KR101474727B1 - System for transmitting data - Google Patents

Abstract

A transmitting node and a receiving node capable of distinguishing deafness and collision that may occur when a transmission request message is transmitted from a transmitting node to a receiving node are disclosed. The disclosed transmitting node / receiving node has a plurality of channels, and by keeping the specific channel active, it is possible to transmit a transmission request message or transmit a receiving acknowledgment message even during data transmission.

Description

[0001] SYSTEM FOR TRANSMITTING DATA [0002]

The present invention relates to a data transmission system including a transmitting node and a receiving node, and more particularly, to a data transmission system including a transmitting node and a receiving node, and more particularly, (Hearing loss, deafness).

There is a growing demand for a technique for exchanging information and data between computers by connecting wirelessly connected computers and their peripheral devices, mobile phones, and home appliances.

Recently, a method of combining the RTS / CTS (Request to Send / Clear to Send) communication mechanism used in the 802.11 protocol and the technique of improving the data transmission efficiency by using a directional antenna in each device has been proposed.

In this method, if the transmitting node transmits an RTS message in all directions, the receiving node fixes the beam pattern of the directional antenna in the direction in which the RTS message is received, and blocks the beam pattern in the other direction. The receiving node communicates with the transmitting node using a fixed beam pattern. Therefore, even if the RTS message is transmitted from another transmitting node in the other direction, the receiving node can ignore the RTS message and perform communication with the transmitting node that transmitted the first RTS message.

The following embodiments are intended to distinguish between collision and deafness in a system that performs a plurality of inter-node communications using a directional antenna.

The following embodiments aim at reducing the overhead of the communication system by stopping the transmission of the transmission request message when the receiving node is in a state of hearing impairment.

According to an exemplary embodiment of the present invention, there is provided a transmitting node for transmitting a transmission request message for data using a first channel to a receiving node and transmitting the transmission request message to the receiving node using a second channel, A receiving unit for receiving the acknowledgment message for the transmission request message using the first channel or the second channel or receiving the acknowledgment message for the transmission request message using the first channel or the second channel, And a controller for determining whether the transmission request message conflicts with the second transmission request message transmitted to the receiving node by the second transmitting node or whether the receiving node is communicating with the third transmitting node, Lt; / RTI >

Here, when the reception confirmation message is not received using the first channel and the reception confirmation message is received using the second channel, the control unit determines that the reception node is communicating with the third transmission node It can be judged.

If the reception confirmation message is not received using the first channel and the reception confirmation message is not received using the second channel, the control unit may determine that the transmission request message has collided have.

Also, the transmitting unit may retransmit the transmission request message.

Here, when receiving the acknowledgment message using the first channel and receiving the acknowledgment message using the second channel, the transmitting unit transmits data using the first channel to the receiving node Lt; / RTI >

The acknowledgment message may be transmitted using a beam pattern having a directivity.

Here, the beam pattern may be activated only in the direction of the transmission node with respect to the first channel, and may be kept active in all directions with respect to the second channel.

According to another exemplary embodiment, there is provided an apparatus for transmitting data, comprising: a receiver for receiving a transmission request message for data using a first channel and a second channel, or a second channel; And a transmitting unit for transmitting an acknowledgment message for the transmission request message to the transmitting node using the second channel.

Here, when the transmission request message is received using the first channel and the transmission request message is received using the second channel, the transmitter transmits the reception acknowledgment message using the first channel And transmit the acknowledgment message using the second channel.

When the transmission request message is not received using the first channel and the transmission request message is received using the second channel, the transmitter transmits the reception acknowledgment message using the second channel Lt; / RTI >

Also, the transmitting unit may transmit the acknowledgment message using a beam pattern having a directivity.

Here, the transmitter may block the beam pattern after the transmission of the acknowledgment message in the direction of the transmission node, and may block the beam pattern in the other direction.

According to another exemplary embodiment, there is provided a method of operating a transmission node, the method comprising: transmitting a transmission request message for data using a first channel to a receiving node; Receiving the acknowledgment message for the transmission request message using the first channel and the second channel or receiving the acknowledgment message using the second channel and transmitting the acknowledgment message to the first channel or the second channel, It is determined whether the transmission request message conflicts with the second transmission request message transmitted to the receiving node by the second transmitting node or whether the receiving node is communicating with the third transmitting node, The method comprising the steps of:

Here, when receiving the acknowledgment message using the first channel and receiving the acknowledgment message using the second channel, the step of determining may include determining that the receiving node transmits the acknowledgment message to the third transmission node It can be determined that communication is in progress.

When the reception confirmation message is not received using the first channel and the reception confirmation message is not received using the second channel, the determining step determines that the transmission request message has collided can do.

The method may further include retransmitting the transmission request message.

Receiving the acknowledgment message using the first channel and transmitting the data to the receiving node using the first channel when the acknowledgment message is received using the second channel; As shown in FIG.

The acknowledgment message may be transmitted using a beam pattern having directivity.

Also, the beam pattern may be activated only in the direction of the transmission node with respect to the first channel, and the active state may be maintained in all directions with respect to the second channel.

According to another exemplary embodiment, there is provided a method for transmitting data, comprising: receiving a transmission request message for data using a first channel and a second channel, or the second channel, And transmitting an acknowledgment message for the transmission request message to the transmitting node using the second channel.

Here, when receiving the transmission request message using the first channel and receiving the transmission request message using the second channel, the transmitting step transmits the acknowledgment message using the first channel, And transmit the acknowledgment message using the second channel.

When the transmission request message is not received using the first channel and the transmission request message is received using the second channel, the transmitting step transmits the reception confirmation message using the second channel, Message can be transmitted.

Also, the transmitting step may transmit the acknowledgment message using a beam pattern having directivity.

Here, the transmitting step may fix the beam pattern in the direction of the transmission node after the transmission of the acknowledgment message, and block the beam pattern in the other direction.

According to the following embodiments, it is possible to distinguish collision and deafness in a system that performs a plurality of inter-node communication using a directional antenna.

The following embodiments can reduce the overhead of the communication system by stopping the transmission of the transmission request message if the receiving node is deaf.

FIG. 1 is a diagram illustrating a deafness problem that may occur when a plurality of nodes are mixed.
2 is a diagram showing a concept of distinguishing a hearing loss from a collision according to an exemplary embodiment.
3 is a block diagram illustrating a structure of a transmission node according to an exemplary embodiment.
4 is a block diagram illustrating the structure of a receiving node according to an exemplary embodiment.
5 is a flowchart illustrating a method of operating a transmission node according to an exemplary embodiment.
6 is a flowchart illustrating a method of operating a receiving node according to an exemplary embodiment.

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

FIG. 1 is a diagram illustrating a deafness problem that may occur when a plurality of nodes are mixed.

The plurality of nodes 110, 120, 130, and 140 shown in FIG. 1 include directional antennas to transmit and receive data. The plurality of nodes 110, 120, 130 and 140 may divide the space into a plurality of sectors 111, 112, 113, 114, 121, 122, 123, 124, 131, 132, 133, 134, 141, , 144). According to one aspect, each of the nodes 110, 120, 130, and 140 includes a plurality of sectors 111, 112, 113, 114, 121, 122, 123, 124, 131, 132, 133, 134, 141, 142, 143, and 144, respectively.

1 shows a case in which node S 110 communicates with node D 120. In Fig. The node S 110 to which data is to be transmitted transmits a data request to send (DRTS) in the direction of each of the sectors 111, 112, 113 and 114 of the node S 110. The node S 110 sequentially activates the beam patterns corresponding to the sectors 111, 112, 113 and 114 to sequentially transmit the transmission request message in the directions of the sectors 111, 112, 113 and 114 As shown in FIG.

The node D 120 may receive the transmission request message transmitted by the node S 120 using the beam pattern corresponding to the sector 4 124. [ The node D 120 may fix the beam pattern of the directional antenna so as to correspond to the sector 4 (124) receiving the transmission request message. In addition, the node D 120 may block beam patterns corresponding to the other sectors 121, 122, and 123 to block beam patterns in other directions than the direction of the node S 110. When the beam pattern in the other direction is blocked, the node D 120 does not receive the signal transmitted from the other sectors 121, 122 and 123 and does not transmit the signal to the other sectors 121, 122 and 123 .

The node D 120 transmits an acknowledgment message corresponding to the transmission request message to the node S 110 using the beam pattern corresponding to the sector 124 in the direction of the node S 120.

The node S 110 receives the acknowledgment message using the beam pattern corresponding to the sector 112 in the direction of the node D 120. The node S 110 may block the beam pattern corresponding to the other sectors 111, 113 and 114 and block beam patterns other than the direction of the node D 120. When the beam pattern in the other direction is blocked, the node S 120 does not receive the signal transmitted from the other sectors 111, 113 and 114, and does not transmit the signal to the other sectors 111, 113 and 114 .

The node S 110 and the node D 120 block signal transmission in the other direction, and signal transmission is possible only for directions between each other. Therefore, the node S (110) and the node D (120) can efficiently transmit data without transmitting interference signals in other directions.

1, a node B 140 located between a node S 110 and a node D 120 may also receive a transmission request message transmitted from the node S 110. In the embodiment shown in FIG. The Node B 140 may block the beam pattern corresponding to the sector 144 in the direction of the node S 110, expecting data transmission between the node S 110 and the node D 120 to be performed.

Node B 140 may also receive an acknowledgment message sent from node D 120. [ The node B 140 may block the beam pattern corresponding to the sector 142 in the direction of the node D 120. [

When the node B 140 blocks the beam pattern corresponding to the sectors 142 and 144, it is not affected by the communication between the node S 110 and the node D 120.

The node A 130 may also receive a transmission request message transmitted from the node S 110. The node A 130 may expect to perform data transmission between the node S 110 and the node D 120 and may block the beam pattern corresponding to the sector 133 in the direction of the node S 110.

When the node B 140 attempts to transmit data to the node A 130, the node B 140 may transmit the transmission request message to the node A 130 using the unblocked beam pattern. 1, since the node A 130 is located in the direction corresponding to the sector 141, the node B 140 transmits the transmission request message to the node A 140 using the beam pattern corresponding to the sector 141 (130).

However, since the beam pattern corresponding to the sector 133 of the node A 130 is blocked, the node A 130 can not receive the transmission request message from the node B 140, I can not even send a message. Accordingly, since the node B 140 does not receive the acknowledgment message from the node A 130, the node B 140 transmits the transmission request message using the beam pattern corresponding to the sector 143, 141) using a beam pattern corresponding to the beam pattern.

According to the embodiment shown in FIG. 1, node A 130, which should receive data, fails to receive a data transmission message from node B 140, which is referred to as deafness. In the case where the hearing loss occurs, the node B 140, which is to transmit data, does not know the occurrence of the hearing loss, and simply transmits the data transmission message transmitted to the node A 130 and another data transmission message It is determined that the data transmission message is collided with the data transmission message, and the data transmission message can be repeatedly transmitted.

Therefore, the repetitive transmission of the meaningless data transmission message continues, wasting radio resources and reducing the data transmission efficiency.

Hereinafter, the present invention proposes a method for effectively reducing the power consumption of each node by effectively using radio resources by distinguishing collision and hearing loss from the node B 140 to which data is to be transmitted.

2 is a diagram showing a concept of distinguishing a hearing loss from a collision according to an exemplary embodiment.

2, each of the nodes 210, 220, and 230 may transmit and receive a transmission request message using two channels.

First, the node A 210 to which data is to be transmitted transmits a transmission request message to the node B 220 using both the first channel and the second channel. The Node B 220 receives the transmission request message using both the first channel and the second channel, and in response to the transmission request message, transmits an acknowledgment message to the node A 210 using both the first channel and the second channel, Lt; / RTI > According to one aspect, the Node B 220 activates a beam pattern corresponding to the sector 221 in the direction of the node A 210 for both the first channel and the second channel, The acknowledgment message can be transmitted using the beam pattern. For the beam patterns corresponding to the sectors 222, 223 and 224 in the different directions, the first channel can be blocked and the second channel can be activated.

The node A 210 receives the acknowledgment message transmitted on the first channel and the second channel using the beam pattern corresponding to the sector 213. The node A 210 can block the beam pattern corresponding to the sector 211, 212, 213 in the other direction for the first channel and activate for the second channel.

The node A 210 and the node B 220 activate the beam pattern corresponding to the sector to which the message has been transmitted for both the first channel and the second channel and the beam pattern corresponding to the other sector blocks the first channel , Only the second channel can be activated.

According to one aspect, the node A 210 may activate the beam pattern corresponding to the sector 213 for the first channel and transmit data using the first channel. Also, the Node B 220 can activate the beam pattern corresponding to the sector 221 for the first channel, and receive the data using the first channel.

In this case, the states of the beam patterns corresponding to the respective sectors of the node A 210 are shown in Table 1 below.

The sector in which the beam pattern corresponds The first channel Second channel 1 (211) block Activation 2 (212) block Activation 3 (213) Activation Activation 4 (214) block Activation

The states of the beam patterns corresponding to the respective sectors of the Node B 220 are shown in Table 2 below.

The sector in which the beam pattern corresponds The first channel Second channel 1 (221) Activation Activation 2 (222) block Activation 3 (223) block Activation 4 (224) block Activation

In the embodiment shown in FIG. 2, node X 230 attempts to transmit data to node A 210. In this case, the node X 230 activates the beam pattern corresponding to the sector 232 in the direction of the node A 210 for both the first channel and the second channel, The transmission request message can be transmitted using the beam pattern.

In this case, the node A 210 may receive the transmission request message from the node X 240 using the beam pattern corresponding to the sector 214. Referring to Table 1, since the beam pattern corresponding to the sector 214 is active only for the second channel, the node A 210 can receive the transmission request message transmitted to the sector 214 only for the second channel have.

The node A 210 transmits an acknowledgment message to the second channel using the beam pattern corresponding to the sector 214 in response to the transmission request message received only for the second channel.

Node X 230 receives an acknowledgment message transmitted on the second channel using a beam pattern corresponding to sector 232. [ According to one aspect, when the node X 230 does not receive the acknowledgment message using the first channel and receives the acknowledgment message using only the second channel, the node A 210 communicates with another node . Accordingly, the node X 230 can wait for the communication between the node A 210 and another node to be terminated, and can avoid transmission of a meaningless transmission request message.

If the node X 230 fails to receive the acknowledgment message on any channel among the first channel and the second channel, it is determined that the transmission request message transmitted by the node X 230 collides with the node A 210 It can be judged. In this case, node X 230 may retransmit the transmission request message to node A 210 after a predetermined time.

According to the embodiment shown in FIG. 2, each node operates a plurality of channels to transmit a message, and a beam pattern for at least one channel is activated to transmit a message. Each node transmits data using another channel. Thus, each node can send and receive messages using a beam pattern for the other channel, even though the beam pattern is blocked for a particular channel for data transmission.

The node to which the data is to be transmitted may determine whether data transmission is possible or not based on whether the reception acknowledgment message is received using a plurality of channels, whether the reception acknowledgment message is received using only one channel, It is possible to determine whether the node is transmitting data or a collision has occurred in the correspondent node.

Therefore, it is possible to efficiently use the radio resources and reduce the power consumption without unnecessary message retransmission.

3 is a block diagram illustrating a structure of a transmission node according to an exemplary embodiment. The transmitting node 300 according to the exemplary embodiment includes a transmitting unit 310, a receiving unit 320, and a control unit 330.

The transmitting unit 310 transmits a transmission request message for the data to the receiving node 340 using the first channel. In addition, the transmitting unit transmits the transmission request message for the data to the receiving node 340 using the second channel. Here, the first channel and the second channel may be sub-frequency bands different in frequency among the frequency bands allocated to the transmission node 300.

In addition, the receiving node 340 may form a beam pattern corresponding to the plurality of sectors 341, 342, 343, and 344 using the directional antenna, and receive the transmission request message using the formed beam pattern. The receiving node 340 may receive a transmission request message individually transmitted to the first channel and the second channel using a beam pattern corresponding to the sector 344 formed in the direction of the transmitting node 300. [

Even when the transmission node 300 individually transmits the transmission request message to the first channel and the second channel, the receiving node 340 determines whether the beam pattern of the receiving node 340 is activated for which channel It may or may not receive the transmission request message. Also, it may be received using only one of the first channel and the second channel.

(1) When the receiving node receives using both the first channel and the second channel

If the beam pattern corresponding to the sector 344 of the receiving node 340 is active for both the first channel and the second channel, all of the transmission request messages transmitted individually using the first channel and the second channel . In this case, the receiving node 340 transmits an acknowledgment message in response to the transmission request message using the activated beam pattern for the first channel and the second channel.

Also, for the beam patterns corresponding to sectors 341, 342, and 343 formed in different directions, the receiving node 340 may block the first channel and maintain the second channel in an activated state. That is, the beam pattern of the receiving node 340 may be activated only for the sector in the direction of the transmitting node 300 with respect to the first channel, and may remain active with respect to the sector in the forward direction with respect to the second channel.

The receiving unit 320 may receive all the acknowledgment messages using the first channel and the second channel. When the receiving unit 320 receives the acknowledgment message using the first channel and the second channel, the control unit 330 can determine that the receiving node 340 is in a state in which data transmission is possible.

In this case, the transmitting unit 330 can transmit data to the receiving node 340 using the first channel.

(2) When the receiving node receives using only the second channel

If the beam pattern corresponding to the sector 344 of the receiving node 340 is blocked for the first channel and activated for the second channel, the receiving node 340 transmits a transmission request message using the first channel And can receive the transmission request message using only the second channel. In this case, the receiving node 340 transmits the acknowledgment message using the second channel in response to the transmission request message.

The receiving unit 320 may receive the acknowledgment message using the second channel. When the receiving unit 320 receives the acknowledgment message using only the second channel, the control unit 330 may determine that the receiving node 340 is communicating with the third transmitting node (not shown).

Accordingly, the transmitting unit 310 can wait until the receiving node 340 completes the communication with the third transmitting node (not shown) without retransmitting the transmitting request message or the like.

(3) When the receiving node fails to receive

The beam pattern of the receiving node 340 is always active for the second channel. Therefore, the transmission request message transmitted by the transmitting node 300 is always transmitted to the receiving node 340. However, if the third transmission node (not shown) also transmits the transmission request message to the receiving node 340, the transmission request message transmitted by the transmission node 300 and the transmission request message transmitted by the third transmission node (not shown) If the transmission request message collides, the receiving node 340 can not successfully receive any transmission request message.

Therefore, the receiving node 340 does not receive the transmission request message even using the second channel. The receiving node 340 can not receive the acknowledgment message for the transmission request message and therefore the receiving unit 320 can not receive the acknowledgment message using the first channel as well as the second channel.

In this case, the control unit 330 may determine that the transmission request message transmitted to the receiving node 340 has collided. The transmitting unit 310 may retransmit the transmission request message to the receiving node 340.

4 is a block diagram illustrating the structure of a receiving node according to an exemplary embodiment. The receiving node 400 according to the exemplary embodiment may include a receiving unit 410 and a transmitting unit 420. [

The receiving unit 410 receives a transmission request message for data from the transmitting node 450 using the first channel and the second channel. Here, the first channel and the second channel may be sub-frequency bands having different frequencies from among the frequency bands allocated to the receiving node 400. The receiving node 400 includes a directional antenna 430 and forms a beam pattern corresponding to each of the sectors 431, 432, 433 and 434 and receives a transmission request message using the formed beam pattern .

According to one aspect, the receiving node 400 may activate or deactivate the beam pattern corresponding to each sector 431, 432, 433, and 434 for the first channel. If the beam pattern is activated, the receiving node 400 receives a transmission request message transmitted to the first channel using a beam pattern corresponding to the sector 431, 432, 433, 434, or transmits a reception acknowledgment message . When the beam pattern is blocked, the receiving node 400 receives a transmission request message transmitted to the first channel using a beam pattern corresponding to the sectors 431, 432, 433, and 434, Can not transmit.

According to one aspect, the receiving node 400 may keep the beam pattern corresponding to each sector 431, 432, 433, and 434 active for the second channel at any time. Accordingly, the receiving node 400 can receive the transmission request message transmitted on the second channel or transmit the reception acknowledgment message using the beam pattern corresponding to the sectors 431, 432, 433, and 434.

4, according to the state of the beam pattern corresponding to the sector 434 formed in the direction of the transmission node 450, the reception unit 410 may transmit the transmission pattern using the first channel or the second channel A request message can be received. Hereinafter, each case will be described separately.

(1) When a transmission request message is received using both the first channel and the second channel

The beam pattern corresponding to the sector 434 of the receiving node 400 is activated for both the first channel and the second channel and the receiving node 400 receives a transmission request mesh from another transmitting node (not shown) If not additionally received, the receiver 410 may receive all of the transmission request messages individually transmitted using the first channel and the second channel. In this case, the transmitter 420 transmits an acknowledgment message in response to the transmission request message using the activated beam pattern for the first channel and the second channel.

Also, for the beam patterns corresponding to sectors 431, 432, and 433 formed in different directions, the receiving node 340 can block the first channel and keep the second channel active. That is, the beam pattern of the receiving node 400 is activated only for the sector in the direction of the transmitting node 450 with respect to the first channel, and the active state can be maintained with respect to the sector in the forward direction with respect to the second channel.

The transmitting node 450 may receive all of the acknowledgment messages using the first channel and the second channel. When the transmitting node 450 receives the acknowledgment message using the first channel and the second channel, the transmitting node 450 can determine that the receiving node 400 is in a state in which data transmission is possible.

In this case, the transmitting node 450 transmits the data to the receiving node 400 using the first channel, and the receiving unit 410 uses the beam pattern corresponding to the sector 434 activated for the first channel And receive data transmitted from the transmitting node 450. [

(2) When a transmission request message is received using only the second channel

If the beam pattern corresponding to the sector 434 of the receiving node 400 is blocked for the first channel and activated for the second channel, the receiving unit 410 receives the transmission request message using the first channel And can receive the transmission request message using only the second channel. In this case, the transmitting unit 42 may transmit the acknowledgment message using the second channel in response to the transmission request message.

The transmitting node 450 may receive the acknowledgment message using the second channel. When the transmitting node 450 receives the acknowledgment message using only the second channel, the transmitting node 450 may determine that the receiving node 400 is communicating with the third transmitting node (not shown).

Accordingly, the transmitting node 450 can wait until the receiving node 400 completes the communication with the third transmitting node (not shown) without retransmitting the transmitting request message or the like.

(3) When the transmission request message is not received

If a third transmission node (not shown) as well as the transmission node 450 transmits a transmission request message to the receiving node 400, the receiving unit 410 receives any transmission request message from the two transmission request messages I can not. Therefore, the transmitting unit 420 can not transmit the acknowledgment message for the transmission request message.

If an acknowledgment message is not transmitted from the receiving node 400, the transmitting node 450 may determine that a collision has occurred in the receiving node 400. In this case, the transmitting node 450 may retransmit the transmission request message after a predetermined time.

5 is a flowchart illustrating a method of operating a transmission node according to an exemplary embodiment.

In step 510, the transmitting node transmits a transmission request message for data using the first channel to the receiving node, and transmits a transmission request message to the receiving node using the second channel. Here, the first channel and the second channel may be sub-frequency bands having different frequencies from among the frequency bands allocated to the transmission node. That is, in step 510, the transmitting node transmits the same transmission request message to the receiving node in a different channel.

In step 520, the transmitting node may receive an acknowledgment message for the transmission request message using the first channel or the second channel. Here, the transmitting node may individually receive the acknowledgment message using the first channel and the second channel, or may receive the acknowledgment message using only the second channel. In some cases, the transmitting node may not receive an acknowledgment message on either the first channel or the second channel.

At step 530, the transmitting node may determine which channel the acknowledgment message is using. The following description will be made based on the determination result.

(1) When receiving using both the first channel and the second channel

If a beam pattern corresponding to a sector in the direction of the transmitting node of the receiving node is activated for both the first channel and the second channel, the receiving node transmits a transmission request message individually transmitted using the first channel and the second channel Both can be received. The receiving node transmits an acknowledgment message in response to the transmission request message using the activated beam pattern for the first channel and the second channel.

Accordingly, the transmitting node can receive the acknowledgment message using both the first channel and the second channel. The transmitting node may determine in step 540 that the receiving node is capable of data transmission.

The transmitting node may, in step 541, send the data to the receiving node. According to one aspect, the transmitting node may keep a beam pattern corresponding to a sector in the direction of the receiving node active for both the first channel and the second channel. Further, the transmitting node may block the beam pattern corresponding to the sector in the other direction, and the second channel may maintain the active state.

The transmitting node can transmit data to the receiving node using the beam pattern of the first channel corresponding to the sector of the receiving node direction in which the activated state is maintained.

(2) Receiving using only the second channel

If the beam pattern corresponding to the sector in the direction of the transmitting node of the receiving node is blocked for the first channel and activated for the second channel, the receiving node can not receive the transmission request message using the first channel, A transmission request message can be received using only the second channel. In this case, the receiving node transmits the acknowledgment message using the second channel in response to the transmission request message.

The transmitting node may receive the acknowledgment message using the second channel. If the transmitting node receives the acknowledgment message using only the second channel, the transmitting node may determine in step 550 that the receiving node is communicating with the third transmitting node. That is, it can be determined that the receiving node is in a state in which data reception using the first channel is impossible. This condition can be called hearing loss.

In this case, the transmitting node can wait until the receiving node completes the communication with the third transmitting node without retransmitting the transmission request message or the like.

(3) When the first channel or the second channel is not received by any channel

If the transmission request message transmitted from the transmitting node to the receiving node collides with the transmission request message transmitted from the third transmitting node to the receiving node, the receiving node can not successfully receive any of the two transmission requesting messages.

Therefore, the receiving node can not transmit the acknowledgment message either to the first channel or to the second channel.

If the transmitting node does not receive the acknowledgment message either on the first channel or on the second channel, the transmitting node may determine that a collision occurred in step 560. [

In this case, the transmitting node may retransmit the transmission request message to the receiving node after a predetermined time.

6 is a flowchart illustrating a method of operating a receiving node according to an exemplary embodiment.

In step 610, the receiving node receives a transmission request message for the data from the transmitting node using the first channel or the second channel. According to one aspect, the receiving node may activate or deactivate the beam pattern corresponding to each sector for the first channel. The receiving node may keep the beam pattern corresponding to each sector active for the second channel at any time. Accordingly, the receiving node may receive the transmission request message using the first channel and the second channel, or may use only the second channel, depending on whether the beam pattern corresponding to the sector is activated or blocked for the first channel And receive a transmission request message. In some cases, it may not receive the transmission request message.

In step 620, the receiving node determines on which channel the transmission request message was received.

If the receiving node receives the transmission request message using the first channel and the second channel, the receiving node transmits the acknowledgment message to the transmitting node using the first channel and the second channel in step 630 .

In this case, the transmitting node can determine that the receiving node is ready to transmit data, and can transmit data using the first channel.

The receiving node can remain active for both the first channel and the second channel with respect to the beam pattern corresponding to the sector formed in the direction of the transmitting node. Accordingly, the receiving node can receive data transmitted using the first channel.

Also, for the beam pattern corresponding to the sector formed in the other direction, not the direction of the transmitting node, the receiving node may block the first channel and maintain the second channel in the activated state.

If the receiving node receives the transmission request message using only the second channel, the receiving node may transmit the acknowledgment message to the transmitting node using the second channel in step 640. [

In this case, the transmitting node can determine that the receiving node is communicating with another transmitting node, and can wait until communication between the receiving node and another transmitting node is completed.

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. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. 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 (25)

In the transmitting node,
A transmitting unit for transmitting a transmission request message for data using a first channel to a receiving node and transmitting the transmission request message to the receiving node using a second channel;
A receiving unit receiving the acknowledgment message for the transmission request message using the first channel and the second channel or receiving the acknowledgment message using the second channel; And
Whether or not the transmission request message conflicts with a second transmission request message transmitted from the second transmission node to the reception node according to whether the reception confirmation message is received using the first channel or the second channel, A control unit for determining whether or not communication with the third transmission node is in progress
/ RTI >
The method according to claim 1,
When receiving the acknowledgment message using the first channel and receiving the acknowledgment message using the second channel,
Wherein the control unit determines that the receiving node is communicating with the third transmitting node.
The method according to claim 1,
When the reception confirmation message is not received using the first channel and the reception confirmation message is not received using the second channel,
Wherein the control unit determines that the transmission request message has collided.
The method of claim 3,
Wherein the transmission unit retransmits the transmission request message.
The method according to claim 1,
When receiving the acknowledgment message using the first channel and receiving the acknowledgment message using the second channel,
Wherein the transmitting unit transmits data to the receiving node using the first channel.
The method according to claim 1,
Wherein the acknowledgment message is transmitted using a directional beam pattern. The method according to claim 6,
Wherein the beam pattern is fixed in the direction of the transmission node and blocked in the other direction.
A receiving unit for receiving a transmission request message for data from the transmitting node using the first channel and the second channel or the second channel; And
And a transmission unit for transmitting an acknowledgment message for the transmission request message to the transmission node using the first channel and the second channel or the second channel,
/ RTI >
9. The method of claim 8,
When receiving the transmission request message using the first channel and receiving the transmission request message using the second channel,
Wherein the transmitting unit transmits the acknowledgment message using the first channel and transmits the acknowledgment message using the second channel.
9. The method of claim 8,
When the transmission request message is not received using the first channel and the transmission request message is received using the second channel,
And the transmitting unit transmits the acknowledgment message using the second channel.
9. The method of claim 8,
Wherein the transmitting unit transmits the acknowledgment message using a beam pattern having a directivity.
12. The method of claim 11,
Wherein the transmitter blocks the beam pattern in the direction of the transmission node after the transmission of the acknowledgment message and blocks the beam pattern in the other direction.
A method of operating a transmitting node,
Transmitting a transmission request message for data using a first channel to a receiving node and transmitting the transmission request message to the receiving node using a second channel;
Receiving an acknowledgment message for the transmission request message using the first channel and the second channel or using the second channel; And
Whether or not the transmission request message conflicts with a second transmission request message transmitted from the second transmission node to the reception node according to whether the reception confirmation message is received using the first channel or the second channel, Determining whether the third transmission node is in communication with the third transmission node
/ RTI >
14. The method of claim 13,
When receiving the acknowledgment message using the first channel and receiving the acknowledgment message using the second channel,
Wherein the determining step determines that the receiving node is communicating with the third transmitting node.
14. The method of claim 13,
When the reception confirmation message is not received using the first channel and the reception confirmation message is not received using the second channel,
Wherein the determining step determines that the transmission request message is collided.
16. The method of claim 15,
The step of retransmitting the transmission request message
Lt; RTI ID = 0.0 > 1, < / RTI >
14. The method of claim 13,
When receiving the acknowledgment message using the first channel and receiving the acknowledgment message using the second channel,
And transmitting data to the receiving node using the first channel.
14. The method of claim 13,
Wherein the acknowledgment message is transmitted using a beam pattern having a directivity.
19. The method of claim 18,
Wherein the beam pattern is fixed in the direction of the transmission node and blocks in the other direction.
Receiving a transmission request message for data using a first channel and a second channel or the second channel from a transmitting node; And
Transmitting an acknowledgment message for the transmission request message to the transmission node using the first channel and the second channel or the second channel;
Lt; / RTI >
21. The method of claim 20,
When receiving the transmission request message using the first channel and receiving the transmission request message using the second channel,
Wherein the transmitting step transmits the acknowledgment message using the first channel and transmits the acknowledgment message using the second channel.
21. The method of claim 20,
When the transmission request message is not received using the first channel and the transmission request message is received using the second channel,
Wherein the transmitting comprises transmitting the acknowledgment message using the second channel.
21. The method of claim 20,
Wherein the transmitting step transmits the acknowledgment message using a beam pattern having a directivity.
24. The method of claim 23,
Wherein the transmitting step fixes the beam pattern to the direction of the transmitting node after transmission of the acknowledgment message and blocks the beam pattern in the other direction.
A computer-readable recording medium having recorded thereon a program for executing the method according to any one of claims 13 to 24.

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