KR20240032332A - Method, apparatus and system for network virtualization - Google Patents

Abstract

The present invention relates to a network virtualization method, device, and system, and more specifically, to a network function in a mobile communication system that can effectively improve network performance by virtualizing a mobility management entity (MME) in a mobile communication system. It relates to virtualization methods, devices, and systems.
In the present invention, a network function virtualization (NFV) system for virtualizing a mobility management device (MME) based on a software defined network (SDN), includes a data plane having a plurality of switches to transmit data; a control plane that controls the topology of the plurality of switches; and an application plane that provides a series of requirements for performing the functions of the mobility management device (MME) to the control plane. Disclosed is a network function virtualization system comprising a.

Description

{Method, apparatus and system for network virtualization}

The present invention relates to a network virtualization method, device, and system, and more specifically, to a network function in a mobile communication system that can effectively improve network performance by virtualizing a mobility management entity (MME) in a mobile communication system. It relates to virtualization methods, devices, and systems.

Mobile communication services are one of the most rapidly developing technological fields, and more advanced and integrated systems are required to meet the demand for improvements to conventional mobile communication systems and implement more efficient networks. In addition, as the number of mobile communication users rapidly increases worldwide, high-speed data communication networks and backbone infrastructure based on next-generation communication standards are required.

However, the problem is more specifically, how to improve the current network by adding new devices and improving the system based on the existing mobile communication system. In particular, existing mobile communication systems are already suffering from excessive load, and furthermore, new multimedia applications are based on augmented reality, 3D data traffic, high-speed broadcasting, Internet of Things (IoT), video conferencing, etc., and these new services and More improved infrastructure and resources are required for technology.

In this regard, research has recently been actively conducted to manage and utilize resources more flexibly and efficiently through virtualization in computing and networking environments.

In particular, Network Functions Virtualization (NFV) is an architecture that can improve network performance, a technology that can improve network processing capacity, reduce costs, accelerate network services, and facilitate the transition to virtual servers. It is evaluated as

The network function virtualization (NFV) is one of the more improved and efficient technologies applicable to distributed computing, and can provide more advanced applications (cutting-edge applications) based on various arrangements, organizations, and virtualization. At this time, the network can provide a network function that executes software in a virtual machine based on a hardware application. Additionally, the virtualization can provide various functions such as traffic control, firewall, and virtual routing.

Additionally, in mobile communication systems, the Mobility Management Entity (MME) is evaluated as one of the components that can be virtualized because it does not process data traffic.

However, the mobility management device (MME) does not process user data and does not use hardware to process data in the cloud. Additionally, deploying a mobility management device (MME) in the cloud can result in large loads and complicated processes, making it difficult to consider it an appropriate strategy.

Accordingly, a method for virtualizing the mobility management device (MME) based on the cloud is required, but an appropriate solution has not yet been proposed.

Republic of Korea Patent Publication No. 10-2021-0032760 (published on March 25, 2021)

The present invention was created to solve the problems of the prior art as described above, and provides a network function virtualization technology that can effectively improve network performance by virtualizing a mobility management entity (MME) in a mobile communication system. The purpose is to

In addition, the detailed purpose of the present invention can be clearly understood and understood by experts or researchers in this technical field through the specific contents described below.

A network function virtualization system according to an aspect of the present invention for solving the above problem is a network function virtualization (NFV) system for virtualizing a mobility management device (MME) based on a software defined network (SDN), comprising a plurality of A data plane equipped with switches to transmit data; a control plane that controls the topology of the plurality of switches; and an application plane that provides a series of requirements for performing the functions of the mobility management device (MME) to the control plane.

Here, the data plane can process the data transmission function of the serving gateway (SGW), and the control plane can process the control function of the serving gateway (SGW).

At this time, the control plane may be provided with a control unit that controls the flow of data for the plurality of switches.

Additionally, the control function of the serving gateway (SGW) may be driven in conjunction with the control unit.

Additionally, the mobility management device (MME) and the serving gateway (SGW) may be implemented as applications running on the control unit.

Additionally, the control unit may perform load balancing based on load statistics calculated for the plurality of switches.

Furthermore, for load balancing, when a new flow is received, a corresponding flow rule can be set and the traffic can be delivered to the Packet Data Network Gateway (PGW).

Additionally, information for processing the data transmission function of the serving gateway (SGW) in the data plane and the control function of the serving gateway (SGW) in the control plane can be transmitted using the GPRS tunneling protocol.

Accordingly, in the method, device, and system for virtualizing network functions in a mobile communication system according to an embodiment of the present invention, network performance can be effectively improved by virtualizing the mobility management entity (MME) in the mobile communication system. There will be.

The accompanying drawings, which are included as part of the detailed description to aid understanding of the present invention, provide embodiments of the present invention, and together with the detailed description, explain the technical idea of the present invention.
Figure 1 is a diagram illustrating a mobile communication system 10 according to an embodiment of the present invention.
Figure 2 is a configuration diagram of a network function virtualization system 100 according to an embodiment of the present invention.
3 to 7 are diagrams illustrating specific operations of the network function virtualization system 100 according to an embodiment of the present invention.
8 to 10 are diagrams illustrating the performance of the network function virtualization system 100 according to an embodiment of the present invention.

The present invention can be modified in various ways and can have various embodiments. Hereinafter, specific embodiments will be described in detail based on the accompanying drawings.

The following examples are provided to provide a comprehensive understanding of the methods, devices and/or systems described herein. However, this is only an example and the present invention is not limited thereto.

In describing the embodiments of the present invention, if it is determined that a detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. In addition, the terms described below are terms defined in consideration of functions in the present invention, and may vary depending on the intention or custom of the user or operator. Therefore, the definition should be made based on the contents throughout this specification. The terminology used in the detailed description is only for describing embodiments of the present invention and should in no way be limiting. Unless explicitly stated otherwise, singular forms include plural meanings. In this description, expressions such as “comprising” or “comprising” are intended to indicate certain features, numbers, steps, operations, elements, parts or combinations thereof, and one or more than those described. It should not be construed to exclude the existence or possibility of any other characteristic, number, step, operation, element, or part or combination thereof.

In addition, terms such as first, second, etc. may be used to describe various components, but the components are not limited by the terms, and the terms are used for the purpose of distinguishing one component from another component. It is used only as

First, Figure 1 illustrates a diagram explaining the configuration of a mobile communication system 10 according to an embodiment of the present invention. As can be seen in Figure 1, the mobile communication system 10 according to an embodiment of the present invention is a software-defined network (SDN) 11 and a network functions virtualization (NFV) network. (12), with a cellular network (13) and a cloud computing environment (14), a network for mobility management entity (MME), etc. based on a software defined network (SDN) in a mobile communication system (10). Network Functions Virtualization (NFV) can be implemented.

In relation to this, Figure 2 shows a configuration diagram of a network function virtualization system 100 according to an embodiment of the present invention.

At this time, as can be seen in FIG. 2, the network function virtualization system 100 according to an embodiment of the present invention is a network function virtualization for virtualizing a mobility management device (MME) based on a software defined network (SDN). (NFV) system 100, a data plane comprising a plurality of switches 110 to transmit data, a control plane controlling the topology of the plurality of switches 110, and the mobility management device (MME) 170 ) characterized in that it includes an application plane that provides a series of requirements for performing the function of the control plane.

Here, the data transmission function of the serving gateway (SGW) 180 may be processed in the data plane, and the control function of the serving gateway (SGW) 180 may be processed in the control plane.

At this time, the control plane may be provided with a control unit 120 that controls the flow of data for the plurality of switches 110.

Additionally, the control function of the serving gateway (SGW) 180 may be driven in conjunction with the control unit 120.

Additionally, the mobility management device (MME) 170 and the serving gateway (SGW) 180 may be implemented as applications running on the control unit 120.

Additionally, the control unit 120 may perform load balancing based on load statistics calculated for the plurality of switches 110.

Furthermore, for load balancing, when a new flow is received, a corresponding flow rule can be set and the traffic can be delivered to the packet data network gateway (PGW) 150.

In addition, information for processing the data transmission function of the serving gateway (SGW) 180 in the data plane and the control function of the serving gateway (SGW) 180 in the control plane can be transmitted using the GPRS tunneling protocol. .

Accordingly, in the network function virtualization method, device, and system in a mobile communication system according to an embodiment of the present invention, network performance is effectively improved by virtualizing the mobility management entity (MME) 170 in the mobile communication system. can be improved.

Hereinafter, exemplary embodiments of a network function virtualization method, device, and system in a mobile communication system according to an embodiment of the present invention will be described in more detail with reference to the attached drawings.

More specifically, the network function virtualization system 100 according to the present invention may be configured based on a software defined network (SDN) to improve the processes and functions of an existing mobile communication network.

Here, the software-defined network-based network function virtualization (SDN-NFV) architecture proposed in the present invention may be based on three layers: data plane, control plane, and application plane. .

At this time, the data plane may include a switch, and in one embodiment, it may be implemented using the OF (Open Flow) protocol and OpenSwitch virtual software.

The data plane can process data traffic and deliver it to an appropriate destination based on the flow entity of the flow table.

Additionally, the control plane is responsible for the entire network topology and can be implemented to include the functions of a conventional non-SDN router.

The control plane is responsible for handling all requirements and policies coming from the application plane.

Additionally, the application plane may use a virtualization environment in which running applications and all requirements are defined in the corresponding controller.

(1) Data plane settings

More specifically, Figure 3 shows a flowchart explaining the setting of a data plane.

Referring to FIG. 3, in the SDN-NFV architecture proposed in the present invention, data plane setup is one of the core operations and is required for all new sessions.

More specifically, as can be seen in FIG. 3, the user interface module (UIM) of the UE 130 transmits a request message for granting permission to the MME and setting up a radio data bearer.

After this session, the eNB 140 determines its own flow table. At this time, if there is no flow entry, the eNB 140 may transmit a packet to the OpenFlow controller 120 through a packet_in message.

Additionally, the eNB 140 has eNB_Value for downlink traffic and S1 interface. Accordingly, the control unit (OpenFlow controller) 120 defines the information, checks the packet header, and identifies the source and destination IP addresses. Next, the OpenFlow controller 120 provides the information to the data plane of the Serving Gateway (SGW) 180, and load statistics can also be checked for improved service quality.

Furthermore, the same process can be performed for packet_out messages for uplink traffic.

(2) Control plane settings

Additionally, Figure 4 explains the structure and operation of the control plane.

Referring to FIG. 4, the SDN-NFV architecture proposed in the present invention can be configured based on three layers including a data plane, control plane, and application plane. .

At this time, the on-demand function in the control plane is performed by the MME 170 and the MME 170 using the SI-MMS protocol and the Open Flow protocol between the MME 170 and the eNB 140. It can be configured using S11 between the SGW 180 interfaces.

More specifically, the core concept of the control plane architecture proposed in the present invention is to separate the data transmission function and control function of the Serving Gateway (SGW) 180 in the same pool area.

At this time, as can be seen in FIG. 4, all functions of the SGW 180 software and MME 170 can be implemented as applications running on the control unit (OpenFlow controller) 120 in a centralized manner.

Additionally, as can be seen in FIG. 4, the following functions may be included to implement the SDN-NFV architecture of the present invention.

i) OpenFlow controller: A key element of the SDN-NFV architecture proposed in the present invention, where the forwarding plane of the eNB (140) and the Service Gateway (SGW) (180) are located with respect to the data plane. You can. At this time, the OpenFlow controller can set up a user session and monitor the load in the data plane.

ii) MME (Mobility Management Substance): Can be used for user interface authentication (UIA) for mobility management. In the SDN-NFV architecture proposed in the present invention, the MME can communicate with the OpenFlow controller using API.

iii) SGW (Serving Gateway) Control Plane: As one of the intelligent elements, it uses GTP tunnel and TEID allocation, and the SGW controller based on the unique value of every session for uplink traffic and the value for downlink value. It can be driven by .

iv) SGW (Serving Gateway) data plane: Can be implemented with an advanced OpenFlow switch responsible for encapsulation and decapsulation of GTP packets. The SGW is received from the OpenFlow controller and can apply rules responsible for packet delivery between PDN (Packet Data Networks) and the eNB 140.

v) eNB (Evolved Node B): Can use the same wireless functions as specified in the 5GPP standard. Additionally, the OpenFlow protocol can be activated for data transfer.

vi) PGW (Packet Data Networks Gateway): The PGW can also be driven based on the 5G standard in which the values of the SGW controller are performed on a session basis.

(3) Load balancing

Additionally, Figure 5 illustrates an algorithm for load balancing.

Referring to FIG. 5, load balancing can be performed in the SDN-NFV architecture proposed in the present invention, and at this time, the architecture proposed in the present invention includes a flow table for flow entities. ) can be used. Here, you can set the timeout, command field, priority, and match fields for every flow entry, and whenever a new flow enters the SDN switch, OpenSwitch searches for the flow and If found, the packet can be updated.

On the other hand, if no flow is found, a packet_in message containing the header information of the first packet can be sent to the SDN controller. The obtained header is parsed and the resulting information can be used in OpenSwitch to create a new flow rule and direct flow up to rule generation. Additionally, in the case of a match field, source and destination MAC addresses and input port information may be used.

A thread running on an OpenSwitch controller can periodically perform a predetermined operation every second.

At this time, after receiving the request, a flow update may be generated and transmitted, and the received and transmitted bytes for all ports may be calculated and the total bytes for all ports may be added.

In addition, in the SDN-NFV architecture proposed in the present invention, for load balancing, the UIM (User Interface Module) operates each time a new connection is established with the eNodeB and incoming flows use the default established link. (incoming flow) can be forwarded. At this time, the switch 110 sends a packet_in message every time it receives a new flow and installs a new flow rule to route the traffic to the PGW 150 and the UE 130 or user interface. The route can be saved to handle additional flows coming from the module (UIM).

Additionally, Figure 6 illustrates a research framework for the present invention.

Hereinafter, the SDN-NFV architecture proposed in the present invention is evaluated from the perspective of latency generation and load. Additionally, to confirm the performance of the SDN-NFV architecture proposed in the present invention, it is evaluated against the existing model in terms of data throughput.

As can be seen in Figure 6, the present invention used a three-step methodology for the three main modules of the proposed SDN-NFV architecture for the experimental setup.

In the first module, problem investigation presented problems extracted from the literature after analyzing existing work in the relevant technical field.

In the second module, the basic elements were analyzed and a three-level architecture for the MME network was implemented, and then applied to implement the maximum load handling model for the mobile communication network.

In the last module, the inclusion criteria for all performance parameters and the result generation process were reviewed for performance evaluation of the work proposed in the present invention.

The implementation in the present invention was based on MME software. More specifically, in the prior art, the entire function of the MME is implemented based on a stand-alone architecture based on a single virtual machine, whereas in the present invention, the MME model is reorganized based on three layers to solve elasticity and scalability problems. did.

Subsequently, the SDN-NFV architecture proposed in the present invention was tested using several evaluation models, and the performance of the proposed SDN-NFV architecture was evaluated in terms of various performance parameters. At this time, performance parameters can be used to evaluate the proposed architecture and generate results.

In the present invention, NetSim LTE Simulation for MME is used and important interfaces and protocols in the LTE network are set.

In this regard, Figure 7 illustrates the software gateway function built into the MME.

(4) Latency Placement Analysis

In the first experiment for the present invention, delay time was analyzed as a standard for evaluating existing LTE networks. In this experiment, the latency values were normalized and the latency was calculated by reflecting the weight for overload.

Figure 8 shows the delay time analysis in the normal and overload situations. In Figure 8, it can be seen that while the delay time is in the normal range under a general traffic load, the delay time can also increase as the load increases, such as in the 40 to 90 second section in an overload situation.

Additionally, it was found that the delay time was within the normal range when the load balancing technique was triggered. Nevertheless, although the delay time could be higher under overload conditions compared to normal load conditions, it was confirmed that load balancing showed better delay time performance.

(5) Load Analysis

Additionally, in the second experiment, the load of the two switches in the network core was tested. At this time, the idle core load of the two switches was set to 100Mbps and the load was applied to the switches. Parallel links with values of 400 Mbps and 450 Mbps were also used on two ports of the switch. The results show the impact of the proposed load balancing technique for offloading traffic from the core network to other less loaded switches.

Figure 9 shows a rapid increase in traffic load. More specifically, as can be seen in Figure 9, there is a sharp increase in traffic load at 30 seconds for Switch 4 and Switch 5. If the offload occurs at 30 seconds, both switches have high throughput. The load balancing method proposed in the present invention processes both switches and distributes traffic between switches 4 and 5 when the load is at its peak.

Accordingly, the load balancing method proposed in the present invention evenly distributes the traffic load between the two switches with a smaller difference, as can be seen in FIG. 9.

(6) Measure data plane throughput (4.3 Data Plane Throughput Measurement

Additionally, the third experiment analyzes the throughput of the data plane when network bandwidth is shared by various user devices during data transmission. The results were tested with and without triggering the SDN-NFV system proposed in the present invention. In this experiment, different UEs 130 were set up as shown in FIG. 10 and the throughput (Mbps) per UE 130 was analyzed.

In Figure 10, it can be seen that the SDN-NFV proposed in the present invention can implement better UE (130) throughput even in a network with more UEs (130) compared to the existing SDN network, and one of the reasons is that SDN -This can be attributed to the load distribution method of the NFV system.

Accordingly, the present invention can provide a software-defined network-based network function virtualization (SDN-NFV) architecture with an optimized structure for cloud-based virtualization for the mobility management device (MME) 170. At this time, the architecture proposed in the present invention has a three-layer structure for the mobility management device (MME) 170, and has the advantage of being adjustable and expandable according to client traffic.

In addition, the architecture proposed in the present invention has the advantage of being flexible in terms of data processing, load balancing, and resource management through the cloud, and can provide flexibility and scalability to users and prevent virtual machine failures in the cloud. It can also provide resilience to .

In addition, the architecture proposed in the present invention can implement the mobility management equipment (MME) 170 in a distributed structure, effectively utilize the advantages of mobile communication networks, and provide scalability and improved data delivery and resource management. function can be provided.

In addition, the present invention provides a mobility management equipment (MME) 170 architecture that can handle the load of the mobile communication network as much as possible without affecting the session for the input request.

Furthermore, the present invention can provide a means to efficiently manage the elements constituting the network and the services provided.

Accordingly, in the method, device, and system for virtualizing network functions in a mobile communication system according to an embodiment of the present invention, network performance can be effectively improved by virtualizing the mobility management entity (MME) in the mobile communication system. There will be.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention. Accordingly, the embodiments described in the present invention are for illustrative purposes rather than limiting the technical idea of the present invention, and are not limited to these embodiments. The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of rights of the present invention.

10: Mobile communication system
11: SDN network
12: NFV Network
13: Cellular network
14: Cloud Computing
100: Network function virtualization system
110: switch
120: control unit
130:UE
140:eNB
150:PGW
160: Load balancing
170 : MME
180:SGW

Claims (8)

In a network functions virtualization (NFV) system for virtualizing a mobility management device (MME) based on a software defined network (SDN),
A data plane comprising a plurality of switches to transmit data;
a control plane that controls the topology of the plurality of switches; and
an application plane that provides a set of requirements for performing the functions of the mobility management device (MME) to the control plane;
A network function virtualization system comprising: According to paragraph 1,
The data plane processes the data delivery function of the serving gateway (SGW),
A network function virtualization system characterized in that the control plane processes the control function of a serving gateway (SGW). According to paragraph 2,
A network function virtualization system, characterized in that the control plane is provided with a control unit that controls the flow of data for the plurality of switches. According to paragraph 3,
A network function virtualization system, characterized in that the control function of the serving gateway (SGW) is driven in conjunction with the control unit. According to paragraph 3,
A network function virtualization system, wherein the mobility management device (MME) and the serving gateway (SGW) are implemented as applications running on the control unit. According to paragraph 3,
A network function virtualization system, wherein the control unit performs load balancing based on load statistics calculated for the plurality of switches. According to clause 6,
A network function virtualization system characterized in that when a new flow is received for the load balancing, a corresponding flow rule is set and the traffic is delivered to a packet data network gateway (PGW). According to paragraph 2,
A network function virtualization system, characterized in that information for processing the data transmission function of the serving gateway (SGW) in the data plane and the control function of the serving gateway (SGW) in the control plane are transmitted using the GPRS tunneling protocol.

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