KR101307827B1 - Apparatus for simultaneously transmitting data in heterogeneous network - Google Patents

Abstract

The present invention discloses a heterogeneous network-based simultaneous data transmission / reception apparatus and a transmission / reception method. That is, the heterogeneous network-based data simultaneous transmission / reception apparatus of the present invention receives partial data divided from specific transmission target data through two or more access networks, and stores each partial data received through the two or more access networks in order information. Reorder based on the result, and wait for delivery of the partial data having the order information after the non-received specific order information according to the rearranged result, and transfer the preset waiting time corresponding to the partial data waiting for delivery. And providing a receiving acknowledgment corresponding to the transmitted partial data to the transmitting apparatus which transmits the partial data, wherein the specific retransmission timeout time elapses with the transmitting apparatus not receiving a reply acknowledgment corresponding to the partial data. Retransmission based on the retransmission timeout time. May be limited, including the configuration, prevent unnecessary data retransmission part beforehand, and consequently improve the transmission performance of the broadcast service.

Description

[0001] APPARATUS FOR SIMULTANEOUSLY TRANSMITTING DATA IN HETEROGENEOUS NETWORK [0002]

The present invention relates to a data simultaneous transmission method, and more particularly, in the environment of providing a simultaneous transmission service for transmitting / receiving partial data obtained by dividing data using a plurality of heterogeneous networks, the transmission delay between networks is different. According to the sequence of the received partial data in order to dynamically set the waiting time in the receiving buffer to wait for the partial data after the unreceived partial data, the unnecessary retransmission time-out time-based partial data generated in the sending device The present invention relates to a heterogeneous network-based simultaneous data transmission / reception apparatus and a transmission / reception method capable of preventing retransmission and consequently improving transmission performance of a simultaneous transmission service.

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

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

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

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

The present invention was created in view of the above circumstances, and an object of the present invention is to receive partial data divided from specific transmission target data through two or more access networks, and receive each of the two or more access networks. Reorder the partial data based on the order information, and wait for the partial data having the order information after the unreceived specific order information according to the rearranged result, and set a preset wait corresponding to the partial data waiting for delivery. It transmits when time passes, and provides a receiving arc corresponding to the transmitted partial data to the transmitting apparatus which transmits the partial data, so that the transmitting apparatus specifies that the receiving acknowledgment is not returned in response to the partial data. Resend timeout time to resend as the resend timeout time elapses To provide a heterogeneous network based on the data broadcast receiving apparatus and a method for limiting the half retransmission operation, sikineunde prevent unnecessary data retransmission part beforehand, and consequently improve the transmission performance of the broadcast service.

The heterogeneous network-based data transmission and reception apparatus according to the first aspect of the present invention for achieving the above object comprises: a communication unit for receiving partial data divided from specific transmission target data through two or more access networks; According to a result of rearranging the partial data received through the two or more access networks based on the order information, the partial data having the order information after the unreceived specific order information is waited for delivery, and the partial data waiting to be delivered. Receiving buffer for transmitting when the preset waiting time corresponding to; And providing a reception acknowledgment corresponding to the partial data transmitted from the reception buffer unit to the transmitting apparatus for transmitting the partial data, wherein the transmitting apparatus transmits a specific retransmission timeout in a state that the receiving acknowledgment is not returned in response to the partial data. And a control unit for limiting a retransmission operation based on a retransmission timeout time for retransmission as time passes.

Preferably, the waiting time may be set based on at least one of the network information used when the retransmission timeout time is predicted and the retransmission timeout.

Preferably, the waiting time may be set based on the maximum packet reciprocating time of the packet reciprocating time for each of the two or more access networks.

Preferably, the control unit, if the partial data transmitted from the receiving buffer unit is the partial data having the order information after the unreceived specific order information, induces retransmission of the partial data of the unreceived specific order information. The reception acknowledgment including a retransmission guide message may be provided to the transmitter.

The heterogeneous network-based data transmission and reception method according to the second aspect of the present invention for achieving the above object comprises: partial data receiving step of receiving partial data divided from specific transmission target data through two or more access networks; An order rearranging step of rearranging the partial data received through the two or more access networks based on the order information; A delivery waiting step of waiting for a partial data having order information after the unreceived specific order information according to the rearranged result, and transmitting a preset waiting time corresponding to the partial data waiting to be delivered; And providing a receiving acknowledgment corresponding to the transmitted partial data to the transmitting apparatus which transmits the partial data, so that the specific retransmission timeout time elapses with the transmitting apparatus not receiving a reply acknowledgment corresponding to the partial data. And a receiving arc providing step of limiting the retransmission time-based retransmission operation according to the retransmission.

Preferably, the waiting time may be set based on at least one of the network information used when the retransmission timeout time is predicted and the retransmission timeout.

Preferably, the waiting time may be set based on the maximum packet reciprocating time of the packet reciprocating time for each of the two or more access networks.

Preferably, the receiving acknowledgment step, if the transmitted partial data is the partial data having the order information after the unreceived specific order information, induces retransmission of the partial data of the unreceived specific order information. The reception acknowledgment including a retransmission guide message may be provided to the transmitter.

Accordingly, according to the heterogeneous network-based simultaneous data transmission / reception apparatus and transmission / reception method of the present invention, in an environment in which a simultaneous transmission service is provided, a retransmission timeout time of a transmitting device based on a different transmission delay for each access network is provided. Alternatively, the dynamic / adaptive waiting time (T_th) based on the packet reciprocating time for each access network is set in the receiving buffer of the receiving device, and the received partial data is rearranged according to the order information. Thereafter, even if the partial data having a sequence is provided, the receiving arc is provided to the transmitting device when the waiting time T_th elapses, so that only the partial data that is not actually received by the receiving device is duplicated based on the retransmission operation or the retransmission timeout time based retransmission operation. Is performed on the partial data of the sequence after the unreceived partial data. Documentation can be prevented from being unnecessary retransmissions performed particularly retransmission timeout-based retransmission operation.

In addition, according to the heterogeneous network-based simultaneous data transmission / reception apparatus and transmission / reception method of the present invention, a retransmission timeout time of a transmitting device based on a different transmission delay for each access network or a packet reciprocating time for each access network may be determined. Since the latency T_th is dynamically and adaptively set, the retransmission based on the retransmission timeout time according to the TCP retransmission rule can be minimized, thereby effectively preventing the TCP transmission performance.

1 is a block diagram illustrating a heterogeneous network-based data concurrent transmission system according to a preferred embodiment of the present invention.
2 is a block diagram illustrating a configuration of a heterogeneous network-based data concurrent transmission / reception apparatus according to a preferred embodiment of the present invention.
3 is a flowchart illustrating a flow of a heterogeneous network-based data transmission method according to a preferred embodiment of the present invention.
FIG. 4 is a flowchart illustrating a method of transmitting and receiving a heterogeneous network-based data concurrently according to a preferred embodiment of the present invention.

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

FIG. 1 illustrates a heterogeneous network-based data concurrent transmission system according to a preferred embodiment of the present invention.

As shown in FIG. 1, the heterogeneous network-based data concurrent transmission system according to the present invention includes a management apparatus 400 for supporting a simultaneous transmission service for dividing data to be transmitted into two or more partial data and transmitting the data over two or more networks, And at least one terminal apparatus 100 connected to the management apparatus 400 and using the simultaneous transmission service.

Here, two or more networks, that is, heterogeneous networks, may include WCDMA, CDMA, WiBro, WLAN (WiFi), Long Term Evolution (LTE), and the like.

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

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

The external device 500 refers to a server device that transmits and receives data to and from the terminal device 100 through the management device 400. The external device 500 is connected to the terminal device 100 through data transmission / For example, various services such as a portal service and a content providing service can be provided.

Accordingly, the heterogeneous network-based data concurrent transfer service according to the present invention divides one piece of data between the terminal device 100 and the management device 400 for data transmission / reception between the terminal device 100 and the external device 500 And implements a simultaneous transmission service in which divided partial data is transmitted using a plurality of heterogeneous networks (e.g., 3G and WiFi), and the received partial data is combined 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 device 400 as a transmission device for providing data simultaneous transmission service to a terminal device 100 located in a heterogeneous network environment is assumed and described, and the management device 400 and data are described. A description will be given assuming a terminal device 100 as a receiving device that performs transmission and reception.

Accordingly, since the simultaneous transmission service provided by the present invention simultaneously transmits partial data divided from one data using a plurality of heterogeneous networks (for example, 3G and WiFi), a plurality of heterogeneous types may be provided on the terminal device 100 side. It is very important to restore all the partial data received through the network (eg 3G and WiFi) without loss / loss and rearrange them in the order of division to restore the data to be transmitted.

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 heterogeneous 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. Since there is a difference in the reception time of the partial data received through the packet, even if the reception is delayed due to transmission delay without being lost, the partial TCP data packet is unnecessarily retransmitted according to the TCP retransmission rule, thereby reducing the overall TCP performance. .

That is, according to the TCP retransmission rule, the duplication of retransmitting the corresponding data (partial data packet) when a duplicate Ack is received from the receiving device receiving the data (partial data packet) a specific number of times (for example, three times). Ack-based retransmission operation and retransmission of the corresponding data (partial data packet) as a specific retransmission time-out (RTO) time elapses with the reception acknowledgment corresponding to the data (partial data packet). Retransmission Timeout A retransmission operation based on timeout is common.

Particularly, if unnecessary retransmission occurs due to redundant arc-based retransmission operation and / or retransmission timeout time-based retransmission operation, TCP determines that the network is in a bad state and artificially lowers the transmission speed to avoid TCP transmission performance degradation. In particular, when unnecessary retransmission occurs due to the retransmission timeout time-based retransmission operation, the transmission speed is largely lowered, and thus, the TCP transmission performance is deteriorated.

Accordingly, in the present invention, as the transmission delay between networks is different in an environment for providing simultaneous transmission service, the received partial data is rearranged in order to reduce the waiting time in the receiving buffer waiting for the partial data after the unreceived partial data. By dynamically setting and operating, it is proposed a configuration that prevents unnecessary retransmission of partial data packets according to the TCP retransmission rule.

For convenience of explanation, the downlink is described with reference to the description, and the management apparatus 400 as the transmitting side apparatus measures the packet round trip time (RTT) for each access network.

That is, since the transmission latency is different for each access network, the packet reciprocal time (RTT) will also be different for each access network. The packet reciprocal time (RTT) means the time taken by the transmitting end (management apparatus) to send a packet (partial data) and return to the transmitting end-receiving end-transmitting end.A shorter RTT results in a shorter retransmission timeout and a longer RTT. Ground retransmission timeout is also lengthened. In this case, short RTT means that the packet transmission speed is high, which means that the network quality is good.

In this case, the management apparatus 400 may measure various packet reciprocating time (RTT) for each access network.

For example, the management apparatus 400 may measure the packet reciprocating time (RTT) for each access network by transmitting and receiving a separate packet for the packet reciprocating time (RTT) with the terminal apparatus 100 through each access network. Alternatively, the packet reciprocal time (RTT) for each access network may be determined using the packet arrival time and the packet arrival time based on the packets transmitted and received with the terminal device 100 to measure the delay time between packets through the access networks. It can be measured. Here, the delay time value means a difference in arrival time between packets on the receiving side with respect to packets transmitted for each access network.

Accordingly, the management device 400 measures the packet reciprocating time (RTT) for each access network through various packet reciprocating time (RTT) measuring methods as described above at every periodic or random time or when a specific event occurs, and for each access network. The packet reciprocating time (RTT) information may be provided to the terminal device 100, and more preferably, the maximum packet reciprocating time (RTT) information of the packet reciprocating time (RTT) of each access network is provided to the terminal device 100. can do.

On the other hand, the management apparatus 400 measures the packet reciprocating time (RTT) for each access network through various packet reciprocating time (RTT) measuring methods as described above at every periodic or random time or when a specific event occurs, and based on this, each connection The average packet return time (RTT) of the network can be calculated.

The management apparatus 400 can provide the terminal apparatus 100 with the calculated average packet reciprocal time (RTT) information of each access network, preferably in the average packet reciprocation time (RTT) of each access network. Average packet return time (RTT) information having a maximum value may be provided to the terminal device 100.

In this case, the management device 400 periodically provides the terminal device 100 with the maximum packet return time (RTT) information or the average packet return time (RTT) information having the maximum value, or the maximum packet return time (RTT). The information may be provided to the terminal device 100 when the average packet return time (RTT) information having the maximum value is changed by more than a certain ratio (β) compared to the previous information.

In addition, when the management apparatus 400 measures the packet reciprocating time (RTT) for each access network through various packet reciprocating time (RTT) measuring methods as described above at every periodic or random time or when a specific event occurs, such a connection network A retransmission time-out (RTO) time based on a TCP retransmission rule may be set using the packet repetition time (RTT) per packet or the average packet repetition time (RTT) for each access network described above.

The management device 400 operates as a transmission side device, and selects, for each access network, partial data divided from data to be transmitted based on a preset data transmission rate for each access network.

In other words, 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 a data transmission rate for each network (eg, 3G and WiFi). 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 first partial data to be transmitted to the first network apparatus 200 is selected among the partial data, and the second partial data to be transmitted to the second network apparatus 300 is selected from the remaining partial data.

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

Accordingly, the terminal apparatus 100 as a receiving side apparatus of the present invention receives the partial data through two or more access networks, rearranges them according to the division order based on the received order information of the partial data, and normally rearranges the partial data. By combining, the data to be transmitted can be restored.

That is, the terminal device 100 rearranges the partial data received through the two or more access networks to the reception buffer (the reception buffer unit 120 of FIG. 2) based on the order information.

At this time, the terminal device 100, according to the result of rearranging each piece of data based on the order information, for the partial data normally rearranged without the part data of the unreceived previous order information, the reception layer according to the higher layer, that is, TCP. Transfer to a function unit (controller 130 of FIG. 2) to perform the transmission and partial data combination.

In this case, the terminal device 100 will provide the management device 400 with an Ack indicating that the reception acknowledgment is normally received in a normal order corresponding to each piece of partial data delivered to the upper layer.

On the other hand, the terminal device 100 waits for the partial data having the order information after the non-received specific order information according to the result of rearranging the pieces of the partial data based on the order information, and delivers them to a higher layer. When the preset waiting time (T_th) has elapsed corresponding to the waiting partial data, it is transmitted.

Accordingly, the terminal device 100 provides the reception device corresponding to each piece of the partial data transferred to the upper layer to the management device 400 so that the management device 400 has subsequent order information of the unreceived partial data but is waiting. A retransmission timeout time based retransmission operation may be limited as a specific retransmission timeout time elapses while a reception acknowledgment is not returned in response to partial data waited in the reception buffer for a time T_th.

That is, when the reception buffer waits for the waiting time T_th even for the partial data received by the terminal device 100 but the partial data of the previous order is not transmitted to the management device 400 because the partial data of the previous order is not received. By transmitting to a higher layer, the reception acknowledgment can be transmitted to the management device (400).

Here, the waiting time T_th is at least one of network information and the retransmission timeout (RTO) time used when the management apparatus 400 estimates the retransmission timeout (RTO) time used in the retransmission time-based retransmission operation. It is possible to set on the basis of one.

For example, the management device 400 calculates a retransmission timeout (RTO) time using network information including network characteristic information of each of two or more access networks, transmission latency values of two or more access networks, and the like. Can predict. In other words, the network information used for the RTO time prediction includes network characteristic information of each of two or more access networks, a transmission latency value of each of the two or more access networks, and the like.

Accordingly, the terminal device 100 obtains at least one of the above-described network information and retransmission timeout (RTO) time information from the management device 400, and obtains at least one of the network information and the retransmission timeout (RTO) time. On the basis, the waiting time T_th can be set dynamically.

On the other hand, the waiting time (T_th) is preferably set based on the maximum packet reciprocating time of the packet reciprocating time for each of two or more access networks.

For example, the terminal device 100 may obtain the maximum packet return time (RTT) information or the average packet return time (RTT) information having the maximum value provided from the management device 400 as described above. Accordingly, the terminal device 100 may dynamically set the waiting time T_th based on the maximum packet return time RTT or the average packet return time RTT having the maximum value.

Of course, the terminal device 100, as described above, the management device 400 performs a variety of methods for measuring the packet reciprocating time (RTT) for each access network by itself to obtain the maximum packet without obtaining from the management device 400 Round trip time (RTT) information or average packet return time (RTT) information having a maximum value may be obtained by itself.

On the other hand, the terminal device 100, in setting the waiting time (T_th) of the type of the terminal device 100 itself (for example, terminal performance, terminal CPU available capacity, memory available capacity, etc.), the current terminal device 100 The wait time T_th may be dynamically set based on the number of connection sessions.

For example, the management apparatus 400 transmits the partial data packets 1 and 2 having the order information 1 and 2 through the second network (eg, WiFi), and the order information through the first network (eg, 3G). The partial data packet 3 having 3 is transmitted, and the partial data packet 4,5 having sequence information 4, 5 is transmitted through the second network (for example, WiFi). Thus, the partial data packet 1, Assume that 2, 4, 5 are received and partial data packet 3 has not been received.

In this case, as a result of the rearrangement in the reception buffer, the terminal device 100 will deliver the partially rearranged partial data, that is, the partial data packets 1 and 2 to the upper layer without the partial data of the unreceived previous sequence information.

Accordingly, the terminal device 100 will provide the management device 400 with an Ack indicating that reception packets corresponding to each of the partial data packets 1 and 2 transmitted to the upper layer, that is, are normally received in a normal order.

Meanwhile, as a result of the rearrangement in the reception buffer, the terminal device 100 waits for transmission of the partial data having the sequence information after the unreceived specific sequence information 3, that is, the partial data packets 4 and 5 to the upper layer. The terminal apparatus 100 determines whether the preset waiting time T_th has elapsed corresponding to each of the partial data packets 4 and 5, and transmits the partial data packet having the elapsed waiting time T_th to the upper layer.

Accordingly, the terminal device 100 provides a reception arc corresponding to each of the partial data packets 4 and 5 transmitted to the upper layer to the management device 400, so that the management device 400 receives the reception ack in response to the partial data. As a specific retransmission timeout time elapses with no reply, the retransmission operation based on the retransmission timeout time may be limited.

More specifically, when the partial data transmitted to the upper layer is partial data having sequence information after the unreceived specific sequence information, the terminal device 100 induces retransmission of the partial data of the unreceived specific sequence information. The reception acknowledgment message including the retransmission guide message may be provided to the management apparatus 400.

That is, referring to the above-described example, the terminal apparatus 100, if the partial data packet delivered to the upper layer is the partial data having the sequence information 4, 5 after the non-received specific sequence information 3, not received The reception acknowledgment message including a retransmission guide message for inducing retransmission of the partial data of the specific sequence information 3 will be provided to the management apparatus 400. Here, the retransmission guide message may include a duplicate ACK generated corresponding to the unreceived partial data according to the TCP retransmission rule.

Meanwhile, the management apparatus 400 may transmit partial data packets 1, 2, 3, 4, and 5 through two or more access networks and start counting retransmission timeout time corresponding to each partial data packet.

At this time, as described above, when receiving the reception acknowledgment including the Ack indicating that the terminal device 100 is normally received in the normal order corresponding to each of the partial data packets 1,2, the management device 400, partial data packet 1, End counting for retransmission timeout for 2.

As described above, when the reception apparatus includes a reception acknowledgment corresponding to each of the partial data packets 4 and 5, that is, a reception acknowledgment including a duplicate acknowledgment that induces retransmission of the partial data of the sequence information 3, the terminal apparatus 100 receives a reply. In addition, the management device 400 terminates the retransmission timeout time counting for the partial data packets 4 and 5 to maintain the retransmission timeout time counting for the partial data of the sequence information 3 and duplicates the partial data of the sequence information 3. Remember the number of arcs (e.g. 2 times).

Accordingly, the management apparatus 400 according to the TCP retransmission rule, when the number of duplicated arcs for the partial data of the sequence information 3 reaches a specific number (eg, three times), the redundant acknowledgment-based retransmission operation of retransmitting the corresponding partial data packet 3 In addition, if the retransmission timeout time being counted for the partial data of the sequence information 3 elapses, a retransmission time-based retransmission operation for retransmitting the corresponding partial data packet 3 may be performed.

As a result, according to the present invention, the redundant arc-based retransmission operation or the retransmission timeout time-based retransmission operation is performed only on the partial data (for example, the partial data packet 3) that is not actually received by the terminal apparatus 100. It is possible to prevent the retransmission operation based on the retransmission timeout time on partial data (eg, partial data packets 4 and 5) in the sequence after the data.

In addition, according to the present invention, the waiting time T_th set in the reception buffer of the terminal apparatus 100 may be stored in network information including different transmission delay, network characteristics, etc. for each access network, or such network information. Based on the retransmission timeout time or the packet reciprocation time of the management device 400 calculated based on the dynamic / adaptive setting, the TCP transmission performance by minimizing the retransmission occurrence based on the retransmission timeout time according to the TCP retransmission rule The fall can be prevented efficiently.

Meanwhile, in the above description, a case in which the terminal device 100 receives the partial data obtained by dividing the transmission target data by the management device 400 based on the downlink will be described.

On the contrary, if the management apparatus 400 receives the partial data obtained by dividing the transmission target data by the terminal apparatus 100 based on the uplink, the management apparatus 400 operating as the receiving side apparatus may be used. When the waiting time for the partial data rearrangement performed by the terminal apparatus 100 and the partial data having the sequence information after the unreceived specific sequence information and the preset waiting time corresponding to the partial data waiting for delivery have passed. Carry out operations such as forwarding and reception of a reception acknowledgment (including a retransmission guide message that induces retransmission of partial data of unreceived specific sequence information) corresponding to partial data having sequence information after unreceived specific sequence information. No wonder you can.

Hereinafter, a heterogeneous network-based simultaneous data transmission / reception apparatus, that is, a receiver side apparatus, according to the present invention will be described with reference to FIG. 2. The reference number of the terminal apparatus 100 is referred to on the basis of the downlink for the convenience of description and the reference number of the management apparatus 400 is used to refer to the transmission apparatus 400. [

The heterogeneous network-based simultaneous data transmission / reception apparatus according to the preferred embodiment of the present invention, that is, the apparatus 100 on the receiving side, includes a communication unit 110 for receiving partial data divided from specific transmission target data through two or more access networks, According to a result of rearranging the partial data received through the two or more access networks based on the order information, the partial data having the order information after the unreceived specific order information is waited for delivery, and the partial data waiting to be delivered. In response to the predetermined waiting time elapses, the receiving buffer unit 120 and the receiving buffer corresponding to the partial data transmitted from the receiving buffer unit 120 to the transmitting device 400 for transmitting the partial data Providing a specific retransmission timeout in a state in which the transmitting apparatus 400 does not return a reception acknowledgment corresponding to the partial data. And a controller (130) for limiting the re-transmission time-out time based on the retransmission operation for the retransmission, as time has elapsed.

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.

Accordingly, the communication unit 110 receives the partial data divided from the data to be transmitted based on a preset data transmission rate for each access network through two or more access networks (eg, 3G and WiFi).

That is, the communication unit 110 receives the first partial data transmitted from the transmitting apparatus 400 through the first network apparatus 200 located in the 3G network and transmits the second partial data transmitted from the transmitting apparatus 400. To receive through the second network device 300 located in the WiFi network.

The receiving buffer unit 120 rearranges each piece of data received through two or more access networks (eg, 3G and WiFi) based on the order information, and the order information after the unreceived specific order information according to the rearranged result. Delivery is waited for the partial data having a transmission, and when a predetermined waiting time has elapsed corresponding to the partial data waiting to be delivered.

In more detail, the reception buffer unit 120 rearranges the partial data received through two or more access networks (eg, 3G and WiFi) based on the order information.

At this time, the reception buffer unit 120 receives the received data according to the higher layer, that is, TCP, for the partial data normally rearranged without the partial data of the unreceived previous sequence information according to the result of rearranging the partial data based on the order information. The controller 130 transmits the acknowledgment and the partial data combination.

On the other hand, the reception buffer unit 120 waits for transmission to the control unit 130 for the partial data having the order information after the unreceived specific order information according to the result of rearranging the partial data based on the order information. When the preset waiting time T_th elapses corresponding to the partial data waiting to be delivered, the controller 130 transmits the data to the controller 130.

Here, the waiting time T_th is at least one of network information and the retransmission timeout (RTO) time used when the transmitter 400 estimates the retransmission timeout (RTO) time used in the retransmission time-based retransmission operation. It is possible to set on the basis of one.

For example, the transmitter 400 calculates a retransmission timeout (RTO) time using network information including network characteristic information of each of two or more access networks, transmission latency values of two or more access networks, and the like. Can predict. In other words, the network information used for the RTO time prediction includes network characteristic information of each of two or more access networks, a transmission latency value of each of the two or more access networks, and the like.

Accordingly, the reception buffer unit 120 obtains at least one of the above-described network information and retransmission timeout (RTO) time information from the transmitting apparatus 400, and at least one of the network information and the retransmission timeout (RTO) time. Based on the wait time (T_th) can be set dynamically.

On the other hand, the waiting time (T_th) is preferably set based on the maximum packet reciprocating time of the packet reciprocating time for each of two or more access networks.

For example, the reception buffer unit 120 may obtain the maximum packet return time (RTT) information or the average packet return time (RTT) information having the maximum value provided from the transmitter 400 as described above. Accordingly, the reception buffer unit 120 may dynamically set the waiting time T_th based on the maximum packet return time RTT or the average packet return time RTT having the maximum value.

Of course, as described above, the terminal apparatus 100 performs various methods of measuring the packet reciprocating time (RTT) for each access network by itself, so that the terminal apparatus 100 can obtain the maximum value without obtaining from the transmitter 400. Packet reciprocating time (RTT) information or average packet reciprocating time (RTT) information having a maximum value may be obtained by itself and used to set the waiting time T_th of the reception buffer unit 120.

On the other hand, the reception buffer unit 120, in setting the waiting time (T_th) of the type of the terminal device 100 (for example, terminal performance, terminal CPU available capacity, memory available capacity, etc.), of the current terminal device 100 The wait time T_th may be dynamically set based on the number of connection sessions.

For example, the transmitter 400 transmits the partial data packets 1 and 2 having the order information 1 and 2 through the second network (eg, WiFi), and the order information through the first network (eg, 3G). The partial data packet 3 having 3 is transmitted, and the partial data packet 4,5 having sequence information 4, 5 is transmitted through the second network (for example, WiFi), and thus the partial data packet 1 is transmitted to the receiving device 100. Assume that 2, 4 and 5 are received and that the partial data packet 3 has not been received.

In this case, the reception buffer unit 120, as a result of the rearrangement, will transfer the partially rearranged partial data, that is, the partial data packets 1,2 to the controller 130 without the partial data of the unreceived previous sequence information.

On the other hand, the reception buffer unit 120, as a result of the rearrangement, waits for the transmission of the partial data having the sequence information after the unreceived specific sequence information 3, that is, the partial data packets 4 and 5 to the upper layer. In addition, the reception buffer unit 120 determines whether the preset waiting time T_th has elapsed corresponding to each of the partial data packets 4 and 5, and controls the partial data packet after the waiting time T_th has elapsed. Will pass by.

The control unit 130 provides a reception arc corresponding to the partial data transmitted from the reception buffer unit 120 to the transmitting device 400 for transmitting the partial data, so that the transmitting device 400 corresponds to the partial data. Retransmission timeout based on the specific retransmission timeout time with the received acknowledgment is not limited.

In more detail, the control unit 130 is a function unit for restoring the transmission target data by combining the partial data normally rearranged by the reception acknowledgment transmission and reception buffer unit 120 according to TCP.

That is, the controller 130 provides the reception device corresponding to the partial data transmitted from the reception buffer unit 120 to the transmitter 400.

In other words, if the partial data transmitted from the reception buffer unit 120 is the partial data normally rearranged without the partial data of the unreceived previous order information (for example, the partial data packets 1 and 2 described above). In response to each of the partial data transferred from the reception buffer unit 120, an Ack indicating that the reception is normally received in the normal order will be provided to the transmitting device 400.

On the other hand, when the partial data transmitted from the reception buffer unit 120 is partial data having order information after the non-received specific sequence information (eg, the partial data packets 4 and 5 described above), A reception acknowledgment including a retransmission induction message for inducing retransmission of partial data of the unreceived specific sequence information (eg, the partial data packet 3 described above) will be provided to the transmitter 400.

Here, the retransmission guide message may include a duplicate ACK generated corresponding to the unreceived partial data according to the TCP retransmission rule.

Accordingly, the control unit 130 provides the reception device corresponding to each of the partial data packets 4 and 5 transmitted to the transmission device 400 so that the reception device does not return the reception acknowledgment corresponding to the partial data. As a specific retransmission timeout period elapses, a retransmission operation based on a retransmission timeout time may be limited.

As described above, according to the heterogeneous network-based simultaneous data transmission / reception apparatus and a system including the same according to the present invention, in an environment for providing a simultaneous transmission service, different transmission delays and network characteristics for each access network may be determined. Receiving device receives dynamic / adaptive waiting time (T_th) based on retransmission timeout time of the sending device, or packet reciprocating time for each access network calculated on the basis of the network information including the network information. By setting the buffer and reordering the received partial data according to the order information, if the waiting time T_th elapses even for partial data having a completion order of unreceived partial data, a receiving acknowledgment is provided to the transmitting side apparatus. Duplicate Ack-based retransmission only for partial data not actually received by the device Or a re-transmission time-out time based, and ensure that a re-transmission operation can be prevented from being non-received portion of the data sequence after the unnecessary retransmission in particular re-transmission time-out time based on the retransmission operations for the data part of the perform.

In addition, according to the heterogeneous network-based simultaneous data transmission and reception apparatus according to the present invention and a system including the same, network information including different transmission delay and network characteristics for each access network, or calculation based on such network information Since the wait time T_th is dynamically and adaptively set based on the retransmission timeout time of the transmitted sender device or the packet reciprocation time for each access network, the case of occurrence of retransmission based on the retransmission timeout time according to the TCP retransmission rule By minimizing, TCP transmission performance degradation can be effectively prevented.

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

First, a heterogeneous network-based simultaneous data transmission method according to a preferred embodiment of the present invention will be described with reference to FIG. 3. For convenience of explanation, the description will be made based on the downlink.

The management apparatus 400 measures the packet round trip time (RTT) for each access network (S100).

In this case, the management apparatus 400 may measure various packet reciprocating time (RTT) for each access network.

For example, the management apparatus 400 may measure the packet reciprocating time (RTT) for each access network by transmitting and receiving a separate packet for the packet reciprocating time (RTT) with the terminal apparatus 100 through each access network. Alternatively, the packet reciprocal time (RTT) for each access network may be determined using the packet arrival time and the packet arrival time based on the packets transmitted and received with the terminal device 100 to measure the delay time between packets through the access networks. It can be measured. Here, the delay time value means a difference in arrival time between packets on the receiving side with respect to packets transmitted for each access network.

Accordingly, the management device 400 measures the packet reciprocating time (RTT) for each access network through various packet reciprocating time (RTT) measuring methods as described above at every periodic or random time or when a specific event occurs, and for each access network. The packet reciprocating time (RTT) information may be provided to the terminal device 100 (S30), and more preferably, the maximum packet reciprocating time (RTT) information of the packet reciprocating time (RTT) of each access network in step S30. It may be provided to the device 100.

On the other hand, the management apparatus 400 measures the packet reciprocating time (RTT) for each access network through various packet reciprocating time (RTT) measuring methods as described above at every periodic or random time or when a specific event occurs, and based on this, each connection The average packet return time (RTT) of the network can be calculated.

In addition, the management device 400 may provide the calculated average packet return time (RTT) information of each access network to the terminal device 100 in step S30, preferably in step S30, the average packet of each access network. Average packet return time (RTT) information having a maximum value among the round trip time (RTT) can be provided to the terminal device (100).

In this case, the management device 400 periodically provides the terminal device 100 with the maximum packet return time (RTT) information or the average packet return time (RTT) information having the maximum value, or the maximum packet return time (RTT). The information may be provided to the terminal device 100 when the average packet return time (RTT) information having the maximum value is changed by more than a certain ratio (β) compared to the previous information.

In addition, when the management apparatus 400 measures the packet reciprocating time (RTT) for each access network through various packet reciprocating time (RTT) measuring methods as described above at every periodic or random time or when a specific event occurs, such a connection network TCP retransmission using network information such as network characteristic information for each access network and transmission delay value for each access network, including each packet return time (RTT) or the average packet return time (RTT) for each access network described above. A retransmission time-out (RTO) time based on a rule may be calculated / set (S20).

The management device 400 operates as a transmission side device, selects the partial data divided from the transmission target data for each connection network based on a preset data transmission rate for each connection network, and selects the partial data selected through each connection network. Transmit (S50, S55).

In other words, 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 a data transmission rate for each network (eg, 3G and WiFi). 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 first partial data to be transmitted to the first network apparatus 200 is selected among the partial data, and the second partial data to be transmitted to the second network apparatus 300 is selected from the remaining partial data.

In addition, the management apparatus 400 transmits each partial data selected for each network (eg, 3G and WiFi) to each network (eg, 3G and WiFi), and thus the first network apparatus 200 is the management apparatus 400. Transmits the first partial data transmitted from the terminal apparatus 100 to the terminal apparatus 100 (S50), and the second network apparatus 300 transmits the second partial data transmitted from the management apparatus 400 to the terminal apparatus 100. (S55).

Accordingly, the terminal device 100 as a receiving side device receives partial data through two or more access networks, reorders them according to the division order based on the received order information of the partial data, and transmits them by combining the normally rearranged partial data. The target data can be restored.

The terminal device 100 sets the waiting time T_th used by the reception buffer unit 120 (S40).

Here, the waiting time T_th is at least one of network information and the retransmission timeout (RTO) time used when the management apparatus 400 estimates the retransmission timeout (RTO) time used in the retransmission time-based retransmission operation. It is possible to set on the basis of one.

For example, the management apparatus 400 uses the network information including the network characteristic information of each of two or more access networks, the transmission latency value of each of the two or more access networks, and the like. RTO) time can be calculated / predicted. In other words, the network information used for the RTO time prediction includes network characteristic information of each of two or more access networks, a transmission latency value of each of the two or more access networks, and the like.

Accordingly, the terminal device 100 obtains at least one of the above-described network information and retransmission timeout (RTO) time information from the management device 400 and based on at least one of the network information and the retransmission timeout (RTO) time. The wait time (T_th) can be set dynamically.

On the other hand, the waiting time (T_th) is preferably set based on the maximum packet reciprocating time of the packet reciprocating time for each of two or more access networks.

For example, the terminal device 100 may obtain the maximum packet return time (RTT) information or the average packet return time (RTT) information having the maximum value provided from the management device 400 through the step S30 as described above. Can be. Accordingly, the terminal device 100 may dynamically set the waiting time T_th based on the maximum packet return time RTT or the average packet return time RTT having the maximum value.

Of course, the terminal device 100, as described above, the management device 400 performs a variety of methods for measuring the packet reciprocating time (RTT) for each access network by itself to obtain the maximum packet without obtaining from the management device 400 Round trip time (RTT) information or average packet return time (RTT) information having a maximum value may be obtained by itself.

On the other hand, the terminal device 100, in setting the waiting time (T_th) of the type of the terminal device 100 itself (for example, terminal performance, terminal CPU available capacity, memory available capacity, etc.), the current terminal device 100 The wait time T_th may be dynamically set based on the number of connection sessions.

The terminal device 100 rearranges the partial data received through the two or more access networks to the reception buffer unit 120 based on the order information (S60).

At this time, the terminal device 100, according to the result of rearranging each piece of data based on the order information, for the partial data normally rearranged without the part data of the unreceived previous order information, the reception layer according to the higher layer, that is, TCP. The control unit 130 transmits and transmits the partial data to the control unit 130.

In this case, the terminal device 100 will provide the management device 400 with an Ack indicating that the reception acknowledgment is normally received in a normal order corresponding to each piece of partial data delivered to the upper layer (S65).

On the other hand, the terminal device 100 waits for the transfer of the partial data having the order information after the unreceived specific order information to the upper layer according to the result of rearranging the partial data based on the order information (S70). In response to the partial data waiting to be transmitted, it is determined whether the preset waiting time T_th has elapsed (b80), and when the waiting time T_th has elapsed, the information is transmitted to a higher layer.

Accordingly, the terminal device 100 provides the reception arc corresponding to each piece of the partial data transferred to the upper layer to the management device 400 (S90), so that the management device 400 subsequently orders information of the partial data not received. However, the retransmission time-out based retransmission operation may be limited as a specific retransmission timeout time elapses with the reception acknowledgment not being returned in response to partial data waited in the reception buffer during the waiting time T_th.

That is, when the reception buffer waits for the waiting time T_th even for the partial data received by the terminal device 100 but the partial data of the previous order is not transmitted to the management device 400 because the partial data of the previous order is not received. By transmitting to a higher layer, the reception acknowledgment can be transmitted to the management device (400).

For example, the management device 400 transmits the partial data packets 1 and 2 having the order information 1 and 2 through the second network (eg, WiFi), and the order information 3 through the first network (eg, 3G). The partial data packet 3 having the transmission rate is transmitted, and the partial data packets 4 and 5 having the sequence information 4 and 5 are transmitted through the second network (for example, WiFi). Thus, the partial data packets 1 and 2 are transmitted to the terminal device 100. Assume that 4,5 has been received and partial data packet 3 has not been received.

In this case, as a result of rearranging the partial data, the terminal device 100 transmits the normally rearranged partial data, that is, the partial data packets 1 and 2 to the upper layer without the partial data of the unreceived previous order information.

Accordingly, the terminal device 100 will provide the management device 400 with an Ack indicating that reception packets corresponding to each of the partial data packets 1 and 2 transmitted to the upper layer, that is, are normally received in a normal order.

On the other hand, as a result of rearranging the partial data, the terminal apparatus 100 waits for transmission of the partial data having the sequence information after the non-received specific sequence information 3, that is, the partial data packets 4 and 5 to the upper layer. The terminal apparatus 100 determines whether the preset waiting time T_th has elapsed corresponding to each of the partial data packets 4 and 5, and transmits the partial data packet having the elapsed waiting time T_th to the upper layer.

Accordingly, the terminal device 100 provides a reception arc corresponding to each of the partial data packets 4 and 5 transmitted to the upper layer to the management device 400, so that the management device 400 receives the reception ack in response to the partial data. As a specific retransmission timeout time elapses with no reply, the retransmission operation based on the retransmission timeout time may be limited.

At this time, the terminal device 100, if the partial data packet transmitted to the upper layer in step S90 is the partial data having the sequence information 4, 5 after the unreceived specific sequence information 3, the non-received specific sequence information 3 A reception acknowledgment including a retransmission guide message for inducing retransmission for the partial data will be provided to the management device 400. Here, the retransmission guide message may include a duplicate ACK generated corresponding to the unreceived partial data according to the TCP retransmission rule.

On the other hand, the management apparatus 400 starts counting the retransmission timeout time corresponding to each partial data packet after the steps S50 and S55 of transmitting the partial data packets 1, 2, 3, 4 and 5 through two or more access networks. (S23).

At this time, as described above, when receiving the received acknowledgment including the Ack indicating that the normal reception in accordance with the normal order corresponding to each of the partial data packets 1 and 2 from the terminal device 100 in step S65, the management device 400 is partial The retransmission timeout time counting for the data packets 1 and 2 will be terminated and the retransmission timeout time counting for the partial data packets 3, 4 and 5 will be maintained (S26).

Then, as described above, the reception including a duplicate acknowledgment (Duplicate ACK) to induce the retransmission of the received data corresponding to each of the partial data packet 4,5, that is, the sequence information 3 from the terminal device 100 through step S90 Upon receiving the acknowledgment, the management device 400 terminates the retransmission timeout time counting for the partial data packets 4 and 5 to maintain the retransmission timeout time counting for the partial data of the sequence information 3 (S29), and also the sequence information. Store the number of duplicated arcs (eg 2) for the partial data of 3.

Accordingly, the management apparatus 400 according to the TCP retransmission rule, when the number of duplicated arcs for the partial data of the sequence information 3 reaches a specific number (eg, three times), the redundant acknowledgment-based retransmission operation of retransmitting the corresponding partial data packet 3 In addition, if the retransmission timeout time being counted for the partial data of the sequence information 3 elapses, a retransmission time-based retransmission operation for retransmitting the corresponding partial data packet 3 may be performed.

Hereinafter, a heterogeneous network-based simultaneous data transmission / reception method according to the present invention will be described in detail with reference to FIG. 4.

In the heterogeneous network-based simultaneous data transmission / reception method according to the present invention, that is, the operation method of the reception apparatus, the waiting time T_th of the reception buffer unit 120 is set (S110).

Here, the waiting time T_th is at least one of network information and the retransmission timeout (RTO) time used when the transmitter 400 estimates the retransmission timeout (RTO) time used in the retransmission time-based retransmission operation. It is possible to set on the basis of one.

For example, the transmitter 400 calculates a retransmission timeout (RTO) time using network information including network characteristic information of each of two or more access networks, transmission latency values of two or more access networks, and the like. Can predict. In other words, the network information used for the RTO time prediction includes network characteristic information of each of two or more access networks, a transmission latency value of each of the two or more access networks, and the like.

Accordingly, in the method of operating a receiving side apparatus according to the present invention, at least one of the above-described network information and retransmission timeout (RTO) time information is obtained from the transmitting apparatus 400, and the network information and retransmission timeout (RTO) are obtained. The waiting time T_th may be dynamically set based on at least one of the times.

On the other hand, the waiting time (T_th) is preferably set based on the maximum packet reciprocating time of the packet reciprocating time for each of two or more access networks.

For example, in the method of operating the receiving side apparatus according to the present invention, as described above, the maximum packet reciprocating time (RTT) information provided from the transmitting apparatus 400 or the average packet reciprocating time (RTT) information having the maximum value is received. Can be obtained (S100).

Accordingly, the operation method of the receiving apparatus according to the present invention may dynamically set the waiting time T_th based on the maximum packet return time (RTT) or the average packet return time (RTT) having the maximum value.

Of course, in the operation method of the receiving apparatus according to the present invention, as described above, the transmitting apparatus 400 performs a variety of methods for measuring the packet reciprocating time (RTT) for each access network by itself, the transmitting apparatus 400 The maximum packet return time (RTT) information or the average packet return time (RTT) information having the maximum value may be obtained by itself and used to set the waiting time T_th of the reception buffer unit 120 without obtaining the information.

On the other hand, the operation method of the receiving device according to the present invention, in setting the waiting time (T_th), the type of the receiving device 100 itself (eg, terminal performance, terminal CPU available capacity, memory available capacity, etc.), present The wait time T_th may be dynamically set based on the number of access sessions of the receiving device 100.

In the operation method of the receiving device according to the present invention, the partial data divided from the specific transmission target data is received through two or more access networks (eg, 3G and WiFi) (S120).

In the operation method of the receiving apparatus according to the present invention, the partial data received through two or more access networks (eg, 3G and WiFi) are rearranged based on the order information, and the specific order information which is not received according to the rearranged result is rearranged. Subsequently, the processor waits for the partial data having the order information thereafter and transmits the preset partial time corresponding to the partial data waiting for delivery.

In more detail, in the operation method of the reception apparatus according to the present invention, the partial data received through two or more access networks (eg, 3G and WiFi) are rearranged based on the order information (S130).

For example, the transmitter 400 transmits the partial data packets 1 and 2 having the order information 1 and 2 through the second network (eg, WiFi), and the order information through the first network (eg, 3G). The partial data packet 3 having 3 is transmitted, and the partial data packet 4, 5 having sequence information 4, 5 is transmitted through the second network (for example, WiFi), and thus the partial data packet is transmitted to the receiving apparatus 100. Assume that 1,2,4,5 have been received and partial data packet 3 has not been received.

At this time, the operation method of the receiving device according to the present invention, according to the result of rearranging the respective pieces of partial data based on the order information, the upper layer, that is, the upper layer, The control unit 130 transmits the received acknowledgment and partial data combining according to TCP.

That is, the method of operating the reception apparatus according to the present invention will deliver the partially rearranged partial data, that is, the partial data packets 1 and 2 to the upper layer without the partial data of the unreceived previous order information.

Accordingly, the operation method of the receiving device according to the present invention will provide the receiving device corresponding to the partial data transferred from the receiving buffer unit 120 to the upper layer to the transmitting device 400.

That is, in the operation method of the receiving apparatus according to the present invention, the partial data transferred from the receiving buffer unit 120 to the upper layer is partially rearranged without the partial data of the previous sequence information that is not received (eg, the aforementioned If the partial data packets 1 and 2), corresponding to each of the transmitted partial data will be provided to the transmitting device 400 to the Ack indicating that the normal reception is received in a normal order (S140).

On the other hand, in the operation method of the receiving apparatus according to the present invention, according to the result of rearranging each piece of data based on the order information, the partial data having the order information after the unreceived specific order information is transferred to the upper layer. After the preset waiting time T_th has passed in response to the partial data waiting to be delivered, the processor transmits to the upper layer.

That is, in the method of operating the reception apparatus according to the present invention, the partial data having the sequence information after the non-received specific sequence information 3, that is, the partial data packets 4 and 5, waits for the transfer to the upper layer (S150).

In addition, the operation method of the receiving apparatus according to the present invention determines whether the preset waiting time T_th has elapsed corresponding to each of the partial data packets 4 and 5 (S160), and has elapsed the waiting time T_th. It will forward the data packet to the upper layer.

Accordingly, in the method of operating the receiving apparatus according to the present invention, the receiving apparatus corresponding to the partial data transferred from the receiving buffer unit 120 to the upper layer is provided to the transmitting apparatus 400, so that the transmitting apparatus 400 receives the portion. In response to the reception acknowledgment corresponding to the data, a retransmission timeout time based retransmission operation for retransmission is restricted as a specific retransmission timeout time elapses (S170).

That is, in the operation method of the receiving apparatus according to the present invention, the partial data transmitted from the receiving buffer unit 120 to the upper layer has partial data (eg, the partial data packet having the sequence information after the specific sequence information not received). 4, 5), the reception apparatus including the retransmission induction message for inducing retransmission for the partial data of the unreceived specific sequence information (eg, the partial data packet 3 described above) may be provided to the transmitter 400. will be.

Here, the retransmission guide message may include a duplicate ACK generated corresponding to the unreceived partial data according to the TCP retransmission rule.

Accordingly, in the method of operating a receiving device according to the present invention, the receiving device corresponding to each of the partial data packets 4 and 5, which has waited for transmission during the waiting time T_th and has order information after the unreceived specific order information, is transmitted. In operation 400, the transmission apparatus 400 may limit the retransmission time based retransmission operation of retransmission as a specific retransmission timeout time elapses with the reception acknowledgment not being returned in response to the partial data. .

As described above, according to the heterogeneous network-based simultaneous data transmission and reception method and the heterogeneous network-based simultaneous data transmission method according to the present invention, in an environment for providing a simultaneous transmission service, different transmission delays for each access network and Receive network information including network characteristics, or the dynamic / adaptive waiting time (T_th) based on the retransmission timeout time of the sending device calculated on the basis of such network information, or the packet reciprocation time for each access network. When the waiting time T_th has elapsed, even if the partial data having the completion order of unreceived partial data is set in the receiving buffer of the side apparatus and the received partial data is rearranged according to the order information, the receiving arc is provided to the transmitting apparatus. Thus, only partial data not actually received by the receiving device is The transmission-based retransmission operation or the retransmission timeout time-based retransmission operation may be performed, and unnecessary retransmission, particularly the retransmission timeout time-based retransmission operation, may be prevented for the partial data of the sequence after the unreceived partial data. .

In addition, according to the heterogeneous network-based data simultaneous transmission and reception method and the heterogeneous network-based data simultaneous transmission method according to the present invention, network information including different transmission delay and network characteristics for each access network, or such network information. Based on the retransmission timeout time of the sending side device or the packet reciprocation time for each access network, the waiting time T_th is dynamically and adaptively set. By minimizing retransmissions, TCP transmission performance can be effectively prevented.

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 heterogeneous network-based simultaneous data transmission / reception apparatus and transmission / reception method according to the present invention, unnecessary partial data retransmission is effectively prevented in a simultaneous transmission service environment in which partial data divided data is transmitted / received using a plurality of heterogeneous networks. In the sense that it is possible to overcome the limitations of the existing technology, 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 practically clear and practical, so that there is industrial applicability. Invention.

100: terminal device
110: communication unit 120: receiving buffer unit
130:

Claims (8)

A communication unit configured to receive, through each of the two or more access networks, partial data divided by specific transmission target data and designated for each of two or more access networks;
According to a result of rearranging the partial data received through the two or more access networks based on the order information, the partial data having the order information after the unreceived specific order information is waited for delivery, and the partial data waiting to be delivered. Receiving buffer for transmitting when the preset waiting time corresponding to; And
Providing a receiving arc corresponding to the partial data waiting to be delivered from the receiving buffer unit to a transmitting device which transmits the partial data waiting to be delivered, so that the receiving device has received a reception acknowledgment for the partial data waiting to be delivered. And a control unit for limiting retransmission as a specific retransmission timeout time elapses in a reply state. The method of claim 1,
The waiting time is,
And heterogeneous network-based data simultaneous transmission / reception apparatus, characterized in that set based on at least one of the network information and the retransmission timeout used when the retransmission timeout time is predicted. The method of claim 1,
The waiting time is,
Heterogeneous network-based simultaneous data transmission and reception apparatus characterized in that the packet is set based on the maximum packet reciprocating time of each of the two or more access network. The method of claim 1,
The control unit,
If the partial data transmitted from the reception buffer unit is the partial data waiting for delivery having the sequence information after the unreceived specific sequence information, a retransmission guide message for inducing retransmission of the partial data of the unreceived specific sequence information. Heterogeneous network-based data simultaneous transmission and reception apparatus characterized in that for providing the receiving acknowledgment to the transmitter. A partial data receiving step of receiving partial data divided by specific transmission target data and designated for each of two or more access networks through each of the two or more access networks;
An order rearranging step of rearranging the partial data received through the two or more access networks based on the order information;
A delivery waiting step of waiting for a partial data having order information after the unreceived specific order information according to the rearranged result, and transmitting a preset waiting time corresponding to the partial data waiting to be delivered; And
Providing a reception acknowledgment corresponding to the partial data waiting to be delivered to the transmitting device which transmits the partial data waiting to be delivered, so that the transmission apparatus specifies a state in which the reception ack is not returned to the partial data waiting to be delivered; And a reception acknowledgment step of limiting retransmission as the retransmission timeout time elapses. The method of claim 5, wherein
The waiting time is,
Heterogeneous network-based data simultaneous transmission and reception method characterized in that it is set based on at least one of the network information and the retransmission timeout used when the retransmission timeout time prediction. The method according to claim 6,
The waiting time is,
Heterogeneous network-based simultaneous data transmission and reception method characterized in that the packet is set based on the maximum packet reciprocating time of each of the two or more access networks. The method according to claim 6,
The receiving acknowledgment step,
And the retransmission induction message for inducing retransmission of the partial data of the unreceived specific sequence information when the partial data to be transmitted is the partial data waiting for delivery having the sequence information after the unreceived specific sequence information. Heterogeneous network-based data simultaneous transmission and reception method comprising providing a reception acknowledgment to the transmitter.

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