KR100656475B1 - Wireless data throughput apparatus and method in wireless lan system - Google Patents

Abstract

A wireless data processing apparatus in a wireless LAN system and a method thereof are provided to change setting of an MAC channel access mode in the environment where transmission of a packet fails or no retransmission occurs, thereby transmitting data without unnecessary waiting time. A wireless data processing apparatus in a wireless LAN(Local Area Network) system comprises the followings: a monitoring unit(100) which determines whether there is a collision with at least one or more other wireless LAN terminals(1-2) during transmission of data; and an MAC(Media Access Control) controller(200) which changes the standard MAC channel access mode into an abbreviated MAC channel access mode if it is determined that there is no collision with the other wireless LAN terminal(1-2) by the monitoring unit(100).

Description

Wireless data processing apparatus and method in a wireless LAN system {Wireless data throughput apparatus and method in wireless LAN system}

1 is a functional block diagram showing the configuration of a wireless data processing apparatus in a wireless LAN system according to the present invention.

2 is a flowchart illustrating a method of processing wireless data in a WLAN system according to the present invention.

3A is a reference diagram illustrating a standard MAC channel approach in a wireless data processing apparatus and method in a WLAN system according to FIGS. 1 and 2.

3B is a reference diagram illustrating a shortened MAC channel approach controlling only "AIFS" in a wireless data processing apparatus and method in a WLAN system according to FIGS. 1 and 2.

3C is a reference diagram illustrating a standard MAC channel access method of controlling only a "Back_off" count in a wireless data processing apparatus and method in a WLAN system according to FIGS. 1 and 2.

FIG. 3D is a reference diagram illustrating a standard MAC channel approach for controlling "AIFS" and "Back_off" counts in the apparatus and method for wireless data processing in a WLAN system according to FIGS. 1 and 2.

<Explanation of symbols for the main parts of the drawings>

100: monitoring unit 200: MAC control unit

The present invention relates to a wireless data processing apparatus and method in a WLAN system.

In general, the WLAN system uses the IEEE 802.11 standard and uses a channel approach using carrier sense multiple access with collision detection (CAMA) and collision avoidance (CA).

Here, the channel access method using CSMA / CA performs a carrier sense (CS) before a wireless LAN terminal sends data.

Thereafter, when data is not transmitted from another WLAN terminal, this is a method of transmitting data by checking it.

However, when the data is checked, the data is transmitted from other wireless LAN terminals, so collision occurs, both computers stop the transmission, and the transmission of the data is stopped for a certain random period.

Therefore, any wireless LAN terminal checks the frequency domain every predetermined time and decreases the "Back_off" count only when no one is sending data, and transmits the data when its "Back_off" count reaches "0".

Referring to FIG. 3A, a data transmission process of a WLAN terminal using the 802.11 standard is checked. The WLAN terminal checks a frequency region to transmit data every predetermined time.

If another wireless LAN terminal is using the frequency domain to transmit data, the frequency domain is in the "Busy medium" state, and the wireless LAN terminal to transmit data waits for data transmission.

After that, when the "Busy medium" is terminated and no WLAN terminal 1-2 is used in the frequency domain, the WLAN terminal waits for the SIFS time. In this case, the SIFS is slightly longer than the IEEE 802.11 one slot time, and is a time for giving priority to another WLAN terminal to receive an ACK / CTS for the transmitted data packet / RTS.

Thereafter, when there is no transmission of ACK / CTS from another WLAN terminal during the SIFS time, the WLAN terminal waits until the PIFS time. Here, PIFS is a value obtained by adding slot time to SIFS, and is a time for giving priority to a point coordination function (PCF) over another distributed coordination function (DCF).

If data is not transmitted from another WLAN terminal during the PCF time, the WLAN terminal waits until the DIFS / AIFS time. Here, the DIFS time is equal to the value obtained by adding two slot times to the SIFS, and the AIFS means a value obtained by adding a slot time currently present in the SIFS. In the general 802.11 standard, it is common to have a wait time for AIFS [2] (50us (802.11b), 28us (802.11g)).

Thereafter, the WLAN terminal waits until its " Back_off " count is '0', and if its " Back_off " count is '0' first, the WLAN terminal has priority and transmits data. do.

If the "Back_off" count of another WLAN terminal is '0' first, the WLAN terminal has a priority to transmit data and transmits the data, and the WLAN terminal stops the "Back_off" count.

After that, wait for SIFS, PIFS, and DIFS / AIFS time again as described above, and then perform a "Back_off" count to transmit data with a priority of '0'.

However, the conventional wireless LAN system is to wait a certain time unconditionally through the general channel approach as described above even in an environment where other wireless LAN terminals do not operate. In other words, wait for AIFS [2] (DIFS) time when the "Busy medium" is terminated even when no other WLAN terminal is operating, and transmit the data when its "Back_off" count reaches "0". It was.

Therefore, there is a problem in that the wireless throughput is limited due to waiting for unnecessary AIFS (11b: 40us, 11g: 18us) even when no competition with other WLAN terminals is required.

Therefore, the present invention is to solve the above-mentioned conventional problems, an object of the present invention is to change the application of AIFS according to the presence of other WLAN terminals in the WLAN system around the wireless LAN that can improve the wireless throughput A wireless data processing apparatus and method in a system are provided.

According to an aspect of a wireless data processing apparatus in a wireless LAN system according to the present invention for achieving the above object, a monitoring unit for determining whether or not collision with at least one other wireless LAN terminal during data transmission, and the monitoring unit If there is no collision with another WLAN terminal through, the MAC control unit for changing the standard MAC channel approach to a shortened MAC channel approach.

Here, the monitoring unit determines whether an error occurs during data transmission and whether a preset number of retransmissions is exceeded.

Meanwhile, the MAC controller changes the setting of AIFS [N], which is a standard MAC channel approach, to AIFS [0] or AIFS [1] of a single WLAN terminal environment, or does not wait for a "Back_off" count in the standard MAC channel approach. It transmits data without changing data, or changes the setting of AIFS [N], which is a standard MAC channel approach, to AIFS [0] or AIFS [1] in a single WLAN terminal environment, and transmits data without waiting for the “Back_off” count.

The wireless data processing apparatus in the WLAN system is applicable to at least one of a WLAN access point and a WLAN terminal.

Meanwhile, the monitoring unit determines whether a data error and a retransmission request are generated in the shortened MAC channel approach, and when a data error and a retransmission request occurs in the shortened MAC channel approach, the MAC controller is a standard MAC in the shortened MAC channel approach. Change to the channel approach.

According to an aspect of a wireless data processing method in a wireless LAN system according to the present invention, determining whether or not a collision with another wireless LAN terminal during data transmission; Determining whether to use a standard MAC channel access method when there is no collision with another WLAN terminal in the data collision determination step; And using the standard MAC channel approach in the MAC channel approach determination step, changing the standard MAC channel approach to a shortened MAC channel approach.

On the other hand, if a collision with another wireless LAN terminal is identified in the data collision determination step, it changes or maintains the standard MAC channel approach.

If the standard MAC channel approach is not used in the MAC channel approach determination step, the shortened MAC channel approach is maintained.

In this case, the shortened MAC channel approach may be configured to change AIFS [N], which is a standard MAC channel approach, to AIFS [0] or AIFS [1] in a single WLAN terminal environment, or “Back_off” in the standard MAC channel approach. Send data without waiting for a count, or change the setting of AIFS [N], a standard MAC channel approach, to AIFS [0] or AIFS [1] in a single WLAN terminal environment while simultaneously waiting for a "Back_off" count. send.

And at least one of a wireless LAN access point and a wireless LAN terminal.

According to an aspect of an apparatus for processing wireless data in a single WLAN system according to the present invention, a waiting time of AIFS is set to at least one of AIFS [N] to AIFS [0] or AIFS [1] in a standard MAC channel approach. It includes a MAC control unit for changing the.

And the MAC control unit further includes not waiting for the "Back_off" count in the MAC channel approach.

According to another aspect of a wireless data processing apparatus in a single WLAN system according to the present invention, a MAC control unit does not wait for a "Back_off" count in a MAC channel approach.

Hereinafter, exemplary embodiments of a wireless data processing apparatus and method in a WLAN system according to the present invention will be described in detail with reference to the accompanying drawings. At this time, it will be understood by those of ordinary skill in the art that the system configuration described below is a system cited for the purpose of the present invention and does not limit the present invention to the following system.

1 is a diagram illustrating a configuration of a wireless data processing apparatus in a wireless LAN system according to the present invention. The wireless data processing apparatus in the wireless LAN system according to the present invention includes a monitoring unit 100 and a MAC control unit 200. Include.

First, the monitoring unit 100 determines whether there is a collision with another WLAN terminal 1-2 during data transmission. At this time, the monitoring unit 100 determines whether an error occurs during data transmission and whether a preset number of retransmissions is exceeded.

Meanwhile, the monitoring unit 100 determines whether a data error and a retransmission request are generated in the shortened MAC channel approach.

The MAC controller 200 changes the standard MAC channel approach to a shortened MAC channel approach if there is no collision with another WLAN terminal 1-2 through the monitoring unit 100. At this time, in the MAC channel approach changed by the MAC control unit 200, the standard MAC channel approach as shown in FIG. 3A waits for a waiting time of DIFS / AIFS (AIFS [N]), and is shown in FIG. 3B. The shortened MAC channel approach as described above waits for the latency of DIFS / AIFS (AIFS [0] or AIFS [1]).

Meanwhile, the MAC controller 200 transmits data without waiting for the "Back_off" count in the standard MAC channel approach as shown in FIG. 3C, or waits for AIFS in the standard MAC channel approach as shown in FIG. 3D. It is also possible to change the time setting from AIFS [N] to at least one of AIFS [0] or AIFS [1] and transfer data without waiting for the "Back_off" count.

If a data error and a retransmission request are generated in the shortened MAC channel approach, the MAC controller 200 changes from the shortened MAC channel approach to the standard MAC channel approach.

Such a wireless data processing apparatus in the WLAN system of the present invention is applicable to at least one of a WLAN access point and a WLAN terminal.

General functions and detailed operations of the above-described elements will be omitted, and the operations will be described based on operations corresponding to the present invention.

First, an operation process for improving the wireless throughput by controlling only the AIFS by the WLAN terminal 1-1 will be described.

The monitoring unit 100 of the WLAN terminal 1-1 determines whether there is a collision with another WLAN terminal 1-2 based on whether an error occurs during data transmission and a preset number of retransmissions before data transmission. At this time, the monitoring unit 100 of the WLAN terminal 1-1 checks the collision with another WLAN terminal 1-2 from the conventional MAC method.

If there is no collision with another WLAN terminal 1-2 through the monitoring unit 100 of the WLAN terminal 1-1, the MAC controller 200 of the WLAN terminal 1-1 is standard. Change the MAC channel approach to the shorter MAC channel approach. That is, the MAC controller 200 changes the setting of the waiting time of AIFS from at least one of AIFS [N] to AIFS [0] or AIFS [1] in the standard MAC channel approach.

Then, the WLAN terminal 1-1 intending to transmit the data checks the frequency domain to which the data is to be transmitted.

If the other wireless LAN terminal 1-2 uses the frequency domain to transmit data, the frequency domain is in a "Busy medium" state, and the wireless LAN terminal 1-1 to transmit data is sent to the wireless terminal. Wait for the transfer.

After that, when the " Busy medium " is terminated and no WLAN terminal 1-2 is used in the frequency domain, the WLAN terminal 1-1 displays data for SIFS time as shown in FIG. 3B. Wait for the transmission of.

If there is no transmission of ACK / CTS from another WLAN terminal 1-2 during the SIFS time, the WLAN terminal 1-1 waits until the PIFS time.

If no data transmission is made from another WLAN terminal during the PCF time, the WLAN terminal 1-1 does not wait for an AIFS [N] time, but only waits until an AIFS [0] or AIFS [1] time. .

Thereafter, the WLAN terminal 1-1 waits until its "Back_off" count becomes "0", and when its "Back_off" count reaches "0" first, the WLAN terminal (1--1). 1) has priority and transmits data. Accordingly, the WLAN terminal 1-1 may transmit data by shortening the time of AIFS [N]-(AIFS [0] or AIFS [1]).

Thereafter, the monitoring unit 100 of the WLAN terminal 1-1 determines whether a data error and a retransmission request are generated in the shortened MAC channel approach.

If a data error and a retransmission request are generated in the shortened MAC channel approach, the MAC controller 200 changes from the shortened MAC channel approach to the standard MAC channel approach. That is, the general standard MAC method is used.

Meanwhile, an operation process of improving wireless throughput by the WLAN terminal 1-1 not performing a "Back_off" count in the wireless data processing apparatus in the WLAN system according to the present invention will be described.

First, the monitoring unit 100 of the WLAN terminal 1-1 determines whether there is a collision with another WLAN terminal 1-2 based on whether an error occurs during data transmission and a preset number of retransmissions before data transmission. .

Here, if there is no collision with another WLAN terminal 1-2 through the monitoring unit 100 of the WLAN terminal 1-1, the MAC control unit 200 of the WLAN terminal 1-1 is a standard. Change the MAC channel approach to the shorter MAC channel approach. That is, the MAC controller 200 transmits data without waiting for the "Back_off" count in the standard MAC channel approach.

Then, the WLAN terminal 1-1 intending to transmit the data checks the frequency domain to which the data is to be transmitted.

If the other wireless LAN terminal 1-2 uses the frequency domain to transmit data, the frequency domain is in a "Busy medium" state, and the wireless LAN terminal 1-1 to transmit data is sent to the wireless terminal. Wait for the transfer.

After that, when the " Busy medium " is terminated and no WLAN terminal 1-2 is used in the frequency domain, the WLAN terminal 1-1 displays data for SIFS time as shown in FIG. 3C. Wait for the transmission of.

If there is no transmission of ACK / CTS from another WLAN terminal 1-2 during the SIFS time, the WLAN terminal 1-1 waits until the PIFS time.

If no data transmission is made from another WLAN terminal during the PCF time, the WLAN terminal 1-1 waits until AIFS [N] time.

After that, the WLAN terminal 1-1 transmits data without waiting for its " Back_off " count. Accordingly, the WLAN terminal 1-1 may transmit data by shortening the time for the time of its "Back_off" count.

Thereafter, the monitoring unit 100 of the WLAN terminal 1-1 determines whether a data error and a retransmission request are generated in the shortened MAC channel approach.

If a data error and a retransmission request are generated in the shortened MAC channel approach, the MAC controller 200 changes from the shortened MAC channel approach to the standard MAC channel approach. That is, the general standard MAC method is used.

On the other hand, in the wireless data processing apparatus of the wireless LAN system according to the present invention will be described the operation of the wireless LAN terminal 1-1 to improve the wireless throughput by controlling the AIFS and not "Back_off" count Shall be.

First, the monitoring unit 100 of the WLAN terminal 1-1 determines whether there is a collision with another WLAN terminal 1-2 based on whether an error occurs during data transmission and a preset number of retransmissions before data transmission. .

Here, if there is no collision with another WLAN terminal 1-2 through the monitoring unit 100 of the WLAN terminal 1-1, the MAC control unit 200 of the WLAN terminal 1-1 is a standard. Change the MAC channel approach to the shorter MAC channel approach. That is, AIFS [N], which is a standard MAC channel approach, may be changed to AIFS [0] or AIFS [1] in a single WLAN terminal environment, and data may be transmitted without waiting for the “Back_off” count.

Then, the WLAN terminal 1-1 intending to transmit the data checks the frequency domain to which the data is to be transmitted.

If the other wireless LAN terminal 1-2 uses the frequency domain to transmit data, the frequency domain is in a "Busy medium" state, and the wireless LAN terminal 1-1 to transmit data is sent to the wireless terminal. Wait for the transfer.

After that, when the " Busy medium " is terminated and no WLAN terminal 1-2 is used in the frequency domain, the WLAN terminal 1-1 displays data for an SIFS time as shown in FIG. 3D. Wait for the transmission of.

If there is no transmission of ACK / CTS from another WLAN terminal 1-2 during the SIFS time, the WLAN terminal 1-1 waits until the PIFS time.

If no data transmission is made from another WLAN terminal during the PCF time, the WLAN terminal 1-1 does not wait for AIFS [N] time, but only waits for AIFS [0] or AIFS [1] time. .

After that, the WLAN terminal 1-1 transmits data without waiting for its " Back_off " count. Accordingly, the WLAN terminal 1-1 may transmit data by shortening the time for the time of its "Back_off" count as well as the time of AIFS [N]-(AIFS [0] or AIFS [1]). .

Thereafter, the monitoring unit 100 of the WLAN terminal 1-1 determines whether a data error and a retransmission request are generated in the shortened MAC channel approach.

If a data error and a retransmission request are generated in the shortened MAC channel approach, the MAC controller 200 changes from the shortened MAC channel approach to the standard MAC channel approach. That is, the general standard MAC method is used.

Such a wireless data processing apparatus in the WLAN system of the present invention is applicable to at least one of a WLAN access point and a WLAN terminal.

Next, a wireless data processing method in a WLAN system including at least one WLAN terminal according to the present invention having the above configuration will be described with reference to FIG. 2.

First, the WLAN terminal 1-1 determines whether a collision with another WLAN terminal 1-2 occurs during data transmission (S1). At this time, the step (S1) is determined based on whether an error occurs during data transmission and the preset number of retransmissions.

At this time, if there is no collision with another WLAN terminal 1-2 in the data collision determination step (S1) (NO), the WLAN terminal 1-1 determines whether the standard MAC channel access method is used. (S2).

If the standard MAC channel access method is used in the MAC channel access method determination step (S2) (YES), the WLAN terminal 1-1 changes the standard MAC channel access method to the shortened MAC channel access method ( S3). At this time, the step of changing the standard MAC channel approach to the shortened MAC channel approach (S2) is a standard MAC channel approach to wait for AIFS [N] time as shown in FIG. Likewise, the configuration changes to a shortened MAC channel approach that only waits for AIFS [0] or AIFS [1] time.

At this time, the step of changing the standard MAC channel approach to the shortened MAC channel approach (S2) is a standard MAC channel approach to wait for the AIFS [N] time as shown in FIG. A shortened MAC channel approach that transmits data without waiting for the "Back_off" count as shown, or a shortened way of sending data without waiting for the "Back_off" count and waiting only for AIFS [0] or AIFS [1] time, as shown in Figure 3b. You can change to the MAC channel approach.

On the other hand, if a collision with another WLAN terminal 1-2 is detected in the data collision determination step (S1) (NO), the WLAN terminal 1-1 maintains a standard MAC channel access method (S4). ).

On the other hand, if the MAC channel access method determination step (S2) does not use the standard MAC channel access method (NO), the WLAN terminal 1-1 maintains the shortened MAC channel access method (S5).

The wireless data processing method in the WLAN system is applicable to at least one of a WLAN access point and a WLAN terminal.

A process of checking a frequency domain for transmitting data by a WLAN terminal in a single WLAN system according to the present invention will be described.

First, the MAC controller of the WLAN terminal waits for only the AIFS [0] or AIFS [1] time as shown in FIG. 3B. Change the configuration to the shortened MAC channel approach.

Then, the WLAN terminal 1-1 intending to transmit the data checks the frequency domain to which the data is to be transmitted.

If the other wireless LAN terminal 1-2 uses the frequency domain to transmit data, the frequency domain is in a "Busy medium" state, and the wireless LAN terminal 1-1 to transmit data is sent to the wireless terminal. Wait for the transfer.

After that, when the "Busy medium" is terminated and no WLAN terminal 1-2 is used in the frequency domain, the WLAN terminal 1-1 waits for data transmission during the SIFS time.

If there is no transmission of ACK / CTS from another WLAN terminal 1-2 during the SIFS time, the WLAN terminal 1-1 waits until the PIFS time.

If no data transmission is made from another WLAN terminal during the PCF time, the WLAN terminal 1-1 does not wait for an AIFS [N] time, but only waits until an AIFS [0] or AIFS [1] time. .

Thereafter, the WLAN terminal 1-1 waits until its "Back_off" count becomes "0", and when its "Back_off" count reaches "0" first, the WLAN terminal (1--1). 1) has priority and transmits data. Accordingly, the WLAN terminal 1-1 may transmit data by shortening the time of AIFS [N]-(AIFS [0] or AIFS [1]).

And the MAC control unit further includes not waiting for the "Back_off" count in the MAC channel approach.

Then, the WLAN terminal 1-1 transmits data without waiting for its " Back_off " count. Accordingly, the WLAN terminal 1-1 may transmit data by shortening the time for the time of its "Back_off" count as well as the time of AIFS [N]-(AIFS [0] or AIFS [1]). .

On the other hand, according to another aspect of the wireless data processing apparatus in a single WLAN system according to the present invention, in the MAC channel access method includes a MAC controller that does not wait for the "Back_off" count.

Then, the WLAN terminal 1-1 intending to transmit the data checks the frequency domain to which the data is to be transmitted.

If the other wireless LAN terminal 1-2 uses the frequency domain to transmit data, the frequency domain is in a "Busy medium" state, and the wireless LAN terminal 1-1 to transmit data is sent to the wireless terminal. Wait for the transfer.

After that, when the "Busy medium" is terminated and no WLAN terminal 1-2 is used in the frequency domain, as shown in FIG. 3C, the WLAN terminal 1-1 performs data during SIFS time. Wait for the transmission of.

If there is no transmission of ACK / CTS from another WLAN terminal 1-2 during the SIFS time, the WLAN terminal 1-1 waits until the PIFS time.

If no data transmission is made from another WLAN terminal during the PCF time, the WLAN terminal 1-1 waits until AIFS [N] time.

After that, the WLAN terminal 1-1 transmits data without waiting for its " Back_off " count. Accordingly, the WLAN terminal 1-1 may transmit data by shortening the time for the time of its "Back_off" count.

Although the present invention has been described in detail only with respect to the specific embodiments described, it will be apparent to those skilled in the art that various changes and modifications can be made within the technical spirit of the present invention, and such modifications and modifications belong to the appended claims. .

According to the wireless data processing apparatus and method in the WLAN system according to the present invention as described above, by changing the setting of the MAC channel approach in an environment where packet transmission fails or retransmission does not wait for unnecessary waiting time Being able to transmit data has an excellent effect of improving the wireless throughput of the WLAN system.

Claims (15)

In a wireless data processing apparatus in a wireless LAN system, A monitoring unit to determine whether or not there is a collision with at least one other WLAN terminal during data transmission; And a MAC controller for changing a standard MAC channel approach to a shortened MAC channel approach if there is no collision with another WLAN terminal through the monitoring unit. The method of claim 1, The monitoring unit, An apparatus for processing wireless data in a WLAN system that determines whether an error occurs during data transmission and whether a predetermined number of retransmissions is exceeded. The method of claim 1, The MAC control unit, Wireless data processing apparatus in a WLAN system for changing the setting of the AIFS standby time from AIFS [N] to at least one of AIFS [0] or AIFS [1] in a standard MAC channel approach. The method of claim 3, wherein The MAC control unit, A wireless data processing apparatus in a WLAN system that transmits data without waiting for a "Back_off" count in a standard MAC channel approach. The method of claim 1, The MAC control unit, A wireless data processing apparatus in a WLAN system that transmits data without waiting for a "Back_off" count in a standard MAC channel approach. The method of claim 1, The wireless data processing apparatus in the wireless LAN system, An apparatus for processing wireless data in a WLAN system applicable to at least one of a WLAN access point and a WLAN terminal. The method of claim 1, The monitoring unit, A wireless data processing apparatus in a WLAN system, characterized in that it is determined whether a data error and a retransmission request occurs in the shortened MAC channel approach. The method of claim 7, wherein And confirming that a data error and a retransmission request are generated in the shortened MAC channel approach through the monitoring unit, the MAC controller changes from the shortened MAC channel approach to the standard MAC channel approach. In the wireless data processing method in a wireless LAN system, Determining whether there is a collision with another WLAN terminal during data transmission; Determining whether to use a standard MAC channel access method when there is no collision with another WLAN terminal in the data collision determination step; And And using the standard MAC channel approach in the determining of the MAC channel access method, changing the standard MAC channel approach to a shortened MAC channel approach. The method of claim 9, If the collision with the other WLAN terminal is determined in the data collision determination step, the wireless data processing method comprising the step of changing or maintaining the standard MAC channel access method. The method of claim 9, If the MAC channel access method is not used in the determining of the MAC channel access method, maintaining the shortened MAC channel access method. The method of claim 9, The shortened MAC channel approach in the step of changing the standard MAC channel approach to the shortened MAC channel approach, A wireless data processing method in a WLAN system for changing the setting of the AIFS waiting time from at least one of AIFS [N] to AIFS [0] or AIFS [1]. The method of claim 12, The shortened MAC channel approach in the step of changing the standard MAC channel approach to the shortened MAC channel approach, A method of processing wireless data in a WLAN system that transmits data without waiting for a "Back_off" count in a standard MAC channel approach. The method of claim 9, The shortened MAC channel approach in the step of changing the standard MAC channel approach to the shortened MAC channel approach, A method of processing wireless data in a WLAN system that transmits data without waiting for a "Back_off" count in a standard MAC channel approach. The method of claim 9, Wireless data processing method in the WLAN system, A wireless data processing method in a WLAN system applicable to at least one of a WLAN access point and a WLAN terminal.

Images