KR102356620B1 - Method and system for monitoring traffic in 5G core network - Google Patents

Abstract

A method and apparatus for monitoring traffic in a 5G core network are provided. The method includes: receiving a signal message; and visualizing at least one of a terminal connection state, a session connection state, a flow connection state, an application switching flow state, and an application splitting flow state by using the header information of the received signal message.

Description

Traffic monitoring method and system in 5G core network {Method and system for monitoring traffic in 5G core network}

The present invention relates to a traffic monitoring method, and more particularly, to a traffic monitoring method and system in a 5G core network.

The 5G system is largely divided into a non-standalone (NSA) system and a standalone SA (standalone) system. Since the NSA 5G system uses 5G radio between a user equipment (UE) and a base station (BS), while the core network is a system that uses a 4G core network, it is not a perfect 5G system. The SA 5G system uses 5G radio between the user terminal and the base station, and the core network also uses the 5G core network, so it is a true 5G system.

In the 5G core network of the SA 5G system, when using wired, 5G, and WiFi wireless BS interfaces convergence, a switching method for transferring traffic from one wireless BS interface to another wireless or wired BS interface, not one interface, but two Traffic is delivered to the user terminal in various ways, such as a splitting method for delivering traffic to the BS interfaces.

However, there is no way for an operator of a 5G system to determine whether various traffic delivery methods such as a switching method and a splitting method are being performed normally. Therefore, there is a need for a 5G core network traffic monitoring system capable of monitoring traffic so that an operator can easily determine whether various traffic delivery methods are being performed normally.

An object of the present invention is to provide a method and system capable of visually monitoring traffic in a 5G core network.

In addition, an object of the present invention is to provide a method and system capable of immediately verifying a received signal message sequence and 5G core network traffic processing.

A method according to an aspect of the present invention is a traffic monitoring method in a core network of a 5G mobile communication system, the method comprising: receiving a signal message; and visualizing at least one of a terminal connection state, a session connection state, a flow connection state, an application switching flow state, and an application splitting flow state by using the header information of the received signal message.

According to an embodiment of the present invention, it is possible to provide the following effects.

First, in the 5G system, which is a wireless and wired convergence system, switching to transfer traffic from one wireless BS interface to another wireless or wired BS interface from 5G core network functions constituting the 5G core network, and one BS interface However, since a traffic delivery method such as splitting that delivers traffic to two BS interfaces is provided, by visualizing signal message processing, session establishment, and traffic flow processing, operators can visually monitor traffic easily. It can provide a new visual operator management environment that can track whether an incoming signal message is normal or abnormal.

Second, if there is not only 5G network shape information but also 6G or new future network shape information, it is possible to provide a visual network traffic monitoring system that can be easily applied to 6G and future networks.

1 is a diagram showing the structure of a 5G mobile communication system according to an embodiment of the present invention.
2 is a diagram illustrating a network shape structure for traffic monitoring according to an embodiment of the present invention.
3 is an exemplary diagram illustrating a visualization of a terminal access state according to an embodiment of the present invention.
4 is an exemplary diagram illustrating a visualization of a session connection state according to an embodiment of the present invention.
5 is an exemplary diagram illustrating a visualization of a flow connection state according to an embodiment of the present invention.
6 is an exemplary diagram illustrating a visualization of a signal message according to an embodiment of the present invention.
7 is an exemplary diagram illustrating a visualization of a switching traffic delivery method according to an embodiment of the present invention.
8 is an exemplary diagram illustrating a visualization of a splitting delivery method according to an embodiment of the present invention.
9 is a diagram showing the structure of a traffic monitoring system according to an embodiment of the present invention.
10 to 12 are flowcharts of a traffic monitoring method according to an embodiment of the present invention.
13 is a structural diagram of a traffic monitoring system according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. However, the present invention may be implemented in several different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part "includes" a certain element, it means that other elements may be further included, rather than excluding other elements, unless otherwise stated.

In this specification, expressions described in the singular may be construed in the singular or plural unless an explicit expression such as “a” or “single” is used.

Throughout the specification, a terminal is a user equipment (UE), a mobile station (MS), a mobile terminal (MT), an advanced mobile station (AMS), a high reliability mobile station (high reliability mobile station, HR-MS), subscriber station (subscriber station, SS), portable subscriber station (PSS), access terminal (AT), machine type communication device (machine type communication device, MTC device) and the like, and may include all or some functions of UE, MS, MT, AMS, HR-MS, SS, PSS, AT, and the like.

In addition, the base station (base station, BS) is a node B (node B), an advanced node B (evolved node B, eNB), gNB, an advanced base station (ABS), a high reliability base station (high reliability base station, HR-BS), access point (AP), radio access station (RAS), base transceiver station (BTS), MMR (mobile multihop relay)-BS, a repeater serving as a base station (relay station, RS), a relay node serving as a base station (relay node, RN), an advanced relay station serving as a base station, and a high reliability relay station serving as a base station , HR-RS), small base station [femto base station (femto BS), home node B (home node B, HNB), home eNodeB (HeNB), pico base station (pico BS), macro base station (macro BS), micro base station ( micro BS), etc.], and all or part of the functions of NB, eNB, gNB, ABS, AP, RAS, BTS, MMR-BS, RS, RN, ARS, HR-RS, small base station, etc. may include

Hereinafter, a traffic monitoring method and system according to an embodiment of the present invention will be described with reference to the drawings.

According to a preferred embodiment of the present invention, the present invention provides switching for transferring traffic from one wireless BS interface to another wireless or wired BS interface from 5G core network functions constituting the 5G core network, and two BSs instead of one BS interface. Receive common traffic monitoring transmission messages from each 5G core network function so that the operator can understand the traffic method such as splitting that delivers traffic to the interface, processing the signal messages necessary for switching and splitting, and setting up sessions and allowing the operator to visually express the traffic flow processing process to enable traffic monitoring, and to verify whether the signal message sequence and 5G core network traffic processing are operating normally using the signal message included in the received traffic monitoring transmission message It is characterized by being composed of a 5G core network traffic monitoring system including a signal message sequence diagram that can be

1 is a diagram showing the structure of a mobile communication system according to an embodiment of the present invention.

1, the 5G-based mobile communication system according to an embodiment of the present invention is based on a next-generation mobile communication network, and functions, connection points, and protocols are defined for each network function rather than an entity. made up of a structured It has a structure that minimizes the dependence of AN (Access Network) and CN (Core Network), and CP (Control Plane) and UP (User Plane) of CN can be divided by function.

A radio access network (RAN) represents a base station using a new radio access technology (RAT), and an access network (AN) represents a general base station including a non-3GPP access technology such as Wi-Fi.

UPF (User Plane Function) is the unification of S-GW (serving-gateway) and P-GW (Packet Data Network-gateway).

AMF (Access and Mobility Management Function) is in charge of access and mobility management in units of terminals, and SMF (Session Management Function) is in charge of a session management function. AMF and SMF are considered to be largely modularized by function, such as CM (Connection Management), RM (Registration Management), MM (Mobility Management), and SM (Session Management) functions, the functions of the existing MME (Mobility Management Entity). can

UDM (Unified Data Management) stores the user's subscription data (subscription data), policy data, etc., corresponds to the expansion of the existing HSS (Home Subscriber Server). AUSF (Authentication Server Function) is an authentication server that stores data for authentication of a terminal.

AF (Application Function) provides information on packet flow to a Policy Control Function (PCF) in charge of policy control in order to correct QoS (Quality of Service). The PCF determines policies such as session management and mobility management and delivers them to AMF, SMF, etc., so that appropriate mobility management, session management, QoS management, etc. can be performed. A data network (DN) transmits a protocol data unit (PDU) to be transmitted in the downlink direction to the UPF or receives a PDU sent by a user equipment (UE) through the UPF.

Meanwhile, N1 corresponds to the NAS (Non Access Stratum) interface of the existing mobile communication system (eg, long term evolution (LTE)), N4 is the interface between the CP function and the UP function, and the N2 interface is to the S1AP of the existing LTE. Corresponding, it can be seen that the N3 interface corresponds to S1-U.

The 5G-based mobile communication system according to an embodiment of the present invention having such a structure can be visualized as a network shape structure for traffic monitoring.

2 is a diagram illustrating a network shape structure for traffic monitoring according to an embodiment of the present invention.

The 5G-based mobile communication system shown in FIG. 1 , that is, a network shape structure similar to the 5G network reference model can be visualized as in FIG. shows

First, the main visualization elements for indicating the 5G network status and signal messages related to these visualization elements will be described.

The 5G core network traffic monitoring system (referred to as a traffic monitoring system for convenience of description) according to an embodiment of the present invention basically monitors all signal messages on the 5G network and displays the collected signal messages through graphics. visualize on the

The signal message includes header information required for visualization by the traffic monitoring system and payload information, which is a body including message content exchanged between functions of 5G CN. The header information includes the 5G core network function identifier of the sending side, the 5G core network function identifier of the receiving side, the message category corresponding to the message number between the 5G core network function of the sending side and the 5G core network function of the receiving side, the 5G core network function of the sending side and the receiving side. It includes a message type and a session identifier corresponding to the message name transferred between 5G core network functions.

The visualization element includes a terminal (UE) connection state, a session connection state, a flow connection state, and a signal message.

The terminal connection state visualization element is to visualize a state in which a terminal (UE) is connected to a base station (BS). The visualization of the terminal connection state visualizes the state in which the UE is connected to a specific BS when the traffic monitoring system receives the terminal registration complete message, which is the point at which the registration procedure of the UE is completed.

3 is an exemplary diagram illustrating a visualization of a terminal access state according to an embodiment of the present invention.

3, the UE can be connected to a specific BS, for example, a 5G-based BS, a WiFi-based BS, a fixed BS, etc., and the operator can recognize the connection state of the UE to a specific BS Visualize it so that For example, the connection state may be visualized through a line between the UE and a specific connected BS, and a color indicating the connection state may be displayed differently for each BS.

On the other hand, the session connection state visualization element visualizes the session connection state between the UE and the gateway (GW) corresponding to the aforementioned UPF. A session indicates a connection state between UE, BS, and GW. The session visualization visualizes the session connection state between the UE, the BS, and the GW when the traffic monitoring system receives a session connection completion message, which is the point at which the session connection procedure is completed.

4 is an exemplary diagram illustrating a visualization of a session connection state according to an embodiment of the present invention.

As illustrated in the attached FIG. 4 , when a session is formed between a UE, a BS, and a GW, the session connection state is visualized so that an operator can recognize it. For example, the session connection state can be visualized through a line connecting the UE, BS, and GW where the session is formed, and the color of the line can be displayed differently for each session.

On the other hand, the flow connection state visualization element visualizes the application connection state used by the UE. The flow indicates the connection state between the UE, BS, GW, and the application server (APP). The visualization of the flow connection state visualizes the flow connection state between the UE, BS, GW, and the application server (APP) when the traffic monitoring system receives the application connection completion message transmitted from the UE.

5 is an exemplary diagram illustrating a visualization of a flow connection state according to an embodiment of the present invention.

As illustrated in the attached FIG. 5 , when a flow is formed between a UE, a BS, a GW, and an application server (APP), the flow connection state is visualized so that the operator can recognize it. For example, the flow connection state can be visualized through a line connecting the UE, BS, GW, and application server (APP) where the flow is formed, and the color of the line can be displayed differently for each flow.

On the other hand, the visualization element of the signal message is that the traffic monitoring system receives and visualizes all signal messages on the 5G network.

6 is an exemplary diagram illustrating a visualization of a signal message according to an embodiment of the present invention.

As illustrated in the accompanying FIG. 6 , the traffic monitoring system according to an embodiment of the present invention converts a signal message received on a 5G network topology structure (see FIG. 2 ) into a signal message sequence diagram as illustrated in FIG. 6 . can be displayed

The signal message from the 5G core function of the sender to the 5G core function of the receiver may be indicated by using the 5G core function identifier of the sender, the 5G core function identifier of the receiver, and the message type in the header information of the signal message.

As described above, through the visualization of the terminal (UE) connection state, session connection state, and flow connection state, a switching traffic delivery method for delivering traffic from one wireless BS interface to another wireless or wired BS interface can be visualized. have.

7 is an exemplary diagram illustrating a visualization of a switching traffic delivery method according to an embodiment of the present invention.

As shown in the attached Figure 7, through the visualization of the terminal (UE) connection state, session connection state, and flow connection state, it is possible to visualize in the 5G network shape structure that traffic is transferred by switching from the existing 5G interface to the WiFi interface. .

In addition, through visualization of the UE connection state, the session connection state, and the flow connection state, a split delivery method of delivering traffic to two BS interfaces instead of one BS interface may be visualized.

8 is an exemplary diagram illustrating a visualization of a splitting delivery method according to an embodiment of the present invention.

As shown in the attached FIG. 8, through the visualization of the terminal (UE) connection state, session connection state, and flow connection state, it is possible to visualize in the 5G network shape structure that traffic is simultaneously transmitted to the fixed interface as well as the existing 5G interface. have.

9 is a diagram showing the structure of a traffic monitoring system according to an embodiment of the present invention.

9, the traffic monitoring system 1 according to an embodiment of the present invention includes a signal message reception processing unit 10, a signal message processing unit 20, a traffic visualization processing unit 30, and a signal sequence. It includes a fabrication processing unit 40 , and a network shape information storage 50 .

The signal message reception processing unit 10 is configured to perform a 5G core network function, a function of receiving a signal message transmitted from the BS and the UE to the traffic monitoring system 1 . The signal message includes header information and payload information including message content exchanged between 5G core functions. The header information includes the 5G core network function identifier of the sending side, the 5G core network function identifier of the receiving side, the message category corresponding to the message number between the 5G core network function of the sending side and the 5G core network function of the receiving side, the 5G core network function of the sending side and the receiving side. It includes a message type corresponding to the message name transferred between 5G core network functions, and a session identifier. Here, the message category corresponds to a message number in the 5G network reference model (see FIG. 1), and may be, for example, N1, N2, N4, or the like. The message type corresponds to a message corresponding to the message number of the 5G network reference model (refer to FIG. 1). For example, the message type may be an N4SsnModReq message.

The types of signal messages received by the signal message reception processing unit 10 include all signal messages used in the 5G core network. In particular, as messages for visualization of UE connection status related to 5G core network traffic monitoring visualization, there are N01RegAcpt message related to UE registration visualization and N01DregAcpt message related to UE registration revocation visualization. As a message for visualization of the session connection state, there are a message N04SsnEstbReq which is a message related to session establishment visualization and a message N04SsnRelReq which is a message related to session disconnection visualization. Messages for visualization of flow connection status, N50AppConnected message related to application connection flow status visualization, N50AppDisconnected message related to application disconnection flow status visualization, N50AppSwitched message related to application switching flow status visualization, application split There is a message N50AppSplitted which is related to the visualization of the streaming flow status. The signal message reception processing unit 10 transfers the received message to the signal message processing unit 2 .

The signal message processing unit 20 analyzes the signal message delivered from the signal message reception processing unit 10 and converts all signal messages except for the signal message for visualization of the flow connection state to the signal sequence production processing unit 40 and the traffic visualization processing unit ( 30) is forwarded. The signal message processing unit 20 transmits a signal message for visualization of the flow connection state only to the traffic visualization processing unit 30 .

The traffic visualization processing unit 30 visualizes 5G core network shape information and is configured to perform a function of visualizing a terminal connection state, a session connection state, a flow connection state, a switching traffic delivery method, and a splitting delivery method.

Specifically, when the operator's terminal accesses the traffic monitoring system, the traffic visualization processing unit 30 brings 5G core network shape information from the network shape information storage 50 and provides it to the operator's terminal so that it is output on the screen. And, when the traffic visualization processing unit 30 receives the signal message from the signal message processing unit 20, for signal messages excluding the UE connection status message, the session status message, and the flow status message, which are elements to be visualized, transmission in the header information Using the 5G core network function identifier of the side and the 5G core network function identifier of the receiving side, visualization of signals from the 5G core network function of the transmitting side to the 5G core network function of the receiving side is visualized in the 5G core network shape. Here, the signal disappears after being displayed for a certain period of time. This is because signal messages are continuously transmitted, so it is difficult to determine whether another signal is being transmitted if the existing signal is still displayed.

In addition, when the traffic visualization processing unit 30 receives the UE connection status message (UE registration message), using the 5G core network function identifier of the transmitting side and the 5G core network function identifier of the receiving side in the header information, in the 5G core network shape Signals from the 5G core network function of the transmitting side to the 5G core network function of the receiving side are displayed, and the UE and the UE are connected to the registered BS to visualize the terminal connection state. Here, the signal is displayed for a certain period of time and then processed to disappear.

In addition, when the traffic visualization processing unit 30 receives the session state message (session establishment message), by using the 5G core network function identifier of the transmitting side and the 5G core network function identifier of the receiving side in the header information, the corresponding 5G core network shape The session between UE, BS, and GW is displayed by displaying signals from the 5G core network function of the transmitting side to the 5G core network function of the receiving side, displaying the connection with the selected GW and BS, and also displaying the connection between the BS and the terminal UE. Perform visualization of connection status. Here, the signal is displayed for a certain period of time and then processed to disappear.

In addition, when the traffic visualization processing unit 30 receives the application connection flow message, the transmitting side 5G corresponding to the 5G core network shape using the transmitting side 5G core network function identifier and the receiving side 5G core network function identifier in the header information It displays signals from the core network function to the receiving side 5G core network function, displays the connection between the application server and the GW, and also finds the session corresponding to the session identifier in the GW using the session identifier in the header information to the GW, Visualization of flow connection status between UE, BS, GW, and application server is performed by displaying connections to BS and UE. Here, the signal is displayed for a certain period of time and then processed to disappear.

In addition, when receiving the application switching flow message, the traffic visualization processing unit 30 uses the 5G core network function identifier of the transmitting side and the 5G core network function identifier of the receiving side in the header information, and the corresponding transmitting side 5G in the 5G core network shape Displays signals from the core network function to the receiving side 5G core network function, deletes the session connection indication of BS and UE before switching, and displays a new session to the switching BS and UE, so that the UE, switched BS, GW, application Perform visualization of application switching flow connection status between servers. Here, the signal is displayed for a certain period of time and then processed to disappear. In order to indicate that the session to the newly displayed switching BS and UE is the same as the previous session, it may be displayed in the same color as the previous session.

In addition, when the traffic visualization processing unit 30 receives the application splitting flow message, by using the 5G core network function identifier of the transmitting side and the 5G core network function identifier of the receiving side in the header information, the corresponding transmission in the 5G core network shape Signals from the 5G core network function on the side to the 5G core network function on the receiving side are displayed, the session connection indication of the BS and UE before splitting is maintained as it is, and the session between the newly selected BS and the UE for splitting is renewed. By marking, not only the flow connection between the UE, BS, GW, and the application server, but also the flow connection between the UE, the new BS, GW and the application server is added to visualize the application switching flow connection status. Here, the signal is displayed for a certain period of time and then processed to disappear. In order to indicate that the session between the newly selected BS and the UE is the same session as the previous session, it may be displayed in the same color as the previous session.

On the other hand, when the signal sequence production processing unit 40 receives the signal message from the signal message processing unit 20, using the 5G core network function identifier of the transmitting side and the 5G core network function identification of the receiving side in the header information, the corresponding in the signal sequence It displays signals from the 5G core network function of the transmitting side to the 5G core network function of the receiving side. Then, when a signal message is received, the signal sequence creation processing unit 40 creates a signal sequence for all the received signal messages by displaying the signal after the previously displayed signal in the signal sequence. The signal sequence production processing unit 40 may output a signal sequence on the screen, and when one signal displayed in the signal sequence is selected, payload information of the selected signal message is output. Accordingly, the operator can monitor and track whether the signal message is normal or abnormal.

The network shape information storage 50 is configured to store 5G core network shape information.

When the operator's terminal accesses the traffic monitoring system 1 , the 5G core network shape information stored in the network shape information storage 50 is provided to the operator's terminal through the traffic visualization processing unit 30 . If the 5G core network shape information is changed, the newly changed 5G core network shape information is stored in the network shape information storage 50 .

In an embodiment of the present invention, an operator may access the traffic monitoring system 1 through a method such as logging in, or may access the traffic monitoring system 1 through a separate terminal. Here, when the operator's terminal accesses the traffic monitoring system 1, it is defined as including all methods of the operator accessing the traffic monitoring system 1 as described above.

10 to 12 are flowcharts of a traffic monitoring method according to an embodiment of the present invention.

As shown in the attached Figure 10, before the traffic monitoring system 1 is executed, the 5G core network shape information is stored in the network shape information storage 50 (S100).

When the operator's terminal accesses the traffic monitoring system 1, the traffic visualization processing unit 30 recognizes that the operator's terminal is connected (S110). The 5G core network shape information is brought from the network shape information storage 50 and provided to the operator's terminal, so that the 5G core network shape information is output on the screen (S120).

Thereafter, when the signal message reception processing unit 10 receives a signal message from the 5G core network function, the BS, and the terminal UE (S130), the received signal message is transferred to the signal message processing unit 20 (S140).

The signal message processing unit 20 analyzes the received signal message (S150), and when the received signal message is a signal message for visualization of the application switching flow state and the application splitting flow state (S160), the signal message It is transmitted to the traffic visualization processing unit 30 (S170). When the received signal message is not a signal message for visualization of the application switching flow state and the application splitting flow state, the corresponding signal message is transmitted to the traffic visualization processing unit 30 and the signal sequence production processing unit 40, respectively (S180) .

Next, as shown in FIG. 11 , when the traffic visualization processing unit 30 receives a signal message from the signal message processing unit 20 ( S190 ), the visualization target element UE connection status message, session status message, flow status message, and application switching In the case of a signal message excluding the flow status message and the application splitting flow status message, that is, when it is not a visualization target element message (S200), the transmitter 5G core network function identifier and the receiver 5G core network function identifier in the header information is used to display signals from the 5G core network function on the transmitting side to the 5G core network function on the receiving side in the 5G core network shape, and ends the signal display after a certain period of time (S210).

On the other hand, when the signal message received from the signal message processing unit 20 is a visualization target element message, a terminal connection status message (UE registration message) (S220), the transmitting side 5G core network function identifier in the header information and the receiving side 5G Signals are displayed from the 5G core network function of the transmitting side to the 5G core network function of the receiving side in the 5G core network shape by using the core network function identifier, and the signal display is terminated after a certain period of time (S230). Then, the UE and the UE display the connection with the registered BS to perform visualization of the UE connection state (S240).

On the other hand, when the signal message received from the signal message processing unit 20 is a visualization target element message, a session state message (session establishment message) (S250), the transmitting side 5G core network function identifier and the receiving side 5G core in the header information By using the network function identifier, signals from the 5G core network function of the transmitting side to the 5G core network function of the receiving side are displayed in the 5G core network shape, and the signal display is terminated after a certain period of time (S260). In addition, the selected GW and connection with the BS are displayed, and the connection between the BS and the terminal UE is also displayed to visualize the session connection state between the UE, the BS, and the GW (S270).

On the other hand, if the signal message received from the signal message processing unit 20 is an application connection flow message, which is a visualization target element message (S280), the transmitting side 5G core network function identifier and the receiving side 5G core network function identifier in the header information In the 5G core network shape, signals are displayed from the 5G core network function of the transmitting side to the 5G core network function of the receiving side in the shape of the 5G core network, and the signal display is terminated after a certain period of time (S290). Then, the connection between the corresponding application server and the GW is indicated (S300), and in addition, the session corresponding to the session identifier is found in the GW using the session identifier in the header information, and the connection to the GW, BS, and UE is indicated by displaying the connection to the UE, BS. , GW, and visualization of the flow connection state between the application server (S310).

On the other hand, when the signal message received from the signal message processing unit 20 is an application switching flow message, which is a visualization target element message (S320), the transmitting side 5G core network function identifier and the receiving side 5G core network function identifier in the header information By using, signals from the 5G core network function of the transmitting side to the 5G core network function of the receiving side are displayed in the 5G core network shape, and the signal display is terminated after a certain period of time (S330). And before switching, the session and flow connection indications of the BS and UE are deleted (S340), and the session connection and flow connection are newly displayed with the switched BS and UE, and the application between the UE, the switched BS, GW, and the application server A switching flow connection state visualization is performed (S350). At this time, in order to indicate that the session and flow are the same as the previous session and flow, the newly displayed session connection and flow connection are displayed in the same color as the previous session and flow.

On the other hand, when the signal message received from the signal message processing unit 20 is an application splitting flow message, which is a visualization target element message (S360), the transmitting side 5G core network function identifier and the receiving side 5G core network function in the header information Using the identifier, signals from the 5G core network function of the transmitting side to the 5G core network function of the receiving side are displayed in the 5G core network shape, and the signal display is terminated after a certain period of time (S370). And before splitting, the session connection indication of the BS and UE is maintained as it is (S380), and the session between the BS and the UE newly selected for splitting is newly displayed, so that between the UE, BS, GW, and the application server In addition to the flow connection, the flow connection between the UE, the new BS, the GW, and the application server is added and the application switching flow connection state visualization is performed (S390). At this time, the newly created session is also displayed in the same color as the previous session to indicate that it is the same session as the previous session.

On the other hand, as shown in the attached FIG. 12 , when the signal sequence production processing unit 40 receives a signal message from the signal message processing unit 20 ( S400 ), the transmitting side 5G core network function identifier and the receiving side 5G core in the header information By using the network function identifier, signals are displayed from the 5G core network function of the transmitting side to the 5G core network function of the receiving side in the signal sequence (S410). And when the operator selects the displayed signal (S420), by providing payload information of the signal message (S430), the operator can monitor and track whether the signal message is normal or abnormal.

In this way, the operator can monitor the 5G core network traffic through the network traffic visualization function and the signal sequence production function.

13 is a structural diagram of a traffic monitoring system according to another embodiment of the present invention.

13 , the traffic monitoring system 100 according to another embodiment of the present invention includes a processor 110 , a memory 120 , an input interface device 130 , an output interface device 140 , and a network It includes an interface 150 and a storage device 160 , which can communicate over a bus 170 .

The processor 110 may be configured to implement the methods described with reference to FIGS. 1 to 12 above. The processor 110 may be configured to, for example, perform functions of a signal message processing unit, a traffic visualization processing unit, and a signal sequence production processing unit. The processor 110 may be a central processing unit (CPU) or a semiconductor device that executes instructions stored in the memory 120 or the storage device 160 .

The memory 120 is connected to the processor 110 and stores various information related to the operation of the processor 110 . The memory 120 may store instructions to be executed by the processor 110 or may temporarily store instructions by loading the instructions from the storage device 160 . The processor 110 may execute instructions stored in or loaded from the memory 120 . The memory may include a ROM 121 and a RAM 122 .

In an embodiment of the present invention, the memory 120 may be located inside or outside the processor 110 , and the memory 120 may be connected to the processor 110 through various known means. Memory 120 may be configured to include a network shape information store.

The network interface device 150 is connected to a network and configured to transmit and receive signals. The network interface device 150 may be configured to receive a signal message through a network.

The input interface device 130 may be configured to receive a signal input from an operator (or an operator's terminal) and transmit it to the processor 110 .

The embodiment of the present invention is not implemented only through the apparatus and/or method described above, and may be implemented through a program for realizing a function corresponding to the configuration of the embodiment of the present invention, a recording medium in which the program is recorded, etc. Also, such an implementation can be easily implemented by those skilled in the art to which the present invention pertains from the description of the above-described embodiments.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improved forms of the present invention are also provided by those skilled in the art using the basic concept of the present invention as defined in the following claims. is within the scope of the right.

Claims (10)

A method for monitoring traffic in a core network of a mobile communication system, comprising:
receiving, by the monitoring device, a signal message; and
Visualizing, by the monitoring device, at least one of a terminal connection state, a session connection state, a flow connection state, an application switching flow state, and an application splitting flow state, based on the header information of the received signal message
includes,
Visualizing the at least one
When the received signal message is an application splitting flow message, the session connection indication before splitting is maintained, and a session between the base station and the terminal newly selected for splitting is displayed, and the terminal and the selected base station and the gateway and performing application switching flow connection status visualization further displaying flow connections between the application servers.
A traffic monitoring method comprising: 2. The method of claim 1
The step of visualizing the at least one,
When the received signal message is a session connection completion message, determining that it is the time when the connection procedure of the session is completed and visualizing the session connection state
includes,
Visualizing the session connection state is a traffic monitoring method of visualizing a state in which the terminal, the base station, and the gateway are connected. 2. The method of claim 1
The step of visualizing the at least one,
Visualizing the flow connection state when the received signal message is an application connection completion message received from the terminal
includes,
The step of visualizing the flow connection state visualizes the flow connection state between the terminal, the base station, the gateway, and the application server, traffic monitoring method. 2. The method of claim 1
The step of visualizing the at least one,
When the received signal message is a terminal connection state message, performing terminal connection state visualization to visualize an indication for connecting the terminal and the base station to which the terminal is registered
A traffic monitoring method comprising: 5. The method according to any one of claims 1 to 4
wherein the header information includes a message category corresponding to a transmitting-side core network function identifier, a receiving-side core network function identifier, a message type, a session identifier, and a message number. According to claim 1,
The step of visualizing the at least one,
A traffic monitoring method for performing visualization in which signals from a transmitting-side core network function to a receiving-side core network function are displayed for a set time using header information of the received signal message. 6. The method of claim 5,
The step of visualizing the at least one,
When the received signal message is an application connection flow message, the connection between the application server and the gateway is indicated, and the connection between the gateway, the base station, and the terminal according to the session corresponding to the session identifier in the header information is indicated. Steps to perform state visualization
A traffic monitoring method comprising: According to claim 1,
The step of visualizing the at least one,
If the received signal message is an application switching flow message, delete the displayed session and flow connection indication, and visualize the flow connection state that displays the connection between the base station and the gateway and the application server newly connected to the terminal according to the switching. steps to perform
A traffic monitoring method comprising: A traffic monitoring device in a core network of a mobile communication system, comprising:
an interface device for transmitting and receiving signals through a network; and
A processor connected to the interface device and configured to perform visualization based on a signal message received through the interface device
including,
the processor is
a signal message processing unit configured to analyze the received signal message; and
A traffic visualization processing unit configured to visualize at least one of a terminal connection state, a session connection state, a flow connection state, an application switching flow state, and an application splitting flow state according to the header information of the received signal message
includes,
The visualization processing unit determines whether the received signal message is one of a session connection completion message, an application connection completion message, a terminal connection status message, an application connection flow message, an application switching flow message, and an application splitting flow message, and the determination result Perform the visualization according to
The visualization processing unit additionally, if the received signal message is an application splitting flow message, maintains the session connection indication before splitting, and displays a session between the base station and the terminal newly selected for splitting, A monitoring device, configured to perform application switching flow connection status visualization further displaying flow connections between the terminal and the selected base station, gateway, and application server. 10. The method of claim 9,
The header information of the signal message includes a message category corresponding to a sending-side core network function identifier, a receiving-side core network function identifier, a message type, a session identifier, and a message number,
the processor is
A signal sequence production processing unit configured to visualize signals from a transmitting-side core network function to a receiving-side core network function for a set time using header information of the received signal message
Further comprising, a monitoring device.

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