KR19990049842A - Redundancy Processing Method of Exchange Protocol Device Processor - Google Patents

Abstract

The present invention discloses a duplication processing method of an exchange protocol device processor in order to improve the reliability and efficiency of the system. Such a redundancy processing method does not access the hardware RAM when an active device processor equipped with a protocol engine and a standby device processor board are installed and the active device processor accesses the hardware RAM to exchange messages with the access network. All messages are backed up to the standby device processor, and the standby processor is designated as the master when an active abnormality occurs so that the task can be performed without interruption of the call service.

Description

Redundancy Processing Method of Exchange Protocol Device Processor

TECHNICAL FIELD The present invention relates to a time division electronic switching system, and more particularly, to a duplication processing method of an exchange protocol device processor.

In general, once a switching system is started and started to service, it is necessary to continue the service even if a problem occurs. To solve this problem and the stability of the system, the recent electronic switchboard system has a redundancy process with a protocol device processor loaded with a V5.2 protocol engine. To implement redundancy, one of the two processor boards acts as the master and the other as the slave. In the event of an error in the master processor, the slave processor is converted to the master to continue service. From this point of view, if the V5.2 protocol stack is loaded at the exchange for the service of the ETSI V5.2 interface, the processor board loaded with the V5.2 protocol stack also needs to be redundant.

Accordingly, an object of the present invention is to provide a duplication processing method of a processor board in which a protocol stack is loaded so that a call that is in progress at the time of board transfer can be continued and a newly attempted call can proceed without a problem.

Another object of the present invention is to provide a method of duplexing a processor board loaded with a V5.2 protocol stack when a V5.2 protocol stack is mounted on an exchange to service an ETSI V5.2 interface.

In order to achieve the above object, the present invention provides a duplex processing method of an exchange protocol device processor, wherein an active device processor equipped with a protocol engine and a standby device processor board are installed to access hardware RAM. When a message is exchanged with an access network, all messages are backed up to the standby device processor which does not access the hardware RAM. When an active abnormality occurs, the standby processor is designated as the master so that tasks can be performed without interruption of call service. do.

Other objects and advantages of the invention will be apparent from the following description taken in conjunction with the accompanying drawings.

1 is a block diagram of an exchange protocol device processor in accordance with the present invention.

2 is a control flowchart of a processor duplication processing method according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention for an example method of redundancy of processor boards loaded with the V5.2 protocol stack when the V5.2 protocol stack is mounted on the exchange for service of the ETSI V5.2 interface will be described in detail. do.

1 is a block diagram of an exchange protocol device processor according to the present invention, in which two processors 12, 13, access network 10, RAM 11, and upper NAT 14 are shown. In the embodiment of the present invention, the implementation of the protocol layer 3 module for redundancy of the V5.2 protocol stack board. If you load a redundant V5.2 protocol stack, the two processor boards 12 and 13 will work together, and if a board that is used as a master fails, the slave board will take over and continue the V5.2 service. When the master and slave boards are switched, the call on the call continues and the ringing subscriber continues to hear the ring and there is no problem with the new call. As a result, even if a system problem occurs, the service of the V5.2 interface subscribers will not be affected.

The two device processors 12 and 13 are configured with the same hardware and are loaded with the same V5.2 protocol engine. One of the two chapters is the master, which establishes the actual V5.2 interface and communicates with the access network (AN) or exchanges messages with the upper NAT (National PSTN), while the other is prohibited and acts only as a slave. Should be. Hereinafter, a device processor that is a master is referred to as an active device processor, and a device processor that operates as a slave is called a standby device processor. When configuring the V5.2 protocol layer 3 module, each protocol entity and various components are created as tasks, and the interface between the tasks uses queues. Like the active device processor, the standby device processor creates and starts all of the tasks on startup. The active device processor accesses hardware RAM and exchanges messages with the AN, but the standby device processor does not access hardware RAM, so the active device processor delivers V5.2 messages from the AN to the standby device processor. The standby device processor has the same effect as receiving a message from the AN, with an interface between each task. 1 shows the above. In this case, when the standby device processor suddenly becomes active and the standby device processor becomes active, the internal processor state of the standby processor is the same as the task of the active device processor, so that the call processing that is in progress can be operated without any problem. Will be.

Referring to Figure 2 will be described in more detail the duplex processing method of the V5.2 device processor. 2 shows the control process performed after the V5.2 protocol application program is loaded up to steps 20-34. In operation 20 and 21, the global variable is initialized for the initialization necessary for the application program, and the current state is requested to the counterpart device processor. Requested counterparties send normal or abnormal status information. Therefore, after receiving the status information from the counterpart processor in step 22, it is reported as higher in step 23 and waits for a response. In step 24, the redundant state is received from the upper level, and whether the self is active or standby is recognized in step 25, and the master is activated. In step 26, when the master accesses the hardware RAM, the active signal is normally registered to exchange messages with the AN. Set up the initial data and start the task. Then start up the V5.2 interface. On the other hand, if the slave, steps 30-34 are performed. Because the standby device processor does not have access to the hardware RAM, the active device processor forwards the V5.2 message from the AN to the standby device processor at the same time. That is, the standby device processor has the same effect as receiving a message from the AN, and an interface is established between each task to perform the same task as the counterpart.

As described above, the embodiment of the present invention has been described by way of example with reference to the drawings, but various changes and modifications can be made within the scope allowed by the matter.

According to the method of the present invention described above, since the protocol engine performs the redundancy procedure in the loaded device processor, it is possible to switch the device board. The two device boards maintain the same internal task at the same time, so that in the event of any abnormality, the other board acts as the master while maintaining the state of the system. Therefore, the call that was in progress at the time of the transfer of the board can proceed and the newly attempted call proceeds without a problem, there is an effect that the reliability of the system is expected.

Claims (2)

In the duplex processing method of an exchange protocol device processor, when an active device processor equipped with a protocol engine and a standby device processor board are installed, the configured active device processor accesses hardware RAM to exchange messages with an access network. A method of backing up all messages to a standby device processor that does not access RAM, and designates a standby processor as a master when an active abnormality occurs to perform a task without interruption of call service. In the method of performing redundancy of the electronic exchange protocol device processor: After the V5.2 protocol application program is loaded, initializing a global variable for initialization required for the application program and requesting a current state from the counterpart device processor; Receiving status information from the counterpart processor, reporting the result to a higher level, and receiving a response to recognize whether the terminal is active or standby; Registering an active signal, setting up data, starting a set task, and performing a V5.2 interface startup in order to access a hardware RAM and exchange a message with a network in the case of a master; And if the slave device, the active device processor backs up the V5.2 message received from the network and performs each task in the same way as the other party.