JP2001069146A - Method and device for measuring idle block band of packet exchange network - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method and a device for measuring idle block band of packet exchange network with which load on a packet exchange network is reduced and the idle band of a desired block can be measured. SOLUTION: Plural test packets are respectively transmitted from a measuring instrument 1 through one route to two transmission object nodes located at both ends of a measuring object block, packet transfer delay time to two transmission object nodes is measured, the minimum value and average value of the measured values are found, the sum of average latency in the queue of respective nodes, which the packet passes from the measuring instrument to the transmission object node, is calculated by these values, the block average latency of the queue to the measuring object block is calculated from the difference of sums of the average latency provided concerning respective two transmission object nodes, the measuring object block is made into queue model and the idle band is calculated by performing queue model calculation on the basis of the block average latency.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a technology for managing a packet-switched network such as the Internet, and more particularly, to a technology for measuring a state of a network and a quality of service provided on the network. It is about technology.

[0002]

2. Description of the Related Art As a conventional method for measuring an available bandwidth in a packet switching network, a method of actually transferring data and dividing the amount of transferred data by the time required for the transfer has been used. In this method, there is a problem that another device to be a transfer partner device is required separately from the measurement device in order to transfer data. In addition, the available bandwidth that can be measured by this method is a value of a section where the available bandwidth in the path between the measuring apparatus and the partner apparatus is the smallest, and it is difficult to specify that section. There were problems such as being unable to do so. Further, in this method, it is necessary to perform data transfer in a section of the path between the measuring apparatus and the counterpart apparatus, which has the minimum available bandwidth, so as to use up the available bandwidth, so that the load on the packet switching network is reduced. There is a problem that other traffic sharing the section is adversely affected such as packet loss.

[0003]

SUMMARY OF THE INVENTION An object of the present invention is to provide a method and an apparatus for measuring a free space in a section of a packet-switched network which can lighten the load on the packet-switched network and measure the free bandwidth of a desired section. It is in.

[0004]

According to the present invention, there is provided a method for measuring an available bandwidth in a packet-switched network section, comprising the steps of: providing one path from a measuring device installed in a packet-switched network to two transmission target nodes located at both ends of a measurement target section; By transmitting a plurality of test packets, respectively, measuring the packet transfer delay time to the two transmission target nodes, respectively, from the measured value of the packet transfer delay time, the minimum value for each of the two transmission target nodes Determining, from the measured value of the packet transfer delay time, obtaining an average value for each of the two transmission target nodes, from the minimum value and the average value of the packet transfer delay time for each of the two transmission target nodes, For each node that the packet passes from the measuring device to the destination node Calculating the sum of the average waiting times in the queue, and calculating the section average waiting time in the queue to the measurement target section from the difference between the sums of the average waiting times obtained for each of the two transmission target nodes. And a step of forming a queue model of the section to be measured, calculating a queue model based on the section average waiting time, and calculating an available bandwidth.

The packet switching network section free band measuring apparatus of the present invention transmits a plurality of test packets to an arbitrary transmission target node in the packet switching network and measures the packet transfer delay time. Means for determining a minimum value for each of the two transmission target nodes from the measured value of the above, means for obtaining an average value for each of the two transmission target nodes from a measured value of the packet transfer delay time, a minimum value for the packet transfer delay time Means for calculating the sum of the average waiting time in the queue of each node passing to the transmission target node from the average value, and the sum of the average waiting time in the queue to the two transmission target nodes at both ends of the measurement target section. Means for calculating a section average waiting time in the queue to the measurement target section from the difference, and And queuing model the measurement target section, characterized in that it comprises means for calculating the free bandwidth performs queuing model calculated using the interval average waiting time.

[0006]

Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a diagram for explaining a network configuration and a measurement target section to which the present invention is applied.
IP network as an example of a packet switched network
Shows 10. In this IP network 10, links 1, 2,..., J-1, j,.
, And IP routers 1, 2,..., J-1, j,. Here, the section to be measured is the j-th link j,
The IP routers at both ends are called an IP router j-1 and an IP router j. It is also assumed that the IP router has a function of immediately returning a response packet to a packet response request. All existing IP routers have this function. In addition, it is assumed that the method of the present invention is mounted on the measuring device 1.

FIG. 2 is a block diagram showing an example of the configuration of a packet-switched network section free band measuring apparatus 1 according to the present invention. In the figure, 2 is a packet generating device, 3 is a packet transmitting device, 4 is a packet receiving device, 5 is a device for determining a minimum value of packet transfer delay time, 6 is a device for calculating an average value of packet transfer delay time, 7 Is a device for calculating the average waiting time to the target node, 8 is a device for calculating the average waiting time for the free bandwidth measurement target section, and 9 is a device for calculating the free bandwidth by applying the queue theory.

A test packet is generated by the packet generator 2 based on parameters such as a target node, a packet size, the number of transmissions, and a transmission interval which are input to the measuring device 1.
The generated test packet is transmitted from the packet transmitting device 3. The returned test packet is received by the packet receiving device 4, and data such as the target node and the transfer delay time is stored. Based on the data stored in the packet receiving device 4, the device 5 determines the minimum value of the packet transfer delay time, and the device 6 calculates the average value of the packet transfer delay time. From the minimum value and the average value of the packet transfer delay times, the device 7 calculates the sum of the average waiting times for the target nodes. The device 8 calculates the average waiting time of the section to be used for the measurement of the free bandwidth from the difference between the sums of the average waiting times of the adjacent target nodes. , The device 9 applies the queuing theory to calculate the available bandwidth, and outputs the result.

FIG. 3 is a diagram showing a flow of an embodiment of the present invention. First, a packet transfer delay time D _{j, i} to an IP router j at one end of a measurement target section is measured a plurality of times (1 to i) using a test packet of a fixed size (step 1).
1). Similarly, the packet transfer delay time D _{j-1, i} to the IP router j-1 at the other end of the measurement target section is set to a plurality of times (1 to i).
Measure (step 12). In this case, the order of measurement is arbitrary. Next, from the obtained packet transfer delay times D _{j, i} and D _{j-1, i} , a minimum value min _i (D _{j, i}
) And min _i (D _{j-1, i} ) are determined (steps 13 and 15). Similarly, based on the obtained packet transfer delay times D _{j, i} and D _{j-1, i} , the average value ave
_i (D _{j, i} ) and ave _i (D _{j-1, i} ) are calculated (steps 14 and 16). As the average value, a value indicating another average, such as an intermediate value, may be used depending on the state of the network.

The average packet transfer delay time ave _i (D _{x, i} ) to the x-th IP router x on the route is an average that varies depending on the transfer delay time L _x inherently applied to the route and the congestion state of the route. it can be represented by the sum of the waiting time W _{x. Lx} is the sum of the time required for a signal to propagate through each section on the route and the time required to process a packet at each passing IP router.

W _x is the sum of the section average waiting times 通過 Q _k (k = 1, 2,..., X) for each link that passes through. Minimum value min _i of the packet transfer delay (D _{x, i)} is sufficiently if the measurement data according to a number of test packets, likely to be transferred without waiting for all routers on the path, L _x
Can be considered. _{Thus, W x = ave i (D} x, i) -L x = ave i (D x, i) - min i (D x, i) by, calculating the average waiting time W _x up IP router x Can be. Using this equation, W _j and W _j are obtained for the IP routers j and j−1 at both ends of the measurement target section, respectively.
_j-1 is calculated (steps 17 and 18).

The average section waiting time Q j in the section to be measured _j is the average waiting time up to the IP router j and the IP router j.
can be calculated by the difference _{Q j = W j -W j-} 1 and the average waiting time until j-1.

From the above, the section average waiting time in the section to be measured is obtained (step 19). The traffic flowing in the target section captures a burst corresponding to a content size such as WWW as a unit. At this time, assuming that the generation process of each burst can be described by a Poisson distribution (random arrival) and that the service time is proportional to the burst length expressed by an exponential distribution with an average of M, from the queue calculation, B _j = M · R _j the / _{(M + R j Q j)} , it is possible to calculate the free band B _j of the measurement target section j (step 20). Here, R _j is the link speed of the measurement target section. Although this R _j may be known,
Even if it is not known, a large load on the network can be obtained by applying the method of finding the link speed of an arbitrary section as described in Japanese Patent Application No. 10-275673 to the IP routers at both ends of the section to be measured. Can be obtained without applying

[0014]

As described above, according to the conventional method, it was necessary to exchange data with the partner terminal. However, according to the packet-switched network section free band measuring method of the present invention, the test packet is transmitted from the measuring device. There is an advantage in that transmission to the node does not require a partner terminal. Also,
According to the conventional method, only the value of the section having the smallest available bandwidth on the path between the measuring apparatus and the partner terminal can be measured. However, according to the method of the present invention, the test packet is transmitted from the measuring apparatus to both nodes of the section to be measured. Is transmitted, there is an advantage that a free band in an arbitrary section can be measured. Furthermore, in the conventional method, it is necessary to perform data transfer for the section having the smallest free band on the path between the measuring apparatus and the partner terminal so as to use up the free band, and other sections sharing the section are used. There was a problem that traffic was adversely affected,
According to the method of the present invention, since a test packet having a small capacity is used, the load on the packet switching network can be greatly reduced, and there is an advantage that other traffic sharing a section is not affected.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a network configuration and a measurement target section to which the present invention is applied.

FIG. 2 is a block diagram illustrating a configuration example of a packet-switched network section free band measuring apparatus according to the present invention.

FIG. 3 is a diagram showing a flow of an embodiment of the present invention.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 Measurement device 2 Packet generation device 3 Packet transmission device 4 Packet reception device 5 Device for determining minimum value of packet transfer delay time 6 Device for calculating average value of packet transfer delay time 7 Calculates average waiting time to target node Apparatus 8 Apparatus for calculating the average waiting time to the available bandwidth measurement target section 9 Apparatus for applying the queuing theory to calculate the available bandwidth 10 IP network

Continuing on the front page (72) Inventor Hirohisa Taniguchi 2-3-1 Otemachi, Chiyoda-ku, Tokyo Nippon Telegraph and Telephone Corporation (72) Inventor Takayuki Furuya 2-3-1 Otemachi, Chiyoda-ku, Tokyo Date F-term (reference) in the Telegraph and Telephone Corporation 5K030 GA13 HA08 HC01 JA10 LE03 MA01 MB00 MB06 MC01

Claims (2)

[Claims] 1. A method for measuring an available bandwidth in an arbitrary section of a packet-switched network, comprising the steps of:
Transmitting a plurality of test packets by one path to two transmission target nodes located at both ends of the measurement target section, and measuring packet transfer delay times to the two transmission target nodes, respectively; Determining a minimum value for each of the two transmission target nodes from the measured value of the delay time; obtaining an average value for each of the two transmission target nodes from the measured value of the packet transfer delay time; the two transmissions Calculating the sum of the average waiting time in the queue of each node from which the packet passes from the measuring device to the transmission target node from the minimum value and the average value of the packet transfer delay time for each of the target nodes; Measured from the difference between the sums of the average waiting times obtained for each of the nodes Calculating a section average waiting time in a queue to the target section; and forming a queue model of the measurement target section, calculating a queue model based on the section average waiting time, and calculating an available bandwidth. A method for measuring an available bandwidth in a packet switching network section. 2. A means for transmitting a plurality of test packets to an arbitrary transmission target node in a packet switching network to measure a packet transmission delay time, and for each of the two transmission target nodes from a measured value of the packet transmission delay time. Means for determining a minimum value; means for calculating an average value for each of the two transmission target nodes from the measured value of the packet transfer delay time; Means for calculating the sum of the average waiting times in the queues of the nodes; from the difference between the sum of the average waiting times in the queues to the two transmission target nodes at both ends of the measurement target section, the section average in the queue to the measurement target section Means to calculate the waiting time, and make a queue model of the section to be measured and use the section average waiting time Queuing model calculated packet switched network section free bandwidth measuring apparatus characterized by comprising a means for calculating the free bandwidth performed.