KR20180098444A - Method and system for delay measurement for performance improvement of mptcp - Google Patents

Abstract

Disclosed are a transmission delay measurement method to improve multi-path transmission control protocol (MPTCP) performance, and a system thereof. According to the present invention, the transmission delay measurement method performed by a user terminal included in a network transmitting/receiving data based on MPTCP comprises: a step of operating a timer to measure a first transmission time when transmitting a message, which represents the presence of data to be transmitted, to an access point (AP); a step of receiving an acknowledgement message as a response to the transmitted message; a step of measuring a second transmission time representing a time upon transmission of the data as the acknowledgment message is received; a step of calculating a wireless section delay between the user terminal and the AP based on the first and second transmission times; and a step of measuring a transmission delay between the user terminal and a server based on the calculated wireless section delay.

Description

[0001] METHOD AND SYSTEM FOR DELAY MEASUREMENT FOR PERFORMANCE IMPROVEMENT OF MPTCP [0002]

The following description relates to a technique for measuring the transmission delay in a network section, which is made up of wired / wireless communication for improving multipath TCP (MPTCP) performance.

Due to the proliferation of smartphones and the surge in mobile traffic, a growing number of users are looking to enjoy high-definition video content on mobile devices. To meet the needs of users, mobile operators aim to increase the user's mobile data rate, improve the quality of service (QoS) and quality of experience (QoE).

Conventional user equipment (UE) provides two or more wireless interfaces such as an interface (WIFI) capable of transmitting and receiving in the license-exempt band and an interface (LTE, 3G) capable of transmitting and receiving in the license band to transmit and receive wireless data .

Multipath TCP (MPTCP) is a protocol that controls the transmission of data by multipath. It is a protocol that transmits data transmitted through an existing TCP session by multipath. MPTCP is used as a means to provide stable service in a congested wireless network environment by simultaneously using the air interface of the user terminal and increasing the mobile data rate or keeping the auxiliary connection invisibly.

Although there is a transmission control protocol called SCTP (Stream Control Transmission Protocol) that transmits data by multipath like existing MPTCP, SCTP is not used as a compatibility problem with the existing IP network, but MPTCP is not used in the existing IP network Compatibility with TCP is better.

In 2015, three mobile telcos including KT, LG U +, and SKT introduced data rate enhancement technology using MPTCP. In the case of Apple, the MPTCP was used to provide services such as Siri, and a cellular (WiFi) cellular network to provide seamless connectivity by transmitting Siri data.

In this way, when data is transmitted through a wireless LAN, a transmission delay occurs in the transmission process, and a transmission delay is classified into a transmission delay in a wire section and a transmission delay in a wireless section. The transmission delay of the wired section is small even in the best effort network due to the expansion of the equipment of the Internet service provider. However, the transmission delay of the wireless section is limited to one access point (AP) When a plurality of user terminals are connected or interference is severe, the variation of the transmission delay is large.

Since there is a difference in Round Trip Time (RTT) according to multipath (for example, TCP subflow), TCP segments can not be sequentially transmitted to the TCP transmission buffer due to the above difference, , And the data rate (goodput) at the application layer using real data is reduced (that is, an out-of-order problem occurs). For example, the segment arriving at the MPTCP buffer should be rearranged to the upper TCP buffer according to the segment number order. If a segment of the previous segment number is not received, the segment after the corresponding number can not be moved to the upper TCP buffer, -of-order problem occurs. In this way, the unaligned data occupies the MPTCP buffer of the receiving terminal, so that the AWND (Available Window) value is decreased in the TCP congestion control algorithm, thereby causing additional TCP performance degradation.

Accordingly, there is a need for a technique to improve the MPTCP goodput by solving the out-of-order problem. Korean Patent Laid-Open No. 10-2008-0064445 is directed to an apparatus and method for reducing a transmission delay of a transmission control protocol in a mobile communication system. The mobile station transmits a message for measuring a transmission signal strength to a base station, The round trip time (RTT), which is the time of receiving the response message corresponding to the transmitted data, is confirmed and stored, and the round trip time for measuring the retransmission timeout (RTO) of the transmission protocol is measured And the like.

 [1] T. Le, et al., "Forward Delay-based Packet Scheduling Algorithm for Multipath TCP", Arxiv: 1501, 03196v1, Jan. 2015. [2] H. Kim, et al., "Improvement of MPTCP performance in heterogeneous network using packet scheduling mechanism", in APCC, Oct. 2012.

A method and system for measuring MPTCP performance for improving MPTCP performance according to an exemplary embodiment of the present invention includes transmitting a transmission delay (i.e., a wireless interval delay) of a wireless section, which is severely affected by a number of users accessing an access point and a transmission delay, For example, using a round trip time (RTT) and a timer.

Also, scheduling of each TCP sub-flow in the MPTCP scheduler is performed using the measured transmission delay of the network based on the measured radio interval delay (ie, including the wire interval delay and the radio interval delay) .

A method for measuring a transmission delay performed by a user terminal included in a network for transmitting and receiving data based on multipath TCP (MPTCP), the method comprising: transmitting a message to an access point (AP) Measuring a first transmission time by driving a timer, receiving an acknowledgment message in response to the transmitted message, receiving a second transmission time indicating a time when the data is transmitted as the acknowledgment message is received Calculating a radio section delay between the user terminal and the access device based on the first transmission time and the second transmission time, and calculating a transmission delay between the user terminal and the server based on the calculated radio section delay, And measuring the delay.

According to an aspect of the present invention, the measurement of the transmission delay may measure the transmission delay based on the wired section delay and the wireless section delay as the wired section delay is measured and stored in advance.

According to another aspect of the present invention, the measuring the transmission delay may include measuring a round trip time (RTT) and a sub-flow time per TCP sub-flow corresponding to each of the multi-path TCPs Calculating a wired section delay based on a wireless section delay and calculating the transmission delay for each sub-flow based on the RTT for each sub-flow, wherein the wired section delay comprises: Lt; / RTI >

According to another aspect of the present invention, the step of calculating the wireline delay includes a step of waiting for a predetermined period of time until the RTT for each sub-flow is obtained if the RTT for each sub-flow does not exist can do.

According to another aspect of the present invention, the step of measuring the first transmission time may further include the step of, when transmitting the message corresponding to each of the data allocated to the TCP sub- And measuring the first transmission time for each sub-flow.

According to another aspect of the present invention, the time of transmitting the data allocated to each sub-flow differs depending on the receipt of the acknowledgment message at different times for each sub-flow, and the step of measuring the second transmission time comprises: For each sub-flow, the second transmission time corresponding to the time at which the data is transmitted.

According to another aspect, measuring the first transmission time comprises transmitting an RTS (Request To Send) to the access device, wherein receiving the confirmation message comprises: receiving a clear to send (CTS) Wherein the step of measuring the second transmission time comprises the steps of waiting for transmission of the data for a predefined Short Inter Frame Space (SIFS) time after receiving the CTS, And measuring the second transmission time corresponding to the time of transmitting the data as the SIFS time elapses.

According to another aspect, measuring the second transmission time may include terminating the timer driven by each sub-flow as the data is transmitted to the access device.

According to another aspect, the data to be transmitted at the next time point t + 1 of the current time point t for transmitting the data may be sequentially allocated to each of the plurality of sub-flows based on the transmission delay measured for each sub-flow have.

According to another aspect, measuring the first transmission time comprises retransmitting the message to the access device as the acknowledgment message is not received within a predetermined reference time after transmitting the message .

A transmission delay measurement system for measuring a transmission delay in a network for transmitting and receiving data based on multipath TCP (MPTCP), the system comprising: a timer for transmitting a message indicating that data to be transmitted exists to an access point (AP) A first transmission time measurement unit for driving the first transmission time measurement unit to measure a first transmission time, a second transmission time measurement unit for receiving a confirmation message in response to the message, A radio section delay calculation section for calculating a radio section delay between the transmission delay measurement system and the access device based on the first transmission time and the second transmission time, And a transmission delay measurement unit for measuring a transmission delay between the transmission delay measurement system and the server based on the wireless interval delay. .

According to an aspect of the present invention, the transmission delay measurement unit may measure the transmission delay based on the wired section delay and the wireless section delay as the wired section delay is measured and stored in advance.

According to another aspect of the present invention, the transmission delay measurement unit may calculate a RTT (Round Trip Time) for each TCP sub-flow corresponding to each of the multi-path TCPs and a wireless inter- And calculates the transmission delay on the basis of the sub-flow-based RTT based on the sub-flow-based RTT, and the wired section delay may indicate a delay between the access device and the server.

According to another aspect of the present invention, the transmission delay measurement unit may calculate the wired interval delay until a RTT for each sub-flow is obtained if there is no Round Trip Time (RTT) RTT per sub-flow, can do.

According to another aspect of the present invention, the first transmission time measurement unit measures a timer of the corresponding sub-flow at the time of transmitting the message corresponding to each of the data allocated to each TCP sub-flow corresponding to each of the multipath TCPs to the access device So that the first transmission time can be measured for each sub-flow.

According to another aspect of the present invention, as the confirmation message is received at different times for each sub-flow, the time of transmitting the data allocated for each sub-flow is different, and the second transmission time measurement unit The second transmission time corresponding to the transmission time of each sub-flow can be measured.

According to another aspect, the message includes a Request To Send (RTS), the confirmation message includes a CTS (Clear To Send), and the second transmission time measurement unit is configured to receive the CTS It is possible to wait for the transmission of the data during a short interframe space (SIFS) time and to measure the second transmission time corresponding to the time when the data is transmitted as the SIFS time elapses.

According to another aspect of the present invention, the second transmission time measurement unit may terminate the timer driven for each sub-flow by transmitting the data to the access device.

According to another aspect, the data to be transmitted at the next time point t + 1 of the current time point t for transmitting the data may be sequentially allocated to each of the plurality of sub-flows based on the transmission delay measured for each sub-flow have.

According to another aspect, the first transmission time measurement unit may retransmit the message to the access device after the acknowledgment message is not received within a predetermined reference time after transmitting the message.

A method and system for measuring MPTCP performance for improving MPTCP performance according to an exemplary embodiment of the present invention includes a transmission delay of a radio section in which a degree of change of a transmission delay is severe according to the number of users accessing an access point (AP) Wireless interval delay) can be measured more accurately using RTT (Round Trip Time) and timer of TCP.

Also, scheduling of each TCP sub-flow in the MPTCP scheduler is performed using the measured transmission delay of the network based on the measured radio interval delay (ie, including the wire interval delay and the radio interval delay) Can be improved. That is, good performance can be improved when MPTCP data is transmitted through a congested wireless LAN (LAN) by performing MTCP scheduling by grasping the latest radio interval delay based on an RTS / CTS message.

FIG. 1 is a diagram illustrating an entire network including wireless and wired communication sections according to an exemplary embodiment of the present invention. Referring to FIG.
2 is a block diagram illustrating an internal configuration of a transmission delay measurement system according to an embodiment of the present invention.
3 is a flowchart illustrating a transmission delay measurement method according to an embodiment of the present invention.
4 is a flow diagram illustrating the operation of calculating a wireless interval delay between a transmission delay measurement system and an access point (AP) in a WLAN, according to an embodiment of the present invention.
5 is a diagram illustrating operations up to transmission delay measurement and scheduling in an embodiment of the present invention.
6 is a flowchart illustrating an operation for setting a transmission delay based on a wireless interval delay in an embodiment of the present invention.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings.

The present invention relates to a technique for scheduling data by measuring a transmission delay on a network consisting of a wired and a wireless communication interval based on a multi-path TCP (MPTCP) protocol, The present invention relates to a technique for measuring a network transmission delay in a process of scheduling a segment of an upper TCP buffer to a buffer of a lower MPTCP sub-flow during transmission control for data transmission in a lower MPTCP sub-flow.

In the present embodiments, transmission control may be performed at a user terminal that is a transmitting terminal to which data is to be transmitted. That is, because MPTCP corresponds to a layer 4 (Layer 4) transmission control protocol, it is difficult to perform transmission control in a router or switch located in the middle of communication, so that transmission control can be performed in a user terminal that is a transmitting terminal.

In the present embodiment, an access device (hereinafter, referred to as an " access point ") is located between a user terminal and a server constituting the network. Data transmission and reception are performed wirelessly between the access device and the user terminal. Data transmission / reception can be performed between the device and the server by wire communication.

In addition, in the present embodiments, transmission control can be performed using only a timer existing in a user terminal which is a transmitting terminal to which data is to be transmitted. That is, the above-mentioned non-patent document (1), which performs transmission control using two timers, that is, a timer that exists in each of access points (APs) that are receiving terminals that receive data transmitted from the user terminals and user terminals [1] T. Le, et al., &Quot; Forward Delay-based Packet Scheduling Algorithm for Multipath TCP ", Arxiv: 1501, 03196v1, Jan. 2015. Unlike in 2015 , the transmission delay time can be measured by only one timer located in the user terminal, and since the timer is located only in the user terminal connected to the wireless LAN, the timer measurement result value can be accurate. For example, since the timers need not be synchronized between the user terminal and the access point, the network efficiency such as the reduction of the network overhead can be increased.

Further, in the present embodiments, the user terminal may include an access point (AP) such as a smartphone, a tablet, a notebook, etc. and all electronic devices forming a network based on wireless communication such as WiFi And can be expressed as a 'transmission delay measurement system'.

FIG. 1 is a diagram illustrating an entire network including wireless and wired communication sections according to an exemplary embodiment of the present invention. Referring to FIG.

1, a network 100 may include a user terminal (UE) 101, an access point (AP) 102, and a server 103. [

A network 100 may be formed in a wireless communication interval between the user terminal 101 and the access point 102 and a wired communication interval between the access point 102 and the server 103. [

In this case, the delay of the wireless section is variable, and the delay of the wire section may be relatively stable with respect to the wireless section. Accordingly, in the present embodiments, the transmission delay from the user terminal 101 to the server 103 can be measured by grasping the latest delay information corresponding to the radio section. In other words, the transmission delay 110 can be expressed by the sum of the radio section delay (d, 111) and the wire section delay (D, 112).

For example, in the case of using RTT (Round Trip Time), when the user terminal 101 acquires the RTT value to the server 103 using the existing TCP mechanism, the user terminal Can measure the time interval from the time when the first RTS message is sent in the physical layer to the time when the CTS message is received to the radio layer delay (d). The user terminal (i.e., the transmission delay system) 101 can calculate the wire interval delay D based on the measured radio interval delay d ₁ and the acquired RTT value, and the wired section delay D, The transmission delay (RTT / 2), and the wireless section delay (d) can be expressed by the following Equation (1).

[Equation 1]

In Equation (1), a radio transmission delay in a specific sub-flow among a plurality of sub-flows is denoted by d ₁ , and can be generalized as shown in Equation (2) below.

&Quot; (2) "

In Equation 2, n is n may represent a second TCP subflow, D _n is the transmission delay, d _n of the n-th TCP wired interval delay that corresponds to the sub-flow, RTT _n / 2 is the n-th TCP subflow is n Lt; th > sub-flow. In general, the radio interval delay can be denoted by index d.

1, the MPTCP scheduler may exist on both the user terminal 101 and the server 103. Hereinafter, the transmission delay measurement system will be described with reference to FIG. 1, in which the MPTCP sub-flow path passes through the wired and wireless sections (Tx, n) at which the nth packet is expected to arrive at the receiver (e.g., the server) via path x will be described. In particular, the RTT / 2 is divided into a wired section delay D 112 and a wireless section delay d 111. The stable wired section delay D is treated as a constant and the fluctuating radio section delay d is measured and updated at a node through RTS / The operation of measuring T _1,3 and solving the out-of-order problem will now be described in detail.

FIG. 2 is a block diagram illustrating an internal configuration of a transmission delay measurement system according to an exemplary embodiment of the present invention. FIG. 3 is a flowchart illustrating a transmission delay measurement method according to an exemplary embodiment of the present invention.

2, the transmission delay measurement system 200 includes a first transmission time measurement unit 210, a second transmission time measurement unit 220, a wireless section delay calculation unit 230, a transmission delay measurement unit 240, . ≪ / RTI > 2, transmission control is performed using one timer in relation to a specific TCP subflow, so that the first and second transmission time measurement units include a timer (Not shown) for controlling the timer. At this time, when there are a plurality of subflows based on the multipath TCP, corresponding timers are driven for each subflow, so that the first and second transmission times can be measured.

The transmission delay measurement system 200 corresponds to a user terminal to which data is to be transmitted and the transmission delay measurement system 200 and the access point AP 201 may correspond to a wireless communication section. And the server 202 may correspond to a wired communication section.

Each of the steps 310 through 350 in FIG. 3 includes a first transmission time measurement unit 210, a second transmission time measurement unit 220, a wireless section delay calculation unit 230, And may be performed by the delay measurement unit 240.

In step 310, the first transmission time measurement unit 210 may measure a first transmission time by driving a timer when transmitting a message to the access point (AP) 201 indicating that there is data to be transmitted have. At this time, the first transmission time measurement unit 210 may measure the first transmission time for each TCP subflow corresponding to each of the multipath TCPs.

For example, when performing a wireless LAN (WLAN) based communication between the transmission delay measurement system 200 and the access point 201, the message may include a Request To Send (RTS) message. Here, the first transmission time may indicate the time at which the message (i.e., RTS) is transmitted to the access point 201. [

In step 320, the second transmission time measurement unit 220 may receive an acknowledgment message (ACK) in response to the transmitted message. For example, as a response to the transmitted RTS message, a clear to send (CTS) message may be received from the access point 201. At this time, the second transmission time measurement unit 220 may receive a response message for the RTS message for each TCP subflow corresponding to each of the multipath TCPs.

In step 330, since the data transmission can be started when the confirmation message is received, the second transmission time measurement unit 220 can measure the second transmission time, which is the time when data is transmitted. At this time, the second transmission time measurement unit 220 may measure the second transmission time for each TCP subflow corresponding to each of the multipath TCPs.

In step 331, after receiving the acknowledgment message (ACK) for the transmitted fraudulent message, the second transmission time measurement unit 220 may wait for data transmission during the predetermined SIFS (Short Inter Frame Space) time.

In step 332, when the SIFS time elapses, the second transmission time measurement unit 220 may measure the second transmission time, which is the time when the corresponding data is transmitted for each sub-flow.

In step 333, when data is transmitted for each sub-flow, the second transmission time measurement unit 220 may terminate a timer driven for each sub-flow that transmitted the data.

In step 340, the radio section delay calculation section 230 may calculate the radio section delay d ₁ based on the measured first transmission time and the second transmission time.

At this time, the radio section delay calculation section 230 can calculate the radio section delay based on Equation (3) below.

&Quot; (3) "

In Equation (3), t ₄ may represent the second transmission time, and t ₁ may represent the first transmission time.

According to Equation (3), the radio section delay calculation section 230 calculates the difference (t ₄ -t ₁₎ between the second transmission time t ₄ corresponding to the n-th sub-flow and the first transmission time t ₁ corresponding to the n- ), The radio link delay d (i.e., d _n ) of the corresponding sub-flow can be calculated. Then, the wireless section delay calculator 230 can transmit the calculated wireless section delay d to the server 202 via the TCP option header field or the like.

In step 350, the transmission delay measurement unit 240 may measure a transmission delay between the transmission delay measurement system 200 and the server 202 based on the calculated radio interval delay d _n .

In step 351, if there is no RTT, the transmission delay measurement unit 240 may wait for a predetermined period of time without measuring the transmission delay. At this time, the transmission delay measurement unit 240 can determine whether RTT exists for each TCP sub-flow. Based on the confirmation, the transmission delay measurement unit 240 measures a sub-flow in which the RTT of the corresponding sub- Time can wait.

In step 352, the transmission delay measurement unit 240 may calculate the wired section delay for each sub-flow based on the acquired or updated RTT.

In step 353, when the wired section delay is calculated, the transmission delay measurement unit 240 may set a value (RTT / 2) obtained by dividing the acquired or updated RTT by 2 as a transmission delay.

4 is a flow diagram illustrating the operation of calculating a wireless interval delay between a transmission delay measurement system and an access point (AP) in a WLAN, according to an embodiment of the present invention.

In FIG. 4, it can be assumed that a WLAN is formed between the transmission delay measurement system 401 and the access point 402, which is a user terminal, and it is assumed that a CSMA / CA is used. Then, if there is data to be transmitted through a layer 2 frame, the transmission delay measurement system 401 can transmit the RTS to the access point 402. [ At this time, the transmission delay measurement system 401 can measure the first transmission time, which is the time when the RTS is transmitted to the access point 402 by driving the timer.

Then, upon receiving the CTS from the access point 402, the transmission delay measurement system 401 may wait for the SIFS time and then transmit the data to the access point 402. At this time, the transmission delay measurement system 401 can measure the second transmission time, which is the time corresponding to the time of transmitting the data.

Then, the WLAN congestion RTS (i.e., RTS 1 ^st) since the transmission failure to receive the response of CTS for the RTS within a predefined reference time, the transmission delay measurement system 401 is RTS (RTS 2 ^nd ) May be retransmitted to the access point 402. At this time, the RTS retransmission can be repeatedly performed until the predetermined number of times. In addition, the RST may be periodically transmitted until the CTS is received.

When the CTS is received, the transmission delay measurement system 401 can wait for the SIFS time and then transmit the data to the access point 402 and measure the second transmission time, which is the time when the data is transmitted. Then, the transmission delay measurement system 401 can calculate the wireless interval delay based on the difference between the first transmission time t ₁ and the second transmission time t ₂ , which is the time when the first RTS was transmitted.

For example, because as shown in Equation 3 above, the wireless section of the delay d is t ₄ -t _1, but the measurement time and ends fixed, SIFS is the advance in the standard time received the CTS (t _3, 404), t ₃ The time from + SIFS time to t ₄ can be predicted as (t ₃ - t ₂ ) / 2. At this time, when the CTS is received, the timer is terminated, and the radio section delay d can be calculated by predicting the time from t ₃ to t ₄ . That is, the radio section delay d can be calculated as t ₄ - t ₁ = ((t ₃ - t ₂ ) / 2 + SIFS) + (t ₃ - t ₁ ). The calculated radio link delay d can be recorded in the TCP option header field and transmitted to the server. Accordingly, the wireless section delay d of the latest time (n-1, n-3, etc.) can be transmitted to both the user terminal and the server.

5 is a diagram illustrating operations up to transmission delay measurement and scheduling in an embodiment of the present invention.

5, the radio section delay calculation section 540 and the transmission delay measurement section 550 may correspond to the radio section delay calculation section 230 and the transmission delay measurement section 240 of FIG. The transmission delay measurement system 200 of FIG. 2 may further include TCP subflows 1 to n (520 and 521), radio physical layer network interfaces 1 to n (530 and 531), and MPTCP scheduler 510 . At this time, the TCP subflows 1 to n (520, 521), the MPTCP scheduler 510, and the transmission delay measurement unit 550 may also be included in the server 202.

5, the TCP subflow n 521 represents the nth TCP subflow of the TCP subflow corresponding to each of the multipath TCPs, and the radio physical layer network interface n 531 represents the nth radio physical layer network interface .

5, a communication node can be divided into (a wired node, a wireless node), (a transmitting node, a receiving node) in consideration of characteristics of a node actually communicating (i.e., a user terminal and an access point, Three combinations of communication combination (wired-transmitting node, wireless-receiving node), (wired-receiving node, wireless-transmitting node), (wireless-receiving node, wired-transmitting node) may be possible. Accordingly, in FIG. 5, the MPTCP scheduler 510, the TCP subflows 1 to n (520 and 521), and the radio physical layer network interfaces 1 to n (530 and 531) We will also describe the characteristics of the node where the element is located. That is, when receiving data according to the TCP characteristic, an ACK must be transmitted, so that the end node can be both a transmitting node and a receiving node. And, because the MPTCP subflow considers routing via wireless and wireline coupled paths, the sending node can be the sending node as well as the user terminal. In FIG. 5, a wired node may represent a server, and a wireless node may represent a user terminal.

First, the MPTCP scheduler 510 estimates the transmission delay of each TCP subflow 520, 521 received from the transmission delay measurement unit 550 (that is, the wired interval delay + the wireless interval delay) (Or distribute) the received data to the corresponding TCP subflows 520 and 521 sequentially. For example, the MPTCP scheduler 510 may be located at the transmitting node (i.e., both the server and the user terminal).

Then, one or more TCP subflows 520 and 521 may be generated for each path that can be transmitted from the transmitting node to the receiving node. For example, ISO Layer 4 TCP subflows 520 and 521 may be generated. Then, each of the TCP sub-flows 520 and 521 performs transmission path control for the corresponding path, and can automatically check the RTT for each sub-flow. At this time, if the RTT is updated, the corresponding sub-flow in which the RTT is updated can transmit the updated RTT value to the transmission delay measurement unit 550.

The wireless physical layer network interfaces 530 and 531 receive data from the data or subflows 520 and 521 to be transmitted through the respective TCP subflows 520 and 521 and transmit a response (ACK) It may correspond to an interface for sending. For example, the wireless physical layer network interfaces 530 and 531 may be located in a wirelessly connected node, such as a user terminal (UE). When included in a user terminal (UE), data is wirelessly transmitted . ≪ / RTI > And, when included in the access point (AP) 202, an ACK for the received data can also be represented by data).

The wireless physical layer network interfaces 530 and 531 correspond to the ISO Layer 1, and the wireless physical layer network interfaces 530 and 531 from 1 to n may all be assumed to be a wireless LAN interface. After receiving the CTS from the access point 201, the radio physical layer network interfaces 530 and 531 transmit a signal (or information) to transmit the data frame when transmitting the actual data to the radio section delay calculators 230 and 540 And can be notified. That is, the frame transmission notification can be transmitted to the wireless section delay calculator 230 or 540. When transmitting the first RTS to the access point 201, the radio physical layer network interfaces 530 and 531 can notify the first and second RTS transmission notifications to the radio interval delay calculators 230 and 540, respectively. Here, the first RTS transmission notification includes the first transmission time, and the frame transmission notification may include the second transmission time. Then, the first and second transmission times can be measured by driving the timer.

The wireless section delay calculators 230 and 540 calculate the time and date at which the data frame transmission notification is received for each sub-flow based on the first RTS transmission notification and the frame transmission notification received from the wireless physical layer network interfaces 530 and 531, That is, the difference between the second transmission time t ₄ and the time when the first RTS transmission notification is received for each subflow, that is, the first transmission time t ₁ , can be calculated. The radio section delay calculators 230 and 540 may calculate the radio section delay d _{n for} each sub-flow based on the difference t ₄ - t ₁ . For example, the wireless section delay calculators 230 and 540 may be located in wirelessly connected wireless nodes (i.e., user terminals).

In this case, when the transmission delay measurement units 240 and 550 are located in the wireless node (e.g., user terminal), the wireless interval delay calculation units 230 and 540 transmit the calculated wireless interval delay to the transmission delay measurement unit 240, 550). When the transmission delay measurement units 240 and 550 are located in the wired node (e.g., server), the wireless interval delay calculation units 230 and 540 transmit the calculated wireless interval delay to the corresponding TCP subflows, And can be transmitted to a wired node using a TCP option field reserved bit.

The transmission delay measurement units 240 and 550 may receive the updated RTT value and the wireless interval delay for each TCP sub-flow for each sub-flow. For example, the transmission delay measurement unit 240, 550 may be located at the transmitting node (i.e., both at the user terminal and at the server).

The transmission delay measurement units 240 and 550 can calculate the wired interval delay based on the RTT value updated for each sub-flow and the wireless interval delay calculated for each sub-flow. For example, it is possible to calculate (i.e., measure) the transmission delay for each sub-flow based on the wireless section delay d corresponding to the calculated latest time and the RTT value for each TCP sub-flow. At this time, the wired section delay D can be measured according to the presence or absence of the RTT value per sub-flow, and the detailed operation for calculating the transmission delay (i.e., the transmission delay) and the wired section delay will be described later with reference to FIG. 6 .

6 is a flow chart illustrating an operation for setting a transmission delay based on a wireless interval delay in a transmission delay measurement system, in an embodiment of the present invention.

In FIG. 6, the transmission delay measurement system 200 may correspond to the server 202 or the user terminal, and when the transmission delay measurement system 200 is a server, (d _n ) from the user terminal in advance. If the transmission delay measurement system 200 is a user terminal, the transmission delay measurement system 200 may store the radio interval delay calculated by the transmission delay measurement system 200 in a memory (not shown). In FIG. 6, the case where the transmission delay measurement system 200 is a user terminal will be described as an example.

6, steps 620 to 650 may correspond to an initialization process.

In step 610, the transmission delay measurement system 200 may determine whether there is a wire interval delay (D _n ) previously measured or stored in a memory (not shown).

If there is no pre-measured or stored wired section delay D _n (610, NO), in step 620, RTT (i.e., RTT value) is acquired through the corresponding TCP subflow in which the wired section delay does not exist . For example, an RTT value may be obtained based on an existing TCP mechanism.

At this time, if the RTT is acquired (620, NO), that is, if there is no RTT at the initialization, the transmission delay measurement system 200 can wait for a predetermined period of time until the RTT is obtained have.

For example, when a TCP sub-flow is generated and data is transmitted for the first time, there may not be a pre-computed or stored wire section delay because there is no RTT value measured or stored in advance. Then, it waits until receiving the RTT through the corresponding TCP sub-flow, calculates the wired section delay of the corresponding sub-flow, and sets RTT / 2 as the transmission delay.

That is, if the RTT is obtained (620, YES), the transmission delay measurement system 200 calculates the wired section delay based on the obtained RTT and the wireless section delay d calculated by the user terminal in step 640. For example, the transmission delay measurement system 200 may calculate the wireline section delay D via RTT / 2-d.

At this time, a transmission delay (that is, a path transmission delay) should be calculated by adding a wireless section delay d to the wire section delay D. In the initialization step, since the wireless section delay corresponding to the latest time is not updated, d = (RTT / 2) - d + d.

Accordingly, in step 650, the transmission delay measurement system 200 may set RTT / 2 to a transmission delay.

If it is determined in step 610 that there is a pre-measured or stored wired section delay in step 610, the transmission delay measurement system 200 determines in step 660 that the wired section delay measured or stored in advance, Delay can be summed to calculate the transmission delay. For example, in the initialization step, if the wired section delay is calculated through step 640 and the wired section delay is already present, the transmission delay measurement system 200 adds the wired section delay D and the wireless section delay d calculated in step 640, , Path transmission delay) can be calculated.

In step 670, the calculated transmission delay or the set transmission delay is transmitted to the MPTCP scheduler and can be used for scheduling. That is, the MPTCP scheduler can perform scheduling by sequentially transmitting a segment to a corresponding TCP subflow according to a transmission delay for each TCP subflow. In other words, the wired section delay D is treated as a constant value, and the wireless section delay d corresponding to the updated latest time is added to the wired section delay D to obtain a transmission delay (i.e., a path transmission delay) It is possible to predict when the packet arrives, and the MPTCP scheduler can perform packet scheduling for each sub-flow based on the predicted arrival time. In order to sequentially transmit the segment (i.e., data) to the corresponding TCP sub-flow, the above-described non-patent document [1] T. Le et al., &Quot; Forward Delay-based Packet Scheduling Algorithm for Multipath TCP ", Arxiv : 1501, 03196v1, Jan. 2015. and [2] H. Kim, et al., & Quot ; Improvement of MPTCP performance in heterogeneous network using packet scheduling mechanism ", in APCC , Oct. 2012 .

로 계산함으로써, 보다 정확하게 전송 지연을 측정할 수 있다. 그리고, 사용자 단말 및 서버 양측이 아닌 사용자 단말에서만 타이머(timer)를 구동함으로써 보다 정확하게 지연 시간을 측정할 수 있고, 무선 망 혼잡을 정확하게 예측하여 각 패킷 별로 예상 도착 시간을 계산할 수 있다.As described above, in the MPTCP sub-flow, a transmission delay (that is, a wireless interval delay) in the wireless section is calculated using a timer, an RTS / CTS message together with the RTT of TCP, The performance (i.e., goodput) of the MPTCP can be improved by more precisely calculating the estimated transmission time and performing the scheduling of each sub-flow in the MPTCP scheduler based on the scheduled transmission time. That is, for a sub-flow via a wired line and a wireless line, a transmission delay (i.e., a path transmission delay) is calculated by dividing a wireless section and a wire section, and a fluctuating radio section delay d is defined as t ₄ -t ₁ ,

The transmission delay can be measured more accurately. Also, it is possible to more accurately measure the delay time by driving the timer only in the user terminal and the user terminal not on both sides of the server, and to predict the arrival time of each packet accurately by predicting the wireless network congestion.

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

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. For example, it is to be understood that the techniques described may be performed in a different order than the described methods, and / or that components of the described systems, structures, devices, circuits, Lt; / RTI > or equivalents, even if it is replaced or replaced.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Claims (20)

A transmission delay measurement method performed by a user terminal included in a network for transmitting and receiving data based on multi-path TCP (MPTCP)
Measuring a first transmission time by driving a timer when transmitting a message indicating that data to be transmitted exists to an access point (AP);
Receiving a confirmation message in response to the transmitted message;
Measuring a second transmission time indicating a time when the data is transmitted as the confirmation message is received;
Calculating a radio link delay between the user terminal and the access device based on the first transmission time and the second transmission time; And
Measuring a transmission delay between the user terminal and the server based on the calculated radio link delay;
/ RTI > The method according to claim 1,
Wherein measuring the transmission delay comprises:
Measuring the transmission delay based on the wired section delay and the wireless section delay as the wired section delay is measured and stored in advance
Wherein the transmission delay measurement method comprises the steps of: The method according to claim 1,
Wherein measuring the transmission delay comprises:
Calculating a wired section delay based on RTT (Round Trip Time) and sub-flow-based wireless section delay for each TCP sub-flow corresponding to each of the multi-path TCPs in accordance with no pre-measured and stored wired section delay; And
Calculating the transmission delay for each sub-flow based on the RTT for each sub-flow
Lt; / RTI >
Wherein the wired section delay is indicative of a delay between the access device and the server
Wherein the transmission delay measurement method comprises the steps of: The method of claim 3,
Wherein the calculating the wireline delay comprises:
If there is no Round Trip Time (RTT) RTT for each sub-flow, waiting for a predetermined period of time until the RTT for each sub-flow is obtained
/ RTI > The method according to claim 1,
Wherein the measuring the first transmission time comprises:
Measuring a first transmission time for each sub-flow by driving a timer of the corresponding sub-flow at a time of transmitting the message corresponding to each of the data allocated to each TCP sub-flow corresponding to the multi-path TCP to the access device
/ RTI > The method according to claim 1,
As the acknowledgment message is received at different times for each sub-flow, the time of transmitting the data allocated for each sub-flow is different,
Wherein the measuring the second transmission time comprises:
Measuring the second transmission time corresponding to the time at which the data is transmitted at different points in time for each sub-flow
Wherein the transmission delay measurement method comprises the steps of: The method according to claim 1,
Wherein the measuring the first transmission time comprises:
And sending a Request To Send (RTS) to the access device,
The receiving of the acknowledgment message comprises:
Receiving a clear to send (CTS) from the access device,
Wherein the measuring the second transmission time comprises:
Waiting for the transmission of the data for a predefined Short Inter Frame Space (SIFS) time after receiving the CTS; and
Measuring the second transmission time corresponding to the time of the transmission of the data as the SIFS time elapses
/ RTI > The method according to claim 1,
Wherein the measuring the second transmission time comprises:
Terminating the timer driven by each sub-flow as the data is transmitted to the access device
/ RTI > The method according to claim 1,
Wherein data to be transmitted at a next time point t + 1 of a current time point t for transmitting the data is sequentially allocated to each of a plurality of sub-flows based on the transmission delay measured for each sub-flow. Way. The method according to claim 1,
Wherein the measuring the first transmission time comprises:
Retransmitting the message to the access device as the acknowledgment message is not received within a predetermined reference time after transmitting the message
/ RTI > 1. A transmission delay measurement system for measuring delay in transmission of a network that transmits and receives data based on multipath TCP (MPTCP)
A first transmission time measuring unit for measuring a first transmission time by driving a timer when transmitting a message indicating that data to be transmitted exists to an access point (AP);
A second transmission time measuring unit that receives a confirmation message in response to the message and measures a second transmission time including a time when the data is transmitted as the confirmation message is received;
A wireless section delay calculator for calculating a wireless section delay between the transmission delay measurement system and the access device based on the first transmission time and the second transmission time; And
And a transmission delay measurement unit for measuring a transmission delay between the transmission delay measurement system and the server based on the calculated radio interval delay,
The transmission delay measurement system comprising: 12. The method of claim 11,
Wherein the transmission delay measurement unit comprises:
Measuring the transmission delay based on the wired section delay and the wireless section delay as the wired section delay is measured and stored in advance
Wherein the transmission delay measurement system comprises: 12. The method of claim 11,
Wherein the transmission delay measurement unit comprises:
Calculating a wired section delay based on RTT (Round Trip Time) and sub-flow-based wireless section delay for each TCP sub-flow corresponding to each of the multi-path TCPs in accordance with no pre-measured and stored wired section delay, Calculates the transmission delay for each sub-flow based on the RTT for each sub-flow,
Wherein the wired section delay is indicative of a delay between the access device and the server
Wherein the transmission delay measurement system comprises: 14. The method of claim 13,
Wherein the transmission delay measurement unit comprises:
If there is no Round Trip Time (RTT) RTT per sub-flow, the calculation of the wired section delay is waited for a predetermined period of time until the RTT per sub-flow is obtained
Wherein the transmission delay measurement system comprises: 12. The method of claim 11,
Wherein the first transmission time measuring unit comprises:
And the first transmission time is measured for each sub-flow by driving a timer of the corresponding sub-flow at the time of transmitting the message corresponding to the data allocated to each TCP sub-flow corresponding to each of the multipath TCPs to the access device
Wherein the transmission delay measurement system comprises: 12. The method of claim 11,
As the acknowledgment message is received at different times for each sub-flow, the time of transmitting the data allocated for each sub-flow is different,
Wherein the second transmission time-
Measuring the second transmission time corresponding to the time at which the data is transmitted at different points in time for each sub-flow
Wherein the transmission delay measurement system comprises: 12. The method of claim 11,
The message includes an RTS (Request To Send)
The acknowledgment message includes a CTS (Clear To Send)
Wherein the second transmission time-
The mobile station waits for the transmission of the data for a predetermined short interframe space (SIFS) time after receiving the CTS, and transmits the second transmission time corresponding to the time when the data is transmitted as the SIFS time elapses Measuring
Wherein the transmission delay measurement system comprises: 12. The method of claim 11,
Wherein the second transmission time-
And terminating the timer driven for each sub-flow as the data is transmitted to the access device
Wherein the transmission delay measurement system comprises: 12. The method of claim 11,
Wherein data to be transmitted at a next time point t + 1 of a current time point t for transmitting the data is sequentially allocated to each of a plurality of sub-flows based on the transmission delay measured for each sub-flow. system. 12. The method of claim 11,
Wherein the first transmission time measuring unit comprises:
Retransmitting the message to the access device as the acknowledgment message is not received within a predetermined reference time after transmitting the message
Wherein the transmission delay measurement system comprises:

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