KR101957952B1 - Method and Apparatus for Interworking Network - Google Patents

Abstract

A terminal for heterogeneous network interworking and a method using the same are disclosed.
A first network that is connected to the first network and performs voice communication or low-speed data communication based on the blocking request signal when the blocking request signal for the second network is input; A communication unit; When receiving a connection request signal with the second network in a state of being connected to the first network, measuring a first signal strength of the first network and a second signal strength of the second network to generate a measurement signal A signal measuring unit; A signal judging unit for comparing the measured signal with a predetermined reference value and judging whether or not it is possible to connect to the second network; And a second network communication unit for connecting to the second network and performing high-speed data communication when it is determined that the signal determination unit is connectable to the second network.

Description

Technical Field [0001] The present invention relates to a terminal for interworking with heterogeneous networks,

The present embodiment relates to a terminal for heterogeneous network interworking and a method using the same. More specifically, when the communication terminal changes the connection from the 3G network to the 4G network, the signal strength of the 3G network and the 4G network is measured without performing the location registration procedure in the 3G network, A terminal for heterogeneous network interworking, and a method using the same.

The contents described in this section merely provide background information on the present embodiment and do not constitute the prior art.

Generally, a wireless communication system is a system developed to enable a user to perform communication without restriction of a position. Such a wireless communication system has been developed to provide a high speed data service and a voice service (VoIP) using packets in a form of providing only initial simple voice communication service.

In addition, as a type of a wireless communication system, a system that provides basic packet voice service and a relatively low-speed data service is gradually developed as a system for providing high-speed packet data service. As described above, in a wireless communication system, a network providing a voice service and a relatively low-speed data service is a 2nd generation (hereinafter referred to as "2G") network and a 3rd generation (hereinafter referred to as "3G" . Although the 3G network can provide relatively high-speed data services, users are required to provide higher-speed data services, so that a need for a network developed over 2G or 3G networks is raised, and Long Term Evolution (hereinafter referred to as "4G" ) Network is being developed.

On the other hand, since the wireless communication system has to secure the mobility of the user, many base stations are involved and provide services in many cases. Therefore, a 2G or 3G network and a 4G network are mixed and used. When a user requests access to a 4G network while using a 2G or 3G network using a communication terminal, a packet switched location registration When the location registration is completed, it is determined whether the area is the 4G network area, and the connection is made to the base station, which takes a long time to use the 4G data communication.

The present embodiment provides a terminal for heterogeneous network interworking in which a communication terminal measures a signal strength of a 3G network and a 4G network and confirms and connects to a connectable network without performing a location registration procedure in a 3G network, and a method using the same There is a main purpose.

According to an aspect of the present invention, there is provided a communication terminal for performing communication via a first network and a second network in a wireless communication system, the method comprising: receiving a blocking request signal for the second network, A first network communication unit connected to the first network for blocking connection with the second network and performing voice communication or low-speed data communication; When receiving a connection request signal with the second network in a state of being connected to the first network, measuring a first signal strength of the first network and a second signal strength of the second network to generate a measurement signal A signal measuring unit; A signal judging unit for comparing the measured signal with a predetermined reference value and judging whether or not it is possible to connect to the second network; And a second network communication unit for connecting to the second network and performing high-speed data communication when it is determined that the signal determination unit is connectable to the second network.

According to another aspect of the present invention, there is provided a wireless communication system, comprising: a blocking request signal reception step of receiving a blocking request signal for the second network in linking a first network and a second network in a wireless communication system; A first network communication step of interrupting the connection with the second network based on the blocking request signal and performing a voice communication or a low speed data communication connected to the first network; When receiving a connection request signal for the second network, measures a first signal strength for the first network and a second signal strength for the second network using a predetermined system information block to generate a measurement signal A measurement signal generation process; A location registration step of performing location registration by transmitting terminal location information to the second network when the second network is connectable to the second network based on the measurement signal; And a high-speed data communication process of connecting / receiving contents to / from a peripheral base station included in the second network based on the location registration and using high-speed data communication. to provide.

As described above, according to the present embodiment, in changing the connection from the 3G network to the 4G network, the communication terminal measures the signal strength of the 3G network and the 4G network without performing the location registration procedure in the 3G network, It is possible to check whether the network can be connected and to connect the network, thereby reducing the time consumed. In addition, when converting to a 4G network, it saves battery consumption and improves communication quality and reduces customer complaints due to quick connection.

1 is a block diagram schematically showing a wireless communication system according to the present embodiment;
2 is a block diagram schematically showing a network according to the present embodiment,
3 is a block diagram schematically showing a communication terminal according to the present embodiment.
4 is a flowchart for explaining a method in which a communication terminal cooperates with a network in a wireless communication system according to the present embodiment;
FIG. 5 is a diagram illustrating an exemplary test result of a difference between a network interworking method according to the present embodiment and a general network interworking method.

Hereinafter, the present embodiment will be described in detail with reference to the accompanying drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if 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 describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected to or connected to the other component, It should be understood that an element may be "connected," "coupled," or "connected."

1 is a block diagram schematically showing a wireless communication system according to the present embodiment.

The wireless communication system according to the present embodiment includes a communication terminal 110, a network 120, and a content providing apparatus 130. [ Here, the network 120 includes a first network 122, a second network 124, and an n-th network 126.

The communication terminal 110 is a terminal capable of transmitting and receiving voice and various data via the network 120 in response to a key operation or a command of the user. The communication terminal 110 includes a tablet PC, a laptop, a personal computer A personal computer, a smart phone, a personal digital assistant (PDA), a mobile communication terminal, or the like. The communication terminal 110 may be a cloud computing terminal that supports cloud computing that can use services such as reading and writing data, storing data, and using the network and contents through the network 120.

The communication terminal 110 includes a memory for storing a program or a protocol for communicating with the content providing apparatus 130 or an external terminal via the network 120, a microprocessor for executing and controlling the program, and the like . The communication terminal 110 may include a plurality of communication modules to perform voice or data communication through the specific network 122, 124 and 126 in the network 120, And 126) to the content providing apparatus 130 or an external terminal. Here, the external terminal may be a terminal capable of performing voice communication with the communication terminal 110 via the network 120.

The communication terminal 110 according to the present embodiment performs communication using the specific networks 122, 124, and 126 corresponding to the network selection menu information input through the operation of the user. Here, the network selection menu information includes at least one of a mode using only the first network 122 and a mode using the first network 122 and the second network 124 mixedly. In this case, the mode using only the first network 122 is preferably a CS (Circuit Switched) Only mode, and the mode in which the first network 122 and the second network 124 are mixed is a CS + PS ) Mode, but is not limited thereto.

When the communication terminal 110 receives the blocking request signal for the second network 124 inputted through the user's operation, the communication terminal 110 disconnects the connection with the second network 124, connects with the first network 122, Lt; / RTI > Although the communication terminal 110 is described as being connected to the first network 122 to use only voice communication, the communication terminal 110 is not necessarily limited to this, and data communication at a lower speed than that provided by the second network 124 is also possible Do. The communication terminal 110 transmits a system information block (SIB), which is a broadcast message generated in the first network 122 and the second network 124, even when only the first network 122 is connected, .

Here, the system information block includes at least one of a minimum level reception sensitivity (Qrxlevmin), a minimum threshold transmission value (threshServingLow), a minimum threshold value (X) value (ThreshXlow) and an EUTRA minimum level reception sensitivity (QrxlevminEUTRA) One or more pieces of information. The system information block is information described in the standard (3GPP TS 25.331), the minimum level reception sensitivity (Qrxlevmin) is included in the system information block type (TYPE) 3 and the minimum threshold transmission value (threshServingLow) ThreshXlow) and EUTRA minimum level reception sensitivity (QrxlevminEUTRA) are described in System Information Block Type (TYPE) 19.

Meanwhile, when the communication terminal 110 receives a connection request signal for the second network 124 input through the operation of the user in a state of being connected to the first network 122, A first signal strength for the first network 122 and a second signal strength for the second network 124 to produce a measurement signal. Here, the first signal strength is RSCP (Received Signal Code Power) of the 3G network, and the second signal strength is RSRP (Reference Signal Received Power) of the 4G network. However, the present invention is not limited thereto.

The communication terminal 110 compares the measurement signal with a predetermined reference value and performs location registration with the second network 124 when it is determined that the second network 124 can be connected, And performs data communication to transmit and receive contents to and from the providing apparatus 130. The communication terminal 110 compares the measurement signal with a predetermined reference value and performs location registration with the first network 122 and determines whether the first network 122 is connected to the second network 124. [ Lt; / RTI >

The network 120 is a communication network capable of transmitting and receiving voice and data through various communication protocols including the first network 122, the second network 124 and the nth network 126. [ Preferably, the first network 122 is a 3G network, the second network 124 is a 4G network, and the nth network 126 is a synchronous network, an internet network, an intranet network, Satellite communication networks, and the like.

The network 120 includes a cloud computing network capable of storing computing resources such as hardware and software in cooperation with the content providing apparatus 130 and providing the computing resources required by the client to the communication terminal 110 . Here, cloud computing refers to a computer environment in which information is permanently stored on a server on the Internet and temporarily stored in a client terminal such as a desktop, a tablet computer, a notebook, a netbook, or a smart phone. Cloud computing, Refers to a computer environment access network that stores information on a server on the Internet and makes the information available anytime and anywhere through various IT devices.

The content providing device 130 is a kind of server that performs content storage and management for transmitting or receiving data of the communication terminal 110. The content providing apparatus 130 according to the present exemplary embodiment is preferably connected to the second network 124 and transmits corresponding data when the communication terminal 110 requests data. However, the present invention is not limited thereto, The content corresponding to the request signal received via the specific network 122, 124, or 126 in the network 120 may be transmitted to the communication terminal 110 via the network 120. [ Here, the content may include at least one of text data, image data, and image data. In addition, the content providing apparatus 130 has the same hardware configuration as that of a typical Web server or a network server. In addition, software modules include program modules implemented in any language such as C, C ++, Java, Visual Basic, and Visual C. The content providing apparatus 130 may be implemented as a web server or a network server. The web server is generally connected to an unspecified number of clients and / or other servers through an open computer network such as the Internet, Means a computer system that accepts a request to perform an operation of a server and derives a result of the operation, and computer software (a web server program) installed for the computer system.

2 is a block diagram schematically showing a network according to the present embodiment.

As shown in FIG. 2, the network 120 according to the present embodiment includes a first network 122 and a second network 124.

The first network 122 includes a first transmitter 210, a data processor 212, a data gateway 214 and a first accounting gateway 216.

The UTRAN interworking with the first network 122 refers to a Universal Mobile Telecommunications System (UMTS) terrestrial radio access network and the GERAN refers to a GSM (Global System for Mobile communications) EDGE (Enhanced Data Rates for GSM Evolution) radio access network. UTRAN, GERAN are included in the first network 122.

The communication terminal 110 supports both the first network 122 and the second network 124 so that the communication terminal 110 in the first network 122 communicates with the UTRAN via the Uu interface and through the Um interface Communicates with GERAN. The UTRAN communicates with the data processor 212 via the Iu-ps interface and with the exchange 230 via the Iu-cs interface. The GERAN communicates with the data processor 212 via the Gb interface and with the exchange 230 via the A interface. The communication terminal 110 supports both the first network 122 and the second network 124 so that the data processor 212 communicates with the data gateway 214 via the Gn interface and communicates with the exchange 230 via the Gs interface. Lt; / RTI >

The first transmitter 210 refers to a transmitter in the first network 122 and performs various functions necessary for wireless call processing such as location registration, radio channel assignment, and handoff in the first network 122, The transmitter 210 receives a call request signal from the communication terminal 110 through a signal channel, performs baseband signal processing, wired / wireless conversion, and transmits / receives a radio signal. Also, the first transmitter 210 may receive a data request signal from the communication terminal 110 through a signal channel, and may transmit the received data request signal to the content providing apparatus 130 through the transmission controller. Here, the first transmitter 210 is preferably a node B, but is not limited thereto.

The data processor 212 transmits the data packet to the mobile communication terminal 110 and generates call detail information and billing data for the data packet transmitted to the communication terminal 110 and transmits the data to the first charging gateway 216 . Here, the data processor 212 may be implemented as a Support GPRS Serving Node (SGSN).

The data gateway 214 is a node responsible for a connection function between a backbone network and an external packet data network and transmits packet data received from the data processor 212 in an appropriate packet data protocol (PDP) format (e.g., IP, X.25) And converts the Packet Data Protocol (PDP) address of the incoming packet data to the recipient's global mobile communication system (GSM) address. The data gateway 214 also stores the address and user profile of the current user's data processor in the location register of the data processor 212 and performs authentication and charging functions. The data gateway 214 is preferably a gateway GPRS support node (GGSN), but is not limited thereto.

The first accounting gateway 216 collects call detail information and billing data for data packets received by the communication terminal 110 of the subscriber from a plurality of different data processors 212, And collects the billing data having the same billing ID (Charing ID) into one piece of data, and transmits the consolidated billing data to the billing center. In addition, the first accounting gateway 216 performs a function of collecting data packet amounts of all accounting data having the same accounting ID and generating consolidated accounting data. The first accounting gateway 216 collects call detail information and billing data from at least one data processor of the plurality of data processors 212 in accordance with the handover of the communication terminal 110. Also, the first accounting gateway 216 performs the function of generating the integrated accounting data by using the identifier (IMSI: International Mobile Subscriber Identity) and the accounting ID of the call history information. The charging ID is a value assigned from the data gateway 214 when the data processor 212 generates the charging data of the communication terminal 110. That is, the billing ID is a value that does not change even when the same subscriber moves the plurality of data processors 212 in the same data gateway 214.

When the communication terminal 110 receives the content from the content providing apparatus 130, the first accounting gateway 216 updates the content usage amount information and charges the communication terminal 110 for the required cost based on the updated information Collect the results.

Hereinafter, the second network 124 will be described. The second network 124 includes a second transmitter 220, a control processor 222, a traffic processor 224, a packet processor 226 and a second accounting gateway 228.

The E-UTRAN connected to the second network 124 shown in FIG. 2 refers to the Evolved-UTRAN. The E-UTRAN may be included in the second network 124. Since the communication terminal 110 supports both the first network 122 and the second network 124, the communication terminal 110 communicates with the E-UTRAN through the LTE-Uu interface in the second network 124, The UTRAN communicates with the control processing unit 222 via the S1-U interface.

e Node B is a device that supports Long Term Evolution (LTE), and functions as RF transmission, transmission / reception, signal strength, quality measurement, baseband signal processing, and channel card (channel card resource management) . The second transmitter 220 and the Evolved Packet Core (EPC) (i.e., the control processing unit 222, the traffic processing unit 224, and the packet processing unit 226) may be collectively referred to as EPS (Evolved Packet System). That is, the second transmitter 220 refers to a transmitter in the LTE network that is the second network 124, and performs various functions necessary for wireless call processing such as location registration, radio channel assignment, and handoff in the second network 124 . Here, the second transmitter 220 is preferably an eNode B, but is not limited thereto. Also, the second transmitter 220 receives the high-speed data request signal from the communication terminal 110 through the signal channel in the second network 124, performs baseband signal processing, wired / wireless conversion, and transmits / . The second transmitter 220 can receive the high-speed data request signal from the communication terminal 110 through the signal channel and transmit the received high-speed data request signal to the content providing apparatus 130 through the transmission controller. Here, the second transmitter 220 is preferably a transmitter, but is not limited thereto, and can be extended to an E-UTRAN.

A control processor 222, a traffic processor 224, and a packet processor 226, and may be referred to as a packet core. This packet core refers to EPC. The control processor 222 basically performs call control such as location registration, paging, and authentication with respect to the communication terminal 110 and performs a mobility management function such as a legitimate eavesdropping function and a data call control function for the call controller Management). Here, the control processor 222 is preferably an MME (Mobile Management Entity), but is not limited thereto. The control processor 222 is a node for managing subscriber information and the mobility of the communication terminal 110 and is responsible for session management, idle subscriber management, paging, and subscriber authentication functions.

The traffic processing unit 224 is preferably an S-GW (Serving Gateway), but is not limited thereto. That is, the traffic processing unit 224 is a gateway to an access network and manages mobility in the first network 122. In addition, the traffic processor 224 processes legitimate eavesdropping on call traffic, and performs a traffic processing function. The traffic processor 224 is a session controller for processing payload traffic according to a set session and a user plane node for interworking with a second transmitter 220 as a user plane node, Supports handover, sets a packet processing unit 226 and a PDP context, and delivers PDU (Packet Data Unit) using tunneling. On the other hand, the traffic processing unit 224 and the control processing unit 222 can be flexibly expanded according to the increase of the traffic or the increase of the control signal.

The packet processing unit 226 is preferably a P-GW (PDN Gateway), but is not limited thereto. The packet processing unit 226 is a gateway to a PDS (Packet Data Network) such as an IP Multimedia Subsystem (IMS) and the Internet, manages mobility for a non-3GPP network, performs billing according to policy, . The packet processor 226 is a session control and user plan for assigning an IP of the communication terminal 110 and interworking with an external Internet network and a non-3GPP network. The packet processor 226 is connected to a traffic processor 224 for packet service, Routing information and has tunneling and IP routing functions. In addition, the packet processing unit 226 delivers the PDU to the traffic processing unit 224 and the external network.

The second accounting gateway 228 is a device that performs content accounting on content transmitted from the content providing device 130 to the communication terminal 110 and charges the corresponding content. That is, when the communication terminal 110 receives the content from the content providing apparatus 130, the second accounting gateway 228 updates the content usage amount information, and calculates the required cost of the communication terminal 110 based on the updated information Collect the billing results.

3 is a block diagram schematically showing a communication terminal according to the present embodiment.

The communication terminal 110 according to the present embodiment includes an input receiving unit 310, a signal measuring unit 330, a signal determining unit 340, a location registering unit 350, a first network communication unit 360, and a second network communication unit 370).

The input receiving unit 310 receives a blocking request signal and a connection request signal for the second network 124 inputted through the user's operation. More specifically, when the communication terminal 110 is set to a mode using only the first network 122, the input receiving unit 310 receives a blocking request signal for the second network 124, The input receiving unit 310 receives a connection request signal for the second network 124 when the first network 122 and the second network 124 are mixed. Here, the mode using only the first network 122 is preferably a CS (Circuit Switched) Only mode, and the mode in which the first network 122 and the second network 124 are mixed is a CS + PS mode But is not limited thereto.

The signal measuring unit 330 receives a connection request signal for the second network 124 from the input receiving unit 310 and transmits a first signal strength to the first network 122 and a second signal strength to the second network 124 using a predetermined function. 124 are measured to generate a measurement signal. Here, the first signal strength is RSCP (Received Signal Code Power) of the 3G network, and the second signal strength is RSRP (Reference Signal Received Power) of the 4G network. However, the present invention is not limited thereto.

Meanwhile, the signal measuring unit 330 may measure the first signal strength and the second signal strength even when only the first network 122 is connected, by using broadcasts generated in the first network 122 and the second network 124 (SIB) as a signal at a predetermined period. Here, the system information block includes at least one of a minimum level reception sensitivity (Qrxlevmin), a minimum threshold transmission value (threshServingLow), a minimum threshold value (X) value (ThreshXlow) and an EUTRA minimum level reception sensitivity (QrxlevminEUTRA) One or more pieces of information. The system information block is information described in the standard patent (TS 25.331), the minimum level reception sensitivity (Qrxlevmin) is included in the system information block type (TYPE) 3 and the minimum threshold transmission value (threshServingLow) ThreshXlow) and EUTRA minimum level reception sensitivity (QrxlevminEUTRA) are described in System Information Block Type (TYPE) 19.

Hereinafter, a process for measuring the first signal strength and the second signal strength using the system information block is expressed as follows.

First, the first signal strength (RSCP) measured using the system information block is expressed by Equation (1).

(RSCP: signal strength in the first network, Qrxlevmin: minimum level reception sensitivity, threshServingLow: lowest threshold transmission value)

For example, when the minimum level reception sensitivity is -56 dBm and the minimum threshold transmission value is 30 dBm, the first signal intensity is -56 dBm since -116 dBm + 60 dBm according to Equation (1).

Also, the second signal strength (RSRP) measured using the system information block is expressed by Equation (2).

(RSRP: signal strength in the second network, ThreshXlow: lowest threshold value (X) value, QrxlevminEUTRA: EUTRA minimum level reception sensitivity)

For example, if the minimum threshold value (X) is 0 dBm and the EUTRA minimum level reception sensitivity is -53 dBm, then the second signal strength is -106 dBm since 0 dBm + -106 dBm according to Equation (2).

The signal determination unit 340 determines whether or not the second network 124 is connectable to the second network 124 as compared with a predetermined reference value. Here, the predetermined reference value is preferably a reference value for the first signal intensity and the second signal intensity, but is not limited thereto.

When the signal judging unit 340 judges that the second network 124 can be connected to the second network 124 as compared with the predetermined reference value, ) To perform location registration. Meanwhile, when it is determined that the second network 124 can not be connected to the first network 122, the signal determination unit 340 transmits the current location information to the first network 122 and determines the connection of the first network 122 .

The location registration unit 350 registers the location in the second network 124 without performing location registration in the first network 122 when the signal determination unit 340 determines that the second network 124 can be accessed by the signal determination unit 340 do. By omitting such a procedure of registering a position in the first network 122, the time to be connected to the second network 124 can be shortened.

When the first network communication unit 360 receives the blocking request signal for the second network 124 from the input receiving unit 310, the first network communication unit 360 disconnects the connection with the second network 124, Communication. Although the first network communication unit 360 is described as being connected to the first network 122 to use only voice communication, the first network communication unit 360 is not necessarily limited to this, and data communication at a lower speed than that of the second network 124 is also possible.

The second network communication unit 370 transmits the location information of the cell where the communication terminal 110 is currently located to the second network 124 in the location registration unit 350 and performs location registration, And performs data packet communication in connection with the network base station and transmitting / receiving contents to / from the content providing apparatus 130. Here, the data packet communication means high-speed packet communication of the second network which delivers packets at a higher speed than the communication of the first network.

4 is a flowchart illustrating a method for a communication terminal to interwork with a network in a wireless communication system according to the present embodiment.

The communication terminal 110 receives a blocking request signal for the second network 124 (S410). Here, the communication terminal 110 is preferably set to use only the first network 122, but the present invention is not limited thereto, and may be a mode for using a voice call.

The communication terminal 110 disconnects the connection with the second network 124 based on the blocking request signal and connects to the first network 122 at step S420. Here, the communication terminal 110 is preferably connected to the first network 122 to use only voice communication, but it is not limited thereto, and data communication at a lower speed than the second network 124 is also possible.

The communication terminal 110 identifies the system information blocks for the first network 122 and the second network 124 at a predetermined period even though only the first network 122 is connected at step S430. Here, the system information block includes at least one of a minimum level reception sensitivity (Qrxlevmin), a minimum threshold transmission value (threshServingLow), a minimum threshold value (X) value (ThreshXlow) and an EUTRA minimum level reception sensitivity (QrxlevminEUTRA) One or more pieces of information. The system information block is information described in the standard patent (TS 25.331), the minimum level reception sensitivity (Qrxlevmin) is included in the system information block type (TYPE) 3 and the minimum threshold transmission value (threshServingLow) ThreshXlow) and EUTRA minimum level reception sensitivity (QrxlevminEUTRA) are described in System Information Block Type (TYPE) 19.

When the communication terminal 110 receives the connection request signal for the second network 124 to use the data packet communication (S440), the communication terminal 110 substitutes the system information block into a predetermined function according to the connection request signal, The intensity and the second signal intensity are measured to generate a measurement signal (S450). Here, the first signal strength is RSCP (Received Signal Code Power) of the 3G network, and the second signal strength is RSRP (Reference Signal Received Power) of the 4G network. However, the present invention is not limited thereto. Meanwhile, the communication terminal 110 measures a first signal strength by applying a system information block, which is a broadcast signal generated in the first network 122 and the second network 124, to Equation (1) To measure the second signal strength.

The communication terminal 110 determines whether it is connectable to the second network 124 based on the measurement signal (S460).

The communication terminal 110 performs location registration in the second network 124 in step S470 and transmits the location registration request to the content providing apparatus 102 using the second network 124. [ And performs data packet communication with the terminal 130 (S490). Here, the communication terminal 110 can shorten the time to be connected to the second network 124 by omitting the procedure of registering the location in the first network 122. [

As a result of checking in step S460, if it is impossible to connect to the second network 124, it performs location registration to the first network 122 and establishes a connection with the first network 122 so that voice or data communication can be performed (S480).

4, it is described that steps S410 to S490 are sequentially executed. However, this is only an exemplary description of the technical idea of the embodiment of the present invention, and it is to be understood that the technical knowledge of the technical field to which the embodiment of the present invention belongs Those skilled in the art will appreciate that various modifications and adaptations may be made to those skilled in the art without departing from the essential characteristics of one embodiment of the present invention by changing the order described in Figure 4 or by executing one or more of steps S410 through S490 in parallel And therefore, it is not limited to the time-series order in Fig.

FIG. 5 is a diagram illustrating an exemplary test result of a difference between a network interworking method according to the present embodiment and a general network interworking method.

FIG. 5 shows a comparison of the time when the network connection method according to the present embodiment and the general network interworking method are applied to the communication terminal 110 to connect to the 4G network. For example, "3 * E120S" and "3 * E160S" In the case of changing from the 3G network to the 4G network by applying the general network interworking method using the two models of the communication terminal 110 of the first model and the second model, 49.8 seconds for "3 * E120S" and 56.4 seconds for "3 * E160S" The communication terminal 110 performs location registration with the 4G network, and data packet communication is possible through the 4G network.

On the other hand, when changing from the 3G network to the 4G network by applying the network interworking method according to the present embodiment using the communication terminals 110 of the two models of "E120S" and "E160S" Quot; is 1.3 seconds and "3 * E160S" is 1.3 seconds after the communication terminal 110 performs the location registration with the 4G network, thereby shortening the time required for the communication terminal 110 to access the 4G network, To perform data packet communication.

The foregoing description is merely illustrative of the technical idea of the present embodiment, and various modifications and changes may be made to those skilled in the art without departing from the essential characteristics of the embodiments. Therefore, the present embodiments are to be construed as illustrative rather than restrictive, and the scope of the technical idea of the present embodiment is not limited by these embodiments. The scope of protection of the present embodiment should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

As described above, the present embodiment is applied to the field, so that it is possible to check the connection availability of the 4G network and directly connect to the network. Therefore, the time consumed can be shortened and the battery consumed when converting into the 4G network can be saved And it is a useful invention that has the effect of improving the call quality and reducing the customer complaints due to the quick connection.

110: communication terminal 120: network
122: first network 124: second network
126: nth network 130: content providing apparatus
210: first transmitter 212: data processor
214: data gateway 216: first accounting gate
220: second transmitter 222: control processor
224: Traffic control section 226: Packet processing section
228: Second charging gateway 230:

Claims (11)

A first network communication unit for interrupting the connection with the second network when the interception request signal for the second network is inputted, and performing a communication by connecting to the first network;
A signal measuring unit connected to the first network for continuously checking a system information block (SIB) for the first network and the second network to generate a measurement signal;
A signal judging unit for comparing the measured signal with a predetermined reference value and judging whether or not it is possible to connect to the second network; And
And a second network communication unit for performing communication by switching a connection to the second network without registering the location of the first network when it is determined that the second network can be connected to the second network,
The communication terminal comprising: The method according to claim 1,
Wherein the second network communication unit comprises:
A location register for registering a location by transmitting location information on a cell at a current location in the second network; And
And a data communication unit for performing communication by being connected to the second network base station of the location registered in the vicinity,
The communication terminal comprising: The method according to claim 1,
Wherein the signal measuring unit comprises:
Characterized in that the system information block (SIB) is checked at a predetermined period to measure the first signal strength of the first network and the second signal strength of the second network is measured to generate the measurement signal terminal. The method of claim 3,
The system information block includes:
At least one of the minimum level reception sensitivity (Qrxlevmin), the minimum threshold transmission value (threshServingLow), the minimum threshold value (X) value (ThreshXlow) and the EUTRA minimum level reception sensitivity (QrxlevminEUTRA) specified for the type in the system information block And the communication terminal. The method of claim 3,
Wherein the signal measuring unit comprises:
Measuring a first signal strength (RSCP) of the first network based on a minimum level reception sensitivity (Qrxlevmin) for the first network, a lowest threshold transmission value (threshServingLow)
(RSRP) of the second network based on a minimum threshold value (X) value (ThreshXlow) and an EUTRA minimum level reception sensitivity (QrxlevminEUTRA) for the second network. The method according to claim 1,
And performs a location registration with the first network and maintains a connection with the first network when the signal determination unit determines that connection to the second network is not possible. The method according to claim 1,
The interruption request signal includes:
A mode for using only the first network, and a mode for using the first network and the second network in a mixed manner. Blocking the connection with the second network when the blocking request signal is input to the second network, and performing a communication by connecting to the first network;
Generating a measurement signal by continuously checking a system information block (SIB) for the first network and the second network in a state of being connected to the first network;
Comparing the measured signal with a predetermined reference value to determine whether or not the second network can be accessed; And
And performing communication by switching connection to the second network without registering the location of the first network when it is determined that the second network can be connected to the second network
Wherein the communication terminal is connected to the network. delete delete 9. The method of claim 8,
The method of claim 1,
Wherein the location registration is performed by transmitting the terminal location information corresponding to a currently located cell to the second network without transmitting location information to the first network.

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