KR101267467B1 - Selection method of mobile terminal for distributing traffic in heterogeneous wireless network - Google Patents

Abstract

PURPOSE: A terminal selecting method for distributing traffic is provided to distribute concentrated traffic to a neighboring network when a new terminal requests access to an AP(Access Point) in which the data load is concentrated. CONSTITUTION: A situation information server(500) searches terminal information by searching for a terminal which overlaps a network which neighbors an integrated network for obtaining resources. When the search results in one found terminal, the situation information server selects a traffic distribution network by considering a moving direction of the terminal found in the search. When the search results in two or more found terminals, the situation information server searches for a traffic distribution terminal by using a zone information method. The zone information method determines the terminal found in the search based on priority. [Reference numerals] (200) Terminal T#1; (400) Integrated network #1; (410) Integrated network #2; (500) Situation information server; (520) Core network; (600) Use traffic 100/100; (610) Use traffic 99/100; (640) Disperse traffic; (650) Move 1M

Description

Terminal selection method for distributing traffic in a multi-radio network environment {selection method of mobile terminal for distributing traffic in heterogeneous wireless network}

The present invention relates to a method for selecting a terminal capable of distributing traffic in a multi-radio network environment in which a plurality of heterogeneous networks are mixed. Particularly, the present invention relates to a new terminal in an access point where load is concentrated in a network in which multiple access points exist. When the connection request is made, the present invention relates to a method for distributing traffic to neighboring networks in order to authorize a connection.

Various wireless network environments have a structure in which existing single networks such as wideband code division multiple access (WCDMA) and global system for mobile communications (GSM) independently provide services, such as High Speed Downlink Packet Access (HSDPA), 802.16e, and WLAN (WLAN). Heterogeneous systems, such as Wireless Lan, are coexisting or integrated, and are now changing to a multi-radio environment, which is currently required to provide a service that guarantees seamless and stable communication by effectively managing radio resources of heterogeneous networks. .

In order to meet these demands, in order to provide an optimal service through vertical handoff, development of a common radio resource management technology that integrates and manages resources of the entire network based on resource management functions in each network is underway.

In addition, traffic redistribution and access selection techniques applied between networks using integrated radio resource parameters managed collectively have been studied.

Recently, with the increase of mobile network subscribers and the spread of various smart phones, the demand for multimedia services in the wireless mobile environment is increasing. As a result, the use of SNS (Social Networking Service) services such as Twitter, Facebook, and MeToday have been active using mobile communication terminals, and network traffic has naturally increased.

The reason for the increase in traffic is the rapid increase in the use of streaming video and music using SNS (Social Networking Service) rather than simple text using SNS (Social Networking Service).

Changes in services such as clouding services and Mobile Voice over Internet Protocol (mVoIP) also resulted in increased traffic and increased network load.

In order to solve this problem, a conventional radio resource management technique and traffic redistribution technique have been proposed in the related art that collectively manages all network resources. However, there is no solution in the prior art to reduce the call blocking probability.

In addition, the prior art has a problem in that the call blocking probability increases rapidly when a new terminal requests access to an access point where load is concentrated in a network in which various access points exist.

The present invention has been made to solve the above problems, and in a system equipped with a situation information server for managing common radio resources in multiple wireless networks, a new terminal may request a connection to an access point where data load is concentrated. In this case, an object of the present invention is to provide a method for selecting a terminal capable of reducing call blocking probability by distributing traffic concentrating on call data load to an adjacent network.

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

In order to achieve the above object, the present invention provides a terminal, an ER (Edge Router) provided in a core network, and an integrated network, each of which includes resource usage information of the integrated network and movement information of the terminal. An access router (AR) for delivering to the core network and the core network, the resource usage information of each integrated network, the traffic information of each network, the battery and traffic usage information of the terminal, and the mobile information of the terminal A terminal selection method for distributing traffic in a multi-radio network environment in a traffic distribution system including a situation information server that classifies a network into zones and stores and manages information, when a new terminal requests access to an integrated network, Requesting resource security to the context information server through the ER in an AR belonging to the integrated network; The situation information server searches for terminal information capable of distributing traffic by searching for a terminal overlapped with an adjacent network adjacent to the integrated network to secure resources. Selecting a network to distribute the traffic in consideration of the direction and if the situation information server has more than one terminal, the zone information method that is determined by prioritizing by dividing the network into zones (Zone) Selecting a terminal to distribute the traffic using.

Selecting a terminal to distribute traffic by using the zone information method, when classifying a terminal to distribute traffic using the zone information method, when there are two or more terminals having the same priority, the situation The information server searches for and selects a terminal transmitting non-real-time traffic among two or more terminals having the same priority, and classifies a terminal to distribute traffic by using the zone information method. If there are two or more terminals and all of the terminals are using non-real-time traffic, selecting a terminal to distribute the traffic in consideration of the moving speed and direction of the terminal, the terminal to distribute the traffic using the zone information method When classifying, two or more terminals having the same priority exist and all of them are moving. If Nin, may include the step of considering the holding amount of the battery of the terminal, select a terminal to distribute traffic.

Selecting a terminal to distribute the traffic in consideration of the moving speed and direction of the terminal, to determine the deceleration information by periodically measuring the RSSI (Received Signal Strength Indication) value of the terminal, the terminal by using the deduction information Check the moving direction of, and may be to check the moving speed of the terminal by using the change in the magnitude of the subtraction.

The zone information method may be a method in which the AR or the base station periodically classifies a RSSI value and classifies and manages a range determined according to the size of the RSSI value as a zone based on the measured RSSI value.

Among the terminals located in a range overlapping the first integrated network and the second integrated network, the terminal located in a zone outside the predetermined reference of the first integrated network may be selected as a terminal to distribute traffic.

Alternatively, among the terminals located in a range overlapping the first integrated network and the second integrated network, the terminal located inside the predetermined standard of the second integrated network among the terminals located in the zone outside the predetermined standard of the first integrated network. It can be selected as a terminal to distribute traffic.

When classifying terminals to distribute traffic by using the zone information method, when two or more terminals having the same priority exist, the protocol part of the IP header is checked to determine whether the terminal is transmitting non-real-time traffic. In this case, the terminal transmitting the non real-time traffic may be selected as the terminal to distribute the traffic.

According to the present invention, when a situation information server for managing a common radio resource is provided in a multi-radio network environment, when a new terminal requests a connection to an access point where data load is concentrated, the traffic of the terminal overlapping with an adjacent network is provided. By distributing to neighboring networks, it is possible to reduce the call blocking probability.

In addition, according to the present invention, when determining the terminal to distribute traffic to the adjacent network, by classifying by zone class unit to determine by using the location and movement information of the terminal, there is an advantage that can reduce unnecessary handoff.

In addition, the present invention has the effect of ensuring the quality of service (QoS) to the user by distributing the traffic of the terminal using the non-real-time traffic.

1 is a diagram illustrating a traffic distribution system in a multi-radio network environment according to an embodiment of the present invention.
2 is a diagram illustrating a process of delivering a packet to a terminal through a single network through a conventional single network.
3 is a configuration diagram of a traffic distribution network proposed in the present invention.
FIG. 4 is a diagram for describing a method of classifying and selecting classes in zone units when selecting a terminal for traffic distribution according to an embodiment of the present invention.
5 is a diagram for describing a method of determining traffic distribution in consideration of movement information of a terminal when selecting a terminal for traffic distribution according to an embodiment of the present invention.
6 is a diagram illustrating a procedure for distributing traffic of a network to secure resources according to an embodiment of the present invention.
7 is a flowchart illustrating a data receiving method in an access router according to an embodiment of the present invention.
8 is a flowchart illustrating a traffic distribution method in a contextual information server according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used for the same reference numerals even though they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, throughout the specification, when a part is said to "include" a certain component, it means that it may further include other components, without excluding the other components unless otherwise stated. .

1 is a diagram illustrating a traffic distribution system in a multi-radio network environment according to an embodiment of the present invention.

Referring to FIG. 1, the traffic distribution system according to the present invention includes a terminal T # 1 200 and a situation information server 500.

The present invention will be described under the premise that the context information server 500 manages resource information of the AR, mobile information of the terminal, data usage, battery information, and information on the type of traffic used by the terminal.

As shown in FIG. 1, the context information server 500 includes resource usage information of the integrated network # 1 400 and the integrated network # 2 410, and a plurality of wireless networks using the networks. It serves to manage the information of the terminal T # 1 (200) using.

In an embodiment of the present invention, the integrated network # 1 400 and the integrated network # 2 410 may be configured with wireless access networks such as 3G, Wi-Fi, and WiBro.

In addition, in an embodiment of the present invention, the terminal T # 1 200 may support a dual mode or a multi mode.

AR # 1, # 2 (300, 310; Access Router) periodically transmits the resource usage information (600, 610) of the integrated network and the movement information of the terminal to the situation information server 500 through the ER (edge router) (510) Play a role. That is, information of each network and the terminal is managed by the context information server 500 of the core network 520 through the AR # 1, # 2 (300, 310).

In the embodiment of FIG. 1, the traffic usage among the resource usage information 600, 610 of each integrated network # 1, # 2 (400, 410) is expressed as (bandwidth in use / total bandwidth).

2 is a diagram illustrating a process of delivering a packet to a terminal through a single network through a conventional single network.

As shown in FIG. 2, it is assumed that the terminal T # 1 200 uses 3 megabytes (MB) of resources for the integrated network # 1 400. In addition, it is assumed that the traffic usage of the integrated network # 1 (400) is 98MB / 100MB. That is, assuming that total bandwidth is 100MB available in Integrated Network # 1 (400), it is currently in use of 98MB and thus only 2MB of additional resources are available.

At this time, when the terminal T # 2 210 makes a connection request 620 for 3MB bandwidth using the integrated network # 1 400, the AR # 1 300 determines whether the access is allowed.

In the integrated network # 1 (400), there is not enough 1MB of resources to allow the access of the terminal T # 2 (210). In order to allow the access request of the terminal T # 2 210, the AR # 1 300 requests the resource information of the integrated network # 1 400 from the context information server 500 through the ER 510. In addition, the context information server 500 selects a method and a terminal for distributing traffic from the integrated network # 1 400 to an adjacent network.

FIG. 3 is a block diagram of a traffic distribution network proposed by the present invention, and illustrates a process of distributing traffic to a neighbor network to prevent blocking of a requested call when a new terminal access request is made.

Referring to FIG. 3, 1MB of traffic of the terminal T # 1 200 that is being used in the integrated network # 1 400 is distributed to the integrated network # 2 410. That is, in the present invention, when the access request of the new terminal or the bandwidth of the existing terminal increases, the traffic of the terminal is distributed to the neighbor integrated network to prevent call blocking.

FIG. 4 is a diagram for describing a method of classifying and selecting classes in zone units when selecting a terminal for traffic distribution according to an embodiment of the present invention.

That is, FIG. 4 is an optimal terminal for distributing traffic through the zone class classification method of the integrated network # 1 (400) currently used when the network is overloaded and the neighbor network # 2 (410) that is the neighbor network to distribute traffic. Is a diagram illustrating a method of determining.

Referring to FIG. 4, the inner zone (Zone), that is, the zone closer to the AP (Access Point) or the BT (Base Station), indicates that the class is higher, and conversely, the outer zone, the lower the zone class. do.

As illustrated in FIG. 4, terminals T # 1, 3, 4, and 5 (200, 230, 240, and 250) overlap the integrated networks # 1 and # 2 (400, 410). At this time, when network load or connection request of a new terminal occurs, in order to distribute traffic and secure additional bandwidth, the zones of the zones where the terminals T # 1, 3, 4, 5 (210, 230, 240, 250) are located The class selects a terminal to distribute traffic.

In the present invention, when the zones of the integrated network # 1 (400) are divided into two (420, 430), priorities for distributing traffic by terminals in the outer zones (Zone) # 1-2 (430) Is high. In addition, the UE located in the inner zone # 2-1 (440) of the neighbor network to be distributed has a high priority to be distributed to the neighbor network.

In conclusion, in the present invention, the zone is located in zone # 1-2 (430), which is outside of the integrated network # 1 (400) where a request for access of a new terminal is currently located, and is a zone inside the integrated network # 2 (410) to distribute traffic. The terminal located at # 2-1 440 is selected as the terminal to distribute traffic.

5 is a diagram for describing a method of determining traffic distribution in consideration of movement information of a terminal when selecting a terminal for traffic distribution according to an embodiment of the present invention.

That is, FIG. 5 is a load on the network, when selecting a terminal to distribute traffic by the selection method through the zone of FIG. 4, when there is a terminal having the same priority, the traffic is distributed through the mobile information and the moving speed Is a diagram illustrating a method of determining an optimal terminal to be used.

Referring to Figure 5 in detail, the terminal periodically measures the RSSI (Received Signal Strength Indication) value and transmits the rate of change to the situation information server 500, the situation information server 500 is the RSSI change rate of the terminal Based on this, the direction and speed of movement are recognized. For example, in the integrated network # 1 400, the RSSI values of the terminals T # 1, 3, 4 (200, 230, 240) are measured and the change rate is examined. As we are facing outward of the neighboring network to be distributed, we can see that the RSSI value decreases.

As such, in the present invention, the terminal T # 4 240 is selected in which the strength of the RSSI in the integrated network # 1 400 is weakened and the RSSI strength in the integrated network # 2 410 is increased in consideration of the moving direction of the terminal. Decide to distribute the traffic.

6 is a diagram illustrating a procedure for distributing traffic of a network to secure resources according to an embodiment of the present invention.

That is, FIG. 6 is a diagram illustrating a network resource obtaining procedure in order to prevent call blocking according to an embodiment of the present invention.

Referring to FIG. 6, the ER 510 is transmitting data in a single path to the terminal T # 1 200 through the AR # 1 300 (S700), and the new terminal T # in the AR # 1 300. If there is a connection request of 2 (210) (S701), AR # 1 (300) checks the network resource information that can be provided (S702).

The AR # 1 300 recognizes that the terminal T # 2 210 cannot provide the requested resource, and requests the ER 510 to secure network resources (S703).

The ER 510 receiving the resource securing request requests a terminal and a method for distributing traffic to the situation information server 500 (S704).

The context information server 500 searches for a terminal and a network to distribute traffic using the mobile information of the terminals, and selects the terminal and the network (S705). In addition, the always information server 500 transmits the selected terminal and network information to the ER (510) (S706).

In addition, the ER 510 distributes traffic to the terminal T # 1 200 through the AR # 1 300 and the AR # 2 310 (S707), and accesses the terminal T # 2 210. Allow the data to be transmitted (S708).

7 is a flowchart illustrating a data receiving method in an access router according to an embodiment of the present invention.

Referring to FIG. 7, when UE T # 2 210 attempts to access AR # 1 300, AR # 1 receives a call admission message from UE T # 2 210 ( S800).

The AR # 1 300 checks network resource information (S801).

If there is a network resource that can be transmitted through a single network, the AR # 1 300 selects a network that can be transmitted and requests data transmission (S802, S804, S806). However, if network resources are insufficient, the traffic distribution path through the multiple networks is selected to request data transmission (S803, S804, S806).

If the terminal T # 2 210 cannot provide the desired bandwidth even by distributing traffic, the AR # 1 300 makes a request for securing network resources to the ER 510 and provides the terminal T # 2 210 to the terminal. It is possible to secure network resources (S805).

8 is a flowchart illustrating a traffic distribution method in the context information server 500 according to an exemplary embodiment.

Referring to FIG. 8, when the situation information server 500 receives a request for distributing traffic information for securing network resources of the AR # 1 300 through the ER 510, first, a terminal overlapping with an adjacent network is searched. It is made (S900).

As a result of the search, if there is only one terminal searched for, the information server 500 selects a network to distribute traffic in consideration of the direction in which the terminal moves.

If there are a plurality of terminals overlapping with the neighboring network, the context information server 500 selects a terminal to distribute traffic by using the zone class information of FIG. 4 (S901).

If there is a terminal having the same priority, the context information server 500 searches for a terminal transmitting non-real-time traffic among the terminals having the same priority (S902 and S904). That is, when the situation information server 500 classifies the terminals to which traffic is distributed using the zone class classification method, if there are a plurality of terminals having the same priority, the situation information server 500 selects a terminal using non real-time traffic among the plurality of terminals (S904, S906). In detail, the protocol header of the IP header is used to classify whether the traffic is non-real time or real time.

If there is a terminal using non real-time traffic, the context information server 500 selects a network to distribute the traffic in consideration of network resources (S906 and S916).

If there is no terminal using non real-time traffic, the situation information server 500 searches for the moving terminal among the same priority terminals (S908).

If there is a mobile terminal, the context information server 500 selects a terminal to distribute traffic in consideration of the mobile information (S912, S910), and selects a network to distribute traffic in consideration of network resources (S916). ). In this case, the situation information server 500 periodically measures the RSSI value of the terminal, checks the information of the acceleration and deceleration, confirms the movement direction, and confirms the movement speed by confirming the magnitude change of the acceleration and deceleration.

If the mobile terminal does not exist, that is, all the terminals are in use at a fixed location, the situation information server 500 selects the terminal in consideration of the data usage and the battery amount of the terminal (S914). In other words, the situation information server 500 determines a terminal with a high data usage or a terminal with a large amount of battery as a terminal to distribute traffic.

When the network and the terminal for distributing traffic are selected as described above, the context information server 500 selects the terminal and the network for distributing the traffic in consideration of resource information of the neighboring network (S916). Then, the context information server 500 transmits the determined terminal, the network to distribute the traffic, and the size information of the bandwidth to be distributed to the ER 510 (S918).

While the present invention has been described with reference to several preferred embodiments, these embodiments are illustrative and not restrictive. It will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit of the invention and the scope of the appended claims.

200 Terminals T # 1 300 AR # 1
310 AR # 2 400 Integrated Network # 1
410 Integrated Network # 2 500 Situation Information Server
510 ER 520 Core Network
210 terminal T # 2

Claims (7)

In a multi-radio network environment, an ER (Edge Router) provided in a terminal, a core network, and an AR provided in each integrated network to transmit resource usage information of the integrated network and movement information of the terminal to the core network through the ER Access Router) and the core network to classify resource usage information of each integrated network, traffic information of each network, battery and traffic usage information of the terminal, mobile information of the terminal, and integrated network into zones, and store the information. A method for selecting a terminal for distributing traffic in a multi-radio network environment in a traffic distribution system including a situation information server for managing
When a new terminal requests access to an integrated network, requesting resource security to the context information server through the ER in an AR belonging to the integrated network;
Searching, by the context information server, terminal information capable of distributing traffic in a manner of searching for a terminal overlapped with a neighboring network adjacent to the integrated network to secure resources;
Selecting, by the context information server, a network to which traffic is distributed in consideration of a direction in which the terminal moves, when one terminal is found; And
The context information server includes selecting a terminal for distributing traffic by using a zone information method, which is a method of determining a priority by dividing a network into zones when two or more terminals are searched. A terminal selection method for distributing traffic in a multi-radio network environment.
The method of claim 1,
Selecting a terminal to distribute traffic by using the zone information method,
When classifying terminals to which traffic is distributed using the zone information method, when two or more terminals having the same priority exist, the context information server may detect non real-time traffic among two or more terminals having the same priority. Searching and selecting a terminal being transmitted;
When classifying terminals to distribute traffic by using the zone information method, when two or more terminals having the same priority exist and all of the terminals are using non-real-time traffic, considering the moving speed and direction of the terminal Selecting a terminal to distribute traffic;
When classifying terminals to which traffic is to be distributed using the zone information method, when two or more terminals having the same priority exist and all of the terminals are not moving, traffic is distributed in consideration of the amount of battery capacity of the terminal. Selecting a terminal comprising a terminal selection method for distributing traffic in a multi-radio network environment.
The method of claim 2,
Selecting a terminal to distribute traffic in consideration of the moving speed and direction of the terminal,
Periodically measuring the RSSI (Received Signal Strength Indication) value of the terminal to confirm the deceleration information, to determine the movement direction of the terminal using the deduction information, and to determine the movement speed of the terminal using the change of the magnitude Terminal selection method for distributing traffic in a multi-radio network environment, characterized in that.
The method of claim 1,
The zone information method is a method of multi-radio, characterized in that the AR or the base station periodically measures the RSSI value and classifies and manages a range determined according to the size of the RSSI value based on the RSSI value measured in the zone (Zone) A terminal selection method for distributing traffic in a network environment.
5. The method of claim 4,
Among the terminals located in the overlapping range of the first integrated network and the second integrated network, the terminal located in a zone outside the predetermined standard of the first integrated network, the multi-radio network, characterized in that for selecting the terminal to distribute traffic Terminal selection method for distributing traffic in an environment.
5. The method of claim 4,
Among the terminals located in a range overlapped with the first integrated network and the second integrated network, among the terminals located in a zone outside the predetermined standard of the first integrated network, traffic is transmitted to the terminal located within the predetermined standard of the second integrated network. A terminal selection method for distributing traffic in a multi-radio network environment, characterized in that it is selected as a terminal to be distributed.
The method of claim 2,
When classifying terminals to distribute traffic by using the zone information method, when two or more terminals having the same priority exist, the protocol part of the IP header is checked to determine whether the terminal is transmitting non-real-time traffic. The terminal selection method for distributing traffic in a multi-radio network environment, characterized in that for determining, and accordingly selecting the terminal transmitting the non-real-time traffic as the terminal to distribute the traffic.

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