KR20110101920A - Transmitting apparatus, relaying apparatus, receiving apparatus, transmitting method, relaying method, and receiving method thereof - Google Patents

Abstract

A transmitter for transmitting a frame to an opponent node through an intermediate node is disclosed. The transmitting apparatus includes a data transceiver for transmitting and receiving a frame, a timer counting a threshold time for determining whether a frame is transmitted, a detector for detecting whether the intermediate node transmits a data frame to the counterpart node, and a data frame to the intermediate node. If the data frame transmission is not detected by the detector after the data frame transmission until the end of the first threshold time counted by the timer, it is determined that the data frame transmission has failed and set the time of the preset multiple of the first threshold time. And a control unit for controlling retransmission of the data frame to an intermediate node. Accordingly, transmission errors due to channel contention can be improved, and system throughput can be improved in a poor wireless channel environment.

Description

Transmitting apparatus, relay apparatus, receiving apparatus and frame transmission method, relay method, receiving method {Transmitting apparatus, relaying apparatus, receiving apparatus, transmitting method, relaying method, and receiving method

The present invention relates to a transmitting apparatus, a relay apparatus, a receiving apparatus and a frame transmitting method, a relay method, and a receiving method. More specifically, the present invention relates to a transmitting apparatus, a relay apparatus, a receiving apparatus, and a frame transmitting method based on a MAC protocol for cooperative communication. , Relay method, and receiving method.

In the field of wireless communication, which has poor conditions compared to the wired network such as limited bandwidth and poor channel environment, the 4G mobile communication system provides up to 1Gbps.

However, in mobile networks, terminals are located at cell boundaries or ad hoc networks (Ref. 1: IETF MANET Working Group. Available from: http://www.ietf.org/html .charters / manet-charter.html.) It is still a problem to solve the transmission error that occurs when the channel state deteriorates for a while due to a fading distance or a distance between two nodes performing communication.

In addition, the mobile communication system uses a repeater to improve the transmission quality in the cell boundary area, but in an environment where the network structure is variable due to the mobility of the terminal such as an ad hoc network, a general repeater is used to solve the poor radio channel problem. Can't.

First, reference 2 (G. Holland, N. Vaidya, and P. Bahl, “A rate-adaptive MAC protocol for multi-hop wireless networks”, in Proc. Of ACM / IEEE MOBICOM, Italy, June 2001.) We proposed a receiver-based auto rate (RBAR) technique that describes the MAC header specification and procedure for using link adaptation in WLAN. In particular, all existing MAC protocols for cooperative communication described in this paper are proposed based on the RBAR technique. It is widely used as a standard.

On the other hand, many researches on MAC protocols for cooperative communication have been conducted. First, based on the RBAR technique, a CMAC technique that can support cooperative communication with minimal changes to existing WLAN standards has been proposed (Ref. 3: Sai Shankar N, Chun-Ting Chou, and Monisha Ghosh, “Cooperative communication MAC (CMAC)-A new MAC protocol for next generation wireless LANs,” in Proc. Of IEEE Int. Conf. On Wireless Networks, Communications and Mobile Computing, Hawaii, June 2005 . Reference). In this study, we proposed a procedure for retransmission when a transmission error occurs between two nodes, and FCMAC method integrating CMAC and channel coding.

Reference 4 (H. Zhu and G. Cao, “rDCF: A relay-enabled medium access control protocol for wireless Ad Hoc Networks,” IEEE Trans. On Mobile Computing, Vol. 5, No. 9, pp. 1201-1214). , September 2006.) proposed rDCF (relay DCF) method which extends existing DCF method for cooperative communication. It describes the procedure of selecting intermediate nodes and control frames changed in existing DCF to support cooperative communication. (RRTS1, RRTS2, RCTS), a procedure for transmitting a frame between a transmitting node, a receiving node, and an intermediate node using these control frames has been described.

Reference 5 (P. Liu, Z. Tao, S. Narayanan, T. Korakis, and SS Panwar, “CoopMAC: A cooperative MAC for wireless LANs,” IEEE JSAC, Vol. 25, No. 2, pp. 340- 353, 2007.) proposed the CoopMAC method, which is very similar to the rDCF method, but it is remarkable that the criterion for selecting intermediate nodes is neatly expressed mathematically.

See also reference 6 (K. Tan, Z. Wan, H. Zhu and J. Andrian, “CODE: Cooperative medium access for multi-rate wireless Ad Hoc network,” in Proc. Of IEEE SECOND, 2007.). It is an extension of the existing rDCF technique to obtain the reception diversity gain in the competitive phase. In the past, the procedure of performing a triangular handshake using a control frame was changed to a diamond-type handshake.

So far, the results of the study have been performed on the assumption that all errors occur due to collisions but no transmission errors due to poor radio channels in the channel competition phase. All the proposed methods compared the performance with the RBAR technique. . Meanwhile, Reference 7 (Jang Jaesin, “A Study on Cooperative MAC Protocol in Ad Hoc Network,” Journal of Korean Institute of Maritime Information and Communication Sciences, Vol. 13, No. 8, pp. 1561 ~ 1570, August 2009), Reference 8 ( Jang Jae Shin, “A Study on MAC Protocol for Cooperative Communication with Network Coding Function,” Journal of Korean Institute of Maritime Information and Communication Sciences, Vol. 13, No. 9, pp. 1819 ~ 1828, September 2009), We proposed a new MAC protocol for cooperative communication in an environment where not only errors but also transmission errors occur due to poor wireless channels.

First, in Ref. 7, the CO-MAC protocol was proposed and the performance evaluation was performed with the goal of achieving the reception diversity effect in the channel competition stage and achieving the same level of complexity as rDCF. In Reference 8, we proposed the NC-MAC protocol, which combines the MAC protocol and the network coding concept, and performed the performance evaluation, and showed that the performance increases beyond the network coding gain compared to the rDCF scheme.

However, even with the above-described prior art, the problem of transmission error due to channel contention and excessive system throughput in a poor wireless channel environment still needs to be improved.

An object of the present invention is to provide a transmitter, a relay, a receiver, a frame transmission method, a relay method, and a reception method based on a MAC protocol for cooperative communication, which is resistant to channel errors.

In order to achieve the above object, a transmission apparatus for transmitting a frame to a counterpart node through an intermediate node according to an embodiment of the present invention includes a data transceiver for transmitting and receiving a frame and a threshold time for determining whether to transmit the frame. A counting timer, a sensing unit detecting whether the intermediate node transmits a data frame to the counterpart node, and a first threshold time counting by the timer after transmitting the data frame to the intermediate node If the data frame transmission is not detected by the detector until the end, the data frame transmission is determined to fail and recounts a predetermined multiple of the first threshold time to retransmit the data frame to the intermediate node. It includes a control unit for controlling.

Meanwhile, the relay apparatus for transmitting a frame received from a transmitting node to a counterpart node according to an embodiment of the present invention may include a data transceiver for transmitting and receiving a frame, a timer counting a threshold time for determining whether the frame is transmitted, A detection unit for detecting whether the opposite node transmits an ACK frame to the transmitting node, a second threshold that transmits the data frame received from the transmitting node to the counterpart node, and is counted by the timer after the data frame is delivered. If the ACK frame transmission is not detected by the detection unit before the time expires, it is determined that the data frame transmission has failed, and the data frame is retransmitted to the counterpart node by recounting a predetermined multiple of the second threshold time. It includes a control unit for controlling to.

The detection unit may detect whether the counterpart node transmits a cooperative clear to send (CCTS) frame to the transmitting node before the third threshold time counted by the timer, and the controller receives the received information from the transmitting node. If the frame is a cooperative request to send (CRTS) control frame, transmit an acknowledgment RTS (ARTS) frame to the counterpart node, and if the CCTS frame transmission is not detected by the detector after transmitting the ARTS frame, the ARTS frame After determining that the transmission has failed, the ARTS frame may be retransmitted to the counterpart node by recounting a time of a predetermined multiple of the third threshold time.

On the other hand, the receiving apparatus for receiving a frame from the transmitting node through the intermediate node according to an embodiment of the present invention, the data transmitting and receiving unit for transmitting and receiving the frame, a timer for counting a threshold time for determining whether the frame, the transmission A detector for detecting whether a node transmits a data frame to the intermediate node, and if the received frame is an ARTS frame, transmitting a CCTS frame to the transmitting node and counting by the timer after transmitting the CCTS frame If the CCTS frame transmission is not detected by the sensing unit before the end of the threshold time, it is determined that the CCTS frame transmission has failed, and the CCTS frame is transmitted to the transmitting node by recounting a predetermined multiple of the fourth threshold time. It includes a control unit for controlling to retransmit.

On the other hand, the frame transmission method of the transmitting device for transmitting the frame to the counterpart node through the intermediate node according to an embodiment of the present invention, the step of transmitting the data frame to the intermediate node, for determining whether to transmit the data frame Counting a first threshold time, detecting whether the intermediate node transmits the data frame from the intermediate node until the end of the first threshold time, and if the data frame transmission is not detected, Determining that it has failed and resending the data frame to the intermediate node by recounting a time of a predetermined multiple of the first threshold time.

In addition, the frame transmission method of the relay apparatus for transmitting a frame received from the transmitting node to the counter node according to an embodiment of the present invention, determining whether the frame received from the transmitting node is a data frame or a CRTS control frame, Transmitting the data frame to the counterpart node if the received frame is a data frame, and transmitting an ARTS frame to the counterpart node if the frame received from the transmitting node is a CRTS control frame, and determining whether to transmit the frame. Counting a second threshold time for; detecting whether the counterpart node transmits an ACK frame for the data frame or a CCTS frame for the ARTS frame to the transmitting node before the second threshold time ends; ACK frame or the CCTS frame transmission is not detected And determining that the data frame or the ARTS frame transmission has failed, and retransmitting the corresponding data frame or ARTS frame to the counterpart node by recounting a time of a predetermined multiple of the second threshold time.

In addition, the frame receiving method of the receiving apparatus for receiving a frame from a transmitting node through the intermediate node according to an embodiment of the present invention, determining whether the received frame is a data frame or ARTS frame, the received frame is a data frame In case of the step of transmitting an ACK frame to the transmitting node, if the received frame is an ARTS frame transmitting a CCTS frame to the transmitting node, counting a third threshold time for determining whether the frame transmission, Detecting whether the transmitting node transmits a data frame to the intermediate node before a third threshold time expires; if the data frame transmission is not detected, determining that the CCTS frame transmission has failed and the third threshold Recount the time of a predetermined multiple of time to the transmitting node And a step of retransmitting a frame group CCTS.

On the other hand, in a frame transmission and reception method of a communication system including a transmitting node, an intermediate node and a counterpart node according to an embodiment of the present invention, the transmitting node transmits a CRTS control frame to the intermediate node and receives a CCTS frame from the counterpart node. The transmitting node receiving the CCTS frame transmits the data frame to the intermediate node, and counts a first threshold time for determining whether to transmit the data frame, wherein the transmitting node counts the first threshold time. Detecting whether or not the intermediate node transmits the data frame to the counterpart node before termination; determining that the data frame transmission has failed when the data frame transmission is not detected; and presetting the first threshold time Recount the number of times to present the data to the intermediate node. Retransmitting that.

The method may further include determining, by the intermediate node, whether the frame received from the transmitting node is a data frame or a CRTS control frame, if the received frame is a data frame, forwarding the data frame to the counterpart node and receiving from the transmitting node. Transmitting an ARTS frame to the counterpart node if a frame is a CRTS control frame, counting a second threshold time for determining whether to transmit the frame, or transmitting the node at the counterpart node before the second threshold time expires Detecting whether the ACK frame for the data frame or the CCTS frame for the ARTS frame is transmitted; if the transmission of the ACK frame or the CCTS frame is not detected, the transmission of the data frame or the ARTS frame has failed And the second threshold The method may further include retransmitting the corresponding data frame or ARTS frame to the counterpart node by recounting a time of a predetermined multiple of the time.

The method may further include determining whether the frame received from the intermediate node is a data frame or an ARTS frame, and when the received frame is a data frame, transmits an ACK frame to the transmitting node, and the received frame is an ARTS frame. Is a step of transmitting a CCTS frame to the transmitting node, counting a third threshold time for determining whether the frame is transmitted, and transmitting the data frame from the transmitting node to the intermediate node before the third threshold time ends. Detecting whether the CCTS frame transmission has failed and recounting a predetermined multiple of a time of the third threshold time, and transmitting the CCTS frame to the transmitting node. Retransmitting.

Accordingly, transmission errors due to channel contention can be improved, and system throughput can be improved in a poor wireless channel environment.

1 is a sequence diagram for explaining the overall operation procedure according to the MAC protocol for cooperative communication according to the present invention.
2 is a block diagram illustrating a configuration of a transmitting apparatus according to an embodiment of the present invention.
3 is a block diagram showing a configuration of a relay apparatus according to an embodiment of the present invention.
4 is a block diagram illustrating a configuration of a receiving apparatus according to an embodiment of the present invention.
5 is a flowchart illustrating a procedure performed by a transmitting node according to an embodiment of the present invention.
6 is a flowchart illustrating a procedure performed by an intermediate node according to an embodiment of the present invention.
7 is a flowchart illustrating a procedure performed by a receiving node according to an embodiment of the present invention.
8 to 11 are diagrams for explaining the performance of the RCO-MAC protocol according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the present invention.

1 is a sequence diagram for explaining the overall operation procedure according to the MAC protocol for cooperative communication according to the present invention.

RCO-MAC (reliable cooperative MAC) protocol according to the present invention can be designed based on the existing DCF technique.

Recently, the concept of cooperative communications has been studied as a method for improving wireless communication quality. Cooperative communication is a transmission path between a transmitting node and an intermediate node, and an intermediate node and a counterpart node using an intermediate node located between two nodes in a transmission path when the channel environment between two nodes rapidly deteriorates in an environment using a link adaptation. A communication method that improves quality (Ref. 9: A. Nosratinia, TE Hunter, and A. Hedayat, “Cooperative communication in wireless networks,” IEEE Commun. Mag., Vol. 42, No. 10, pp. 74- 89, Oct. 2004.).

The MAC protocol for cooperative communication corresponds to the data link layer, which is the second layer based on the OSI communication model. Until now, the IEEE 802.11 DCF protocol, which is a wireless LAN protocol (Ref. 10: IEEE Std 802.11-1997, Part 11: Wireless LAN medium access) It is based on the control (MAC) and physical layer (PHY) specifications, June 1997.), so there is no change from the network layer, thus providing transparent data transmission and reception.

The MAC protocol for cooperative communication shown in FIG. 1 has been proposed based on the concept that, in case of frequent transmission errors, it is advantageous in terms of system performance to directly perform retransmission of the old frame. In addition, it is designed to cope with transmission error by using retransmission function as efficiently as possible in each node.

Hereinafter, in order to describe the configuration of a transmitting node, a counterpart node (or a destination node), an intermediate node (or an intermediate node), and procedures to be performed in each node in order to operate according to the RCO-MAC scheme proposed by the present invention, it will be described in detail. do.

2 is a block diagram illustrating a configuration of a transmitting apparatus according to an embodiment of the present invention.

The transmitting device 100 according to FIG. 2 may correspond to the transmitting node S shown in FIG. 1.

The transmission apparatus 100 shown in FIG. 2 includes a data transceiver 110, a timer driver 120, a detector 130, and a controller 140.

The data transceiver 110 functions to transmit and receive a frame according to the RCO-MAC technique according to the present invention.

The timer 120 counts a threshold time for determining whether a frame is transmitted. In detail, the timer 120 may count a threshold time for determining whether to transmit a data frame and a threshold time for determining whether to transmit a control frame such as a cooperative request to send (CRTS).

The detector 130 may detect whether the intermediate node transmits a data frame to the counterpart node during the first threshold time counted by the timer 120. The first threshold time may be a short interframe space (SIFS).

The controller 140 controls to transmit a data frame for transmission to the transmitting node to the intermediate node.

In addition, the controller 140 determines that the data frame transmission from the intermediate node to the transmitting node has failed when the data frame transmission from the intermediate node to the transmitting node is not detected during the first threshold time counted by the timer 120. You can control to retransmit the data frame. In the case of such a retransmission, it may be determined whether a data frame is transmitted from the intermediate node to the transmitting node during a predetermined multiple of the first threshold time. For example, the retransmission threshold time may be 2-SIFS.

In addition, the controller 140 may transmit a cooperative request to send (CRTS) control frame to the intermediate node before transmitting the data frame to the intermediate node. In this case, the controller 140 may control the timer 120 to count a threshold time for determining whether to transmit a CRTS control frame, and in the case of receiving a cooperative clear to send (CCTS) frame from the transmitting node during the threshold time, Data frames can be sent to the node.

On the other hand, if the control unit 140 does not receive the CCTS frame during the threshold time for determining whether to transmit the CRTS control frame, it may retransmit the CRTS frame to the intermediate node.

Other details will be described later with reference to FIG. 5.

3 is a block diagram showing a configuration of a relay apparatus according to an embodiment of the present invention.

The relay device 200 according to FIG. 3 may correspond to the intermediate node H1 or H2 shown in FIG. 1.

The transmitter 200 shown in FIG. 3 includes a data transceiver 210, a timer driver 220, a detector 230, and a controller 240.

The data transceiver 210 functions to transmit and receive a frame according to the RCO-MAC technique according to the present invention.

The timer 220 counts a threshold time for determining whether to transmit a frame. In detail, the timer 220 may count a threshold time for determining whether to transmit a data frame or whether a control frame such as an acknowledgment RTS (RTS) is transmitted. In this case, the threshold time may be a short interframe space (SIFS).

The detector 230 may detect whether the counterpart node transmits an ACK frame for the data frame to the transmitting node during the threshold time counted by the timer 220. Accordingly, the relay device 200 may determine whether the data frame transmitted by the relay device 200 is successfully transmitted to the counterpart node. In this case, the threshold time may be a short interframe space (SIFS).

In addition, the detector 230 may detect whether the counterpart node transmits the CCTS frame to the transmitting node during the threshold time counted by the timer 220. Accordingly, the relay device 200 may determine whether an acknowledgment RTS (RTS) frame transmitted by the relay device 200 is successfully transmitted to the counterpart node. In this case, the threshold time may be a short interframe space (SIFS).

If the frame received from the transmitting node is a data frame, the control unit 240 controls the data frame to be transmitted to the counterpart node. If the frame received from the transmitting node is a CRTS control frame, the control unit 240 sends an ARTS (acknowledge RTS) to the counterpart node. It can be controlled to transmit the frame.

In addition, after transmitting the data frame to the counterpart node, if the ACK frame transmission is not detected by the detector 230 during the threshold time counted by the timer 220, the data frame transmission has failed. The determination may be performed, and the corresponding data frame may be retransmitted to the counterpart node by recounting the time of the predetermined multiple of the threshold time. In this case, the threshold time may be a short interframe space (SIFS), and the threshold time for retransmission may be 2-SIFS.

In addition, the controller 240 transmits an acknowledgment RTS (ARTS) frame to the counterpart node, and if the CCTS frame transmission is not detected by the detector 230 during the threshold time counted by the timer 220, the ARTS frame. After determining that the transmission has failed, the ARTS frame may be retransmitted to the counterpart node by recounting a time of a predetermined multiple of the threshold time. In this case, the threshold time may be a short interframe space (SIFS), and the threshold time for retransmission may be 2-SIFS.

Other details will be described later in the description of FIG. 6.

4 is a block diagram illustrating a configuration of a receiving apparatus according to an embodiment of the present invention.

The receiving device 300 according to FIG. 4 may correspond to the counterpart node D shown in FIG. 4.

The reception device 300 as shown in FIG. 4 includes a data transceiver 310, a timer 320, a detector 330, and a controller 340.

The data transceiver 310 functions to transmit and receive a frame according to the RCO-MAC technique according to the present invention.

The timer 320 functions to count a threshold time for determining whether a frame is transmitted. In detail, the timer 220 may count a threshold time for determining whether to transmit a CCTS frame. That is, the threshold time may be a time for determining whether the CCTS frame is successfully transmitted to the transmitting node when the counter node receiving the ACTS frame from the intermediate node transmits the CCTS frame to the transmitting node.

The detector 330 may detect whether the transmitting node transmits the data frame to the intermediate node during the threshold time counted by the timer 320 after transmitting the CCTS frame to the transmitting node. In this case, the threshold time may be a short interframe space (SIFS). Accordingly, the receiving device 200 may determine whether the CCTS frame transmitted by the receiving device 200 is successfully transmitted to the transmitting node.

If the received frame is an ARTS frame, the controller 340 transmits a CCTS frame to the transmitting node.

In addition, the controller 340 determines that the transmission of the CCTS frame has failed when the transmission node does not detect the transmission of the data frame from the transmitting node to the intermediate node before the threshold time counted by the timer 320 after transmitting the CCTS frame to the transmitting node. The CCTS frame may be retransmitted by recounting a threshold time of a preset multiple of the threshold time. In this case, the threshold time for determining whether to transmit the CCTS frame may be SIFS, and the threshold time for retransmission may be 2-SIFS.

Alternatively, when the data frame is not received, the controller 340 determines that the CCTS frame transmission has failed, and may retransmit the CCTS frame to the transmitting node.

In addition, the controller 340 may determine that the received frame is a data frame when the received frame is not an ARTS frame, and thus may directly transmit the ACK frame to the transmitting node without passing through the intermediate node.

Meanwhile, since the control unit 340 cannot receive a response from the transmitting node after transmitting the ACK frame, the control unit 340 does not basically retransmit the ACK frame. However, if a transmission error occurs frequently due to radio channel deterioration, the counterpart node may unconditionally transmit two or more ACK frames to the transmitting node to improve transmission reliability.

5 is a flowchart illustrating a procedure performed by a transmitting node according to an embodiment of the present invention.

In an embodiment of the present disclosure, since the transmitting node corresponds to the transmitting apparatus 100 shown in FIG. 2, the procedure illustrated in FIG. 5 may be a procedure performed by the transmitting apparatus 100 illustrated in FIG. 2.

According to FIG. 5, when the transmitting node receives a packet to be transmitted from a higher layer (S501), the transmitting node starts channel contention based on the CSMA / CA mechanism of the existing DCF scheme. In this case, RTS / CTS clearing technique is used for better communication environment. We also use some back-off to avoid collisions.

Accordingly, first, a contention window (CW) value is initialized and a random value is generated (S502). Thereafter, a cooperative RTS (CRTS) control frame is transmitted in the corresponding empty slot (S503).

Subsequently, the retransmission timer 1 is driven in preparation for a transmission error occurring in the transmitted CRTS frame (S504). Here, the retransmission timer 1 value may be set to a maximum time value required to successfully receive a CCTS frame and may be set to a time required to receive an ACK frame in a conventional DCF.

Thereafter, it is determined whether a cooperative CTS (CCTS) frame is received until the retransmission timer 1 ends (S505).

If the CCTS frame is not received until the retransmission timer 1 ends in step S505 (S505: N), the contention window value is doubled as in the conventional DCF scheme (S506), and then retransmission is performed (S503).

On the other hand, if the CCTS frame is received until the retransmission timer 1 is terminated in step S505 (S505: Y), the timer 1 is terminated and prepares to transmit the DATA frame. Here, after transmitting the DATA frame, when recognizing that the DATA frame transmission has failed, retransmit the DATA frame. In this case, the success or failure of transmitting the DATA frame can be known by detecting whether the intermediate node transmits the DATA frame to the counterpart node after the short interframe space (SIFS) time. In this case, the SIFS has a characteristic that a transmission right can be obtained earlier than other frame intervals with a short frame interval used for transmitting a frame having the highest priority, such as an RTS / CTS frame or an ACK frame.

On the other hand, the DATA frame can be retransmitted up to N times, using the variable n to manage the number of retransmissions, and initializes this value to 0 before transmitting the DATA frame (S507).

Subsequently, after transmitting the DATA frame to the intermediate node, the variable n value is increased by 1 (S508), and timers 2 and 3 are respectively driven to recover transmission errors by the retransmission procedure (S509). Here, timer 2 is for managing a DATA frame retransmission procedure, and timer 3 may be used for managing a procedure for retransmission using a CRTS frame when an ACK frame is not received from a counterpart node until a predetermined time. .

That is, after transmitting the DATA frame, the middle node detects whether the intermediate node transmits the DATA frame to the counterpart node for twice the SIFS time (value set in the timer 2) (S510), and if it does not detect the transmission in step S510 (S510) : N) It is determined that a transmission error has occurred, and retransmits the DATA frame (S508). However, in this case, it may be determined whether the number of data frame transmissions is less than N preset times (S512), and the data frame may be retransmitted only when the number of data frame transmissions is less than N preset times (S512: Y). If the number of data frame transmissions is greater than or equal to N preset times (S512: N), the contention window may be doubled (S513), and then the CRTS frame may be retransmitted (S503) to solve the transmission error problem.

On the other hand, if the transmission is detected in step S510 (S510: Y), since the intermediate node has transmitted the data frame to the counterpart node, it is determined whether the ACK frame is received before timer 3 from the counterpart node (S511).

If the ACK frame is received before the timer 3 (S511: Y), the data frame transmission procedure is completed.

However, when the ACK frame is not received before the timer 3 (S511: N), the contention window may be doubled (S513), and the transmission of the CRTS frame may be retransmitted (S503) to solve the transmission error problem.

On the other hand, the value set when driving the three timers (timers 1, 2, 3) described above is as shown in equations (1) to (3). Herein, terms indicating frame names (for example, DATA, ARTS, and CCTS) mean a transmission time required for transmitting the frame at the basic transmission rate.

6 is a flowchart illustrating a procedure performed by an intermediate node according to an embodiment of the present invention.

In an embodiment of the present disclosure, since the intermediate node corresponds to the relay apparatus 200 illustrated in FIG. 3, the procedure illustrated in FIG. 6 may be a procedure performed by the relay apparatus 200 illustrated in FIG. 3.

According to FIG. 6, when the intermediate node receives a frame from a transmitting node (S601), first, n sets a value of 0 to manage a retransmission procedure (S602).

Next, it is determined whether the received frame is a CRTS frame (S603).

If it is determined in step S603 that the CRTS frame has been received (S603: Y), after transmitting an ARTS (acknowledge RTS) frame to the counterpart node, the value n is increased (S604).

Subsequently, timer 4 is driven to manage the retransmission procedure according to the transmission error (S605).

It is checked whether the counterpart node transmits the CCTS frame before the timer 4 expires (S606).

If it is confirmed that the counterpart node transmits the CCTS frame to the transmitting node before the timer 4 expires (S606: Y), the role of the intermediate node for the frame is terminated.

On the other hand, if it is not confirmed that the counterpart node transmits the CCTS frame to the transmitting node before the timer 4 expires (S606: N), similarly to the method shown in FIG. In operation S607, when the number of frame transmissions is less than N preset times (S607: Y), a retransmission procedure is performed (S604).

However, when the number of frame transmissions is less than N times, the procedure for the frame may be completed and the procedure for the new frame may be performed.

On the other hand, if it is determined in step S603 that a data frame other than a CRTS frame is received (S603: N), the received data frame is transmitted to the counterpart node, and then n value is increased by 1 (S608).

Also in this case, as in step S605, timer 5 is driven to manage the retransmission procedure according to the transmission error (S609). Here, the timer 5 may be the same value as the timer 4, but is referred to as timer 5 for convenience of description.

Subsequently, before the timer 5 expires, the counter node confirms that the ACK frame is transmitted to the transmitting node (S610).

If it is confirmed that the counterpart node transmits the ACK frame to the transmitting node before the timer 5 expires (S610: Y), the role of the intermediate node for the corresponding frame ends.

On the other hand, if it is not confirmed that the counterpart node transmits the ACK frame to the transmitting node before the timer 5 expires (S610: N), similarly to the method shown in FIG. In operation S611, when the number of frame transmissions is less than N preset times (S611: Y), a retransmission procedure is performed (S608).

However, when the number of frame transmissions is more than N times, the procedure for the frame may be completed and the procedure for the new frame may be performed.

On the other hand, the same method as the method proposed in the references 4, 5, 6 mentioned above can be used for selecting the intermediate node, so a detailed description thereof will be omitted.

7 is a flowchart illustrating a procedure performed by a receiving node according to an embodiment of the present invention.

In an embodiment of the present disclosure, since the receiving node corresponds to the receiving device 300 shown in FIG. 4, the procedure shown in FIG. 7 may be a procedure performed by the receiving device 300 shown in FIG. 4.

According to FIG. 7, when the counterpart node receives a frame from the intermediate node (S701), first, the n variable value is set to 0 to manage the retransmission procedure (S702).

Subsequently, it is determined whether the frame received from the intermediate node is an ARTS frame (S703).

If it is determined in step S703 that the received frame is an ARTS frame (S703: Y), after transmitting the CCTS frame directly to the transmitting node, n value is increased by 1 (S704). Subsequently, timer 6 is driven to manage the CCTS frame retransmission procedure.

Subsequently, it is checked whether a DATA frame is received before the timer 6 ends (S706).

If the counterpart node receives the DATA frame before timer 6 expires (S706: Y), the relevant procedure is terminated because the corresponding CCTS frame is successfully transmitted.

However, if the counterpart node does not receive the DATA frame before timer 6 expires (S706: N), whether the number of frame transmissions is less than the preset N times, similar to the ARTS frame or DATA frame retransmission management procedure in the intermediate node. In operation S707, when the number of frame transmissions is less than N preset times (S707: Y), a retransmission procedure is performed (S704). However, in the case where the number of frame transmissions is N or more times (S707: N), the procedure for the frame may be completed and the procedure for the new frame may be performed.

Meanwhile, if the frame received in step S703 is not an ARTS frame, it is a DATA frame (S703: N), so that an ACK frame is transmitted to the transmitting node (S708), and the procedure for the corresponding data frame is completed. In this case, the ACK frame is not retransmitted basically because the ACK frame cannot be received after transmitting the ACK frame. However, if a transmission error occurs frequently due to radio channel deterioration, the counterpart node may unconditionally transmit two or more ACK frames to the transmitting node to improve transmission reliability.

8 to 11 are diagrams for explaining the performance of the RCO-MAC protocol according to an embodiment of the present invention.

8 to 11 show the results of performance evaluation through computer simulation.

Computer simulations used the SMPL tool (M. H. MacDougall, Simulating computer systems: Techniques and tools, The MIT Press, 1992.), and assumed that the data frames to be transmitted always had traffic saturation.

The system parameters used in this performance evaluation are shown in Table 1.

Here, R _sh means the transmission speed between the transmitting node (S) and the intermediate node (H), and the computer simulation was performed for 1000 seconds. The system performance and frame average delay time were used as the performance evaluation scale, and the system throughput was defined as the total amount of data transmitted successfully during the computer simulation and expressed in bps. The average frame delay time was defined as the time to wait for the transmission to be completed successfully from the moment of transmission attempt, excluding the queuing time. The queuing time in the buffer was excluded.

8 is a diagram comparing the system throughput performance of the conventional rDCF technique and the RCO-MAC technique according to the present invention.

The frame transmission error due to poor channel environment is considered to occur about 10% and the system throughput according to the change of the number of terminals in the transmission range is derived. It can be seen that the change in system throughput according to the change in the number of terminals is similar to the results shown in Refs. Compared to the rDCF method, the system throughput performance is improved by about 24% in the channel environment where frame transmission error is 10%. In the retransmission procedure performed at each node, it can be seen that there is no significant difference between the two retransmission times and the three retransmissions. In other words, in the retransmission environment of about 10%, it can be seen that the system performance can be greatly increased compared to the conventional method by retransmitting only two times in each node.

9 is a diagram illustrating a performance evaluation result in terms of average delay time.

First, if the number of terminals in the transmission range is relatively small, the difference is insignificant, but the proposed RCO-MAC technique is excellent. However, when the number of terminals is relatively large, the average delay time is slightly higher than that of the existing rDCF technique. This is because, in the case of a large number of terminals, system performance is more dependent on a collision occurring at the stage of channel competition using CRTS frames rather than a frame transmission error due to the deterioration of radio channels. After transmitting the CRTS and DATA frames, the average delay time increases because the setup time value of the retransmission timer operated by the transmitting node is set to a larger value than the rDCF scheme because of the retransmission procedure performed by each node. However, although excluded from the performance evaluation of the present invention, if the queuing time waiting in the buffer is considered, the overall system average delay time is expected to decrease. This is because the system throughput of the RCO-MAC technique is increased by 24% compared to the existing rDCF, and as the system throughput increases, the queuing delay time waited in the buffer decreases.

FIG. 10 is a diagram illustrating a comparison of system throughput according to a change in frame transmission error value due to poor channel environment after fixing the maximum number of retransmissions to three times in the proposed RCO-MAC protocol.

If there is no transmission error, it can be confirmed that the performance of up to 2.7 Mbps can be achieved when the number of transmitting nodes is about five. Also, the system performance decreases rapidly as the transmission error increases.

11 is a diagram illustrating average delay time performance according to a change in transmission error.

Based on the numerical results presented so far, it is appropriate to increase the maximum value N of the number of retransmissions performed at each node in order to improve the system performance reduction problem caused by the frame transmission error caused by the poor channel environment. You can see that this is not the case. Increasing the value of N will improve system throughput, but increases the average latency, which cannot accommodate traffic with real-time characteristics.

As described above, according to the MAC protocol for cooperative communication, according to the MAC protocol for cooperative communication, it is advantageously applied in terms of system performance when a transmission error frequently occurs because a node transmitting the frame directly retransmits. Can be. In addition, each node can respond to transmission errors by using the retransmission function as efficiently as possible.

Accordingly, transmission errors due to channel contention can be improved, and system throughput can be improved in a poor wireless channel environment.

In addition, although the preferred embodiment of the present invention has been shown and described above, the present invention is not limited to the above-described specific embodiment, the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

100: transmission device (transmission node) 110: data transmission and reception unit
120: timer 130: detector
140: control unit 200: relay device (intermediate node)
210: data transceiver 220: timer
230: detection unit 240: control unit
300: receiving device (relative node) 310: data transmission and reception unit
320: timer 330: detector
340: control unit

Claims (10)

In the transmitting device for transmitting a frame to the counterpart node through the intermediate node,
A data transceiver for transmitting and receiving a frame;
A timer counting a threshold time for determining whether to transmit a frame;
A detector configured to detect whether the intermediate node transmits a data frame to the counterpart node; And
If the data frame transmission is transmitted to the intermediate node and the data frame transmission is not detected by the detection unit until the first threshold time counted by the timer after the data frame transmission, the data frame transmission has failed. And a control unit configured to recount the time of a predetermined multiple of the first threshold time to retransmit the data frame to the intermediate node. A relay apparatus for transmitting a frame received from a transmitting node to a counterpart node,
A data transceiver for transmitting and receiving a frame;
A timer counting a threshold time for determining whether to transmit a frame;
A detector for detecting whether the counterpart node transmits an ACK frame to the transmitting node;
The data frame received from the transmitting node to the counterpart node, and if the ACK frame transmission is not detected by the sensing unit until a second threshold time counted by the timer after the data frame is delivered, the data; And a controller which determines that the frame transmission has failed and controls to retransmit the corresponding data frame to the counterpart node by recounting a time of a preset multiple of the second threshold time. The method of claim 2,
The detection unit,
Detects whether the counterpart node transmits a cooperative clear to send (CCTS) frame to the transmitting node before a third threshold time counted by the timer,
The control unit,
When the frame received from the transmitting node is a cooperative request to send (CRTS) control frame, an acknowledgment RTS (ARTS) frame is transmitted to the counterpart node, and the CCTS frame transmission is detected by the detector after the ARTS frame is transmitted. If not, it is determined that the ARTS frame transmission has failed, and re-transmits the ARTS frame to the counterpart node by recounting the time of a predetermined multiple of the third threshold time. A receiving apparatus for receiving a frame from a transmitting node through an intermediate node,
A data transceiver for transmitting and receiving a frame;
A timer counting a threshold time for determining whether to transmit a frame;
A detector configured to detect whether the transmitting node transmits a data frame to the intermediate node;
When the received frame is an ARTS frame, when the CCTS frame is transmitted to the transmitting node, and the CCTS frame transmission is not detected by the detector until the fourth threshold time counted by the timer after the CCTS frame is transmitted. And a controller which determines that the CCTS frame transmission has failed and controls to retransmit the CCTS frame to the transmitting node by recounting a time of a preset multiple of the fourth threshold time. In the frame transmission method of the transmitting device for transmitting a frame to the counterpart node through the intermediate node,
Transmitting the data frame to the intermediate node;
Counting a first threshold time for determining whether to transmit the data frame;
Detecting whether the intermediate node transmits the data frame to the counterpart node before the first threshold time expires;
Determining that the data frame transmission has failed when the data frame transmission is not detected; And
And retransmitting the data frame to the intermediate node by recounting a time of a predetermined multiple of the first threshold time. In the frame forwarding method of the relay device for transmitting the frame received from the transmitting node to the counterpart node,
Determining whether the frame received from the transmitting node is a data frame or a CRTS control frame;
Transmitting the data frame to the counterpart node when the received frame is a data frame, and transmitting an ARTS frame to the counterpart node when the frame received from the transmitting node is a CRTS control frame;
Counting a second threshold time for determining whether to transmit the frame;
Detecting whether the counterpart node transmits an ACK frame for the data frame or a CCTS frame for the ARTS frame to the transmitting node before the second threshold time expires;
Determining that the data frame or the ARTS frame transmission has failed when the ACK frame or the CCTS frame transmission is not detected; And
And retransmitting a corresponding data frame or ARTS frame to the counterpart node by recounting a time of a predetermined multiple of the second threshold time. In the frame receiving method of a receiving apparatus for receiving a frame from a transmitting node through an intermediate node,
Determining whether the received frame is a data frame or an ARTS frame;
Transmitting an ACK frame to the transmitting node when the received frame is a data frame, and transmitting a CCTS frame to the transmitting node when the received frame is an ARTS frame;
Counting a third threshold time for determining whether to transmit the frame;
Detecting whether the transmitting node transmits a data frame to the intermediate node before the third threshold time expires;
Determining that the CCTS frame transmission has failed when the data frame transmission is not detected; And
And retransmitting the CCTS frame to the transmitting node by recounting a time of a predetermined multiple of the third threshold time. In the frame transmission and reception method of a communication system including a transmitting node, an intermediate node and a partner node,
A transmitting node transmitting a CRTS control frame to an intermediate node and receiving a CCTS frame from a counterpart node;
Counting a first threshold time for the transmitting node receiving the CCTS frame to transmit the data frame to the intermediate node and determining whether to transmit the data frame;
Detecting whether the transmitting node transmits the data frame from the intermediate node to the counterpart node before the first threshold time expires;
Determining that the data frame transmission has failed when the data frame transmission is not detected; And
And retransmitting the data frame to the intermediate node by recounting a time of a predetermined multiple of the first threshold time. The method of claim 8,
Determining, by the intermediate node, whether a frame received from the transmitting node is a data frame or a CRTS control frame;
Transmitting the data frame to the counterpart node when the received frame is a data frame, and transmitting an ARTS frame to the counterpart node when the frame received from the transmitting node is a CRTS control frame;
Counting a second threshold time for determining whether to transmit the frame;
Detecting whether the counterpart node transmits an ACK frame for the data frame or a CCTS frame for the ARTS frame to the transmitting node before the second threshold time expires;
Determining that the data frame or the ARTS frame transmission has failed when the ACK frame or the CCTS frame transmission is not detected; And
And retransmitting a corresponding data frame or ARTS frame to the counterpart node by recounting a time of a predetermined multiple of the second threshold time. 10. The method of claim 9,
Determining, by the counterpart node, whether a frame received from the intermediate node is a data frame or an ARTS frame;
Transmitting an ACK frame to the transmitting node when the received frame is a data frame, and transmitting a CCTS frame to the transmitting node when the received frame is an ARTS frame;
Counting a third threshold time for determining whether to transmit the frame;
Detecting whether the transmitting node transmits a data frame to the intermediate node before the third threshold time expires;
Determining that the CCTS frame transmission has failed when the data frame transmission is not detected; And
And retransmitting the CCTS frame to the transmitting node by recounting a time of a predetermined multiple of the third threshold time.

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