JP2003124987A - Control method for node that allocates band and node system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control method of node in a communication network, which enables each terminal to use a band proportional to access speed. SOLUTION: In a node in which a plurality of terminals are integrated by different access speeds, queues are provided for each access speed, the allocation of bands is decided for each queue using measurement data of the number of active terminals for each access speed, thereby enabling each terminal to use a band proportional to an access speed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a case where a plurality of terminals having different access speeds are connected to the same node in a communication network and each terminal transmits data by window flow control. The present invention relates to a node control method and a node control system for allocating a band according to an access speed.

[0002]

2. Description of the Related Art Conventionally, when a plurality of terminals having different access speeds are connected to the same node, in order to enable each terminal to use a band proportional to the ratio of access speeds, As shown in FIG. 3, a plurality of terminals 1, 2. ． ．
Queue 1, which accepts each packet from N
2. ． ． It is necessary to provide N for each terminal and allocate the band according to the weight (Wi, i = 1, ... N) proportional to the ratio of access speeds, so when the number of terminals increases, the queue becomes insufficient. However, there is a problem that the control overhead becomes large.

When each terminal transmits data by window flow control, access speeds # 1, # 2 ,. ． ． Queue # 1, 2. ． ． N is set, and a fixed band (Ri, i =
1 ,. ． ． Although a method of allocating a band according to N) is also known, in this method, when the number of active terminals is constant, each terminal can use the band in proportion to the ratio of access speeds. Since it cannot be changed dynamically, when the number of active terminals changes,
There was a problem that we could not respond.

[0004]

SUMMARY OF THE INVENTION An object of the present invention is to reduce the bandwidth for each queue even when the number of active connections changes and the number of terminals is large when each terminal transmits data by window flow control. It is to provide a node control method and a node system in a communication network in which each terminal can use a band proportional to the ratio of access speeds by dynamically changing the allocation depending on the number of active terminals.

[0005]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a node in which a plurality of terminals transmitting data by window flow control are aggregated at different access speeds for each access speed of each terminal. A queue is provided to manage whether the terminal is active or inactive for each IP address based on the header information of the input packet, and when an increase in the amount of arrival data from the terminal is seen within a certain time, the terminal Is determined to be active,
By calculating the number of active terminals for each access speed and determining the bandwidth allocation for each queue using the information on the calculated number of active terminals, each terminal can use the bandwidth in proportion to the access speed ratio. It is characterized by

According to a preferred embodiment of the present invention, when determining bandwidth allocation for each queue using the information on the number of active terminals, the total required bandwidth of access speed #i: = access bandwidth of access speed #i x number of active terminals with access speed #i

[Outside 4] If the sum of requested bandwidths is equal to <output bandwidth of node, access bandwidth #i is allocated bandwidth = required bandwidth, and if sum of requested bandwidth is equal to output bandwidth of node, access speed # The allocated bandwidth is calculated by calculating the sum of the allocated bandwidth of i = the output bandwidth of the node × the requested bandwidth of the access speed # i / the requested bandwidth.

The present invention further provides a node system in a communication network in which a plurality of terminals are aggregated at different access speeds and bandwidths are allocated according to the access speeds, the node system being provided for each access speed of each terminal. The queue manages whether the terminal is active or inactive for each IP address based on the header information of the input packet, and when the arrival data amount from the terminal is increased during a certain time, the terminal Input filtering means for calculating the number of active terminals for each access speed by determining that the bandwidth is allocated for each queue by using the calculated information of the number of active terminals, A computing system for issuing an instruction to change the available bandwidth; and a node system comprising Located in.

Further, the present invention is a node system in a communication network in which a plurality of terminals are aggregated at different access speeds and bandwidths are allocated according to the access speeds. A splitter for splitting each of the transmission data to be transmitted; a node having an input filter for receiving the data split by each splitter and calculating the number of active terminals for each access speed from the header information of the input packet; It is provided for each access speed,
Band allocation is determined for each queue using a queue for receiving data branched by each splitter and information on the number of active terminals calculated by the input filter, and an available bandwidth in each queue is changed. And a node having a calculation means for issuing an instruction to perform.

According to a preferred embodiment of the present invention, the calculating means is: total required bandwidth of access speed #i: = access bandwidth of access speed #i x number of active terminals of access speed #i

[Outside 5] If the sum of requested bandwidths is equal to <output band of node, allocated bandwidth of access speed #i is equal to required bandwidth, and if sum of requested bandwidth is equal to output bandwidth of node, access speed is equal to The allocated bandwidth of # i = the output bandwidth of the node × the sum of the requested bandwidth / requested bandwidth of the access speed #i is calculated, and the allocated bandwidth is calculated.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In order to describe the present invention in more detail, it will be described with reference to the accompanying drawings.

FIG. 1 is a block diagram showing an embodiment of a node control method according to the present invention. The node 10 in this embodiment includes an input filter 11, a calculation unit 12, and a queue 1, a queue 2 ,. ． ． It is assumed that the output queue 13 has a queue N. 1
4 indicates the band (Ri, i =
1 ,. ． ． It is a scheduling unit for extracting packets according to N).

The input filter 11 manages whether the terminal is active or inactive for each IP address based on the header information of the input packet transmitted from each terminal, and determines the amount of data arriving from a certain terminal within a certain period of time. When an increase in the number of active terminals is found, the number of active terminals for each access speed is calculated by determining that the terminal is active, and the information on the calculated number of active terminals is calculated by the calculation unit 12
Send to. The calculation unit 12 determines allocation of a band to each queue from the information on the number of active terminals for each access speed from the input filter 11 and issues an instruction to change the available band in each queue. 14 is calculated by the calculation unit 12, and the packet is extracted according to the instructed allocation band (Ri, i = 1, ... N).

The calculation of the allocated bandwidth for each queue in the calculation unit 12 is preferably performed based on the following equation. Total bandwidth requested for access speed #i: = access bandwidth for access speed #i x number of active terminals for access speed #i

[Outside 6] If the sum of requested bandwidths is equal to <output bandwidth of node, access bandwidth #i is allocated bandwidth = required bandwidth, and if sum of requested bandwidth is equal to output bandwidth of node, access speed # It is calculated as the allocated bandwidth of i = the output bandwidth of the node × the required bandwidth / the required bandwidth of the access speed #i.

FIG. 2 shows another embodiment of the node control method according to the present invention. In this embodiment, the node in the example of FIG. 1 is divided into two nodes 20 and 21, the node 20 is provided with an input filter 22, and the node 21 is shown in FIG.
Of the calculation unit 23 and the queue 1, the queue 2 ,. ． ． An output queue 24 having a queue N is provided. In the scheduling unit 25,
Bands (Ri, i = 1, ...) Instructed by the calculation unit 12
Extract the packet according to N).

The node 1 is transmitted from the terminals having different access speeds, and is split by the splitters 26-1, 26-, respectively.
2 ,. ． ． The transmission data branched by 26-N is received, the input filter 22 calculates the number of active terminals for each access speed from the header information of the input packet, and transfers the information to the node 21.

After receiving the information on the number of active terminals for each class of each access speed from the input filter of the node 20, the node 21 allocates the bandwidth to each queue in the calculation unit 23 from the information on the number of active terminals.
The determination is made in the same manner as in the first embodiment, and an instruction to change the available bandwidth in each queue is issued. As a result, the scheduling unit 25 calculates in the calculation unit 23 and the assigned bandwidth (Ri, i = 1, ... N) to retrieve the packet.

[0017]

As described above, according to the present invention, even when the number of terminals increases, control can be performed with a small number of queues, and the bandwidth allocation changes according to the change in the number of terminals. Therefore, even when the number of terminals is large and the number of active terminals dynamically changes, each terminal can use the band in proportion to the access speed ratio.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a node control method according to the present invention.

FIG. 2 is a block diagram showing another embodiment of the node control method according to the present invention.

FIG. 3 is a block diagram showing an example of a conventional node control method.

FIG. 4 is a block diagram showing another example of a conventional node control method.

[Explanation of symbols] 10 nodes 11 Input filter 12 Calculation Department 13 output queue 14 Packet retrieval scheduling unit 20,21 nodes 22 Input filter 23 Calculation Department 24 output queues 25 Packet retrieval scheduling unit 26-1 to 26-N splitter

Claims (6)

[Claims] 1. A node on a communication network in which a plurality of terminals are aggregated at different access speeds is provided with a queue for each access speed of each terminal, and whether the terminal is active or inactive for each IP address based on the header information of an input packet. It manages whether it is active, and when an increase in the amount of data arriving from a certain terminal is seen within a certain period of time, the terminal is determined to be active, thereby calculating the number of active terminals for each access speed, Bandwidth allocation is characterized by enabling each terminal to use a band proportional to the ratio of access speeds by determining the band allocation for each queue using the calculated information on the number of active terminals. How to control the node. 2. When determining bandwidth allocation for each queue using the information on the number of active terminals, total requested bandwidth of access speed #i: = access bandwidth of access speed #i x active of access speed #i Number of terminals [Outside 1] If the sum of requested bandwidths is equal to <output bandwidth of node, access bandwidth #i is allocated bandwidth = required bandwidth, and if sum of requested bandwidth is equal to output bandwidth of node, access speed # The allocated bandwidth of the node according to claim 1, wherein the allocated bandwidth of i is calculated as a sum of the allocated bandwidth of i = the output bandwidth of the node × the required bandwidth of the access speed # i / the required bandwidth. Control method. 3. A node system in a communication network in which a plurality of terminals are aggregated at different access speeds and bandwidths are allocated according to the access speeds, wherein the node system is: a queue provided for each access speed of each terminal. Manages whether the terminal is active or inactive for each IP address from the header information of the input packet,
Input filter means for calculating the number of active terminals for each access speed by determining that the terminal is active when an increase in the amount of data arriving from the terminal for a certain period of time is observed; A node system, comprising: computing means for determining bandwidth allocation for each queue using the information of the number of active terminals, and for issuing an instruction to change the available bandwidth in each queue. 4. The calculating means: total required bandwidth of access speed #i: = access bandwidth of access speed #i x number of active terminals of access speed #i [external 2] If the sum of requested bandwidths is equal to <output band of node, allocated bandwidth of access speed #i is equal to required bandwidth, and if sum of requested bandwidth is equal to output bandwidth of node, access speed is equal to 4. The node system according to claim 3, wherein the allocation band is calculated by calculating as the sum of the allocated band of # i = the output band of the node × the requested band of the access speed # i / the requested band. . 5. In a node system in a communication network in which a plurality of terminals are aggregated at different access speeds and bandwidths are allocated according to the access speeds, the node system is: transmission data transmitted from each terminal having a different access speed. A node having an input filter for receiving the data branched by each splitter and calculating the number of active terminals for each access speed from the header information of the input packet; for each access speed of each terminal The bandwidth allocation is determined for each queue by using the information on the number of active terminals calculated by the input filter and the queue for receiving the data branched by each splitter, and the bandwidth can be used in each queue. A computer that has a calculation means that gives an instruction to change the appropriate band. And a node system; 6. The calculating means: total required bandwidth of access speed #i: = access bandwidth of access speed #i x number of active terminals of access speed #i [3] If the sum of requested bandwidths is equal to <output band of node, allocated bandwidth of access speed #i is equal to required bandwidth, and if sum of requested bandwidth is equal to output bandwidth of node, access speed is equal to 4. The node system according to claim 3, wherein the allocation band is calculated by calculating as the sum of the allocated band of # i = the output band of the node × the requested band of the access speed # i / the requested band. .