KR20010056954A - A Distributed measurement system for the multipoint performance evaluation in the internet and method thereof - Google Patents

Abstract

PURPOSE: A distribution measuring apparatus and a method for analyzing a performance between multi-points on an Internet network are provided to instruct a network performance measuring to agents through an exclusive line by a manager using a distribution computing technique and independently perform a performance measuring operation by the agents for thereby remotely operating a measuring unit in each measuring point. CONSTITUTION: A manager(10) is installed in a center portion of the network and comprehensively manages a network performance measuring operation. Agents(1-N) installed in each point are constructed to independently operate based on the instruction of the manager(10). A control message is exchanged between the manager(10) and the agents(1-N) through an additional exclusive line, so that the flow of the control message is not affected by the performance of the Internet network, and a clock synchronization is used between the manager(10) and the agents(1-N). The agents(1-N) are in the standby mode and automatically perform the performance measuring operation based on the instruction from the manager and reports a result of the same to the manager.

Description

A distributed measurement system for the multipoint performance evaluation in the internet and method

The present invention relates to a distributed measurement apparatus and method for multi-point performance analysis in a large-scale Internet network, and more particularly, if the central management unit instructs sub-management units to measure network performance through a separate dedicated line. Sub-administrators perform performance measurements independently and report the results automatically to the management unit, so that it is possible to operate the network performance measurement by remotely from a central location without having to manually operate the measuring device at each measuring point. It is about.

In the conventional Internet, since the main purpose of data transmission is the quality of service. In general, data is not very sensitive to time delays and has the flexibility to recover from retransmission once it is found somewhere, even if an error occurs along the way.

However, with the increasing use of the Internet, real-time information such as voice and video, as well as data services, is increasingly being used for Internet traffic. Background of the Invention With the development of computer technology and the development of various terminal technologies, it is possible to packetize and transmit audio and video information.In addition, the discovery of various compression algorithms makes it possible to packetize and transmit them rather than transmitting them by the conventional line method. It is more advantageous to do.

However, unlike real-time data characteristics, media with real-time characteristics such as voice and video information require high quality conditions in the network, which are not only sensitive to time delays, but also media using some compression algorithms are strict against packet loss. Requires a standard.

Therefore, in the future Internet network, it is necessary to continuously measure and monitor the network performance to always maintain a certain level of performance.

Important performance parameters that need to be measured in the Internet are packet loss rate, unidirectional packet propagation delay time, and unidirectional packet delay time variation. The conventional technique for measuring the performance of the Internet network has a method of measuring the performance between the two points by operating two measuring devices in the transmission and reception mode, respectively, in which the measuring device operating in the transmission mode transmits a test packet and receives the reception mode The measuring instrument, which is operated by the RN, analyzes the received test packet and derives network performance between two points.

However, this method is suitable for the purpose of testing the performance of some sections of the Internet network, but not for the purpose of analyzing the performance of the entire network from time to time. This is because in order to analyze the performance of the entire network, it is necessary to install the measuring devices at many points and collect the measurement data. In the conventional method, the measuring devices must be manually operated at each point and the results are collected. There is a difficult problem.

The present invention is to solve the problem that the prior art described above is difficult to apply to a large Internet network using a distributed computing technology, the central management unit instructs the sub-management units to measure network performance through a separate dedicated line. Then, each sub-management unit performs performance measurement independently and reports the result to the management unit automatically. It is intended to be implemented.

1 is a schematic block diagram of a distributed measurement device for multi-point performance measurement in the Internet network according to the present invention.

2 is a signal flow diagram illustrating a control process between a management unit and sub-management units according to the present invention.

3 is a flow chart showing an operation process in the management unit according to the present invention.

4A and 4B are flowcharts illustrating an operation process of a sub management unit according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10: management unit 1 to N: sub-management unit

In order to achieve the above object, in the Internet network performance measurement apparatus,

Establish comprehensive plan for measuring network performance, send clock synchronization and performance measurement instruction message to sub managers through separate dedicated line, receive performance measurement result from sub managers, analyze statistics A management unit for outputting;

After receiving a performance measurement instruction from the management unit and synchronizing the system clock, it generates a test packet message to perform a performance measurement, and characterized in that it comprises a plurality of sub-management unit for reporting the result to the management unit.

In addition, in order to achieve the above object, in the Internet network performance measurement method,

The network performance measurement plan is established, and a clock synchronization message is transmitted to the sub management means to perform the performance measurement using a separate dedicated line, and upon receiving the clock synchronization completion message, the sub management means instructs the performance measurement. A main management process of transmitting a message and statistically analyzing the received message as a result of the network performance analysis when receiving the performance measurement result message;

When the clock synchronization message is received from the main management unit in the standby state, the clock synchronization is performed and the clock synchronization completion message is transmitted. When the performance measurement instruction message is received from the management unit between the two points according to the measured measurement mode. And a plurality of sub-management processes for performing performance measurements and reporting the results.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic block diagram of a distributed measurement apparatus for multi-point performance measurement in an internet network according to the present invention. In the present invention, distributed computing technology is used, and a manager 10 is located at the center to measure network performance. Comprehensive management of the process and the actual measurement has a structure that the sub-management units (Agents 1 to N) installed in each point is independently performed under the direction of the management unit 10.

Control messages are exchanged between the management unit 10 and the sub-management units 1 to N by using a separate dedicated line, which prevents the control message flow from being affected by the performance of the Internet network. This is for use in clock synchronization between the management units 1 to N. FIG. Each sub-management unit (1 to N) is always in a standby state and automatically performs measurement when receiving a performance measurement instruction from the management unit and reports the result back to the management unit.

FIG. 2 is a signal flow diagram illustrating a control process between the management unit and the sub-management units in the present invention. The management unit 10 first transmits a clock synchronization instruction message S1 to the sub-management units 1 to N, which need to measure performance. Upon receiving the clock synchronization completion message S2 from the sub managers 1 to N, the performance measurement instruction message S3 is then transmitted to the sub managers 1 to N. FIG.

The sub managers 1 to N measure the network performance according to the transmission of the test packet S4 between the two points according to the instruction received from the manager 10 and load the result in the performance measurement result message S5 to manage the manager 10. Send to

3 is a flowchart showing an operation process in the management unit according to the present invention, the management unit 10 first establishes a comprehensive plan for measuring network performance (A1).

This includes the type of performance parameter to be measured, the points to be measured, the measurement time and duration, the type of test packet, and so on.

The performance parameters to be measured include packet loss rate, unidirectional packet propagation delay time, and unidirectional packet delay time variation. The points to be measured represent the Internet addresses of the transmission and reception sub management units 1 to N. FIG. The measurement time and period represent the transmission start time St and the end time Et of the test packet and the transmission time interval It of the test packet.

Examples of the test packet include IP packets, TCP packets, UDP packets, and the like.

When the comprehensive plan necessary for measuring the network performance is established, a clock synchronization instruction message is transmitted to the sub managers 1 to N because clock synchronization is required between the manager 10 and the sub managers 1 to N (A2). ).

For clock synchronization, the manager 10 loads its own system clock in a clock synchronization instruction message. The sub managers 1 to N receive the clock synchronization instruction message, synchronize their clocks with the clocks of the manager 10, and then transmit the clock synchronization complete message to the manager 10 again (A3).

After receiving the clock synchronization completion message, the management unit 10 sends a performance measurement instruction message between two points to each of the sub management units 1 to N. In this message, the types of performance parameters to be measured and the sub management units to be measured (1 to N) are measured. Their transmission and reception addresses, measurement time and duration, and the type of test packet (A4).

After that, when the performance measurement results are received from the sub management units 1 to N, the management unit 10 collects them and statistically analyzes them to derive the overall network performance results and complete the measurement (A5).

And in order to maintain the performance of the Internet network always above a certain level, the management unit 10 repeats the above process periodically.

4A is a flowchart illustrating an operation process of the sub management unit according to the present invention. When the sub management units 1 to N are normally in a standby state and receive a clock synchronization instruction message from the management unit 10, the management unit 10 in the message is displayed. The clock is synchronized using the clock of () and transmits a clock synchronization completion message to the management unit 10 (B2).

Subsequently, when the performance measurement instruction message is received from the management unit 10 (B3), performance measurement between two points is started. Each of the sub-management units 1 to N operates in one of a transmission mode, a reception mode, and a transmission / reception mode according to the content of the message. do.

First, when the sub managers 1 to N receive an instruction in the transmission mode, a test packet is generated using the parameters in the performance measurement instruction message (B4), until the system clock T reaches the transmission start time St of the packet. After waiting and transmitting the test instruction to the counterpart sub-management units 1 to N (B5), if the system clock T is greater than or equal to the transmission end time Et, the performance measurement result message is reported to the management unit 10 between the two points. After completing the performance measurement, it returns to the standby state (B6).

If the system clock T is smaller than the transmission end time Et of the packet in step B6, the test packet is generated again after waiting for the transmission time interval It (B7).

In this case, the test packet is inserted with a sequence number of the packet and a timestamp indicating the transmission time so that the reception sub-management units 1 to N can see the packet loss and the transmission delay time. do.

On the other hand, when the sub-management units 1 to N receive an instruction in the reception mode, they wait for a test packet to enter and store the packet in a buffer when they are received. If this is not the last test packet, the sub managers 1 to N continue to wait for the test packet (B8).

If this is the last test packet or if the system clock (T) is greater than Et + To (To: maximum time to wait for a packet from the receiving sub-management unit (1 to N)), it is determined that all test packets have been received and the management unit analyzes the measurement result. By sending the performance measurement result message to the 10, the performance measurement between the two points is completed and the process returns to the standby state (B9).

On the other hand, when the sub-management units 1 to N receive the instruction in the transmission / reception mode, as shown in FIG. Transmit to the other party sub-management units 1-N. The process of transmitting the test packet generates a test packet using the parameters in the performance measurement indication message (B10), waits until the system clock (T) reaches the transmission start time (St) of the packet, and receives the indicated sub-management unit (1). If the system clock T is equal to or larger than the transmission end time Et after the transmission (B11) to the N), the management unit 10 reports the performance measurement result message to return to the standby state after completing the performance measurement between the two points. Ganda (B12).

If the system clock T is smaller than the transmission end time Et of the packet, the test packet is generated again, and the test packet is transmitted after waiting for the transmission time interval It (B13).

The process of receiving the test packet waits for a test packet to enter and stores the packet in a buffer when the packet is received and continuously waits for a test packet if this is not the last test packet (B14). If this is the last test packet or if the system clock (T) is greater than Et + To (To: maximum time to wait for a packet from the receiving sub-management unit (1 to N)), it is determined that all test packets have been received and the management unit analyzes the measurement result. By sending the performance measurement result message to the 10, the performance measurement between the two points is completed and the process returns to the standby state (B15).

As described in detail above, the present invention proposes an effective distributed measurement technique for automating the internet network performance measurement process using distributed computing technology in order to efficiently perform the performance measurement of a large internet network. There is an advantage that can be applied to the commercial Internet network to maintain above the level.

In addition, preferred embodiments of the present invention are disclosed for the purpose of illustration, those skilled in the art will be possible to various modifications, changes, additions, etc. within the spirit and scope of the present invention, such modifications, changes, etc. are defined in the claims below It should be seen as belonging.

Claims (14)

In the network performance measurement apparatus, Establish comprehensive plan for measuring network performance, send clock synchronization and performance measurement instruction message to sub managers through separate dedicated line, receive performance measurement result from sub managers, analyze statistics A management unit for outputting; Located at a plurality of network measurement points, and receiving a performance measurement instruction from the management unit, and after synchronizing the system clock, generating a test packet message to perform a performance measurement, and reporting the results to the management unit having a plurality of sub-management unit Distributed measurement device for multi-point performance analysis in the Internet network, characterized in that. The method of claim 1, The information included in the performance measurement instruction message includes a type of performance parameter to be measured, a transmission / reception address of sub-management units to be measured, a transmission start time of the test packet, an end time, a transmission time interval, and a test packet type. Distributed measurement device for multi-point performance analysis in the Internet network, characterized in that. The method of claim 2, The test packet type is distributed measurement apparatus for multi-point performance analysis in the Internet network, characterized in that the Internet Protocol (IP) packet, TCP packet, UDP packet is provided. The method of claim 1, The test packet message includes a type of performance parameter to be measured, a sequence number and a timestamp of a test packet. The method according to claim 2 or 4, The type of the performance parameter includes a packet loss rate, one-way packet propagation delay time, one-way packet delay time variation, distributed measurement apparatus for multi-point performance analysis in the Internet network. In the Internet network performance measurement method, The network performance measurement plan is established, and a clock synchronization message is transmitted to the sub management means to perform the performance measurement using a separate dedicated line, and upon receiving the clock synchronization completion message, the sub management means instructs the performance measurement. A main management process of transmitting a message and statistically analyzing the received message as a result of the network performance analysis when receiving the performance measurement result message; When the clock synchronization message is received from the main management unit in the standby state, the clock synchronization is performed and the clock synchronization completion message is transmitted. When the performance measurement instruction message is received from the management unit between the two points according to the measured measurement mode. A distributed measurement method for multipoint performance analysis in an Internet network, comprising a plurality of sub-management processes for performing performance measurements and reporting the results. The method of claim 6, The information included in the performance measurement instruction message includes a type of performance parameter to be measured, a transmission / reception address of sub-management units to be measured, a transmission start time of the test packet, an end time, a transmission time interval, and a test packet type. A distributed measurement method for multipoint performance analysis in an internet network. The method of claim 7, wherein The type of the performance parameter includes a packet loss rate, one-way packet propagation delay time, one-way packet delay time variation, distributed measurement method for multi-point performance analysis in the Internet network. The method of claim 7, wherein The test packet type includes an Internet Protocol (IP) packet, a TCP packet, and a UDP packet. The distributed measurement method for multipoint performance analysis in an Internet network. The method of claim 6, If the measurement mode instructed in the sub-management process is a reception mode, waiting for a test packet to be received from the counter-sub management means; Checking whether the received test packet is the last test packet and continuing to receive the test packet if the test packet is not the last packet; A third step of analyzing the measurement result by determining that all the test packets have been received when the check result is the last test packet or the system clock is greater than the sum of the maximum time waiting for the packet in the receiving sub management unit and the transmission end time of the packet; ; And a fourth step of completing the performance measurement between the two points and waiting for the next instruction by transmitting the analysis result to the main management means. The method of claim 6, A first step of generating a test packet using parameters in a performance measurement indication message if the measurement mode indicated in the sub-management process is a transmission mode; A second step of waiting until the system clock reaches the transmission start time of the packet and transmitting the time to the counterpart sub-management means for performance measurement; A third step of checking whether the system clock after the transmission is smaller than the transmission end time of the packet, if it is smaller, generating a test packet again, waiting for a transmission time interval, and then transmitting a test packet; And a fourth step of completing the performance measurement between the two points and waiting for the next instruction by transmitting the performance measurement result message to the main management means if the system clock is equal to or greater than the transmission end time of the packet. Variance measurement method for multipoint performance analysis. The method of claim 6, If the measurement mode instructed in the sub-management process is a transmit / receive mode, Receiving a test packet transmitted from the counterpart sub management means and simultaneously generating and transmitting a test packet to the counterpart sub management means; The receiving of the test packet may include: a first step of waiting for a test packet to be received from a counterpart sub management means; if the packet is received, storing the test packet in a buffer; Checking whether the received test packet is the last test packet and continuing to receive the test packet if the test packet is not the last packet; A third step of analyzing the measurement result by determining that all the test packets have been received when the check result is the last test packet or the system clock is greater than the sum of the maximum time waiting for the packet in the receiving sub management unit and the transmission end time of the packet; ; A fourth step of completing the performance measurement between the two points and waiting for the next instruction by sending the analysis result to the main management means; The transmitting of the test packet comprises: a first step of generating a test packet using parameters in a performance measurement indication message; A second step of waiting until the system clock reaches the transmission start time of the packet and transmitting the time to the counterpart sub-management means for performance measurement; A third step of checking whether the system clock after the transmission is smaller than the transmission end time of the packet, if it is smaller, generating a test packet again, waiting for a transmission time interval, and then transmitting a test packet; And a fourth step of completing the performance measurement between the two points and waiting for the next instruction by transmitting the performance measurement result message to the main management means if the system clock is equal to or greater than the transmission end time of the packet. Variance measurement method for multipoint performance analysis. The method according to any one of claims 10 to 12, The test packet message is a distributed measurement method for multi-point performance analysis in the Internet network characterized in that it comprises a type of performance parameters to be measured, the sequence number and time stamp of the test packet. The method of claim 13, The type of the performance parameter includes a packet loss rate, a unidirectional packet propagation delay time, and a unidirectional packet delay time variation. A distributed measurement method for multipoint performance analysis in an Internet network.