KR101434630B1 - Method and apparatus for transmitting and receiving data in multi network environments - Google Patents

Abstract

The present invention discloses a multiple network-based simultaneous transmission / reception method and an apparatus applied thereto. That is, the partial data segmented from the transmission target data is transmitted to the receiving apparatus through two or more access networks, and quality measurement data for determining the network status through the specific access network among the two or more access networks is transmitted to the receiving apparatus And transmitting the quality measurement data through the other access network in order to determine the network status of the other access network among the two or more access networks after determining the network status of the specific access network based on the reception status of the quality measurement data in the receiving apparatus. By transmitting the measurement data to the receiving apparatus, the network status of each of the multiple networks can be effectively determined.

Description

METHOD AND APPARATUS FOR TRANSMITTING AND RECEIVING DATA IN MULTI NETWORK ENVIRONMENTS BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present invention relates to a method for determining the network status of each of multiple networks in order to determine an optimal data distribution rate between networks applied to partial data division in simultaneously transmitting segmented partial data from transmission target data using multiple networks will be.

In recent years, WCDMA, CDMA, WiBro, and WLAN (WiFi) technology, which are short-range wireless networks, have been introduced and are being provided with LTE (Long Term Evolution) technology.

In addition, various wireless devices such as smart phones and tablet PCs are increasing, and a variety of large-capacity data services targeting these wireless devices are also increasing.

In a multi-network environment in which a plurality of networks are mixed, a data service is generally provided through a single transmission mode in which only one network is selected and data is transmitted.

However, the single transmission scheme has a disadvantage in that when a large amount of data is transmitted / received, the load rate of the network increases sharply, and a smooth data service can not be used.

Accordingly, a simultaneous transmission service for simultaneously transmitting data using a plurality of multiple networks in order to utilize a smooth data service in the multiple network environment has been proposed.

The simultaneous transmission service is a simultaneous transmission method in which partial data divided from data are simultaneously transmitted using multiple networks.

In this regard, in order to provide the above-described simultaneous transmission service to a terminal device held by a user, the terminal device checks the network status of each of the multiple networks currently connected to the terminal, and based on this, .

However, since the location of the actual terminal device is moved by the user, the quality of the network to which the terminal device is connected can not be maintained anytime and anywhere. Therefore, it is difficult to calculate the optimum data distribution rate between the networks.

Therefore, there is a need for a new network state determination method for determining an optimum data distribution rate among multiple networks to which the terminal apparatus is connected.

The present invention relates to a method and apparatus for efficiently determining the network status of each of multiple networks in order to determine an optimal data distribution rate between networks applied to partial data division in a simultaneous transmission environment, .

According to a first aspect of the present invention, there is provided an apparatus for simultaneously transmitting multiple network-based data, comprising: a partial data transmission unit for transmitting partial data segmented from transmission target data to a reception apparatus through two or more access networks; A quality measurement data transmission unit transmitting quality measurement data for determining a network status to at least one of the two or more access networks to the receiving apparatus; And a status determination unit that determines at least one network status among the two or more connection networks based on a reception status of the quality measurement data in the reception apparatus, And transmitting the quality measurement data through the access network. When the status determination unit determines the network status for the specific access network based on the reception status of the quality measurement data, And transmits the quality measurement data through the network.

Wherein the quality measurement data transmission unit transmits the quality measurement data when it is determined that the receiver is in an idle state and the number of transmissions of the quality measurement data transmitted in a specific idle state is the same as the quality measurement data transmitted before And is greater than the number of transmission of quality measurement data transmitted in the idle state.

According to a second aspect of the present invention, there is provided a multiple network-based simultaneous transmission receiving apparatus including: a partial data receiving unit receiving partial data divided from transmission target data from a transmitting apparatus via two or more access networks; A quality measurement data receiving unit for receiving the quality measurement data transmitted from the transmission apparatus through at least one of the two or more connection networks; And a reception status verifying unit for verifying the reception status of the quality measurement data and determining at least one network status among the two or more connection networks in the transmission apparatus based on the reception status.

More specifically, the reception apparatus includes an idle state determination unit for determining whether the reception apparatus is in an idle state; And a quality measurement data requesting unit for requesting the transmission apparatus to transmit the quality measurement data when it is determined to be in the idle state.

More specifically, the idle state determination unit determines whether the idle state is present at a certain point of time, and determines whether or not the idle state at another point in time after the elapse of a predetermined waiting time is determined to be idle And the predetermined waiting time is determined to increase sequentially in each repetition period within a threshold time limit.

According to a third aspect of the present invention, there is provided a method of operating a multiple network-based simultaneous transmission transmitting apparatus, the method including: transmitting partial data divided from transmission target data to a receiving apparatus through two or more access networks; ;

A quality measurement data priority transmission step of transmitting quality measurement data for determining a network status through a specific access network among the two or more access networks to the receiving apparatus; A state determination step of determining a network state of the specific access network based on a reception state of the quality measurement data in the reception apparatus; And a quality measurement data sequential transmission step of transmitting quality measurement data to the receiving apparatus through the other access network to determine a network status of another access network among the two or more access networks after determining a network status of the specific access network And a control unit.

More specifically, the quality measurement data is transmitted to the receiving device when it is determined that the receiving device is in an idle state, and the number of transmissions of the quality measurement data transmitted in a specific idle state, Is greater than the number of transmission of quality measurement data transmitted in the previous idle state that was transmitted.

According to a fourth aspect of the present invention, there is provided a method of operating a multiple network-based simultaneous transmission receiving apparatus, comprising: receiving partial data divided from transmission target data from a transmitting apparatus via two or more access networks; A quality measurement data reception step of receiving the quality measurement data transmitted from the transmission apparatus via at least one of the two or more connection networks; And a reception state checking step of checking the reception state of the quality measurement data and determining at least one network state among the two or more access networks in the transmission apparatus based on the reception state.

More specifically, the quality measurement data reception step may include: an idle state determination step of determining whether the reception apparatus is in an idle state; Requesting the transmitting apparatus to transmit the quality measurement data when the idle state is determined; And a data reception step of receiving the quality measurement data from the transmission apparatus as a response to the quality measurement data transmission request.

More specifically, in the idle state determination step, it is determined whether or not the idle state is at one point, and when it is determined that the idle state is not the idle state, And the predetermined waiting time is determined to increase sequentially in each repetition period within a threshold time limit.

According to the multi-network simultaneous transmission / reception method and apparatus of the present invention, in an environment for simultaneously transmitting divided data using multiple networks, the network state of each of the multiple networks can be effectively determined, It is possible to determine an optimal data distribution rate between networks.

In addition, it enables efficient operation of the simultaneous transmission service according to the determination of the optimal data distribution rate between networks.

1 is a schematic configuration diagram of a multi-network-based simultaneous transmission service system according to an embodiment of the present invention;
2 is a configuration diagram of a terminal device according to an embodiment of the present invention;
3 is a configuration diagram of a management apparatus according to an embodiment of the present invention;
4 is a view for explaining a waiting time of a timer according to an embodiment of the present invention;
5 and 6 are block diagrams of quality measurement data according to an embodiment of the present invention.
FIG. 7 is a schematic flowchart for explaining an operational flow in a multiple network-based simultaneous transmission service system according to an embodiment of the present invention; FIG.
FIG. 8 is a schematic flowchart illustrating an operation of a terminal according to an embodiment of the present invention; FIG.
FIG. 9 is a schematic flowchart for explaining the operation of the management apparatus according to an embodiment of the present invention; FIG.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a diagram illustrating a multi-network based simultaneous transmission service system according to an embodiment of the present invention.

1, a multi-hop network simultaneous transmission service system according to an embodiment of the present invention includes a terminal device 100, an Internet service, a video providing service, an mVoIP service, and the like A first network device 200 for supporting a first network and a second network device for supporting a second network for connecting the terminal device 100 and the external device 500; And a data service provided between the terminal device 100 and the external device 500 and provided by the external device 500 to the first network device 200 and the second network device 300, And a management device 400 for supporting simultaneous transmission services for providing with all of the network devices 300.

Herein, the terminal device 100 refers to a user device for using a data service provided from the external device 500 and may be a smart phone, a personal computer (PC), a notebook, a tablet PC, a PDA, etc. May include, but is not limited to, all devices capable of transmitting and receiving data through both the first network and the second network.

The first network and the second network may also be networks such as, for example, WCDMA, CDMA, WiBro, WLAN (WiFi) and Long Term Evolution (LTE) May all be included.

In this regard, if the first network is a 3G network, the first network device 200 corresponds to a Gateway GPRS Support Node (GGSN) of the 3G network. Also, if the second network is WiFi, which is one of the local networks, the second network device 300 corresponds to an access point (AP).

In the present embodiment, for convenience of description, the first network will be referred to as a "3G network" and the second network as a "WiFi network".

The management device 400 refers to a server for supporting simultaneous transmission service to the terminal device 100. The management device 400 may be located on a 3G network or a WiFi network or on a network other than the 3G network and the WiFi network And can support the simultaneous transmission service.

The external device 500 refers to a server that transmits and receives data to and from the terminal device 100 through the management device 400. The external device 500 is connected to the terminal device 100 through data transmission and reception through the management device 400, , A portal service, and a content providing service.

According to an embodiment of the present invention, the terminal device 100 and the external device 500 are connected to the first network device 200 and the second network device 300 via the management device 400, Data service can be provided using all of them. Hereinafter, such a data service is referred to as the 'simultaneous transmission service' described above.

Hereinafter, for convenience of explanation, the case where the management apparatus 400 is a transmitting apparatus, that is, a downlink will be described as an example.

In this case, the transmission target data received from the external device 500 is provided to the terminal device 100 via the management device 400 via two or more networks.

Although the data transmission method described below is applicable to the case of the downlink, the case of the uplink providing the data service to the external apparatus 500 via the management apparatus 400 in the terminal apparatus 100 is the same Can be applied.

In the simultaneous transmission service, partial data segmented in one transmission target data is simultaneously transmitted using a plurality of multiple networks.

In other words, the management apparatus 400 identifies multiple networks to which the terminal apparatus 100 is connected, divides the transmission target data transmitted from the external apparatus 500 into partial data based on the data distribution rates between the multiple networks, To the terminal device 100 via the network.

Accordingly, the terminal device 100 receives the partial data received through the multiple networks without any loss, and combines them in accordance with the dividing order, thereby restoring the original data to be transmitted.

In order to provide such a simultaneous transmission service, the management apparatus 400 only needs to check the network status of each of the multiple networks currently connected to the terminal apparatus 100, and based on this, The data distribution rate must be determined.

However, because the location of the actual terminal device 100 is moved by the user, the quality of the network to which the terminal device 100 is connected can not be maintained at anytime and anywhere. Therefore, It is a difficult situation.

If a uniform data distribution rate among multiple networks is applied in a state in which the mobility of the terminal device 100 can not be taken into consideration, the terminal device 100 may not be able to receive a partial data transmission delay due to a change in environment of multiple networks to which the terminal device 100 is connected, Loss occurs, and normal simultaneous transmission service can not be provided.

In order to provide a normal simultaneous transmission service, the network state of the multiple networks to which the terminal device 100 is connected is determined in consideration of the mobility of the terminal device 100, and the data distribution rate among multiple networks is determined by reflecting the determination result It is important to do.

Accordingly, in an embodiment of the present invention, in the simultaneous transmission of partial data segmented from data to be transmitted using multiple networks, in order to determine an optimal data distribution rate applied to partial data segmentation, And will be described in detail below.

The terminal device 100 determines whether the current state of the currently connected network is in the idle state.

More specifically, the terminal device 100 determines whether the current state of the currently connected 3G network and the WiFi network is in an idle state required for network state determination.

To this end, the terminal device 100 operates a timer having a waiting time set for determining the idle state, and confirms whether the current state is idle at the time when the timer becomes 'O'.

Further, the terminal device 100 requests to transmit quality measurement data for determining the network status.

More specifically, when the current state of the terminal device 100 is confirmed as idle, the terminal device 100 requests the management device 400 to transmit the quality measurement data for determining the network status of the 3G network and the WiFi network.

Thus, the management apparatus 400 selects the first quality measurement data for determining the network status of the 3G network.

More specifically, when the quality measurement data transmission request is received from the terminal device 100, the management device 400 first transmits data to the first network device 200 corresponding to the 3G network at a predetermined data distribution rate among the multiple networks For example.

In addition, the management apparatus 400 may transmit first quality measurement data having sequential order information, for example, the first quality measurement data of the order information 1, 2, 3, 4, .

In addition, the management device 400 transmits the selected first quality measurement data to the terminal device 100 via the 3G network.

More specifically, the management apparatus 400 transmits the first quality measurement data having the sequential order information selected for checking the network status of the 3G network to the terminal apparatus 100 via the first network apparatus 200 located in the 3G network. For a set time.

Accordingly, the terminal device 100 receives the first quality measurement data through the 3G network.

More specifically, according to the throughput of the 3G network designated by the management apparatus 400, the terminal apparatus 100 transmits the first quality measurement data having the sequential order information to the first network apparatus 200 for a set time period.

In addition, the terminal apparatus 100 confirms the 3G network transmission rate based on the reception state of the first quality measurement data.

More specifically, the terminal apparatus 100 transmits the total number of transmission of the first quality measurement data transmitted for the determination of the network status of the 3G network from the management apparatus 400 through the header analysis of the first quality measurement data received during the set time And subtracts the number of first quality measurement data received during the set time from the total number of transmitted first quality measurement data to delay reception due to a transmission rate higher than an allowable level according to 3G network characteristics The number of first quality measurement data is confirmed and the transmission rate of the 3G network is confirmed.

Further, the terminal apparatus 100 transmits the calculated transmission rate of the 3G network to the management apparatus 400 to determine the network status.

More specifically, when the set time for determining the network status has elapsed and the first quality measurement data is not identified, the terminal device 100 determines the transmission rate of the 3G network calculated during the set time for determining the network status of the 3G network To the management apparatus 400 so that the data distribution rate set in the 3G network can be variably set.

In this regard, the management apparatus 400 determines the network status of the 3G network based on the transmission rate of the 3G network received from the terminal device 100. [

More specifically, the management apparatus 400 compares the data rate of the 3G network calculated by the terminal device 100 during the set time for determining the network status of the 3G network with the throughput of the 3G network, And determines the network state of the network.

Then, the management apparatus 400 selects the second quality measurement data for determining the network status of the WiFi network.

More specifically, when the determination of the network status of the 3G network is completed, the management apparatus 400 confirms the distribution rate for data transmission to the second network device 200 corresponding to the WiFi network at a predetermined data distribution rate among the multiple networks.

In addition, the management apparatus 400 selects the second quality measurement data of sequential order information, for example, sequence information 5, 6, 7, and 8, in order to determine the network status of the WiFi network according to the identified distribution ratio.

In addition, the management device 400 transmits the selected second quality measurement data to the terminal device 100 via the 3G network.

More specifically, the management apparatus 400 transmits second quality measurement data having sequential order information selected for the network status confirmation of the WiFi network to the terminal apparatus 100 via the second network apparatus 300 located in the WiFi network. For a set time.

Accordingly, the terminal device 100 receives the second quality measurement data through the WiFi network.

More specifically, according to the throughput of the WiFi network specified by the management apparatus 400, the terminal apparatus 100 transmits second quality measurement data having sequential order information to a second network apparatus 300 for a set time.

In addition, the terminal device 100 confirms the WiFi network transmission rate based on the reception state of the second quality measurement data.

More specifically, the terminal device 100 determines the total number of transmission of the second quality measurement data transmitted for the determination of the network status of the WiFi network from the management device 400 through header analysis of the second quality measurement data received during the set time By subtracting the number of pieces of second quality measurement data received during the set time from the total number of transmitted second quality measurement data, thereby obtaining a loss of data due to a transmission rate higher than an allowable level according to the WiFi network characteristic 2 Check the transmission rate of WiFi network by checking the number of quality measurement data.

Further, the terminal device 100 transmits the calculated transmission rate of the WiFi network to the management apparatus 400 to determine the network status.

More specifically, when the set time for determining the network status has elapsed and the second quality measurement data is not identified, the terminal device 100 determines the transmission rate of the WiFi network calculated during the set time for determining the network status of the WiFi network To the management apparatus 400 so that the data distribution rate set in the 3G network can be variably set.

The management apparatus 400 determines the network status of the WiFi network based on the transmission rate of the WiFi network received from the terminal apparatus 100. [

More specifically, the management device 400 compares the transmission rate of the WiFi network calculated by the terminal device 100 during the set time for determining the network status of the WiFi network with the throughput of the WiFi network, And determines the network state of the network.

Then, the management apparatus 400 variably sets a predetermined data distribution rate based on the confirmed network status.

More specifically, the management apparatus 400 determines the number of first quality measurement data to be delayed due to a transmission rate higher than an allowable level according to 3G network characteristics, recognizes the network status of each of the 3G network and the WiFi network based on the number of lost second quality measurement data, and sets a predetermined data distribution rate between the 3G network and the WiFi network by reflecting the detected network status.

Hereinafter, the configuration of the terminal device 100 according to an embodiment of the present invention will be described in more detail with reference to FIG.

That is, the terminal apparatus 100 includes a partial data receiving unit 110 for receiving partial data segmented from transmission target data, a quality measurement data receiving unit 120 for receiving quality measurement data, And a reception status confirmation unit 130. [

In addition to the above-described configuration, the terminal apparatus 100 further includes a idle state determination unit 140 for determining whether the idle state is established, and a quality measurement data requesting unit 130 for requesting transmission of the quality measurement data Lt; / RTI >

Herein, the terminal apparatus including the partial data receiving unit 110, the quality measurement data receiving unit 120, the reception state checking unit 130, the idle state determining unit 140 and the quality measurement data requesting unit 130 100 may be implemented as a software module executed by a processor, or a combination thereof.

The partial data receiving unit 110 receives the divided partial data from the transmission object data through the first network device 200 and the second network device 300. [

More specifically, the partial data receiving unit 110 receives the partial data segmented from the transmission object data from the management apparatus 400 based on the pre-established data distribution rate per access network according to the use of the simultaneous transmission service.

That is, the partial data receiving unit 110 receives the first partial data through the first network device 200 located in the 3G network and receives the second partial data through the second network device 300 located in the WiFi network .

The first partial data and the second partial data are combined with each other and restored to the original transmission target data requested to be delivered from the external device 500.

The idle state determination unit 140 determines whether the current state of the currently connected network is idle.

More specifically, the idle state determiner 140 determines whether the current state of the currently connected 3G network and the WiFi network is in an idle state required for network state determination.

Here, the idle state refers to an idle state in which partial data is not received from the management apparatus 400 over the network, or data traffic is not generated through connection with another device other than the reception of the partial data.

The above-described idle state is required for an accurate measurement of the throughput of the reliable network in the network state judgment process.

To this end, the idle state determination unit 140 sets a timer for idle state determination to check the idle state determination time.

More specifically, the idle state determiner 140 operates the timer T ₁ for which the basic wait time for determining the idle state is set, and at the time when the timer T ₁ becomes 'O' Is in an idle state.

In this case, the idle state determining unit 140 is not the current state of the 3G network and the WiFi network is idle, and operating a timer (T ₂₎ the restart wait time set for idle make retry, the timer (T ₂₎ Is 'O', it is confirmed once again whether the current state is idle.

If the idle state determination unit 140 determines that the current state is not the idle state even when the idle state is determined, that is, when the timer T ₂ becomes 'O', the idle state determination unit 140 determines The timer T ₂ is repeatedly operated to check the idle state at the time when the corresponding timers become '0'.

Here, as shown in FIG. 4, the restart waiting time set in the timer T ₂ increases as the number of times of the idle state check retries increases. This is because the terminal device 100 In order to minimize battery consumption.

As described above, the restart waiting time set in the timer T ₂ is increased (for example, 10 sec-20 sec-30 sec-40 sec) as the number of times of retrying the idle state confirmation increases, but the waiting time is increased infinitely (40 sec) of the restart waiting time is designated and managed.

If the idle state confirmation retry is required even after the increase in the restart wait time is set as the critical time, the restart wait time is repeatedly set as the threshold time.

The quality measurement data requesting unit 130 requests to transmit quality measurement data for determining the network status.

More specifically, the quality measurement data requesting unit 130 requests the management apparatus 400 to transmit the quality measurement data for determining the network status of the 3G network and the WiFi network when the current status is determined to be idle.

At this time, the quality measurement data requesting unit 130 requests quality measurement data transmission for both the 3G network and the WiFi network through only one network of the 3G network or the WiFi network, or transmits the quality measurement data to the corresponding network via the 3G network and the WiFi network Each of which can request quality measurement data transmission.

Thus, the quality measurement data receiving unit 120 receives the first quality measurement data through the 3G network.

More specifically, the quality measurement data requesting unit 130 transmits the first quality measurement data having the sequential order information to the first (first) quality measurement data located in the 3G network according to the throughput of the 3G network designated by the management apparatus 400 And is received during the set time through the network device 200.

Here, the management apparatus 400 selects the first quality measurement data having the sequential order information selected for checking the network status of the 3G network, and transmits the selected first quality measurement data to the terminal apparatus 100 through the first network apparatus 200 located in the 3G network. For a set time.

In this regard, the reception status confirmation unit 130 confirms the 3G network transmission rate based on the reception status of the first quality measurement data.

More specifically, the reception status verifying unit 130 confirms the transmission rate during the set time for determining the network status of the 3G network by checking the number of the first quality measurement data received during the set time.

At this time, the reception status verifying unit 130 confirms the total transmission number of the first quality measurement data transmitted from the management device 400 for determining the network status of the 3G network through the header analysis of the received first quality measurement data A first quality that is delayed due to a transmission rate higher than an allowable level according to 3G network characteristics by subtracting the number of first quality measurement data received during the set time from the total number of transmitted first quality measurement data, Check the number of measurement data and check the transmission rate of 3G network.

In other words, the reception state checking unit 130 subtracts the number of first quality measurement data delayed in reception from the total number of transmission of the first quality measurement data transmitted for determination of the network status, It is possible to confirm the transmission rate during the set time for determining the network status of the 3G network corresponding to the number of the first quality measurement data received during the set time.

In addition, the reception status confirmation unit 130 transmits the calculated transmission rate of the 3G network to the management apparatus 400 to determine the network status.

More specifically, if the first quality measurement data is not identified after the set time for determining the network status has elapsed, the reception status verifying unit 130 determines whether the 3G network < RTI ID = 0.0 > To the management apparatus 400 so that the data distribution rate set in the 3G network can be variably set.

At this time, as shown in FIG. 6, the reception state checking unit 130 inserts the data rate (①) of the 3G network calculated on the header of the packet transmitted to the management apparatus 400 and transmits the data.

Then, the quality measurement data receiving unit 120 receives the second quality measurement data through the WiFi network.

More specifically, the quality measurement data receiving unit 120, when the network status determination of the 3G network is completed in the management apparatus 400, according to the throughput of the WiFi network designated by the management apparatus 400, To the second network device 300 located in the WiFi network for a set time period.

Here, the management apparatus 400 transmits the second quality measurement data having the sequential order information selected for the network status confirmation of the WiFi network to the management apparatus 400 via the second network apparatus 300 located in the WiFi network, To the device 100 for the set time.

Accordingly, the reception state confirmation unit 130 confirms the WiFi network transmission rate based on the reception state of the second quality measurement data.

More specifically, the reception status confirmation unit 130 confirms the transmission rate during the set time for determining the network status of the WiFi network by checking the number of the second quality measurement data received during the set time.

At this time, the reception status verifying unit 130 confirms the total transmission number of the second quality measurement data transmitted from the management device 400 for determining the network status of the WiFi network through header analysis of the received second quality measurement data A second quality measurement that is lost due to a transmission rate higher than an allowable level according to the WiFi network characteristic by subtracting the number of second quality measurement data received during the set time from the total number of transmitted second quality measurement data, Check the number of data to check the transmission rate of the WiFi network.

In other words, the reception state checking unit 130 subtracts the number of second quality measurement data delayed in reception from the total number of transmission of the second quality measurement data transmitted for determination of the network status, It is possible to confirm the transmission rate during the set time for determining the network status of the WiFi network corresponding to the number of second quality measurement data received during the set time based on the number of second quality measurement data.

Further, the reception status confirmation unit 130 transmits the calculated transmission rate of the WiFi network to the management apparatus 400 to determine the network status.

More specifically, if the second quality measurement data is not identified because the set time for determining the network status has elapsed and the second quality measurement data is not identified, the reception state checking unit 130 determines whether the WiFi network To the management apparatus 400 so that the data distribution rate set in the 3G network can be variably set.

At this time, as shown in FIG. 6, the reception status verifying unit 130 inserts the data rate (②) of the WiFi network calculated on the header of the packet transmitted to the management apparatus 400 and transmits the data.

The reception status checking unit 130 may be configured to not only transmit the 3G rate of the 3G network and the transmission rate of the WiFi network separately but also transmit the 3G rate of the 3G network calculated on the header of the packet transmitted to the management apparatus 400 ①), and the transmission rate of the WiFi network (②) can be inserted and transmitted at once.

Hereinafter, the configuration of the management apparatus 400 according to an embodiment of the present invention will be described in more detail with reference to FIG.

That is, the management apparatus 400 includes a partial data transmission unit 410 for transmitting partial data segmented from transmission target data, a quality measurement data transmission unit 420 for transmitting quality measurement data, And a status determination unit 430 for determining the status of the network based on the status.

Here, each configuration of the management apparatus 400 including the partial data transfer unit 410, the quality measurement data transfer unit 420, and the status determination unit 430 may be implemented by a software module executed by a processor , Or a combination thereof.

The partial data transmission unit 410 transmits the partial data segmented from the transmission object data to the terminal device 100 through the first network device 200 and the second network device 300.

Particularly, the partial data transmission unit 410 transmits the partial data segmented from the transmission object data received from the external device 500 based on the pre-established data distribution rate per access network according to the simultaneous transmission service use of the terminal apparatus 100 To the terminal device 100 at the same time.

At this time, the partial data transmission unit 410 transmits the first partial data to the terminal device 100 through the first network device 200 located in the 3G network, and transmits the first partial data to the second network device 300 located in the WiFi network, And transmits the second partial data to the terminal device 100 at the same time.

The first partial data and the second partial data are combined with each other by the terminal device 100 and restored to the original transmission target data requested to be delivered from the external device 500.

The quality measurement data transmission unit 420 selects the first quality measurement data for determining the network status of the 3G network.

More specifically, when the quality measurement data transmission request is received from the terminal device 100, the quality measurement data transmission unit 420 first transmits the quality measurement data to the first network device 200 corresponding to the 3G network at a predetermined data sharing rate among the multiple networks. Lt; RTI ID = 0.0 > data transfer rate. ≪ / RTI >

Here, the terminal device 100 operates the timer having the waiting time set for the idle state determination, and when the current state is determined to be idle at the time when the timer becomes 'O', the terminal device 100 determines the network status of the 3G network and the WiFi network And sends the quality measurement data to the management apparatus 400. [

In addition, the quality measurement data transmission unit 420 selects first quality measurement data having sequential order information, for example, sequence information 1, 2, 3 and 4, to check the network status of the 3G network do.

In this case, the quality measurement data transmission unit 420 may transmit the quality measurement data to the 3G network in which the terminal apparatus 100 is connected by the initial operation of the terminal apparatus 100, for example, when the power is applied (On) The first quality measurement data is selected according to the determined distribution ratio.

Meanwhile, when there is a history in which the terminal device 100 transmits the first quality measurement data through the 3G network currently connected to the terminal device 100 in the idle state of the terminal device 100, The first quality measurement data can be transmitted at a higher throughput than before by selecting a larger number of first quality measurement data than the number of transmissions of the first quality measurement data transmitted at.

This is to more accurately determine the network state by intentionally increasing the number of first quality measurement data that is delayed due to a transmission rate higher than an allowable level according to 3G network characteristics.

In addition, the quality measurement data transmission unit 420 transmits the selected first quality measurement data to the terminal device 100 via the 3G network.

More specifically, the quality measurement data transmission unit 420 transmits the first quality measurement data having the sequential order information selected for checking the network status of the 3G network to the terminal apparatus 200 through the first network apparatus 200 located in the 3G network, (100) for a set time.

5, the quality measurement data transmission unit 420 may include type information (e.g., 3G = O; 1) for identifying the 3G network on the header of the first quality measurement data packet, (Throughput (2)) of the quality measurement data transmitted to the mobile station, and the transmitted number of pieces of quality measurement data (3).

In the case of the above-described first quality measurement data and second quality measurement data to be referred to below, the transmitting side and the receiving side can perform a one-sided And a UDP (User Datagram Protocol) method, which is a communication protocol designed to prevent receipt of acknowledgment from the receiver on the transmitted data, is applied.

The state determination unit 430 determines the network state of the 3G network based on the transmission rate of the 3G network received from the terminal device 100. [

More specifically, the state determination unit 430 compares the data rate of the 3G network calculated by the terminal device 100 during the set time for determining the network status of the 3G network with the throughput of the pre-stored 3G network, And determines the network status of the 3G network.

At this time, the state determiner 430 checks the total number of transmission of the first quality measurement data, and transmits the first quality measurement data received from the terminal device 100 for the set time period as the total number of transmitted first quality measurement data It is possible to confirm the number of first quality measurement data that is delayed due to a transmission rate higher than an allowable level according to the 3G network characteristic.

In this regard, when the set time for determining the network status has elapsed and the first quality measurement data is not identified, the terminal device 100 transmits the first quality measurement The transmission rate of the 3G network is confirmed based on the data, and the transmission rate is transmitted to the management apparatus 400 so that the data distribution rate set in the 3G network can be variably set.

Further, the quality measurement data transmission unit 420 selects the second quality measurement data for determining the network status of the WiFi network.

More specifically, the quality measurement data transmission unit 420 may determine a distribution rate for data transmission to the second network device 200 corresponding to the WiFi network at a predetermined data distribution rate among multiple networks, when the network status determination of the 3G network is completed Check.

In addition, the quality measurement data transmission unit 420 selects the second quality measurement data of sequential order information, for example, sequence information 5, 6, 7 and 8, in order to determine the network status of the WiFi network according to the identified distribution ratio.

At this time, the quality measurement data transmission unit 420 transmits the quality measurement data to the WiFi network 100 connected to the terminal 100 by the initial operation of the terminal apparatus 100, for example, power is turned on or released from the airplane mode, The second quality measurement data is selected according to the determined distribution ratio.

Meanwhile, if there is a history in which the terminal device 100 transmits the second quality measurement data through the WiFi network currently connected to the terminal device 100 in the previous idle state, The second quality measurement data can be transmitted at a higher throughput than before by selecting a larger number of second quality measurement data than the number of transmissions of the first quality measurement data transmitted in the second quality measurement data.

This is to more accurately determine the network state by intentionally increasing the number of second quality measurement data that is lost due to a transmission rate higher than an allowable level according to the characteristics of the WiFi network.

In addition, the quality measurement data transmission unit 420 transmits the selected second quality measurement data to the terminal device 100 via the 3G network.

More specifically, the quality measurement data transmission unit 420 transmits the second quality measurement data having the sequential order information selected for confirming the network status of the WiFi network to the terminal apparatus 300 via the second network apparatus 300 located in the WiFi network, (100) for a set time.

At this time, as shown in FIG. 6, the quality measurement data transmission unit 420 transmits type information (e.g., WiFi) for identifying the WiFi network on the header of the second quality measurement data packet on the header of the first quality measurement data packet = 1; 1), a transmission rate (throughput) of quality measurement data transmitted for determining a network status, and a transmitted number of pieces of quality measurement data (3).

Then, the state determination unit 430 determines the network state of the WiFi network based on the transmission rate of the WiFi network received from the terminal device 100.

More specifically, the state determiner 430 compares the transmission rate of the WiFi network calculated by the terminal device 100 during the setup time for determining the network status of the WiFi network with the throughput of the WiFi network, Determine the network status of the WiFi network.

At this time, the status determiner 430 checks the total number of transmission of the second quality measurement data transmitted for determining the network status of the WiFi network, and transmits the total number of transmitted second quality measurement data to the terminal device The number of second quality measurement data that is lost due to a transmission rate higher than an allowable level according to the WiFi network characteristic can be confirmed by subtracting the number of second quality measurement data received from the second quality measurement data.

In this regard, when the set time for determining the network status has elapsed, and the second quality measurement data is not identified, the terminal device 100 transmits the first quality measurement received during the set time for determining the network status of the WiFi network The data transfer rate set in the WiFi network can be variably set by confirming the transfer rate of the WiFi network on the basis of the data and delivering it to the management apparatus 400. [

Further, the state determination unit 430 variably sets a predetermined data distribution rate based on the checked network state.

More specifically, the state determiner 430 determines the number of first quality measurement data that is delayed due to a transmission rate higher than an allowable level according to 3G network characteristics and a transmission rate higher than an allowable level according to a WiFi network characteristic Recognizes the network status of each of the 3G network and the WiFi network based on the number of lost second quality measurement data and sets a predetermined data distribution rate between the 3G network and the WiFi network by reflecting the detected network status .

As described above, according to the multi-network-based data concurrent transmission service system according to the present invention, partial data segmented from transmission target data is transmitted / received using a plurality of multiple networks based on a data distribution rate among multiple networks Transmitting quality measurement data of UDP (User Datagram Protocol) type for a set time period through each of the access networks in the transmission service environment, and transmitting the quality of each access network on the basis of the number of quality measurement data received during the setup time for each access network The performance of the simultaneous transmission service can be improved by setting a predetermined data distribution rate for each access network based on the confirmed access network quality. In addition, UDP packets with higher processing speed than TCP (Transmission Control Protocol) are used to determine the network status of the access network, thereby minimizing the increase in traffic of the entire network when checking the quality of the access network. In addition, reliability of the determination result can be improved by determining the state of the network only in the idle state of the terminal device 100. [

Hereinafter, a multi-network-based simultaneous transmission service method according to an embodiment of the present invention will be described with reference to FIG. 7 to FIG. Here, for convenience of description, the components shown in FIGS. 1 to 6 will be described with reference to corresponding reference numerals.

First, referring to FIG. 7, a description will be made of an operational flow in a multiple network-based simultaneous transmission service system according to an embodiment of the present invention.

First, the terminal device 100 determines whether the current state of the currently connected 3G network and the WiFi network is idle (step S110).

To this end, the terminal device 100 sets a timer for determining the idle state to check the idle state determination time.

More specifically, the terminal device 100 operates a timer having a standby time set to determine an idle state, and confirms whether the current state is idle at the time when the timer becomes 'O', as described above.

Then, when the current state of the terminal device 100 is determined to be idle, the terminal device 100 requests the management device 400 to transmit the quality measurement data for determining the network status of the 3G network and the WiFi network (S120).

When the quality measurement data transmission request is received from the terminal device 100, the management device 400 firstly transmits the quality measurement data to the first network device 200 corresponding to the 3G network at a predetermined data sharing rate among the multiple networks. The first quality measurement data having sequential order information, for example, the order information 1, 2, 3, and 4, is selected in order to confirm the network status of the 3G network according to the distribution ratio (S130).

Then, the management apparatus 400 transmits the first quality measurement data having the sequential order information selected for the network status check of the 3G network to the terminal apparatus 100 via the first network apparatus 200 located in the 3G network For the set time (S140).

Accordingly, the terminal device 100 confirms the total number of transmission of the first quality measurement data transmitted for the determination of the network status of the 3G network from the management device 400 through header analysis of the first quality measurement data received during the set time And the number of first quality measurement data received during the set time is subtracted from the total number of transmitted first quality measurement data, The number of quality measurement data is confirmed and the transmission rate of the 3G network is confirmed (S150 - S160).

Then, when the set time for determining the network status has passed and the first quality measurement data is not identified, the terminal device 100 determines the transmission rate of the 3G network calculated during the set time for determining the network status of the 3G network To the management apparatus 400 so that the data sharing rate set in the 3G network can be variably set (S170).

Accordingly, the management apparatus 400 compares the data rate of the 3G network calculated in the terminal device 100 during the set time for determining the network status of the 3G network with the throughput of the 3G network stored in advance, The network status is determined (S180).

Then, when the determination of the network status of the 3G network is completed, the management device 400 determines whether the WiFi network is connected to the second network device 200 according to the distribution rate for data transmission to the second network device 200 corresponding to the WiFi network at a pre- In order to determine the network status, the second quality measurement data of sequential order information, for example, order information 5, 6, 7, and 8, is selected (S190).

Then, the management apparatus 400 transmits the second quality measurement data having the sequential order information selected for confirming the network status of the WiFi network to the terminal apparatus 100 through the second network apparatus 300 located in the WiFi network For the set time (S200).

Accordingly, the terminal device 100 confirms the total transmission number of the second quality measurement data transmitted for the determination of the network status of the WiFi network from the management device 400 through header analysis of the second quality measurement data received during the set time And the number of second quality measurement data received during the set time is subtracted from the total number of transmitted second quality measurement data to determine a second quality that is lost due to a transmission rate higher than an allowable level according to the WiFi network characteristic The number of measured data is confirmed and the transmission rate of the WiFi network is confirmed (S210 - S220).

Further, when the set time for determining the network status has elapsed and the second quality measurement data is not identified, the terminal device 100 manages the transmission rate of the WiFi network calculated during the set time for determining the network status of the WiFi network To the device 400 so that the data sharing rate set in the 3G network can be variably set (S230).

The management device 400 compares the transmission rate of the WiFi network calculated by the terminal device 100 during the set time for determining the network status of the WiFi network with the throughput of the WiFi network, The network status is determined (S240).

Thereafter, the management device 400 determines the number of first quality measurement data to be delayed due to the transmission rate higher than the allowable level according to the 3G network characteristic and the loss rate due to the transmission rate higher than the allowable level according to the WiFi network characteristic ) Of the 3G network and the WiFi network based on the number of the second quality measurement data (S250), and sets a preset data distribution rate between the 3G network and the WiFi network by reflecting the recognized network status (S250) .

Hereinafter, an operation method of the terminal device 100 according to an embodiment of the present invention will be described in detail with reference to FIG.

First, the idle state determiner 140 operates the timer T ₁ for which the basic waiting time for determining the idle state is set, and when the timer T ₁ becomes 'O', the current state is idle (S310 - S340).

At this time, when the current state of the 3G network and the WiFi network is not idle, the idle state determiner 140 operates a timer T ₂ for which a restart waiting time for idle state retry is set, and a timer T ₂ (S340, S350-S360) when the current state becomes 'O'.

Here, if the idle state determination unit 140 determines that the current state is not idle at the time of idle state determination, that is, when the timer T ₂ becomes 'O', the idle state determination unit 140 determines The timer T ₂ is repeatedly operated to check the idle state at the time when the corresponding timers become '0'.

At this time, the quality measurement data requesting unit 130 requests the management apparatus 400 to transmit the quality measurement data for determining the network status of the 3G network and the WiFi network (S370).

The quality measurement data receiving unit 120 receives the first quality measurement data having the sequential order information from the first network device (hereinafter, referred to as " first quality measurement data ") located in the 3G network according to the throughput of the 3G network designated by the management apparatus 400 200) for a set time (S380).

In this regard, the reception status verifying unit 130 receives from the management device 400 through the header analysis of the received first quality measurement data a total transmission number of the first quality measurement data transmitted for determining the network status of the 3G network And the number of first quality measurement data received during the set time is subtracted from the total number of transmitted first quality measurement data to determine whether or not the first quality measurement data is delayed due to a transmission rate higher than an allowable level according to 3G network characteristics 1 quality measurement data to confirm the transmission rate of the 3G network (S390-S410, S430).

In other words, the reception state checking unit 130 subtracts the number of first quality measurement data delayed in reception from the total number of transmission of the first quality measurement data transmitted for determination of the network status, It is possible to confirm the transmission rate during the set time for determining the network status of the 3G network corresponding to the number of the first quality measurement data received during the set time.

In addition, if the first quality measurement data is not identified after the set time for determining the network status has elapsed, the reception status verifying unit 130 confirms that the setting for determining the network status of the 3G network The data rate of the 3G network calculated during the time is transmitted to the management apparatus 400 so that the data distribution rate set in the 3G network can be variably set (S440).

At this time, as shown in FIG. 6, the reception state checking unit 130 inserts the data rate (①) of the 3G network calculated on the header of the packet transmitted to the management apparatus 400 and transmits the data.

On the other hand, when the management apparatus 400 determines that the network status of the 3G network has been completed, the quality measurement data receiving unit 120 may receive the quality measurement data from the management apparatus 400 in accordance with the throughput of the WiFi network designated by the management apparatus 400, The second quality measurement data is received for the set time through the second network device 300 located in the WiFi network (S380).

The reception status verifying unit 130 receives the total transmission number of the second quality measurement data transmitted from the management apparatus 400 for determining the network status of the WiFi network through header analysis of the second quality measurement data received during the set time By subtracting the number of pieces of second quality measurement data received during the set time from the total number of transmitted second quality measurement data, thereby obtaining a loss of data due to a transmission rate higher than an allowable level according to the WiFi network characteristic 2 quality measurement data to confirm the transmission rate of the WiFi network (S390-S400, S420).

In other words, the reception state checking unit 130 subtracts the number of second quality measurement data delayed in reception from the total number of transmission of the second quality measurement data transmitted for determination of the network status, It is possible to confirm the transmission rate during the set time for determining the network status of the WiFi network corresponding to the number of second quality measurement data received during the set time based on the number of second quality measurement data.

In addition, if the second quality measurement data is not identified after the set time for determining the network status has elapsed, the reception status verifying unit 130 determines the transmission rate of the WiFi network calculated during the set time for determining the network status of the WiFi network To the management apparatus 400 so that the data sharing rate set in the 3G network can be variably set (S440).

At this time, as shown in FIG. 6, the reception status verifying unit 130 inserts the data rate (②) of the WiFi network calculated on the header of the packet transmitted to the management apparatus 400 and transmits the data.

Meanwhile, when the idle state determiner 120 transmits both the 3G rate of the 3G network and the transmission rate of the WiFi network to the management apparatus 400, the idle state determiner 120 initializes a timer having a waiting time for determining the idle state (S450-S460).

Hereinafter, an operation method of the management apparatus 400 according to an embodiment of the present invention will be described in detail with reference to FIG.

First, when a quality measurement data transmission request is received from the terminal device 100, the quality measurement data transmission unit 420 transmits data to the first network device 200 corresponding to the 3G network at a predetermined data distribution rate among multiple networks, The distribution rate for transmission is confirmed (S510 - S520).

In addition, the quality measurement data transmission unit 420 may transmit the first quality measurement data having the sequential order information, for example, the first quality of the sequence information 1, 2, 3 and 4, in order to confirm the network status of the 3G network according to the identified distribution ratio Measurement data is selected.

In this case, the quality measurement data transmission unit 420 may transmit the quality measurement data to the 3G network in which the terminal apparatus 100 is connected by the initial operation of the terminal apparatus 100, for example, when the power is applied (On) The first quality measurement data is selected according to the determined distribution ratio.

Meanwhile, when there is a history in which the terminal device 100 transmits the first quality measurement data through the 3G network currently connected to the terminal device 100 in the idle state of the terminal device 100, The first quality measurement data can be transmitted at a higher throughput than before by selecting a larger number of first quality measurement data than the number of transmissions of the first quality measurement data transmitted at.

The quality measurement data transmission unit 420 transmits the first quality measurement data having the sequential order information selected for checking the network status of the 3G network to the terminal apparatus 100 (100) via the first network apparatus 200 located in the 3G network, ) For a set time.

5, the quality measurement data transmission unit 420 may include type information (e.g., 3G = O; 1) for identifying the 3G network on the header of the first quality measurement data packet, (Throughput (2)) of the quality measurement data transmitted to the mobile station, and the transmitted number of pieces of quality measurement data (3).

In this regard, the state determiner 430 compares the rate of the 3G network calculated by the terminal device 100 during the set time for determining the network status of the 3G network with the throughput of the pre-stored 3G network, The network status of the 3G network is determined (S540).

At this time, the state determiner 430 checks the total number of transmission of the first quality measurement data, and transmits the first quality measurement data received from the terminal device 100 for the set time period as the total number of transmitted first quality measurement data It is possible to confirm the number of first quality measurement data that is delayed due to a transmission rate higher than an allowable level according to the 3G network characteristic.

When the determination of the network state of the 3G network is completed, the quality measurement data transmission unit 420 confirms the distribution rate for data transmission to the second network device 200 corresponding to the WiFi network at a predetermined data distribution rate among the multiple networks (S550-S560).

In addition, the quality measurement data transmission unit 420 selects the second quality measurement data of sequential order information, for example, sequence information 5, 6, 7 and 8, in order to determine the network status of the WiFi network according to the identified distribution ratio.

At this time, the quality measurement data transmission unit 420 transmits the quality measurement data to the WiFi network 100 connected to the terminal 100 by the initial operation of the terminal apparatus 100, for example, power is turned on or released from the airplane mode, The second quality measurement data is selected according to the determined distribution ratio.

Meanwhile, if there is a history in which the terminal device 100 transmits the second quality measurement data through the WiFi network currently connected to the terminal device 100 in the previous idle state, The second quality measurement data can be transmitted at a higher throughput than before by selecting a larger number of second quality measurement data than the number of transmissions of the first quality measurement data transmitted in the second quality measurement data.

The quality measurement data transmission unit 420 transmits the second quality measurement data having the sequential order information selected for confirming the network status of the WiFi network to the terminal apparatus 100 through the second network apparatus 300 located in the WiFi network ) For a set time.

At this time, as shown in FIG. 6, the quality measurement data transmission unit 420 transmits type information (e.g., WiFi) for identifying the WiFi network on the header of the second quality measurement data packet on the header of the first quality measurement data packet = 1; 1), a transmission rate (throughput) of quality measurement data transmitted for determining a network status, and a transmitted number of pieces of quality measurement data (3).

In this regard, the state determiner 430 compares the transmission rate of the WiFi network calculated by the terminal device 100 during the setup time for determining the network status of the WiFi network with the throughput of the WiFi network, The network status of the WiFi network is determined (S580).

At this time, the status determiner 430 checks the total number of transmission of the second quality measurement data transmitted for determining the network status of the WiFi network, and transmits the total number of transmitted second quality measurement data to the terminal device The number of second quality measurement data that is lost due to a transmission rate higher than an allowable level according to the WiFi network characteristic can be confirmed by subtracting the number of second quality measurement data received from the second quality measurement data.

Further, the state determiner 430 may determine the number of first quality measurement data to be delayed due to a transmission rate higher than an allowable level according to 3G network characteristics, loss of the second quality measurement data, and determines a predetermined data distribution rate between the 3G network and the WiFi network by reflecting the recognized network status (S590 ).

As described above, according to the multi-network-based data concurrent transmission service method according to the present invention, partial data segmented from transmission target data is transmitted / received using a plurality of multiple networks based on the data distribution rate among multiple networks Transmitting quality measurement data of UDP (User Datagram Protocol) type for a set time period through each of the access networks in the transmission service environment, and transmitting the quality of each access network on the basis of the number of quality measurement data received during the setup time for each access network The performance of the simultaneous transmission service can be improved by setting a predetermined data distribution rate for each access network based on the confirmed access network quality. In addition, UDP packets with higher processing speed than TCP (Transmission Control Protocol) are used to determine the network status of the access network, thereby minimizing the increase in traffic of the entire network when checking the quality of the access network. In addition, reliability of the determination result can be improved by determining the state of the network only in the idle state of the terminal device 100. [

Meanwhile, the steps of a method or algorithm described in connection with the embodiments disclosed herein may be embodied directly in hardware, in a software module executed by a processor, or in a combination of both. A software module may reside in a RAM memory, a flash memory, a ROM memory, an EPROM memory, an EEPROM memory, registers, a hard disk, a removable disk, a CD-ROM, or any other form of storage medium known in the art. An exemplary storage medium is coupled to the processor such that the processor can read information from, and write information to, the storage medium. Alternatively, the storage medium may be integrated into the processor. The processor and the storage medium may be included within an ASIC. The ASIC may be included in the user terminal device. In the alternative, the processor and the storage medium may be included as separate components within the user terminal device.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

According to the multiple network-based simultaneous transmission / reception method and apparatus applied thereto, a single transmission mode for transmitting data through one network and a simultaneous transmission mode for simultaneous transmission over two or more networks can be selectively applied It is an invention that is industrially applicable since it is not only the use of related technology but also the possibility of commercialization or operation of the applied device as well as the practical use of the device.

100: terminal device
110: partial data reception unit 120: idle state determination unit
130: Quality measurement data requesting unit 140: Quality measurement data receiving unit
150: Reception status confirmation unit
200: first network device
300: second network device
400: management device
410: partial data transmission unit 420: quality measurement data transmission unit
430:
500: External device

Claims (10)

A partial data transmission unit for transmitting partial data segmented from transmission target data to a receiving apparatus through two or more access networks;
A status determination unit for determining at least one network status among the two or more access networks based on a reception status of the reception apparatus for quality measurement data transmitted through at least one access network among the two or more access networks; And
The quality measurement data is transmitted through a specific one of the two or more access networks, and when the status determiner completes the network status determination for the specific access network based on the reception status of the quality measurement data, And a quality measurement data transmission unit for transmitting the quality measurement data through an access network other than the specific access network among the access networks. The method according to claim 1,
Wherein the quality measurement data transmission unit comprises:
Transmit the quality measurement data when it is determined that the receiving apparatus is in an idle state,
The number of transmissions of the quality measurement data transmitted in a specific idle state,
Wherein the number of transmitted quality measurement data is greater than the number of transmitted quality measurement data that has been transmitted in the idle state identified at a previous time than the specific idle state. A partial data receiving unit for receiving the partial data segmented from the transmission target data from the transmission apparatus through two or more access networks;
A quality measurement data receiver for receiving quality measurement data transmitted from the transmission apparatus through at least one of the two or more access networks; And
And a reception status verifying unit for verifying a reception status of the quality measurement data and determining at least one network status among the two or more access networks in the transmission apparatus based on the reception status. Transmission receiving apparatus. The method of claim 3,
The receiving apparatus includes:
An idle state determiner for determining whether the receiver is in an idle state; And
And a quality measurement data requesting unit for requesting the transmission apparatus to transmit the quality measurement data when it is determined that the idle state is established. 5. The method of claim 4,
The idle state determination unit may determine,
If the idle state is not the idle state, it is determined that the idle state is determined to be idle at another point in time after the elapse of the predetermined idle time,
Wherein the predetermined wait time is determined to increase sequentially in each repetition period within a threshold time limit. A partial data transmission step of transmitting partial data segmented from transmission target data to a reception device through two or more access networks;
A quality measurement data priority transmission step of transmitting quality measurement data for determining a network status through a specific access network among the two or more access networks to the receiving apparatus;
A state determination step of determining a network state of the specific access network based on a reception state of the quality measurement data in the reception apparatus; And
And a quality measurement data sequential transmission step of determining the state of the other access network by transmitting the quality measurement data to the reception apparatus through another access network among the two or more access networks after determining the network status of the specific access network Wherein the method comprises the steps of: The method according to claim 6,
Wherein the quality measurement data comprises:
When the receiving apparatus is determined to be in an idle state,
The number of transmissions of the quality measurement data transmitted in a specific idle state,
Wherein the number of transmitted quality measurement data is greater than the number of quality measurement data transmissions that were transmitted in the idle state identified prior to the specific idle state. A partial data receiving step of receiving partial data segmented from transmission target data from a transmission device via two or more access networks;
A quality measurement data reception step of receiving quality measurement data transmitted from the transmission apparatus through at least one connection network among the two or more connection networks; And
And a reception state checking step of checking the reception state of the quality measurement data and determining at least one network state among the two or more access networks in the transmission apparatus based on the reception state. A method of operating a simultaneous transmission receiving apparatus. 9. The method of claim 8,
The quality measurement data receiving step includes:
An idle state determination step of determining whether the reception apparatus is in an idle state;
Requesting the transmitting apparatus to transmit the quality measurement data when the idle state is determined; And
And a data reception step of receiving the quality measurement data from the transmission apparatus as a response to the quality measurement data transmission request. 10. The method of claim 9,
The idle state determination step may include:
If it is not idle, it is determined whether it is idle at another point in time after the lapse of a certain waiting time until the idle state is determined
Wherein the predetermined waiting time is determined to increase sequentially in each repetition period within a threshold time limit.

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