KR101017502B1 - Duplicate billing system and method in a communication network - Google Patents

Abstract

A redundant charging system and method are provided. The redundant charging system includes: a first charging unit configured to receive a data packet transmitted to a first communication network and perform charging processing according to a predetermined charging rule; A second charging unit disposed in series with the first charging unit and configured to switch to an active mode and perform the charging process when the first charging unit is inoperable; And a switching unit for bypassing the data packet passing through the first charging unit and transferring the data packet to the second charging unit when the first charging unit is inoperable.

Billing Redundancy, Bypass, Billing System

Description

Duplex billing system and method in a communication network

The present invention relates to a redundant billing system and method, and more particularly, to a redundant billing system and method capable of continuously performing billing processing without interrupting service provision in response to an inoperable state of the billing system. .

The demand for communication services is rapidly increasing, including the generalization of information and communication services, the emergence of various multimedia services, and the emergence of high quality services. Various mobile communication technologies are emerging to satisfy these demands.

Due to competition in the communication market and technological development, various types of packet-based services are provided in mobile communication, and various services based on packet services are being developed day by day.

Appropriate billing systems are needed for these various services. For example, the charging system may be down or the operation of the charging system may be interrupted or the user may not be able to efficiently process the traffic.

Therefore, various researches and developments have been attempted for stable and reliable charging processing while providing a service through a data packet. There is a need for a system and method for stably and reliably charging a variety of services provided by a service provider providing a communication network.

The problem to be solved by the present invention is to provide a stable and reliable billing system and method by continuously performing the billing process without interrupting service provision in response to the inoperable state of the billing system.

The objects of the present invention are not limited to the above-mentioned objects, and other objects that are not mentioned will be clearly understood by those skilled in the art from the following description.

One aspect of the redundant charging system of the present invention for achieving the above object is a first charging unit for receiving a data packet transmitted to the first communication network and performs the charging process according to a predetermined charging rule; A second charging unit disposed in series with the first charging unit and configured to switch to an active mode and perform the charging process when the first charging unit is inoperable; And a switching unit for bypassing the data packet passing through the first charging unit and transferring the data packet to the second charging unit when the first charging unit is inoperable.

One aspect of the redundant charging method of the present invention for achieving the above object is an inoperable state of a first charging unit in a method for charging a data packet passing through a transmission path between a first communication network and a second communication network. Detecting; If it is determined that the first charging unit is inoperable, bypassing the data packet transmitted from the first communication network so that the first charging unit does not pass through the first charging unit; Transmitting the bypassed data packet to a second charging unit by a second switching unit; And transmitting, by the second charging unit, the data packet to the second communication network after the charging process.

Specific details of other embodiments are included in the detailed description and the drawings. Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, and only the embodiments make the disclosure of the present invention complete, and the general knowledge in the art to which the present invention belongs. It is provided to fully inform the person having the scope of the invention, which is defined only by the scope of the claims. Like reference numerals refer to like elements throughout.

Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating a WCDMA communication network according to an embodiment of the present invention. Referring to FIG. 1, a WCDMA communication network (aka UMTS network) according to an embodiment of the present invention is connected to a terminal 10, a wireless access network (UTRAN; UMTS Terrestrial RAN, 20), and a wireless access network. It may include a core network (Core Network) 60 in response to the connection with the. In this case, the WCDMA communication network of FIG. 1 may be understood as a universal mobile telecommunication system (UMTS) system, but is not limited thereto. For example, it can be applied not only to WCDMA networks but also to IMS networks or other next-generation networks.

The terminal 10 may include personal digital assistants (PDAs), computers, and the like capable of wireless communication as well as user equipment used for wireless communication. The terminal 10 may be classified into a calling terminal that makes a call request, a message transmission request, a data packet transmission request, and a destination terminal that is a destination of a call, message, data packet transmission, and the like.

A radio access network (RAN) 20 includes a base station 22 and a base station controller 24 that accommodates a 3GPP standard radio access standard to support WCDMA. The radio access network 20 transmits a call request signal, a data transmission signal, and the like from the terminal 100 to the core network.

The base station 22 sets a wireless physical channel necessary for data exchange with the terminal 10 according to the control information transmitted from the base station controller 24, and transfers the data transmitted from the upper layer protocol to the terminal 10 according to the wireless environment. send.

A base station controller (Radio network controller) 24 dynamically allocates radio resources of the wireless communication system and controls the base station 22.

The mobile switching center 31 transfers incoming and outgoing signals from the base station 22, and provides a function of switching between mobile subscribers and a fixed network subscriber such as PSTN and ISDN. . The circuit switch 31 may include a visitor location register (VLR) having subscriber information such as location information of the terminal 10 temporarily to process a call from the subscriber.

The circuit switched gateway (GMSC) 32 is a gateway at a point where the circuit switched 31 is connected to the external network 80. All circuit switched connections are made via circuit switched gateway 32.

The circuit switching unit 30 may be referred to as a circuit switching unit 30 including the circuit switch 31 and the circuit switching gateway 32. The circuit switching unit 30 establishes a communication path with the terminal 10 through a circuit switching connection. .

The Serving GPRS Support Node (SGSN) 45 (SGSN) is a mobile station for managing GPRS services, a call management procedure for calling and receiving calls, and a session management, authentication and billing function for handling packet data transmission and reception. And so on. It also has a routing processing function of packet data.

A packet switching gateway (GGSN) 46 is a serving node of an IP (Internet Protocol) based packet network that provides a high speed packet data service for GPRS data service. It manages the packet data routing function of the packet data and provides an interface for connecting the WDCMA network and other network 300.

The packet exchange support node 45 and the packet exchange gateway 46 may be referred to as a packet exchange unit 40. The packet exchanger 40 transmits and receives data in packet units in the data transmission and reception of the terminal 10.

A home location register (HLR) 53 stores and manages location information of a subscriber, and an authentication center (AuC, not shown) generates an authentication vector and performs a subscriber authentication function.

In addition, the subscriber database server 52 includes subscriber information, subscriber terminal information, and the like, and provides the subscriber information, the subscriber terminal information, and the like to other components that request the subscriber information.

The external network 80 is a network connected to the outside through the circuit switching unit 30 or the packet switching unit 40. The circuit switching unit 30 is related to transmission and reception of circuits such as voice calls. The circuit switching unit 30 may be a public switched telephone network (PSTN), an integrated services digital network (ISDN), or a public land mobile network (PLMN). The packet exchange unit 30 is related to the transmission and reception of data packets. The other network 300 connected by the packet switching unit 40 may be, for example, an Internet Protocol (IP) network such as the Internet, an IMS network, a service provider building network, or the like.

The billing system 200 analyzes the packet data entering and exiting through the packet exchanger 40 to perform billing processing. The billing system 200 may be arranged inline on a path of entering and exiting the packet data, and may analyze the packet data in real time or temporarily store the billed data for each terminal 10 or service provider.

Figure 2 shows a predetermined network configuration including a redundant charging system according to an embodiment of the present invention. Referring to FIG. 2, the structure of the communication network including the charging system may further include the charging system 200 as shown in FIG. 1.

The other network 300 may refer to a network connected to the general mobile communication network disclosed in FIG. 1 and transmitting and receiving data through a packet unit or IP. Here, the other network 300 may be connected to one or more service servers 150 that provide various services in the case of a predetermined core network.

Meanwhile, in one embodiment of the present invention, a general mobile communication network including the wireless access network 20 and the packet switching unit 40 will be referred to as a first communication network, and the other network 300 will be referred to as a second communication network.

The service server 150 is a server connected to the core network of the second communication network and providing multimedia services such as voice, audio, video, and data based on the IP protocol. Therefore, the service server 150 may be configured in plurality according to the content and type of service. For example, a VOD service server is required to perform a video on demand (VOD) service, and a traffic situation providing server is required to perform a service providing a real-time traffic situation. It may include a content server for a variety of services to provide and an additional service server for providing an additional service.

The charging system 200 analyzes the packet data signal passing over a given interface between the packet switched gateway (GGSN) 46 and the other network 300. Here, the predetermined interface 41 refers to an interface supporting between the packet switched gateway 46 and the other network 300.

For example, suppose that when the video conferencing or the like is supported from the calling terminal 11 to the called terminal 12, the service server 150 passes through the IMS core network as another network 300 network. In this case, the packet data from the originating terminal 11 passes through the radio access network 20, the packet switching support node 45, the packet switching gateway 46, the IMS core network and the service server 150, and again the IMS core network. Then, the destination terminal 12 is reached via the packet switched gateway 46, the packet switched support node 45, and the wireless access network 20.

As described above, when performing a service through the service server 150 in the external network, such as a communication network (IMS network) of the IP multimedia subsystem, data packets passing through a predetermined interface may be analyzed. Can be. In the charging system 200 according to an embodiment of the present invention, the data packet passing through the interface may be analyzed to perform billing processing for each terminal 11 or 12 or a service provider.

The billing system 200 may be configured inline between communication networks that are transferred to another network 300. Accordingly, when the charging system 200 is in an inoperable state such as the power of the charging system 200 is turned off, the system according to the inoperation is down, or the possibility of part of the system is stopped, the packet switching gateway (GGSN) 46 and other networks are lost. It is not possible to handle user traffic passing over a given interface between the 300, so that the service provided may be disconnected.

Therefore, even if a portion of the predetermined charging system 200 is switched to an inoperable state, there is a need for a system and method for processing charging for data packets without loss while continuously processing user traffic.

3 shows a block diagram of a redundant charging system according to an embodiment of the present invention. Referring to FIG. 3, the redundant charging system 200 according to an embodiment of the present invention includes a gateway 110 and 111, a first charging unit 210, a second charging unit 220, and a switching unit 230. 231, 240, and 241, routers 120 and 121, and a system diagnosis unit 250 may be included. The charging system 200 according to an embodiment of the present invention may be located between the first communication network and the second communication network, which are different communication networks. In addition, the charging system 200 may be a configuration included in the first communication network, or may be a configuration included in the second communication network.

The gateways 110 and 111 serve to provide an interface for transferring data packets transmitted from the first communication network to the second communication network. For example, if the first communication network is a WCDMA communication network, the gateways 110 and 111 may be packet switched gateways. The gateways 110 and 111 may perform a router function informing the moving path to the destination of the data packet. The gateway may be composed of a first gateway 110 and a second gateway 111. The first gateway 110 is a gateway that performs a predetermined operation in an active mode, and the second gateway 110 is a gateway that is waiting for stopping a predetermined operation in a standby mode. Therefore, when the first gateway 110 is in an inoperable state, the second gateway 110 may be converted into an active mode to perform a predetermined operation on behalf of the first gateway 110. In this case, the inoperable state refers to a state in which the power of the gateways 110 and 111 is turned off or fails to perform a role of a gateway such as a system down due to an overload or abnormal operation.

The charging unit 210 or 220 performs charging processing according to a predetermined rule for data packets passing between the gateways 110 and 111 and the routers 120 and 121 to be described later. The charging unit 210 or 220 may change the charging process according to the charging policy of the service provider or the charging policy of the packet network. The charging unit 210 or 220 may receive data packets from the switching units 230, 231, 240, and 241 which will be described later, and analyze the data packets to generate charging data.

The charging units 210 and 220 may be arranged in series along the transmission paths 115 and 125 of the first charging unit 210 and the second charging unit 220 to have a redundant structure. The first charging unit 210 operates in an active mode and performs charging processing on the data packets passing through the transmission paths 115 and 125. In this case, the second charging unit 220 operates in the standby mode, and the data packet is immediately transmitted without passing through the second charging unit 220 by the third switching unit 240 which will be described later.

When the first charging unit 210 is in an inoperable state, the second charging unit 220 may operate by switching to the active mode. Here, the inoperable state refers to a state in which the power of the first charging unit 210 is turned off, or the charging unit such as a system down due to an overload or abnormal operation does not play a role. When the first charging unit 210 is in an inoperable state, a data packet does not pass through the first charging unit 210 due to bypass by the first switching unit 230, which will be described later. 220). The second charging unit 220 may perform the charging process while continuing to perform the service without disconnecting the service even if the first charging unit 210 becomes inoperative by performing the charging process instead of the first charging unit 210. have.

The switching units 230, 231, 240, and 241 serve to adjust the path of the data packet by a predetermined switch. For example, when the first charging unit 210 operates normally, the first switching unit 230 transmits the data packet transmitted from the first gateway 110 to the first charging unit 210. The first charging unit 210 transfers the data packet to the second switching unit 240 after a predetermined charging process, and the second switching unit 240 does not pass the data packet to the second charging unit 220. Bypass the transmission to the first router (120).

However, when it is determined that the first charging unit 210 is in an inoperable state, the first switching unit 230 may bypass the switching by not transferring the data packet to the first charging unit 210. The bypassed data packet is switched to pass through the second charging unit 220 by the second switching unit 240, and the second charging unit 220 analyzes the data packet to perform the charging process. The charged data packet may be transmitted to the second communication network by the router 120. Here, switching means changing the existing data passing path by the switching element.

If the first gateway connected to the first communication network is in an inoperable state, the second gateway 111 switches to the active mode and operates. At this time, the second gateway 111 transfers the data packet from the first communication network to the first charging unit 210 by the third switching unit 231. However, when it is determined that the first charging unit 210 is in an inoperable state, the third switching unit 231 bypasses the data packet by switching without transferring the data packet to the first charging unit 210. . The bypassed data packet may be transmitted to the second communication network after being charged by the second charging unit 220 by the fourth switching unit 241.

As described above, in the embodiment of the present invention, when the first charging unit 210 is switched to the inoperable state, the data packet is bypassed by the switching units 230 and 231 performing the bypass function. By passing through the second charging unit 220, in response to the sudden inoperability of the charging units 210 and 220 configured inline, continuous charging processing can be performed without disconnecting the service.

The routers 120 and 121 set a transmission path of the data packet for the destination to the service server of the second communication network. The routers 120 and 121 may be configured of a first router 120 operating in an active mode and a second router 121 waiting in a standby mode. In response to the inoperability of the first router 120 or the inability of the transmission path 125, the second router 121 may switch to the active mode and transmit a data packet to a predetermined service server of the second communication network.

The system diagnosis unit 250 includes a first charging unit 210, a second charging unit 220, a switching unit 230, 231, 240, 241, transmission paths 115, 117, 125, and 127, and a gateway 110. 111 and the routers 120 and 121 serve to diagnose operating states of one or more components. For example, when diagnosing an operating state of the first charging unit 210, the system diagnosis unit 250 transmits a predetermined test packet to the first charging unit 210 to determine an operating state of the first charging unit 210. Can be. Or the first charging unit 210, the second charging unit 220, the switching unit 230, 231, 240, 241, transmission paths 115, 117, 125, 127, gateways 110, 111, and routers ( 120 and 121) may detect the operation of each component or by receiving a packet indicating the operation state of each component periodically or aperiodically to detect the operation state of each component. However, the present disclosure is not limited to the above method, and the operation state of each component may be detected or determined by various methods. In addition, the system diagnosis unit 250 may serve to convert an operation mode of each component into an active mode or a standby mode, based on the detected operating state of each component.

When the first gateway 110 is in an inoperable state by operating state detection, the second gateway 111 may be switched to an active mode to operate in place of the first gateway 110.

As another example, when the first charging unit 210 is in an inoperative state, the first switching unit 230 switches the first charging unit 210 by bypassing the data packet transmitted to the first communication network. Without passing through it, the second charging unit 220 may be transmitted to the second communication network.

As another example, when the first transmission path 115 that is a moving path of the data packet between the first gateway 110 and the first switching unit 230 is in an inoperative state, a second transmission path that replaces the second transmission path ( The data packet may be transmitted through 116. In addition, when the third transmission path 117 that is a moving path of the data packet between the second gateway 111 and the third switching unit 231 is in an inoperative state, the fourth transmission path 118 that replaces the third transmission path 118 is disabled. Through the data packet can be transmitted.

As another example, when the first router 120 is in an inoperative state, the data is transmitted through the sixth transmission path 126 instead of the fifth transmission path 125 while switching the second router 121 to the active mode. You can send a packet. Similarly, when the second router 121 is in an inoperable state while the data packet is transmitted through the second gateway 111, the seventh transmission path 127 is switched by switching the first router 120 to the active mode. In place of), the data packet may be transmitted through the eighth transmission path 128.

Similarly, when the second charging unit 220, the second switching unit 240, the fourth switching unit 241, etc. are in an inoperative state, other components may be replaced to operate.

As described above, in one embodiment of the present invention, the service is disconnected by converting the replacement component into an active mode in case some of the components of the charging system including the charging units 210 and 220 are inoperable. The billing process can be performed without.

4 shows a flowchart of a redundant charging method according to an embodiment of the present invention. Referring to FIG. 4, first, an inoperable state of the first charging unit 210 is detected by the system diagnosis unit 250 (S400). If it is determined that the operation is disabled, the data packet is bypassed immediately by the first switching unit 230 without passing through the first charging unit 210 (S410).

The bypassed data packet is transmitted to the second charging unit 220 which is arranged in a serial duplex structure on the transmission paths 115 and 125 (S420). The transmission to the second charging unit 220 is performed by transferring the data packet to the second charging unit 220 without bypassing by switching of the second switching unit 240.

After charging the transferred data packet according to a predetermined rule, the second charging unit 220 may transmit the data packet to the service server of the second communication network through the first router 120 (S430).

As described above, in the embodiment of the present invention, even when the first charging unit 210 is inoperable, the data packet passes through the second charging unit 22 serially duplicated by the switching units 230 and 240. For example, the billing process can be performed without disconnection of service.

5 shows a flowchart of a redundant charging method according to another embodiment of the present invention. Referring to FIG. 5, first, the system diagnosis unit 250 determines whether the first gateway 110 is in an inoperable state (S500). If the first gateway 110 is in an inoperable state, the second gateway 111 is switched to the active mode to transmit the data packet through the second gateway 111 (S505).

Next, it is determined whether the first transmission path 115 is in an inoperable state (S510). If the first transmission path 115 is in an inoperable state, the data packet is transmitted through the second transmission path 116 (S515).

In operation S520, it is determined whether the first charging unit 210 is in an inoperable state. The first charging unit 210 is determined to be in an inoperable state, and the first switching unit 230 bypasses the data packet so as not to pass through the first charging unit 210 (S525). The second switching unit 240 transmits the bypassed data packet to the second charging unit 220, and the second charging unit 220 performs the charging process for the corresponding data packet according to a predetermined charging rule ( S527, S530).

On the other hand, if the first charging unit 210 is in normal operation, the charging process is performed on the data packet according to a predetermined rule (S530).

The charged data packet is transmitted to the service server of the second communication network (S540).

However, when the data packet is transmitted by the second gateway 111, the roles of the third switching unit 231 and the fourth switching unit 241 may differ depending on the inoperable state of the first charging unit 210. Can be. For example, when the first charging unit 210 is in an inoperable state, the third switching unit 231 bypasses the data packet and immediately transfers the data packet to the fourth switching unit 241 and the fourth switching unit 241. ) May transfer the data packet to the second charging unit 220 so as to perform a predetermined charging process. In contrast, when the first charging unit 210 operates normally, the third switching unit 231 transfers the data packet to the first charging unit 210 and the fourth switching unit 241 sends the data packet. Pass it and transmit it to the second router 121.

As described above, according to an embodiment of the present invention, in case that the charging unit that is arranged inline is inoperable or when some components of the charging system are inoperative, the charging component is activated or the charging unit is redundant by the switching unit. The billing process can be performed without loss while preventing service disconnection by the system.

On the other hand, the components or '~' used in this embodiment is software such as tasks, classes, subroutines, processes, objects, execution threads, programs, or FPGAs (field-) that are performed in a predetermined area on the memory. It may be implemented in hardware such as a programmable gate array or an application-specific integrated circuit (ASIC), or may be a combination of the software and hardware. The component or 'unit' may be included in a computer readable storage medium, or a part of the components may be distributed and distributed to a plurality of computers.

Although embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains have various permutations, modifications, and modifications without departing from the spirit or essential features of the present invention. It is to be understood that modifications may be made and other embodiments may be embodied. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

1 is a block diagram illustrating a WCDMA communication network according to an embodiment of the present invention.

2 is a predetermined network configuration including a charging system according to an embodiment of the present invention.

3 is a block diagram of a redundant charging system according to an embodiment of the present invention.

4 is a flowchart of a redundant charging method according to an embodiment of the present invention.

5 is a flowchart of a redundant charging method according to another embodiment of the present invention.

* Description of the main parts of the drawings *

11: calling terminal 12: called terminal

22: base station 24: base station controller

45: packet switched support node 46: packet switched gateway

200: billing system

110, 111: gateway

115, 116, 117, 118, 125, 126, 127, 128: transmission path

230, 231, 240, 241: switching unit

120, 121: Router

210, 220: billing section 250: system diagnostic section

Claims (14)

A first charging unit which receives the data packet transmitted to the first communication network and performs charging processing according to a predetermined charging rule; A second charging unit disposed in series with the first charging unit and configured to switch to an active mode and perform the charging process when the first charging unit is inoperable; A first switching unit for bypassing the data packet transmitted from the first communication network so as not to pass through the first charging unit when the first charging unit is inoperable; And When the first charging unit is inoperable, the data packet bypassed by the first switching unit is transferred to the second charging unit. When the first charging unit is normally operated, the data packet destined for the second charging unit is bypassed. Redundant charging system comprising; a second switching unit to make. delete The method of claim 1, And a system diagnosis unit configured to periodically or aperiodically detect whether the first charging unit is in an inoperable state. The method of claim 1, A first gateway providing an interface for transferring data packets transmitted from the first communication network to a second communication network; And And a first router for adjusting a transmission path of the data packet to the second communication network. The method of claim 4, wherein And a second gateway that provides an interface for delivering data packets transmitted from the first communication network to the second communication network when the first gateway is inoperable. The method of claim 4, wherein A first transmission path providing a path for transmitting the data packet between the first gateway and the first switching unit; And And a second transmission path providing a passage for transmitting the data packet between the first gateway and the first switching unit when the data packet transmission is disabled in the first transmission path. The method of claim 4, wherein And a second router configured to set a transmission path of a data packet to be transmitted to the second communication network when the first router is inoperative. The method of claim 5, A third switching unit for transferring the data packet transferred by the operation of the second gateway to the first charging unit, and bypassing the data packet directed to the first charging unit when the first charging unit is inoperable; And When the first charging unit is inoperable, the data packet bypassed by the third switching unit is transferred to the second charging unit. When the first charging unit is normally operated, the data packet destined for the second charging unit is bypassed. And a fourth switching unit to make a redundant charging system. A method for charging data packets passing through a transmission path between a first communication network and a second communication network, Detecting an inoperable state of the first charging unit; If it is determined that the first charging unit is inoperable, bypassing the data packet transmitted from the first communication network so as not to pass through the first charging unit by the first switching unit; Transmitting the bypassed data packet to a second charging unit by a second switching unit; And And transmitting the data packet to the second communication network after the charging process by the second charging unit. The method of claim 9, And bypassing, by the second switching unit, the data packet passing through the second charging unit when the first charging unit is in normal operation. The method of claim 9, And if the first charging unit is in normal operation, receiving the data packet transmitted from the first communication network and performing the charging process according to a predetermined rule. The method of claim 9, If transmission of the data packet through the first transmission path providing a path for transmitting the data packet between the first gateway and the first switching unit of the first communication network is disabled, between the first gateway and the first switching unit. And transmitting the data packet through a second transmission path which is another transmission path of the. The method of claim 9, wherein the transmitting to the second communication network If the first router is inoperable, switching the second router to an active mode to transmit the data packet. The method of claim 9, And if it is determined that the operation of the first gateway of the first communication network is disabled, switching the second gateway to an active mode and operating the second gateway.

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