KR101327656B1 - Method for forwarding parket on real time streaming - Google Patents

Abstract

The present invention relates to a method for forwarding end-to-end streaming packets and, more specifically, to a method for forwarding packets capable of improving communication efficiency in a restricted communication bandwidth by measuring packet transmission delay time between the routers constructing a routing path between a source router and a destination router in a communication network synchronized with standard time, by calculating the packet bypass time of the respective routers, and by transmitting the packets, received from the respective routers in packet bypass time without special processes, to next groove of the router. [Reference numerals] (AA) Start;(BB) No;(CC) Yes;(DD) End;(S10) Measure the packet receiving time;(S20) Packet bypass time?;(S30) Transmit the packet with a next-hop Router

Description

Forwarding method of real time streaming packet {Method for forwarding parket on real time streaming}

The present invention relates to an end-to-end packet forwarding method, and more particularly, a packet reception delay between each router constituting a packet routing path from a source router to a destination router in a standard time-synchronized communication network. Packet forwarding to improve communication efficiency at limited communication bandwidth by calculating the packet bypass time of each router from the time and sending packets received at the packet bypass time from each router to the next hop router without any additional packet processing. It is about a method.

The quality of service (QoS) of a communication network is determined by factors of timeliness, bandwidth, and reliability. Among the factors that determine the quality of service of a communication network, bandwidth and reliability can be overcome by increasing the bandwidth or improving the reliability performance of communication equipment as a cost-proportional factor. The time necessary for forwarding to a router is important, especially for seamless playback of audio or video in a real-time streaming service such as audio or video. Here, the timeliness is determined by the processing of the router's queuing mechanism, buffering structure, and the like, and it takes time for the router to forward the packet to the next hop router, including queuing or buffering the packet.

In order to improve service quality in end-to-end real-time communication service, an integrated service (Intserv, Integrated Service) model has been proposed and used. The integrated service model uses a resource reservation protocol (RSVP) signaling protocol, which is a resource reservation protocol, to guarantee quality of service on a traffic flow basis. RSVP is used to reserve resources and forward packets before traffic is transmitted, ensuring the quality of the real-time streaming service.

In the integrated service model, the quality of service is satisfied by forwarding packets using reserved transmission resources. However, in the case of end-to-end real-time packet forwarding service, packet forwarding time is delayed due to packet processing delay at each router in the packet routing path. This causes a failure to efficiently use the limited communication bandwidth.

The present invention is to solve the problems of the above-mentioned end-to-end real-time packet forwarding method, an object of the present invention is to set the packet bypass time of each router and to receive the packet received at the set packet bypass time It provides a packet forwarding method that can reduce the packet processing latency by forwarding to the next hop router of the routing path.

 Another object of the present invention is to provide a packet forwarding method capable of optimizing packet bypass time of each router constituting a packet routing path from a source router to a destination router by transmitting and receiving a plurality of configuration request messages and configuration response messages. It is.

Another object of the present invention is to provide packet reception delay time information and reception delay parameter between each router included in the last n configuration request messages among the packet reception delay times included in the plurality of configuration request messages. It is to provide a packet forwarding method that can reduce the amount of time and computation required to calculate the packet bypass time by setting the packet bypass time from the average value of the packet processing delay time calculated based on.

The packet forwarding method according to the present invention comprises the steps of synchronizing a standard time of a router provided in a communication network, and a configuration request message including packet reception delay time information between routers of a packet routing path calculated based on the standard time. Is sequentially transmitted from the source router to the destination router in the packet routing path, and the packet bypass time of each router in the packet routing path is calculated based on the packet reception delay time information and the reception delay parameter at the destination router. And generating a setup response message having a packet bypass time of each router, and sequentially transmitting the generated setup response message from a destination router located on a packet routing path to a source router. Setting up the Basis of the packet to the packet router, the bypass time will be from the source router of a packet routing path comprises the step of forwarding the packet to a destination router.

A packet received at the packet bypass time set by each router on the packet routing path is bypassed to the next hop router of each router.

In the packet forwarding method according to the present invention, a communication network is an integrated service model for transmitting and receiving a packet using a resource reservation protocol, and the packet is a real time streaming packet.

In the packet forwarding method according to the present invention, the setup request message and the setup response message are repeatedly transmitted and received between the source router and the destination router on the packet routing path, and the destination router receives the packet bypass time from the packet reception delay time of the repeatedly received setup request message. Calculate

Preferably, in the packet forwarding method according to the present invention, the setup request message and the setup response message are repeatedly transmitted and received between the source router and the destination router on the packet routing path at a set number of times, or the setup request message and the setup response message are each set on the packet routing path. Repeated transmission and reception until the packet bypass time of the router is calculated within the threshold bypass time.

In the packet forwarding method according to the present invention, the step of transmitting a setup request message may include calculating a packet reception delay time from a time difference between the packet reception time of the previous hop router and the standard time of the next hop router of the previous hop router in the packet routing path; Generating a setup request message having the calculated packet reception delay time information and packet reception time information of the next hop router, and transmitting the generated setup request message from the next hop router to the next hop router of the next hop router. It is characterized by including.

Generating a configuration response message in the packet forwarding method according to the present invention comprises the steps of extracting the packet reception delay time information between each router on the packet routing path from the configuration request message received at the destination router, the packet between each extracted router Calculating packet processing delay time at each router from the transmission delay time information and reception delay parameters of each router; calculating packet bypass time at each router from the calculated packet processing delay time; Generating a setup response message having a packet bypass time.

Preferably, the packet bypass time is calculated for each router based on the average value of the packet processing delay time at each router or based on the average value of the packet processing delay time calculated from all the configuration request messages received at the destination router. It is calculated for each router based on the average value of the packet processing delay time calculated from the last or n (n is a natural number) received from the configuration request message received from the destination router.

In this case, the standard time of each router constituting the packet routing path may be synchronized using a PTP (Precision Time Protocol) method of the IEEE 1588 standard.

A packet forwarding method according to another embodiment of the present invention comprises the steps of synchronizing a standard time of a router provided in a communication network, and packet reception delay time information between routers of a packet routing path calculated based on the standard time. Sequentially transmitting the first configuration request message from the source router to the destination router in the packet routing path, and receiving and delaying the packet reception between the routers in the packet routing path of the first configuration request message received at the destination router. Calculating a spare packet bypass time from the parameter and sending a setup response message with the spare packet bypass time to the source router in the packet routing path to set the packet bypass time of each router to the spare packet bypass time; Requests first configuration from destination router Calculating an average value of packet processing time of each router from the packet reception delay time information and the reception delay parameter of each router of the next configuration request message which is repeatedly received in the preliminary packet bypass time after the message and the first configuration request message; Calculating the final packet bypass time of each router in the packet routing path from the average value of the packet processing time, generating a final configuration response message with the final packet bypass time, and generating a final configuration response message for each router in the packet routing path. And setting the final packet bypass time of each router by transmitting to the router.

The packet forwarding method according to the present invention has various effects as follows compared to the conventional packet forwarding method.

First, the packet forwarding method according to the present invention sets the packet bypass time of each router and forwards the received packet to the next hop router in the packet routing path without packet processing delay, thereby setting the packet bypass time in the limited communication resource. Real time streaming packets can be sent quickly without packet processing delays.

Second, the packet forwarding method according to the present invention optimizes each router by transmitting and receiving a plurality of configuration request messages and configuration response messages, and calculating the packet bypass time of each router constituting the packet routing path from the source router to the destination router. The calculated packet bypass time can be calculated.

Third, the packet forwarding method according to the present invention is a packet processing delay calculated from the packet reception delay time of each router included in the last n configuration request messages among the packet reception delay time of each router included in the plurality of configuration request messages. By setting the packet bypass time from the average value of the time, it is possible to reduce the time and the amount of computation required to calculate the packet bypass time of each router.

1 is a diagram illustrating a packet forwarding communication system according to the present invention.
2 is a flowchart illustrating a packet forwarding method according to the present invention.
3 is a view for explaining a message transmitted and received between each router of the packet routing path in order to set the packet bypass time in the present invention.
4 is a flowchart illustrating a method of generating a setup request message in a packet forwarding method according to the present invention.
5 is a view for explaining a method for generating a setup response message in a packet forwarding method according to the present invention.
6 is a diagram illustrating an example of generating a setup request message and a setup response message according to the present invention.
7 is a view for explaining a first example of a method for calculating a packet bypass time in the packet forwarding method according to the present invention.
8 is a diagram for describing a second example of a method of calculating a packet bypass time in the packet forwarding method according to the present invention.
9 is a diagram for describing a third example of a method of calculating a packet bypass time in the packet forwarding method according to the present invention.

Hereinafter, a packet forwarding method according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating a packet forwarding communication system according to the present invention.

A plurality of communication terminals 20 and 30 are connected to the network 10. Here, the network 10 transmits and receives data in a packet unit between a plurality of communication terminals 20 and 30 connected to the network 10 in a wired / wireless communication network. The network 10 includes a plurality of routers R for forwarding packets between the plurality of communication terminals 20 and 30, and the communication terminal 20 and the communication terminal 30 are routers of the network 10. (R) performs end-to-end communication. All routers R present in the network 10 are synchronized with one another in standard time.

The routers provided in the network 10 are synchronized with each other in standard time by the IEEE 1588 Precision Time Protocol (PTP). The IEEE 1588 PTP precisely measures network equipment in microsecond units in a network such as Ethernet. A standard that allows synchronization to be synchronized to ensure that the trigger and event time stamps use the same standard time by synchronizing the local and master clocks of the local device and master device on the network. In the present invention, the standard time of all routers (R) existing in the network 10 is synchronized using the IEEE 1588 PTP standard, but various standard time synchronization methods may be used according to the field to which the present invention is applied. Belongs to the range.

Here, the network 10 is a communication bandwidth of a routing path between the communication terminal 20 and the communication terminal 30 before data transmission and reception in order to transmit and receive data between the communication terminal 20 and the communication terminal 30 performing end-to-end communication. Pre-allocates and operates as an integrated service model that transmits and receives data between the communication terminal 20 and the communication terminal 30 through the reserved allocated communication bandwidth.

The data transmitted and received between the communication terminal 20 and the communication terminal 3 through the network 10 is characterized in that the real-time streaming data, such as audio, video.

2 is a flowchart illustrating a packet forwarding method according to the present invention.

Referring to FIG. 2, when a packet is received at each router constituting a packet routing path, a reception time of a packet is measured (S10). In each router, the packet bypass time is set, and it is determined whether the packet is received at the set packet bypass time by comparing the set packet bypass time and the packet receiving time (S20). When a packet is received at packet bypass time, it forwards the packet directly to the next hop router in the packet routing path without a separate packet processing delay.

In the packet forwarding method according to the present invention, it is determined whether the packet is received at the packet bypass time, and according to the determination result, the packet is normally switched to the packet forwarding path and forwarded to the next hop router or switched to the bypass path to the next hop router. Forward it.

If the packet is not received at the packet bypass time, the received packet is stored in the standby buffer, and the packet scheduler extracts the packet stored in the standby buffer with different weights according to the importance and forwards the packet to the next hop router. Paths that are queued and queued and forwarded to the next hop router are commonly referred to as forwarding paths. When forwarding the received packet to the next hop router by the normal forwarding path, the packet header is analyzed and the received packet is stored in the standby buffer according to the importance of the packet, and the packet scheduler again has different weights according to the importance of the packet. It is necessary to go through the steps of extracting and forwarding to the forwarding queue. In this way, the processing of forwarding the packets received through the forwarding path from each router to the next hop router is referred to as packet processing, and the time required to perform packet processing is described. This is referred to as packet processing time.

On the other hand, when a packet is received at the packet bypass time, a path that normally forwards the packet to the next hop router without switching the packet to the forwarding path and without waiting and queuing processing is referred to as a bypass path.

3 is a view for explaining a message transmitted and received between each router of the packet routing path in order to set the packet bypass time in the present invention.

In more detail with reference to Figure 3, for the end-to-end packet transmission from the source terminal (S) to the destination terminal (D), the ingress router (IR) connected to the source terminal (S) first 1 A setup request message is generated and the generated first setup request message is transmitted to the next hop router CR1 of the packet routing path to the egress router ER to which the destination terminal D is connected. We refer to the ingress router as the source router and the egress router as the destination router.

The first setting request message SM1 generated by the source router stores information about a reception time of a packet transmitted from the source terminal to the destination terminal. The next hop first router CR1 measures the reception time of the first setup request message SM1 based on the standard time, and the packet reception time stored in the first setup request message SM1 and the measured first setup request. The packet first reception delay time between the source router and the next hop first router CR1 is calculated from the reception time of the message SM1. The next hop first router CR1 generates a second setup request message SM2 having the packet first reception delay time information and generates the second setup request message SM2 generated by the next hop second router of the packet routing path. Transmit to (CR2). The second configuration request message SM2 stores packet first reception delay time information between the source router and the next hop first router CR1 and reception time information of the first configuration request message. The next hop second router CR2 calculates the packet second reception delay time of the next hop first router and the next hop second router, requests packet first reception delay time information, packet second reception delay time information, and a second setting request. A third setup request message SM3 having the reception time information of the message SM2 is generated and transmitted to the next hop third router of the packet routing path.

In this manner, each router on the packet routing path regenerates a configuration request message including packet reception delay time between each router and reception time information of the configuration request message, and sequentially transmits the configuration request message to the destination router.

When the destination router receives the configuration request message regenerated sequentially at each router from the source router to the destination router, the destination router is based on the packet reception delay time information between each router and the reception delay parameter information at each router. Calculates the packet bypass time and generates a configuration response message (SSM) for setting the calculated packet bypass time as the packet bypass time of each router, and sequentially transmits from the destination router to the source router to each router. . Each router in the packet routing path receiving the configuration response message (SSM) extracts its own packet bypass time information and sets the packet bypass time using the extracted packet bypass time information. In this case, the reception delay parameter is a parameter that configures the time taken to forward the packet received by the previous hop router to receive the packet at the next hop router. electronic delay, serialization delay for serializing a packet on the link, transmission delay for transmitting a packet from a transmission medium, and electronic delay, continuous delay, and transmission delay among packet reception delay times. Except for this, it may be divided into a packet processing delay required for forwarding a packet to a next hop router. Since the electronic delay, continuous delay, and transmission delay are quantitative in each router, the packet processing delay time can be calculated by subtracting the electronic delay, continuous delay, and transmission delay from the packet reception delay time.

The configuration request message and the configuration response message are repeatedly transmitted and received between the source router and the destination router by the set number of times, and the destination router receives a set request message each time after receiving the set request message or the set number of packets of each router. Optimize the packet bypass time by averaging the processing delay time.

4 is a flowchart illustrating a method of generating a setup request message in a packet forwarding method according to the present invention.

Referring to FIG. 4, when the current router of the packet routing path receives the configuration request message from the previous hop router of the packet routing path, the current router measures the time when the configuration request message is received from the previous hop router (S110). . The received configuration request message stores time information of receiving the configuration request message from the previous hop router and packet reception delay time information between the previous hop router and the previous hop router of the previous hop router. The packet reception delay time between the previous hop router and the current router is calculated based on the reception time of the configuration request message and the measured reception time of the configuration request message stored in the configuration request message (S120). The current router generates a setup request message including the packet reception delay time calculated, the reception time of the setup request message from the current router, and the packet reception delay time information between the previous hop router and the previous hop router of the previous hop router (S130). The generated setup request message is transmitted to the next hop router of the packet routing path (S140).

5 is a view for explaining a method for generating a setup response message in a packet forwarding method according to the present invention.

Referring to FIG. 5, each router extracting packet reception delay time information of each router from a configuration request message received sequentially by each router in the packet routing path from the source router to the destination router is extracted and extracted. The packet processing time of each router is calculated from the packet reception delay time information and the reception delay parameter of S210. The packet bypass time of each router is calculated based on the determined packet processing time of each router (S220). Generates a setup response message containing the packet bypass time information of each router of the calculated packet routing path, and transmits the setup response message generated to each router of the reverse packet routing path from the destination router to the source router. Each router of the path extracts the packet bypass time information from the configuration response message and sets the packet bypass time based on the extracted packet bypass time information (S230).

6 is a diagram illustrating an example of generating a setup request message and a setup response message according to the present invention.

Referring to an example of generating a setup request message with reference to FIG. 6 (a), a source router IR of a packet routing path generates a first setup request message having a packet reception time T to generate a next hop of a packet routing path. Transmit to router CR1. The next hop router CR1 extracts packet reception time information from the first setup request message, and extracts the source router IR and the next hop router from the standard time of the next hop message CR1 and the reception time information of the first setup request message. The packet first reception delay time Δt11 between CR1) is calculated. The next hop router CR1 generates a second setup request message including packet first reception delay time and reception time information of the first setup request message from the next hop router CR1 to generate a next hop router ( CR2). The next hop router CR2 extracts the reception time information of the first configuration request message from the second configuration request message, and the next hop router CR1 is extracted from the reception time of the first configuration request message and the reception time of the second configuration request message. The packet second reception delay time [Delta] t12 between the next hop routers CR2 is calculated. The next hop message CR2 generates a third setup request message including a packet first reception delay time, a packet second reception delay time, and a reception time information of the second configuration request message to generate a next hop router CR3 in the packet routing path. To send). In the same way, each router in the packet routing path generates a synchronization message and sequentially sends it to the next hop router to the destination router (ER).

Referring to an example of generating a setup response message with reference to FIG. 6 (b), the destination router ER extracts packet reception delay time information of each router existing in the packet routing path from the setup request message, and extracts the packet of each router. The packet bypass time of each router is calculated from the reception delay time and the reception delay parameter information of each router. The packet bypass time T _BPi of the router i may be calculated as Equation (1) below by adding or subtracting a threshold time from a packet reception delay time of the router.

[Equation 1]

Where Δtij is the packet reception delay time between router i and the next hop router j of router i in the packet routing path, Pi is the reception delay parameter of router i, and TH is the threshold time. do.

For example, if a real-time streaming service receives a packet at a predetermined period (T), the packet processing delay time is subtracted from the packet reception delay time of each router, and the threshold time (TH) is further subtracted and then the period (2T) is added to each router. Calculate the packet bypass time According to the field to which the present invention is applied, the destination router may use the sum of the total packet reception delay times of the packet routing paths between the routers instead of calculating the packet bypass time in the period T.

7 is a view for explaining a first example of a method for calculating a packet bypass time in the packet forwarding method according to the present invention.

Referring to FIG. 7, the packet reception delay time information between the routers of the packet routing path is extracted from the received configuration request message (S311). The packet processing time of each router is calculated from the extracted packet reception delay time information, the packet reception delay time information and the reception delay parameter information between each router extracted from the previously received configuration request message, and the average value of the packet processing time is calculated. (S313). It is determined whether the number of times of receiving the setting request message is the setting number of times (S315), and when the setting request message is received by the number of setting times, the packet bypass of each router is subtracted from the packet receiving delay time of each router minus the average value of the packet processing time. The time is calculated (S317). Preferably, the packet bypass time of each router may be calculated as in Equation (2) below.

&Quot; (2) "

Where T _BPi is the packet bypass time of router i, T _delayi is the packet reception delay time of router i, T _APi is the average value of packet processing time at router i, and T _TH is the threshold time. to be.

8 is a diagram for describing a second example of a method of calculating a packet bypass time in the packet forwarding method according to the present invention.

Referring to FIG. 8, the packet reception delay time information between the routers of the packet routing path is extracted from the received configuration request message (S321). The packet process delay time information calculated from the packet reception delay time information extracted from the packet reception delay time information extracted from the previously received configuration request message, and the packet reception delay time between the routers and the packet reception delay time between the routers. The average value is calculated (S323). It is determined whether the average value of the calculated packet process time exists in the threshold packet process time (TH _PT ) (S325), and when the average value of the calculated packet process time exists in the critical packet process time, from the average value of the calculated packet process time. The packet bypass time of each router is calculated (S327). However, if the average value of the calculated packet process time does not exist in the critical packet process time, the setting request message is repeatedly received until the average value of the calculated packet process time exists in the critical packet process time. In the second example described with reference to FIG. 8, by narrowing the average value of the packet process time to the threshold packet process time, once the packet bypass time is set, the communication bandwidth can be used without waste, but the calculated average value of the packet process time is the critical packet. By repeatedly receiving the setup request message until it exists at the process time, communication bandwidth and setup time can be wasted until the packet bypass time is set.

9 is a diagram for describing a third example of a method of calculating a packet bypass time in a packet forwarding method.

Referring to FIG. 9, the packet reception delay time information of each router of the packet routing path is extracted from the configuration request message received by the destination router (S331). The preliminary packet bypass time of each router is calculated from the extracted packet reception delay time information and the reception delay parameter of each router (S333).

Determining whether the number of times of receiving the setting request message is the setting number of times (S335), when the setting request message is received by the setting number of times, the packet reception delay of each router in the packet routing path from the setting request message received in the preliminary packet bypass time range. The time information is extracted, and the final packet bypass time of each router is set from the average value of the packet processing delay time and the packet process time of each router calculated from the received packet delay time parameters of each router (S337).

In the third example described with reference to FIG. 9, instead of calculating a packet bypass time each time a setup request message is received, the packet reception delay of each router is received after receiving the setup number setup request message in a preliminary packet bypass time range. By calculating the packet bypass time of each router from the average value of the packet process time calculated from the time, it is possible to reduce the amount of computation and computation time required to calculate the packet bypass time.

Preferably, in the third example, the packet reception delay time information between each router of the packet routing path is extracted only from the last n configuration request messages received in the spare packet bypass time range, and from the extracted packet reception delay time. The final packet bypass time of each router may be set based on the calculated average value of the packet process time of each router.

In the third example, each router from an average value of packet process times calculated from packet reception delay times of each router included in the last n configuration request messages among the packet reception delay times among the routers included in the plurality of configuration request messages. By calculating the packet bypass time of the router, it is possible to reduce the amount of computation and the time required to calculate the packet bypass time of each router.

Meanwhile, the above-described embodiments of the present invention can be written as a program that can be executed in a computer, and can be implemented in a general-purpose digital computer that operates the program using a computer-readable recording medium.

The computer-readable recording medium may be an electrically or magnetic storage medium such as a ROM, a floppy disk, a hard disk, etc., an optical reading medium such as a CD-ROM or a DVD and a carrier wave, , Transmission over the Internet).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

10: network 20, 30: communication terminal

Claims (17)

Synchronizing a standard time of a router provided in the communication network;
Sequentially transmitting, at each router from the source router to the destination router of the packet routing path, a setup request message including packet reception delay time information between each router in the packet routing path, calculated based on the standard time;
Calculating a packet bypass time of each router in the packet routing path based on the packet reception delay time information and the reception delay parameter at the destination router, and generating a configuration response message including the packet bypass time of each router; step;
Sequentially transmitting the generated setup response message from the destination router located on the packet routing path to the source router to set a packet bypass time of each router; And
Forwarding the packet from a source router to a destination router in the packet routing path based on the packet at the packet bypass time of each router. The method of claim 1,
And a packet received at the packet bypass time set by each router on the packet routing path is bypassed to a next hop router of each router. 3. The system of claim 2, wherein the communication network is
Packet forwarding method characterized in that the integrated service model for transmitting and receiving packets using the resource reservation protocol. 4. The method of claim 3, wherein in the packet forwarding method
And said packet is a real time streaming packet. 5. The method of claim 4, wherein in the packet forwarding method
The configuration request message and the configuration response message are repeatedly transmitted and received between the source router and the destination router on the packet routing path,
And the destination router calculates the packet bypass time from the packet reception delay time of the repeatedly received setup request message. 6. The method of claim 5, wherein in the packet forwarding method
The configuration request message and the configuration response message is a packet forwarding method, characterized in that repeated transmission and reception between the source router and the destination router on the packet routing path. 6. The method of claim 5, wherein in the packet forwarding method
The setup request message and the setup response message are repeatedly transmitted and received until the packet bypass time of each router on the packet routing path is calculated within a threshold bypass time. The method of claim 5, wherein the transmitting of the setting request message comprises:
Calculating a packet reception delay time from a packet reception time of a previous hop router and a standard time difference of a next hop router of the previous hop router in the packet routing path;
Generating a setup request message including the calculated packet reception delay time information and packet reception time information of the next hop router; And
And transmitting the generated setup request message from the next hop router to the next hop router of the next hop router. The method of claim 5, wherein the generating of the setup response message comprises:
Extracting packet reception delay time information between routers on the packet routing path from the configuration request message received by the destination router;
Calculating packet processing delay time at each router from the extracted packet transmission delay time information between each router and the reception delay parameter of each router;
Calculating a packet bypass time at each router from the calculated packet processing delay time; And
Generating a setup response message having a packet bypass time of each router. 10. The method of claim 9, wherein the packet bypass time is
The packet forwarding method is calculated for each router based on the average value of the packet processing delay time in each router. The method of claim 10, wherein the packet bypass time is
The packet forwarding method is calculated for each router based on the average value of the packet processing delay time calculated from all the configuration request message received by the destination router. The method of claim 10, wherein the packet bypass time is
The packet forwarding method of claim 1, wherein the router is calculated for each router based on an average value of packet processing delay times calculated from the last n (n is natural numbers) configuration request messages received from the destination router. 13. The system of claim 1, wherein the standard time of the router is
Packet forwarding method characterized in that the synchronization by the PTP (Precision Time Protocol) method of the IEEE 1588 standard. Synchronizing a standard time of a router provided in the communication network;
Sequentially transmitting from the source router to the destination router of the packet routing path a first setup request message including packet reception delay time information between each router of the packet routing path calculated based on the standard time;
A setup response message including a spare packet bypass time and calculating a spare packet bypass time from a packet reception delay time and a reception delay parameter between respective routers of the packet routing path of the first configuration request message received at the destination router; Transmitting to the source routers in the packet routing path to set the packet bypass time of each router as a spare packet bypass time;
The packet from each packet received delay time information of the next configuration request message repeatedly received at the destination packet after the first configuration request message and the first configuration request message after the first configuration request message, and the received delay parameter Calculating an average value of packet processing time of the router;
Calculating a final packet bypass time of each router in the packet routing path from the average value of the packet processing time; And
Generating a final configuration response message having the final packet bypass time, and sending the final configuration response message to each router in the packet routing path to set a final packet bypass time for each router; Packet forwarding method. 15. The method of claim 14, wherein the final packet bypass time of each router is
And a packet forwarding method is calculated for each router from an average value of packet processing time calculated from a packet reception delay time between each router of all subsequent configuration request messages received by the destination router. 15. The method of claim 14, wherein the final packet bypass time of each router is
Calculated by the respective routers from the average value of the packet processing time calculated from the packet reception delay time between the routers of the last n (n is natural numbers) of the next setup request messages received by the destination router. Packet forwarding method. 17. The router of claim 14, wherein the standard time of the router is
Packet forwarding method characterized in that the synchronization by the PTP (Precision Time Protocol) method of the IEEE 1588 standard.

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