KR100733380B1 - Collision solving system in data transmission in wireless network and method thereof and recording medium thereof - Google Patents

Abstract

A collision solving system during data transmission in a wireless network, a solving method thereof, and a recording medium for recording the method are provided to attempt retransmission by maximally maintaining contention window size of a data frame which attempts the retransmission if collision of frames including data occurs, thereby reducing a probability of collision of retransmission frames. A terminal(50) comprises as follows. A communication unit(501) transceives plural signals and data with other terminals. A signal decider(502) decides on transmission results of the data transmitted through the communication unit(501). A collision manager(504) sets contention window size information and backoff stage information, and manages collision occurring when the data are transmitted to the other terminals. The collision manager(504) sets contention window size which determines priority for using a wireless medium according to the decided transmission results.

Description

Collision Solving System in Data Transmission in Wireless Network and Method Thereof and Recording Medium Thereof}

1 is a view showing a basic approach of the conventional distributed coordination function (DCF),

2 is a diagram showing a contention window of a DCF when using a conventional direct sequence spread spectrum (DSSS) physical layer,

3 is a diagram illustrating the throughput of DCF as the number of terminals sharing a medium increases;

4 is a block diagram illustrating a collision resolution system during data transmission in a wireless network according to an embodiment of the present invention;

5 is a view showing the size of a contention window according to a backoff stage according to an embodiment of the present invention;

6 is a flowchart illustrating a conflict resolution method in data transmission in a wireless network according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

50: terminal 501: communication means

502: signal determining means 503: memory means

504: collision management means 505: control means

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system for resolving collisions in data transmission in a wireless network, a method for solving the same, and a recording medium recording the same. Keep the contention window (CW) size of the data frame attempting to maximize, and if the previous data frame succeeds in initial transmission, reduce the contention window size of the next frame to be sent to half the size of the previous contention window, The present invention relates to a collision resolution system, a method of solving the same, and a recording medium recording the same in data transmission in a wireless network that improves throughput.

IEEE 802.11 is a set of standards for wireless LANs developed by the Working Group of the Institute of Electrical and Electronics Engineers (IEEE), and currently includes four standards: 802.11, 802.11a, 802.11b, and 802.11g. . The IEEE 802.11 protocol is currently standardized into Medium Access Control (MAC) and Physical Layer (Physical Layer). The basic MAC structure is composed of DCS (Distributed Coordination Function) based on Carrier Sense Multiple Access with Collision Avoidance (CSMA / CA).

MAC is a lower layer of the two sublayers of the Data Link Layer defined by the IEEE. The MAC is the address of the data link layer of the Open Systems Interconnection 7 Layer. Bit Refers to the hardware address. The MAC sublayer handles shared media access issues such as token passing or contention. In general, CSMA is used as a MAC algorithm in an WLAN.

CSMA is a technology that reliably transmits signals by avoiding communication collisions between devices in a network in which many devices exist, and detecting collisions and resolving collisions to reduce time and bandwidth consumed by collisions. More specifically, in order to effectively access a channel between nodes in a shared channel in which a plurality of nodes exist, a node to communicate first takes a standby state and then checks whether another node communicates with the channel. You should try to communicate afterwards. If several nodes start communication at the same time, collision is inevitable. A method of detecting, retransmitting, or avoiding collision is used, and CSMA / CD (Carrier Sense Multiple Access with Collision Detect) and CSMA / CA are mainly used. CSMA / CD is an access method that detects a collision and retransmits data in case of a collision. CSMA / CA prevents a collision by preventing a collision, but if data is being transmitted first, it is unconditionally until the other side comes. An access method that keeps you waiting.

In particular, CSMA / CA is a method of predicting collisions at the physical layer in advance and minimizing the possibility of collisions before transmission. The CSMA / CA creates a priority race window by a priority provided by the network layer with a race window. Slot time is created in each window, and communication frames of the same priority generate random numbers, calculate a backoff time corresponding to the random number, and communicate at the corresponding slot time. In CSMA / CA, the allocation of window and slot time is closely related to communication efficiency, so it should be allocated according to the characteristics of each network.

IEEE 802.11 uses two protocols, DCF and PCF (Point Coordination Function), which are defined in the MAC layer. PCF guarantees real-time data transmission as a contention-free transmission method, but DCF is advantageous for non-real-time data transmission as a contention-based transmission method.

Next, an approach using a conventional DCF method will be described with reference to FIGS. 1 to 3.

FIG. 1 is a diagram illustrating a basic approach of a conventional DCF, FIG. 2 is a diagram illustrating a contention window of a DCF when a conventional DSSS physical layer is used, and FIG. 3 is a diagram of a DCF according to an increase in the number of terminals sharing a medium. It is a figure which shows a yield.

In IEEE 802.11 MAC, an IFS (Inter Frame Space) is used to define a minimum time to wait for a next operation after a terminal for wireless communication detects an idle state of a medium. Several types of priority are provided by IFS. The smaller the IFS value, the higher the priority. The types of IFS used in IEEE 802.11 MAC are as follows.

SIFS (Shorter Inter Frame Space)

It is a time interval after transmission of one data frame and before transmission of acknowledgment (ACK), clear to send frame (CTS) frame, etc., and provides the highest priority level among IFS. The SIFS has a fixed value according to the physical layer in consideration of the time until the UE that has transmitted the data frame can receive another data frame.

Point Inter Frame Space (PIFS)

When operating as a PCF, an access point is used to obtain media access authority over other terminals. PIFS is determined by SIFS + slot time.

Distributed Inter Frame Space (DIFS)

All terminals operating in DCF are used to transmit data and management frames. It is transmitted at a lower priority than PCF-based transmission and is equal to the PIFS + slot time value.

Extended Inter Frame Space (EIFS)

When a DCF-based UE has an error in data frame transmission, it is used to give a sufficient time for sending an ACK frame to a receiving UE.

When the terminal wants to transmit data, it is first checked whether the medium is used. If the result of the check is that the medium is not in use, it checks whether the medium is still in use during DIFS, and transmits a data frame if it is not in use during DIFS. As a result of checking whether the medium is used, if the medium is in use by another terminal, transmission of the data frame is delayed until the medium is not used. If two or more terminals are postponing data frame transmission until the medium is not in use, the possibility of collision increases at the end of DIFS, so IEEE 802.11 performs a backoff process as shown in FIG. That is, the terminal that defers data frame transmission until the medium is not in use does not immediately start transmission at the end of DIFS, but waits for a certain time before starting data frame transmission.

The backoff process is as follows. The terminal attempting initial transmission initializes the backoff stage to 0 and the contention window to the minimum value CW _min , and selects an arbitrary backoff counter from [0, CW _min ]. The terminal detecting that the medium is not used during the slot time decrements the backoff counter by one, and does not decrease the back off counter when the medium is in use during the slot time. At the start of the slot, the UE having the backoff counter 0 starts frame transmission. Slot time is determined by the corresponding physical layer.

The backoff counter is any integer selected from [0, CW] and CW is the contention window. The CW is determined by the backoff stage, and each time the retransmission is attempted without receiving the ACK, the backoff stage increases by 1 and the CW increases by 2 times as shown in FIG. 2. CW does not increase any more when the maximum value of CW _max is reached. If the retransmission is attempted and succeeded, the backoff stage and CW are initialized to 0 and CW _min , respectively. In addition, if the backoff stage exceeds the maximum retry limit, the data frame is dropped, and the backoff stage and the CW are initialized to 0 and CW _min , respectively. In FIG. 2, CW _min = '31 'and CW _max =' 1023 '.

Using the conventional DCF scheme, a yield as shown in FIG. 3 is obtained according to the number of terminals sharing a medium.

As such, an example of a service technology in a wireless LAN system is disclosed in Korean Patent Laid-Open Publication No. 2005-0003809 (published on Jan. 12, 2005, a service quality improvement method in a wireless LAN system).

According to the technique disclosed in Korean Patent Laid-Open Publication No. 2005-0003809, a preset minimum and maximum values of different contention windows for each of a plurality of WLAN clients are occupied and occupy a channel among the plurality of clients. Reducing the backoff time by the minimum value of the contention window set to the client if the clients want to check the occupancy state of the channel, respectively, and when the backoff time ends, the clients attempt to occupy the channel. By adding a method that sets the competitive window value of a specific client differently from other clients, a client that requires a higher quality of service for each client can receive a higher quality of service than a client that does not. Service in the system A method of improving quality is described.

In addition, an example of a technology related to a contention window in a wireless network is disclosed in Korean Patent Laid-Open Publication No. 2006-0013225 (published on February 9, 2006, a method for setting a contention window in a wireless network).

The technique disclosed in the Republic of Korea Patent Publication No. 2006-0013225 is a step in which a predetermined station transmits a frame including data and then checks whether a response frame is received for the frame transmission. Increasing the number of retransmissions when a response frame for the result frame transmission is not received; comparing the increased number of retransmissions with the maximum number of retransmissions; and when the comparison result retransmissions exceeds the maximum number of retransmissions, the data is included. And dropping the dropped frame and setting the final contention window value of the dropped frame to the contention window value of the next frame to be transmitted, and the contention window value according to the number of final retransmissions of the frame when a frame transmission including data fails. Set to the contention window value on the next frame transmission. Writing has been described for the contention window settings of the wireless network to improve overall throughput methods.

However, in the techniques disclosed in the above-mentioned publications, including the prior art, if a successful retransmission is attempted, the method of initializing the backoff stage and the contention window size and the number of retransmissions exceed the maximum retransmission times, discarding the data frame and performing the next frame transmission. For the case of using the method of initializing the backoff stage and the contention window size, the number of UEs competing for media occupancy is not taken into account. Therefore, the UEs participating in the contention experience continuous collisions and consequently the overall yield drops. .

In addition, according to the conventional DCF scheme, there is a problem in that more collisions occur when more terminals compete for media occupancy.

SUMMARY OF THE INVENTION An object of the present invention is to solve the problems described above, and to reduce the possibility of collision of the retransmission frame by attempting retransmission by maintaining the maximum contention window size of the data frame attempting retransmission when a collision of a frame including data occurs. The present invention provides a collision resolution system, a method of solving the same, and a recording medium recording the same in data transmission in a wireless network.

Another object of the present invention is to reduce the unnecessary window delay due to backoff when the number of UEs competing for media occupancy is reduced by reducing the contention window size of the next frame to be transmitted to half of the previous contention window size when the previous frame succeeds in initial transmission. The present invention provides a collision resolution system, a method of solving the same, and a recording medium recording the same in data transmission in a wireless network.

Another object of the present invention is to define a backoff stage as a positive backoff stage, a zero backoff stage, and a negative backoff stage, using a maximum sized contention window at backoff stage 0 and a positive backoff stage. The contention window in the negative backoff stage provides a conflict resolution system, a solution, and a record medium for transmitting data in a wireless network that improves the overall yield by using half of the contention window size used in the previous backoff stage. It is.

In order to achieve the above object, a collision resolution system during data transmission in a wireless network according to the present invention includes a plurality of terminals connected through a wireless medium, the terminal communicating means for transmitting and receiving a plurality of signals and data with other terminals, A signal judging means for judging the transmission result of the data transmitted through the communication means, a collision management means for setting a backoff stage information and contention window size information to manage a collision occurring when data is transmitted to the other terminals; And the collision management means sets a contention window size for determining a priority to use the wireless medium according to the transmission result determined by the signal determination means.

In addition, in the conflict resolution system when transmitting data in the wireless network according to the present invention, the collision management means is characterized in that the maximum contention window size of the data to be retransmitted when the transmission result is failed.

In addition, in the conflict resolution system when transmitting data in a wireless network according to the present invention, the collision management means, if the transmission result is successful, sets the contention window size of the next data to be transmitted to half of the contention window size of previous successful data. Characterized in that.

In addition, in the collision resolution system during data transmission in the wireless network according to the present invention, the backoff stage is a positive backoff stage, a zero backoff stage or a negative backoff stage.

In addition, in the collision resolution system when transmitting data in a wireless network according to the present invention, the collision management means is characterized in that the check the back-off stage information, if the transmission result is failed.

In addition, in the collision resolution system when transmitting data in a wireless network according to the present invention, if the backoff stage is less than or equal to 0, the backoff stage is set to 1 and the contention window size is set to a maximum value. do.

In addition, in the collision resolution system when transmitting data in a wireless network according to the present invention, if the backoff stage is greater than zero, the backoff stage is increased by one, and the contention window size is set to a maximum value. do.

In the conflict resolution system when transmitting data in a wireless network according to the present invention, the collision management means checks the backoff stage information when the transmission result is successful.

In the collision resolution system when transmitting data in a wireless network according to the present invention, if the backoff stage is greater than zero, the backoff stage is set to zero and the contention window size is set to a maximum value.

In addition, the conflict resolution system when transmitting data in the wireless network according to the present invention, if the backoff stage is less than or equal to 0, further comprising the step of checking whether the backoff stage is the minimum backoff stage do.

In addition, in a collision resolution system for data transmission in a wireless network according to the present invention, if the backoff stage is not the minimum backoff stage, the backoff stage is decreased by one, and the contention window size is reduced in the previous backoff stage. It is set to half of the size of the competing window used.

In addition, in a collision resolution system for data transmission in a wireless network according to the present invention, when the backoff stage is equal to the minimum backoff stage, the backoff stage is the minimum backoff stage, and the contention window size is the previous backoff stage. Set the contention window size to be used.

In addition, in order to achieve the above object, a conflict resolution method in data transmission in a wireless network according to the present invention is connected via a wireless medium, communication means for transmitting and receiving a plurality of signals and data with other terminals, the transmission means through the communication means Among a plurality of terminals including a signal determination means for determining the result of the transmission of the data, conflict management means for setting the back-off stage information and contention window size information to manage the collision occurring when data is transmitted to the other terminals A method for transmitting data by one terminal winning a competition, the method comprising: (a) the communication means transmitting the data, (b) the signal determining means determining the transmission result, and (c) the collision Setting, by management means, a contention window size that determines a priority to use the wireless medium according to the transmission result; It is characterized by including.

In addition, in the method for resolving conflict during data transmission in a wireless network according to the present invention, the step (c) is characterized in that the contention window size of data to be retransmitted is set to the maximum when the transmission result is unsuccessful. do.

In addition, in the method for resolving conflicts in data transmission in a wireless network according to the present invention, in step (c), if the transmission result is successful, the contention window size of the next data to be transmitted is equal to half the contention window size of previous successful data. It is characterized by setting.

In the method for resolving collision in data transmission in a wireless network according to the present invention, the backoff stage may be a positive backoff stage, a zero backoff stage, or a negative backoff stage.

In addition, in the method for resolving conflicts in data transmission in a wireless network according to the present invention, in step (c), if the transmission result is unsuccessful, (c10) the collision management means checks the back-off stage information. It further comprises.

In addition, in the method for resolving conflicts in data transmission in a wireless network according to the present invention, if the backoff stage is less than or equal to 0 as a result of the checking in the step (c10), the collision management means may include 1, The contention window size may be set to a maximum value.

In the collision resolution method when transmitting data in a wireless network according to the present invention, when the backoff stage is greater than zero as a result of the checking in the step (c10), the collision management means increases the backoff stage by one, The contention window size may be set to a maximum value.

In addition, in the method for resolving conflicts in data transmission in a wireless network according to the present invention, after setting the backoff stage and the contention window size, (c11) the collision management means exceeds the maximum number of retransmissions. And if it is exceeded, after the collision management means discards the data, the backoff stage is set to zero and the contention window size is set to a maximum value.

In addition, in the method for resolving conflicts in data transmission in a wireless network according to the present invention, in step (c), if the transmission result is successful, (c20) the collision management means checks the back-off stage information. It further comprises.

In addition, in the method for resolving conflicts in data transmission in a wireless network according to the present invention, if the backoff stage is greater than zero as a result of the checking in the step (c20), the collision management means indicates that the backoff stage is 0, and the competition is performed. The window size may be set to a maximum value.

In addition, in the method for resolving conflicts in data transmission in a wireless network according to the present invention, when the backoff stage is less than or equal to 0 as a result of the checking in the step (c20), (c21) the collision management means is the backoff stage. And confirming that is equal to the minimum backoff stage.

In addition, in the method for resolving conflicts in data transmission in a wireless network according to the present invention, if the backoff stage is not the minimum backoff stage as a result of the checking in (c21), the collision management means decreases the backoff stage by one. The contention window size is set to half of the contention window size used in the previous backoff stage.

In the collision resolution method for data transmission in a wireless network according to the present invention, when the backoff stage is a minimum backoff stage as a result of the check in the step (c21), the collision management means determines that the backoff stage is a minimum backoff. The contention window size may be set to the contention window size used in the previous backoff stage.

In addition, in order to achieve the above object, a computer-readable recording medium capable of resolving a conflict in data transmission in a wireless network according to the present invention is connected through a wireless medium, and communicates a plurality of signals and data with other terminals. Means for determining a transmission result of the data transmitted through the communication means, a collision management means for setting a backoff stage information and contention window size information to manage a collision occurring when data is transmitted to the other terminals; Claims [1] A recording medium readable by a computer, a method of transmitting data by one terminal, which has won a competition among a plurality of terminals, comprising: (a) the communication means transmitting the data; (b) the signal determining means Determining the transmission result; (c) the collision management means uses the wireless medium according to the transmission result; First characterized in that it comprises the step of setting a contention window size to determine the rankings.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. In addition, in describing this invention, the same code | symbol is attached | subjected and the repeated description is abbreviate | omitted.

4 is a block diagram illustrating a collision resolution system during data transmission in a wireless network according to an embodiment of the present invention.

As illustrated in FIG. 4, one terminal 50 of a plurality of terminals 50 connected through a wireless medium such as a wireless network communicates with a plurality of other terminals 50 via a communication means ( 501, the signal determination means 502 for determining the result of the transmission of the data transmitted through the communication means 501, the memory means 503 for storing the data to be transmitted, the backoff stage information and the contention window size information are set The terminal (including the collision management means 504, the communication means 501, the signal determination means 502, the memory means 503 and the collision management means 504) for managing a collision occurring when data is transmitted to the terminals 50; And control means 505 for controlling the interior of the apparatus 50.

The terminal 50 shown in FIG. 4 uses the IEEE 802.11 protocol and firstly checks whether or not the wireless medium is occupied and used by another terminal 50 in the DIFS section. Since the technique for checking whether or not to use is a well-known technique commonly used in the art, detailed description thereof will be omitted. When the wireless medium is not in use as a result of the test, the communication means 501 of the terminal 50 transmits data to the other terminal 50, and the determination of the success or failure of the transmission result is performed by the signal determining means 502. The collision management means 504 sets the contention window size according to the transmission result determined by the signal determination means 502.

In order to avoid collisions when attempting to access a wireless medium, a plurality of terminals 50 to transmit data are assigned a channel use in a backoff window period through a backoff process. In addition, by allowing a plurality of terminals 50 to randomly access the wireless medium, it increases the probability that the lower priority terminals 50 can win the media access competition with the higher priority terminals 50. The priority for using wireless media is higher as the contention window size, which is the medium access latency, is smaller.

5 illustrates a contention window size according to a backoff stage according to an embodiment of the present invention.

As shown in FIG. 5, the collision management means 504 sets the contention window size of the data to be retransmitted to the maximum when the data transmission result is unsuccessful, and sets the maximum size of the next data to be transmitted when the transmission result is successful. The contention window size is set to half of the contention window size of the previous successful data.

More specifically, we define the backoff stage as a positive backoff stage, a zero backoff stage, and a negative backoff stage, with the largest contention window being used for the backoff stage 0 and the positive backoff stage. The contention window at the negative backoff stage uses half the contention window size used in the previous backoff stage.

Next, a collision resolution method for data transmission in a wireless network according to the present invention will be described with reference to FIG. 6.

6 is a flowchart illustrating a conflict resolution method in data transmission in a wireless network according to an embodiment of the present invention.

As shown in FIG. 6, the present invention provides a method of checking a state of a backoff stage according to whether a transmission is successful and resetting a backoff stage and a contention window size according to a state of a backoff stage after transmitting a data frame. It consists of steps.

First, the terminal 50 having the data to be transmitted checks whether the medium is in use in the DIFS section to determine whether another terminal 50 is occupying the medium and transmitting a frame.

Next, the terminal 50 winning the competition transmits the data frame through the communication means 501 (S1), the signal determination unit determines whether the transmission is successful (S2). The collision management means 504 sets the contention window size according to the transmission result of step S2.

If the transmission of the transmission result of step (S2) fails, the collision management unit checks the backoff stage information to determine whether it is less than or equal to zero (S3). If the backoff stage is less than or equal to 0, the collision management unit sets the backoff stage to 1 and the contention window size to the maximum value (S4). The maximum value is set (S5).

After step (S5), the collision management unit checks whether the backoff stage has exceeded the maximum number of retransmissions. If the maximum number of retransmissions is not exceeded, the collision management unit goes to step (S1). After discarding the data frame (S7), the backoff stage is set to 0 and the contention window size is set to the maximum value (S8).

If the transmission result of step (S2) is successful, the collision management unit checks the backoff stage information to determine whether the backoff stage is greater than zero (S9). If the backoff stage is greater than zero, the collision management unit sets the backoff stage to zero and the contention window size to the maximum value (S10).

If the collision management unit checks the backoff stage at step S9 and is less than zero, the collision management unit checks whether the backoff stage is the minimum backoff stage (S11). The off stage is reduced by one and the contention window is set to half the size of the contention window used in the previous backoff stage (S12).

If the backoff stage is the minimum backoff stage in step S11, the collision management unit sets the backoff stage to the minimum backoff stage and the contention window to the contention window size of the previous backoff stage (S13).

As mentioned above, although the invention made by this inventor was demonstrated concretely according to the said Example, this invention is not limited to the said Example and can be variously changed in the range which does not deviate from the summary.

As described above, according to the present invention, a collision resolution system, a method for solving data transmission, and a recording medium recording the same, according to the present invention, attempt to retransmit by using the maximum contention window when data frame collision occurs. The effect of reducing the possibility of collision is obtained.

In addition, according to the present invention, a collision resolution system, a method for solving data transmission, and a recording medium recording the same in the wireless network according to the present invention reduce the contention window size by half of the contention window size when the previous data frame is successfully transmitted. The effect of minimizing unnecessary delay due to backoff can also be obtained when the number of terminals competing for media occupancy is small.

In addition, according to the present invention, a collision resolution system, a method of resolving data, and a recording medium recording the same in the wireless network according to the present invention can solve the decrease in yield caused by the increase in the number of contention terminals, which is a problem of the conventional DCF scheme. Obtained.

Claims (26)

In a plurality of terminals connected via a wireless medium, The terminal is Communication means for transmitting and receiving a plurality of signals and data with other terminals, Signal determination means for determining a transmission result of the data transmitted through the communication means, Conflict management means for setting a backoff stage information and contention window size information to manage a collision occurring when data is transmitted to the other terminals, And the collision management means sets a contention window size for determining a priority to use the wireless medium according to the transmission result determined by the signal determination means. The method of claim 1, And the collision management means sets the contention window size of the data to be retransmitted to the maximum when the transmission result is unsuccessful. The method of claim 1, And the collision management means sets the contention window size of the next data to be transmitted to half of the contention window size of the previous successful data when the transmission result is successful. The method of claim 1, And said backoff stage is a positive backoff stage, a zero backoff stage, or a negative backoff stage. The method of claim 4, wherein And the collision management means checks the back-off stage information when the transmission result is unsuccessful. The method of claim 5, And if the backoff stage is less than or equal to zero, the backoff stage is set to 1 and the contention window size is set to a maximum value. The method of claim 5, If the backoff stage is greater than zero, the backoff stage is increased by one and the contention window size is set to a maximum value. The method of claim 4, wherein And the collision management means checks the back-off stage information when the transmission result is successful. The method of claim 8, And if the backoff stage is greater than zero, the backoff stage is set to zero and the contention window size is set to a maximum value. The method of claim 8, And if the backoff stage is less than or equal to zero, determining whether the backoff stage is a minimum backoff stage. The method of claim 10, If the backoff stage is not the minimum backoff stage, the backoff stage is reduced by one, and the contention window size is set to half of the contention window size used in the previous backoff stage. Conflict Resolution System in Data Transfer. The method of claim 10, When the backoff stage is equal to the minimum backoff stage, the backoff stage is set to the minimum backoff stage, the contention window size is set to the contention window size used in the previous backoff stage, during data transmission in a wireless network Conflict Resolution System. Communication means connected through a wireless medium, the communication means for exchanging a plurality of signals and data with other terminals, signal determination means for determining the transmission result of the data transmitted through the communication means, backoff stage information and contention window size information In a method of transmitting data by one terminal winning the competition among a plurality of terminals including a conflict management means for managing a collision occurring when transmitting data to the other terminals by setting a; (a) the communication means transmitting the data; (b) the signal determining means determining the transmission result; and c) setting, by the collision management means, a contention window size for determining a priority of using the wireless medium according to the transmission result. The method of claim 13, Step (c) is And if the transmission result is unsuccessful, setting a contention window size of data to be retransmitted to a maximum. The method of claim 13, Step (c) is And if the transmission result is successful, setting the contention window size of the next data to be transmitted to half of the contention window size of previous successful data. The method of claim 13, And said backoff stage is a positive backoff stage, a zero backoff stage, or a negative backoff stage. The method of claim 16, In step (c), if the transmission result is unsuccessful, (c10) the collision management means further comprises the step of inspecting the back off stage information conflict resolution method in the data transmission in a wireless network. The method of claim 17, When the backoff stage is less than or equal to 0 as a result of the checking in the step (c10), the collision management means sets the backoff stage to 1 and the contention window size to a maximum value. How to resolve conflicts in transmission. The method of claim 17, If the backoff stage is greater than 0, the collision management means increases the backoff stage by 1 and sets the contention window size to a maximum value. How to resolve conflicts in transmission. The method of claim 18 or 19, After setting the backoff stage and the contention window size, (c11) the collision management means checks whether the back off stage has exceeded the maximum number of retransmissions, and if the collision management means discards the data, the back off stage is 0, And the contention window size is set to a maximum value. The method of claim 16, In step (c), if the transmission result is successful, (c20) the collision management means further comprises the step of inspecting the back off stage information conflict resolution method in the data transmission in a wireless network. The method of claim 21, When the backoff stage is greater than 0, the collision management means sets the backoff stage to 0 and the contention window size to a maximum value. How to resolve the conflict. The method of claim 21, If the backoff stage is less than or equal to 0 as a result of the inspection in step (c20), (c21) the collision management means further comprising the step of checking whether the back off stage is equal to the minimum back off stage. The method of claim 23, wherein If the backoff stage is not the minimum backoff stage, the collision management means decreases the backoff stage by one, and the contention window size is the same as the contention window size used in the previous backoff stage. Method for resolving conflicts in data transmission in a wireless network, characterized in that the setting in half. The method of claim 23, wherein When the backoff stage is the minimum backoff stage, the collision management means determines that the backoff stage is the minimum backoff stage, and the contention window size is the contention window size used in the previous backoff stage. Method for resolving conflict during data transmission in a wireless network, characterized in that the setting. Communication means connected through a wireless medium, the communication means for exchanging a plurality of signals and data with other terminals, signal determination means for determining the transmission result of the data transmitted through the communication means, backoff stage information and contention window size information In a recording medium that can be read by a computer, a method of transmitting data from one of the plurality of terminals including a conflict management means for managing a collision occurring when transmitting data to the other terminals by setting the , (a) the communication means transmitting the data; (b) the signal determining means determining the transmission result; and (c) setting, by the collision management means, a contention window size for determining a priority to use the wireless medium according to the transmission result.

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