KR20020055849A - Ip distribution method in intelligent network - Google Patents

Abstract

PURPOSE: An IP(Intelligent Peripheral) distributing method in an Internet network is provided to effectively cope with an increase in subscribers by effectively connecting a plurality of SSPs(Service Switching Point) and IPs when expanding them according to an increase in a subscriber capacity in an intelligent network, and provide a service without software change even if the IP is kept expanding to the intelligent network in the future. CONSTITUTION: When an operator inputs an IP list for its connection to each SSP through an OMP(Operation and Maintenance Processor), a message handler of an SCP(Service Control Point) receives it through an MMCD(Main-Machine Command Dialog) and stores it in a shared memory(S1). When an SLEE(Service Logic Execution Environment) receives an intelligent network call from an arbitrary SSP, it determines whether a specific service has been registered on the basis of information on an originating number and a termination number of the intelligent network call(S2). If a specific service has been registered for the intelligent network call, the SLEE determines whether a specific IP has been registered for the arbitrary SSP(S3). If a specific IP has been registered for the arbitrary SSP, the SLEE determines whether the specific IP registered for the arbitrary SSP is in an available state(S4). If the specific IP is in an available state, the SLEE selects the specific IP registered for the arbitrary SSP(S5). The SLEE determines whether an IP to be connected to the specific service registered for the intelligent network call has been registered(S6). If the IP to be connected to the specific service registered for the intelligent network call, the SLEE selects the IP to be connected to the specific service and connects the IP to the arbitrary SSP to proceed with the intelligent network call(S7).

Description

IP distribution method in intelligent network {IP DISTRIBUTION METHOD IN INTELLIGENT NETWORK}

The present invention relates to a method of distributing IP (Intelligent Peripheral) in an intelligent network. More specifically, the method selects and connects an IP to be connected among a plurality of IPs to a caller's call. The present invention relates to an IP distribution method in an intelligent network.

As is known, in the conventional intelligent network, a service of an intelligent network call has been provided in a structure in which only a single service switching point (hereinafter referred to as "SSP") and a single IP exist. However, as the number of intelligent network subscribers increases, it becomes impossible to provide an intelligent network service with one SSP and IP, thereby establishing a plurality of SSPs and IPs.

Therefore, an algorithm that connects a plurality of SSPs and a plurality of IPs is required for intelligent network call processing. In the past, such algorithms do not exist to efficiently connect a plurality of SSPs and IPs and to distribute the intelligent network calls appropriately. There was a problem that the implementation itself is impossible.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to implement an IP connection algorithm for each SSP and an IP connection algorithm for each service, thereby increasing IP and SSP due to an increase in subscriber capacity. The present invention provides an IP distribution method in an intelligent network to efficiently cope with this.

In order to achieve the above object, the IP distribution method in the present invention intelligent network includes a plurality of SSPs; A plurality of IPs; OMP; In the IP distribution method in the intelligent network consisting of MMCD, message handler, shared memory, SLEE, and subscriber DB,

A first step in which the message handler in the SCP receives an operator's input of an IP list to be connected for each SSP through the OMP and stores the received IP in the shared memory;

A second step of the SLEE determining whether a specific service is registered on the basis of the originating number and the called number information of the call when an intelligent network call is received from any of the plurality of SSPs;

A third step of determining, by the SLEE, whether a specific IP is registered in the SSP if the specific service is registered in the intelligent network call in the second step;

A fourth step of determining, by the SLEE, whether a specific IP registered in the arbitrary SSP is available if the specific IP is registered in the originating SSP in the third step;

A fifth step of the SLEE selecting a specific IP registered in the arbitrary SSP if the state of the specific IP registered in the arbitrary SSP is available in the fourth step;

A sixth step of determining, by the SLEE, whether an IP to be connected to a specific service registered in the intelligent network call is registered; And

In step 6, if the IP to be connected to a specific service registered in the intelligent network call is registered, the SLEE selects an IP to be connected to a specific service registered in the intelligent network call, and then connects to an arbitrary SSP to proceed with the intelligent network call. Characterized in that the seventh step.

1 is a functional block diagram showing a configuration of an IP distribution apparatus in an intelligent network according to an embodiment of the present invention;

2 is an operation flowchart showing an IP distribution method in an intelligent network according to an embodiment of the present invention;

FIG. 3 is a flowchart illustrating a detailed operation of a twelfth step in the IP distribution method of the intelligent network according to FIG. 2.

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

100: SSP 200: IP

300: OMP 400: SCP

401: MMCD 402: Message Handler

403: shared memory 404: SLEE

405: Subscriber DB

Hereinafter, an IP distribution method in an intelligent network according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a functional block diagram of an IP distribution apparatus in an intelligent network according to an embodiment of the present invention, the IP distribution apparatus in an intelligent network according to an embodiment of the present invention includes a plurality of SSPs 100; A plurality of IPs 200; An OMP (Operation & Maintenance Processor; " OMP ")300; Main-Machine Command Deamon (MMCD) 401, Message Handler 402, Shared Memory 403, Service Logic Execution Environment (SLEE) 404, and a SCP (Service Control Point; hereinafter referred to as " SCP ") 400 having a subscriber database (405).

When the originating subscriber attempts an intelligent network call, the plurality of SSPs 100 respectively switches the intelligent network call.

In addition, when the plurality of IPs 200 receive one of the intelligent network calls from the plurality of SSPs 100 as one of the intelligent network components, the plurality of IPs 200 provides functions of transmitting announcements, providing voice mailboxes, and the like to the subscribers, respectively. .

On the other hand, the OMP 300 is a processor that performs the operation / management function of the intelligent network system, when the operator inputs an IP list (List), or a specific IP block command to be connected to each SSP (100) in the SCP (400) It serves to transmit to the MMCD (401).

In addition, the SCP 400 is a system in charge of the control of the intelligent network service serves to advance the intelligent network call by connecting the sender and a specific IP for the intelligent network call received from the SSP (100), MMCD (401), message It consists of a handler 402, a shared memory 403, a SLEE 404, and a subscriber DB 405.

At this time, the MMCD 401 mounted in the SCP 400 transmits the IP list or specific IP block command to the SSP 100 from the OMP 300 to the message handler 402. Do it.

In addition, when the message handler 402 mounted in the SCP 400 receives an IP list to be connected for each SSP 100 from the MMCD 401, the message handler 402 stores the IP list in the shared memory 403, while the MMCD 401 is stored. When a specific IP block command is received from the network, the specific IP block command is deleted from the IP list stored in the shared memory 403.

Meanwhile, the shared memory 403 mounted in the SCP 400 is a memory that stores an IP list to be connected to each SSP 100.

In addition, the SLEE 404 mounted in the SCP 400 determines the service type and the connected IP 200 for the intelligent network call transmitted from any SSP 100 among the plurality of SSPs 100, and then the corresponding IP 200. It connects the 200 and the arbitrary SSP 100 serves to advance the intelligent network call.

On the other hand, the subscriber DB 405 mounted in the SCP (400) is a memory that stores a variety of information about the intelligent network subscribers.

Next, a method of distributing an IP in an intelligent network using an IP distributing device in an intelligent network having the above configuration will be described with reference to FIG. 2.

First, when the message handler 402 in the SCP 400 inputs an IP list to be connected for each SSP through the OMP 300, the message handler 402 receives the message through the MMCD 401 and then inputs the IP list to the shared memory 403. Save (S1). At this time, when the operator inputs a specific IP block command, the message handler 402 deletes and updates a specific IP from the list of IPs stored in the shared memory 403.

On the other hand, when the SLEE 404 receives an intelligent network call from any of the SSP 100 of the plurality of SSP 100, the SLEE 404 determines whether or not a specific service is registered based on the originating number and the called party information of the intelligent network call ( S2). Here, whether to register a specific service of the intelligent network call is determined through subscriber information stored in the subscriber DB 405.

At this time, if a specific service is registered in the intelligent network call (YES) in the second step (S2), the SLEE 404 determines whether or not the specific IP 200 is registered in the arbitrary SSP 100. Determine (S3). Here, one or more IPs 200 may be registered in each of the SSPs 100, and the registration information may be obtained through an IP list stored in the shared memory 403.

If the specific IP 200 is registered in the third originating SSP 100 in the third step S3 (YES), the SLEE 404 registers the specific IP 200 registered in the arbitrary SSP 100. It is determined whether or not the state of) is an available state (S4).

At this time, if the state of the specific IP 200 registered in the arbitrary SSP 100 is available in the fourth step S4 (YES), the SLEE 404 is the arbitrary SSP 100. Select a specific IP (200) registered in (S5).

Then, the SLEE 404 determines whether or not the IP 200 to be connected to a specific service registered in the intelligent network call is registered (S6).

At this time, if the IP 200 to be connected to the specific service registered to the intelligent network call is registered in the sixth step S6 (YES), the SLEE 404 is the IP to be connected to the specific service registered to the intelligent network call. After selecting (200) it is connected to the arbitrary SSP (100) to proceed with the intelligent network call (S7).

On the other hand, the specific IP 200 is not registered to the SSP 100 in the third step S3 (NO) or the SSP 100 is not registered in the fourth step S4. If the state of the registered specific IP 200 is not available (NO), the SLEE 404 determines whether the intelligent network call originated from the arbitrary SSP 100 is a call that can proceed without an IP connection (S8). ).

At this time, if the call originating from the arbitrary SSP 100 in the eighth step S8 is a call that can proceed without an IP connection (YES), the SLEE 404 proceeds with the process for the intelligent network call without an IP connection. On the other hand (S9), if the call originating from the SSP 100 is impossible to proceed without the IP connection (NO), the SLEE 404 terminates after performing the call failure process (S10).

In addition, in the sixth step S6, when the IP 200 to be connected to the specific service registered in the intelligent network call is not registered (NO), the SLEE 404 is a specific IP registered in any SSP 100. An intelligent network call is advanced by connecting the 200 and the random SSP 100 (S11).

On the other hand, if the specific service is not registered in the intelligent network call in the second step (S2) (NO), the SLEE 404 is a specific IP 200 registered in the arbitrary SSP (100) and any arbitrary The SSP 100 is connected to proceed with the intelligent network call (S12).

Hereinafter, a detailed operation process of the twelfth step S12 will be described with reference to FIG. 3.

First, the SLEE 404 determines whether or not a specific IP 200 is registered in the arbitrary SSP 100 (S12-1). Here, one or more IPs 200 may be registered in each of the SSPs 100, and the registration information may be obtained through an IP list stored in the shared memory 403.

At this time, if the specific IP 200 is registered in the arbitrary SSP 100 in step 12-1 (S12-1) (YES), the SLEE 404 is assigned to the arbitrary SSP 100. It is determined whether the state of the registered specific IP 200 is available (S12-2).

If the state of the specific IP 200 registered to the arbitrary SSP 100 is available (YES) in step 12-2 (S12-2), the SLEE 404 reads the arbitrary SSP 100. Select a specific IP (200) registered in the (S12-3).

Thereafter, the SLEE 404 connects the specific IP 200 registered to the arbitrary SSP 100 with the arbitrary SSP 100 to advance the intelligent network call (S12-4).

On the other hand, the specific IP 200 is not registered in the arbitrary SSP 100 in step 12-1 (S12-1) (NO) or in step 12-2 (S12-2). If the state of the specific IP 200 registered to the arbitrary SSP 100 is not available (NO), the SLEE 404 is a call capable of proceeding without an IP connection by the intelligent network call originating from the arbitrary SSP 100. It is determined whether or not the recognition (S12-5).

At this time, if the call originating from the SSP 100 in step 12-5 is a call that can proceed without an IP connection (YES), the SLEE 404 processes the intelligent network call. Proceed without the IP (200) connection (S12-6).

On the other hand, if the call originating from the arbitrary SSP 100 in step 12-5 (S12-5) is impossible to proceed without the IP 200 connection (NO), the SLEE 404 performs call failure processing After that, it ends (S12-7).

As described above, the IP distribution method of the intelligent network according to the present invention enables the IP network and the SSP to be efficiently connected when the IP and the SSP are increased due to the increase in subscriber capacity in the intelligent network, thereby coping with the increase in subscribers. In the future, even if IP is continuously added to the intelligent network, it can provide a service without changing the software.

Claims (8)

A plurality of SSPs; A plurality of IPs; OMP; In the IP distribution method in the intelligent network consisting of MMCD, message handler, shared memory, SLEE, and subscriber DB, A first step in which the message handler in the SCP receives an operator's input of an IP list to be connected for each SSP through the OMP and stores the received IP in the shared memory; A second step of the SLEE determining whether a specific service is registered on the basis of the originating number and the called number information of the call when an intelligent network call is received from any of the plurality of SSPs; A third step of determining, by the SLEE, whether a specific IP is registered in the SSP if the specific service is registered in the intelligent network call in the second step; A fourth step of determining, by the SLEE, whether a specific IP registered in the arbitrary SSP is available if the specific IP is registered in the originating SSP in the third step; A fifth step of the SLEE selecting a specific IP registered in the arbitrary SSP if the state of the specific IP registered in the arbitrary SSP is available in the fourth step; A sixth step of determining, by the SLEE, whether an IP to be connected to a specific service registered in the intelligent network call is registered; And In step 6, if the IP to be connected to a specific service registered in the intelligent network call is registered, the SLEE selects an IP to be connected to a specific service registered in the intelligent network call, and then connects to an arbitrary SSP to proceed with the intelligent network call. IP distribution method for an intelligent network, characterized in that the seventh step. The method of claim 1, If the specific IP is not registered to the SSP in the third step, or if the state of the specific IP registered to the SSP in the fourth step is not available, the SLEE originates from the SSP. An eighth step of determining whether an intelligent network call is a call that can proceed without an IP connection; And If the call originating from the SSP in the eighth step is a call capable of proceeding without an IP connection, the SLEE further includes a ninth step of proceeding the process for the intelligent network call without an IP connection; IP distribution method. The method of claim 2, If the call originating from the SSP in step 8 is a call that cannot proceed without an IP connection, then the SLEE further includes a tenth step of terminating after performing call failure processing; Way. The method of claim 1, In step 6, if the IP to be connected to the specific service registered in the intelligent network call is not registered, the eleventh step of advancing the intelligent network call by connecting the specific IP registered to the SSP with the arbitrary SSP is performed. IP distribution method in an intelligent network characterized in that it further comprises. The method of claim 1, If the specific service is not registered in the intelligent network call in the second step, the SLEE further includes a twelfth step of advancing the intelligent network call by connecting the specific IP registered in the arbitrary SSP with the arbitrary SSP. IP distribution method in an intelligent network characterized by. The method of claim 5, The twelfth step may include: a twelve-first step in which the SLEE determines whether a specific IP is registered in any SSP; Step 12-2, in step 12-1, if the specific IP is registered in the SSP, the SLEE determines whether the state of the specific IP registered in the SSP is available; Step 12-3, in step 12-2, if the state of the specific IP registered in the SSP is available, the SLEE selects the specific IP registered in the SSP; And The method of claim 10, wherein the SLEE comprises a 12-4 step of advancing the intelligent network call by connecting the specific IP registered in any SSP and the arbitrary SSP. The method of claim 6, If the specific IP is not registered in the random SSP in step 12-1 or if the status of the specific IP registered in the random SSP in step 12-2 is not available, the SLEE is determined to be random. Step 12-5, determining whether the intelligent network call originated from the SSP is a call that can proceed without an IP connection; And In step 12-5, if the call originating from the SSP is a call that can proceed without an IP connection, the SLEE further includes steps 12-6, in which the processing of the intelligent network call is performed without an IP connection. IP distribution method in an intelligent network. The method of claim 7, wherein If the call originating from the SSP in step 12-5 is a call that cannot proceed without an IP connection, the SLEE further includes steps 12-7 of terminating after performing the call failure processing. IP distribution method in.