KR100849316B1 - Method of improvement of isup call release processing - Google Patents

Abstract

end. FIELD OF THE INVENTION

The present invention relates to common line signaling processing used between network devices, and more particularly, to a relay line recovery method in an ISD user area.

I. The technical problem to be solved by the invention

It is an object of the present invention to provide a method for enabling efficient relay line use.

All. Summary of Solution of the Invention

The present invention provides a process in which a terminating network device that has transmitted a call release completion message to an originating network device transitions and manages a relay line state into a standby-idle state, and when the predetermined time elapses from the standby-idle state, the relay line state is " idle " We propose a relay line recovery procedure processing method characterized by a process of transitioning to a state.

la. Important uses of the invention

It is used for relay line recovery between network devices.

Network devices, trunk lines, recovery

Description

How to improve the recovery process of ISU Youth relay call {METHOD OF IMPROVEMENT OF ISUP CALL RELEASE PROCESSING}             

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram showing the signal flow in the procedure of restoring the IS-IP between exchanges.

2 is a diagram illustrating a signal flow between switching stations according to the prior art;

3 is a diagram in accordance with the present invention, illustrating signal flow between exchanges;

4 is a diagram showing an embodiment of the present invention in more detail, showing the signal flow between exchanges.

The present invention relates to common line signaling processing used between network devices, and more particularly, to a relay line recovery method in an ISD user area.

The network device refers to a mobile switching center (MSC), a voice mailing system (VMS), an inter working function (IWF), and the like. In addition, ISDN (Integrated Service Digital Network), or integrated telecommunications network, is digitalized in both transmission and exchange, so that users can use a wide range of services, including telephone and non-vision services, by one subscriber line. It is an information network. The most basic technology for enabling comprehensive information communication is to set up a standard multi-purpose interface at the responsibility threshold of the network and the terminal.

Here, the switching center among the network devices will be described.

Fig. 1 shows the signal flow in the IS-IP recovery process between exchanges.

The ISSUP (ISdn User Part) refers to a user unit of ISD. A A switching center (MSC-A) 100 shown in FIG. 1 is an originating exchange station that makes a call, and a B switching center (MSC-B) 120 is a terminating exchange station that calls a call originated by the originating exchange station.

Meanwhile, the STP 110 may refer to a signal relay station or a function of relaying and exchanging signal messages in a common line signaling method of ITU-T. The signal relay point 110 also has a function of notifying the cover station of the telephone signal message and notifying the other station when the signal relay is impossible. In the common line signaling system, the signal link for switching control is provided separately from the circuit line group. Since it is uneconomical to establish an independent signal link between stations with a small number of circuits, the switching station relaying signals when the signal link is used as a bypass path and shared with other stations is called a signal relay point 110. That is, the signal relay point 110 may be referred to as a kind of switching station.                         

 In step 1) of FIG. 1, the originating exchange station 100 transmits an initial address message (IAM) for call setup to the terminating exchange station 120. The transmitted message is transmitted via the signal relay point 110, and both the relay lines of the source switching center 100 and the destination switching center 120 are managed in a "setting" state. In step 2), the destination switching center 120 transmits an address complete message (ACM) to the calling switching center 100 in response to the initial address message when the status of the called subscriber is idle. At this time, the relay line state is managed in a "busy" state for both exchanges. When the called subscriber hooks off in step 3), the recipient switching station 120 transmits an ANSwer message (ANM) to the calling switching center 100. In step 4), the call state between subscribers is maintained after the response message processing. In step 5), when the calling subscriber recovers, the calling exchange 100 transmits a release message (REL; Release Message) to the called exchange 120. The release message is transmitted via the signal relay point 110, and the relay line of the source switching center 100 is managed in a "released" state. The terminating exchange station 120 receiving the release message transmits a release complete message (ReLease Complete Message) as a response thereto in step 6) and manages the relay line in an "idle" state. The originating exchange 100 receives the release complete message and also manages the relay line in an "idle" state.

However, there is a problem in the prior art as described above.

2 is a diagram showing a signal flow between switching stations according to the prior art.

In step 1) of FIG. 2, the originating exchange station 100 transmits a release message upon restoration of origination. In step 2), the destination switching center 120 transmits a release completion message and manages the relay line state as "idle." In step 3), the terminating exchange station 120 manages the relay line state as "idle" after transmitting the release completion message, thus occupying the corresponding relay line when establishing a new call, and the originating exchange station 100 relays the state after receiving the release completion message. Will be managed by transitioning from "busy" to "idle". Therefore, if the initial address message is received before the end of the process and the management of the relay line as "idle", the originating exchange 100 transmits an RSC message and fails the call because the relay line is not idle. In other words, even if the call can be accommodated more, the failure processing occurs.

Accordingly, an object of the present invention for solving the above problems is to provide a method for enabling efficient relay line use.

In order to achieve the above object, the present invention provides a process for managing a relay line state by transitioning a relay line state to a standby-idle state, and transmitting a call release completion message to an originating network device, and for a predetermined time in the standby-idle state. A relay line recovery procedure processing method is characterized in that the process of transitioning the relay line state to an "idle" state when elapsed.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the reference numerals to the components of the drawings, it should be noted that the same reference numerals as much as possible even if displayed on different drawings.

3 is a diagram according to the present invention, showing a signal flow between switching stations.

In step 1) of FIG. 3, the originating exchange station 100 transmits a release message to the terminating exchange station 120 indicating recovery of the origination. The release message is transmitted via the signal relay point 110. In step 2), the destination switching center 120 transmits a release completion message to the calling switching center 100. In step 3), the destination exchange station 120 does not immediately transition the relay line state to "idle", but rather transitions to the "standby-idle" state. The standby-idle state means a state in which only incoming calls are allowed. That is, the new outgoing relay A <-B is not allowed until the transition from the "standby-idle" state to the "idle" state.

Even if the relay line state of the originating exchange station 100 transitions to the "idle" state before the guard time of the terminating exchange station 120 (ie, the time required to transition from the idle-idle state to the idle state), a call occurs ( A-> B) The destination exchange station 120 does not matter because it allows incoming calls in the "wait-idle" state. In step 4), the guard time is set to receive the release message from the source switching center 100 so that the state of the relay line may be changed to "idle" (Guard for relay line state matching during the exchange period). In the present embodiment, the guard time is set to 200 milliseconds, but this may be variably set according to the state of the relay line. In step 5), the destination exchange station 120 transitions the relay line state to "idle" after the guard time.

Among the above-mentioned relay line states, the wait-idle state is an intermediate state before the transition to the "idle" state, and the outgoing relay is limited and the incoming relay accepts. In addition, the idle state means a state capable of accepting both incoming / outgoing relays.

4 is a diagram illustrating another embodiment of the present invention in more detail, showing signal flow between switching stations.

Steps 1) and 2) of FIG. 4 are the same as those shown in FIG. 3. Here too, a guard time exists as in FIG. 3. The guard time is also set to 200 milliseconds. As shown in step 3) of FIG. 4, the destination exchange station 120 cannot transmit the initial address message during the guard time. At this time, as shown in step 4), the relay line of the source switching center 100 is in an "idle" state, and the originating switching center 100 may transmit an initial address message to the destination switching center 120. When the initial address message is received from the source switching center 100, the destination switching center 120 changes the state of the relay line to "busy" and allows incoming calls. If no initial address message is received, the relay line state remains “Standby-Idle” and transitions to the “Idle” state at the end of the guard time. In the " idle " state, the destination exchange station 120 also enables both outgoing calls and incoming calls.

By implementing the present invention as described above, even if there is an idle relay line, it is possible to prevent the occurrence of a call failure, and 100% of the trunk of the corresponding route can be used, so that the relay line can be used and operated more efficiently. .

Claims (2)

In the relay line recovery procedure processing method between all network devices interworking with the common SS signaling Managing, by the destination network device, which has transmitted the call release completion message to the calling network device, transitioning the relay line state to the standby-idle state; And translating the relay line state to an idle state when a predetermined time elapses from the standby-idle state. The method of claim 1, The standby-idle state is a relay line recovery procedure processing method, characterized in that the incoming call is allowed only, the outgoing call is not allowed.

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