KR20090061434A - Network management system and method thereof - Google Patents

Abstract

A network management system and a method thereof are provided to measure a delay jitter in a correspondent section with only one-way message reception by using a receiving expectation time and an RTCP(Real Time Transport Protocol) message receiving time between routers. A router generates quality measurement information, and the quality measurement information includes a delay jitter. A first quality management unit(400) receives quality measurement information from the router and a second quality management unit compares the section delay jitter included in the section quality measurement information with a preset reference section delay jitter.

Description

Network management system and its method {NETWORK MANAGEMENT SYSTEM AND METHOD THEREOF}

The present invention relates to a network management system and method thereof. In particular, the present invention relates to a network management system and method for measuring message transmission quality in a network section using a transmission interval of a Real-Time Transport Protocol (RTCP).

RTP (Real-Time Transport Protocol, hereinafter referred to as "RTP") provides the ability to transmit real-time data (audio, video and simulation data, etc.) between end-to-end in a multicast or unicast network. Speak protocol provided. Since these RTPs do not provide a resource reservation function, quality of service (QoS) such as timely delivery and sequential delivery is not guaranteed.

The RTP real-time data transmission function is extended by a control protocol called RTCP (RTP Control Protocol), which monitors the transmission of data and provides minimal control and media identification. To provide.

RTP has a relatively constant bit rate regardless of the number of participants (since one or two speakers always speak), but RTCP increases the bit rate in proportion to the number of participants (each participant sends control packets at regular intervals to all others). Will be done). Therefore, the transmission interval of the control packet should be controlled.

Conventionally, in order to calculate end-to-end round trip time (RTT) to measure network quality using RTCP, an RTCP SR (SRender Report) for RTCP transmission is received from a transmitter, and an RTCP Receiver Report for RTCP reception from a receiver is received. ) To calculate the delay jitter occurring on the network. The field values used herein are LSR (last SR timestamp) and DLSR (delay since last SR), and the equation for calculating delay jitter is shown in Equation 1 below.

Delay (n) = A (n)-LSR (n)-DLSR (n)

Where A (n) is the time when the RR packet is received from the receiver for the nth SR, LSR (n) is the time when the nth SR packet is transmitted, and DLSR (n) is the nth SR packet. Delay time for receiving and transmitting an RR packet for the SR packet.

Since the end-to-end delay jitter measurement can recognize the delay jitter occurring in the network only after receiving the RR packet for the SR report packet, there is a difficult problem for real-time network monitoring.

An object of the present invention is to provide a network management system and method for measuring message transmission quality in a network section using a transmission interval of a real-time transport protocol (RTCP).

According to a feature of the present invention for solving the above problems, a network management system for managing a network,

After receiving the first real-time transmission message, the quality measurement information including the delay jitter calculated based on a difference between the calculated expected time of receiving the second real-time transmission message and the actual time of the second real-time transmission message is generated. At least two routers; A first quality management device that receives and accumulates the quality measurement information from the two or more routers; And receiving the quality measurement information accumulated from the at least two routers from the network operator quality management device, generating interval quality measurement information between the routers based on the accumulated collected quality measurement information, and generating the generated interval quality. And a second quality control device configured to detect a section in which an abnormality is generated by comparing the section delay jitter included in the measurement information with the previously stored reference section delay jitter.

Here, each of the two or more routers,

Upon receiving the first real-time transmission message, confirm the source of the first real-time transmission message, calculate the expected reception time for the second real-time transmission message of the source, and the actual modification time of the second real-time transmission message. The quality measurement information is generated based on the difference between the expected time and the reception time.

According to a feature of the invention, a network management system for managing a network comprising a first network and a second network,

When the first RTCP message is included in the first network, the first expected reception time for the second RTCP message is calculated based on a pre-stored RTCP transmission interval, and the actual reception time of the second RTCP message is calculated. A first router configured to generate quality measurement information based on a difference between the first reception expected time and a first reception time; In response to the first RTCP message included in the second network and received from the first router, a second reception expectation time for the second RTCP message is calculated based on a pre-stored RTCP transmission interval. A second router generating quality measurement information based on a difference between an actual reception time of an RTCP message and the expected second reception time; A first quality management device managing a network of the first network and receiving and collecting the quality measurement information from the first router; A second quality management device for managing the network of the second network and receiving and collecting the quality measurement information from the second router; And accumulate and collect quality measurement information collected from the first and second quality management devices, and determine interval quality measurement information between the first router and the second router based on the accumulated and collected quality measurement information. And a third quality control device to generate.

Here, the first router and the second router, respectively,

After receiving the first RTCP message, the second RTCP message of the same source as the first RTCP message is received to generate the quality measurement information.

According to a feature of the invention, a network management system for managing a network,

A message detector for detecting a real-time transmission message among the received messages; A reception interval for receiving and transmitting a transmission interval for the real time transmission message from the quality control device, and calculating a reception expected time for a second real time transmission message based on the transmission interval when the first real time transmission message is received. A time calculation unit; And when the message detector detects the second real-time transmission message, calculates delay jitter based on a difference between an actual reception time of the second real-time transmission message and the expected expected time, and measures the quality including the delay jitter. It includes a quality measuring unit for generating information and transmitting to the quality control device for managing the network.

According to a feature of the invention, the network management method of the message filtering device for transmitting and receiving data and the quality measuring device for managing the message transmission quality in the network,

Detecting a first Real-Time Transport Protocol (RTCP) message among the received messages; Confirming a source of the detected first RTCP message; Calculating an expected reception time of the second RTCP message based on a pre-stored RTCP message transmission interval; And when receiving the second RTCP message, measuring delay jitter based on a difference between a reception time of the second RTCP message and the expected reception time.

The method may further include transmitting quality measurement information including the measured delay jitter, the reception time, and the expected reception time to a system for measuring network interval transmission quality.

According to the present invention, it is possible to expect an effect of measuring delay jitter in a corresponding section by using an RTCP message reception time and an expected reception time between routers in a network or between a network and a network. In particular, delay jitter measurement can be expected only by receiving one-way messages.

In addition, it is possible to expect the effect of real-time monitoring for the network provided with the real-time service (RTCP).

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise. In addition, the terms “… unit”, “… unit”, “module”, etc. described in the specification mean a unit that processes at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software. have.

Now, with respect to the network management system and method for measuring the message transmission quality of the network interval using the transmission interval of the Real-Time Transport Protocol (hereinafter referred to as "RTCP") according to an embodiment of the present invention It demonstrates in detail with reference to drawings.

1 is a diagram illustrating a network management system according to an exemplary embodiment of the present invention.

As shown in FIG. 1, a network management system according to an exemplary embodiment of the present invention includes a quality management apparatus 500, first and second network operator quality management apparatuses 400 and 450, and first and second access routers ( 200, 250, and first and second border routers 300 and 350, wherein the first and second user terminals 100 and 150 of different networks are referred to as the first network (hereinafter referred to as " first network "). And second network (hereinafter also referred to as "second network"), respectively.

The quality management apparatus 500 receives the quality measurement information accumulated and collected from the first network and the second network operator quality management apparatus 400 and 450, and each section (first access router) based on the received accumulated quality measurement information. Section 200 between the first border router 300, the first border router 300 and the second border router 350, and the second border router 350 and the second access router 250). Generate quality measurement information. Then, the generated quality measurement information for each section is stored. At this time, the quality measurement information for each section is each section (between the first access router 200 and the first border router 300, between the first border router 300 and the second border router 350, the second border router ( Delay jitter (including delay time as a delay variation value) for the second access router 250) and the number of lost packets.

In addition, the quality management apparatus 500 compares the quality measurement information for each section with the basic section information previously stored, searches for a problem section, and when a problem section occurs (the quality measurement information for each section is the reference section information (section). In case of exceeding the delay delay jitter and the reference lost packet number), the administrator is informed that an abnormal interval is detected.

The first network operator quality management apparatus 400 collects and collects quality measurement information on RTCP message reception from the first access router 200 and the first boundary router 300 included in the first network, and accumulates them. The quality measurement information is transmitted to the quality control device 500. Here, the cumulative quality measurement information includes the N-th RTCP message reception time, the N-th RTCP message reception expected time, delay jitter, and the number of lost packets.

In addition, the first network operator quality management apparatus 400 confirms the RTCP session connection of the first network, calculates the RTCP transmission interval based on the number of RTCP message senders and the bandwidth situation among the session participants of the confirmed session, and generates a first RTCP transmission interval. Provided to each RTCP filtering device (210, 310, 360, 260) in the network.

This RTCP transmission interval is calculated by a conventional RTCP transmission interval calculation method, which will be easily understood by those skilled in the art how to calculate the RTCP transmission interval of the RFC.

The first access router 200 includes an RTCP filtering device 210, and performs a function of a wireless access terminal performed by a conventional access router.

When the RTCP filtering device 210 receives the first message corresponding to the RTCP message among the messages received from the first user terminal 100 or the first boundary router 300, the RTCP filtering apparatus 210 receives the first user terminal 100 or the first boundary. The expected reception time for the next RTCP message received from the router 300 is estimated based on the pre-stored RTCP transmission interval. When the RTCP filtering device 310 receives the next RTCP message, the RTCP filtering device 310 measures the reception time of the received RCTP message, generates quality measurement information obtained by calculating a difference between the expected reception time and the reception time, and then generates the first network. It transmits to the operator quality management device (400).

The first edge router 300 includes an RTCP filtering device 310, and performs a network interworking function between heterogeneous operators performed by a conventional edge router.

When the RTCP filtering device 310 receives a message corresponding to the RTCP message among the messages received from the first access router 200 or the second boundary router 350, the RTCP filtering device 310 may determine the first access router 200 or the second boundary router ( The anticipated reception time for the next RTCP message received from 300 is estimated based on a pre-stored RTCP transmission interval. When the RTCP filtering device 310 receives the next RTCP message, the RTCP filtering device 310 measures the reception time of the received RCTP message, generates quality measurement information obtained by calculating a difference between the expected reception time and the reception time, and then generates the first network. Transmit to the operator quality management device (400).

The first user terminal 100 includes a function of generating an RTCP message including real time information such as voice and video communication and transmitting the generated RTCP message to the second user terminal 150.

On the other hand, the second operator quality management device 450, the second boundary router 350 and the second access router 250 of the second network, respectively, the operator quality management device 400, the first network of the first network described above The functions corresponding to the access router 200 and the first border router 300 can be sufficiently inferred by those skilled in the art, and thus detailed description thereof will be omitted.

Hereinafter, the RTCP filtering apparatus of the first access router according to an embodiment of the present invention will be described in detail with reference to FIG. 2.

RTCP filtering apparatus (210, 310, 360, respectively) of the first access router 200, the first border router 300, the second border router 350 and the second access router 250 according to an embodiment of the present invention Since 260 performs substantially the same function as the first access router 200, only the RTCP filtering device 210 included in the first access router 200 will be described in detail with reference to FIGS. 2 and 3 below. do.

2 is a block diagram illustrating in detail an RTCP filtering apparatus of a first access router according to an exemplary embodiment of the present invention.

As shown in FIG. 2, the RTCP filtering device 210 of the first access router 200 according to an embodiment of the present invention may include a communication unit 212, an RTCP message detection unit 214, an expected reception time calculation unit 216, and The quality measuring unit 218 is included.

The communication unit 212 includes an interface for accessing and communicating with the first network, and performs data transmission / reception with the first user terminal 100 and the first boundary router 300 through the first network.

The RCTP message detector 214 detects a message corresponding to the RTCP message among the messages received from the first user terminal 100 or the first boundary router 300, and if the RTCP message is detected, the quality measurer ( 218) that an RTCP message has been detected.

When the reception expectation time calculation unit 216 receives the reception expectation time calculation request for the next RTCP message from the quality measurement unit 218, the reception expectation time calculation unit 216 receives the RCTP transmission interval previously received and stored from the first network operator quality management apparatus 400. Based on that, we calculate the expected reception time for the next RTCP message.

When the quality measuring unit 218 notifies that the RTCP message has been received from the RTCP message detecting unit 214, in the case of the first RTCP message, the quality measuring unit 218 checks the source and sends the received expected time calculation unit 216 of the next RTCP message to be transmitted from the source. Request to calculate the expected reception time.

In addition, when the RTCP message detection unit 214 detects the next RTCP message for the source, the quality measuring unit 218 is based on the difference between the reception time for the next received RTCP message and the calculated expected reception time. Generate quality measurement information. At this time, if the quality measurement unit 218 does not receive the next RTCP message for a predetermined time, it determines that the RCTP message is lost and generates quality measurement information.

Next, an RTCP filtering method in an RTCP filtering apparatus of a first access router according to an embodiment of the present invention will be described in detail with reference to FIG. 3.

3 is a flowchart illustrating an RTCP filtering method in an RTCP filtering apparatus of a first access router according to an embodiment of the present invention.

As shown in FIG. 3, the RTCP filtering method according to an embodiment of the present invention is performed by checking the received message by the RTCP filtering device 210 of the first access router 200.

The RTCP filtering device 210 determines whether the RTCP message is an RTCP message by checking the received message (S100, S110). If the received message is not an RTCP message, the RTCP filtering device 210 determines the RTCP message. Check the message until the message is received.

 As a result of the determination of S110, when the received message is an RTCP message, the RTCP filtering device 210 checks the origin of the corresponding RTCP message (S120), and when it is the first RTCP message, receives the expected time for receiving the next RTCP message. Calculate (S130).

In this case, the RTCP filtering device 210 calculates an expected reception time based on a pre-stored RTCP transmission interval. For example, when the reception time of the currently received RCTP message is 1 second and the RTCP transmission interval is 5 seconds, the reception expected time is 6 seconds.

The RTCP filtering device 210 receives a next RTCP message having a source of the first RTCP message among the received messages (S140), and stores a reception time of the received next RTCP message (S150).

The RTCP filtering device 210 calculates a difference between the reception time of the next RTCP message and the expected reception time. For example, if the next RTCP message reception time is 6.4 seconds, the reception time-receive expected time, 6.4-6 = 0.4, becomes the delay jitter. In this case, the delay jitter includes a delay time.

The RTCP filtering device 210 generates the quality measurement information based on the calculated difference (S160). In this case, when the RTCP filtering device 210 does not receive the next RTCP message for a predetermined time, the RTCP filtering device 210 considers it as a lost packet and generates quality measurement information based thereon.

The RTCP filtering device 210 transmits the generated quality measurement information to the first network operator quality management device 400.

4 is a flowchart illustrating a quality control method of a quality control apparatus according to an exemplary embodiment of the present invention.

As shown in FIG. 4, in the quality control method according to an exemplary embodiment of the present invention, the quality management apparatus 500 periodically checks the network internal devices (the RTCP filtering devices of each router) from each network operator quality management apparatus 400, 450. By receiving cumulative quality measurement information collected from.

The quality management apparatus 500 periodically receives cumulative collected quality measurement information from each network operator's quality management apparatus 400 and 450 (S300), and calculates quality measurement information for each section based on the received cumulative quality measurement information. (S302).

Then, the problem section is searched based on the calculated quality measurement information for each section (S304), and the searched problem section is provided to the manager (S306). At this time, the quality control device 500 searches for a problem section based on the pre-stored basic section information.

Through the RTCP filtering method and the quality control method according to the embodiment of the present invention, by checking only the one-way RTCP message by using the RTCP message reception time and the expected reception time between routers, a great advantage that the delay jitter measurement of the corresponding section can be measured have.

In addition, there is a big advantage that can be monitored in real time for the network provided real-time services (RTCP).

The embodiments of the present invention described above are not only implemented through the apparatus and the method, but may also be implemented through a program for realizing a function corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded. Implementation may be easily implemented by those skilled in the art from the description of the above-described embodiments.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

1 is a diagram illustrating a network management system according to an exemplary embodiment of the present invention.

2 is a block diagram illustrating in detail an RTCP filtering apparatus of a first access router according to an exemplary embodiment of the present invention.

3 is a flowchart illustrating an RTCP filtering method in an RTCP filtering apparatus of a first access router according to an embodiment of the present invention.

4 is a flowchart illustrating a quality control method of a quality control apparatus according to an exemplary embodiment of the present invention.

Claims (14)

In the network management system for managing a network, After receiving the first real-time transmission message, the quality measurement information including the delay jitter calculated based on a difference between the calculated expected time of receiving the second real-time transmission message and the actual time of the second real-time transmission message is generated. At least two routers; A first quality management device that receives and accumulates the quality measurement information from the two or more routers; And Receives quality measurement information accumulated from the at least two routers from the network operator quality management device, generates interval quality measurement information between the routers based on the accumulated collected quality measurement information, and measures the generated interval quality A second quality control device for detecting a section in which an abnormality occurs by comparing the section delay jitter included in the information with the previously stored reference section delay jitter Network management system comprising a. The method of claim 1, Each of the two or more routers, Upon receiving the first real-time transmission message, confirm the source of the first real-time transmission message, calculate the expected reception time for the second real-time transmission message of the source, and the actual modification time of the second real-time transmission message. And generating the quality measurement information based on the difference between the reception expected time. The method of claim 2, The second quality control device, And comparing the interval delay jitter with the previously stored reference interval delay jitter and determining that an abnormality has occurred and notifying an administrator when the interval delay jitter exceeds the reference interval delay jitter. The method of claim 2, Each of the two or more routers, A communication unit communicating with the network; A message detector for detecting the first real-time transmission message and the second real-time transmission message; Receive and store transmission intervals for the first real-time transmission message and the second real-time transmission message from the quality control device, and when the first real-time transmission message is received, the second real-time transmission based on the transmission interval. A reception expectation time calculation unit configured to calculate a reception expectation time for the message; And When the message detector detects the second real-time transmission message, the delay jitter is calculated based on a difference between the actual reception time of the second real-time transmission message and the expected reception time, and the quality measurement including the delay jitter. Quality measuring unit for generating information and transmitting to the first quality management device Network management system comprising a. The method according to any one of claims 1 to 4, The first real time transmission message and the second real time transmission message, Network management system, characterized in that the Real-Time Transport Protocol (RTCP) message. In the network management system for managing a network including a first network and a second network, When the first RTCP message is included in the first network, the first expected reception time for the second RTCP message is calculated based on a pre-stored RTCP transmission interval, and the actual reception time of the second RTCP message is calculated. A first router configured to generate quality measurement information based on a difference between the first reception expected time and a first reception time; In response to the first RTCP message included in the second network and received from the first router, a second reception expectation time for the second RTCP message is calculated based on a pre-stored RTCP transmission interval. A second router generating quality measurement information based on a difference between an actual reception time of an RTCP message and the expected second reception time; A first quality management device managing a network of the first network and receiving and collecting the quality measurement information from the first router; A second quality management device for managing the network of the second network and receiving and collecting the quality measurement information from the second router; And Receives cumulative quality measurement information from the first quality management device and the second quality control device, and generates interval quality measurement information between the first router and the second router based on the cumulative collected quality measurement information. Third quality control device Network management system comprising a. The method of claim 6, The first router and the second router, respectively, And receiving the second RTCP message of the same source as the first RTCP message after receiving the first RTCP message to generate the quality measurement information. The method according to claim 6 or 7, And the third quality management apparatus determines whether an abnormality has occurred by comparing the interval delay jitter included in the generated interval quality measurement information with the previously stored reference interval delay jitter. In the network management system for managing a network, A message detector for detecting a real-time transmission message among the received messages; A reception interval for receiving and transmitting a transmission interval for the real time transmission message from the quality control device, and calculating a reception expected time for a second real time transmission message based on the transmission interval when the first real time transmission message is received. A time calculation unit; And When the message detection unit detects the second real time transmission message, the delay jitter is calculated based on a difference between the actual reception time of the second real time transmission message and the expected reception time, and the quality measurement information including the delay jitter. Quality measurement unit for generating and transmitting to the quality control device that manages the network Network management system comprising a. The method of claim 9, The quality measuring unit, Confirm the source of the first real-time transmission message, request the reception expectation time calculation unit to calculate the reception expected time for the second real-time transmission message of the source, and receive the second real-time transmission message for a preset time period. If not, the network management system generating the quality measurement information by determining that the second real-time transmission message is lost. The method of claim 9 or 10, And the first real time transport message and the second real time transport message are Real Time Transport Protocol (RTCP) messages. In the network management method of the message filtering device for transmitting and receiving data with the quality measuring device for managing the message transmission quality in the network, Detecting a first Real-Time Transport Protocol (RTCP) message among the received messages; Confirming a source of the detected first RTCP message; Calculating an expected reception time of the second RTCP message based on a pre-stored RTCP message transmission interval; And When receiving the second RTCP message, measuring delay jitter based on a difference between a reception time of the second RTCP message and the expected reception time; Network management method comprising a. The method of claim 12, Transmitting quality measurement information including the measured delay jitter, the reception time, and the expected reception time to a system for measuring network interval transmission quality; Network management method further comprising. The method of claim 13, If the second RTCP message is not received for a predetermined time, determining that the second RTCP message is lost, and transmitting a loss of the second RTCP message to the system; Network management method further comprising.

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