KR19990050507A - Load Sharing Method of Asynchronous Transfer Mode Switch Using Address Translation Server - Google Patents

Abstract

The present invention relates to a load distribution method of an asynchronous transmission mode switch using an address translation server when establishing a switched virtual circuit (SVC) call in an ATM switch, and a message processing method of an address translation server in an asynchronous transmission mode system.

In the load distribution method of the asynchronous transmission mode switch using the address translation server of the present invention, each ATM switch receives an SVC call request from a user and sends an address translation request message to an ATS. The ATM switch receiving the address translation response attempts to connect to the corresponding address; if the call connection is successful, the source ATM switch sends a CALL_CONFIRMED message to the ATS, sends an SVC call connection confirmation message to the user, and the confirmation message. Asking why the call connection is unsuccessful in the transmission step, if the PORT_FAIL, PORT_FAIL, and sending a PORT_FAIL message, and transmitting the SVC call connection failure message to the user.

In the asynchronous transmission mode system of the present invention, a message processing method of an address translation server includes the steps of receiving a message by ATS, classifying the message into a corresponding processing step by classifying the message, and when the message is an address translation request message. Processing, if the message is a CALL_RELEASED message, and processing if the message is a PORT_ALIVE message.

According to the present invention, in a call setup using a load distribution service, the bandwidth allocated from the ATS is the smallest among the ports available for ATS based on the information on the current bandwidth and the information on the port status between the ATM switch and the ATS. By allocating ports, it is possible to effectively distribute the load among the various links in the LDG and to effectively use network resources by blocking call setup requests to the failed ports in advance.

Description

Load Distribution Method of Asynchronous Transfer Mode Switch Using Address Translation Server

The present invention relates to a load distribution method of an asynchronous transfer mode (ATM) switch using an address translation server. In particular, the present invention relates to an asynchronous transfer mode using an address translation server when setting a switched virtual circuit (SVC) call in an ATM switch. A load distribution method of a switch and a message processing method of an address translation server in an asynchronous transmission mode system.

In general, B-ISDN (Broadband-Integrated Service Digital Network), which can provide high-speed data / facsimile communication of several Mbps or more, and broadband TV video communication / high definition television (HDTV) of several MHz or more, It is based on ATM, and it can be said that ATM is an improvement of packet switching to cope with high speed and broadband communication service. SVC is one of the communication methods used in ATM. It is a method of designating a connection to each other when starting communication. It is a device that converts general address information of each call into internal address of ATM network to service SVC call in ATM network. Address Translation Server (ATS) is used. When a subscriber wants to distribute the load by using multiple physical ports at one address, the network provides Load Distribution Group (LDG) service to distribute call requests for the corresponding addresses to the various physical ports. Conventionally, each physical port is sequentially assigned to each call request. Such sequential allocation can be naturally load distributed in systems such as telephone networks, but it is difficult to obtain a substantial load sharing effect in systems with different bandwidths for each call such as ATM networks. have. Also, when there is a failed link among several physical links belonging to one LDG, the call setup completion rate is lowered by allocating a call to the corresponding link, and the network resource is wasted without wasting. Occurs.

Accordingly, the present invention was devised to solve the above problems, and provides an accurate load distribution function for an LDG service using multiple physical ports as one logical address in an ATM network, and provides one of several physical ports. In the case of load allocation method and asynchronous transmission mode system using an address translation server to reduce unnecessary waste of network resources by providing a function that does not allocate a call to a troubled port when a problem occurs. An object of the present invention is to provide a method for processing a message in an address translation server.

1 is a block diagram of an ATM network applied to the present invention.

2 is an operational flowchart of an ATM switch in accordance with the present invention.

3 is an operation flowchart of an address translation server according to the present invention;

<Description of the symbols for the main parts of the drawings>

10: User Equipment 12: ATM Switch

14: Address Translation Server (ATS) 16: Communication Channel

Load distribution method of the asynchronous transmission mode switch using the address translation server according to the present invention was created to achieve the above object,

A first step in which each ATM switch receives an SVC call request from a user and sends an address translation request message to the ATS;

Receiving, by the ATS, an address translation response message, the ATM switch receiving the address translation response attempts to connect to the corresponding address;

If the call connection is successful, the source-side ATM switch sends a CALL_CONFIRMED message to the ATS, and sends a SVC call connection confirmation message to the user.

In the third step, if the reason why the call connection is not successful is PORT_FAIL, and if PORT_FAIL, a PORT_FAIL message is transmitted, and a fourth step of transmitting an SVC call connection failure message to the user.

In the present invention, in the fourth step, if the connection failure reason is not PORT_FAIL, it is preferable to transmit an SVC call connection failure message to the user without transmitting the PORT_FAIL message.

Message processing method of the address translation server in the asynchronous transmission mode system of the present invention for achieving the above another object,

The ATS receiving a message;

Classifying the message by a type into a corresponding processing step;

Processing the message if it is an address translation request message;

Processing the message if it is a CALL_RELEASED message; And

Processing the message if it is a PORT_ALIVE message.

In the present invention, the processing step when the message is an address translation request message,

Selecting a port having the lowest allocated bandwidth among several physical ports in the ALIVE state assigned to the current destination address;

Sending an address translation response message;

Checking the received message as received; And

Preferably, checking whether the message is a CALL_CONFIRMED message,

If the message is a CALL_CONFIRMED message, it is preferable to replace the allocated bandwidth with the bandwidth specified in the message,

If the message is not a CALL_CONFIRMED message but a PORT_FAIL message, it is preferable to change the port to FAILED state.

If the message is a CALL_RELEASED message, the processing step is preferably performed by replacing the allocated bandwidth with the bandwidth specified in the message,

If the message is a PORT_ALIVE message, the step of processing,

Changing the port to an ALIVE state; And

It is preferable to include replacing the allocated bandwidth with the bandwidth specified in the message.

Hereinafter, the operation principle of the present invention will be described in detail with reference to FIGS. 1, 2, and 3.

1 is a schematic diagram of an ATM network according to the present invention, in which an ATM switch 12 capable of handling SVCs and an ATS 14 capable of address translation, each ATM switch 12 having user equipment 10. ) And a communication channel 16 capable of communicating to the ATS 14.

2 is an operation flowchart of an ATM switch according to the present invention, and FIG. 3 is an operation flowchart of an address translation server. With reference to Figures 2 and 3 will be described in detail the operation principle of the present invention.

First, each ATM switch sends an address translation request message to the ATS when it receives an SVC call request, and has the lowest bandwidth among the physical ports allocated to the current destination address when the address translation request message is received from the ATS. Send an address translation response so that the call can be connected. After receiving an address translation response from the ATS, the ATM switch attempts to connect to that address. If the call connection is successful, the source ATM switch sends a CALL_CONFIRMED message to the ATS. This message specifies the bandwidth allocated to the destination port of the currently connected call, so ATS replaces the allocated bandwidth for that port with the bandwidth specified in the CALL_CONFIRMED message, and when the connected call is released, the source-side ATM switch Send a CALL_RELEASED message to the ATS. This message specifies the bandwidth allocated to the destination port of the currently released call, so ATS replaces the bandwidth allocated for that port with the bandwidth specified in the CALL_CONFIRMED message.

Also, when a subscriber port has a problem, that is, communication to the port is not possible, the ATM switch that acknowledges it sends a PORT_FALL message to the ATS. The ATS uses the allocated bandwidth of the port as 0 and changes the state of the port to FALLED so that the port corresponding to the subsequent call request is not used. When the port with the above problem becomes available again, the ATM switch sends a PORT_ALIVE message to ATS to make the port available again. The PORT_ALIVE message contains the currently allocated bandwidth information, and the ATS that receives it initializes the bandwidth information with the allocated bandwidth for the corresponding port. If this bandwidth is greater than zero, it means that there is an existing PVC call on that port.

According to the present invention operating as described above, in call setup using a load distribution service, an ATS can be allocated among available ports on the basis of information on the current bandwidth and information on the port state between the ATM switch and the ATS. By allocating the port with the smallest bandwidth, it is possible to effectively distribute the load among the various links in the LDG and to effectively use the network resources by blocking the call setup request to the failed port in advance.

Claims (8)

A first step in which each ATM switch receives an SVC call request from a user and sends an address translation request message to the ATS; Receiving, by the ATS, an address translation response message, the ATM switch receiving the address translation response attempts to connect to the corresponding address; If the call connection is successful, the source-side ATM switch sends a CALL_CONFIRMED message to the ATS, and sends a SVC call connection confirmation message to the user. In step 3, if the reason why the call connection is not successful is PORT_FAIL, and if PORT_FAIL, a PORT_FAIL message is transmitted. Load distribution method of the mode switch. The method of claim 1, wherein in the fourth step, if the connection failure reason is not PORT_FAIL, the SVC call connection failure message is transmitted to the user without transmitting the PORT_FAIL message. The ATS receiving a message; Classifying the message by a type into a corresponding processing step; Processing the message if it is an address translation request message; Processing the message if it is a CALL_RELEASED message; And And processing the message if the message is a PORT_ALIVE message. The processing step according to claim 3, wherein the processing step when the message is an address translation request message, Selecting a port having the lowest allocated bandwidth among several physical ports in the ALIVE state assigned to the current destination address; Sending an address translation response message; Checking the received message as received; And Checking whether the message is a CALL_CONFIRMED message. 5. The method of claim 4, wherein if the message is a CALL_CONFIRMED message, the allocated bandwidth is replaced by the bandwidth specified in the message. 5. The method of claim 4, wherein if the message is not a CALL_CONFIRMED message but a PORT_FAIL message, the port is changed to the FAILED state. 4. The method of claim 3, wherein processing if the message is a CALL_RELEASED message is performed by replacing the allocated bandwidth with the bandwidth specified in the message. 4. The method of claim 3, wherein processing if the message is a PORT_ALIVE message, Changing the port to an ALIVE state; And Replacing the allocated bandwidth with the bandwidth specified in the message.