KR101353438B1 - Apparatus and method for simultaneously transmitting data in heterogeneous network - Google Patents

Abstract

The present invention discloses a method for simultaneously transmitting heterogeneous network-based data. That is, a data transmission step of simultaneously transmitting the selected partial data divided by the transmission target data to the receiving device through two or more access networks; A data duplication transmission step of selecting one or more specific partial data from the partial data and simultaneously transmitting the same to the two or more access networks; And a status determination step of determining a network state for each of the two or more access networks based on the reception state of the one or more specific partial data in each of the two or more access networks, thereby ensuring transmission performance of the simultaneous transmission service. Can be improved.

Description

TECHNICAL FIELD [0001] The present invention relates to a heterogeneous network-based data transmission method and a device applied thereto. [0002]

The present invention relates to a simultaneous data transmission scheme using heterogeneous networks, and more particularly, to transmit / receive partial data divided from data to be transmitted using a plurality of heterogeneous networks based on a data transmission rate for each access network. In the simultaneous transmission service environment, the quality of each access network is measured based on the reception status of each access network for the same partial data transmitted redundantly through each access network for a set time, and based on the measured access network quality. The present invention relates to a heterogeneous network-based data transmission method for varying a set data transmission rate, an apparatus applied thereto, and an operation method thereof.

Recently, operators often provide services based on multiple wireless technologies at the same time. In Korea, major operators are building and servicing networks by introducing WCDMA, CDMA, WiBro and WLAN (WiFi) technology, which is the nearest wireless network. In addition, LTE (Long Term Evolution) network is actively being introduced recently.

In the heterogeneous network environment in which a plurality of networks are mixed, a current method of using a data service through a terminal device is a network selection method by directly changing a terminal device user, and a method in which controllability of a provider is excluded This is a passive approach when considering the position of the business operator.

Meanwhile, as various wireless devices such as smartphones and tablet PCs are increasing and data rates are becoming cheaper, and at the same time, various large-capacity data services are increasing, the network load ratio of operators is rapidly rising, It is a threat from the side.

Accordingly, in a heterogeneous network environment where a plurality of networks are mixed, a new service scheme for efficiently selecting a network of a terminal device according to the state of the network and efficiently using the selected network is desired.

The present invention was created in view of the above circumstances, and an object of the present invention is to transmit / receive partial data divided from data to be transmitted using a plurality of heterogeneous networks based on a data transmission rate for each access network. In the receiving simultaneous transmission service environment, the quality of each access network is measured based on the reception status of each access network for the same partial data that is duplicated and transmitted through each access network for a set time, and based on the measured access network quality. By varying the preset data transmission rate, the performance of the simultaneous transmission service is improved.

The heterogeneous network-based simultaneous data transmission apparatus according to the first aspect of the present invention for achieving the above object comprises: a communication unit for simultaneously transmitting the selected partial data divided by the transmission target data to the receiving apparatus through two or more access networks; And selecting one or more specific partial data from the partial data to be simultaneously transmitted to both of the two or more access networks, and based on a reception state of the one or more specific partial data in each of the two or more access networks. It characterized in that it comprises a transmission control unit for determining the network state for each network.

Preferably, the transmission control unit is configured to variably set the partial data transmission rate for each of the two or more access networks according to the network state, or not to use a specific access network among the two or more access networks.

Preferably, the one or more specific partial data, characterized in that it comprises an identifier for identifying that the one or more specific partial data is the partial data for determining the network state.

Preferably, the transmission control unit, characterized in that for controlling a predetermined time to transmit the at least one specific partial data to both of the two or more access network at the same time.

The heterogeneous network-based simultaneous data transmission / reception apparatus according to the second aspect of the present invention for achieving the above object is based on a predetermined data transmission rate for each access network, through the two or more access networks. A communication unit for receiving from a transmitting device; And a reception control unit that obtains information on a reception state of the same one or more specific partial data in each of the two or more access networks, when the same one or more specific partial data of the partial data are received through both the two or more access networks. The communication unit may provide information on the reception state to the transmitter.

The at least one same specific partial data may include an identifier for identifying that the at least one specific partial data is partial data for obtaining information on the reception state.

Preferably, the reception information includes delay information indicating a difference in reception time between the one or more specific partial data for each of the two or more access networks, and information on the number of unreceived specific partial data among the one or more specific partial data. And information about the number of pieces of specific partial data in which a transmission order of the one or more specific partial data and a reception order of the one or more specific partial data do not coincide.

In the heterogeneous network-based data transmission method according to the third aspect of the present invention for achieving the above object, the partial data selected by dividing the transmission data based on the data transmission rate for each access network through a two or more access networks A data transmission step of simultaneously transmitting to a receiving device; A data duplication transmission step of selecting one or more specific partial data from the partial data and simultaneously transmitting the same to the two or more access networks; And a status determination step of determining a network state for each of the two or more access networks based on the reception state of the one or more specific partial data in each of the two or more access networks.

Preferably, the method may further include a step of changing the transmission rate in which the data transmission rate is variably set or the specific access network is not used according to the network condition.

In the heterogeneous network-based data transmission method according to the fourth aspect of the present invention for achieving the above object, the partial data divided from the data to be transmitted is transmitted through two or more access networks based on a data transmission rate for each access network. Receiving a data from the device; A duplicate data identification step of confirming that one or more specific partial data of the partial data are received through both of the two or more access networks; An information acquiring step of acquiring information on a reception state of the one or more specific partial data in each of the two or more access networks; And providing an information on the reception state to the transmitter.

Accordingly, a heterogeneous network-based simultaneous data transmission method and an apparatus applied thereto may simultaneously transmit / receive partial data divided from data to be transmitted using a plurality of heterogeneous networks based on a preset data transmission rate for each access network. In the service environment, the quality of each access network is measured based on the reception status of each access network for the same partial data that is redundantly transmitted through each access network for a set time, and the preset data transmission is performed based on the measured access network quality. By setting the ratio variably, the performance of the simultaneous transmission service can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a system for simultaneously transmitting data based on heterogeneous networks according to an embodiment of the present invention; FIG.
2 is a schematic configuration diagram of a terminal device according to an embodiment of the present invention;
3 is a schematic configuration diagram of a management apparatus according to an embodiment of the present invention;
4 and 6 is a block diagram of a packet according to an embodiment of the present invention.
7 to 9 are schematic flowcharts for explaining a heterogeneous network-based data transmission method according to a first embodiment of the present invention.
10 to 12 are schematic flowcharts for explaining a heterogeneous network-based data transmission method according to a second embodiment of the present invention.
13 to 15 are schematic flowcharts for explaining a heterogeneous network-based data transmission method according to a third embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 1 shows a schematic diagram of a heterogeneous network-based data concurrent transmission system according to an embodiment of the present invention.

As shown in FIG. 1, the heterogeneous network-based data transmission system according to the present invention divides data into two or more partial data and connects a specific virtual network to first partial data corresponding to a portion of the two or more partial data. From the management apparatus 400 and the management apparatus 400 of the transmitting apparatus which includes the information and transmits the information including the virtual network connection information in the second partial data corresponding to another part of the two or more partial data and transmits the information. The first network device 200 to receive the first partial data, the second network device 300 to receive the second partial data from the management device 400, and the first network device 200 from the first network device 200; Receiving the partial data and the second partial data from the second network device 300, the first partial data and the virtual net included in the second partial data By combining the first partial data and second partial data according to a particular virtual network connection information based on the greater the access information comprises a terminal device 100 as a receiving device for generating the data. In addition, the heterogeneous network-based data concurrent transmission system according to the present invention has a configuration including an external device 500 for transferring data to be transmitted to the management apparatus 400 and requesting transmission to the terminal apparatus 100.

The heterogeneous network-based data concurrent transfer service according to the present invention implements a configuration in which data is transmitted and received between the terminal device 100 and the external device 500 and transmitted and received using a plurality of heterogeneous networks. Accordingly, in the present invention, the session is divided in the management apparatus 400 in order to realize simultaneous link transmission through a plurality of heterogeneous networks for one session. At this time, since the terminal device 100 is connected to each of the plurality of heterogeneous networks, it is recognized that the management device 400 recognizes that each of the simultaneous links through the plurality of heterogeneous networks is a link of one terminal device 100, It must be managed by the terminal device 100, that is, a single entity. For this purpose, it is inevitably required to allocate and manage separate virtual network connection information (e.g., virtual IP) for the simultaneous transmission service corresponding to the terminal device 100. [

The external device 500 refers to a server device that transmits and receives data to and from the terminal device 100 through the management device 400. The external device 500 may transmit and receive data to and from the terminal device 100 through the management device 400, Portal service, and content providing service.

The heterogeneous network may be a variety of networks including, for example, WCDMA, CDMA, WiBro, WLAN (WiFi) and Long Term Evolution (LTE) (Hereinafter referred to as a " WiFi network ") that refers to a first network (hereinafter referred to as a 3G network) and a second wireless network (WiFi)

Accordingly, the first network device 200 refers to a 3G network, that is, a Gateway GPRS Support Node (GGSN) for operating a wireless packet service network. In addition, the second network device 300 includes a WiFi network, And an access point (AP) for operating a short-range wireless network.

Also, the terminal device 100 and the management device 400 may be a transmission device according to a service flow, i.e., a subject that transmits data using a simultaneous data transmission service, that is, according to an uplink process and a downlink process , Or a receiving device.

In this embodiment, for convenience of description, a management apparatus 400 as a transmitting apparatus for providing a data concurrent transmission service to the terminal apparatus 100 in a heterogeneous network environment is assumed, and the management apparatus 400 and the data transmission / Will be described below with reference to a terminal apparatus 100 as a receiving apparatus that performs a receiving operation.

Hereinafter, a configuration of a heterogeneous network-based data simultaneous transmission system according to a first embodiment of the present invention will be described with reference to the above description with reference to FIG. 1.

The terminal device 100 receives the partial data through the first network device 200 and the second network device 300.

More specifically, the terminal device 100 receives the partial data divided from the transmission target data from the management device 400 on the basis of a preset data transmission rate for each access network. That is, the terminal device 100 receives the first partial data through the 3G network, that is, the first network device 200, and receives the second partial data through the WiFi network, that is, the second network device 300. do. At this time, the terminal device 100 receives the partial data having the continuous sequence information selected by the management device 400 to check the quality for each access network through the first network device 200 located in the 3G network, Partial data having the same sequence information received through the 3G network through the second network device 300 located in the WiFi network is received for a predetermined time overlapping. For example, the terminal apparatus 100 includes a first partial data packet of the order information 1, 2, 3, and 4 selected by the management apparatus 400 to check the quality of each of the access networks among the partial data divided into the transmission target data. When received through the first network device 200 of the 3G network, the second partial data packet of the same sequence information 1, 2, 3, 4 as the 3G network through the second network device 300 of the WiFi network likewise Duplicate reception

Thus, the terminal device 100 identifies the partial data duplicated through the first network device 200 and the second network device 300.

More specifically, the terminal device 100 parses the header of the partial data packet received through the 3G network and the WiFi network, thereby recognizing the order information specified in each partial data, and recognizing the recognized order information. The partial data is rearranged accordingly. At this time, the terminal apparatus 100 identifies the identifier additionally inserted in the header of the partial data packet, thereby identifying that the partial data is partial data for quality check of each access network. In this regard, the management apparatus 400 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted and transmitted. Meanwhile, the terminal device 100 reorders the partial data first received through the 3G network or the WiFi network among the partial data having the same order information to restore the transmission target data to be transmitted from the management device 400. The target data is restored by combining the rearranged partial data normally, and the received partial data is later deleted after being used for network quality check, thereby minimizing the simultaneous transmission performance deterioration due to duplicate transmission of partial data packets. Done.

Based on this, the terminal device 100 calculates state information for each access network based on a reception state of the same partial data duplicated through the first network device 200 and the second network device 300.

More specifically, the terminal device 100 receives a partial data packet received through the first network device 200 of the 3G network and the same partial data received through the second network device 300 of the WiFi network. Based on the state information for each of the 3G network and the WiFi network, for example, delay information (delay), which is the time difference information received between the partial data packets having consecutive sequence information, and the packet loss rate, which is a probability that the partial data packet is not received. loss), and order information of partial data packets are changed to calculate a disorder, which is a probability of being received. At this time, the terminal device 100 preferentially calculates delay information, which is the time difference information received between the partial data packets, corresponding to each of the 3G network and the WiFi network, and confirms that the calculated delay information exceeds a threshold. If so, the transmission stop request for the corresponding access network is transmitted to the management device 400, so that the management device 400 recognizes the access network quality state to stop the operation of transmitting the duplicate partial data packet thereafter.

Furthermore, the terminal device 100 transmits the state information calculated for each access network to the management device 400.

More specifically, when the setting time for checking the access network quality has elapsed and the duplicate partial data packet is not identified, the terminal device 100 calculates the status information corresponding to each of the 3G network and the WiFi network. Delay information, which is received time difference information between partial data packets having sequence information, packet loss rate, which is a probability that the partial data packet is not received due to loss, and ratio, which is a probability that the sequence information of the partial data packet is changed and received. By delivering a sort rate to the management device 400, the management device 400 may set a predetermined data transmission rate for each access network based on the transmitted state information to improve performance of the simultaneous transmission service. Make sure At this time, the terminal device 100 piggy-backing the calculated state information on the response message transmitted to the management device 400 in accordance with the partial data, that is, as shown in Figure 4 (b) On the header of the response message (Ack) transmitted to the management device 400, access network information (①), transmission stop request (②), delay information (③), packet loss rate (④), and misalignment rate (⑤) ) Is inserted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

The management apparatus 400 selects the partial data divided from the transmission target data for each access network according to a data transmission rate preset for each access network.

More specifically, the management device 400 checks the preset data transmission rate, that is, the first transmission rate and the second transmission rate for data transmission to the second network device 300, between the access networks, and checks the identified transmission rate. Selecting the first partial data to be transmitted to the first network device 200 among the divided partial data from the transmission target data received from the external device 500 based on, and to the second network device 300 of the remaining partial data The second partial data to be transmitted is selected. At this time, the management device 400 selects the partial data having the continuous sequence information corresponding to the 3G network to check the quality for each access network, and also the partial data having the same sequence information as the selected partial data corresponding to the 3G network. Is selected corresponding to the WiFi network. For example, the management device 400 selects the first partial data packet of the order information 1, 2, 3, and 4 corresponding to the 3G network to check the quality of each of the access networks among the partial data divided into the transmission target data. Similarly, the second partial data packets of the order information 1, 2, 3, and 4, which are the same as those of the 3G network, are selected corresponding to the WiFi network.

In addition, the management device 400 inserts an identifier for identifying that the partial data for quality check for each access network.

More specifically, the management apparatus 400 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted.

Furthermore, the management device 400 transmits the same partial data selected for each access network in duplicate.

More specifically, the management device 400 transmits the partial data having the continuous sequence information selected for quality check for each access network through the first network device 200 located in the 3G network and is located in the WiFi network. The partial data having the same order information as the partial data transmitted through the 3G network through the second network device 300 is repeatedly transmitted for a set time. For example, the management device 400 may transmit the first partial data packet of the sequence information 1, 2, 3, and 4 among the partial data divided into the transmission target data through the first network device 200 located in the 3G network. 100 and the second partial data packet of the same sequence information 1, 2, 3, and 4 as the 3G network is duplicated in the terminal device 100 through the second network device 300 located in the WiFi network. Will be delivered.

Then, the management device 400 receives the status information calculated based on the reception status for each access network for the same partial data transmitted.

More specifically, the management device 400 is a partial data packet transmitted through the first network device 200 of the 3G network when a set time for transmitting the same partial data for each access network elapses to check the quality for each access network. And, based on the reception state for the same partial data transmitted through the second network device 300 of the WiFi network receives the state information for each of the 3G network and WiFi network calculated by the terminal device (100). At this time, in the case of the state information transmitted from the terminal device 100, for example, delay information (delay) which is the time difference information received between the partial data packets having continuous sequence information, a packet having a probability that the partial data packet is lost and not received. The loss rate and the order information of the partial data packet are changed to include a disorder rate which is a probability of being received. Here, in the case of delay information (delay) is first calculated by the terminal device 100, when it is confirmed that the calculated delay information exceeds the threshold, the management device 400 is a 3G network or WiFi network The terminal 100 receives a stop request for transmission, and thus recognizes the quality state of the access network before the set time for transmitting the same partial data elapses, thereby overlapping the quality of the access network. The operation of transmitting the partial data packet is stopped. In this regard, the terminal apparatus 100 piggy-backs the calculated state information for each access network on the response message transmitted to the management apparatus 400 according to the partial data reception, that is, FIG. 4 (b). As shown in FIG. 4, access network information (1), transmission stop request (2), delay information (3), packet loss rate (4), and the like on the header of the response message (Ack) transmitted to the management device 400, and It is delivered with the misalignment rate (⑤) inserted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

Thereafter, the management apparatus 400 variably sets a preset data transmission rate based on the state information transmitted for each access network.

More specifically, the management apparatus 400 receives delay information (delay), which is the time difference information received between the partial data packets having the continuous sequence information, for example, status information for each of the 3G network and the WiFi network, and receives the partial data packet. Recognizes the quality status of each of the 3G network and the WiFi network based on the probability of packet loss (loss), which is a non-probable probability, and the disorder rate, which is a probability that the order information of partial data packets is changed. Reflecting this, the preset data transmission rate is variably set for each access network.

Hereinafter, a more specific configuration of the terminal device 100 according to the first embodiment of the present invention will be described with reference to FIG. 2.

That is, the terminal device 100 is a communication unit 110 for receiving partial data dividedly transmitted from the first network device 200 and the second network device 300, the state information for each access network based on the reception state of the partial data. It has a configuration including a reception control unit 120 for calculating the.

The communication unit 110 receives the partial data through the first network device 200 and the second network device 300.

More specifically, the communication unit 110 receives the partial data divided from the transmission target data from the management device 400 based on a preset data transmission rate for each access network. That is, the communication unit 110 receives the first partial data through the 3G network, that is, the first network device 200, and receives the second partial data through the WiFi network, that is, the second network device 300. . At this time, the communication unit 110 receives the partial data having the continuous sequence information selected by the management device 400 to check the quality for each access network through the first network device 200 located in the 3G network, and WiFi Through the second network device 300 located in the network, partial data having the same order information received through the 3G network is repeatedly received for a set time. For example, the communication unit 110 is a 3G of the first partial data packet of the order information 1, 2, 3, 4 selected by the management device 400 to check the quality of each of the access network of the partial data divided into the transmission target data When received through the first network device 200 of the network, the second partial data packet of the same order information 1, 2, 3, 4 as the 3G network is duplicated through the second network device 300 of the WiFi network likewise. To receive it.

The reception control unit 120 identifies the partial data repeatedly received through the first network device 200 and the second network device 300.

More specifically, the reception controller 120 parses the header of the partial data packet received through the 3G network and the WiFi network, thereby recognizing the order information designated for each partial data. The partial data are rearranged according to the recognized order information. In this case, the reception control unit 120 identifies the identifier additionally inserted in the header of the partial data packet, thereby identifying that the partial data is partial data for checking the quality of each access network. In this regard, the management apparatus 400 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted and transmitted. Meanwhile, the reception controller 120 rearranges the partial data first received through the 3G network or the WiFi network among the partial data having the same order information to restore the transmission target data to be transmitted by the management device 400. The target data is restored by combining the rearranged partial data normally, and the received partial data is later deleted after being used for network quality check, thereby minimizing the simultaneous transmission performance deterioration due to duplicate transmission of partial data packets. Done.

Based on this, the reception controller 120 calculates state information for each access network based on a reception state of the same partial data duplicated through the first network device 200 and the second network device 300.

More specifically, the reception controller 120 receives a partial data packet received through the first network device 200 of the 3G network and the same partial data received through the second network device 300 of the WiFi network. Based on the state information for each of the 3G network and the WiFi network, for example, delay information (delay), which is the time difference information received between the partial data packets having consecutive sequence information, and the packet loss rate, which is a probability that the partial data packet is not received. loss), and order information of partial data packets are changed to calculate a disorder, which is a probability of being received. In this case, the reception controller 120 first calculates delay information, which is the time difference information received between the partial data packets, corresponding to each of the 3G network and the WiFi network, and confirms that the calculated delay information exceeds a threshold. If so, the transmission stop request for the corresponding access network is transmitted to the management device 400, so that the management device 400 recognizes the access network quality state to stop the operation of transmitting the duplicate partial data packet thereafter.

Furthermore, the reception control unit 120 transmits the state information calculated for each access network to the management device 400.

More specifically, the reception control unit 120 when the set time for checking the access network quality has elapsed, and the duplicate partial data packet is not identified, the state information calculated for each of the 3G network and the WiFi network, for example, continuous Delay information, which is received time difference information between partial data packets having sequence information, packet loss rate, which is a probability that the partial data packet is not received due to loss, and ratio, which is a probability that the sequence information of the partial data packet is changed and received. By delivering a sort rate to the management device 400, the management device 400 may set a predetermined data transmission rate for each access network based on the transmitted state information to improve performance of the simultaneous transmission service. Make sure In this case, the reception controller 120 piggybacks the calculated state information for each access network on the response message transmitted to the management device 400 according to partial data reception, that is, as shown in FIG. 4 (b). As described above, on the header of the response message (Ack) transmitted to the management device 400, access network information (1), transmission stop request (2), delay information (3), packet loss rate (4), and misalignment It is delivered with the rate (⑤) inserted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

Hereinafter, a more specific configuration of the management apparatus 400 according to the first embodiment of the present invention will be described with reference to FIG. 3.

That is, the management device 400 is based on the reception state of the same partial data, the communication unit 410 for transmitting the divided partial data from the transmission target data through the first network device 200 and the second network device 300 The transmission control unit 120 for varying the preset data transmission rate for each access network has a configuration.

The transmission controller 120 selects the partial data divided from the transmission target data for each access network according to a data transmission rate preset for each access network.

More specifically, the transmission controller 120 checks the preset data transmission rate, that is, the first transmission rate and the second transmission rate for data transmission to the second network apparatus 300, between the access networks, and checks the confirmed transmission rate. Selecting the first partial data to be transmitted to the first network device 200 among the divided partial data from the transmission target data received from the external device 500 based on, and to the second network device 300 of the remaining partial data The second partial data to be transmitted is selected. At this time, the transmission control unit 120 selects the partial data having continuous sequence information corresponding to the 3G network to confirm the quality of each access network, and also has the partial data having the same sequence information as the selected partial data corresponding to the 3G network. Is selected corresponding to the WiFi network. For example, the transmission controller 120 selects the first partial data packet of the sequence information 1, 2, 3, and 4 corresponding to the 3G network to check the quality of each of the access networks among the partial data divided into the transmission target data. Similarly, the second partial data packets of the order information 1, 2, 3, and 4, which are the same as those of the 3G network, are selected corresponding to the WiFi network.

In addition, the transmission control unit 120 inserts an identifier for identifying that the partial data for quality check for each access network.

More specifically, the transmission controller 120 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted.

The communication unit 410 transmits duplicately selected partial data for each access network.

More specifically, the communication unit 410 transmits the partial data having the continuous sequence information selected by the management device 400 through the first network device 200 located in the 3G network to check the quality for each access network; In addition, the partial data having the same order information as the partial data transmitted through the 3G network through the second network device 300 located in the WiFi network is repeatedly transmitted for a set time. For example, the communication unit 410 may transmit the first partial data packet of the sequence information 1, 2, 3, and 4 among the partial data divided into the transmission target data through the first network device 200 located in the 3G network. In addition, the second partial data packet of the same sequence information 1, 2, 3, and 4 as the 3G network is repeatedly transmitted to the terminal device 100 through the second network device 300 located in the WiFi network. Done.

Then, the communication unit 410 receives the state information calculated based on the reception state for each access network for the same partial data transmitted.

More specifically, the communication unit 410 and the partial data packet transmitted through the first network device 200 of the 3G network when the set time for transmitting the same partial data for each access network elapsed to confirm the quality for each access network and the like; On the basis of the reception state for the same partial data transmitted through the second network device 300 of the WiFi network, the terminal device 100 receives the state information for each of the 3G network and the WiFi network. At this time, in the case of the state information transmitted from the terminal device 100, for example, delay information (delay) which is the time difference information received between the partial data packets having continuous sequence information, a packet having a probability that the partial data packet is lost and not received. The loss rate and the order information of the partial data packet are changed to include a disorder rate which is a probability of being received. In this case, the delay information (delay) is first calculated by the terminal device 100, when it is confirmed that the calculated delay information exceeds the threshold, the communication unit 410 is connected to the 3G network or WiFi network Receives a request to stop the transmission from the terminal device 100, accordingly, the transmission control unit 120 recognizes the quality of the access network before the set time for transmitting the same partial data, the quality of the access network The transmission of the duplicate partial data packet is stopped for confirmation. In this regard, the terminal apparatus 100 piggy-backs the calculated state information for each access network on the response message transmitted to the management apparatus 400 according to the partial data reception, that is, FIG. 4 (b). As shown in FIG. 4, access network information (1), transmission stop request (2), delay information (3), packet loss rate (4), and the like on the header of the response message (Ack) transmitted to the management device 400, and It is delivered with the misalignment rate (⑤) inserted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

Thereafter, the transmission controller 120 variably sets the preset data transmission rate based on the state information transmitted for each access network.

More specifically, the transmission controller 120 receives the delay information (delay), which is the time difference information between the partial data packets having the sequence information of each of the 3G network and the WiFi network, for example, consecutive sequence information, and is lost. Recognizes the quality status of each of the 3G network and the WiFi network based on the probability of packet loss (loss), which is a non-probable probability, and the disorder rate, which is a probability that the order information of partial data packets is changed. Reflecting this, the preset data transmission rate is variably set for each access network.

Hereinafter, a configuration of a heterogeneous network-based simultaneous data transmission system according to a second embodiment of the present invention will be described with reference to the above description with reference to FIG. 1.

The terminal device 100 receives the partial data through the first network device 200 and the second network device 300.

More specifically, the terminal device 100 receives the partial data divided from the transmission target data from the management device 400 on the basis of a preset data transmission rate for each access network. That is, the terminal device 100 receives the first partial data through the 3G network, that is, the first network device 200, and receives the second partial data through the WiFi network, that is, the second network device 300. do. At this time, the terminal device 100 receives the partial data having the continuous sequence information selected by the management device 400 to check the quality for each access network through the first network device 200 located in the 3G network, Partial data having the same sequence information received through the 3G network through the second network device 300 located in the WiFi network is received for a predetermined time overlapping. For example, the terminal apparatus 100 includes a first partial data packet of the order information 1, 2, 3, and 4 selected by the management apparatus 400 to check the quality of each of the access networks among the partial data divided into the transmission target data. When received through the first network device 200 of the 3G network, the second partial data packet of the same sequence information 1, 2, 3, 4 as the 3G network through the second network device 300 of the WiFi network likewise Duplicate reception

Thus, the terminal device 100 identifies the partial data duplicated through the first network device 200 and the second network device 300.

More specifically, the terminal device 100 parses the header of the partial data packet received through the 3G network and the WiFi network, thereby recognizing the order information specified in each partial data, and recognizing the recognized order information. The partial data is rearranged accordingly. At this time, the terminal apparatus 100 identifies the identifier additionally inserted in the header of the partial data packet, thereby identifying that the partial data is partial data for quality check of each access network. In this regard, the management device 400 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted and transmitted. Meanwhile, the terminal device 100 reorders the partial data first received through the 3G network or the WiFi network among the partial data having the same order information to restore the transmission target data to be transmitted from the management device 400. The target data is restored by combining the rearranged partial data normally, and the received partial data is later deleted after being used for network quality check, thereby minimizing the simultaneous transmission performance deterioration due to duplicate transmission of partial data packets. Done.

Based on this, the terminal device 100 calculates state information on the WiFi network based on the reception state of the same partial data duplicated through the first network device 200 and the second network device 300.

More specifically, the terminal device 100 receives through the second network device 300 of the WiFi network in order to calculate the status information for the WiFi network having a large quality difference according to the quality of the wired Internet network and the number of users compared to the 3G network. Calculating the state information of the WiFi network, for example, the number of partial data packets transmitted through the WiFi network, and the partial data throughput transmitted through the WiFi network, based on the reception state of the partial data having consecutive sequence information. Done. In this case, when it is determined that the calculated number of partial data packets and the partial data throughput are less than the threshold value, the terminal device 100 places a request to stop using the WiFi network in the 3G network 200. By transmitting to the management device 400, the management device 400 recognizes the quality status of the WiFi network, and subsequently variablely set the preset data transmission rate for each access network so that all partial data packets are transmitted through the 3G network. Let's do it.

In addition, the terminal device 100 transmits the state information calculated corresponding to the WiFi network to the management device 400.

More specifically, when the setting time for checking the access network quality has elapsed and the duplicate partial data packet is not identified, the terminal device 100 calculates the state information corresponding to the WiFi network, for example, for checking the access network quality. By transmitting the number of packets received during the set time, and the partial data throughput during the set time for checking the access network quality to the management device 400, by allowing the management device 400 to recognize the WiFi network quality state, Reflecting this, a variable data transmission rate is set for each access network to improve the performance of the simultaneous transmission service. At this time, the terminal device 100 piggy-backing the calculated state information on the response message transmitted to the management device 400 according to the partial data reception, that is, as shown in FIG. On the header of the response message (Ack) transmitted to the management device 400, the stop request for the WiFi network (①), the number of packets received during the set time for checking the access network quality (②), and the access network quality The partial data rate (③) during the set time for confirmation is transmitted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

The management apparatus 400 selects the partial data divided from the transmission target data for each access network according to a data transmission rate preset for each access network.

More specifically, the management device 400 checks the preset data transmission rate, that is, the first transmission rate and the second transmission rate for data transmission to the second network device 300, between the access networks, and checks the identified transmission rate. Selecting the first partial data to be transmitted to the first network device 200 among the divided partial data from the transmission target data received from the external device 500 based on, and to the second network device 300 of the remaining partial data The second partial data to be transmitted is selected. At this time, the management device 400 selects the partial data having the continuous sequence information corresponding to the 3G network to check the quality for each access network, and also the partial data having the same sequence information as the selected partial data corresponding to the 3G network. Is selected corresponding to the WiFi network. For example, the management device 400 selects the first partial data packet of the order information 1, 2, 3, and 4 corresponding to the 3G network to check the quality of each of the access networks among the partial data divided into the transmission target data. Similarly, the second partial data packets of the order information 1, 2, 3, and 4, which are the same as those of the 3G network, are selected corresponding to the WiFi network.

In addition, the management device 400 inserts an identifier for identifying that the partial data for quality check for each access network.

More specifically, the management device 400 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted.

Furthermore, the management device 400 transmits the same partial data selected for each access network in duplicate.

More specifically, the management device 400 transmits the partial data having the continuous sequence information selected for quality check for each access network through the first network device 200 located in the 3G network and is located in the WiFi network. The partial data having the same order information as the partial data transmitted through the 3G network through the second network device 300 is repeatedly transmitted for a set time. For example, the management device 400 may transmit the first partial data packet of the sequence information 1, 2, 3, and 4 among the partial data divided into the transmission target data through the first network device 200 located in the 3G network. 100 and the second partial data packet of the same sequence information 1, 2, 3, and 4 as the 3G network is duplicated in the terminal device 100 through the second network device 300 located in the WiFi network. Will be delivered.

Then, the management device 400 receives the state information calculated based on the reception state of the WiFi network for the same partial data transmitted.

More specifically, the management device 400 is the same partial data transmitted through the second network device 300 of the WiFi network, when the set time for transmitting the same partial data for each access network elapsed to check the quality for each access network elapsed. Receives state information on the WiFi network calculated by the terminal device 100 based on the reception state of the. At this time, in the case of the state information transmitted from the terminal device 100, for example, the number of packets received through the WiFI network during the setting time for checking the access network quality, and the part of the WiFI network during the setting time for checking the access network quality. The data throughput may correspond. On the other hand, the number of packets received through the WiFI network during the setting time for the access network quality, and the partial data transmission rate of the WiFI network during the setting time for the access network quality check When it is confirmed that the threshold value is less than the elapsed time, the management device 400 receives a stop request for the WiFi network from the terminal device 100, and accordingly, before a set time for transmitting the same partial data elapses. By recognizing the quality state of the WiFi network, the variable data transmission rate is variably set for each access network so that all partial data packets are transmitted through the 3G network. In this regard, the terminal device 100 piggy-backing the calculated state information on the response message transmitted to the management device 400 according to the partial data reception, that is, as shown in FIG. As described above, on the header of the response message (Ack) transmitted to the management device 400, the stop request (①) for the WiFi network, the number of packets received during the set time for checking the access network quality (②), and the access The partial data rate ③ during the set time for checking network quality is inserted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

Thereafter, the management apparatus 400 variably sets a preset data transmission rate based on the state information calculated for the WiFi network.

More specifically, the management device 400 is the state information calculated for the WiFi network, for example, the number of packets received during the set time for checking the access network quality, and the partial data transmission rate during the set time for checking the access network quality ( By recognizing the quality of the WiFi network based on throughput, the data transmission rate is changed for each access network based on the quality of the WiFi network, which has a large quality difference according to the quality of the wired Internet network and the number of users compared to the 3G network. By setting it, the performance of the simultaneous transmission service can be improved.

Hereinafter, a more specific configuration of the terminal device 100 according to the second embodiment of the present invention will be described with reference to FIG. 2.

That is, the terminal device 100 is a communication unit 110 for receiving partial data transmitted from the first network device 200 and the second network device 300, the state for the WiFi network based on the reception state of the partial data. It has a configuration including a reception control unit 120 for calculating the information.

The communication unit 110 receives the partial data through the first network device 200 and the second network device 300.

More specifically, the communication unit 110 receives the partial data divided from the transmission target data from the management device 400 based on a preset data transmission rate for each access network. That is, the communication unit 110 receives the first partial data through the 3G network, that is, the first network device 200, and receives the second partial data through the WiFi network, that is, the second network device 300. . At this time, the communication unit 110 receives the partial data having the continuous sequence information selected by the management device 400 to check the quality for each access network through the first network device 200 located in the 3G network, and WiFi Through the second network device 300 located in the network, partial data having the same order information received through the 3G network is repeatedly received for a set time. For example, the communication unit 110 is a 3G of the first partial data packet of the order information 1, 2, 3, 4 selected by the management device 400 to check the quality of each of the access network of the partial data divided into the transmission target data When received through the first network device 200 of the network, the second partial data packet of the same order information 1, 2, 3, 4 as the 3G network is duplicated through the second network device 300 of the WiFi network likewise. To receive it.

The reception control unit 120 identifies the partial data repeatedly received through the first network device 200 and the second network device 300.

More specifically, the reception control unit 120 parses the header of the partial data packet received through the 3G network and the WiFi network, thereby recognizing the sequence information specified in each partial data, and recognizing the sequence information. The partial data is rearranged accordingly. In this case, the reception control unit 120 identifies the identifier additionally inserted in the header of the partial data packet, thereby identifying that the partial data is partial data for checking the quality of each access network. In this regard, the management device 400 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted and transmitted. Meanwhile, the reception controller 120 rearranges the partial data first received through the 3G network or the WiFi network among the partial data having the same order information to restore the transmission target data to be transmitted by the management device 400. The target data is restored by combining the rearranged partial data normally, and the received partial data is later deleted after being used for network quality check, thereby minimizing the simultaneous transmission performance deterioration due to duplicate transmission of partial data packets. Done.

Based on this, the reception controller 120 calculates state information on the WiFi network based on the reception state of the same partial data duplicated through the first network device 200 and the second network device 300.

More specifically, the reception control unit 120 receives through the second network device 300 of the WiFi network in order to calculate the status information for the WiFi network having a large quality difference according to the quality of the wired Internet network and the number of users compared to the 3G network. Calculating the state information of the WiFi network, for example, the number of partial data packets transmitted through the WiFi network, and the partial data throughput transmitted through the WiFi network, based on the reception state of the partial data having consecutive sequence information. Done. In this case, when it is determined that the calculated number of partial data packets and the partial data throughput are less than a threshold value, the reception controller 120 places a request to stop using the WiFi network in the 3G network 200. By transmitting to the management device 400, the management device 400 recognizes the quality status of the WiFi network, and subsequently variablely set the preset data transmission rate for each access network so that all partial data packets are transmitted through the 3G network. Let's do it.

In addition, the reception controller 120 transmits the state information calculated corresponding to the WiFi network to the management device 400.

More specifically, the reception control unit 120 when the set time for checking the access network quality has elapsed, and the duplicate partial data packet is not identified, the state information calculated for the WiFi network, for example, for checking the access network quality. By transmitting the number of packets received during the set time, and the partial data throughput during the set time for checking the access network quality to the management device 400, by allowing the management device 400 to recognize the WiFi network quality state, Reflecting this, a variable data transmission rate is set for each access network to improve the performance of the simultaneous transmission service. At this time, the reception control unit 120 piggy-backing the calculated state information on the response message transmitted to the management device 400 in accordance with the partial data, that is, as shown in Figure 5 (b) On the header of the response message (Ack) transmitted to the management device 400, the stop request for the WiFi network (①), the number of packets received during the set time for checking the access network quality (②), and the access network quality The partial data rate (③) during the set time for confirmation is transmitted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

Hereinafter, a more specific configuration of the management device 400 according to the second embodiment of the present invention will be described with reference to FIG. 3.

That is, the management device 400 is based on the reception state of the same partial data, the communication unit 410 for transmitting the divided partial data from the transmission target data through the first network device 200 and the second network device 300 The transmission control unit 120 checks the quality state of the WiFi network and variably sets a preset data transmission rate for each access network.

The transmission controller 120 selects the partial data divided from the transmission target data for each access network according to a data transmission rate preset for each access network.

More specifically, the transmission controller 120 checks the preset data transmission rate, that is, the first transmission rate and the second transmission rate for data transmission to the second network apparatus 300, between the access networks, and checks the confirmed transmission rate. Selecting the first partial data to be transmitted to the first network device 200 among the divided partial data from the transmission target data received from the external device 500 based on, and to the second network device 300 of the remaining partial data The second partial data to be transmitted is selected. At this time, the transmission control unit 120 selects the partial data having continuous sequence information corresponding to the 3G network to confirm the quality of each access network, and also has the partial data having the same sequence information as the selected partial data corresponding to the 3G network. Is selected corresponding to the WiFi network. For example, the transmission controller 120 selects the first partial data packet of the sequence information 1, 2, 3, and 4 corresponding to the 3G network to check the quality of each of the access networks among the partial data divided into the transmission target data. Similarly, the second partial data packets of the order information 1, 2, 3, and 4, which are the same as those of the 3G network, are selected corresponding to the WiFi network.

In addition, the transmission control unit 120 inserts an identifier for identifying that the partial data for quality check for each access network.

More specifically, as shown in FIG. 5 (a), the transmission controller 120 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality of each access network. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted.

Furthermore, the communication unit 420 transmits duplicately selected partial data for each access network.

More specifically, the communication unit 420 transmits the partial data having the continuous sequence information selected by the management device 400 through the first network device 200 located in the 3G network to check the quality of each access network. In addition, the partial data having the same order information as the partial data transmitted through the 3G network through the second network device 300 located in the WiFi network is repeatedly transmitted for a set time. For example, the communication unit 420 may transmit the first partial data packet of the sequence information 1, 2, 3, and 4 among the partial data divided into the transmission target data through the first network device 200 located in the 3G network. In addition, the second partial data packet of the same sequence information 1, 2, 3, and 4 as the 3G network is repeatedly transmitted to the terminal device 100 through the second network device 300 located in the WiFi network. Done.

Then, the communication unit 420 receives the state information calculated based on the reception state of the WiFi network for the same partial data transmitted.

More specifically, the communication unit 420 is applied to the same partial data transmitted through the second network device 300 of the WiFi network when a set time for transmitting the same partial data for each access network elapses to check the quality of each access network. Receives the state information on the WiFi network calculated by the terminal device 100 based on the received state. At this time, in the case of the state information transmitted from the terminal device 100, for example, the number of packets received through the WiFI network during the setting time for checking the access network quality, and the part of the WiFI network during the setting time for checking the access network quality. The data throughput may correspond. Meanwhile, the number of packets received through the WiFI network during the setting time for the access network quality before the setting time for the access network quality check, and the partial data transmission rate of the WiFI network during the setting time for the access network quality check When it is determined that the throughput is less than the threshold value, the communication unit 420 receives a stop request for the WiFi network from the terminal device 100, and accordingly, the control unit 410 transmits the same partial data. By recognizing the quality of the WiFi network before this elapses, it is possible to variably set a preset data transmission rate for each access network so that all partial data packets are transmitted through the 3G network. In this regard, the terminal device 100 piggy-backing the calculated state information on the response message transmitted to the management device 400 according to the partial data reception, that is, as shown in FIG. As described above, on the header of the response message (Ack) transmitted to the management device 400, the stop request (①) for the WiFi network, the number of packets received during the set time for checking the access network quality (②), and the access The partial data rate ③ during the set time for checking network quality is inserted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

Thereafter, the controller 410 variably sets a preset data transmission rate based on the state information calculated for the WiFi network.

More specifically, the control unit 410 is the state information calculated for the WiFi network, for example, the number of packets received during the set time for checking the access network quality, and the partial data transmission rate during the set time for checking the access network quality (throughput). By recognizing the quality of the WiFi network based on the quality of the WiFi network, a variable data transmission rate is set for each access network based on the quality of the WiFi network with a large quality difference according to the quality of the wired Internet network and the number of users. The performance of the simultaneous transmission service can be improved.

Hereinafter, a configuration of a heterogeneous network-based simultaneous data transmission system according to a third embodiment of the present invention will be described with reference to the above description with reference to FIG. 1.

The terminal device 100 selects the same partial data corresponding to each of the access networks to check the quality of each access network.

More specifically, the terminal device 100 is an uplink partial data packet for the management device 400 that transmits the partial data through the 3G network and the WiFi network according to a preset data transmission rate for each access network. Is present (e.g., ACK, SYN, FIN, Duplicate ACK message, etc.), in order to check the quality of each access network, partial data having continuous sequence information is selected corresponding to the 3G network and corresponding to the 3G network. The partial data having the same order information as the selected partial data is selected corresponding to the WiFi network. For example, the terminal device 100 selects the first partial data packet of the order information 1, 2, 3, and 4 corresponding to the 3G network to check the quality of each of the access networks among the partial data divided into the transmission target data. Similarly, the second partial data packets of the order information 1, 2, 3, and 4, which are the same as those of the 3G network, are selected corresponding to the WiFi network.

In addition, the terminal device 100 inserts an identifier for identifying that the partial data for quality check for each access network.

More specifically, the terminal device 100 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted.

In addition, the terminal device 100 transmits duplicately selected partial data for each access network.

More specifically, the terminal device 100 transmits the partial data having the continuous sequence information selected by the management device 400 through the first network device 200 located in the 3G network to check the quality for each access network. In addition, the partial data having the same order information as the partial data transmitted through the 3G network through the second network device 300 located in the WiFi network is repeatedly transmitted for a set time. For example, the management device 400 may transmit the first partial data packet of the sequence information 1, 2, 3, and 4 among the partial data divided into the transmission target data through the first network device 200 located in the 3G network. 100 and the second partial data packet of the same sequence information 1, 2, 3, and 4 as the 3G network is duplicated in the terminal device 100 through the second network device 300 located in the WiFi network. Will be delivered.

Then, when the terminal device 100 receives a usage stop request for the WiFi network from the management device 400, the terminal device 100 stops using the WiFi network.

More specifically, the terminal device 100 checks the first network device 200 where a stop request for the WiFi network is located in the 3G network from the management device 400 before the setting time for checking the access network quality has elapsed. When received via the WiFi network, the use of the WiFi network is stopped, thereby minimizing partial data packet transmission time and waiting time, thereby preventing deterioration in simultaneous transmission performance. In this regard, the management device 400, as shown in 6 (b), on the header of the partial data packet transmitted to the terminal device 100, the stop request (①) for the WiFi network, confirming the access network quality It is delivered with the number of received packets (②) inserted during the set time for. Meanwhile, in the case of the request for disabling the WiFi network, the status information of the WiFi network with a large difference in quality depending on the quality of the wired Internet network and the number of users compared to the 3G network, that is, through the WiFi network during the set time for checking the access network quality. If the number of received packets is less than the threshold value will be delivered from the management device (400).

The management device 400 receives the same partial data through the first network device 200 and the second network device 300.

More specifically, the management device 400 receives the partial data having the continuous sequence information selected by the terminal device 100 through the first network device 200 located in the 3G network to check the quality of each access network. In addition, the partial data having the same order information received through the 3G network via the second network device 300 located in the WiFi network is repeatedly received for a set time. For example, the management apparatus 400 may include the first partial data packet of the order information 1, 2, 3, and 4 selected by the terminal apparatus 100 to check the quality of each of the access networks among the partial data divided into the transmission target data. When received through the first network device 200 of the 3G network, the second partial data packet of the same sequence information 1, 2, 3, 4 as the 3G network through the second network device 300 of the WiFi network likewise Duplicate reception

Thus, the management device 400 identifies the partial data duplicated through the first network device 200 and the second network device 300.

More specifically, the management apparatus 400 parses the header of the partial data packet received through the 3G network and the WiFi network, thereby recognizing the sequence information designated in each partial data, and recognizing the recognized sequence information. The partial data is rearranged accordingly. In this case, the management apparatus 400 identifies the identifier additionally inserted in the header of the partial data packet, thereby identifying that the partial data is partial data for quality check of each access network. In this regard, as shown in FIG. 6 (a), the terminal device 100 indicates a transmission order in a partial data header having the same order information selected for each of the 3G network and the WiFi network to confirm the quality of each access network. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted and transmitted. Meanwhile, the management apparatus 400 performs rearrangement on the partial data first received through the 3G network or the WiFi network among the partial data having the same order information to restore the transmission target data to be transmitted from the terminal device 100. The target data is restored by combining the rearranged partial data normally, and the received partial data is later deleted after being used for network quality check, thereby minimizing the simultaneous transmission performance deterioration due to duplicate transmission of partial data packets. Done.

Based on this, the management device 400 calculates the state information of the WiFi network based on the reception state of the same partial data duplicated through the first network device 200 and the second network device 300.

More specifically, the management device 400 is received through the second network device 300 of the WiFi network in order to calculate the status information for the WiFi network having a large quality difference according to the quality of the wired Internet network and the number of users compared to the 3G network. Based on the reception status of the partial data having continuous sequence information, the status information of the WiFi network, for example, the number of partial data packets transmitted through the WiFi network is calculated. In this case, when it is determined that the number of partial data packets calculated before the setting time for checking access network quality is less than the threshold value, the management device 400 places a request to stop using the WiFi network in the 3G network. By transmitting to the terminal device 100 through the network device 200, the terminal device 100 stops using the WiFi network, thereby minimizing partial data packet delivery time and waiting time to prevent simultaneous transmission performance degradation. . At this time, the management device 400, as shown in Figure 6 (b), on the header of the partial data packet delivered to the terminal device 100, the stop request (①), the access network quality check for the WiFi network The number of received packets (②) is inserted during the set time.

Thereafter, the management apparatus 400 variably sets a preset data transmission rate based on the state information calculated for the WiFi network.

More specifically, the management apparatus 400 recognizes the quality state of the WiFi network based on the state information calculated for the WiFi network, for example, the number of packets received during the set time for checking the access network quality, thereby making it more wired than the 3G network. Based on the quality of the WiFi network with a large quality difference according to the quality of the internet network and the number of users, the performance of the simultaneous transmission service can be improved by varying the preset data transmission rate for each access network.

Hereinafter, a more specific configuration of the terminal device 100 according to the third embodiment of the present invention will be described with reference to FIG. 2.

That is, the terminal device 100 transmits the same partial data through the first network device 200 and the second network device 300 to transmit the communication unit 110, and the partial data having the same order information to the 3G network and the WiFi network. It has a configuration including a reception control unit 120 to select corresponding to each.

The reception control unit 120 selects the same partial data corresponding to each of the access networks to check the quality of each access network.

More specifically, the reception control unit 120 is an uplink partial data packet for the management device 400 for splitting and transmitting the partial data through the 3G network and the WiFi network according to a preset data transmission rate for each access network. Is present (e.g., ACK, SYN, FIN, Duplicate ACK message, etc.), in order to check the quality of each access network, partial data having continuous sequence information is selected corresponding to the 3G network and corresponding to the 3G network. The partial data having the same order information as the selected partial data is selected corresponding to the WiFi network. For example, the reception controller 120 selects the first partial data packet of the sequence information 1, 2, 3, and 4 corresponding to the 3G network to check the quality of each of the access networks among the partial data divided into the transmission target data. Similarly, the second partial data packets of the order information 1, 2, 3, and 4, which are the same as those of the 3G network, are selected corresponding to the WiFi network.

In addition, the reception control unit 120 inserts an identifier for identifying that the partial data for quality check for each access network.

More specifically, the reception controller 120 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted.

The communication unit 110 transmits duplicately selected partial data for each access network.

More specifically, the communication unit 110 transmits the partial data having the continuous sequence information selected by the management device 400 through the first network device 200 located in the 3G network to check the quality for each access network. In addition, the partial data having the same order information as the partial data transmitted through the 3G network through the second network device 300 located in the WiFi network is repeatedly transmitted for a set time. For example, the communication unit 110 transmits the first partial data packet of the sequence information 1, 2, 3, and 4 among the partial data divided into the transmission target data through the first network device 200 located in the 3G network. In addition, the second partial data packet of the same sequence information 1, 2, 3, and 4 as the 3G network is repeatedly transmitted to the terminal device 100 through the second network device 300 located in the WiFi network. Done.

Thereafter, when the reception controller 120 receives a stop request for the WiFi network from the management apparatus 400, the reception controller 120 stops using the WiFi network.

More specifically, the reception control unit 120 checks the first network device 200 in which the stop request for the WiFi network from the management device 400 is located in the 3G network before the set time for checking the access network quality has elapsed. When received via the WiFi network, the use of the WiFi network is stopped, thereby minimizing partial data packet transmission time and waiting time, thereby preventing deterioration in simultaneous transmission performance. In this regard, the management device 400, as shown in 6 (b), on the header of the partial data packet transmitted to the terminal device 100, the stop request (①) for the WiFi network, confirming the access network quality It is delivered with the number of received packets (②) inserted during the set time for. Meanwhile, in the case of the request for disabling the WiFi network, the status information of the WiFi network with a large difference in quality depending on the quality of the wired Internet network and the number of users compared to the 3G network, that is, through the WiFi network during the set time for checking the access network quality. If the number of received packets is less than the threshold value will be delivered from the management device (400).

Hereinafter, a more specific configuration of the management apparatus 400 according to the third embodiment of the present invention will be described with reference to FIG. 3.

That is, the management device 400 is a communication unit 410 for receiving the partial data dividedly transmitted from the first network device 200 and the second network device 300, the preset preset for each access network based on the reception status of the partial data It has a configuration including a transmission control unit 120 for varying the data transmission rate.

The communication unit 410 receives the same partial data through the first network device 200 and the second network device 300.

More specifically, the communication unit 410 receives the partial data having the continuous sequence information selected by the terminal device 100 through the first network device 200 located in the 3G network to check the quality for each access network. In addition, the second network apparatus 300 located in the WiFi network receives the partial data having the same order information received through the 3G network in duplicate for a set time. For example, the communication unit 410 is a 3G first partial data packet of the order information 1, 2, 3, 4 selected by the terminal device 100 to check the quality of each of the access network of the partial data divided into the transmission target data When received through the first network device 200 of the network, the second partial data packet of the same order information 1, 2, 3, 4 as the 3G network is duplicated through the second network device 300 of the WiFi network likewise. To receive it.

The transmission controller 120 identifies the partial data repeatedly received through the first network device 200 and the second network device 300.

More specifically, the transmission control unit 120 parses the header of the partial data packet received through the 3G network and the WiFi network, thereby recognizing the sequence information specified in each partial data, and recognizing the recognized sequence information. The partial data is rearranged accordingly. At this time, the transmission controller 120 identifies the identifier additionally inserted in the header of the partial data packet, thereby identifying that the partial data is partial data for quality checking of each access network. In this regard, as shown in FIG. 6 (a), the terminal device 100 indicates a transmission order in a partial data header having the same order information selected for each of the 3G network and the WiFi network to confirm the quality of each access network. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted and transmitted. Meanwhile, the transmission controller 120 rearranges the partial data first received through the 3G network or the WiFi network among the partial data having the same order information to restore the transmission target data to be transmitted from the terminal device 100. The target data is restored by combining the rearranged partial data normally, and the received partial data is later deleted after being used for network quality check, thereby minimizing the simultaneous transmission performance deterioration due to duplicate transmission of partial data packets. Done.

Based on this, the transmission controller 120 calculates state information on the WiFi network based on the reception state of the same partial data duplicated through the first network device 200 and the second network device 300.

More specifically, the transmission control unit 120 receives through the second network device 300 of the WiFi network in order to calculate the status information for the WiFi network having a large quality difference according to the quality of the wired Internet network and the number of users compared to the 3G network. Based on the reception status of the partial data having continuous sequence information, the status information of the WiFi network, for example, the number of partial data packets transmitted through the WiFi network is calculated. In this case, when it is determined that the number of partial data packets calculated before the setting time for checking access network quality is less than the threshold value, the transmission control unit 120 places the request to stop using the WiFi network in the 3G network. By transmitting to the terminal device 100 through the network device 200, the terminal device 100 stops using the WiFi network, thereby minimizing partial data packet delivery time and waiting time to prevent simultaneous transmission performance degradation. . At this time, the transmission control unit 120, as shown in Figure 6 (b), on the header of the partial data packet transmitted to the terminal device 100 confirms the use stop request (①), access network quality check for the WiFi network The number of received packets (②) is inserted during the set time.

Thereafter, the transmission controller 120 variably sets a preset data transmission rate based on the state information calculated for the WiFi network.

More specifically, the transmission controller 120 recognizes the quality state of the WiFi network based on the state information calculated for the WiFi network, for example, the number of packets received during the set time for confirming the access network quality. Based on the quality of the WiFi network with a large quality difference according to the quality of the internet network and the number of users, the performance of the simultaneous transmission service can be improved by varying the preset data transmission rate for each access network.

As described above, according to the heterogeneous network-based data transmission system according to the present invention, the partial data divided from the data to be transmitted is transmitted / received using a plurality of heterogeneous networks based on a data transmission rate for each access network. In the simultaneous transmission service environment, the quality of each access network is measured based on the reception status of each access network for the same partial data transmitted redundantly through each access network for a set time, and based on the measured access network quality. By varying the set data transmission rate, it is possible to improve the performance of the simultaneous transmission service.

Hereinafter, a heterogeneous network-based data transmission method according to a first embodiment of the present invention will be described with reference to FIGS. 7 to 9. Here, the above-described configuration shown in Figures 1 to 6 will be described by referring to the reference numerals for convenience of description.

First, a method of operating a heterogeneous network-based simultaneous data transmission system according to a first embodiment of the present invention will be described with reference to FIG. 7.

First, the management apparatus 400 selects the partial data divided from the transmission target data for each access network according to a preset data transmission rate for each access network (S10).

Preferably, the management device 400 checks the preset data transmission rate, that is, the first transmission rate and the second transmission rate for data transmission to the second network device 300 between the access networks, and checks the identified transmission rate. Selecting the first partial data to be transmitted to the first network device 200 among the divided partial data from the transmission target data received from the external device 500 based on, and to the second network device 300 of the remaining partial data The second partial data to be transmitted is selected. At this time, the management device 400 selects the partial data having the continuous sequence information corresponding to the 3G network to check the quality for each access network, and also the partial data having the same sequence information as the selected partial data corresponding to the 3G network. Is selected corresponding to the WiFi network. For example, the management device 400 selects the first partial data packet of the order information 1, 2, 3, and 4 corresponding to the 3G network to check the quality of each of the access networks among the partial data divided into the transmission target data. Similarly, the second partial data packets of the order information 1, 2, 3, and 4, which are the same as those of the 3G network, are selected corresponding to the WiFi network.

Then, the management apparatus 400 inserts an identifier for identifying that the partial data for quality check for each access network (S20).

Preferably, the management apparatus 400 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted.

Then, the management device 400 repeatedly transmits the same partial data selected for each access network (S30).

Preferably, the management device 400 transmits the partial data having the continuous sequence information selected for quality check for each access network through the first network device 200 located in the 3G network and is located in the WiFi network. The partial data having the same order information as the partial data transmitted through the 3G network through the second network device 300 is repeatedly transmitted for a set time. For example, the management device 400 may transmit the first partial data packet of the sequence information 1, 2, 3, and 4 among the partial data divided into the transmission target data through the first network device 200 located in the 3G network. 100 and the second partial data packet of the same sequence information 1, 2, 3, and 4 as the 3G network is duplicated in the terminal device 100 through the second network device 300 located in the WiFi network. Will be delivered.

Next, the terminal device 100 identifies the partial data repeatedly received through the first network device 200 and the second network device 300 (S40).

Preferably, the terminal device 100 performs parsing on the header of the partial data packet received through the 3G network and the WiFi network, thereby recognizing the order information specified in each partial data, and recognizing the order information. The partial data is rearranged accordingly. At this time, the terminal apparatus 100 identifies the identifier additionally inserted in the header of the partial data packet, thereby identifying that the partial data is partial data for quality check of each access network. Meanwhile, the terminal device 100 reorders the partial data first received through the 3G network or the WiFi network among the partial data having the same order information to restore the transmission target data to be transmitted from the management device 400. The target data is restored by combining the rearranged partial data normally, and the received partial data is later deleted after being used for network quality check, thereby minimizing the simultaneous transmission performance deterioration due to duplicate transmission of partial data packets. Done.

Furthermore, the terminal device 100 calculates the state information for each access network based on the reception state of the same partial data duplicated through the first network device 200 and the second network device 300 (S60-S80). ).

Preferably, the terminal device 100 receives a partial data packet received through the first network device 200 of the 3G network and the same partial data received through the second network device 300 of the WiFi network. Based on the state information for each of the 3G network and the WiFi network, for example, delay information (delay), which is the time difference information received between the partial data packets having consecutive sequence information, and the packet loss rate, which is a probability that the partial data packet is not received. loss), and order information of partial data packets are changed to calculate a disorder, which is a probability of being received. At this time, the terminal device 100 preferentially calculates delay information, which is the time difference information received between the partial data packets, corresponding to each of the 3G network and the WiFi network, and confirms that the calculated delay information exceeds a threshold. If so, the transmission stop request for the corresponding access network is transmitted to the management device 400, so that the management device 400 recognizes the access network quality state to stop the operation of transmitting the duplicate partial data packet thereafter.

Then, the terminal device 100 transmits the state information calculated for each access network to the management device 400 (S90).

Preferably, when the setting time for checking the access network quality has elapsed and the duplicate partial data packet is not identified, the terminal device 100 calculates the status information corresponding to each of the 3G network and the WiFi network. Delay information, which is received time difference information between partial data packets having sequence information, packet loss rate, which is a probability that the partial data packet is not received due to loss, and ratio, which is a probability that the sequence information of the partial data packet is changed and received. By delivering a sort rate to the management device 400, the management device 400 may set a predetermined data transmission rate for each access network based on the transmitted state information to improve performance of the simultaneous transmission service. Make sure At this time, the terminal device 100 piggy-backing the calculated state information on the response message transmitted to the management device 400 in accordance with the partial data, that is, as shown in Figure 4 (b) On the header of the response message (Ack) transmitted to the management device 400, access network information (①), transmission stop request (②), delay information (③), packet loss rate (④), and misalignment rate (⑤) ) Is inserted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

Thereafter, the management apparatus 400 variably sets a preset data transmission rate based on the state information transmitted for each access network (S100).

Preferably, the management device 400 is delayed (delay), which is the time difference information received between the state information for each of the 3G network and the WiFi network, for example, the partial data packet having the sequence information, the partial data packet is lost and received Recognizes the quality status of each of the 3G network and the WiFi network based on the probability of packet loss (loss), which is a non-probable probability, and the disorder rate, which is a probability that the order information of partial data packets is changed. Reflecting this, the preset data transmission rate is variably set for each access network.

Hereinafter, an operation method of the terminal device 100 according to the first embodiment of the present invention will be described with reference to FIG. 8.

First, partial data is received through the first network device 200 and the second network device 300 (S110).

Preferably, the communication unit 110 receives the partial data divided from the transmission target data from the management device 400 on the basis of a preset data transmission rate for each access network. That is, the communication unit 110 receives the first partial data through the 3G network, that is, the first network device 200, and receives the second partial data through the WiFi network, that is, the second network device 300. . At this time, the communication unit 110 receives the partial data having the continuous sequence information selected by the management device 400 to check the quality for each access network through the first network device 200 located in the 3G network, and WiFi Through the second network device 300 located in the network, partial data having the same order information received through the 3G network is repeatedly received for a set time. For example, the communication unit 110 is a 3G of the first partial data packet of the order information 1, 2, 3, 4 selected by the management device 400 to check the quality of each of the access network of the partial data divided into the transmission target data When received through the first network device 200 of the network, the second partial data packet of the same order information 1, 2, 3, 4 as the 3G network is duplicated through the second network device 300 of the WiFi network likewise. To receive it.

Then, the partial data repeatedly received through the first network device 200 and the second network device 300 are identified (S120).

Preferably, the reception control unit 120 parses the header of the partial data packet received through the 3G network and the WiFi network, thereby recognizing the order information specified in each partial data. The partial data are rearranged according to the recognized order information. In this case, the reception control unit 120 identifies the identifier additionally inserted in the header of the partial data packet, thereby identifying that the partial data is partial data for checking the quality of each access network. In this regard, the management apparatus 400 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted and transmitted. Meanwhile, the reception controller 120 rearranges the partial data first received through the 3G network or the WiFi network among the partial data having the same order information to restore the transmission target data to be transmitted by the management device 400. The target data is restored by combining the rearranged partial data normally, and the received partial data is later deleted after being used for network quality check, thereby minimizing the simultaneous transmission performance deterioration due to duplicate transmission of partial data packets. Done.

Based on this, state information for each access network is calculated based on a reception state of the same partial data duplicated through the first network device 200 and the second network device 300 (S130-S170).

Preferably, the reception controller 120 receives a partial data packet received through the first network device 200 of the 3G network and the same partial data received through the second network device 300 of the WiFi network. Based on the state information for each of the 3G network and the WiFi network, for example, delay information (delay), which is the time difference information received between the partial data packets having consecutive sequence information, and the packet loss rate, which is a probability that the partial data packet is not received. loss), and order information of partial data packets are changed to calculate a disorder, which is a probability of being received. In this case, the reception controller 120 first calculates delay information, which is the time difference information received between the partial data packets, corresponding to each of the 3G network and the WiFi network, and confirms that the calculated delay information exceeds a threshold. If so, the transmission stop request for the corresponding access network is transmitted to the management device 400, so that the management device 400 recognizes the access network quality state to stop the operation of transmitting the duplicate partial data packet thereafter.

Thereafter, the state information calculated for each access network is transmitted to the management device 400 (S180).

Preferably, the reception control unit 120 when the set time for checking the quality of the access network has elapsed, and the duplicated partial data packet is not identified, the state information calculated for each of the 3G network and the WiFi network, for example, continuous Delay information, which is received time difference information between partial data packets having sequence information, packet loss rate, which is a probability that the partial data packet is not received due to loss, and ratio, which is a probability that the sequence information of the partial data packet is changed and received. By delivering a sort rate to the management device 400, the management device 400 may set a predetermined data transmission rate for each access network based on the transmitted state information to improve performance of the simultaneous transmission service. Make sure In this case, the reception controller 120 piggybacks the calculated state information for each access network on the response message transmitted to the management device 400 according to partial data reception, that is, as shown in FIG. 4 (b). As described above, on the header of the response message (Ack) transmitted to the management device 400, access network information (1), transmission stop request (2), delay information (3), packet loss rate (4), and misalignment It is delivered with the rate (⑤) inserted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

Hereinafter, an operation method of the management apparatus 400 according to the first embodiment of the present invention will be described with reference to FIG. 9.

First, the partial data divided from the data to be transmitted is selected for each access network according to a data transmission rate preset for each access network (S210).

Preferably, the transmission controller 120 checks a preset data transmission rate, that is, a first transmission rate and a second transmission rate for data transmission to the second network apparatus 300, between the access networks, and checks the identified transmission rate. Selecting the first partial data to be transmitted to the first network device 200 among the divided partial data from the transmission target data received from the external device 500 based on, and to the second network device 300 of the remaining partial data The second partial data to be transmitted is selected. At this time, the transmission control unit 120 selects the partial data having continuous sequence information corresponding to the 3G network to confirm the quality of each access network, and also has the partial data having the same sequence information as the selected partial data corresponding to the 3G network. Is selected corresponding to the WiFi network. For example, the transmission controller 120 selects the first partial data packet of the sequence information 1, 2, 3, and 4 corresponding to the 3G network to check the quality of each of the access networks among the partial data divided into the transmission target data. Similarly, the second partial data packets of the order information 1, 2, 3, and 4, which are the same as those of the 3G network, are selected corresponding to the WiFi network.

Then, an identifier for identifying that the partial data for quality check for each access network is inserted (S220).

Preferably, the transmission control unit 120 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted.

Thereafter, the same partial data selected for each access network is repeatedly transmitted (S230).

Preferably, the communication unit 410 transmits the partial data having the continuous sequence information selected by the management device 400 through the first network device 200 located in the 3G network to check the quality for each access network. In addition, the partial data having the same order information as the partial data transmitted through the 3G network through the second network device 300 located in the WiFi network is repeatedly transmitted for a set time. For example, the communication unit 410 may transmit the first partial data packet of the sequence information 1, 2, 3, and 4 among the partial data divided into the transmission target data through the first network device 200 located in the 3G network. In addition, the second partial data packet of the same sequence information 1, 2, 3, and 4 as the 3G network is repeatedly transmitted to the terminal device 100 through the second network device 300 located in the WiFi network. Done.

Furthermore, state information calculated based on a reception state for each access network for the same partial data transmitted is received (S240-S260).

Preferably, the communication unit 410 and the partial data packet transmitted through the first network device 200 of the 3G network when the set time for transmitting the same partial data for each access network elapses to check the quality of each access network and the like; On the basis of the reception state for the same partial data transmitted through the second network device 300 of the WiFi network, the terminal device 100 receives the state information for each of the 3G network and the WiFi network. At this time, in the case of the state information transmitted from the terminal device 100, for example, delay information (delay) which is the time difference information received between the partial data packets having continuous sequence information, a packet having a probability that the partial data packet is lost and not received. The loss rate and the order information of the partial data packet are changed to include a disorder rate which is a probability of being received. In this case, the delay information (delay) is first calculated by the terminal device 100, when it is confirmed that the calculated delay information exceeds the threshold, the communication unit 410 is connected to the 3G network or WiFi network Receives a request to stop the transmission from the terminal device 100, accordingly, the transmission control unit 120 recognizes the quality of the access network before the set time for transmitting the same partial data, the quality of the access network The transmission of the duplicate partial data packet is stopped for confirmation. In this regard, the terminal apparatus 100 piggy-backs the calculated state information for each access network on the response message transmitted to the management apparatus 400 according to the partial data reception, that is, FIG. 4 (b). As shown in FIG. 4, access network information (1), transmission stop request (2), delay information (3), packet loss rate (4), and the like on the header of the response message (Ack) transmitted to the management device 400, and It is delivered with the misalignment rate (⑤) inserted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

Thereafter, the preset data transmission rate is variably set based on the state information transmitted for each access network (S270).

Preferably, the transmission controller 120 receives the delay information (delay), which is the time difference information between the partial data packets having the sequence information of each of the 3G network and the WiFi network, for example, consecutive sequence information, and is lost. Recognizes the quality status of each of the 3G network and the WiFi network based on the probability of packet loss (loss), which is a non-probable probability, and the disorder rate, which is a probability that the order information of partial data packets is changed. Reflecting this, the preset data transmission rate is variably set for each access network.

Hereinafter, a heterogeneous network-based data transmission method according to a second embodiment of the present invention will be described with reference to FIGS. 10 to 12. Here, the above-described configuration shown in Figures 1 to 6 will be described by referring to the reference numerals for convenience of description.

First, a method of operating a heterogeneous network-based data transmission system according to a second embodiment of the present invention will be described with reference to FIG. 10.

First, the management device 400 selects the partial data divided from the transmission target data for each access network according to a preset data transmission rate for each access network (S310).

Preferably, the management device 400 checks the preset data transmission rate, that is, the first transmission rate and the second transmission rate for data transmission to the second network device 300 between the access networks, and checks the identified transmission rate. Selecting the first partial data to be transmitted to the first network device 200 among the divided partial data from the transmission target data received from the external device 500 based on, and to the second network device 300 of the remaining partial data The second partial data to be transmitted is selected. At this time, the management device 400 selects the partial data having the continuous sequence information corresponding to the 3G network to check the quality for each access network, and also the partial data having the same sequence information as the selected partial data corresponding to the 3G network. Is selected corresponding to the WiFi network. For example, the management device 400 selects the first partial data packet of the order information 1, 2, 3, and 4 corresponding to the 3G network to check the quality of each of the access networks among the partial data divided into the transmission target data. Similarly, the second partial data packets of the order information 1, 2, 3, and 4, which are the same as those of the 3G network, are selected corresponding to the WiFi network.

Then, the management apparatus 400 inserts an identifier for identifying that the partial data for quality check for each access network (S320).

Preferably, the management device 400 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted.

Then, the management apparatus 400 transmits the same partial data selected for each access network in duplicate (S330).

Preferably, the management device 400 transmits the partial data having the continuous sequence information selected for quality check for each access network through the first network device 200 located in the 3G network and is located in the WiFi network. The partial data having the same order information as the partial data transmitted through the 3G network through the second network device 300 is repeatedly transmitted for a set time. For example, the management device 400 may transmit the first partial data packet of the sequence information 1, 2, 3, and 4 among the partial data divided into the transmission target data through the first network device 200 located in the 3G network. 100 and the second partial data packet of the same sequence information 1, 2, 3, and 4 as the 3G network is duplicated in the terminal device 100 through the second network device 300 located in the WiFi network. Will be delivered.

Accordingly, the terminal device 100 identifies the partial data duplicated through the first network device 200 and the second network device 300 (S340).

Preferably, the terminal device 100 performs parsing on the header of the partial data packet received through the 3G network and the WiFi network, thereby recognizing the order information specified in each partial data, and recognizing the order information. The partial data is rearranged accordingly. At this time, the terminal apparatus 100 identifies the identifier additionally inserted in the header of the partial data packet, thereby identifying that the partial data is partial data for quality check of each access network. Meanwhile, the terminal device 100 reorders the partial data first received through the 3G network or the WiFi network among the partial data having the same order information to restore the transmission target data to be transmitted from the management device 400. The target data is restored by combining the rearranged partial data normally, and the received partial data is later deleted after being used for network quality check, thereby minimizing the simultaneous transmission performance deterioration due to duplicate transmission of partial data packets. Done.

Based on this, the terminal device 100 calculates state information on the WiFi network based on the reception state of the same partial data duplicated through the first network device 200 and the second network device 300 ( S350-S370).

Preferably, the terminal device 100 receives through the second network device 300 of the WiFi network in order to calculate the status information for the WiFi network having a large quality difference according to the quality of the wired Internet network and the number of users compared to the 3G network. Calculating the state information of the WiFi network, for example, the number of partial data packets transmitted through the WiFi network, and the partial data throughput transmitted through the WiFi network, based on the reception state of the partial data having consecutive sequence information. Done. In this case, when it is determined that the calculated number of partial data packets and the partial data throughput are less than the threshold value, the terminal device 100 places a request to stop using the WiFi network in the 3G network 200. By transmitting to the management device 400, the management device 400 recognizes the quality status of the WiFi network, and subsequently variablely set the preset data transmission rate for each access network so that all partial data packets are transmitted through the 3G network. Let's do it.

Further, the terminal device 100 transmits the state information calculated in response to the WiFi network to the management device 400 (S380).

Preferably, when the setting time for checking the access network quality has elapsed and the duplicate partial data packet is not identified, the terminal device 100 calculates the state information corresponding to the WiFi network, for example, for checking the access network quality. By transmitting the number of packets received during the set time, and the partial data throughput during the set time for checking the access network quality to the management device 400, by allowing the management device 400 to recognize the WiFi network quality state, Reflecting this, a variable data transmission rate is set for each access network to improve the performance of the simultaneous transmission service. At this time, the terminal device 100 piggy-backing the calculated state information on the response message transmitted to the management device 400 according to the partial data reception, that is, as shown in FIG. On the header of the response message (Ack) transmitted to the management device 400, the stop request for the WiFi network (①), the number of packets received during the set time for checking the access network quality (②), and the access network quality The partial data rate (③) during the set time for confirmation is transmitted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

Thereafter, the management apparatus 400 variably sets a preset data transmission rate based on the state information calculated for the WiFi network (S390).

Preferably, the management device 400 is a state information calculated for the WiFi network, for example, the number of packets received during the set time for checking the access network quality, and the partial data transmission rate during the set time for checking the access network quality ( By recognizing the quality of the WiFi network based on throughput, the data transmission rate is changed for each access network based on the quality of the WiFi network, which has a large quality difference according to the quality of the wired Internet network and the number of users compared to the 3G network. By setting it, the performance of the simultaneous transmission service can be improved.

Hereinafter, an operation method of the terminal device 100 according to the second embodiment of the present invention will be described with reference to FIG. 11.

First, partial data is received through the first network device 200 and the second network device 300 (S410).

Preferably, the communication unit 110 receives the partial data divided from the transmission target data from the management device 400 on the basis of a preset data transmission rate for each access network. That is, the communication unit 110 receives the first partial data through the 3G network, that is, the first network device 200, and receives the second partial data through the WiFi network, that is, the second network device 300. . At this time, the communication unit 110 receives the partial data having the continuous sequence information selected by the management device 400 to check the quality for each access network through the first network device 200 located in the 3G network, and WiFi Through the second network device 300 located in the network, partial data having the same order information received through the 3G network is repeatedly received for a set time. For example, the communication unit 110 is a 3G of the first partial data packet of the order information 1, 2, 3, 4 selected by the management device 400 to check the quality of each of the access network of the partial data divided into the transmission target data When received through the first network device 200 of the network, the second partial data packet of the same order information 1, 2, 3, 4 as the 3G network is duplicated through the second network device 300 of the WiFi network likewise. To receive it.

Then, the partial data duplicated through the first network device 200 and the second network device 300 is identified (S420).

Preferably, the reception control unit 120 parses the header of the partial data packet received through the 3G network and the WiFi network, thereby recognizing the sequence information specified in each partial data, and recognizing the recognized sequence information. The partial data is rearranged accordingly. In this case, the reception control unit 120 identifies the identifier additionally inserted in the header of the partial data packet, thereby identifying that the partial data is partial data for checking the quality of each access network. In this regard, the management device 400 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted and transmitted. Meanwhile, the reception controller 120 rearranges the partial data first received through the 3G network or the WiFi network among the partial data having the same order information to restore the transmission target data to be transmitted by the management device 400. The target data is restored by combining the rearranged partial data normally, and the received partial data is later deleted after being used for network quality check, thereby minimizing the simultaneous transmission performance deterioration due to duplicate transmission of partial data packets. Done.

Next, the state information for the WiFi network is calculated based on the reception state of the same partial data duplicated through the first network device 200 and the second network device 300 (S430-S450).

Preferably, the reception control unit 120 receives through the second network device 300 of the WiFi network in order to calculate the status information for the WiFi network having a large quality difference according to the quality of the wired Internet network and the number of users compared to the 3G network. Calculating the state information of the WiFi network, for example, the number of partial data packets transmitted through the WiFi network, and the partial data throughput transmitted through the WiFi network, based on the reception state of the partial data having consecutive sequence information. Done. In this case, when it is determined that the calculated number of partial data packets and the partial data throughput are less than a threshold value, the reception controller 120 places a request to stop using the WiFi network in the 3G network 200. By transmitting to the management device 400, the management device 400 recognizes the quality status of the WiFi network, and subsequently variablely set the preset data transmission rate for each access network so that all partial data packets are transmitted through the 3G network. Let's do it.

Thereafter, the state information calculated corresponding to the WiFi network is transmitted to the management device 400 (S460).

Preferably, the reception control unit 120 when the set time for checking the access network quality has elapsed, and the duplicated partial data packet is not identified, the state information calculated for the WiFi network, for example, for checking the access network quality. By transmitting the number of packets received during the set time, and the partial data throughput during the set time for checking the access network quality to the management device 400, by allowing the management device 400 to recognize the WiFi network quality state, Reflecting this, a variable data transmission rate is set for each access network to improve the performance of the simultaneous transmission service. At this time, the reception control unit 120 piggy-backing the calculated state information on the response message transmitted to the management device 400 in accordance with the partial data, that is, as shown in Figure 5 (b) On the header of the response message (Ack) transmitted to the management device 400, the stop request for the WiFi network (①), the number of packets received during the set time for checking the access network quality (②), and the access network quality The partial data rate (③) during the set time for confirmation is transmitted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

Hereinafter, an operation method of the management apparatus 400 according to an embodiment of the present invention will be described with reference to FIG. 12.

First, the partial data divided from the transmission target data is selected for each access network according to a preset data transmission rate for each access network (S510).

Preferably, the transmission controller 120 checks a preset data transmission rate, that is, a first transmission rate and a second transmission rate for data transmission to the second network apparatus 300, between the access networks, and checks the identified transmission rate. Selecting the first partial data to be transmitted to the first network device 200 among the divided partial data from the transmission target data received from the external device 500 based on, and to the second network device 300 of the remaining partial data The second partial data to be transmitted is selected. At this time, the transmission control unit 120 selects the partial data having continuous sequence information corresponding to the 3G network to confirm the quality of each access network, and also has the partial data having the same sequence information as the selected partial data corresponding to the 3G network. Is selected corresponding to the WiFi network. For example, the transmission controller 120 selects the first partial data packet of the sequence information 1, 2, 3, and 4 corresponding to the 3G network to check the quality of each of the access networks among the partial data divided into the transmission target data. Similarly, the second partial data packets of the order information 1, 2, 3, and 4, which are the same as those of the 3G network, are selected corresponding to the WiFi network.

Then, an identifier for identifying that the partial data for quality check for each access network is inserted (S520).

Preferably, the transmission control unit 120 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted.

Thereafter, the same partial data selected for each access network is repeatedly transmitted (S530).

Preferably, the communication unit 420 transmits the partial data having the continuous sequence information selected by the management device 400 through the first network device 200 located in the 3G network to check the quality of each access network. In addition, the partial data having the same order information as the partial data transmitted through the 3G network through the second network device 300 located in the WiFi network is repeatedly transmitted for a set time. For example, the communication unit 420 may transmit the first partial data packet of the sequence information 1, 2, 3, and 4 among the partial data divided into the transmission target data through the first network device 200 located in the 3G network. In addition, the second partial data packet of the same sequence information 1, 2, 3, and 4 as the 3G network is repeatedly transmitted to the terminal device 100 through the second network device 300 located in the WiFi network. Done.

Then, it receives the state information calculated based on the reception state of the WiFi network for the same partial data transmitted (S540-S560).

Preferably, the communication unit 420 is applied to the same partial data transmitted through the second network device 300 of the WiFi network when a set time for transmitting the same partial data for each access network elapses to check the quality for each access network. Receives the state information on the WiFi network calculated by the terminal device 100 based on the received state. At this time, in the case of the state information transmitted from the terminal device 100, for example, the number of packets received through the WiFI network during the setting time for checking the access network quality, and the part of the WiFI network during the setting time for checking the access network quality. The data throughput may correspond. Meanwhile, the number of packets received through the WiFI network during the setting time for the access network quality before the setting time for the access network quality check, and the partial data transmission rate of the WiFI network during the setting time for the access network quality check When it is determined that the throughput is less than the threshold value, the communication unit 420 receives a stop request for the WiFi network from the terminal device 100, and accordingly, the control unit 410 transmits the same partial data. By recognizing the quality of the WiFi network before this elapses, it is possible to variably set a preset data transmission rate for each access network so that all partial data packets are transmitted through the 3G network. In this regard, the terminal device 100 piggy-backing the calculated state information on the response message transmitted to the management device 400 according to the partial data reception, that is, as shown in FIG. As described above, on the header of the response message (Ack) transmitted to the management device 400, the stop request (①) for the WiFi network, the number of packets received during the set time for checking the access network quality (②), and the access The partial data rate ③ during the set time for checking network quality is inserted. On the other hand, if a response message transmitted according to partial data reception does not occur during the set time, a separate dummy packet is generated, and the packet loss rate for each access network is piggybacked into the dummy packet. It can be delivered to the management device (400).

Subsequently, the preset data transmission rate is variably set based on the state information calculated for the WiFi network (S570).

Preferably, the control unit 410 is the state information calculated for the WiFi network, for example, the number of packets received during the set time for checking the access network quality, and the partial data transmission rate during the set time for checking the access network quality (throughput). By recognizing the quality of the WiFi network based on the quality of the WiFi network, a variable data transmission rate is set for each access network based on the quality of the WiFi network with a large quality difference according to the quality of the wired Internet network and the number of users. The performance of the simultaneous transmission service can be improved.

Hereinafter, a heterogeneous network-based data transmission method according to a third embodiment of the present invention will be described with reference to FIGS. 13 to 15. Here, the above-described configuration shown in Figures 1 to 6 will be described by referring to the reference numerals for convenience of description.

First, a method of operating a heterogeneous network-based data transmission system according to a third embodiment of the present invention will be described with reference to FIG. 13.

First, the terminal apparatus 100 selects the same partial data corresponding to each of the access networks in order to check the quality of each access network (S610).

Preferably, the terminal device 100 is an uplink partial data packet for the management device 400 that transmits the partial data through the 3G network and the WiFi network according to a preset data transmission rate for each access network. Is present (e.g., ACK, SYN, FIN, Duplicate ACK message, etc.), in order to check the quality of each access network, partial data having continuous sequence information is selected corresponding to the 3G network and corresponding to the 3G network. The partial data having the same order information as the selected partial data is selected corresponding to the WiFi network. For example, the terminal device 100 selects the first partial data packet of the order information 1, 2, 3, and 4 corresponding to the 3G network to check the quality of each of the access networks among the partial data divided into the transmission target data. Similarly, the second partial data packets of the order information 1, 2, 3, and 4, which are the same as those of the 3G network, are selected corresponding to the WiFi network.

Then, the terminal device 100 inserts an identifier for identifying that the partial data for quality check for each access network (S620).

Preferably, the terminal device 100 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted.

Then, the terminal device 100 transmits the same partial data selected for each access network in duplicate (S630).

Preferably, the terminal device 100 transmits the partial data having the continuous sequence information selected by the management device 400 through the first network device 200 located in the 3G network to check the quality of each access network. In addition, the partial data having the same order information as the partial data transmitted through the 3G network through the second network device 300 located in the WiFi network is repeatedly transmitted for a set time. For example, the management device 400 may transmit the first partial data packet of the sequence information 1, 2, 3, and 4 among the partial data divided into the transmission target data through the first network device 200 located in the 3G network. 100 and the second partial data packet of the same sequence information 1, 2, 3, and 4 as the 3G network is duplicated in the terminal device 100 through the second network device 300 located in the WiFi network. Will be delivered.

Next, the management device 400 identifies the partial data duplicated through the first network device 200 and the second network device 300 (S640).

Preferably, the management device 400 performs parsing on the header of the partial data packet received through the 3G network and the WiFi network, thereby recognizing the order information specified in each partial data and recognizing the recognized order information. The partial data is rearranged accordingly. In this case, the management apparatus 400 identifies the identifier additionally inserted in the header of the partial data packet, thereby identifying that the partial data is partial data for quality check of each access network. In this regard, as shown in FIG. 6 (a), the terminal device 100 indicates a transmission order in a partial data header having the same order information selected for each of the 3G network and the WiFi network to confirm the quality of each access network. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted and transmitted. Meanwhile, the management apparatus 400 performs rearrangement on the partial data first received through the 3G network or the WiFi network among the partial data having the same order information to restore the transmission target data to be transmitted from the terminal device 100. The target data is restored by combining the rearranged partial data normally, and the received partial data is later deleted after being used for network quality check, thereby minimizing the simultaneous transmission performance deterioration due to duplicate transmission of partial data packets. Done.

Based on this, the management device 400 calculates the state information of the WiFi network based on the reception state of the same partial data duplicated through the first network device 200 and the second network device 300 ( S650-S680).

Preferably, the management device 400 is received through the second network device 300 of the WiFi network in order to calculate the status information for the WiFi network having a large quality difference according to the quality of the wired Internet network and the number of users compared to the 3G network. Based on the reception status of the partial data having continuous sequence information, the status information of the WiFi network, for example, the number of partial data packets transmitted through the WiFi network is calculated. In this case, when it is determined that the number of partial data packets calculated before the setting time for checking access network quality is less than the threshold value, the management device 400 places a request to stop using the WiFi network in the 3G network. By transmitting to the terminal device 100 through the network device 200, the terminal device 100 stops using the WiFi network, thereby minimizing partial data packet delivery time and waiting time to prevent simultaneous transmission performance degradation. . At this time, the management device 400, as shown in Figure 6 (b), on the header of the partial data packet delivered to the terminal device 100, the stop request (①), the access network quality check for the WiFi network The number of received packets (②) is inserted during the set time.

Thereafter, the management apparatus 400 variably sets a preset data transmission rate based on the state information calculated for the WiFi network (S690).

Preferably, the management device 400 is wired compared to the 3G network by recognizing the quality of the WiFi network based on the state information calculated for the WiFi network, for example, the number of packets received during the set time for checking the access network quality. Based on the quality of the WiFi network with a large quality difference according to the quality of the internet network and the number of users, the performance of the simultaneous transmission service can be improved by varying the preset data transmission rate for each access network.

Hereinafter, an operation method of the terminal device 100 according to the third embodiment of the present invention will be described with reference to FIG. 14.

First, in order to check the quality of each access network, the same partial data is selected corresponding to each access network (S710).

Preferably, the reception control unit 120 is an uplink partial data packet for the management device 400 for splitting and transmitting the partial data through the 3G network and the WiFi network according to a preset data transmission rate for each access network. Is present (e.g., ACK, SYN, FIN, Duplicate ACK message, etc.), in order to check the quality of each access network, partial data having continuous sequence information is selected corresponding to the 3G network and corresponding to the 3G network. The partial data having the same order information as the selected partial data is selected corresponding to the WiFi network. For example, the reception controller 120 selects the first partial data packet of the sequence information 1, 2, 3, and 4 corresponding to the 3G network to check the quality of each of the access networks among the partial data divided into the transmission target data. Similarly, the second partial data packets of the order information 1, 2, 3, and 4, which are the same as those of the 3G network, are selected corresponding to the WiFi network.

Then, an identifier for identifying that the partial data for quality check for each access network is inserted (S720).

Preferably, the reception control unit 120 indicates the transmission order in the partial data header having the same order information selected corresponding to each of the 3G network and the WiFi network for checking the quality for each access network as shown in FIG. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted.

Thereafter, the same partial data selected for each access network is repeatedly transmitted (S730).

Preferably, the communication unit 110 transmits the partial data having the continuous sequence information selected by the management device 400 through the first network device 200 located in the 3G network to check the quality of each access network. In addition, the partial data having the same order information as the partial data transmitted through the 3G network through the second network device 300 located in the WiFi network is repeatedly transmitted for a set time. For example, the communication unit 110 transmits the first partial data packet of the sequence information 1, 2, 3, and 4 among the partial data divided into the transmission target data through the first network device 200 located in the 3G network. In addition, the second partial data packet of the same sequence information 1, 2, 3, and 4 as the 3G network is repeatedly transmitted to the terminal device 100 through the second network device 300 located in the WiFi network. Done.

Thereafter, when the reception controller 120 receives a stop request for the WiFi network from the management apparatus 400, the reception controller 120 stops the use of the WiFi network (S740-S760).

Preferably, the reception controller 120 checks the first network device 200 in which a stop request for the WiFi network from the management device 400 is located in the 3G network before the setting time for checking the access network quality has elapsed. When received via the WiFi network, the use of the WiFi network is stopped, thereby minimizing partial data packet transmission time and waiting time, thereby preventing deterioration in simultaneous transmission performance. In this regard, the management device 400, as shown in 6 (b), on the header of the partial data packet transmitted to the terminal device 100, the stop request (①) for the WiFi network, confirming the access network quality It is delivered with the number of received packets (②) inserted during the set time for. Meanwhile, in the case of the request for disabling the WiFi network, the status information of the WiFi network with a large difference in quality depending on the quality of the wired Internet network and the number of users compared to the 3G network, that is, through the WiFi network during the set time for checking the access network quality. If the number of received packets is less than the threshold value will be delivered from the management device (400).

Hereinafter, an operation method of the management apparatus 400 according to the third embodiment of the present invention will be described with reference to FIG. 15.

First, the same partial data is received through the first network device 200 and the second network device 300 (S810).

Preferably, the communication unit 410 receives the partial data having the continuous sequence information selected by the terminal device 100 through the first network device 200 located in the 3G network to check the quality of each access network. In addition, the second network apparatus 300 located in the WiFi network receives the partial data having the same order information received through the 3G network in duplicate for a set time. For example, the communication unit 410 is a 3G first partial data packet of the order information 1, 2, 3, 4 selected by the terminal device 100 to check the quality of each of the access network of the partial data divided into the transmission target data When received through the first network device 200 of the network, the second partial data packet of the same order information 1, 2, 3, 4 as the 3G network is duplicated through the second network device 300 of the WiFi network likewise. To receive it.

Then, the partial data repeatedly received through the first network device 200 and the second network device 300 are identified (S820).

Preferably, the transmission control unit 120 parses the header of the partial data packet received through the 3G network and the WiFi network, thereby recognizing the sequence information specified in each partial data, and recognizing the sequence information. The partial data is rearranged accordingly. At this time, the transmission controller 120 identifies the identifier additionally inserted in the header of the partial data packet, thereby identifying that the partial data is partial data for quality checking of each access network. In this regard, as shown in FIG. 6 (a), the terminal device 100 indicates a transmission order in a partial data header having the same order information selected for each of the 3G network and the WiFi network to confirm the quality of each access network. Order information (①) and an identifier (②) indicating a duplicate partial data packet for network quality check are inserted and transmitted. Meanwhile, the transmission controller 120 rearranges the partial data first received through the 3G network or the WiFi network among the partial data having the same order information to restore the transmission target data to be transmitted from the terminal device 100. The target data is restored by combining the rearranged partial data normally, and the received partial data is later deleted after being used for network quality check, thereby minimizing the simultaneous transmission performance deterioration due to duplicate transmission of partial data packets. Done.

Based on this, the state information of the WiFi network is calculated based on the reception state of the same partial data duplicated through the first network device 200 and the second network device 300 (S830-S850).

Preferably, the transmission control unit 120 receives through the second network device 300 of the WiFi network in order to calculate the status information for the WiFi network having a large quality difference according to the quality of the wired Internet network and the number of users compared to the 3G network. Based on the reception status of the partial data having continuous sequence information, the status information of the WiFi network, for example, the number of partial data packets transmitted through the WiFi network is calculated. In this case, when it is determined that the number of partial data packets calculated before the setting time for checking access network quality is less than the threshold value, the transmission control unit 120 places the request to stop using the WiFi network in the 3G network. By transmitting to the terminal device 100 through the network device 200, the terminal device 100 stops using the WiFi network, thereby minimizing partial data packet delivery time and waiting time to prevent simultaneous transmission performance degradation. . At this time, the transmission control unit 120, as shown in Figure 6 (b), on the header of the partial data packet transmitted to the terminal device 100 confirms the use stop request (①), access network quality check for the WiFi network The number of received packets (②) is inserted during the set time.

Subsequently, the preset data transmission rate is variably set based on the state information calculated for the WiFi network (S860).

Preferably, the transmission controller 120 recognizes the quality of the WiFi network based on the number of packets received during the set time for checking the access network quality, for example, the wired network compared to the 3G network. Based on the quality of the WiFi network with a large quality difference according to the quality of the internet network and the number of users, the performance of the simultaneous transmission service can be improved by varying the preset data transmission rate for each access network.

As described above, according to the heterogeneous network-based data transmission method according to the present invention, the partial data divided from the data to be transmitted is transmitted / received using a plurality of heterogeneous networks based on a data transmission rate for each access network. In the simultaneous transmission service environment, the quality of each access network is measured based on the reception status of each access network for the same partial data transmitted redundantly through each access network for a set time, and based on the measured access network quality. By varying the set data transmission rate, it is possible to improve the performance of the simultaneous transmission service.

Meanwhile, the simultaneous network-based data concurrent transfer method according to an embodiment of the present invention may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

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 heterogeneous network-based simultaneous data transmission method according to the present invention and the apparatus applied thereto, the quality of each access network is measured based on the reception status of each access network for the same partial data transmitted redundantly through each access network for a set time. In addition, it is possible to improve the performance of the simultaneous transmission service by varying the preset data transmission rate based on the measured access network quality. It is an invention with industrial applicability because the device is commercially available or commercially available, and it is practically obvious.

100: terminal device
110: communication unit 120: reception control unit
200: first network device
300: second network device
400: management device
410: communication unit 420: transmission control unit
500: External device

Claims (10)

A communication unit for simultaneously transmitting the partial data divided from the transmission target data to a receiving device through two or more access networks; And
Selecting the specific partial data from the partial data to simultaneously transmit the specific partial data to both of the two or more access networks, and based on the reception status of the specific partial data in each of the two or more access networks; Heterogeneous network-based simultaneous data transmission apparatus comprising a transmission control unit for determining the network state for each network. The method of claim 1,
The transmission control unit,
Heterogeneous network-based simultaneous data transmission apparatus characterized in that the variable data transmission rate for each of the two or more access networks is variably set or not a specific access network is used among the two or more access networks according to the network condition. The method of claim 1,
The specific partial data,
And heterogeneous network-based data transmission and transmission apparatus comprising an identifier for identifying that the specific partial data is partial data for determining the network state. The method of claim 1,
The transmission control unit,
And transmitting the specific partial data simultaneously to both of the two or more access networks during a preset time period. A communication unit which receives the partial data divided from the transmission target data from the transmitting apparatus through two or more connection networks based on a preset data transmission rate for each connection network; And
When the same specific partial data of the partial data is received through both of the two or more access networks, information on a reception state of the same specific partial data in each of the two or more access networks is obtained, and the information is transmitted to each of the two or more access networks. Receiving control unit for determining the network status for,
Wherein,
And heterogeneous network-based data transmission / reception device, characterized in that providing information on the reception state to the transmitter. The method of claim 5, wherein
The specific partial data,
And heterogeneous network-based data simultaneous transmission / reception apparatus, characterized in that it comprises an identifier for identifying that the specific partial data is partial data for obtaining the information on the reception status. The method of claim 5, wherein
The information on the reception state,
Delay information indicating a difference in reception time between the specific partial data for each of the two or more access networks, information on the number of unreceived specific partial data among the specific partial data, and a transmission order of the specific partial data and reception of the specific partial data. Heterogeneous network-based simultaneous data transmission and reception apparatus characterized in that it comprises at least one of the number information of the specific partial data does not match. A data transmission step of simultaneously transmitting the selected partial data by dividing the transmission target data based on a data transmission rate for each access network to two or more access networks to a receiving device;
A data redundant transmission step of selecting specific partial data from the partial data and simultaneously transmitting the specific partial data to both of the two or more access networks; And
And determining a network state for each of the two or more access networks based on a reception state of the specific partial data in each of the two or more access networks. The method of claim 8,
The method comprises:
Heterogeneous network-based data transmission method, characterized in that it further comprises the step of varying the data transmission rate in accordance with the network state or the transmission rate is not used for a specific access network. A data receiving step of receiving the partial data divided from the transmission target data from the transmitting apparatus through two or more connection networks based on a preset data transmission rate for each connection network;
A duplicate data identification step of confirming that the same specific partial data of the partial data is received through both the two or more access networks;
An information obtaining step of obtaining information on a reception state of the specific partial data in each of the two or more access networks; And
And providing an information on the reception state to the transmitter so that a network state of each of the two or more access networks can be determined.

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