RU2336649C1 - Developing system of commuted public switched telephone network and method of service processing in this network - Google Patents

Abstract

FIELD: physics, communications.

SUBSTANCE: invention concerns system of Public Switched Telephone Network (PSTN) and method of service processing in such network. Terminal equipment (TE) is transformed into Service Switching Point (SSP) with Service Switching Function (SSF), so that a call can be directed to the relevant Service Control Point (SCP) for service processing according to different conditions; without modernisation of Local Equipment (LE) all services are directed by data configuration to SSP point of TE station with the help of call routing function of LE station; billing center obtains service information for payment charge only from SSP.

EFFECT: possibility to utilise available devices and network resources to the maximum, thus reducing costs and reconstruction problems.

13 cl, 6 dwg

Description

Field of Invention

The present invention relates to methods for organizing a telecommunications network, and more particularly, to an evolving Public Switched Telephone Network (PSTN) system and to a method for processing services in this network.

State of the art

Among the existing telecommunication networks, the majority of communication service users and the bulk of the operating revenues belong to the PSTN network. The functions of information transfer, control and switching of channels are built into a program-controlled Telephone Line Switching System, which allows the provision of fixed voice services and other communication services.

In the case of PSTN (PSTN), in order to simplify and ensure network efficiency, a multilevel network organization mode is usually used. Currently, PSTN network stations (PSTN) can be generally divided into two categories: Local Station (MS (LE)) and Intermediate Station (PS (TE)). The switching systems of both MS (LE) stations and PS (TE) stations are traditional Software-controlled Telephone Line Switching Systems, with the MS (LE) station being directly connected to the subscriber line, and the PS (TE) station is not connected to the subscriber line , and with the station MS (LE). Figure 1 shows a diagram showing the basic structure of a PSTN network organization (PSTN) according to the state of the art. As shown in FIG. 1, the PSTN network (PSTN) comprises a billing center 10, a Service Control Point (SCP) 11, a PS station (TE), and an MS station (LE). In Fig. 1, two PS (TE) stations are indicated as an example, i.e. MS (TE) 12 and MS (TE) 13, and six MS (LE) stations, i.e. MS (LE) 14, 15, 16, 17, 18, and 19. MS (LE) 14, 15, 16, 17, 18, and 19 stations are connected respectively to two stations of the upper level PS (TE) - PS (TE) 12 and 13 to provide the user with Class 5 (C5) services, which are services aimed at organizing access to users or directly related to user equipment. The interconnection between the stations PS (TE) 12 and PS (TE) 13 provides the convergence of services and Class 4 (C4) services, which are services of trunk (long-distance) communication lines. The billing center 10 is connected to the stations PS (TE) 12 and PS (TE) 13 and all MS (LE) in order to obtain complete billing information from the stations MS (LE) and PS (TE), necessary for charging. The SCP (SCP) 11 refers to a control point that supports internationally advanced telephone services and Intelligent Network (IP) communication protocol services, i.e. to PUU (SCP) signal system No. 7, which can be connected to the stations PS (TE) 12 and PS (TE) 13 or can be directly connected to each station MS (LE). In an IP network (IN), an SCP (SCP) is a control point for providing information of a database of intellectual services and for direct management of intellectual services.

The advantages of the PSTN network, known from the prior art, include an extensive network infrastructure and a huge number of users, as well as providing high Quality Services (QoS) and the provision of services in a finished form.

Given the current trend towards convergence in the field of telecommunications, namely, when the telephone network, computer network and cable television network tend to merge, network loads increase and the need for more diverse services grows, therefore, for telecommunication network operators, the only way to attract users is to provide all more multimedia services. Under the influence of these circumstances, according to modern requirements, the Next Generation Network (NGN) has appeared, based on the methods of software switching. The SSP network (NGN) is a comprehensive and open network structure that provides services such as voice, data services, multimedia services, etc. Services such as communication, information transfer, electronic commerce and trade services implemented in a network of unified packages can be integrated into the NGN network (NGN), which allows satisfying various and personalized requirements for services. Compared to PSTN (PSTN), a packet network has additional advantages, such as more efficient use of bandwidth and equipment, lower voice transmission costs, and the ability to provide new services that combine voice and data transmission.

In the field of mobile communications, the Third Generation (3G) network also appeared, implemented on the basis of packet technology and capable of satisfying the growing requirements for mobile communications.

In both the NGN network and the 3G network, the separation between the logical processing of services and media processing, i.e. the separation between switching and control is based on packet technology, which allows a higher degree to realize the possibility of expanding the range of services. To meet the demands of the networks of the future, it is necessary to upgrade the existing PSTN network (PSTN). During the modernization of the PSTN network (PSTN) of a particular telecom operator, it is necessary to maximize the protection of existing telecommunication facilities and services; as for communication users, it is necessary to add some low-cost and easily implemented broadband services that meet the principles of protecting users ’money resources and their habits. Therefore, the PSTN network modernization process (PSTN) will undoubtedly be implemented in a transitional mode, and at the same time problems such as the effective inheritance of existing PSTN network services (PSTN) and the provision of the possibility of using the available PSTN network resources (PSTN) must be resolved. )

The PSTN system (PSTN) in transition is called the evolving PSTN system (PSTN). The models of the developing PSTN system (PSTN), known from the prior art, are usually divided into two categories: integrated models and distributed development models. In the integrated development model, key functional components of the NGN network (NGN), such as multiservice access, broadband switching, call management and service creation, will be integrated into integrated services stations, and development from the PSTN source network to the multi-service NGN platform is carried out thanks to the PSTN architecture, whose elements are such stations. According to the distributed development model, the NGN network consists mainly of separate components such as a call / session management module, application server (AS), gateway, station, and router. Currently, the second model is generally recognized in this industry.

In particular, two traditional evolving PSTN systems (PSTNs) known in the art can be described as follows:

Prototype I: Divided PSTN Development System (PSTN). Figure 2 presents a diagram showing the architecture of a divided evolving PSTN system (PSTN), known from the prior art. As shown in FIG. 2, the evolving PSTN system (PSTN) comprises a billing center 20, an ICP (SCP) 21, a call server 22, and Media Gateways (MG). Media gateways (MS (MG)) are divided into two categories: MS (MG) of the lower level and MS (MG) of the upper level. As an example, figure 2 shows 7 MS (MG), of which the gateways MS (MG) 25, 26, 27, 28 and 29 are lower level MS (MG), respectively connected to two upper level MS (MG), those. with gateways MS (MG) 28 and 29, and MS (MG) lower level provide users with class C5 services or other services directly related to user equipment. Providing the implementation of the convergence of services and functions of services of class C4, the gateway MS (MG) of the upper level functionally replaces the station PS (TE) of the PSTN network (PSTN), shown in figure 1.

The billing center 20 is connected to the server 22 calls and all gateways MS (MG) to obtain billing information sufficient for charging.

An SCP (SCP) 21 is connected to the call server 22 for managing intelligent services.

The call server 22 is a software switching device, also known as the Media Gateway Controller (MGC), in accordance with the commands of which the MS (MG) 23, 24, 25, 26, 27, 28 and 29 operate. controls the gateways MSH (MG) 23 and 24, designed to provide services of class C4, and controls the gateways MSH (MG) 25, 26, 27, 28 and 29, designed to provide services of class C5. At the same time, the call server provides the implementation of the intelligent services interface, interacts with the PUU (SCP) point and performs the functions of the Service Switching Point (SSP) of the IP network (IN).

In such a divided developing PSTN system (PSTN), it is necessary to rebuild the MS (LE) and PS (TE) stations of the original PSTN network (PSTN), respectively. As for the MS (LE), the control and switching functions of the traditional Software-controlled Telephone Line Switching System of the source MS (LE) station will be divided in such a way that the MS (LE) station will implement only the channel switching and transfer functions and will be reconstructed in simple switching point, i.e. the MS (LE) station will be turned into a lower level gateway МС (MG), with which the call can be switched to the upper level МШ (MG) and to the call server, and the lower level МС (MG) will process services of class C5 in accordance with control command returned by the server 22 calls. Similarly, for a PS (TE) station, it is also necessary to separate the control and switching functions of the traditional Program-controlled Telephone Line Switching System of the original PS (TE) so that the PS (TE) station can be reconstructed into a simple switching point, i.e. The MS (TE) becomes a top-level gateway MS (MG), with which the call can be switched to the call server 22, and the top-level MS (MG) can implement the convergence of services and services of class C4 in accordance with the control command returned by the server 22 calls. In other words, the service control function will be separated from the MS (LE) and MS (TE) stations of the PSTN source network (PSTN) and added to the call server 22, in which the management functions of the MS (LE) and MS (TE) source stations will be combined.

In such a divided developing PSTN system (PSTN), it is necessary to improve and reconstruct both traditional Program-controlled Telephone Line Switching Systems of the PS (TE) and MS (LE) stations of the original PSTN network (PSTN) so that they can be converted into MS gateways ( MG), which can exchange commands with the call server and carry out the functions of switching channels and forwarding according to the commands returned by the call server; and to implement the upstream media path interface in the ME (MG) gateway, the Time Division Multiplexing (MBP (TDM)) interface of a traditional Software-Managed Telephone Switching System can be reserved or directly converted to a packet-serving interface.

In a divided developing PSTN system (PSTN), the separation between management and switching is almost completely implemented, and even management of services through a call server provides a good platform for possible future expansion; however, taking into account the current situation in such a network, the following disadvantages should be indicated.

1) In this development mode, an expensive modernization of all the traditional Software-Managed Telephone Switching Systems of the PSTN source network (PSTN) is necessary.

2) Many traditional Software-controlled Telephone Line Switching Systems cannot be upgraded due to various historical reasons related to manufacturers, technologies used, etc .; instead, these systems need to be directly replaced, resulting in a low degree of reuse of available equipment.

3) Most of the software used in traditional Software-controlled Telephone Line Switching Systems cannot be used in the new system.

Briefly, in accordance with the terms of creating a divided developing PSTN system (PSTN), the telecom operator must directly replace all the original host devices of the Program-Managed Telephone Switching Systems with new ones, which will be equivalent to creating a new service network, will have a significant impact on the existing telecommunications network of this operator and will be interfaced with high operational risk.

Prototype II: an evolving PSTN system (PSTN) based on an IP network (IN) using a traditional intelligent network solution. The architecture of a traditional IP (IN) based on a PSTN network (PSTN) is shown in FIG. As shown in figure 3, the IS (IN) borrows the architecture of the network, the basis of which are the points PUU (SCP), and contains the environment 30 for creating services, device 31 access to administer services, Service Administration Point (PAU) (SMP) 32, and also points PUU (SCP) 33 and PUU (SCP) 34, which form a network of IP (IN) through SS7. The environment 30 for creating services at the highest logical level of the architecture of the IP network (IN) is intended mainly for the creation of IP services (IN), i.e. to provide an environment in which IP services (IN) could be defined, developed and tested, and also to implement features such as network configuration modeling and network utility software modeling. The service administration access device 31 belonging to the service administration system and the PAH point (SMP) 32, both of which are at the second logical level, form the service administration system level responsible for managing the IP network (IN) / IP network services (IN), including administration of services, users of services, network, access to services, access to the system, etc. The PUU item (SCP) 33, which belongs to the third logical level of such an architecture, operates throughout the IS system (IN), which allows you to manage and process intelligent services, which implements the Service Management Function (SCF) and the Data Transfer Function about the Service (FDU (SDF)), and the management of the PUU (SCP) 33 is carried out by the service management system. The PKP point (SSP) 34 operating at the fourth logical level is intended mainly for the implementation of Service Switching Functions (PKF (SSF)) and the Call Control Function (CCF), for switching the service call to the SCP (SCP) point and for implementation the CCF function according to the control command returned by the SCP (SCP), and the local lower-level PKU (SSP) also provides access to call control, while the upper-level SSP (SSP) performs the service switching function, in accordance with which he switches to PUU (SCP) only the service that meets the conditions for switching.

Figure 4 is a diagram showing the architecture of a developing IP system (IN) according to the state of the art, comprising a billing center 30, an SCP (SCP) 41, top-level PKP (SSP) points and lower-level PKP (SSP) points. As indicated in FIG. 4, as an example, an embodiment is shown comprising two upper-level control points (SSPs), two low-level control points (SSPs) 42 and 43, and five lower-level control points (SSPs), PKU (SSP) 44, 45, 46 , 47 and 48.

PKU points (SSP) 44, 45, 46, 47, and 48 are connected to two top-level PKU (SSP) points, respectively, designed to provide the user with class C5 services and other services directly related to the user terminal.

PKU (SSP) points 42 and 43 replace the PS (TE) stations 12 and 13 shown in FIG. 1, performing both service convergence and class C4 service functions, but without implementing a service control function.

The billing center 40 is connected to all points of the PKU (SSP) to obtain billing information sufficient for charging.

An SCP (SCP) 41 can be connected either to a high-level SSP (SSP) or directly to a lower-level SSP (SSP) to enable the implementation of the intelligent services management function, and the SCP (SCP) 41 can send a service control command in the PKU item (SSP) to instruct that PKU (SSP) to manage calls.

Unlike prototype I, in the developing PSTN system (PSTN) based on the IS network (IN), the control function and the switching function are not clearly and completely separated from each other; instead, the implementation of these functions is prescribed in the PKU (SSP) clause, including the PKU (SSF) and CCF (CCF) functions, but after the reconstruction of the Program-Managed Telephone Switching Systems of the MS (LE) and PS (TE) stations, this clause does not perform logical processing services. In order to implement the upstream media path interface at the PKP point (SSP), the TDM interface of a traditional Software-controlled Telephone Line Switching System can be reserved, and this interface is dedicated to supporting the protocol through which interaction with the SCP (SCP) point is made, which allows implementing services.

In such a developing PSTN system (PSTN) based on the IS network (IN), a more flexible service delivery platform can be implemented by maximizing the use of existing network resources; on the other hand, in the future such a system may, of course, be better integrated with an NGN or 3G network, i.e. after the traditional Program-controlled Telephone Line Switching System will no longer implement the integrated services functions, and only the basic management and switching functions will be retained behind it; at the same time, with subsequent development, the SCP (SCP) 41 can also be converted into a service level component of the future network.

However, taking into account the current situation in the existing network, the following problems exist in the aforementioned developing PSTN system (PSTN) based on the IP network (IN).

1) In order to improve all the diverse and numerous stations of the original PSTN network (PSTN), as required by the concept of a developing system, significant costs are required.

2) It is difficult for some old low-power station models to carry out new functions even after modernization and reconstruction.

3) Since it will be necessary to establish connections between a large number of stations and a billing center in order to charge online, problems will arise due to the number and type of stations and software versions, as well as the size of the investments required for this and the complexity of the technology, which will cause serious difficulties due to the fact that collecting billing information will require very high costs.

4) The entire network should be involved in the development, which also applies to various manufacturers, models and versions of stations, and its implementation will require a long period and be fraught with many difficulties.

Briefly, according to the requirements of this plan, the telecom operator must simultaneously upgrade the software / hardware of all Software-Managed Telephone Switching Systems of the previous PSTN network (PSTN), which will require too much reconstruction of the existing networks of this telecom operator and lead to additional risks.

SUMMARY OF THE INVENTION

A developing system of the Public Switched Telephone Network (PSTN) is proposed, the introduction of which will allow to achieve a higher degree of reuse of available devices and network resources, reduce the cost of reconstruction and simplify the implementation of the system during the development of the PSTN network (PSTN).

The evolving Public Switched Telephone Network (PSTN) system contains:

a billing center, a plurality of Local Stations (MS (LE)), at least one Service Switching Point (SSP) and at least one service control device,

The Local Station (MS (LE)) is designed to receive a call from a user terminal, which is a request for a service, and to route a received call, which is a request for a service, to an SSP;

PKU (SSP) item is designed to receive a call representing a service request from an MS (LE) station, to transfer a call representing a service request to a service control device according to pre-configured switching conditions, executing a control command returned from the service control device, and further it is intended for sending service information necessary for charging payment to the billing center;

the service control device is designed to receive a call, which is a request for a service, from the PKU (SSP) item according to the service switching condition, to process the service according to the requirements of this service and return the control command to the PKP (SSP) station to manage the call;

The billing center is designed to charge according to the information about the service coming from the PKU (SSP) point.

The PKU (SSP) item contains: a module that implements the Service Switching Function (PKF (SSF)) and a module that implements the Call Control Function (CCF), moreover

the PKU module (SSF) is designed to communicate with the service control device and send the control command returned by the service control device to the CCF module, and the CCF module is intended to perform call / connection processing and to control according to the control command received from the PKU module (SSF).

The service control device contains all the service processing modules of the MS (LE) stations and the Intermediate Stations (PS) of the PSTN network intended for processing the corresponding services sent to the service control device.

The service control device is a Service Management Point (SCP) of the Intelligent Network (IS) or Application Server (SP) of the Next Generation Network (NGN).

An MS (LE) station is some MS (LE) with a basic PSTN call forwarding function (PSTN).

The method for processing a service in the developing system of the Public Switched Telephone Network (PSTN) contains the following steps:

the access level of the developing system directs all received calls, which are requests for the provision of services, to the intermediate level of the developing system;

upon receipt from the access level of calls representing requests for the provision of services, the intermediate layer receives calls representing requests for the provision of services, regardless of a pre-configured switching condition;

upon receipt of calls representing service requests from the access level, the intermediate layer switches and addresses calls, representing service requests, to the service level of the developing system according to a pre-configured switching condition;

the service level processes calls representing service requests from the intermediate level and sends control commands to manage calls representing service requests to the intermediate level;

and the intermediate layer manages the service calls in accordance with the received control commands.

The step of directing the access level of all service calls to the Service Switching Point (SSP) contains:

Configuring the call addressing direction of the Program-Managed Telephone Line Switching System of the access level to an intermediate level in advance.

This method further comprises the following steps:

after the intermediate layer receives a call representing a service request, the intermediate layer requests a type of service processing device corresponding to a received call representing a service request according to a corresponding pre-configured relationship between calls representing service requests and device types processing services; if it is discovered that the type of service processing device is the Service Management Point (SCP) of the Intelligent Network (IS), then the intermediate layer commutes and addresses the received call, which is a request for the provision of the service, to the PUC (SCP) the level of services of the IP network (IN) for its processing; if it is discovered that the type of service processing device is the Next Generation Network Application Server (AS) of the Next Generation Network (NGN), then the intermediate layer switches and addresses the received call, which is a service request, to the AS server (AS) the level of service network MTP (NGN).

This method further comprises the following steps:

the intermediate level sends information about the service for charging to the billing center of the developing system, and the billing center performs charging according to the information received.

The access level functions are performed by the Local Station (MS (LE)) of the PSTN network (PSTN).

The intermediate level functions are performed by the PKU (SSP) point of the IS network (IN), formed as a result of modernization from the Intermediate Station (PS (TE)) of the PSTN network.

The functions of the service level are performed by the upgraded Service Control Point (SCP) of the PSTN network (PSTN), and the step of modernizing the Point of Service Control Point (SCP) of the PSTN network (PSTN) contains

adding to the PUK (SCP) point service processing modules of Program-Managed Telephone Line Switching Systems of MS (LE) and PS (TE) stations of the PSTN network (PSTN).

The functions of the service level are provided by the SP server (AS) of the SSP network (NGN).

Differences of the technical solution proposed in this invention from solutions known from the prior art are as follows:

Firstly, the Program-controlled Telephone Line Switching System of the PS (TE) station has been transformed into a PKU (SSP) item with a PKU (SSF) function, which will allow the call to be switched to the corresponding service control device for processing the service; secondly, it is only necessary to configure the data in such a way that, using the call and routing functions of the MS (LE) station, to direct all services to the control point (SSP) of the PS (TE) station, and there is no need to upgrade the MS (LE) itself; thirdly, the billing center will have to receive service information for charging only from the PKU (SSP).

These differences provide the following obvious benefits:

Firstly, since there is no need to reconstruct a large number of MS (LE) stations, the cost of upgrading these MS (LE) stations has been reduced, the degree of reuse of available devices and network resources has been increased, the implementation of such a system has been simplified, the costs of development of the entire PSTN network (PSTN), protection of the invested funds of this telecom operator is ensured, and the risk associated with the development of the PSTN network (PSTN) is minimized;

Secondly, the billing center collects service information for charging only from the PKU (SSP) point, and as a result of simplifying the charging process, data collection costs are reduced;

Thirdly, since only PS (TE) stations of the PKU (SSP) point need to be reconstructed, the amount of necessary work is reduced and such a development plan is safer, since there is no need to use complex MS (LE) stations or to carry out their large-scale replacement and modernization .

In addition, with the development of the NGN network, the concept of separation of switching and control becomes more attractive, since the level of services will have to solve more and more problems of an increased degree of complexity, and the requirements for network levels will increase. In this sense, the independent level of services proposed in the developing PSTN system according to the present invention provides a clearer organization of network levels, which makes the separation of functions of each level more clear.

Brief Description of the Drawings

Figure 1 presents a diagram showing the basic architecture of a PSTN network (PSTN) according to the prior art;

Figure 2 presents a diagram showing the architecture of an evolving PSTN system (PSTN) according to the prior art;

Figure 3 presents a diagram showing the structure of a traditional IP network (IN) based on PSTN (PSTN);

Figure 4 presents a diagram showing the architecture of a developing PSTN system (PSTN) based on the IP network (IN) according to the prior art;

5 is a diagram showing the architecture of an evolving PSTN system (PSTN) according to an embodiment of the present invention;

FIG. 6 illustrates an algorithm for processing a simultaneous call service in a developing PSTN system (PSTN) shown in FIG. 5.

Embodiments of the invention

The following is a detailed description of the present invention with reference to the accompanying drawings and embodiments thereof.

5 is a diagram showing the architecture of an evolving PSTN system (PSTN) according to an embodiment of the present invention. As shown in FIG. 5, the system comprises a billing center and three levels, namely a service level 51, an intermediate level 52 and an access level 53. The service layer 51 comprises at least one service control device, which may be an IC (IN) point 510, an NGN network SP (AS) server 511, or a combination of an SCP (SCP) 510 and a server SP (AS) 511. The intermediate level 52 contains at least one PKP (SSP) point connected to the PUK (SCP) 510 and to the SP server (AS) 511 of the service level 51. Items PKU (SSP) 520 and 521, interconnected, are shown as an example in figure 5. The access level 53 contains a large number of MS (LE) stations connected to the PCPs (SSPs) of the intermediate level 52, which are represented in FIG. 5 by the MS (LE) stations 530, 531, 532, 533, 534 and 535. The billing center 50 is connected with the items PKU (SSP) 520 and PKU (SSP) 521.

At access level 53, each of the MS (LE) stations is designed to receive service calls from user terminals and to route received service calls to an SSP point connected to this MS (LE) station at an intermediate level. In an embodiment of the present invention, each MS (LE) station can be connected to at least one PKP (SSP) point, and the number of SSPs (SSPs) to which the MS (LE) is connected depends on the specific network environment.

In this embodiment, each MS (LE) station still uses the traditional Program-driven Telephone Switching System of the MS (LE) stations of the source PSTN (PSTN). However, this embodiment of the invention uses the basic service forwarding function, therefore, it is necessary to configure the data for each Program-controlled Telephone Line Switching System of each MS (LE) so that all calls received by this MS station (LE) are routed directly to the PKU (SSP) point connected to this MS (LE) station at the intermediate level 52.

At the intermediate level 52, each PKU (SSP) item contains the FCF (CCF) and FCU (SSF) modules. The CCF module (SSF) is designed to implement the communication interface between the FCF module (CCF) and the service control device and for sending the control command returned from the service control device to the FCF module (CCF); CCF module (CCF) is designed to perform call / connection processing and to manage service calls according to the control command transmitted by the FCF module (SSF); if the service control device is a server of a joint venture (AS) of an SSP (NGN) or 3G network, then the communication interface implemented by the PKU module (SSF) must also contain a packet transmission protocol interface to provide communication with the joint venture (AS) server. The PKU (SSP) item is mainly intended for establishing a connection to a service call, and the service switching condition can be set and saved depending on factors such as the number of the calling subscriber, the number of the called subscriber or the type of service; the CCF module (CCF) determines whether the service call meets the switching condition; if the service call meets the switching condition, then it will be directed to the appropriate service control device; otherwise, switching will not be performed.

The PKU (SSP) item is intended for receiving service calls from the MS (LE) station, for establishing connections with service calls, switching and redirecting service calls according to the switching condition to the corresponding service control device, executing the control command returned from the service control device, and call management. The PKU item (SSP) also transmits information about the service to the billing center for charging.

In the PKP (SSP) point, a detection point and a control point can also be created for a particular service, where the detection point is designed to inform the service control device about events occurring during the call processing and to wait for a new control command from the service control device, and the point control is designed to control the call procedure according to the control command received from the service control device.

The PKU point (SSP) of this implementation of the invention is formed by reconstructing the traditional Program-controlled Telephone Switching System of the Substation PS (TE) of the PSTN source network (PSTN). In the traditional Program-managed Telephone Line Switching System of the PSTN source network (PSTN), i.e. at stations operating on the principle of channel switching, such functions as access, the function of CCF (CCF), the functions of switching, services and signaling are implemented. All these functions are united in one station, forming an integrated, closed and specialized system structure. Its reconstruction involves the removal of a module with the processing function of services of a traditional Program-controlled Telephone Line Switching System, simplification of the CCF module (CCF) so that it will no longer be associated with the implementation of services, modernization and conversion of the module with the switching function to the CCF module (SSF) , which will implement the communication interface between the source FCF module (CCF) of the station and the FCF module (SCF) in the service control device, as a result of which the station will be able to manage service calls under the control of the mode I SCF (SCF). In more detail, the way to simplify the CCF module (CCF), which allows organizing it unrelated to the implementation of services, as well as upgrading and converting the module with the switching function to the PKU module (SSF), is similar to the way of simplifying, upgrading and converting a Program-controlled Telephone Switching System in the developing PSTN system (PSTN) based on the IP network (IN), which is already known from the prior art and will not be described hereinafter. Through the aforementioned reconstruction, a traditional Program-Controlled Telephone Line Switching System of a PST station (PSTN) network can be transformed into a PCP point (SSP) by the method proposed in the embodiment of the invention. If the traditional Program-managed Telephone Line Switching System of the source station PS (TE) already supports some interfaces and packet transfer protocols, then the service call can be routed by the reconstructed PKU (SSP) point directly to the SP (AS) server of the SSP (NGN) or 3G networks , and this joint venture (AS) is designed to handle a service call. If the traditional Program-managed Telephone Line Switching System of the source station PS (TE) does not support interfaces and packet transfer protocols, then in cases when the service control device is a SP server (AS), to the PKU module (SSF) of the PKU (SSP) item it is necessary to add interfaces and packet transfer protocols.

With the subsequent development and expansion of the network, the intermediate control point (SSP) point of this implementation option can become the KMSh (MGC) controller of the SSN network (NGN). Since many of the functions of the KMSh controller (MGC) can be implemented by the software of the Program-controlled Telephone Switching System of an existing channel switching station, the KMSh (MGC) controller according to this embodiment can be formed by reconstructing a traditional Program-controlled Telephone Switching System the source station PS (TE) of the PSTN network (PSTN) in a manner similar to converting a Software-Managed Telephone Line Switching System to an SSP point above A developing PSTN system (PSTN) based on the IP network (IN), which is not described further here.

At the service level 51, the IC network item (SCP) of the IP network (IN) known in the art, the CPS network server (AS) of the MSC network (NGN), or the device containing the CCP network (SCP) and the SP server can be used as a service control device (AS). The service control device comprises an FCF module (SCF) for managing calls and an FCF module (SDF) for storing service data and network user data. The service control device further comprises a service processing module for processing service calls. Persons skilled in the art can develop various options for service processing modules depending on the various requirements for service processing and combine these various service processing modules in a service control device. The service control device is designed to receive service calls from the PKU (SSP) point, to call the corresponding service processing module depending on the type of service call, and to return the control command necessary for processing the service to the PKU (SSP) point, i.e. in order to send a command to the control panel (SSP) about the need to manage this service call. As an alternative, the PDF (SDF) function can be implemented by an independent device that communicates with the FCF module (SCF) through an open interface.

In this embodiment, the service control device is formed by reconstructing a PSTN point of the PSTN network according to the state of the art, i.e. through the PUU point (SCP) of the traditional IP network (IN), and the reconstruction process is as follows: service processing modules in the Program-managed Telephone Line Switching System of the MS station (LE) of the PSTN source network (PSTN) and the Program-controlled Telephone Line Switching System PS (TE) stations of the original PSTN network (PSTN) are attached to the PSTN point of the PSTN source network (SCP), and new service processing modules are also added to the PST point of the original PSTN network (PSTN) in accordance with the requirements new services. The development of services due to the reconstruction of the SCP (SCP) point is carried out in a uniform and smooth manner during the development of the PSTN network itself (PSTN), which reduces the cost of this development.

If a service center server (AS) of an SSP network (NGN) is adopted as a service control device, then the service processing modules in the PSTN source program network (PSTN) and the program-controlled station telephone line switching system The MS (TE) of the source PSTN (PSTN) is connected to the SP server (AS), and other new service processing modules will also be added to the SP server (AS) in accordance with the requirements of the new services.

As the billing center 50, the PSTN network billing center (PSTN), known from the prior art, is still used, except that the relationship of the connections between it and other devices is changed. According to this embodiment of the invention, the connections of all service calls are established by an intermediate level control center (SSP) point, so that the billing center 50 does not need to establish a connection with all access stations of the MS (LE) level 53, but only needs to establish a connection with all points of the control panel (SSP) intermediate level; PKU (SSP) sends information about services for charging to the billing center 50, which can carry out charging according to the received information about the services.

As described above, for a developing PSTN system (PSTN) according to an embodiment of this invention, in the development process, it is only necessary to reconstruct the nodes in three parts of the initial PSTN network (PSTN), namely the devices contained in the billing center, the PS (TE) station and the point PKU (SSP), without significant reconstruction of traditional Software-controlled Telephone Line Switching Systems contained in all MS (LE) stations of the PSTN source network (PSTN), which are the most numerous and expensive and whose design var iruetsya according to different manufacturers, types and options. Instead, by using the routing capabilities of the basic services of traditional stations, the risk associated with the development and reconstruction processes and the costs of their implementation are minimal.

In accordance with an embodiment of this invention, the development of a traditional PSTN network (PSTN) is achieved through the full use of the basic routing functionality of the services of traditional Software-controlled Telephone Switching Systems and through the reconstruction of a PS (TE) station. New and old services used by users are provided and supported by the IS network (IN), which contains the intermediate level SSP (SSP) points and the service level PUU (SCP) points, or the combined network of NGN and IS (IN), which contains the PKU points (SSP) middle tier and server SP (AS) service level.

With the subsequent development of the network, if the traditional station will be transformed into such functional elements as the MLU gateway (MG), the KMSh controller (MGC) and the signaling gateway, you can integrate the control function of the ICP (SCP) point into the KMSh controller (MGC), and then the level of services in the developing system may contain only a joint venture (AS) server, while the services of the IS (IN) network will be included in the set of services of the SSP (NGN) network.

Based on the above developing PSTN system (PSTN), a method for processing services in a developing PSTN system (PSTN) according to the implementation of the present invention is described below on the example of one of the basic telecommunication services - simultaneous call service.

In order to process the service of simultaneous making calls, it is necessary to set and save the switching condition in the PKU (SSP) item of the intermediate level and add the service processing module to the service level service control device. Here, the condition for switching is to register subscriber information for the simultaneous call service by the number of the called subscriber.

Figure 6 shows the algorithm for processing services for simultaneous sending calls in a developing PSTN system (PSTN) according to the above implementation option, which contains the following steps:

Step 601: The calling subscriber initiates a call directed to the called subscriber, the call arrives at the access level station MS (LE) and is then routed by the station MS (LE) directly to the intermediate control center (SSP) point. The routing direction of the call to the SSP point (SSP) is predefined in the Program-controlled Telephone Line Switching System of the MS (LE) station by configuring the data, which forces the MS (LE) station to forward all received service calls to the SSP point.

Step 602: After receiving the service call, the PKP (SSP) item checks on the basis of the pre-configured switching conditions whether the user has registered for the simultaneous call service; if the user has registered such a subscription to the simultaneous call service, the call to the simultaneous call service is sent to the device of the service level service.

Step 603: Since the corresponding simultaneous call service processing module has been added to the service control device, after receiving the simultaneous call service call, the service control device calls the simultaneous call service processing module, which should generate an appropriate response to the call to this service. In the process of processing the service, the FDU (SDF) module searches for the number of the called subscriber and the corresponding numbers for simultaneously sending calls, and a control command for managing the call, which contains all of the above numbers, is transmitted to the PKP (SSP) item.

Step 604: The PKU (SSP) item receives a control command of the service control device and performs call control according to the control command, i.e. To perform the service, calls of the called subscriber and subscribers of the numbers of simultaneous making calls are simultaneously initiated.

Step 605: The PKP point (SSP) sends information about the service for charging to the billing center, and the billing center performs charging according to the received information about the service.

Alternatively, the PKU (SSP) point sends information about the service to the billing center for charging in the process of switching and forwarding the service call by the PKP (SSP) point to the service control device, and the billing center performs charging according to the received information about the service.

For a smooth transition from a developing PSTN system (PSTN) to NGN or 3G networks, a service control device is usually a combination of an SCP (SCP) and a SP server (AS), and in case of switching, you must specify the types of service control devices for each type of service call, i.e. it is necessary to clearly determine whether the ICP (IN) point of the IP network (SCP) or the JV server (AS) of the MNP network (NGN) processes this service. After the service call is received by the PKU (SSP) item, the method contains the following steps:

the PKU (SSP) item requests the type of service control device corresponding to the received service call; if the type of service management device corresponding to the received service call is the ICP (SCP) point of the IP network (IN), then the received service call should be routed to the ICP (SCP) point of the IP network (IN); if the type of service management device corresponding to the received service call is the server of the network of the network of networks (NGN), then the received call of the service should be sent to the server of the network of the network of the network (NG) network of the network (NGN).

End users use the new and old services in exactly the same way as they would use the services provided by the NGN network alone, which includes MS gateways and MGC controllers, so that a developing system according to embodiments of the present invention is capable of provide a variety of network services for a sufficiently long period, which ensures smooth development with the maximum possible use of available devices and network resources, protection of existing investment resources of telecom operators and allows to avoid the risks associated with development to the maximum extent.

The above descriptions are only preferred embodiments of the present invention, and they are not used to limit the scope of legal protection of the present invention. Any modifications or replacements that can easily be performed by specialists with knowledge in the art do not go beyond the legal protection of the present invention.

Claims (13)

1. The developing system of the Public Switched Telephone Network (PSTN (PSTN-)), containing a billing center, a plurality of Local Stations (MS (LE)), at least one Service Switching Point (SSP) and at least one service control device, the station (MS (LE)) is designed to receive a call representing a request for a service from a user terminal and to send a received call representing a request for a service to an SSP; PKU (SSP) item is designed to receive a call representing a service request from an MS (LE) station, to transfer a call representing a service request to a service control device according to pre-configured switching conditions, executing a control command returned from the service control device, and further it is intended for sending service information necessary for charging payment to the billing center; the service control device is designed to receive a call, which is a request for a service, from the PKU (SSP) item according to the service switching condition, to process the service according to the requirements of this service and return the control command to the PKP (SSP) station to manage the call; The billing center is designed to charge according to the information about the service coming from the PKU (SSP) point. 2. The evolving PSTN network system (PSTN) according to claim 1, in which the SSP item contains a module that implements the Service Switching Function (SSF) and a module that implements the Call Control Function (CCF), moreover the PKU module (SSF) is designed to communicate with the service control device and send the control command returned by the service control device to the CCF module, and the CCF module is intended to perform call / connection processing and to control according to the control command received from the PKU module (SSF). 3. The developing PSTN system (PSTN) according to claim 1, in which the service control device comprises all the service processing modules of the MS (LE) stations and the Intermediate Stations (PS) of the PSTN network intended for processing the corresponding services forwarded into this service management device. 4. The developing PSTN system (PSTN) according to claim 3, wherein the service control device is a Service Management Point (SCP) of the Intelligent Network (IS) or an Application Server (SP) of the Next Generation Network (MTS) (NGN)). 5. The developing PSTN system (PSTN) according to claim 1, in which the MS station (LE) is the MS station (LE) with the main call forwarding function of the PSTN network (PSTN). 6. A method for processing a service in the developing Public Switched Telephone Network (PSTN) system, which contains the following steps: the access level of the developing system directs all received calls, which are requests for the provision of services, to the intermediate level of the developing system; upon receipt from the access level of calls representing requests for the provision of services, the intermediate layer receives calls representing requests for the provision of services, regardless of a pre-configured switching condition; upon receipt of calls representing service requests from the access level, the intermediate layer switches and addresses calls, representing service requests, to the service level of the developing system according to a pre-configured switching condition; the service level processes calls representing service requests from the intermediate level and sends control commands to manage calls representing service requests to the intermediate level; and the intermediate layer manages the calls, which are requests for the provision of services, in accordance with the received control commands. 7. The method according to claim 6, in which the step of directing the access level of all service calls to the Service Switching Point (SSP) comprises configuring the addressing direction of the call of the Software-managed Telephone Line Switching System of the access level to an intermediate level in advance. 8. The method according to claim 6, further comprising the following steps: after the intermediate layer receives a call representing a service request, the intermediate layer requests a type of service processing device corresponding to a received call representing a service request according to a corresponding pre-configured relationship between calls representing service requests and device types processing services; if it is discovered that the type of service processing device is the Service Management Point (SCP) of the Intelligent Network (IS), then the intermediate layer commutes and addresses the received call, which is a request for the provision of the service, to the PUC (SCP) the level of services of the IP network (IN) for its processing; if it is discovered that the type of service processing device is the Next Generation Network Application Server (AS) of the Next Generation Network (NGN), then the intermediate layer switches and addresses the received call, which is a service request, to the AS server (AS) the level of service network MTP (NGN). 9. The method according to claim 6, further containing the following steps: the intermediate level sends information about the service for charging to the billing center of the developing system, and the billing center performs charging according to the information received. 10. The method according to any one of claims 6 to 9, wherein the access level functions are performed by the Local Station (MS (LE)) of the PSTN network (PSTN). 11. The method according to any one of claims 6 to 9, in which the intermediate level functions are performed by a control unit (SSP) of the IS network (IN) formed as a result of modernization from the Intermediate Station (PS) of the PSTN network. 12. The method according to any one of claims 6 to 9, wherein the upgraded Service Control Point (SCP) of the PSTN network (PSTN) performs the functions of the service level, and the step of upgrading the PSTN point of SCP (PSTN) contains an appendix to the point of the PUU (SCP) of the service processing modules of the Program-Managed Telephone Switching Systems of the MS (LE) and PS (TE) stations of the PSTN network (PSTN). 13. The method according to any one of claims 6 to 9, in which the functions of the service level are performed by the server of the joint venture (AS) of the network of the SSP (NGN).

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