KR20130138598A - Apparatus for simultaneously transmitting data in heterogeneous network - Google Patents

Abstract

Disclosed are a reception device and method for multiple network-based simultaneous data transmission and a transmission device and method for multiple network-based simultaneous data transmission in an environment which provides a simultaneous transmission service for transmitting and receiving partial data produced by partitioning data using a plurality of multiple networks, wherein transmission delay between networks is effectively measured using a transmission time interval and a reception time interval for partial data, thereby minimizing an unnecessary request for retransmission of partial data and improving the transmission performance and quality of the simultaneous transmission service based on the measured transmission delay between the networks. [Reference numerals] (110) Communication unit;(120) Storage unit;(130) Information verification unit;(140) Control unit

Description

A device that supports multiple network-based simultaneous transport services {APPARATUS FOR SIMULTANEOUSLY TRANSMITTING DATA IN HETEROGENEOUS NETWORK}

The present invention relates to a simultaneous transmission service scheme, and more particularly, a transmission time interval for partial data in an environment for providing a simultaneous transmission service for transmitting / receiving partial data obtained by dividing data using a plurality of multiple networks. And by effectively measuring the transmission delay between each network using the receiving time interval, based on the measured transmission delay between each network, it is possible to minimize unnecessary partial data retransmission request and improve the transmission performance and quality of the simultaneous transmission service. The present invention relates to a network-based simultaneous transmission receiving apparatus and a receiving method, and to a multiple network-based simultaneous transmission transmitting apparatus and a transmitting method.

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

In the heterogeneous network environment in which multiple networks are mixed, the current method of using a data service by a terminal device is a method of selecting a network by a direct change of a terminal user, thereby eliminating operator controllability. Because of this, it can be said to be passive in consideration of the operator's position.

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

Accordingly, in a multi-network environment in which several networks are mixed, a new service scheme for actively selecting a network of a terminal device according to the state of a network and efficiently transmitting data using the selected network is required.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object of the present invention is to provide partial data in an environment for providing a simultaneous transmission service for transmitting / receiving partial data obtained by dividing data using a plurality of multiple networks. By effectively measuring the transmission delay between each network by using the transmission time interval and the receiving time interval, the unnecessary partial data retransmission request is minimized based on the measured transmission delay between each network, and the transmission performance and quality of the simultaneous transmission service are improved. To improve.

According to a first aspect of the present invention, there is provided a multiple network-based simultaneous transmission and reception apparatus including: a communication unit configured to receive partial data divided from transmission target data through two or more access networks; An information checking unit for identifying a pair of partial data having consecutive transmission order information received through different access networks of the two or more access networks; And a control unit which checks a network transmission delay value between the different access networks using at least one of a reception time interval and a transmission time interval associated with the pair of partial data.

Preferably, the control unit may obtain a reception time interval associated with the pair of partial data based on the reception time of each of the pair of partial data.

Preferably, the partial data includes transmission time interval information with the partial data having the previous transmission order information, and the control unit is configured to transmit the transmission time of the partial data having later transmission order information among the pair of partial data. The transmission time interval may be obtained based on the interval information.

Preferably, the network transmission delay value may be a network transmission delay value based on the access network in which the partial data having the previous transmission order information among the pair of partial data is received.

Preferably, the controller may vary the waiting time set to wait for a request for retransmission of unreceived partial data based on the network transmission delay value.

Preferably, the controller may determine an average value of network transmission delay values based on each of the two or more access networks, and set a maximum value of the average values determined for each of the two or more access networks as the waiting time.

Multi-network-based simultaneous transmission and transmission apparatus according to a second aspect of the present invention for achieving the above object is a part for selecting each of the partial data divided from the transmission target data for each network based on the data transmission rate for each of two or more preset network A data selection unit; An information insertion unit for inserting, in each partial data selected for each of the two or more access networks, transmission sequence information related to the transmission order transmitted to the two or more access networks and transmission time interval information related to the partial data having immediately previous transmission order information; And a communication unit transmitting the selected partial data for each of the two or more access networks through each access network.

Preferably, the different access networks identified using at least one of a reception time interval and a transmission time interval associated with a pair of partial data having consecutive transmission order information received through each of the different access networks of the two or more access networks. The control unit may further include a controller configured to obtain a network transmission delay value between the two and change the data transmission rate of each of the two or more networks based on the obtained network transmission delay value.

According to a third aspect of the present invention, there is provided a multiple network-based simultaneous transmission and reception method including: partial data reception step of receiving partial data divided from transmission target data through two or more access networks; A partial data checking step of identifying a pair of partial data having consecutive transmission order information received through each of different access networks of the two or more access networks; And checking a network transmission delay value between the different access networks by using at least one of a reception time interval and a transmission time interval associated with the pair of partial data.

According to a fourth aspect of the present invention, there is provided a multiple network-based simultaneous transmission transmission method comprising: partial data selection step of selecting partial data divided from transmission target data for two or more access networks; An information insertion step of inserting, in each partial data selected for each of the at least two access networks, transmission sequence information related to a transmission sequence transmitted to at least two access networks and transmission time interval information related to partial data having immediately preceding transmission sequence information; And a partial data transmission step of transmitting the selected partial data for each of the two or more access networks through each access network.

Accordingly, according to the multi-network based simultaneous transmission receiving apparatus and reception method, and the multi-network based simultaneous transmission transmission apparatus and transmission method, the objective is to transmit / receive partial data obtained by splitting data using a plurality of multiple networks. In an environment providing simultaneous transmission service, the transmission delay between each network is effectively measured by using the transmission time interval and the reception time interval for partial data, and thus the unreceived portion is not received at the receiving side based on the measured transmission delay between networks. Unnecessary retransmission requests related to data can be minimized, and the sender can optimize the rate of partial data transmission for each network. As a result, the transmission performance and quality of the simultaneous transmission service can be improved.

1 is a block diagram showing a multiple network-based simultaneous transmission service system according to a preferred embodiment of the present invention.
2 is a block diagram showing the configuration of a multi-network based simultaneous transmission receiving apparatus according to a preferred embodiment of the present invention.
3 is a block diagram showing the configuration of a multi-network based simultaneous transmission transmitter according to a preferred embodiment of the present invention.
4 is a flowchart illustrating an operation flow in a multi-network based simultaneous transmission service system according to a preferred embodiment of the present invention.
5 is a flowchart illustrating a flow of a method for receiving simultaneous transmission based on multiple networks according to an embodiment of the present invention.
6 is a flowchart illustrating a flow of a multi-network based simultaneous transmission transmission method according to a preferred embodiment of the present invention.
7 is an exemplary diagram for transmitting partial data in the simultaneous transmission of multiple network-based data in accordance with a preferred embodiment of the present invention.

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

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

As shown in FIG. 1, the multiple network-based simultaneous transmission service system according to the present invention includes a management apparatus 400 for supporting a simultaneous transmission service in which transmission target data is divided into a pair of partial data and transmitted through two or more networks. And at least one terminal device 100 connected to the management device 400 to use a simultaneous transmission service.

Here, two or more networks, i.e., heterogeneous networks, may include WCDMA, CDMA, WiBro, WLAN (WiFi) and Long Term Evolution (LTE).

In the present invention, for convenience of explanation, a first network (hereinafter referred to as a "3G network"), which refers to a wireless packet service network (WCDMA) among two or more networks, and a second network 2 network (hereinafter referred to as "WiFi network"). Accordingly, the first network device 200 refers to a 3G network, that is, a Gateway GPRS Support Node (GGSN) for operating a wireless packet service network. In addition, the second network device 300 includes a WiFi network, And an access point (AP) for operating a short-range wireless network.

Furthermore, the multi-network based simultaneous transmission service system according to the present invention, the external device 500 for receiving the combined / restored data according to the simultaneous transmission service from the management device 400 and the policy management device for providing a network selection policy (Not shown).

Here, the external device 500 refers to a server device that performs data reception with the terminal device 100 through the management device 400, the terminal device 100 through the data reception through the management device 400. For example, various services such as a portal service and a content providing service may be provided.

Accordingly, the multi-network-based simultaneous transmission service according to the present invention divides and divides one data between the terminal device 100 and the management device 400 for data reception between the terminal device 100 and the external device 500. The data is transmitted using a plurality of multiple networks (eg, 3G and WiFi), and the received data is combined to implement a simultaneous transmission service to restore the original data.

At this time, the terminal device 100 and the management device 400 may be devices on the transmission side according to the uplink process and the downlink process, depending on the subject of data transmission using the service flow, that is, the data transmission service And may be a device on the receiving side. In the present embodiment, for convenience of description, a management apparatus 400 serving as a transmission apparatus for providing a simultaneous transmission service to a terminal apparatus 100 located in a multi-network environment based on a downlink process will be described. 400 and a terminal device 100 as a reception device for performing data reception.

Therefore, since the simultaneous transmission service provided by the present invention simultaneously transmits the partial data divided from one data using a plurality of multiple networks (for example, 3G and WiFi), the plurality of multiple transmissions are performed on the terminal apparatus 100 side. It is very important to restore all the partial data received through the network (eg 3G and WiFi) without loss / loss and combine them according to the partitioning order.

However, there is a difference between the latency of each network because the network quality (throughput, delay, loss, etc.) between each network is different from each other and the network state of each network is variable in real time. Therefore, even though each piece of data is simultaneously transmitted using a plurality of multiple networks (eg, 3G and WiFi), the terminal device 100 may not actually transmit each network (eg, 3G and WiFi) due to differences in transmission latency between networks. Differences occur when the partial data received is received.

On the other hand, according to the TCP retransmission rule, when a retransmission request, for example, a duplicate Ack is received a specific number of times (for example, three times) from a receiving device that receives data (partial data packet), the corresponding data (partial) is received. There is a redundant Ack-based retransmission operation that determines that data packets are lost during transmission and retransmits.

Therefore, in the receiving device, in consideration of the difference in the time of reception of the partial data received through each network due to the transmission delay of each network, the receiving buffer receives the partial data received through each network in order. If the partial data of the previous sequence is not received, the partial data of the sequence after the unreceived partial data is not delivered to the upper layer (for example, an application using a simultaneous transmission service) for a preset waiting time, and the waiting time is If the unreceived partial data still cannot be received, the partial data of the received sequence is first delivered to the upper layer until the unreceived partial data is received so that a retransmission request such as a Dup Ack related to the unreceived partial data can be generated. Unnecessary retransmission of unreceived partial data For example, a duplicate Ack can be prevented from occurring.

Therefore, as described above, the waiting time, which is a time reference for generating a retransmission request related to unreceived partial data, should be optimally set based on the transmission delay of each network. In other words, if the waiting time is too long, unnecessarily waiting for other partial data in a high-quality network, and the loss determination time is too long, and the transmission performance decreases. Eventually, transmission performance may be reduced.

Accordingly, in the present invention, in the environment for providing simultaneous transmission service, as the transmission delay between networks is different in the receiving device, the transmission delay between each network is effectively measured by using the transmission time interval and the reception time interval for the partial data. On the basis of the measured transmission delays between the networks, the present invention proposes a method for minimizing unnecessary partial data retransmission requests in the transmitting device and / or the receiving device.

For convenience of explanation, the downlink will be described with reference to the following. The management apparatus 400 as the transmitting apparatus, that is, the multi-network based simultaneous transmitting transmitting apparatus, transmits data to be transmitted from the external apparatus 500 to the terminal apparatus 100. When received, the data is divided into partial data, and each divided data is selected for each access network based on a data transfer rate of two or more networks.

That is, when the management device 400 receives the transmission target data to be transmitted from the external device 500 to the terminal device 100, the management device 400 divides the data into partial data, and the data transmission rate for each access network (for example, WiFi and 3G). That is, the first transmission rate for data transmission to the first network device 200 and the second transmission rate for data transmission to the second network device 300 are identified, and the data is divided into transmission target data based on the confirmed transmission rate. The partial data to be transmitted to the first network device 200 is selected from the partial data, and the partial data to be transmitted to the second network device 300 is selected from the remaining partial data.

At this time, it is preferable that the management apparatus 400 combines the partial data divided from the transmission target data and adds / inserts the division order information to each partial data so that the original transmission target data can be restored.

In addition, the management apparatus 400 transmits each partial data selected for each access network (eg, WiFi and 3G) through each access network (eg, WiFi and 3G), and thus, the first network apparatus 200 is a management apparatus. The partial data transmitted from the 400 is transmitted to the terminal device 100, and the second network device 300 transmits the partial data transmitted from the management device 400 to the terminal device 100.

At this time, the management device 400 inserts, in each of the partial data, the transmission sequence information related to the transmission sequence transmitted to the two or more access networks and the transmission time interval information associated with the partial data having consecutive preceding transmission sequence information.

That is, the management device 400 may assign / insert transmission sequence information for the entire order of transmission without division of network types to each partial data transmitted through the access network (eg, WiFi and 3G).

For example, as shown in FIG. 7, the management apparatus 400 assigns / inserts transmission order information 1,2 to the first and second partial data transmitted to the first network, that is, the 3G network, and the second network, such as WiFi. Granting / inserting transmission order information 3 to the third partial data to be transmitted to the network, assigning / inserting transmission order information 4 to the fourth partial data to be transmitted to the 3G network, and transmitting to the fifth and sixth partial data to be transmitted to the WiFi network. Transmission order information 5 and 6 can be assigned / inserted, and transmission order information 7 can be assigned / inserted to the seventh partial data transmitted to the 3G network.

At this time, the transmission order information and the division order information described above to be given / inserted to each partial data may be the same or different from each other.

Then, the management device 400 inserts the transmission time interval information associated with the partial data immediately preceding the partial data, that is, the partial data having the preceding transmission sequence information continuous with the partial data.

For example, as shown in FIG. 7, the management device 400 is continuous with partial data of transmission order information 2 since there is no partial data having previous transmission order information subsequent to partial data of transmission order information 1. 10 ms of transmission time interval information with the partial data having the preceding transmission sequence information 1, and 3 ms of the transmission time interval information with the partial data having the preceding transmission sequence information 2 consecutive The transmission time interval information can be inserted up to the partial data of the transmission sequence information 7 by inserting the transmission time interval information 10 ms with the partial data having the preceding transmission sequence information 2 consecutively into the partial data.

In this case, the management device 400 may maintain a constant transmission time interval (eg 10 ms) between each piece of data having continuous transmission order information and transmit each piece of data accordingly, in which case it is inserted into each piece of data. The transmission time interval information is the same as the transmission time interval (eg, 10ms) that is kept constant.

On the other hand, the management device 400, each time the transmission of each piece of data can be measured as a transmission time interval associated with the partial data having the preceding transmission sequence information to be inserted as the transmission time interval information, in this case to each piece of data Inserted transmission time interval information may be different.

Therefore, referring to FIG. 7, referring to the partial data of the transmission order information 1 to be transmitted through 3G as an example, information as the transmission order information according to the order transmitted from the management device 400 in the area ⓐ without distinguishing between 3G and WiFi networks. 1 may be included, and the area ⓑ may include information 0ms as transmission time interval information with the partial data having consecutive preceding transmission sequence information.

Accordingly, the terminal device 100 can restore the transmission object data by combining the partial data received through two or more networks based on the division order information.

In more detail, the terminal device 100 receives the partial data from the first network device 200 through two or more access networks (eg, WiFi, 3G) and the partial data from the second network device 300. Will be received.

Accordingly, the terminal device 100 recognizes partial data having the same identification information (eg, virtual IP) indicating that the data is divided from one data based on identification information (eg, virtual IP) included in the received partial data. And, they can be rearranged to the receiving buffer based on the transmission order information included in the corresponding partial data.

In this case, the terminal device 100 applies a preset waiting time to wait for a retransmission request related to unreceived partial data in response to each partial data received through two or more access networks (eg, 3G and WiFi). The redundant ack-based retransmission operation as described above will be performed.

That is, the terminal device 100 rearranges each partial data received through two or more access networks (eg, 3G and WiFi) to the reception buffer (storage unit 120 of FIG. 2) based on the transmission order information. When the unreceived partial data is confirmed, after the unreceived partial data, the partial data of the transmission order information is not transmitted to a higher layer (for example, an application using a simultaneous transmission service) for a preset waiting time, and the waiting time elapses. If the unreceived partial data still cannot be received, the partial data of the transmission sequence information is first transmitted after being received first, so that a retransmission request such as a Dup Ack related to the unreceived partial data can be generated. For example, a retransmission request for the lost unreceived partial data may be provided to the management apparatus 400 of the transmitting side, for example, a duplicate Ack.

The terminal device 100 confirms a pair of partial data having consecutive transmission order information received through each of the different access networks of two or more access networks.

For example, the terminal device 100 may include a pair of pieces of serial data received through two or more access networks (eg, 3G and WiFi) having consecutive transmission order information received through different access networks. Check the partial data.

Referring to FIG. 7, the terminal device 100 may identify partial data of transmission order information 2 and 3 as a pair of partial data having consecutive transmission order information received through each of different access networks. The sub partial data of the transmission order information 3 and 4 can be confirmed, the partial data of the transmission order information 4 and 5 can be confirmed, and the partial data of the transmission order information 6 and 7 can be confirmed.

Thereafter, the terminal apparatus 100 includes at least one of a reception time interval and a transmission time interval associated with the pair of partial data identified, that is, the pair of partial data having consecutive transmission order information received through each of different access networks. Confirm the network transmission delay value between the different access networks by using.

To describe in more detail with reference to the partial data of the transmission order information 2 and 3 confirmed, the terminal device 100, the reception time (eg, 07/00/00) when the partial data of the transmission order information 2 is received / 00 (h / m / s / ms)), based on the reception time (for example, 07/00/00/40 (h / m / s / ms)) when the partial data of the transmission order information 3 is received, The reception time interval associated with the partial data of the sequence information 2 and 3 can be checked.

At this time, preferably, the terminal device 100 first receives the second partial data having the transmission sequence information after the later received, among the partial data of the transmission sequence information 2 and 3, that is, the partial data reception time of the transmission sequence information 3. By subtracting the first partial data of the previous transmission sequence information, that is, the partial data reception time of the transmission sequence information 2, the reception time interval (for example, 40 ms) related to the partial data of the transmission sequence information 2 and 3 can be confirmed.

Then, the terminal device 100, from the second partial data having the later transmission order information of the partial data of the transmission order information 2 and 3, that is, the partial data of the transmission order information 3, the first part having continuous preceding transmission order information By checking the transmission time interval information related to the data, that is, the partial data of the transmission order information 2, the transmission time interval related to the partial data of the transmission order information 2 and 3 can be obtained. As described above with reference to FIG. 7, the terminal device 100 may acquire transmission time interval information (eg, 10 ms) included in the partial data of the transmission order information 3.

Accordingly, the terminal apparatus 100 includes a first transmission sequence information having at least one of a reception time interval (for example, 40 ms) and a transmission time interval (for example, 10 ms) associated with the partial data of the transmission sequence information 2 and 3. It is possible to calculate the network transmission delay value of the WiFi for which the second partial data having the transmission order information, that is, the partial data of the transmission order information 2, after the partial data of the transmission order information 2 has been received, that is, the partial data of the transmission order information 3 is received.

In this case, the network transmission delay value may be a network transmission delay value based on the access network in which the partial data having the previous transmission order information among the pair of partial data is received.

That is, the terminal device 100 uses the network transmission delay value calculated with respect to the partial data of the transmission order information 2 and 3 as described above, based on the 3G from which the partial data of the previous transmission order information 2 was received. It can be checked by network transmission delay value.

Preferably, it may be calculated by Equations 1 and 2 below.

Network transmission delay value between 3G standard access network = {(Receive time via WiFi)-(Receive time via 3G)}-(Transmission time interval) Equation 1

Network transmission delay value between WiFi access network = {(Receive time through 3G)-(Receive time through WiFi)}-(Transfer time interval) Equation 2

In other words, with respect to the partial data of the transmission order information 2 and 3, the terminal apparatus 100 refers to the first partial data having the previous transmission order information received first, that is, the 3G on which the partial data of the transmission order information 2 is received. By using the reception time interval and the transmission time interval related to the partial data of the transmission sequence information 2 and 3, the network transmission delay value between the access networks (3G and WiFi) based on 3G can be calculated / confirmed according to Equation 1. have.

As described above, the terminal apparatus 100 refers to the first partial data having the previous transmission order information received, that is, the partial data of the transmission order information 3, with respect to the partial data of the transmission order information 3 and 4, based on the received WiFi. By using the reception time interval and the transmission time interval related to the partial data of the transmission sequence information 3 and 4, the network transmission delay value between the access networks (WiFi and 3G) based on WiFi can be calculated / confirmed according to Equation 2. have.

In addition, the terminal device 100, in connection with the partial data of the transmission order information 4 and 5, the same as the partial data of the transmission order information 2 and 3 described above, the access network (3G and WiFi) based on 3G according to Equation 1 Network transmission delay value), and the access network based on WiFi according to Equation 2 in the same manner as the partial data of the transmission sequence information 3 and 4 described above with respect to the partial data of the transmission sequence information 6 and 7. You can calculate / check the network transmission delay value between (WiFi and 3G).

As such, whenever the pair of partial data having the continuous transmission order information received through each of the different access networks is confirmed, the terminal apparatus 100 receives the first partial data having the previous transmission order information received first. The network transmission delay value between the access networks based on the access network will be calculated. In this case, if the calculated network transmission delay value is negative (-), the terminal device 100 preferably discards the calculated network transmission delay value.

Accordingly, the terminal device 100, based on the network transmission delay value between the access network on the basis of the access network calculated as described above, the receiving buffer (storage unit (Fig. 2) 120) can be set variably.

For example, the terminal device 100 may calculate an average value of network transmission delay values between access networks calculated on the basis of each access network as described above.

Accordingly, when the specific setting time elapses, the terminal device 100 waits for the reception buffer (storage unit 120 of FIG. 2) by using the largest average value among the average values of the network transmission delay values based on each access network. Can be set.

Accordingly, the terminal apparatus 100 may variably set the waiting time of the reception buffer (the storage unit 120 of FIG. 2), and then receive the partial data to be rearranged to the reception buffer (the storage unit 120 of FIG. 2). In this case, the redundant delay-based retransmission operation will be performed by applying a variable set latency.

On the other hand, in the foregoing description, the case where the management apparatus 400 transmits partial data obtained by dividing the transmission object data to the terminal apparatus 100 on the basis of the downlink is described.

In addition, in the simultaneous transmission service to which the present invention is applied, the terminal apparatus 100 transmits the partial data obtained by dividing the transmission target data to the management apparatus 400 during the uplink, and the management apparatus 400 rearranges the partial data. In this case, the terminal apparatus 100 as the transmitting apparatus in the uplink performs the above-mentioned partial data division and the transmission sequence information and the transmission time interval information insertion and the partial data transmission performed by the management apparatus 400 as the transmitting apparatus in the downlink. And the above-mentioned partial data rearrangement and redundant arc-based retransmission operation performed by the terminal apparatus 100 as a receiving apparatus during downlink, calculation of network transmission delay value between each access network reference access network, and variable time setting. The management device 400 as a receiving device may perform the uplink.

Hereinafter, a configuration of a multi-network based simultaneous transmission receiving apparatus, that is, a receiving apparatus according to the present invention will be described in more detail with reference to FIG. 2. For convenience of description, reference numbers of the terminal apparatus 100 are referred to based on the downlink, and reference is made to the transmitting apparatus 400 using the reference numbers of the management apparatus 400.

Multi-network-based simultaneous transmission and reception apparatus according to a preferred embodiment of the present invention, that is, the receiving device 100, the communication unit 110 for receiving the partial data divided from the transmission target data through two or more access networks, and the two or more An information checking unit 130 for confirming a pair of partial data having consecutive transmission order information received through each of different access networks among the access networks, and among reception time intervals and transmission time intervals related to the pair of partial data; And a controller 140 for checking a network transmission delay value between the different access networks using at least one of them.

In addition, the multi-network-based simultaneous transmission receiving apparatus according to the preferred embodiment of the present invention, that is, the receiving side apparatus 100 may further include a storage unit 130 for temporarily storing the rearranged received partial data according to the transmission order information. Can be.

The communication unit 110 refers to a communication module for interfacing with the first network device 200 using the 3G network and interworking with the second network device 300 using the WiFi network.

Thus, the communication unit 110 may receive a plurality of pieces of partial data divided from the transmission target data from the above-mentioned transmission apparatus 400 through two or more access networks (eg, 3G, WiFi).

Accordingly, the multi-network based simultaneous transmission receiving apparatus, that is, the receiving apparatus 100 according to the preferred embodiment of the present invention, is divided into one data based on identification information (eg, virtual IP) included in the received partial data. Recognizing partial data having the same identification information (for example, virtual IP) indicating that the data, and reordering them in the storage unit 120 based on the transmission order information included in the corresponding partial data.

The storage unit 120 may perform a redundant arc-based retransmission operation by applying a preset waiting time to wait for a retransmission request related to the unreceived partial data, in response to each partial data to be rearranged and stored.

That is, when the unreceived partial data is confirmed, the storage unit 120 transfers the partial data of the transmission order information after the unreceived partial data to a higher layer (for example, an application using a simultaneous transmission service) for a preset waiting time. If the unreceived partial data is still not received until the waiting time has elapsed, the partial data of the transmission sequence information is first transmitted to the upper layer after receiving the first partial data. By allowing a Dup Ack to be generated, a retransmission request for the lost unreceived partial data, for example, a duplicate Ack, may be provided to the transmitter 400.

The information confirming unit 130 confirms the pair of partial data having consecutive transmission order information received through each of the different access networks of the two or more access networks.

That is, the information checking unit 130, a pair of parts having a continuous transmission order information received through each of the different access network, each of the partial data received through the two or more access networks (eg 3G, WiFi) Check the data.

For example, referring to FIG. 7, the information checking unit 130 rearranges the transmission data based on the transmission order information in response to each piece of data received through two or more access networks (eg, 3G and WiFi). As a pair of partial data having consecutive transmission order information received through each of different access networks, the partial data of the transmission order information 2 and 3 can be confirmed, and the partial partial data of the transmission order information 3 and 4 can be confirmed. The partial data of the transmission order information 4 and 5 can be confirmed, and the partial data of the transmission order information 6 and 7 can be confirmed.

The controller 140 uses at least one of a reception time interval and a transmission time interval associated with the pair of partial data identified, that is, the pair of partial data having consecutive transmission sequence information received through each of different access networks. Check the network transmission delay value between the different access networks.

In more detail, the control unit 140 confirms a pair of partial data, for example, partial data of the transmission order information 2 and 3, and transmits the partial data of the transmission order information 2 and 3 based on the reception time at which each of the partial data of the transmission order information 2 and 3 is received. Obtain a reception time interval associated with the partial data of sequence information 2 and 3.

That is, the controller 140 receives the reception time (eg, 07/00/00/00 (h / m / s / ms)) when the partial data of the transmission order information 2 is received and the partial data of the transmission order information 3 is received. Based on the received time (eg, 07/00/00/40 (h / m / s / ms)), the receiving time interval related to the partial data of the transmission order information 2 and 3 can be checked.

At this time, preferably, the control unit 140 is first received at the time of receiving the second partial data of the partial data of the transmission order information 2 and 3 after the received later, that is, the partial data of the transmission order information 3. By subtracting the first partial data of the transmission sequence information, that is, the partial data reception time of the transmission sequence information 2, the reception time interval (for example, 40 ms) related to the partial data of the transmission sequence information 2 and 3 can be confirmed.

Then, the control unit 140 is the first partial data having the preceding transmission sequence information consecutive from the second partial data having the later transmission sequence information, that is, the partial data of the transmission sequence information 3 among the partial data of the transmission sequence information 2 and 3, The transmission time interval information related to the partial data of the transmission sequence information 2 is checked to obtain a transmission time interval related to the partial data of the transmission sequence information 2 and 3.

That is, as shown in FIG. 7 described above, the controller 140 may obtain transmission time interval information (eg, 10 ms) included in the partial data of the transmission order information 3.

In response, the control unit 140 uses the first transmission sequence information having at least one of a reception time interval (for example, 40 ms) and a transmission time interval (for example, 10 ms) related to the partial data of the transmission sequence information 2 and 3. It is possible to calculate a network transmission delay value of WiFi in which the second data having the transmission order information, that is, the partial data of the transmission order information 3, is received, compared to the 3G in which the partial data of the transmission order information 2 is received.

Accordingly, the control unit 140 may determine the network transmission delay value calculated in relation to the partial data of the transmission order information 2 and 3 as described above, and that is, the connection network where the partial data having the preceding transmission order information among the pair of partial data is received. The network transmission delay value between the access networks (3G and WiFi) based on 3G can be confirmed.

In this way, the control unit 140, with respect to the partial data of the transmission order information 2 and 3, based on the first partial data having the previous transmission order information received, that is, the partial data of the transmission order information 2, is received on the basis of 3G. , Using the reception time interval and transmission time interval related to the partial data of the transmission order information 2 and 3, the network transmission delay value between the access networks (3G and WiFi) based on 3G can be calculated / confirmed according to Equation 1 above. have.

In this way, the control unit 140, with respect to the partial data of the transmission order information 3 and 4, based on the first partial data having the previously received transmission order information, that is, the partial data of the transmission order information 3, is received based on the WiFi received. By using the reception time interval and the transmission time interval related to the partial data of the transmission sequence information 3 and 4, the network transmission delay value between the access networks (WiFi and 3G) based on WiFi can be calculated / confirmed according to Equation 2 above. Can be.

Further, the control unit 140, in connection with the partial data of the transmission order information 4 and 5, the same as the partial data of the transmission order information 2 and 3 described above, the access network (3G and WiFi) based on 3G according to Equation 1 The network transmission delay value can be calculated / confirmed, and in connection with the partial data of the transmission order information 6 and 7, the same as the partial data of the transmission order information 3 and 4 described above, the access network based on WiFi according to Equation 2 ( The network transmission delay value between WiFi and 3G) can be calculated / verified.

As such, the controller 140 may access the first partial data having the first transmission order information received first each time a pair of partial data having the consecutive transmission order information received through each of the different access networks is identified. The network transmission delay value between the access networks based on the network will be calculated. At this time, if the calculated network transmission delay value is negative (-), the controller 140 preferably discards the calculated network transmission delay value.

The controller 140 variably sets the waiting time of the storage unit 120 applied to the above-described redundant arc-based retransmission operation based on the network transmission delay value between the access networks based on the access network criteria calculated as described above. Can be.

For example, the controller 140 may calculate an average value of network transmission delay values between access networks calculated on the basis of each access network as described above.

Thus, when the specific setting time elapses, the controller 140 may set the waiting time of the storage unit 120 using the largest average value among the average values of the network transmission delay values based on each access network.

Accordingly, the storage unit 120 may perform the redundant arc-based retransmission operation as described above by applying a variable set waiting time to partial data received and rearranged and stored.

Furthermore, the controller 140 may report the average value of the network transmission delay values calculated on the basis of each access network and the variable set waiting time to the transmitter 400.

Hereinafter, a configuration of a multiple network-based simultaneous transmission transmitter, that is, a transmitter side apparatus according to an embodiment of the present invention will be described in more detail with reference to FIG. 3. For convenience of description, reference numbers of the management apparatus 400 are referred to based on the downlink, and reference is made to the reception apparatus 100 using the reference numbers of the terminal apparatus 100.

The multi-network-based simultaneous transmission transmitter according to the preferred embodiment of the present invention, that is, the transmitter side 400, selects each partial data divided from the transmission target data for each network based on a preset data transmission rate of two or more networks. Transmission time associated with partial data selection unit 410 and transmission data related to the transmission order transmitted to two or more access networks and partial data having consecutive preceding transmission order information, for each partial data selected for each of the two or more access networks. An information insertion unit 420 for inserting interval information and a communication unit 430 for transmitting the selected partial data for each of the two or more connection networks through each connection network.

In addition, the multi-network-based simultaneous transmission transmission device, that is, the transmission side device 400 according to the preferred embodiment of the present invention may further include a control unit 440.

The partial data selector 410 selects the partial data divided from the transmission target data for each access network based on a preset data transmission rate (eg, 3G: WiFi = 2: 5) for each of the access networks.

That is, the partial data selection unit 410 divides the data into partial data when the transmission target data to be transmitted to the receiving apparatus 100 is received. At this time, the partial data selection unit 410 preferably combines / partitions the split sequence information into each piece of data so that the original piece of data can be restored by combining the pieces of divided data from the piece of data to be transferred.

In addition, the partial data selector 410 may include a data transmission rate for each access network (eg, 3G and WiFi), that is, a first transmission rate for transmitting data to the first network device 200 and the second network device 300. By checking the second transmission rate for data transmission, selecting the 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 the first of the remaining partial data The partial data to be transmitted to the network device 300 is selected.

The information insertion unit 420 transmits, to each partial data selected for each of the two or more access networks, transmission time interval information related to the transmission sequence information related to the transmission sequence transmitted to the two or more connection networks, and the partial data having consecutive preceding transmission sequence information. Insert

That is, the information insertion unit 420 may assign / insert transmission sequence information for the entire order of transmission without distinction of the network type to each partial data transmitted through the access network (for example, WiFi and 3G).

For example, as illustrated in FIG. 7, the information insertion unit 420 assigns / inserts transmission order information 1,2 to the first and second partial data transmitted to the first network, that is, the 3G network, and the second network, ie, the second network. Assign / insert transmission sequence information 3 to the third partial data transmitted to the WiFi network, and assign / insert transmission sequence information 4 to the fourth partial data transmitted to the 3G network, and send the fifth and sixth partial data to the WiFi network. The transmission order information 5, 6 can be assigned / inserted, and the transmission order information 7 can be assigned / inserted to the seventh partial data transmitted to the 3G network.

Then, the information insertion unit 420 inserts, in each piece of data, transmission time interval information related to the piece of data having the preceding transmission sequence information consecutive to the piece of data.

For example, as shown in Fig. 7, the information insertion unit 420 has no partial data having the preceding transmission sequence information subsequent to the partial data of the transmission sequence information 1, so that 0 ms and the partial data of the transmission sequence information 2 do not exist. 10 ms of transmission time interval information with the partial data having consecutive preceding transmission sequence information 1, and 10 ms of transmission time interval information with the partial data having continuous preceding transmission sequence information 2, transmission sequence information 3 The transmission time interval information can be inserted up to the partial data of the transmission sequence information 7 by inserting 10 ms of the transmission time interval information with the partial data having the preceding transmission sequence information 2 consecutive to the partial data of.

In this case, the multi-network-based simultaneous transmission transmitter 400 may maintain a constant transmission time interval (for example, 10 ms) between each partial data having continuous transmission sequence information, and may transmit each partial data accordingly. The transmission time interval information inserted into each piece of data in the information insertion unit 420 may be the same as the transmission time interval (eg, 10 ms) that is kept constant.

On the other hand, the information inserting unit 420 measures the transmission time interval associated with the partial data having successive preceding transmission sequence information each time the partial data is transmitted, and inserts it as the transmission time interval information. The transmission time interval information inserted in may be different.

Therefore, referring to FIG. 7, referring to the partial data of the transmission order information 1 to be transmitted through 3G as an example, information as the transmission order information according to the order transmitted from the management device 400 in the area ⓐ without distinguishing between 3G and WiFi networks. 1 may be included, and the area ⓑ may include information 0ms as transmission time interval information with the partial data having consecutive preceding transmission sequence information.

The communication unit 430 refers to a communication module for interworking with the first network device 200 using a 3G network and interworking with the second network device 300 using a WiFi network.

The communication unit 430 transmits the partial data selected for each of the two or more access networks, that is, the partial data including the partial data into which the transmission order information and the transmission time interval information are inserted as described above, through the corresponding access network.

That is, the communication unit 430 transmits a plurality of pieces of partial data selected in response to the 3G network to the first network device 200 located in the 3G network, and transmits a plurality of pieces of partial data selected in response to the WiFi network in the WiFi network. By transmitting to the second network device 300, the first network device 200 transmits the partial data to the receiving device 100, the second network device 300 transmits the partial data to the receiving device 100 Done.

The control unit 440, in the receiving device 100 that receives the partial data through two or more access networks, a pair of parts having consecutive transmission order information received through each of the different access networks of the two or more access networks. Obtaining network transmission delay values between the different access networks identified using at least one of a reception time interval and a transmission time interval related to data, and based on the obtained network transmission delay values between the different access networks, the data for each of the two or more networks. Change the transmission rate.

In more detail, the receiving apparatus 100 according to the embodiment of the present invention described with reference to FIG. 2 is a continuous transmission sequence received through each of different access networks (eg, 3G, WiFi) among two or more access networks. Identifying a pair of partial data having information, and using the at least one of the receiving time interval and the transmission time interval associated with the identified pair of partial data to determine the network transmission delay value between each different access network (e.g. 3G, WiFi) In addition, the average value of the network transmission delay value between each access network (eg, 3G, WiFi) based on each access network may be calculated.

Accordingly, the controller 440 may report and report the average value of the network transmission delay values calculated on the basis of each access network from the receiving apparatuses 100 and the waiting time variably set by the receiving apparatus 100.

Accordingly, the control unit 440 uses the average network transmission delay value between the access networks based on the access network criteria received and received from the receiving apparatus 100 to determine the data transmission rate for each network set in the partial data selection unit 410. You can change it.

As described above, according to the multi-network based simultaneous transmission receiving apparatus and the multi-network based simultaneous transmission transmitting apparatus according to the present invention, a simultaneous transmission service for transmitting / receiving partial data obtained by splitting data using a plurality of multiple networks is provided. In the providing environment, the receiving device checks the reception time interval and the transmission time interval from a pair of partial data having continuous transmission order information received through different access networks, and effectively uses the same to delay the transmission delay between each access network. By measuring, based on the measured transmission delay between each network, the receiving side can set the waiting time variably, minimizing unnecessary retransmission requests related to unreceived partial data, and optimizing the partial data transmission rate per network on the sending side. As a result, concurrent It has the effect of improving the transmission efficiency and quality of service.

Hereinafter, a multi-network based simultaneous transmission transmission method according to a preferred embodiment of the present invention will be described with reference to FIGS. 4 to 6. Here, for convenience of description, the components shown in FIGS. 1 to 3 will be described with reference to corresponding reference numerals.

First, an operation flow in a multi-network based simultaneous transmission service system according to a preferred embodiment of the present invention will be described with reference to FIG. 3.

The management apparatus 400 receives the transfer target data to be transferred from the external apparatus 500 to the terminal apparatus 100 and divides the transfer target data into partial data, Each piece of partial data is selected for each access network (S10).

At this time, it is preferable that the management apparatus 400 combines the partial data divided from the transmission target data and adds / inserts the division order information to each partial data so that the original transmission target data can be restored.

In addition, the management apparatus 400 assigns / inserts transmission order information for the entire order of transmission without distinction of the network type to each partial data transmitted through the access network (for example, WiFi and 3G), and continues the preceding step. The transmission time interval information associated with the partial data having the transmission order information is inserted (S20).

In addition, the management apparatus 400 transmits each partial data selected for each access network (eg, WiFi and 3G) through each access network (eg, WiFi and 3G), and thus, the first network apparatus 200 is a management apparatus. The partial data transmitted from the 400 is transmitted to the terminal device 100 (S30), and the second network device 300 transmits the partial data transmitted from the management device 400 to the terminal device 100 ( S35).

The terminal device 100 receives the partial data from the first network device 200 and the partial data from the second network device 300 through two or more access networks (eg, WiFi, 3G).

Accordingly, the terminal device 100 recognizes partial data having the same identification information (eg, virtual IP) indicating that the data is divided from one data based on identification information (eg, virtual IP) included in the received partial data. Then, these may be rearranged to the reception buffer based on the transmission order information included in the corresponding partial data (S40).

In this case, the terminal device 100 applies a preset waiting time to wait for a retransmission request related to unreceived partial data in response to each partial data received through two or more access networks (eg, 3G and WiFi). The redundant ack-based retransmission operation as described above will be performed.

The terminal device 100 confirms a pair of partial data having consecutive transmission order information received through each of the different access networks of two or more access networks (S50).

For example, the terminal device 100 may include a pair of pieces of serial data received through two or more access networks (eg, 3G and WiFi) having consecutive transmission order information received through different access networks. Check the partial data.

Referring to FIG. 7, the terminal device 100 may identify partial data of transmission order information 2 and 3 as a pair of partial data having consecutive transmission order information received through each of different access networks. The sub partial data of the transmission order information 3 and 4 can be confirmed, the partial data of the transmission order information 4 and 5 can be confirmed, and the partial data of the transmission order information 6 and 7 can be confirmed.

Thereafter, the terminal apparatus 100 includes at least one of a reception time interval and a transmission time interval associated with the pair of partial data identified, that is, the pair of partial data having consecutive transmission order information received through each of different access networks. Check the network transmission delay value between the different access network using (S60).

To describe in more detail with reference to the partial data of the transmission order information 2 and 3 confirmed, the terminal device 100, the reception time (eg, 07/00/00) when the partial data of the transmission order information 2 is received / 00 (h / m / s / ms)), based on the reception time (for example, 07/00/00/40 (h / m / s / ms)) when the partial data of the transmission order information 3 is received, The reception time interval associated with the partial data of the sequence information 2 and 3 can be checked.

At this time, preferably, the terminal device 100 first receives the second partial data having the transmission sequence information after the later received, among the partial data of the transmission sequence information 2 and 3, that is, the partial data reception time of the transmission sequence information 3. By subtracting the first partial data of the previous transmission sequence information, that is, the partial data reception time of the transmission sequence information 2, the reception time interval (for example, 40 ms) related to the partial data of the transmission sequence information 2 and 3 can be confirmed.

Then, the terminal device 100, from the second partial data having the later transmission order information of the partial data of the transmission order information 2 and 3, that is, the partial data of the transmission order information 3, the first part having continuous preceding transmission order information By checking the transmission time interval information related to the data, that is, the partial data of the transmission order information 2, the transmission time interval related to the partial data of the transmission order information 2 and 3 can be obtained. As described above with reference to FIG. 7, the terminal device 100 may acquire transmission time interval information (eg, 10 ms) included in the partial data of the transmission order information 3.

Accordingly, the terminal apparatus 100 includes a first transmission sequence information having at least one of a reception time interval (for example, 40 ms) and a transmission time interval (for example, 10 ms) associated with the partial data of the transmission sequence information 2 and 3. It is possible to calculate the network transmission delay value of the WiFi for which the second partial data having the transmission order information, that is, the partial data of the transmission order information 2, after the partial data of the transmission order information 2 has been received, that is, the partial data of the transmission order information 3 is received.

Accordingly, the terminal device 100 uses the network connection delay value calculated based on the partial data of the transmission order information 2 and 3 as described above, based on the 3G in which the partial data of the previous transmission order information 2 is received. 3G and WiFi) can be confirmed by the network transmission delay value.

In other words, with respect to the partial data of the transmission order information 2 and 3, the terminal apparatus 100 refers to the first partial data having the previous transmission order information received first, that is, the 3G on which the partial data of the transmission order information 2 is received. By using the reception time interval and the transmission time interval related to the partial data of the transmission sequence information 2 and 3, the network transmission delay value between the access networks (3G and WiFi) based on 3G can be calculated / confirmed according to Equation 1. have.

As described above, the terminal apparatus 100 refers to the first partial data having the previous transmission order information received, that is, the partial data of the transmission order information 3, with respect to the partial data of the transmission order information 3 and 4, based on the received WiFi. By using the reception time interval and the transmission time interval related to the partial data of the transmission sequence information 3 and 4, the network transmission delay value between the access networks (WiFi and 3G) based on WiFi can be calculated / confirmed according to Equation 2. have.

In addition, the terminal device 100, in connection with the partial data of the transmission order information 4 and 5, the same as the partial data of the transmission order information 2 and 3 described above, the access network (3G and WiFi) based on 3G according to Equation 1 Network transmission delay value), and the access network based on WiFi according to Equation 2 in the same manner as the partial data of the transmission sequence information 3 and 4 described above with respect to the partial data of the transmission sequence information 6 and 7. You can calculate / check the network transmission delay value between (WiFi and 3G).

As such, whenever the pair of partial data having the continuous transmission order information received through each of the different access networks is confirmed, the terminal apparatus 100 receives the first partial data having the previous transmission order information received first. The network transmission delay value between the access networks based on the access network will be calculated.

Accordingly, the terminal device 100, based on the network transmission delay value between the access network on the basis of the access network calculated as described above, the receiving buffer (storage unit (Fig. 2) 120) can be set variably (S70).

For example, the terminal device 100 may calculate an average value of network transmission delay values between access networks calculated on the basis of each access network as described above.

Accordingly, when the specific setting time elapses, the terminal device 100 waits for the reception buffer (storage unit 120 of FIG. 2) by using the largest average value among the average values of the network transmission delay values based on each access network. Can be set.

Accordingly, the terminal apparatus 100 may variably set the waiting time of the reception buffer (the storage unit 120 of FIG. 2), and then receive the partial data to be rearranged to the reception buffer (the storage unit 120 of FIG. 2). In this case, the redundant delay-based retransmission operation will be performed by applying a variable set latency.

Hereinafter, a multi-network based simultaneous transmission receiving method according to a preferred embodiment of the present invention, that is, an operation method of a receiving device will be described in detail with reference to FIG. 5.

In the multiple network-based simultaneous transmission and reception method of the present invention, the partial data divided from the transmission target data is received through two or more access networks (eg, 3G and WiFi) (S100).

Accordingly, the multi-network-based simultaneous transmission and reception method according to the present invention has the same identification information (eg, virtual IP) indicating that it is divided from one data based on identification information (eg, virtual IP) included in the received partial data. The partial data may be recognized and rearranged to the storage 120 based on the transmission order information included in the corresponding partial data (S110).

In this case, the multi-network-based simultaneous transmission and reception method according to the present invention may perform a redundant arc-based retransmission operation by applying a preset waiting time to wait for a retransmission request related to unreceived partial data, corresponding to each partial data that is rearranged and stored. will be.

In the multiple network-based simultaneous transmission and reception method of the present invention, a pair of partial data having consecutive transmission order information received through each of different access networks among two or more access networks is identified (S120).

That is, the multi-network based simultaneous transmission receiving method of the present invention has a continuous transmission order information received through each of the different access networks, each of the partial data received through two or more access networks (eg 3G, WiFi). Check a pair of partial data.

For example, referring to FIG. 7, the multi-network-based simultaneous transmission and reception method according to the present invention may be based on transmission sequence information corresponding to each partial data received through two or more access networks (eg, 3G and WiFi). As a result of reordering, as a pair of partial data having continuous transmission order information received through each of different access networks, the partial data of transmission order information 2 and 3 can be confirmed, The partial data can be confirmed, the partial data of the transmission order information 4 and 5 can be confirmed, and the partial data of the transmission order information 6 and 7 can be confirmed.

In the multi-network based simultaneous transmission and reception method of the present invention, a reception time interval and transmission time associated with a pair of identified partial data, that is, a pair of partial data having consecutive transmission sequence information received through each of different access networks, are provided. The network transmission delay value between the different access networks is checked using at least one of the intervals (S130).

In more detail, in the multiple network-based simultaneous transmission and reception method of the present invention, a pair of partial data, for example, partial data of transmission sequence information 2 and 3 is identified, and each of partial data of transmission sequence information 2 and 3 is received. Based on the reception time, a reception time interval associated with the partial data of the transmission order information 2 and 3 is obtained.

That is, in the multiple network-based simultaneous transmission and reception method of the present invention, a reception time (for example, 07/00/00/00 (h / m / s / ms)) at which partial data of transmission sequence information 2 is received and transmission sequence information Based on the reception time when the partial data of 3 is received (e.g., 07/00/00/40 (h / m / s / ms)), the reception time interval related to the partial data of the transmission order information 2 and 3 can be checked. have.

At this time, preferably, the multi-network-based simultaneous transmission and reception method of the present invention includes the second partial data of the transmission sequence information 2 and 3, that is, the second partial data having the transmission sequence information after being received later, that is, the partial data of the transmission sequence information 3. The reception time interval (e.g., 40 ms) associated with the partial data of the transmission sequence information 2 and 3 is subtracted by subtracting the reception time of the first partial data of the preceding transmission sequence information, that is, the partial data of the transmission sequence information 2, from the reception time. You can check it.

In the multi-network-based simultaneous transmission and reception method of the present invention, the previous transmission sequence immediately preceding or continuing from the second partial data having the later transmission sequence information, that is, the partial data of the transmission sequence information 3, among the partial data of the transmission sequence information 2 and 3 The transmission time interval information related to the first partial data having information, that is, the partial data of the transmission sequence information 2 is checked to obtain a transmission time interval related to the partial data of the transmission sequence information 2 and 3.

That is, according to the multiple network-based simultaneous transmission and reception method of the present invention, as shown in FIG. 7, the transmission time interval information (eg, 10 ms) included in the partial data of the transmission order information 3 may be obtained.

Accordingly, the multi-network-based simultaneous transmission and reception method according to the present invention uses the at least one of a reception time interval (for example, 40 ms) and a transmission time interval (for example, 10 ms) related to the partial data of the transmission order information 2 and 3, and thus the previous transmission. Calculate the network transmission delay value of WiFi in which the first partial data having the order information, that is, the partial data of the transmission order information 2 has been received, and the second partial data having the transmission order information, i.e., the partial data of the transmission order information 3 have been received. Can be.

Accordingly, in the multiple network-based simultaneous transmission and reception method of the present invention, the network transmission delay value calculated with respect to the partial data of the transmission order information 2 and 3 as described above is based on the 3G from which the partial data of the previous transmission order information 2 is received. It can be confirmed by the network transmission delay value between the access network (3G and WiFi).

As described above, according to the multiple network-based simultaneous transmission and reception method of the present invention, with respect to the partial data of the transmission order information 2 and 3, first partial data having the previous transmission order information received, that is, partial data of the transmission order information 2 is received. On the basis of the 3G, the network transmission delay between the access network (3G and WiFi) based on 3G according to Equation 1 above using the reception time interval and the transmission time interval related to the partial data of the transmission order information 2 and 3 The value can be calculated / verified.

As described above, according to the multiple network-based simultaneous transmission and reception method of the present invention, with respect to the partial data of the transmission order information 3 and 4, the first partial data having the previous transmission order information received first, that is, the partial data of the transmission order information 3 Based on the received WiFi, network transmission between the access networks (WiFi and 3G) based on WiFi according to Equation 2 above using the reception time interval and transmission time interval associated with the partial data of the transmission order information 3 and 4 The delay value can be calculated / verified.

In addition, in the multi-network-based simultaneous transmission and reception method of the present invention, in connection with the partial data of the transmission order information 4 and 5, the connection based on 3G according to Equation 1 is the same as the partial data of the transmission order information 2 and 3 described above. The network transmission delay value between the networks (3G and WiFi) can be calculated / confirmed, and with regard to the partial data of the transmission order information 6 and 7, the WiFi can be determined according to Equation 2 in the same manner as the partial data of the transmission order information 3 and 4 described above. The network transmission delay value between the access network (WiFi and 3G) as a reference can be calculated / verified.

As described above, the multi-network-based simultaneous transmission and reception method according to the present invention comprises a first method having previous transmission order information first received whenever a pair of partial data having consecutive transmission order information received through each of different access networks is identified. The network transmission delay value between the access networks based on the access network where the partial data is received will be calculated.

In the multiple network-based simultaneous transmission and reception method according to the present invention, the storage unit 120 applied to performing the above-described redundant arc-based retransmission operation based on the network transmission delay value between the access networks based on each access network standard calculated as described above. You can set the waiting time of the variable.

For example, in the multiple network-based simultaneous transmission and reception method of the present invention, as described above, an average value of network transmission delay values between access networks calculated based on each access network may be calculated (S140).

Accordingly, in the multiple network-based simultaneous transmission and reception method of the present invention, when a specific set time elapses, the standby time of the storage unit 120 is set using the largest average value of the average values of network transmission delay values based on each access network. It may be (S150).

Accordingly, the multi-network-based simultaneous transmission and reception method according to the present invention will perform a redundant arc-based retransmission operation in step S110 by applying a variable set waiting time to partial data received and rearranged and stored (S160). .

Furthermore, in the multiple network-based simultaneous transmission and reception method of the present invention, the average value of the network transmission delay values calculated on the basis of each access network and the variablely set waiting time may be reported to the transmission apparatus 400 (S170).

Hereinafter, a multi-network-based simultaneous transmission transmission method according to a preferred embodiment of the present invention, that is, an operation method of a transmitting device will be described in detail with reference to FIG. 6.

In the multiple network-based simultaneous transmission transmission method of the present invention, when receiving the transmission target data to be transmitted to the receiving apparatus 100 divides it into partial data (S200). In this case, in the multi-network-based simultaneous transmission and transmission method of the present invention, it is preferable to assign / insert division order information to each partial data so that the original transmission target data can be restored by combining the partial data divided from the transmission target data. Do.

In addition, the multi-network-based simultaneous transmission transmission method of the present invention, the data transmission rate for each access network (eg, 3G and WiFi), that is, the first transmission rate and the second network device for data transmission to the first network device 200 ( By checking the second transmission rate for data transmission to 300, selecting the 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 the remaining portion The partial data to be transmitted to the second network device 300 is selected from the data (S210).

The multi-network based simultaneous transmission transmission method of the present invention relates to partial data having transmission sequence information related to a transmission sequence transmitted to two or more connection networks and partial data having consecutive preceding transmission sequence information, for each partial data selected for each of two or more connection networks. Insert the transmission time interval information (S220).

That is, in the multiple network-based simultaneous transmission transmission method of the present invention, the transmission sequence information for the entire order of transmission without distinction of the network type is assigned / inserted to each partial data transmitted through the access network (for example, WiFi and 3G). Can be.

For example, in the multiple network-based simultaneous transmission transmission method of the present invention, as shown in FIG. 7, transmission order information 1,2 is assigned / inserted to the first and second partial data transmitted to the first network, that is, the 3G network. The fifth order of assigning / inserting transmission order information 3 to the third partial data transmitted to the second network, that is, the WiFi network, the fifth order of assigning / inserting transmission order information 4 to the fourth partial data transmitted to the 3G network, and transmitting to the WiFi network, Transmission order information 5, 6 can be assigned / inserted to the sixth partial data, and transmission order information 7 can be assigned / inserted to the seventh partial data transmitted to the 3G network.

The multi-network-based simultaneous transmission transmission method of the present invention inserts transmission time interval information associated with partial data having previous transmission sequence information consecutive with the corresponding partial data into each partial data.

For example, in the multiple network-based simultaneous transmission transmission method of the present invention, as shown in FIG. 7, since there is no partial data having preceding transmission sequence information consecutive to the partial data of the transmission sequence information 1, 0 ms, transmission sequence information 2 10 ms of transmission time interval information with the partial data having the preceding transmission sequence information 1 consecutive to the partial data of the data, and 10 ms of the transmission time interval with the partial data having the preceding transmission sequence information 2 consecutive The transmission time interval information can be inserted up to the partial data of the transmission sequence information 7 by inserting the transmission time interval information 10 ms with the partial data having the preceding transmission sequence information 2 consecutive to the partial data of the transmission sequence information 3.

Therefore, referring to FIG. 7, referring to the partial data of the transmission order information 1 to be transmitted through 3G as an example, information as the transmission order information according to the order transmitted from the management device 400 in the area ⓐ without distinguishing between 3G and WiFi networks. 1 may be included, and the area ⓑ may include information 0ms as transmission time interval information with the partial data having consecutive preceding transmission sequence information.

In the multi-network based simultaneous transmission transmission method of the present invention, each partial data selected for each of two or more access networks, that is, the partial network including the partial data including the transmission order information and the transmission time interval information as described above corresponding to the access network Transmit each through (S230).

In the multiple network-based simultaneous transmission transmission method of the present invention, the reception apparatus 100 that receives the partial data through two or more access networks, the continuous transmission order information received through each of the different access networks of the two or more access networks; Acquiring a network transmission delay value between the different access networks identified using at least one of a reception time interval and a transmission time interval associated with a pair of partial data having a; and based on the obtained network transmission delay value between the different access networks. The data transfer rate of each of the two or more networks is changed.

In more detail, the receiving apparatus 100 according to the embodiment of the present invention described with reference to FIG. 2 is a continuous transmission sequence received through each of different access networks (eg, 3G, WiFi) among two or more access networks. Identifying a pair of partial data having information, and using the at least one of the receiving time interval and the transmission time interval associated with the identified pair of partial data to determine the network transmission delay value between each different access network (e.g. 3G, WiFi) In addition, the average value of the network transmission delay value between each access network (eg, 3G, WiFi) based on each access network may be calculated.

Accordingly, in the multiple network-based simultaneous transmission transmission method of the present invention, the average value of the network transmission delay values calculated on the basis of each access network can be reported from the reception apparatus 100 and the standby time variably set by the reception apparatus 100. There is (S240).

Accordingly, in the multiple network-based simultaneous transmission transmission method of the present invention, the partial data selection unit 410 is configured by using the average network transmission delay value between the access networks based on each access network reference obtained from the receiving apparatus 100. The data transmission rate for each network can be changed (S250).

As described above, according to the multi-network based simultaneous transmission receiving method and the multi-network based simultaneous transmission transmission method according to the present invention, a simultaneous transmission service for transmitting / receiving partial data obtained by using a plurality of multiple networks In the providing environment, the receiving device checks the reception time interval and the transmission time interval from a pair of partial data having continuous transmission order information received through different access networks, and effectively uses the same to delay the transmission delay between each access network. By measuring, based on the measured transmission delay between each network, the receiving side can set the waiting time variably, minimizing unnecessary retransmission requests related to unreceived partial data, and optimizing the partial data transmission rate per network on the sending side. As a result, concurrent It has the effect of improving the transmission efficiency and quality of service.

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

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

According to the multiple network-based simultaneous transmission receiving apparatus and reception method, the multiple network-based simultaneous transmission transmission apparatus and transmission method according to the present invention, in an environment for providing a simultaneous transmission service, the receiving device is a continuous reception that is received through a different access network By checking the reception time interval and transmission time interval from a pair of partial data having transmission sequence information and effectively measuring the transmission delay between each access network, the receiving side waits time based on the measured transmission delay between each network. It is possible to minimize the unnecessary retransmission requests related to unreceived partial data and to optimize the transmission rate of partial data for each network on the sender side, thereby improving transmission performance and quality of simultaneous transmission service. Over the limit of According to the present invention, there is not only the use of the related technology but also the possibility of marketing or sales of the applied device as well as the degree to which it can be clearly realized in reality.

100: terminal device
110: communication unit 120: storage unit
130: information confirmation unit 140: control unit

Claims (10)

A communication unit which receives the partial data divided from the transmission target data through two or more access networks;
An information checking unit for identifying a pair of partial data having consecutive transmission order information received through different access networks of the two or more access networks; And
And a control unit which checks a network transmission delay value between the different access networks by using at least one of a reception time interval and a transmission time interval associated with the pair of partial data. The method of claim 1,
The control unit,
And a reception time interval associated with the pair of partial data based on a reception time of each of the pair of partial data. The method of claim 1,
The partial data is,
Includes transmission time interval information with the partial data having the previous transmission order information,
The control unit,
And transmitting the transmission time interval based on the transmission time interval information of the partial data having the later transmission order information of the pair of partial data. The method of claim 1,
The network transmission delay value is,
And the network transmission delay value based on the access network in which the partial data having the preceding transmission order information among the pair of partial data is received. The method of claim 1,
The control unit,
And variably setting a waiting time set to wait for a retransmission request of unreceived partial data based on the network transmission delay value. The method of claim 5, wherein
The control unit,
And determining an average value of network transmission delay values based on each of the two or more access networks, and setting a maximum value of the average values determined for each of the two or more access networks as the waiting time. . A partial data selecting unit selecting each partial data divided from the transmission target data for each network based on two or more preset data transmission rates for each network;
An information insertion unit for inserting, in each partial data selected for each of the two or more access networks, transmission sequence information related to the transmission order transmitted to the two or more access networks and transmission time interval information related to the partial data having immediately previous transmission order information; And
And a communication unit which transmits the selected partial data for each of the two or more access networks through each access network. The method of claim 7, wherein
Network transmission delay between the different access networks identified using at least one of a reception time interval and a transmission time interval associated with a pair of partial data having consecutive transmission sequence information received through each of the different access networks of the two or more access networks. And a controller for acquiring a value and changing a data transmission rate for each of the two or more networks based on the obtained network transmission delay value. A partial data receiving step of receiving the partial data divided from the transmission target data through two or more access networks;
A partial data checking step of identifying a pair of partial data having consecutive transmission order information received through each of different access networks of the two or more access networks;
And a network transmission delay value checking step of confirming a network transmission delay value between the different access networks by using at least one of a reception time interval and a transmission time interval associated with the pair of partial data. Transmission Receive Method. A partial data selection step of selecting the partial data divided from the transmission target data for each of two or more access networks;
An information insertion step of inserting, in each partial data selected for each of the at least two access networks, transmission sequence information related to a transmission sequence transmitted to at least two access networks and transmission time interval information related to partial data having immediately preceding transmission sequence information; And
And transmitting the partial data selected for each of the two or more access networks through each access network.

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