KR20130071882A - Apparatus and method for simultaneously transmitting data in heterogeneous network - Google Patents

Abstract

PURPOSE: Heterogeneous network based data simultaneous transmission method and device applied thereby are provided to convert a simultaneous transmission mode into a single transmission mode and to transmit partial data through a specific access network according to conversion into the single transmission mode. CONSTITUTION: A communication unit (110) transmits partial data divided from transmission target data based on a data transmission ratio variably set between more than two access networks according to activation of a simultaneous transmission mode through more than two access networks. An operation control unit (120) confirms a data transmission ratio variable with the access network. If a data transmission ratio of a specific access network exceeds a predetermined maximum transmission ratio, the operation control unit converts the simultaneous transmission mode into a single transmission mode. [Reference numerals] (110) Communication unit; (120) Operation control unit

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 data simultaneous transmission method using heterogeneous networks, and more particularly, to determine a data transmission rate that varies between access networks, when the access network is detected that exceeds the preset maximum transmission rate, the simultaneous transmission mode By disabling the data transmission through the single access network, and simultaneously detecting the degradation of the corresponding access network when transmitting data using the single access network, enable simultaneous transmission mode to perform simultaneous data transmission using heterogeneous networks. The present invention relates to a heterogeneous network-based data transmission method, 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.

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.

The present invention has been made in view of the above circumstances, and an object of the present invention is to obtain partial data divided from data to be transmitted based on a data transmission rate that is variably set between two or more access networks according to activation of a simultaneous transmission mode. Is transmitted through two or more access networks, checks whether the data transmission rate varies for each access network to determine whether the maximum transmission rate is exceeded, and the data transmission rate of a specific access network exceeds the preset maximum transmission rate. When it is confirmed that the simultaneous transmission mode is deactivated to switch to a single transmission mode, heterogeneous network-based data simultaneous transmission method for transmitting the partial data over the specific access network in accordance with the switch to the single transmission mode and Heterogeneous nets by providing applicable devices Improve the efficiency of the broadcast service using a greater Sikkim and, at the same time, has to satisfy the user's Quality of Experience.

The heterogeneous network-based simultaneous data transmission apparatus according to the first aspect of the present invention for achieving the above object is divided from the data to be transmitted based on a data transmission rate that is variably set between two or more access networks according to activation of the simultaneous transmission mode. Communication unit for transmitting the partial data through the two or more access networks; And an operation control unit for checking a data transmission rate that is variable for each access network, and when the data transmission rate of a specific access network exceeds a preset maximum transmission rate, deactivating the simultaneous transmission mode to switch to a single transmission mode. And the communication unit transmits the partial data through the specific access network according to the switching to the single transmission mode.

Preferably, the operation control unit, according to the simultaneous transmission mode designates the utilization efficiency for the entire bandwidth of the two or more access network, the maximum transmission for the data transmission rate between the access network to ensure the specified utilization efficiency The rate is set, and when it is confirmed that the data transmission rate of the specific access network exceeds the maximum transmission rate, the simultaneous transmission mode is deactivated.

Preferably, the operation control unit, in the state of switching to the single transmission mode, checks the packet delay value which is the interval information between the packets of the partial data transmitted through the specific access network, the checked packet delay value is threshold When the value is exceeded, the single transmission mode is deactivated to switch to the simultaneous transmission mode.

The heterogeneous network-based data transmission method according to the second aspect of the present invention for achieving the above object is divided from the data to be transmitted based on a data transmission rate that is variably set between two or more access networks according to activation of the simultaneous transmission mode. A simultaneous transmission mode operation step of transmitting partial data through two or more access networks; A maximum transmission rate exceeding checking step of checking a data transmission rate variable for each access network to determine whether a preset maximum transmission rate is exceeded; A single transmission mode switching step of deactivating the simultaneous transmission mode and switching to a single transmission mode when it is confirmed that a data transmission rate of a specific access network exceeds a preset maximum transmission rate; And a single transmission mode operation step of transmitting the partial data through the specific access network in accordance with the switching to the single transmission mode.

Preferably, the maximum transmission rate exceeded confirmation step, the use efficiency designation step of designating the utilization efficiency for the entire bandwidth of the two or more access network according to the simultaneous transmission mode; A maximum transmission rate setting step of setting the maximum transmission rate with respect to a data transmission rate between access networks to ensure the specified utilization efficiency; And an excess checking step of checking whether a data transmission rate variable for each access network is exceeded to determine whether a preset maximum transmission rate is exceeded.

Preferably, the method comprises: a packet delay value checking step of checking a packet delay value which is information on a packet interval of partial data transmitted through the specific access network, in a state of switching to the single transmission mode; A threshold value over-checking step of confirming whether the checked packet delay value exceeds a threshold value; And a simultaneous transmission mode switching step of deactivating the single transmission mode and switching to the simultaneous transmission mode when the checked packet delay value exceeds a threshold value.

Therefore, according to the heterogeneous network-based simultaneous data transmission method and apparatus applied thereto, in a data simultaneous transmission environment using a heterogeneous network, an access network exceeding a specified maximum transmission rate may be detected by checking a variable data transmission rate between access networks. In this case, the simultaneous transmission mode is deactivated to allow data transmission through a single access network, and at the same time, when it is confirmed that the packet delay value of the corresponding access network exceeds the threshold when transmitting data using the single access network, By enabling the transmission mode to perform simultaneous data transmission using heterogeneous networks, it is possible to improve the efficiency of the simultaneous transmission service using heterogeneous networks and to satisfy user's quality of experience.

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 management device according to an embodiment of the present invention.
3 is a view for explaining the maximum transmission rate setting according to the access network utilization efficiency according to an embodiment of the present invention.
4 is a schematic flowchart illustrating a method of operating a heterogeneous network-based simultaneous data transmission system according to an embodiment of the present invention.
5 is a schematic flowchart illustrating 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.

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 pieces of partial data, and connects a specific virtual network to first partial data corresponding to a portion of the two or more pieces of partial data. The management apparatus 100 of the transmitting apparatus and the management apparatus 100 including the information and transmitting the information including the virtual network connection information in the second partial data corresponding to another part of the two or more partial data. A first network device 200 receiving the first partial data, a second network device 300 receiving the second partial data from the management device 100, and the first network device 200 from the first network device 200; Receives partial data and receives the second partial data from the second network device 300, the virtual network included in the received first partial data and the second partial data On the basis of the access information by combining the first partial data and second partial data according to a particular virtual network connection information comprises a terminal device 400 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 100 and requesting delivery to the terminal apparatus 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. For this purpose, it is inevitably required to allocate and manage separate virtual network connection information (e.g., virtual IP) for simultaneous transmission service corresponding 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 selects the partial data divided from the transmission target data for each access network according to a data transmission rate that is variably set between access networks.

More specifically, the management apparatus 100 checks the data transmission rate that is variably set between the access networks according to the simultaneous transmission mode activation, that is, the first transmission rate and the second transmission rate for data transmission to the second network device 300. do. Furthermore, the management apparatus 100 selects the first partial data to be transmitted to the first network device 200 from the partial data segmented from the transmission object data received from the external device 500 based on the confirmed transmission ratio, And selects the second partial data to be transmitted to the second network device 300 among the remaining partial data. In this regard, the management apparatus 100 dynamically and variably sets the data transmission rate between access networks based on various factors such as the characteristics of the access network, the current load state, and the type of data to be transmitted, and according to the set data transmission rate. Partial data is transmitted for each access network. Meanwhile, in the present embodiment, the management apparatus 100 is used as an example of setting the data transmission rate between access networks, but the data transmission rate is set by operation in a separate policy management device (not shown), and the set data transmission rate is set. Application of the configuration to provide the management device 100 will also be possible.

In addition, the management device 100 transmits the selected partial data using the corresponding access network.

More specifically, the management apparatus 100 transmits the partial data selected corresponding to the transmission target network, that is, the first partial data to the first network apparatus 200 located in the 3G network, and thus the first network apparatus 200. Transmits the first partial data to the terminal apparatus 400 as a receiving apparatus, and simultaneously transmits the second partial data to the second network apparatus 300 located in the WiFi network, thereby causing the second network apparatus 300 to transmit. The second partial data is transmitted to the terminal device 400 as a receiving device.

At the same time, the management apparatus 100 confirms that the data transmission rate of the specific access network exceeds a preset maximum transmission rate.

More specifically, the management apparatus 100 checks the data transmission rate variable for each access network to check whether the data transmission rate of the specific access network exceeds a preset maximum transmission rate. To this end, as shown in FIG. 3, the management apparatus 100 designates the utilization efficiency (eg, 80% to 90%) for the entire bandwidth of the access network, that is, the 3G network and the WiFi network, according to the simultaneous transmission mode. In addition, the maximum transmission rate (eg, 3G network: WiFi network = 3: 1 or 1: 3) for the data transmission rate between access networks to ensure the specified utilization efficiency is set. Based on this, the management apparatus 100 is that the data transmission rate of a particular access network that is variably set based on various factors such as the characteristics of each access network, the current load state, and the type of data to be transmitted exceeds the maximum transfer rate. If confirmed, the simultaneous transmission mode is deactivated. For example, the management apparatus 100 may determine that the current data transmission rate of the 3G network and the WiFi network is 3G network: WiFi network = 4: 1, and the current data transmission rate of the 3G network is a preset maximum transmission rate ( 3G network: WiFi network = 3: 1). On the other hand, the management apparatus 100, if the currently confirmed data transmission rate between the 3G network and the WiFi network, for example, '3G network: WiFi network = 1: 4', the current data transmission rate of the WiFi network is the maximum transmission preset It will be perceived as exceeding the ratio (3G network: WiFi network = 1: 3).

Accordingly, when it is confirmed that the data transmission rate of the specific access network exceeds the maximum transmission rate, the management apparatus 100 deactivates the simultaneous transmission mode or readjusts the data transmission rate.

More specifically, the management apparatus 100 determines that the data transmission rate of the specific access network exceeds the preset maximum transmission rate by checking the data transmission rate between the access networks as described above, and simultaneously activates the simultaneous transmission mode. Deactivate to switch to single transmission mode. For example, the management apparatus 100 determines that the current data transmission rate of the 3G network (3G network: WiFi network = 4: 1) exceeds the preset maximum transmission rate (3G network: WiFi network = 3: 1). By switching to a single transmission mode over a 3G network (3G network: WiFi network = 10: 1), the efficiency of the simultaneous transmission service is prevented from being degraded due to the decrease in the transmission performance of the WiFi network. On the other hand, if the management apparatus 100 determines that the current data transmission ratio (3G network: WiFi network = 1: 4) of the WiFi network exceeds the preset maximum transmission ratio (3G network: WiFi network = 1: 3). By switching to a single transmission mode (3G network: WiFi network = 1:10) over a WiFi network, the transmission performance of the 3G network is prevented from being lowered in the efficiency of the simultaneous transmission service.

Furthermore, the management apparatus 100 confirms that the packet delay value, which is the interval information between packets of the partial data, exceeds the threshold in the state of switching to the single transmission mode.

More specifically, the management apparatus 100 checks the packet delay value, which is the interval information between packets of the partial data transmitted to the terminal apparatus 400 through the specific access network, in the switching state to the single transmission mode, and confirms It is checked whether the packet delay value exceeds the threshold. At this time, the management device 100 performs the continuous monitoring for the delay time between the packet [x_i, y_i] through the following [Equation 1], and if the result value through [Equation 1] is less than 0, the confirmed packet It is determined that the transmission performance of the access network is degraded because the delay value exceeds the threshold. Here, 'x_i' refers to a delay time between neighboring packets when transmitting partial data of the management apparatus 100, and 'y_i' refers to a delay time between neighboring packets when the corresponding partial data is received by the terminal device 400. Done. In this regard, when the partial data is received, the terminal device 400 continuously reports 'y_i' representing the delay time between neighboring packets to the management device 100. On the other hand, in the present embodiment, when the result value through [Equation 1] is less than 0, the transmission performance of the access network is reduced as an example, but in the case of the reference value to be compared with the calculated result value, the connection It can be set to other values depending on the state or setting of the network. In addition, instead of comparing the calculated result value with a specific reference value, the monitoring result of the inter-packet delay time [x_i, y_i] is performed through [Equation 1], so that the variation of the calculated result value is changed. If the value becomes smaller (eg, -0.1-> -0.2-> -0.3 ....), it can be determined that the transmission performance of the access network is degraded.

[Equation 1]

,

,

Accordingly, the management apparatus 100 switches to the simultaneous transmission mode when the checked packet delay value exceeds the threshold.

More specifically, the management apparatus 100 is the single transmission mode when it is confirmed that the packet delay value of the partial data transmitted to the terminal device 400 via the access network in the transition to the single transmission mode exceeds the threshold value Deactivate to switch to simultaneous transmission mode. For example, in the single transmission mode (3G network: WiFi network = 10: 1) through the 3G network, the management apparatus 100 determines that the performance degradation occurs because the packet delay value of the 3G network exceeds the threshold. By considering the transmission performance of the 3G network, the single transmission mode over the 3G network is deactivated to recover to the simultaneous transmission mode (3G network: WiFi network = 2: 1). On the other hand, in the single transmission mode (3G network: WiFi network = 1:10) over the WiFi network, the management device 100, if it is confirmed that the performance degradation occurs because the packet delay value of the WiFi network exceeds the threshold, By considering the transmission performance of the WiFi network, the single transmission mode over the WiFi network is deactivated to restore the simultaneous transmission mode (for example, 3G network: WiFi network = 1: 2).

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

More specifically, the terminal device 400 receives the first partial data through the first network device 200 according to the simultaneous transmission mode of the management device 100, and also the second through the second network device 300. Partial data will be received. In addition, the terminal device 400 generates the data by combining the first partial data and the second partial data based on the virtual network access information included in the received first partial data and the second partial data, and thereby, the management apparatus 100. Restores the data to be sent. 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. On the other hand, when the management device 100 operates in a single transmission mode through the 3G network, the terminal device 400 receives all partial data through the first network device 200, and enters the single transmission mode through the WiFi network. In operation, all partial data is received through the second network device 300.

Hereinafter, a more specific configuration of the management apparatus 100 according to the embodiment of the present invention will be described with reference to FIG.

That is, the management apparatus 100 transmits the partial data divided from the transmission target data for each access network based on the preset data transmission rate, and the simultaneous transmission mode and the single transmission mode through the status check for each access network. It has a configuration including an operation control unit 120 for switching the transmission mode between.

The communication unit 110 selects the partial data divided from the transmission target data for each access network according to a data transmission rate that is variably set between access networks.

More specifically, the communication unit 110 checks the data transmission rate that is variably set between the access networks according to the simultaneous transmission mode activation, that is, the first transmission rate and the second transmission rate for data transmission to the second network device 300. . Furthermore, the management apparatus 100 selects the first partial data to be transmitted to the first network device 200 from the partial data segmented from the transmission object data received from the external device 500 based on the confirmed transmission ratio, And selects the second partial data to be transmitted to the second network device 300 among the remaining partial data.

In addition, the communication unit 110 transmits the selected partial data using the corresponding access network.

More specifically, the communication unit 110 transmits the partial data selected corresponding to the transmission target network, that is, the first partial data to the first network device 200 located in the 3G network, to the first network device 200. Transmits the first partial data to the terminal apparatus 400 as a receiving apparatus, and simultaneously transmits the second partial data to the second network apparatus 300 located in the WiFi network, thereby causing the second network apparatus 300 to transmit the second partial data. The two-part data is transmitted to the terminal device 400 as a receiving device.

The operation controller 120 confirms that the data transmission rate of the specific access network exceeds a preset maximum transmission rate.

More specifically, the operation control unit 120 checks the data transmission rate that is variable for each access network to determine whether the data transmission rate of the specific access network exceeds a preset maximum transmission rate. That is, the operation controller 120 may determine that the data transmission rate of the specific access network that is variably set based on various factors such as the characteristics of each access network, the current load state, and the type of data to be transmitted exceeds the maximum transfer rate. In this case, the simultaneous transmission mode is deactivated. For example, the operation controller 120 may determine that the current data transfer rate of the 3G network and the WiFi network is 3G network: WiFi network = 4: 1, and the current data transfer rate of the 3G network is a preset maximum transfer rate ( 3G network: WiFi network = 3: 1). On the other hand, the operation control unit 120 when the currently confirmed data transmission rate between the 3G network and the WiFi network, for example, '3G network: WiFi network = 1: 4', the current data transmission rate of the WiFi network is the maximum transmission preset It will be perceived as exceeding the ratio (3G network: WiFi network = 1: 3).

Accordingly, when it is confirmed that the data transmission rate of the specific access network exceeds the maximum transmission rate, the operation controller 120 deactivates the simultaneous transmission mode or readjusts the data transmission rate.

More specifically, the operation control unit 120 by checking the data transmission rate between the access network as described above, when it is recognized that the data transmission rate of the specific access network exceeds the preset maximum transmission rate, the active simultaneous transmission mode Deactivate to switch to single transmission mode. For example, the operation controller 120 determines that the current data transmission rate (3G network: WiFi network = 4: 1) of the 3G network exceeds the preset maximum transmission rate (3G network: WiFi network = 3: 1). By switching to a single transmission mode over a 3G network (3G network: WiFi network = 10: 1), the efficiency of the simultaneous transmission service is prevented from being degraded due to the decrease in the transmission performance of the WiFi network. On the other hand, the operation controller 120 determines that the current data transmission rate (3G network: WiFi network = 1: 4) of the WiFi network exceeds the preset maximum transmission rate (3G network: WiFi network = 1: 3). By switching to a single transmission mode (3G network: WiFi network = 1:10) over a WiFi network, the transmission performance of the 3G network is prevented from being lowered in the efficiency of the simultaneous transmission service.

Further, the operation controller 120 confirms that the packet delay value, which is the interval information between packets of the partial data, exceeds the threshold in the state of switching to the single transmission mode.

More specifically, the operation control unit 120 checks the packet delay value which is the interval information between the packets of the partial data transmitted to the terminal device 400 through the specific access network in the state of switching to the single transmission mode, and the confirmation It is determined whether the packet delay value exceeds the threshold value, and when it exceeds the threshold value, it is determined that the transmission performance of the access network is degraded.

Accordingly, when the checked packet delay value exceeds the threshold, the operation controller 120 switches to the simultaneous transmission mode.

More specifically, the operation control unit 120 when it is confirmed that the packet delay value of the partial data transmitted to the terminal device 400 through the access network in the state of switching to the single transmission mode exceeds the threshold value, the single transmission mode. Deactivate to switch to simultaneous transmission mode. For example, in the single transmission mode (3G network: WiFi network = 10: 1) through the 3G network, the management apparatus 100 determines that the performance degradation occurs because the packet delay value of the 3G network exceeds the threshold. By considering the transmission performance of the 3G network, the single transmission mode over the 3G network is deactivated to recover to the simultaneous transmission mode (3G network: WiFi network = 2: 1). On the other hand, the operation control unit 120 in the single transmission mode over the WiFi network (3G network: WiFi network = 1:10), when the packet delay value of the WiFi network is confirmed that the performance degradation occurs because the threshold exceeds, By considering the transmission performance of the WiFi network, the single transmission mode over the WiFi network is deactivated to restore the simultaneous transmission mode (for example, 3G network: WiFi network = 1: 2).

Meanwhile, when the communication unit 110 is switched to the single transmission mode, the communication unit 110 transmits the partial data through the single access network.

More specifically, when the communication unit 100 is switched to a single transmission mode through the 3G network under the control of the operation control unit 120, all the partial data is transmitted to the terminal device 400 through the first network device 200. In addition, when switching to the single transmission mode through the WiFi network, all the partial data is transmitted to the terminal device 400 through the second network device 300.

As described above, according to the heterogeneous network-based data simultaneous transmission system according to the present invention, in a data simultaneous transmission environment using a heterogeneous network, an access network exceeding a specified maximum transmission rate by checking a variable data transmission rate between access networks Is detected, the simultaneous transmission mode is deactivated to allow data transmission through a single access network, and at the same time, when it is confirmed that the packet delay value of the corresponding access network exceeds the threshold when transmitting data using the single access network, By activating the deactivated simultaneous transmission mode to perform simultaneous data transmission using heterogeneous networks, it is possible to improve the efficiency of the simultaneous transmission service using heterogeneous networks and to satisfy user's quality of experience.

Hereinafter, a heterogeneous network-based data transmission method according to an embodiment of the present invention will be described with reference to FIGS. 4 and 5. Here, the above-described configuration shown in Figures 1 to 3 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 an embodiment of the present invention will be described with reference to FIG. 4.

First, the management apparatus 100 selects the partial data divided from the transmission target data for each access network according to a data transmission rate that is variably set between access networks (S110-S130).

Preferably, the management device 100 checks the data transmission rate that is variably set between the access networks according to activation of the simultaneous transmission mode, that is, the first transmission rate and the second transmission rate for data transmission to the second network device 300. do. Furthermore, the management device 100 selects the first partial data to be transmitted to the first network device 200 among the partial data divided from the transmission target data received from the external device 500 based on the confirmed transmission rate. The second partial data to be transmitted to the second network device 300 is selected from the remaining partial data.

Then, the management apparatus 100 transmits the selected partial data using the corresponding access network (S150).

Preferably, the management device 100 transmits the partial data selected corresponding to the transmission target network, that is, the first partial data to the first network device 200 located in the 3G network, and thus the first network device 200. Transmits the first partial data to the terminal apparatus 400 as a receiving apparatus, and simultaneously transmits the second partial data to the second network apparatus 300 located in the WiFi network, thereby causing the second network apparatus 300 to transmit. The second partial data is transmitted to the terminal device 400 as a receiving device.

Then, the terminal device 400 receives and restores the partial data transmitted from the first network device 200 and the second network device 300 (S160).

Preferably, the terminal device 400 receives the first partial data through the first network device 200 in accordance with the simultaneous transmission mode of the management device 100, and also the second through the second network device 300. Partial data will be received. In addition, the terminal device 400 generates the data by combining the first partial data and the second partial data based on the virtual network access information included in the received first partial data and the second partial data, and thereby, the management apparatus 100. Restores the data to be sent. 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.

Then, the management apparatus 100 confirms that the data transmission rate of the specific access network exceeds a preset maximum transmission rate (S180).

Preferably, the management device 100 checks the data transmission rate variable for each access network to determine whether the data transmission rate of the specific access network exceeds a preset maximum transmission rate. To this end, as shown in FIG. 3, the management apparatus 100 designates the utilization efficiency (eg, 80% to 90%) for the entire bandwidth of the access network, that is, the 3G network and the WiFi network, according to the simultaneous transmission mode. In addition, the maximum transmission rate (eg, 3G network: WiFi network = 3: 1 or 1: 3) for the data transmission rate between access networks to ensure the specified utilization efficiency is set. Based on this, the management apparatus 100 is that the data transmission rate of a particular access network that is variably set based on various factors such as the characteristics of each access network, the current load state, and the type of data to be transmitted exceeds the maximum transfer rate. If confirmed, the simultaneous transmission mode is deactivated. For example, the management apparatus 100 may determine that the current data transmission rate of the 3G network and the WiFi network is 3G network: WiFi network = 4: 1, and the current data transmission rate of the 3G network is a preset maximum transmission rate ( 3G network: WiFi network = 3: 1). On the other hand, the management apparatus 100, if the currently confirmed data transmission rate between the 3G network and the WiFi network, for example, '3G network: WiFi network = 1: 4', the current data transmission rate of the WiFi network is the maximum transmission preset It will be perceived as exceeding the ratio (3G network: WiFi network = 1: 3).

Accordingly, when it is confirmed that the data transmission rate of the specific access network exceeds the maximum transmission rate, the management apparatus 100 deactivates the simultaneous transmission mode or readjusts the data transmission rate (S180).

Preferably, the management apparatus 100, through the above-described data transmission rate between the access network, if it is recognized that the data transmission rate of the specific access network exceeds the preset maximum transmission rate, the active simultaneous transmission mode Deactivate to switch to single transmission mode. For example, the management apparatus 100 determines that the current data transmission rate of the 3G network (3G network: WiFi network = 4: 1) exceeds the preset maximum transmission rate (3G network: WiFi network = 3: 1). By switching to a single transmission mode over a 3G network (3G network: WiFi network = 10: 1), the efficiency of the simultaneous transmission service is prevented from being degraded due to the decrease in the transmission performance of the WiFi network. On the other hand, if the management apparatus 100 determines that the current data transmission ratio (3G network: WiFi network = 1: 4) of the WiFi network exceeds the preset maximum transmission ratio (3G network: WiFi network = 1: 3). By switching to a single transmission mode (3G network: WiFi network = 1:10) over a WiFi network, the transmission performance of the 3G network is prevented from being lowered in the efficiency of the simultaneous transmission service.

In this regard, the management device 100 transmits the partial data via a single access network (S190).

Preferably, when the management device 100 is switched to a single transmission mode through the 3G network, all the partial data is transmitted to the terminal device 400 through the first network device 200, a single transmission through the WiFi network When the mode is switched, all partial data is transmitted to the terminal device 400 through the second network device 300.

Furthermore, the management apparatus 100 confirms that the packet delay value, which is the inter-packet interval information of the partial data, exceeds the threshold in the state of switching to the single transmission mode (S200).

Preferably, the management device 100 checks the packet delay value, which is the interval information between the packets of the partial data transmitted to the terminal device 400 through the specific access network, in the state of switching to the single transmission mode, and the confirmation It is checked whether the packet delay value exceeds the threshold. At this time, the management device 100 performs the continuous monitoring for the delay time between the packet [x_i, y_i] through the following [Equation 1], and if the result value through [Equation 1] is less than 0, the confirmed packet It is determined that the transmission performance of the access network is degraded because the delay value exceeds the threshold. Here, 'x_i' refers to a delay time between neighboring packets when transmitting partial data of the management apparatus 100, and 'y_i' refers to a delay time between neighboring packets when the corresponding partial data is received by the terminal device 400. Done. In this regard, when the partial data is received, the terminal device 400 continuously reports 'y_i' representing the delay time between neighboring packets to the management device 100. On the other hand, in the present embodiment, when the result value through [Equation 1] is less than 0, the transmission performance of the access network is reduced as an example, but in the case of the reference value to be compared with the calculated result value, the connection It can be set to other values depending on the state or setting of the network. In addition, instead of comparing the calculated result value with a specific reference value, the monitoring result of the inter-packet delay time [x_i, y_i] is performed through [Equation 1], so that the variation of the calculated result value is changed. If the value becomes smaller (eg, -0.1-> -0.2-> -0.3 ....), it can be determined that the transmission performance of the access network is degraded.

[Equation 1]

,

,

Thereafter, the management apparatus 100 switches to the simultaneous transmission mode when the checked packet delay value exceeds a threshold value (S210).

Preferably, the management apparatus 100 is the single transmission mode when it is confirmed that the packet delay value of the partial data transmitted to the terminal device 400 via the access network in the switching state to the single transmission mode exceeds the threshold value. Deactivate to switch to simultaneous transmission mode. For example, in the single transmission mode (3G network: WiFi network = 10: 1) through the 3G network, the management apparatus 100 determines that the performance degradation occurs because the packet delay value of the 3G network exceeds the threshold. By considering the transmission performance of the 3G network, the single transmission mode over the 3G network is deactivated to recover to the simultaneous transmission mode (3G network: WiFi network = 2: 1). On the other hand, in the single transmission mode (3G network: WiFi network = 1:10) over the WiFi network, the management device 100, if it is confirmed that the performance degradation occurs because the packet delay value of the WiFi network exceeds the threshold, By considering the transmission performance of the WiFi network, the single transmission mode over the WiFi network is deactivated to restore the simultaneous transmission mode (for example, 3G network: WiFi network = 1: 2).

Hereinafter, a method of operating the management apparatus 100 according to an embodiment of the present invention will be described with reference to FIG. 5.

First, the partial data divided from the transmission target data for each access network are selected according to the data transmission rate that is variably set between access networks (S310 to S340).

Preferably, the communication unit 110 checks the data transmission rate that is variably set between the access networks according to activation of the simultaneous transmission mode, that is, the first transmission rate and the second transmission rate for data transmission to the second network device 300. . Furthermore, the management apparatus 100 selects the first partial data to be transmitted to the first network device 200 from the partial data segmented from the transmission object data received from the external device 500 based on the confirmed transmission ratio, And selects the second partial data to be transmitted to the second network device 300 among the remaining partial data.

Then, the selected partial data is transmitted using the corresponding access network (S250).

Preferably, the communication unit 110 transmits the partial data selected corresponding to the transmission target network, that is, the first partial data to the first network device 200 located in the 3G network, to the first network device 200. Transmits the first partial data to the terminal apparatus 400 as a receiving apparatus, and simultaneously transmits the second partial data to the second network apparatus 300 located in the WiFi network, thereby causing the second network apparatus 300 to transmit the second partial data. The two-part data is transmitted to the terminal device 400 as a receiving device.

At the same time, it is confirmed that the data transmission rate of the specific access network exceeds the preset maximum transmission rate (S260-S270).

Preferably, the operation control unit 120 checks the data transmission rate that is variable for each access network to determine whether the data transmission rate of a specific access network exceeds a preset maximum transmission rate. That is, the operation controller 120 may determine that the data transmission rate of the specific access network that is variably set based on various factors such as the characteristics of each access network, the current load state, and the type of data to be transmitted exceeds the maximum transfer rate. In this case, the simultaneous transmission mode is deactivated. For example, the operation controller 120 may determine that the current data transfer rate of the 3G network and the WiFi network is 3G network: WiFi network = 4: 1, and the current data transfer rate of the 3G network is a preset maximum transfer rate ( 3G network: WiFi network = 3: 1). On the other hand, the operation control unit 120 when the currently confirmed data transmission rate between the 3G network and the WiFi network, for example, '3G network: WiFi network = 1: 4', the current data transmission rate of the WiFi network is the maximum transmission preset It will be perceived as exceeding the ratio (3G network: WiFi network = 1: 3).

In this case, when it is confirmed that the data transmission rate of the specific access network exceeds the maximum transmission rate, the simultaneous transmission mode is deactivated or the data transmission rate is readjusted (S280).

Preferably, the operation controller 120 checks the data transfer rate between the access networks as described above, and when it is recognized that the data transfer rate of the specific access network exceeds the preset maximum transfer rate, the active transmission mode is activated. Deactivate to switch to single transmission mode. For example, the operation controller 120 determines that the current data transmission rate (3G network: WiFi network = 4: 1) of the 3G network exceeds the preset maximum transmission rate (3G network: WiFi network = 3: 1). By switching to a single transmission mode over a 3G network (3G network: WiFi network = 10: 1), the efficiency of the simultaneous transmission service is prevented from being degraded due to the decrease in the transmission performance of the WiFi network. On the other hand, the operation controller 120 determines that the current data transmission rate (3G network: WiFi network = 1: 4) of the WiFi network exceeds the preset maximum transmission rate (3G network: WiFi network = 1: 3). By switching to a single transmission mode (3G network: WiFi network = 1:10) over a WiFi network, the transmission performance of the 3G network is prevented from being lowered in the efficiency of the simultaneous transmission service.

In this regard, the partial data is transmitted through the single access network (S290).

Preferably, when the communication unit 100 is switched to the single transmission mode via the 3G network under the control of the operation control unit 120, all the partial data is transmitted to the terminal device 400 through the first network device 200. In addition, when switching to the single transmission mode through the WiFi network, all the partial data is transmitted to the terminal device 400 through the second network device 300.

Further, it is confirmed that the packet delay value, that is, the interval information between the packets of the partial data, exceeds the threshold in the switching state to the single transmission mode (S300-S310).

Preferably, the operation control unit 120 checks the packet delay value, which is the interval information between the packets of the partial data transmitted to the terminal device 400 through the specific access network, in the state of switching to the single transmission mode, and the confirmation It is determined whether the packet delay value exceeds the threshold value, and when it exceeds the threshold value, it is determined that the transmission performance of the access network is degraded.

After that, if the checked packet delay value exceeds the threshold value, the simultaneous transmission mode is switched (S320).

Preferably, the operation control unit 120 when the packet delay value of the partial data transmitted to the terminal device 400 via the access network in the transition to the single transmission mode is confirmed to exceed the threshold value in the single transmission mode Deactivate to switch to simultaneous transmission mode. For example, in the single transmission mode (3G network: WiFi network = 10: 1) through the 3G network, the management apparatus 100 determines that the performance degradation occurs because the packet delay value of the 3G network exceeds the threshold. By considering the transmission performance of the 3G network, the single transmission mode over the 3G network is deactivated to recover to the simultaneous transmission mode (3G network: WiFi network = 2: 1). On the other hand, the operation control unit 120 in the single transmission mode over the WiFi network (3G network: WiFi network = 1:10), when the packet delay value of the WiFi network is confirmed that the performance degradation occurs because the threshold exceeds, By considering the transmission performance of the WiFi network, the single transmission mode over the WiFi network is deactivated to restore the simultaneous transmission mode (for example, 3G network: WiFi network = 1: 2).

As described above, according to the heterogeneous network-based data transmission method according to the present invention, in a data simultaneous transmission environment using a heterogeneous network, the access network that exceeds the specified maximum transmission rate by checking the variable data transmission rate between access networks Is detected, the simultaneous transmission mode is deactivated to allow data transmission through a single access network, and at the same time, when it is confirmed that the packet delay value of the corresponding access network exceeds the threshold when transmitting data using the single access network, By activating the deactivated simultaneous transmission mode to perform simultaneous data transmission using heterogeneous networks, it is possible to improve the efficiency of the simultaneous transmission service using heterogeneous networks and to satisfy user's quality of experience.

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, etc. 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 recording media include magnetic media such as hard disks, floppy disks, and magnetic tape, optical media such as CD-ROMs, DVDs, and magnetic disks, 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 not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like. The hardware device 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, in the simultaneous data transmission environment using a heterogeneous network, the heterogeneous network is activated by dynamically activating or deactivating the simultaneous transmission mode by recognizing the current state of each access network. Overcoming the limitations of existing technologies in improving the efficiency of the simultaneous transmission service used, not only the use of related technologies, but also the possibility of market or sales of the applied devices are not only sufficient but also realistically implemented. It is an invention that can be used.

100: management device
110: communication unit 120: operation control unit
200: first network device
300: second network device
400: terminal device
500: External device

Claims (6)

A communication unit configured to transmit, through the two or more access networks, partial data divided from the data to be transmitted based on a data transmission rate that is variably set between two or more access networks according to the simultaneous transmission mode activation; And
An operation control unit for checking a data transmission rate that is variable for each access network and determining that the data transmission rate of a specific access network exceeds a preset maximum transmission rate, and deactivating the simultaneous transmission mode to switch to a single transmission mode. ,
Wherein,
And transmitting the partial data through the specific access network according to the switching to the single transmission mode. The method of claim 1,
The operation control unit,
Designate a utilization efficiency for the entire bandwidth of the two or more access networks according to the simultaneous transmission mode, and set the maximum transfer rate for the data transfer rate between access networks to ensure the specified use efficiency,
And disabling the simultaneous transmission mode when it is confirmed that the data transmission rate of the specific access network exceeds the maximum transmission rate. The method of claim 1,
The operation control unit,
In the switching state to the single transmission mode, the packet delay value, which is the interval information between packets of the partial data transmitted through the specific access network, is checked.
And disabling the single transmission mode to switch to the simultaneous transmission mode when the checked packet delay value exceeds a threshold value. A simultaneous transmission mode operation step of transmitting, through the two or more access networks, partial data divided from the transmission target data based on a data transmission rate that is variably set between two or more access networks according to activation of the simultaneous transmission mode;
A maximum transmission rate exceeding checking step of checking a data transmission rate variable for each access network to determine whether a preset maximum transmission rate is exceeded;
A single transmission mode switching step of deactivating the simultaneous transmission mode and switching to a single transmission mode when it is confirmed that a data transmission rate of a specific access network exceeds a preset maximum transmission rate; And
And a single transmission mode operation step of transmitting the partial data through the specific access network in accordance with the switching to the single transmission mode. The method of claim 4, wherein
The maximum transmission rate exceeded confirmation step,
A use efficiency specifying step of designating a use efficiency for the entire bandwidth of the two or more access networks according to the simultaneous transmission mode;
A maximum transmission rate setting step of setting the maximum transmission rate with respect to a data transmission rate between access networks to ensure the specified utilization efficiency; And
Heterogeneous network-based simultaneous data transmission method comprising the step of checking whether the data transmission rate that is variable for each access network to determine whether or not to exceed a predetermined maximum transmission rate. The method of claim 4, wherein
The method comprises:
A packet delay value checking step of checking a packet delay value, which is interval information between packets of partial data transmitted through the specific access network, in a state of switching to the single transmission mode;
A threshold value over-checking step of confirming whether the checked packet delay value exceeds a threshold value; And
And disabling the single transmission mode and switching to the simultaneous transmission mode when the checked packet delay value exceeds a threshold value.

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