KR100919219B1 - Method and apparatus for providing signaling message mapping/tracing service in wcdma circuit switched network - Google Patents

Abstract

The present invention relates to a method and apparatus for providing a signaling message mapping / tracking service in a WCDMA circuit switched (hereinafter, referred to as CS) network. The present invention relates to a Node-B, a radio network controller (RNC), and an exchange (MSC) through a WCDMA CS network. And a signal message mapping / tracking service providing method performed in a service providing apparatus coupled to additional equipment and including a probing server and a mapping server, wherein the probing server controls the Node-B and the wireless network of the WCDMA CS network. Monitoring signaling messages in a station (RNC), the radio network control station (RNC), the switch (MSC), the switch (MSC) and the supplementary equipment section, respectively; Generating a transaction detail record (TDR) for the signal message monitored by the probing server in each section; Receiving, by the mapping server, a transaction detail record (TDR) generated by the probing server and mapping the specific mapping key; And the mapping server can provide a method and apparatus for providing a signal message mapping / tracking service of the WCDMA CS network comprising the step of tracking the entire signal message using the mapped transaction details (TDR).

Description

METHOD AND APPARATUS FOR PROVIDING SIGNALING MESSAGE MAPPING / TRACING SERVICE IN WCDMA CIRCUIT SWITCHED NETWORK}

The present invention relates to a method and apparatus for providing signaling message mapping / tracking service of a WCDMA CS (Circuit Switched) network. More particularly, the present invention relates to a call unit signal message monitored in each section of a WCDMA CS network. Call) Create a transaction detail record (hereinafter referred to as TDR), map TDRs belonging to the same call generated in each section with a specific mapping key, and map TDRs mapped by call unit. The present invention relates to a method and an apparatus capable of tracking a section and a cause for performing a message procedure different from a normal call by checking a signal of a mapped section signal when a failure occurs in some sections among the entire sections monitored using the MAP.

Recently, a mobile communication service using a WCDMA scheme has been provided. Due to the development of such communication technology, users are provided with various types of mobile communication services, and users are demanding high quality communication services such as lower cost and various convenient functions.

Due to the high expectations of these users, the service provider constantly checks whether the communication service provided by the user is properly provided without any obstacles, and invests a lot of time and money to quickly overcome the failure in the event of service failure. I'm doing it.

Conventionally, when a service failure occurs only for a specific section in service provision (for example, a radio network controller (hereinafter referred to as RNC) of FIG. 1) and a switch (mobile switched center (hereinafter referred to as MSC)) section In the case of service failure in the network), the signal flow is sequentially monitored for each section between Node B and RNC, RNC and MSC, MSC and additional equipment in order to find the portion where such failure occurs, and the monitored signal message is decoded. Later, Call Flow was used to track the section where the failure occurred.

As described above, when a service is provided through a total of three sections, a section in which a service failure occurs can be traced only by passing through at least three times a process for tracking a failure section in the prior art described above. The disadvantage was that it takes a lot of time and effort.

In addition, since the entire section of the call unit can be tracked only when the data decoded by monitoring in each section is mapped to the same call unit, the conventional technique also has a disadvantage in that time and effort are required.

The present invention has been made to overcome the above-mentioned problems. In the case where a call service failure occurs in a WCDMA CS network, an entire call without having to check whether a call unit signaling message is disturbed for each section is required. It is an object of the present invention to provide a method and apparatus for providing a signaling message mapping / tracking service of a WCDMA CS network capable of simultaneously checking a unit signal message and tracking a failure section.

In addition, the present invention generates a call unit TDR for each section in which a signaling message is transmitted, and uses the same call start / end time and a specific mapping key of a call included in each TDR. (Call) Mapping / tracking process is performed only for unit TDR, and even if multiple callers / recipients call simultaneously during the same time period, the purpose is to provide signaling message mapping / tracking service for a call between a specific caller and a called party. It is done.

In addition, the present invention can easily track the failure interval using the signal flow for the entire signaling message using the mapped call unit TDR bar, the signal that can efficiently manage the mobile communication network from the service provider's point of view It aims to provide a message mapping / tracking service.

In order to achieve the above object, according to an aspect of the present invention, the interval between the Node-B and the radio network control station (RNC), the radio network control station (RNC) and the switch (MSC) of the WCDMA CS network A signal message mapping / tracking service providing method performed by a service providing apparatus including a mapping server coupled to a probing server and a probing server connected to a section of an MSC and an additional device, wherein the probing server includes the WCDMA. Monitoring signaling messages in the Node-B and the Radio Network Control Station (RNC), the Radio Network Control Station (RNC), the Switchboard (MSC), the Switchboard (MSC), and the Supplementary Equipment section of the CS network, respectively; And generating a call unit transaction detail record (TDR) for the signal message monitored by the probing server in each section, and by the mapping server, a call unit transaction generated by the probing server. Receiving and mapping a session detail record (TDR) to a specific mapping key; and tracking, by the mapping server, an entire call unit signal message using a mapped call unit transaction detail record (TDR). A signal message mapping / tracking service providing method of a WCDMA CS network may be provided.

Herein, the call unit transaction detail record (TDR) includes a call start / end time, an international mobile station identification number / temporary mobile subscriber identification number / mobile station international ISDN number ( IMSI / TMSI / MSISDN) and protocol messages of each monitoring interval. The generating of the call unit transaction detail record (TDR) for the signal message monitored by the probing server in each section may include extracting a predetermined extraction value from the signal message monitored by the probing server in each section. And determining a tracking value from the extracted value and determining whether it matches the extracted value of the signal message transmitted to the next step, wherein the extracted value from the trace value and the signal message transmitted to the next step is determined. If it matches, it can be configured to determine that the message belongs to the same call. The additional equipment may be any one of a home location register (HLR) / authentication station (AuC), a message service center (MSC) or a short message service center (SMSC). The mapping server may receive a call detail transaction detail record (TDR) generated by the probing server and map it to a specific mapping key in a call detail transaction detail record (TDR) of each section. Determining whether the call unit transaction detail record (TDR) of each section belonging to the same call is checked by checking the call start / end time of the included call; and as a result of the determination, the call belongs to the same call. And mapping the call unit transaction detail record (TDR) of each section by using a specific mapping key included in each call unit transaction detail record (TDR). In addition, the call unit transaction details of each section belonging to the same call by checking the call start / end time of the call included in the call unit transaction detail record (TDR) of each section. Determining whether or not it is a recording (TDR), the call start / end time (Call Start / End Time) of the call between the switch (MSC) and the additional equipment interval is the radio network control station (RNC) and the switch (MSC) The call start / end time of the call of the interval is included, and the call start / end time of the call of the RNC and the MSC interval is the Node-. When it is included in the call start / end time of the call between the B and the RNC, it may be configured to determine a transaction detail record (TDR) belonging to the same call. In addition, the mapping server tracks the entire call signal unit signal message using the mapped call unit transaction detail record (TDR), the mapped transaction detail record of each section belonging to the same call ( The signal flow may be analyzed using TDR to determine a section that does not exist among the signal messages constituting the Transaction Detail Record (TDR) as a failure section.

According to another aspect of the present invention, in the service providing apparatus for providing a signal message mapping / tracking service connected to a Node-B, a radio network control station (RNC), an exchange (MSC) and additional equipment through a WCDMA CS network, Signaling messages are monitored in the Node-B, the radio network control station (RNC), the radio network control station (RNC), the switchboard (MSC), the switchboard (MSC), and the additional equipment section, respectively, and in each section. Receives a probing server generating a call detail transaction detail record (TDR) and a transaction detail record (TDR) generated by the probing server and maps it to a specific mapping key, and maps the mapped transaction detail record ( A signal message mapping / tracking service providing apparatus of a WCDMA CS network including a mapping server that tracks a signal message of an entire period using a TDR) may be provided.

According to the present invention, when a call service failure occurs in a WCDMA CS network, by simultaneously checking the entire call signal signal without checking whether the call signal signal has failed in each section, It is possible to provide a method and apparatus for providing signaling message mapping / tracking service of a WCDMA CS network capable of quickly and efficiently tracking a fault section and solving it.

According to the present invention, a call unit TDR is generated for each section in which a signal message is transmitted, and a call start / end time and a specific mapping key of a call included in each TDR are generated. By performing the mapping / tracking process only for the same call unit TDR, it is possible to provide signaling message mapping / tracking service precisely for a call between a specific caller and a called party even when multiple callers / recipients simultaneously call during the same time. Can be.

In addition, according to the present invention, it is possible to easily track the failure interval by using the signal flow for the entire signaling message using the mapped call unit TDR, so that the mobile communication network can be efficiently managed from the service provider's point of view. Provide signal message mapping / tracking services.

1 is a diagram showing a configuration for providing a signaling message mapping / tracking service of a WCDMA CS network according to the present invention;

FIG. 2 is a diagram illustrating a procedure for providing a signal message mapping / tracking service provided by the configuration as shown in FIG. 1.

3 is a diagram illustrating a protocol stack between a Node-B and an RNC section of FIG. 1;

4 is a diagram illustrating a message transmitted through the protocol stack of FIG. 3, extracted values extracted from the same, and a tracking value;

5 is a diagram illustrating a flow of a signal message actually transmitted through the protocol stack of FIG. 3.

6 is a diagram illustrating a protocol stack between an RNC and an MSC section of FIG. 1;

FIG. 7 is a diagram illustrating a message transmitted through the protocol stack of FIG. 6, an extracted value extracted from the same, and a tracking value.

8 is a diagram illustrating a protocol stack of an HLR interval that is an MSC and an additional device of FIG. 1;

FIG. 9 is a diagram illustrating a message transmitted through the protocol stack of FIG. 8, an extracted value extracted from the same, and a tracking value.

FIG. 10 is a view for explaining a method of mapping a call unit TDR and a TDR generated in the configuration shown in FIG. 1; FIG.

FIG. 11 is a flowchart of an entire signaling message generated to explain a method of tracking a signaling message using the TDR of FIG. 10.

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

1 is a diagram illustrating a configuration for providing a signaling message mapping / tracking service of a WCDMA CS network according to the present invention.

Referring to FIG. 1, a signal message mapping / tracking service providing apparatus 100 of a WCDMA CS network according to the present invention includes a probing server 10 and a mapping server 20. Here, the probing server 10 is a section between a Node-B 30 and a radio network controller (hereinafter referred to as RNC) 40, a section between the RNC 40 and a mobile switched center (hereinafter referred to as MSC) 50. And connected to the interval between the MSC (50) and the additional equipment (60 to 80), monitor the signal message through the monitoring card, and analyze the protocol of each section through the protocol decoder to call for the signal message monitored in each section (Call) Creates a unit TDR. The probing server 10 is present in the section between the Node-B 30 and the RNC 40, the RNC 40 and the MSC 50, and the MSC 50 and the additional equipment 60 to 80, respectively.

The mapping server 20 is combined with the probing server 10, receives a call unit TDR from the probing server, maps the TDR using a specific mapping key included in the TDR, and maps the unit to the mapped call. The TDR is used to analyze the signal flow of the call signal of the entire section call and track the specific section when a failure occurs in the specific section.

Meanwhile, a predetermined point between the Node-B 30 and the RNC 40, the RNC 40 and the MSC 50, and the MSC 50 and the additional equipment is connected to the probing server 10, and at this point, the probing server Will monitor the signaling message. Here, the additional equipment may be a Home Location Register (hereinafter referred to as HLR 60) / Authentication Center (hereinafter referred to as AuC), a Message Service Center (hereinafter referred to as MSC, 70) or a short message. It may be any one of a Short Message Service Center (hereinafter referred to as SMSC).

FIG. 2 is a diagram illustrating a procedure for providing a signal message mapping / tracking service provided by the configuration as shown in FIG. 1.

Referring to FIG. 2, in the signaling message mapping / tracking service providing procedure, a probing server 10 may add a Node-B 30, an RNC 40, an RNC 40, an MSC 50, and an MSC 50. The signal message is monitored in each section between the equipment (S201), and a call unit TDR is generated for the signal message of each monitored section (S203). These call unit TDRs include Call Start / End Time, International Mobile Station Identification Number / Temporary Mobile Subscriber Identification Number / Mobile International ISDN Number (IMSI / TMSI / MSISDN), and each monitoring in each segment. A protocol message of a section is included, which will be described later with reference to FIG. 10.

Meanwhile, the call unit TDR of each section generated by the probing server 10 is mapped by the mapping server 20 using a specific mapping key included in each call unit TDR (S205). The entire call unit signal message is tracked using the called call unit TDR (S207). Here, the tracking of the call signal of the entire section call analyzes the signal flow for the entire signal message by using the call unit TDR and traces the message of the section that does not exist in such a signal flow, It can be done by judging. Through this procedure, when a failure occurs in a specific section of the entire signaling message, the failure section can be tracked by analyzing call unit TDR, and efficient mobile communication network can be managed.

FIG. 3 is a diagram illustrating a protocol stack between a Node-B 30 and an RNC 40 in FIG. 1, and FIG. 4 is a diagram illustrating a message transmitted through the protocol stack of FIG. 3, an extracted value, and a tracking value extracted therefrom. Drawing.

3 to 4, FIG. 3 illustrates a protocol stack between a Node-B 30 and an RNC 40, and a signal flow in a Node-B 30 and an RNC 40 of FIG. 4. This is done through the protocol stack of FIG. 3, and a detailed description of the protocol stack will be omitted.

4 is a diagram illustrating a message and an extraction value / tracking value transmitted between an actual Node-B 30 and an RNC 40 through the protocol stack of FIG. 3. In FIG. 4, an RRC Connection Request message is transmitted from the Node-B 30 to the RNC 40 through a Radio Resource Control (hereinafter referred to as RRC) protocol, and from this message, an international mobile station identification number / temporary mobile subscriber identification number / The mobile station international ISDN number (hereinafter referred to as IMSI / TMSI) and the Scramble Code are extracted and used as extraction values (S401). Here, the Scramble Code serves as an identifier connecting the RRC protocol message and the NBAP protocol message.

Meanwhile, Radio Link Setup Request message is transmitted from RNC to Node-B through Node-B Application Protocol (hereinafter referred to as NBAP), and from these messages, Transaction ID, CRNC Communication Context ID, Node-B Communication Context ID, Uplink The scrambling code and the downlink channelization code are extracted as extraction values (S403). Here, Transaction ID serves to identify a call unit transaction of NBAP protocol message, and CRNC Communication Context ID and Node-B Communication Context ID each identify the same call, Uplink Scrambling Code and Downlink Channelization Code acts as an identifier connecting Dedicated Channel.

If the scramble code extracted in step 401 and the scramble code included in the radio link setup request message match in step 403, the two messages may be determined to belong to the same call. It determines the message belonging to the same call.

The RNC transmits a Radio Link Setup Response message to the Node-B, and extracts a Binding ID from the RNC (S405). Here, the Binding ID is an identifier connecting the NBAP protocol and the ALCAP protocol. In step 405, as described in step 403, the transaction ID may be used as a tracking value to determine that the message belongs to the same call as the Radio Link Setup Request message.

Meanwhile, an Establish Request (hereinafter referred to as ERQ) message is transmitted from the RNC to Node-B through the Access Link Control Application Part (hereinafter referred to as ALCAP) protocol, and from this message, a Virtual Path Identifier (hereinafter referred to as VPI) / A Virtual Channel Identifier (hereinafter referred to as VCI) / Connection Identifier (hereinafter referred to as CID) is extracted as an extraction value (S407). Here, the Binding ID of the Radio Link Setup Response and the Served User Generated Reference (hereinafter, referred to as SUGR) of the ERQ are identically connected, thereby connecting the NBAP protocol and the ALCAP protocol.

Then, the RRC Connection Setup message is transmitted from the RNC to the Node-B through the RRC protocol, and the Scramble Code and IMSI / TMSI are extracted from the RNC, and the IMSI / TMSI extracted in step 401 and the IMSI / TMSI extracted in step 409 are extracted. By comparison, it is also possible to determine whether the message belongs to the same call.

As described with reference to FIG. 4, the process of extracting the extracted value and the trace value from the message transmitted through the protocol in each section and confirming that the message belongs to the same call using these values is actually a point in time in each section. Since signals are transmitted by multiple users in, it is important to generate a TDR by dividing a signal message of a specific sender and a called party.

5 is a diagram illustrating a flow of a signal message actually transmitted through the protocol stack of FIG. 3.

As shown in FIG. 5, in the process of transmitting a signal message in an actual section, more messages are transmitted than in FIG. 4. However, in order to generate a TDR in each section, the present invention transmits a signal message to the same call. Since only necessary values are extracted in order to determine that the message belongs, only the meaningful messages are referred to as shown in FIG. 4.

FIG. 6 is a diagram illustrating a protocol stack between the RNC 40 and the MSC 50 in FIG. 1, and FIG. 7 is a diagram illustrating a message transmitted through the protocol stack of FIG. 6, an extracted value, and a tracking value extracted therefrom.

The process of determining the message belonging to the same signal by extracting the extracted value / trace value of FIGS. 6 to 7 is the same as the process described with reference to FIGS. 6 to 7, a Connection Request / Confirm message is transmitted through a signaling connection control part (hereinafter referred to as SCCP) protocol, and such SCCP connection is maintained until the signal is terminated in the RNC and MSC intervals. It is responsible for monitoring all upper protocol messages transmitted through the connection. Therefore, the Source Location Reference / Destination Location Reference (hereinafter referred to as SLR / DLR) extracted from the Connection Request / Confirm message becomes an extract value and traces to extract RANAP protocol messages exchanged between the RNC and the MSC through the SCCP Connection. The value is used (S701, S703).

FIG. 8 is a diagram illustrating a protocol stack between an MSC 50 of FIG. 1 and an HLR 60, which is an additional device. FIG. 9 is a diagram illustrating a message transmitted through the protocol stack of FIG. 8, an extracted value, and a tracking value extracted therefrom. Drawing.

8 to 9, the process of using extraction values / tracking values to determine that the messages belonging to the same signal are also the same as those of FIGS. 3 to 4, and thus only the characteristic parts will be described. Let's do it.

The MSC (50) and the HLR (60) section is also the Subsystem Number (hereinafter referred to as SSN) / Originating Point Code (hereinafter referred to as OPC) / Destination Point Code (hereinafter referred to as DPC) Extracting the Global Title (hereinafter, referred to as GT) extracts the extracted value, and this extracted value serves as an identifier for using the HLR 60 to which a corresponding signal is transmitted among a plurality of HLRs (S801 and S803).

On the other hand, since the MSC 50 and the HLR 60 are related to a specific call by starting and ending the dialog of the TCAP protocol, Originating Transaction ID (hereinafter referred to as OTI) / Destination Transaction ID (hereinafter referred to as DTI) ) Is an extracted value and used as a tracking value (S805 and S807).

Here, the MSC 50 and the HLR 60 perform a call-related procedure with the MAP protocol, which is a TCAP user part. These mobile application part (hereinafter referred to as MAP) protocol messages are managed by a dialog of TCAP, and TCAP related messages include BEGIN, END, CONTINUE, and ABORT of the transaction part, and INVOKE, RETURN-RESULT, and RETURN- of the component part. ERROR, etc. The MAP message is transmitted by payload of the component part message of the TCAP, and the dialog is terminated when the call unit transaction ends. Accordingly, the TCAP is generated by tracking the TCAP message with the OTI and DTI of the TCAP to extract the MAP message.

FIG. 10 is a diagram for describing a method of mapping call units TDR and TDR generated in the configuration shown in FIG. 1.

Referring to FIG. 10, the probing server 10 may be configured in the section between the Node-B 30 and the RNC 40, the RNC 40 and the MSC 50, and the MSC 50 and the additional equipment 60 to 80. Through the described process, a call unit TDR included in a message transmitted in each section is generated.

The call unit TDR includes the following information. First, the call unit TDR between the Node-B 30 and the RNC 40 includes a call start / end time, an international mobile station identification number, and a temporary mobile subscriber identification number (IMSI / TMSI). And NBAP / RRC / ALCAP / NAS protocol messages.

Call unit TDR between the RNC 40 and the MSC 50 includes Call Start / End Time, International Mobile Station Identification Number / Temporary Mobile Subscriber Identification Number / Mobile International ISDN Number (IMSI / TMSI). / MSISDN) and RANAP / ALCAP / NAS protocol messages.

The call unit TDR between the MSC (50) and the HLR (60) section contains the call start / end time, the international mobile station identification number / mobile station international ISDN number (IMSI / MSISDN), and the MAP protocol message. Included.

Referring to the method of mapping call unit TDRs generated in each section, the same call is confirmed by checking the call start / end time of the call included in the call unit TDR of each section. It is determined whether the TDR of each section belongs to, and as a result of the determination, it is mapped to a call unit TDR of each section belonging to the same call using a specific mapping key included in each TDR.

Here, the step of determining whether the call unit TDR of each section belonging to the same call by checking the call start / end time of the call included in the TDR of each section is MSC 50. Call Start / End Time of the call of the interval between the HLR 60 and the HLR 60 is included in the Call Start / End Time of the call of the interval between the RNC 40 and the MSC 50, and the RNC 40 Call start / end time of the call between the MSC (50) section and the call start / end time of the call between the Node-B (30) and the RNC 40 section (Call Start / End Time) It can be determined as a TDR belonging to the same call. This is because the signal message is transmitted in the direction of the NSC 50 and the HLR 60 in the Node-B 30 and the RNC 40 section, and then returns to the Node-B 30 and the RNC 40 section again. The start / end time of the signal message between the Node-B 30 and the RNC 40 is the RNC 40 and the MSC 50 and the MSC 50 and the HLR 60. Call Start / End Time (Call Start / End Time) of the signal message.

Meanwhile, the call unit TDR of each section includes a specific mapping key for mapping the TDR. That is, IMSI / TMSI is included in the TDR of the Node-B 30 and the RNC 40 section, and IMSI / TMSI / MSISDN is included in the TDR of the RNC 40 and the MSC 50 section. In the TDR, IMSI is used as a mapping key.

FIG. 11 is a flowchart of an entire signaling message generated to explain a method of tracking a signaling message using the TDR of FIG. 10.

Referring to FIG. 11, in order to track a section in which a failure occurs when a call failure occurs while a call is made between a caller and a called party after the call unit TDR is generated and mapped with a mapping key in each section by the above process. The TDR can be used to construct a signal flow diagram.

That is, when a call occurs between the caller and the receiver in the MSC 50 and the HLR 60, when a failure occurs, a signal flow chart is created using the mapped call unit TDR belonging to the same call, and the TDR is analyzed. A failure section may be tracked by determining a section corresponding to a signal message that does not exist among the signal messages to be configured as a failure section. For example, if the signal flow is analyzed using the mapped TDR when a failure occurs during the call in the MSC 50 and the HLR 60, the MAP message is not expressed in the MSC 50 and the HLR 60. Will not. In addition, when the RANAP message is not represented in the signal flow chart between the MSC 50 and the RNC 40, it may be determined that a communication failure has occurred in this section. By generating a call unit TDR in each section for the same signal and analyzing the signal flow after mapping, it will be possible to efficiently track communication failures in a particular section.

Although the preferred embodiments of the present invention have been described above with reference to the accompanying drawings, the present invention is not limited to the above embodiments. It will be apparent to those skilled in the art that variations, modifications, and improvements can be made.

Claims (8)

The interval between the Node-B and the Radio Network Control Station (RNC), the interval between the Radio Network Control Station (RNC) and the Exchange (MSC) and the Exchange (MSC) and Home Location Register / Authorization Station, the Message Service Center, A signal message mapping / tracking service providing method performed by a service providing apparatus including a probing server connected to a section of an additional device, which is one of a short message service center, and a mapping server coupled to the probing server, The probing server signals the Node-B of the WCDMA CS network and the radio network control station (RNC), the radio network control station (RNC), the switch (MSC), the switch (MSC), and the additional equipment section. Monitoring each message; Generating a call unit transaction detail record (TDR) for the signaling message monitored by the probing server in each section; Receiving, by the mapping server, a call unit transaction detail record (TDR) generated by the probing server and mapping the call unit to a mapping key of each call unit; And Tracking, by the mapping server, an entire call signal unit message using a mapped call unit transaction detail record (TDR) Including; The probing server may generate a call unit transaction detail record (TDR) for the signal message monitored in each section. Extracting, by the probing server, an extraction value according to a protocol and a signal message for each section from the signal message monitored in each section; And determining a tracking value from the extracted value and determining whether it matches the extracted value of the signal message transmitted to the next step, wherein the tracking value is identical to the extracted value in the signal message transmitted to the next step. Method for providing a signaling message mapping / tracking service of the WCDMA CS network, characterized in that the case is determined to be a message belonging to the same call. The method of claim 1, The call unit transaction detail record (TDR), Call start / end time of each call, international mobile station identification number / temporary mobile subscriber identification number / mobile station international ISDN number (IMSI / TMSI / MSISDN), and protocol message of each monitoring section Signaling message mapping / tracking service providing method of WCDMA CS network. delete delete The method of claim 1, The mapping server may receive a call detail transaction (TDR) generated by the probing server and map it to a mapping key for each call unit. Call detail transaction record of each section belonging to the same call by checking call start / end time of the call included in the call detail transaction detail record (TDR) of each section ( TDR), and each call unit included in each call unit transaction detail record (TDR) for each call unit transaction detail record (TDR) of each section belonging to the same call. A signal mapping / tracking service providing method of a WCDMA CS network, characterized by mapping using a mapping key. The method of claim 5, Call detail transaction record of each section belonging to the same call by checking call start / end time of the call included in the call detail transaction detail record (TDR) of each section ( Determining whether or not the call start / end time of the call between the MSC and the additional equipment section is the call of the RNC and the MSC section. A call start / end time is included in a call start / end time, and a call start / end time of a call between the radio network controller (RNC) and the switch (MSC) section is determined by the node-B and the call. Signal mapping of a WCDMA CS network, which is determined as a transaction detail record (TDR) belonging to the same call when it is included in a call start / end time of a call in a radio network controller (RNC) section. How to provide tracking service. The method of claim 1, The mapping server tracking the entire call signal unit signal message using the mapped call unit transaction detail record (TDR), WCDMA, characterized in that a non-existent section is determined as a failure section among the signal messages constituting the transaction detail record (TDR) by analyzing the signal flow using the mapped transaction detail record (TDR) of each section belonging to the same call. Signal mapping / tracking service provision method of CS network. Signal message mapping / tracking through WCDMA CS network connected to Node-B, Radio Network Control Station (RNC), Switchboard (MSC), and supplementary equipment, which is any one of Home Locator / Authenticator, Message Service Center, and Short Message Center. In the service providing apparatus for providing a service, Signaling messages are monitored in the Node-B, the radio network control station (RNC), the radio network control station (RNC), the switchboard (MSC), the switchboard (MSC), and the additional equipment section, respectively, and in each section. A probing server generating a call unit transaction detail record (TDR) for the monitored signaling message; And Receives call detail transaction detail record (TDR) generated by the probing server, maps it to mapping key of each call unit, and traces the signal message of the entire section using the mapped transaction detail record (TDR) Mapping server Including but not limited to: The probing server extracts an extraction value according to a protocol and a signal message for each section from the signal message monitored in each section, determines a tracking value from the extraction value, and matches whether it is identical to the extraction value of the signal message transmitted to the next step. And determining that the message belongs to the same call when the tracking value and the extracted value of the signal message transmitted to the next step are identical to each other.