TWAMP, the packet loss rate is calculated between two points within 1 second, so it may not significantly affect users' network usage.

In the above description, the bandwidth measurement period is one day, but the present invention is not limited thereto, and the bandwidth measurement period may be greater or smaller than one day depending on the design.

Meanwhile, the network quality management apparatus 100 may predict the upload bandwidth determined according to the measured packet loss. As described above with reference to FIG. 10 , the determination of the upload bandwidth may be made once during one bandwidth measurement period, and thereafter, the determination of the upload bandwidth may not be made.

In this case, the packet loss may be continuously measured for one period, and an upload bandwidth determined according to the measured packet loss may be predicted. For example, an artificial intelligence may derive a packet loss rate between user terminals by learning a plurality of packet loss measurements. The prediction of the upload bandwidth may be performed by updating the upload bandwidth according to the derived packet loss rate.

Alternatively, if the packet loss is 0.1% after the upload bandwidth is determined to be 90Mbps in the nth cycle in FIG.

Meanwhile, the network quality management apparatus 100 may determine the determined upload bandwidth as the download bandwidth of the counterpart user terminal. That is, in the present invention, since the network quality between one user terminal (eg, T1 in FIG. 3 ) and the other user terminal (eg, T3 in FIG. 3 ) is measured, upload of one user terminal (T1) The bandwidth may be the download bandwidth of the counterpart user terminal T3.

Accordingly, even if a separate download bandwidth is not measured, the download bandwidth of the counterpart user terminal may be determined through the upload bandwidth measurement.

As described above, the embodiments according to the present invention have been reviewed, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope of the present invention in addition to the above-described embodiments is recognized by those with ordinary skill in the art. It is self-evident to Therefore, the above-described embodiments are to be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description, but may be modified within the scope of the appended claims and their equivalents.

User terminals (T1~T8)
Network Quality Management Device (100)

Claims (9)

A method comprising: installing a network quality measurement tool in a plurality of user terminals connectable to a network;
transmitting and receiving packets for network quality measurement between one user terminal among the plurality of user terminals and a plurality of counterpart user terminals through the network;
and statistically processing, by a network quality management device, a result of network quality measurement between the one user terminal and the counterpart user terminal,
The network quality management device receives and stores IP addresses from the one user terminal and the plurality of counterpart user terminals,
the one user terminal receives the IP addresses of the plurality of counterpart user terminals received from the network quality management device and transmits the network quality measurement packet to the plurality of counterpart user terminals;
Each of the plurality of counterpart user terminals transmits a network quality measurement result according to the network quality measurement packet to the one user terminal,
the one user terminal transmits the network quality measurement result transmitted from each of the plurality of counterpart user terminals to the network quality management device;
The network quality management apparatus provides the network quality measurement result of each of the one user terminal and the plurality of counterpart user terminals through the one user terminal,
The network quality management device,
receiving, from the plurality of user terminals, the dynamic IP addresses of the plurality of user terminals obtained through a boot strap during the booting process of the plurality of user terminals;
Receiving the unique identification code generated by the network quality measurement tool from the plurality of user terminals,
Match and store the dynamic IP address and the unique identification code,
When the dynamic IP address is changed, the network quality management method characterized in that the unique identification code is matched with the changed IP address and stored.
According to claim 1,
The network quality measurement tool of the one user terminal transmits the network quality measurement packet to the counterpart user terminal at a preset time to derive a network quality measurement result, and transmits the network quality measurement result to the network quality management apparatus send to
wherein the network quality management device statistically processes the network quality measurement result between the one user terminal and the counterpart user terminal, and displays it through the user terminal connected to the network quality management device. .
3. The method of claim 2,
The network quality management device,
receiving the IP address of each of the plurality of user terminals from the network quality measurement tool installed in each of the plurality of user terminals;
Check the ISP (Internet Service Provider) of the user terminal through the IP address,
and displaying the statistically processed network quality measurement result for the ISP through the user terminal connected to the network quality management device.
delete 4. The method according to any one of claims 1 to 3,
The network quality management device,
receiving a selection command for selecting the counterpart user terminal from the one user terminal;
The network quality management method, characterized in that the packet for measuring the network quality is transmitted/received between the one user terminal and the selected counterpart user terminal.
According to claim 1,
The network quality measurement tool of the one user terminal,
transmitting a packet for measuring network quality corresponding to each of the first upload bandwidth and the second upload bandwidth in the order of size to the counterpart user terminal;
The network quality measurement tool of the counterpart user terminal,
transmitting a packet loss for each packet for network quality measurement corresponding to the first upload bandwidth and a packet for network quality measurement corresponding to the second upload bandwidth to the user terminal or the network quality management device,
The one user terminal or the network quality management device,
If the packet loss for each packet for network quality measurement corresponding to the first upload bandwidth is less than or equal to a reference value, and the packet loss for each packet for network quality measurement corresponding to the second upload bandwidth is greater than the reference value, the first upload The network quality management method, characterized in that the bandwidth is determined as the upload bandwidth of the one user terminal.
7. The method of claim 6,
The network quality management as the network quality measurement tool of the one user terminal transmits a packet for network quality measurement corresponding to each of the first upload bandwidth and the second upload bandwidth to the counterpart user terminal in the order of size at each predetermined bandwidth measurement period The device determines the upload bandwidth of the one user terminal for each bandwidth measurement period,
When the upload bandwidth is determined in the bandwidth measurement period, the network quality management method, characterized in that during the bandwidth measurement period, packet loss is measured without transmitting a network quality measurement packet for upload bandwidth measurement.
delete 8. The method according to claim 6 or 7,
The network quality management method, wherein the network quality management apparatus determines the determined upload bandwidth as the download bandwidth of the counterpart user terminal.

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