KR20130017880A - Apparatus and method for simultaneously transmitting data in heterogeneous network - Google Patents

Abstract

PURPOSE: A heterogeneous network based data simultaneous transmission service method and apparatus thereof are provided to transmit divided data according to a predetermined data transmission rate. CONSTITUTION: A distribution rate setting unit(110) sets data transmission rates in a network. A control unit(120) selects part data divided from transmission target data based on a data transmission rates in the set network. The control unit provides the selected part data according to a transmission delay value in the network. A communication unit(130) transmits the provided part data through heterogeneous networks. The distribution rate setting unit confirms data transmission rates in the network. The distribution setting unit sets the data transmission rate in the network corresponding to the confirmed data transmission rate. [Reference numerals] (110) Distribution rate setting unit; (120) Control unit; (130) Communication unit

Description

Heterogeneous network-based data transmission service method and apparatus applied thereto {APPARATUS AND METHOD FOR SIMULTANEOUSLY TRANSMITTING DATA IN HETEROGENEOUS NETWORK}

The present invention relates to a data simultaneous transmission method, and more particularly, to divide data to be transmitted simultaneously in a heterogeneous network environment, the data transmission rate for each network considering the data transmission rate (Throughput) for each network The present invention relates to a heterogeneous network-based simultaneous data transmission service method for setting and dividing data to be transmitted according to a set transmission rate, and having a delay difference corresponding to the data transmission rate, and a method of operating a transmitter and a transmitter.

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.

The present method in which a terminal device uses a data service in a heterogeneous network environment in which a plurality of networks are mixed is a method in which a controllability of a provider is excluded by an access network selection method by directly changing a terminal device user It is a passive method when considering the position of the business operator.

Meanwhile, as various wireless devices such as smartphones and tablet PCs are increasing, data rates are getting cheaper, and various large data services are increasing at the same time, as network load rate of operators is rapidly increasing, network investment is excessively expended and service stability. The situation is being threatened.

Accordingly, there is a need for a new service method for efficiently selecting an access network of a terminal device according to the state of a network in a heterogeneous network environment where a plurality of networks are mixed and efficiently transmitting data using the selected network.

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.

The present method in which a terminal device uses a data service in a heterogeneous network environment in which a plurality of networks are mixed is a method in which a controllability of a provider is excluded by an access network selection method by directly changing a terminal device user It is a passive method when considering the position of the business operator.

Meanwhile, as various wireless devices such as smartphones and tablet PCs are increasing, data rates are getting cheaper, and various large data services are increasing at the same time, as network load rate of operators is rapidly increasing, network investment is excessively expended and service stability. The situation is being threatened.

Accordingly, there is a need for a new service method for efficiently selecting an access network of a terminal device according to the state of a network in a heterogeneous network environment where a plurality of networks are mixed and efficiently transmitting data using the selected network.

A transmission apparatus according to the first aspect of the present invention for achieving the above object, the distribution rate setting unit for setting the data transmission rate for each network; A control unit selecting partial data divided from transmission target data for each network based on the set data transmission rate for each network, and providing the selected partial data corresponding to a transmission delay value designated for each network; And a communication unit configured to transmit the divided partial data through heterogeneous networks.

Preferably, the distribution rate setting unit checks the data transmission rate for each network, and sets the data transmission rate for each network in response to the confirmed data transmission rate.

Preferably, the control unit is characterized in that for determining the transmission order for each network based on the transmission delay value, and providing the selected partial data in accordance with the determined transmission order.

Preferably, the control unit sequentially stores the selected partial data in a transmission buffer designated for each network according to the order information specified in the partial data, and sequentially stores the stored partial data in the reception device in correspondence to the designated order information. In order to transfer, the partial data stored for each network is extracted and provided based on the transmission delay value.

Preferably, when the first transmission delay value is specified in the first network and the second transmission delay value is specified in the second network, the controller compares the first transmission delay value and the second transmission delay value, and When the first transmission delay value is smaller than the second transmission delay value, the selected partial data is provided for the first network through the first network in which the first transmission delay value is designated, and the first transmission delay value and the first transmission delay value are provided. After the time corresponding to the difference between the two transmission delay values elapses, the selected partial data for the second network is provided through the second network to which the second transmission delay value is assigned.

Preferably, the transmission delay value is specified corresponding to each network to have a size proportional to the data transmission rate for each network.

The heterogeneous network-based simultaneous transmission service method according to the second aspect of the present invention for achieving the above object comprises: a distribution rate setting step of setting, by a transmitter, a data transmission rate for each network; A data selecting step of the transmitting apparatus selecting partial data divided from transmission target data for each network based on the set data transmission rate for each network; A data transmission step of the transmission apparatus determining the transmission order for each network based on a transmission delay value designated for each network, and transmitting the selected partial data according to the determined transmission order; And a data receiving step in which a receiving device combines the transmitted partial data to generate the transmission target data.

According to a third aspect of the present invention, there is provided a method of operating a transmitter, comprising: a distribution rate setting step of setting a data transmission rate for each network; A data selection step of selecting partial data divided from transmission target data for each network based on the set data transmission rate for each network; A data providing step of providing the selected partial data corresponding to a transmission delay value designated for each network; And a data transmission step of splitting and transmitting the provided partial data through a heterogeneous network.

Preferably, the step of setting the distribution rate, characterized in that for confirming the data transmission rate for each network, and setting the data transmission rate for each network corresponding to the confirmed data transmission rate.

Preferably, the data providing step is characterized in that for determining the transmission order for each network based on the transmission delay value, and providing the selected partial data in accordance with the determined transmission order.

Preferably, the data providing step comprises: a data storing step of sequentially storing the selected partial data in a transmission buffer designated for each network according to the order information specified in the partial data; And a data extraction step of extracting and providing the partial data stored for each network based on the transmission delay value in order to sequentially transmit the stored partial data to the receiving apparatus in correspondence with the designated order information.

Preferably, in the data providing step, when the first transmission delay value is specified in the first network and the second transmission delay value is specified in the second network, the first transmission delay value and the second transmission delay value are compared. And, when the first transmission delay value is smaller than the second transmission delay value, provide the selected partial data for the first network through the first network to which the first transmission delay value is assigned, and the first transmission delay value. And after the time corresponding to the difference between the second transmission delay value elapses, the selected partial data for the second network is provided through the second network in which the second transmission delay value is designated.

Preferably, the transmission delay value is specified corresponding to each network to have a size proportional to the data transmission rate for each network.

The computer-readable recording medium according to the fourth aspect of the present invention for achieving the above object is to set the data transmission rate for each network, the partial data divided from the transmission target data for each network based on the set data transmission rate for each network And selecting the data, providing the selected partial data corresponding to the transmission delay value specified for each network, and splitting the provided partial data through heterogeneous networks.

Accordingly, according to the heterogeneous network-based data transmission service method of the present invention, in the heterogeneous network environment, data transmission rate for each network in consideration of data transmission rate (Throughput) is determined in the heterogeneous network environment. By dividing the data to be transmitted according to the set transmission rate and transmitting the delayed difference corresponding to the data transmission rate, the data traffic of the entire network is transferred in consideration of the data transmission rate for each network to improve the data service quality. Network stability can be secured.

1 is a schematic configuration diagram of a heterogeneous network-based data transmission service system according to an embodiment of the present invention.
2 is a schematic configuration diagram of a management device according to an embodiment of the present invention.
3 is a schematic flowchart illustrating a method of operating a heterogeneous network-based simultaneous data transmission service system according to an embodiment of the present invention.
Figure 4 is a schematic flow chart for explaining the operation of the management device according to an embodiment of the present invention.

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

1 is a schematic block diagram of a heterogeneous network-based simultaneous data transmission service system according to an embodiment of the present invention.

As shown in FIG. 1, the heterogeneous network-based data transmission service system according to the present invention divides data into two or more pieces of partial data, and assigns a specific virtual network to first partial data corresponding to a portion of the two or more pieces of partial data. From the management apparatus 100 and the management apparatus of the transmission apparatus which transmits including the connection information and transmitting the virtual network connection information in the second partial data corresponding to another part of the two or more partial data. The first network apparatus 200 for receiving the first partial data, the second network apparatus 300 for receiving the second partial data from the management apparatus 100 and the first network apparatus 200 from the first network apparatus 200. Receives the first partial data and the second partial data from the second network device 300, the first partial data and the virtual data included in the second partial data And a terminal device 400 as a receiving device for generating the data by combining the first partial data and the second partial data according to the specific virtual network connection information based on the network connection information. In addition, the heterogeneous network-based data transmission service system according to the present invention has a configuration that includes an external device 500 for transmitting the transmission target data to the management device 100 to request delivery to the terminal device 400.

The heterogeneous network-based data transmission service according to the present invention implements a configuration in which data is transmitted and received by using a plurality of heterogeneous networks for data transmission and reception between the terminal device 400 and the external device 500.

Therefore, in the present invention, session division is performed in the management apparatus 100 to implement simultaneous link transmission through a plurality of heterogeneous networks for one session. In this case, since the terminal device 400 is connected to each of a plurality of heterogeneous networks, the management device 100 recognizes that the terminal device 400 is a link of one terminal device 400 for each simultaneous link through the plurality of heterogeneous networks. The terminal device 400 must be managed as one subject. To this end, it is necessary to allocate and manage separate virtual network access information (eg, virtual IP) for the transmission service in correspondence to the terminal device 400.

The external device 500 refers to a server device that performs data transmission and reception with the terminal device 400 through the management device 100, for example, to the terminal device 400 through data transmission and reception through the management device 100, Various services such as portal service and content providing service can be provided.

The heterogeneous network may correspond to various access networks including, for example, WCDMA, CDMA, WiBro, WLAN (WiFi), and Long Term Evolution (LTE). ) And a second network (hereinafter, referred to as a "3G network") and a second network (hereinafter referred to as a "WiFi network") which refer to a local area wireless network (WiFi).

Accordingly, the first network device 200 refers to a gateway GPRS support node (GGSN) device for operating a 3G network, that is, a wireless packet service network, and the second network device 300 is a WiFi network, It refers to an access point (AP) for operating a local area wireless network.

In addition, the management apparatus 100 and the terminal apparatus 400 may also be a transmitting apparatus according to the uplink process and the downlink process, that is, depending on the service flow, that is, the subject transmitting data using the data simultaneous transmission service. It can also be a receiver. In the present embodiment, for convenience of description, assuming a management apparatus 100 as a transmission apparatus for providing data simultaneous transmission service to a terminal apparatus 400 by being located in a heterogeneous network environment, and transmitting and receiving data with the management apparatus 100. Assuming a terminal device 400 as a receiving device to perform the following description.

The management apparatus 100 sets a data transmission rate for each network based on the data transmission rate for each network.

That is, the management device 100 checks the data transmission rate through the first network device 200 located in the 3G network and the data transmission rate through the second network device 300 located in the WiFi network, and confirms the data transmission rate for each identified network. Based on this, the data transmission rate between the 3G network and the WiFi network will be set.

To this end, the management apparatus 100 transmits the first partial data through the first network device 200 located in the 3G network and the second partial data through the second network device 300 located in the Wi-Fi network. Check the transmission amounts of the first partial data and the second partial data. In other words, the management apparatus 100 confirms the order of the plurality of packets constituting the first partial data and the second partial data, respectively, as described above from the terminal device 400 that has received the first partial data and the second partial data. Receiving a response message (ACK) in response to the inserted order information for the data transmission rate, that is, transfer of the first partial data and the second partial data transmitted to the terminal device 400 by applying Round Trip Time (RTT) You can check the number of bits per second of the data.

Furthermore, the management apparatus 100 sets the data transmission rate between the 3G network and the WiFi network by grasping the current state of each network based on the confirmed data transmission rate for each network as described above. For example, the management apparatus 100 sets the data transmission rate between the 3G network and the WiFi network to 1 to 3 when the confirmed data rate of the 3G network is 1 Mbps and the data rate of the WiFi network is 3 Mbps.

In addition, the management apparatus 100 selects the partial data divided from the transmission target data for each network based on the set data transmission rate for each network.

That is, the management device 100 receives the transmission target data from the external device 500, and the first transmission rate for data transmission to the first network device 200 and the first data transmission rate for the data to the second network device 300. 2 confirming the transmission rate, selecting first partial data to be transmitted to the first network device 200 among the partial data divided from the transmission target data based on the confirmed transmission rate, and also a second network device among the remaining partial data The second partial data to be transmitted to 300 is selected. In this case, the management apparatus 100 sequentially stores the selected partial data in a transmission buffer designated for each network according to the order information specified in the partial data, and simultaneously stores a storage time for the selected partial data. The storage elapsed time of the partial data sequentially stored in each transmission buffer can be checked.

In addition, the management apparatus 100 extracts the selected partial data according to a transmission delay value set to correspond to a data transmission rate for each network.

That is, the management apparatus 100 extracts the selected partial data from the transmission buffer for each network according to the transmission delay value set to correspond to the data transmission rate for each network, thereby the terminal apparatus according to the order information in which the stored partial data is assigned to the partial data. To be passed to 400. In the case of the transmission delay value, a small value is applied to a network having a relatively low data rate among 3G networks and a WiFi network, and thus, partial data selected for a network having a low data rate compared to a network having a high data rate. To be first extracted and transmitted,

In other words, the management apparatus 100 confirms the storage elapsed time for the partial data selected for each network by comparing the storage time of the partial data sequentially stored in the transmission buffer with the current time, and the confirmed storage elapsed time for each network. If the transmission delay value is set, the corresponding partial data is extracted from the transmission buffer. For example, the management apparatus 100, when the confirmed data rate of the 3G network is 1Mbps, the data rate of the WiFi network is 3Mbps, the transmission delay value of the 3G network is smaller than the transmission delay value of the WiFi network is assigned to the 3G network Correspondingly, the first partial data selected is first extracted from the transmission buffer, and after waiting by the difference between the 3G network and the WiFi network transmission delay value, the second partial data selected corresponding to the WiFi network is extracted from the transmission buffer.

Furthermore, the management device 100 transmits the extracted partial data using the corresponding network.

That is, the management device 100 transmits the partial data extracted from the transmission buffer in response to the set transmission delay value, that is, the first partial data to the first network device 200 located in the 3G network, and thus the first network device. 200 will transmit the first partial data to the terminal device 400 as a receiving device. The management apparatus 100 transmits the second partial data to the second network apparatus 300, and the second network apparatus 300 will then transmit the second partial data to the terminal apparatus 400 as a receiving apparatus.

The terminal device 400 receives data dividedly transmitted from the first network device 200 and the second network device 300 to restore the data.

That is, the terminal device 400 receives the first partial data from the first network device 200 and the second partial data from the second network device 300, and receives the received first partial data and the second partial data. By generating data by combining the first partial data and the second partial data based on the virtual network access information included in the data, the management object 100 restores the data to be transmitted. That is, the terminal device 400 recognizes the first partial data and the second partial data having the same virtual network connection information based on the virtual network access information included in the received partial data, and includes them in the partial data. By combining and combining according to the information, the original transmission target data can be generated.

Hereinafter, the management device 100 according to an embodiment of the present invention will be described in more detail with reference to FIG. 2.

In other words, the management device 100 is a distribution rate setting unit 110 that sets the data transmission rate for each network based on the data transmission rate for each network, and the partial data divided from the transmission target data for each network based on the data transmission rate for each network. A controller 120 for selecting; And a communication unit 130 for transmitting the selected partial data through heterogeneous networks. Here, the communication unit 130 refers to a communication module for interworking with the first network device 200 using the 3G network and interworking with the second network device 300 using the WiFi network.

The distribution rate setting unit 110 sets a data transmission rate for each network based on the data transmission rate for each network.

That is, the distribution rate setting unit 110 checks the data transmission rate through the first network device 200 located in the 3G network and the data transmission rate through the second network device 300 located in the WiFi network, and confirms the data for each network. Based on the transmission rate, the data transmission rate between the 3G network and the WiFi network will be set.

To this end, the distribution ratio setting unit 110 transmits the first partial data through the first network device 200 located in the 3G network and the second partial data through the second network device 300 located in the Wi-Fi network. Checks the transmission amounts of the first partial data and the second partial data. In other words, the distribution ratio setting unit 110 orders the plurality of packets constituting the first partial data and the second partial data, respectively, as described above from the terminal device 400 that has received the first divided data and the second partial data. By receiving a response message (ACK) corresponding to the inserted order information for confirmation, the data transmission rate of the first partial data and the second partial data transmitted to the terminal device 400 through the application of Round Trip Time (RTT), that is, Check the number of bits per second of transmitted data.

In addition, the distribution rate setting unit 110 determines the current state of each network based on the data rate for each network identified as described above to set the data transfer rate between the 3G network and the WiFi network. For example, the distribution rate setting unit 110 sets the data transfer rate between the 3G network and the WiFi network to 1 to 3 when the confirmed data rate of the 3G network is 1 Mbps and the data rate of the WiFi network is 3 Mbps.

The controller 120 selects the partial data divided from the transmission target data for each network based on the set data transmission rate for each network.

That is, the controller 120 receives the transmission target data from the external device 500, and transmits the first transmission rate for data transmission to the first network device 200 and the second data transmission for the second network device 300. Check the transmission rate, select the first partial data to be transmitted to the first network device 200 of the divided partial data in the transmission target data based on the confirmed transmission rate, and the second network device ( The second partial data to be transmitted to 300 is selected. At this time, the control unit 120 sequentially stores the selected partial data in a transmission buffer designated for each network according to the order information specified in the partial data, and simultaneously stores the storage time for the selected partial data, for each network. It is possible to check the storage elapsed time of the partial data sequentially stored in the transmission buffer.

Further, the control unit 120 extracts the selected partial data according to the transmission delay value set to correspond to the data transmission rate for each network.

That is, the control unit 120 extracts the selected partial data from the transmission buffer for each network according to the transmission delay value set to correspond to the data transmission rate for each network, so that the stored partial data is assigned to the terminal device according to the order information assigned to the partial data. 400). In the case of the transmission delay value, a small value is applied to a network having a relatively low data rate among 3G networks and a WiFi network, and thus, partial data selected for a network having a low data rate compared to a network having a high data rate. Is preferentially extracted and transmitted.

In other words, the controller 120 checks the storage elapsed time for the partial data selected for each network by comparing the storage time of the partial data sequentially stored in the transmission buffer with the current time, and the confirmed storage elapsed time is set for each network. If the transmission delay value is applicable, the corresponding partial data is extracted from the transmission buffer. For example, if the confirmed data rate of the 3G network is 1Mbps, the data rate of the WiFi network is 3Mbps, the transmission delay value of the 3G network is smaller than the transmission delay value of the WiFi network to correspond to the 3G network The first partial data is first extracted from the transmission buffer, and after waiting for the difference between the 3G network and the WiFi network transmission delay value, the second partial data selected for the WiFi network is extracted from the transmission buffer.

The communication unit 130 transmits the extracted partial data using the corresponding network.

That is, the communication unit 130 transmits the partial data extracted from the transmission buffer in response to the set transmission delay value, that is, the first partial data to the first network device 200 located in the 3G network, and thus the first network device ( 200 may transmit the first partial data to the terminal device 400 as a receiving device. The communication unit 130 transmits the second partial data to the specific second network device 300 selected based on the connection target network device information, and the second network device 300 transmits the second partial data as a receiving device. The terminal 400 will transmit.

As described above, according to the heterogeneous network-based simultaneous data transmission service system according to the present invention, in the heterogeneous network (Heterogeneous network) environment in partitioning and transmitting data to be transmitted simultaneously, the network considering the data transmission rate (Throughput) for each network By setting the data transmission rate for each segment, the data to be transmitted is divided and transmitted with a delay difference corresponding to the data transmission rate according to the set transmission rate, thereby transferring data traffic of the entire network in consideration of the data transmission rate for each network. It can improve service quality and secure network stability.

Hereinafter, a heterogeneous network-based data transmission service method according to an embodiment of the present invention will be described with reference to FIGS. 3 and 4. Here, the configurations shown in FIGS. 1 and 2 will be described with reference to corresponding reference numerals for convenience of explanation.

First, a method of operating a heterogeneous network-based simultaneous data transmission service system according to an embodiment of the present invention will be described with reference to FIG. 3.

First, the management apparatus 100 checks the data transmission rate through the first network device 200 located in the 3G network and the data transmission rate through the second network device 300 located in the WiFi network (S110).

Preferably, the management device 100 transmits the first partial data through the first network device 200 located in the 3G network and the second partial data through the second network device 300 located in the Wi-Fi network. Checks the transmission amounts of the first partial data and the second partial data. In other words, the management apparatus 100 confirms the order of the plurality of packets constituting the first partial data and the second partial data, respectively, as described above from the terminal device 400 that has received the first partial data and the second partial data. Receiving a response message (ACK) in response to the inserted order information for the data transmission rate, that is, transfer of the first partial data and the second partial data transmitted to the terminal device 400 by applying Round Trip Time (RTT) You can check the number of bits per second of the data.

Then, the management apparatus 100 sets the data transmission rate between the 3G network and the WiFi network based on the confirmed data transmission rate for each network (S120).

Preferably, the management apparatus 100 sets the data transmission rate between the 3G network and the WiFi network by grasping the current state of each network based on the identified data transmission rate for each network. For example, the management apparatus 100 sets the data transmission rate between the 3G network and the WiFi network to 1 to 3 when the confirmed data rate of the 3G network is 1 Mbps and the data rate of the WiFi network is 3 Mbps.

Then, the management apparatus 100 selects the partial data divided from the transmission target data for each network based on the set data transmission rate for each network (S130-S140).

Preferably, the management device 100 receives the data to be transmitted from the external device 500 and transmits the first transmission rate for data transmission to the first network device 200 and the data transmission to the second network device 300. Confirming the second transmission rate for the second data; selecting first partial data to be transmitted to the first network apparatus 200 among the partial data divided from the transmission target data based on the confirmed transmission rate; The second partial data to be transmitted to the network device 300 is selected. In this case, the management apparatus 100 sequentially stores the selected partial data in a transmission buffer designated for each network according to the order information specified in the partial data, and simultaneously stores a storage time for the selected partial data. The storage elapsed time of the partial data sequentially stored in each transmission buffer can be checked.

Next, the management apparatus 100 extracts the selected partial data according to the transmission delay value set to correspond to the data transmission rate for each network (S150-S160).

Preferably, the management apparatus 100 extracts the selected partial data from the transmission buffer for each network in accordance with the transmission delay value set to correspond to the data transmission rate for each network, according to the order information in which the stored partial data is assigned to the partial data. It can be delivered to the terminal device (400). In the case of the transmission delay value, a small value is applied to a network having a relatively low data rate among 3G networks and a WiFi network, and thus, partial data selected for a network having a low data rate compared to a network having a high data rate. Is preferentially extracted and transmitted.

In other words, the management apparatus 100 confirms the storage elapsed time for the partial data selected for each network by comparing the storage time of the partial data sequentially stored in the transmission buffer with the current time, and the confirmed storage elapsed time for each network. If the transmission delay value is set, the corresponding partial data is extracted from the transmission buffer. For example, the management apparatus 100, when the confirmed data rate of the 3G network is 1Mbps, the data rate of the WiFi network is 3Mbps, the transmission delay value of the 3G network is smaller than the transmission delay value of the WiFi network is assigned to the 3G network Correspondingly, the first partial data selected is first extracted from the transmission buffer, and after waiting by the difference between the 3G network and the WiFi network transmission delay value, the second partial data selected corresponding to the WiFi network is extracted from the transmission buffer.

Furthermore, the management device 100 transmits the extracted partial data using the corresponding network (S170).

Preferably, the management device 100 transmits the partial data extracted from the transmission buffer in response to the set transmission delay value, that is, the first partial data to the first network device 200 located in the 3G network and thus transmits the first data. The network device 200 will transmit the first partial data to the terminal device 400 as a receiving device. The management apparatus 100 transmits the second partial data to the second network apparatus 300, and the second network apparatus 300 will then transmit the second partial data to the terminal apparatus 400 as a receiving apparatus.

Thereafter, the terminal device 400 receives data dividedly transmitted from the first network device 200 and the second network device 300 to restore the data (S180).

Preferably, the terminal device 400 receives the first partial data from the first network apparatus 200 and the second partial data from the second network apparatus 300, and receives the received first partial data and the second partial data. By generating data by combining the first partial data and the second partial data based on the virtual network access information included in the partial data, the management apparatus 100 restores the data to be transmitted. That is, the terminal device 400 recognizes the first partial data and the second partial data having the same virtual network connection information based on the virtual network access information included in the received partial data, and includes them in the partial data. By combining and combining according to the information, the original transmission target data can be generated.

Hereinafter, an operation method of the management apparatus 100 according to an embodiment of the present invention will be described with reference to FIG. 4.

First, the data transmission rate through the first network device 200 located in the 3G network and the data transmission rate through the second network device 300 located in the WiFi network are checked (S210).

Preferably, the distribution ratio setting unit 110 transmits the first partial data through the first network device 200 located in the 3G network and the second partial data through the second network device 300 located in the Wi-Fi network. In the process, the transmission amounts of the first partial data and the second partial data are checked. In other words, the distribution ratio setting unit 110 orders the plurality of packets constituting the first partial data and the second partial data, respectively, as described above from the terminal device 400 that has received the first divided data and the second partial data. By receiving a response message (ACK) corresponding to the inserted order information for confirmation, the data transmission rate of the first partial data and the second partial data transmitted to the terminal device 400 through the application of Round Trip Time (RTT), that is, Check the number of bits per second of transmitted data.

Then, the data transmission rate for each network is set based on the confirmed data transmission rate for each network (S220).

Preferably, the distribution rate setting unit 110 determines the current state of each network based on the identified data rate for each network to set the data transfer rate between the 3G network and the WiFi network. For example, the distribution rate setting unit 110 sets the data transfer rate between the 3G network and the WiFi network to 1 to 3 when the confirmed data rate of the 3G network is 1 Mbps and the data rate of the WiFi network is 3 Mbps.

Then, based on the set data transmission rate for each network, select the partial data divided from the transmission target data for each network (S230-S250).

Preferably, the control unit 120 receives the data to be transmitted from the external device 500 and transmits the data to the first transmission rate and the second network device 300 for data transmission to the first network device 200. Confirming the second transmission rate, selecting first partial data to be transmitted to the first network apparatus 200 among the partial data divided from the transmission target data based on the confirmed transmission rate, and also selecting a second network among the remaining partial data; The second partial data to be transmitted to the device 300 is selected.

Next, the selected partial data is stored for each network (S260).

Preferably, the controller 120 sequentially stores the selected partial data in a transmission buffer designated for each network according to the order information specified in the partial data, and simultaneously stores the storage time for the selected partial data. The storage elapsed time of the partial data sequentially stored in the transmission buffer for each network can be checked.

Then, the selected partial data is extracted according to the transmission delay value set to correspond to the data transmission rate for each network (S270-S290).

Preferably, the controller 120 checks the storage elapsed time for the partial data selected for each network by comparing the storage time of the partial data sequentially stored in the transmission buffer with the current time, and the identified storage elapsed time for each network. If the transmission delay value is set, the corresponding partial data is extracted from the transmission buffer. For example, if the confirmed data rate of the 3G network is 1Mbps, the data rate of the WiFi network is 3Mbps, the transmission delay value of the 3G network is smaller than the transmission delay value of the WiFi network to correspond to the 3G network The first partial data is first extracted from the transmission buffer, and after waiting for the difference between the 3G network and the WiFi network transmission delay value, the second partial data selected for the WiFi network is extracted from the transmission buffer.

Thereafter, the extracted partial data is transmitted using the corresponding network (S300).

Preferably, the communication unit 130 transmits the partial data extracted from the transmission buffer in response to the set transmission delay value, that is, the first partial data to the first network device 200 located in the 3G network, and thus the first network. The device 200 will transmit the first partial data to the terminal device 400 as a receiving device. The communication unit 130 transmits the second partial data to the specific second network device 300 selected based on the connection target network device information, and the second network device 300 transmits the second partial data as a receiving device. The terminal 400 will transmit.

As described above, according to the heterogeneous network-based simultaneous data transmission service method according to the present invention, in the simultaneous transmission by dividing the transmission target data in a heterogeneous network (Heterogeneous network) environment, the network considering the data transmission rate (Throughput) for each network By setting the data transmission rate for each segment, the data to be transmitted is divided and transmitted with a delay difference corresponding to the data transmission rate according to the set transmission rate, thereby transferring data traffic of the entire network in consideration of the data transmission rate for each network. It can improve service quality and secure network stability.

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

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

According to the heterogeneous network-based simultaneous data transmission service system and method thereof according to the present invention, in the heterogeneous network environment, in the simultaneous transmission of data to be transmitted in a heterogeneous network environment, data transmission for each network in consideration of the data transmission rate per network (Throughput) Applied apparatus that is not only used for related technologies as it exceeds the limitations of the existing technology in that it transmits with a delay difference corresponding to the data transmission rate by dividing the data to be transmitted according to the set transmission rate by setting the ratio. It is an invention with industrial applicability because it is not only commercially available or commercially viable, but also practically evident.

100: management device
110: distribution ratio setting unit 120: control unit
130:
200: first network device
300: second network device
400: terminal device
500: External device

Claims (13)

A distribution rate setting unit for setting a data transmission rate for each network;
A control unit selecting partial data divided from transmission target data for each network based on the set data transmission rate for each network, and providing the selected partial data corresponding to a transmission delay value designated for each network; And
And a communication unit configured to transmit the divided partial data through heterogeneous networks. The method of claim 1,
The distribution ratio setting unit,
And a data transmission rate for each network, and setting a data transmission rate for each network in response to the identified data transmission rate. The method of claim 1,
The control unit,
And a transmission order for each network based on the transmission delay value, and providing the selected partial data according to the determined transmission order. The method of claim 1,
The control unit,
The selected partial data are sequentially stored in a transmission buffer designated for each network according to the order information designated in the partial data, and the transmission delay value is sequentially transmitted to sequentially transmit the stored partial data to a receiving device corresponding to the designated order information. Transmitting apparatus, characterized in that for extracting the partial data stored for each network based on the provided. The method of claim 1,
The control unit,
When the first transmission delay value is specified in the first network and the second transmission delay value is specified in the second network, the first transmission delay value and the second transmission delay value are compared;
If the first transmission delay value is smaller than the second transmission delay value, providing the partial data selected for the first network through the first network to which the first transmission delay value is assigned;
After the time corresponding to the difference between the first transmission delay value and the second transmission delay value elapses, providing the selected partial data for the second network through the second network to which the second transmission delay value is assigned. Transmission device. The method of claim 2,
The transmission delay value is
And a corresponding device is designated corresponding to each network so as to have a size proportional to the data transmission rate for each network. A distribution rate setting step of setting, by the transmitting apparatus, a data transmission rate for each network;
A data selecting step of the transmitting apparatus selecting partial data divided from transmission target data for each network based on the set data transmission rate for each network;
A data transmission step of the transmission apparatus determining the transmission order for each network based on a transmission delay value designated for each network, and transmitting the selected partial data according to the determined transmission order; And
Heterogeneous network-based data simultaneous transmission service method comprising a data receiving step of generating the transmission target data by combining the partial data to be transmitted. A distribution rate setting step of setting a data transmission rate for each network;
A data selection step of selecting partial data divided from transmission target data for each network based on the set data transmission rate for each network;
A data providing step of providing the selected partial data corresponding to a transmission delay value designated for each network; And
And a data transmission step of dividing and transmitting the provided partial data through a heterogeneous network. The method of claim 8,
The distribution ratio setting step,
Confirming the data transmission rate for each network, and setting a data transmission rate for each network in response to the identified data transmission rate. The method of claim 8,
The data providing step,
And determining the transmission order for each network based on the transmission delay value, and providing the selected partial data according to the determined transmission order. The method of claim 8,
The data providing step,
A data storage step of sequentially storing the selected partial data in a transmission buffer designated for each network according to the order information designated in the partial data; And
And a data extraction step of extracting and providing the partial data stored for each network based on the transmission delay value so as to sequentially transfer the stored partial data to the receiving device corresponding to the designated order information. Method of operation. The method of claim 8,
The data providing step,
When the first transmission delay value is specified in the first network and the second transmission delay value is specified in the second network, the first transmission delay value and the second transmission delay value are compared;
If the first transmission delay value is smaller than the second transmission delay value, providing the partial data selected for the first network through the first network to which the first transmission delay value is assigned;
After the time corresponding to the difference between the first transmission delay value and the second transmission delay value elapses, providing the selected partial data for the second network through the second network to which the second transmission delay value is assigned. Operation method of the transmission apparatus. The method of claim 9,
The transmission delay value is
And a method corresponding to each network to have a size proportional to the data rate of each network.

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