KR20080075957A - Apparatus and method for selecting tranmission mode in multi-antenna system - Google Patents

Abstract

An apparatus and a method for selecting transfer modes in a multi-antenna system are provided to increase the gain of system capacity by comparing MPRs(Modulation order Product code Rates) dependent on the channel states of multi-antenna transfer modes and applying a suitable multi-antenna transfer mode according to a channel environment. If a signal is received from a base station(401), a terminal obtains the CINR(Carrier to Interference and Noise Ratio) of a diversity mode and the CINR of a spatial multiplexing mode, based on the preamble or pilot signal contained in the received signal(403). Then the terminal confirms MPRs dependent on the obtained CINRs respectively(405). The terminal compares the MPR of the diversity mode with the MPR of the spatial multiplexing mode(407). If the MPR of the spatial multiplexing mode is higher than the MPR of the diversity mode, the terminal selects the spatial multiplexing mode(409). In case the MPR of the spatial multiplexing mode is lower than or equal to the MPR of the diversity mode, however, the terminal selects the diversity mode(413). Then the terminal reports the selected mode to the base station(411).

Description

Apparatus and method for selecting a transmission method in a multi-antenna system {APPARATUS AND METHOD FOR SELECTING TRANMISSION MODE IN MULTI-ANTENNA SYSTEM}

1 is a block diagram of a terminal in a multi-antenna system according to the present invention;

2 is a block diagram of a base station in a multi-antenna system according to the present invention;

3 is a block diagram illustrating a detailed block configuration of a transmission mode control unit in a multiple antenna system according to the present invention;

4 is a diagram illustrating an operation procedure of a terminal in a multi-antenna system according to an embodiment of the present invention;

5 is a diagram illustrating an operation procedure of a base station in a multi-antenna system according to an embodiment of the present invention;

6 is a diagram illustrating a signal-to-interference and noise ratio graph in a multi-antenna system according to an embodiment of the present invention; and

7 is a diagram illustrating an MPR graph according to signal-to-interference and noise ratio according to an embodiment of the present invention.

The present invention relates to an apparatus and method for selecting a transmission method in a multi-antenna system, and to an apparatus and method for selecting a transmission method according to a modulation order product code rate (MPR) in the multi-antenna system.

Due to the rapid growth of the wireless mobile communication market, various multimedia services are required in a wireless environment. Accordingly, in order to provide the multimedia service, a research on a multi-antenna system (for example, MIMO (Multiple Input Multiple Output)) capable of efficiently using a limited frequency is being conducted as the capacity of transmission data and the speed of data transmission are increased. .

The multi-antenna system transmits data by using independent channels for each antenna to increase transmission reliability and transmission rate compared to a single antenna system without additional frequency or transmission power allocation. That is, the multi-antenna system may improve system performance through diversity gain and may improve transmission rate through multiplexing gain.

In the multi-antenna system, when the spatial multiplexing transmission scheme is used to improve the transmission rate, the base station transmits different data for each stream according to a transmission antenna. In this case, the terminal may reduce the gain due to interference between the data received through the stream.

Therefore, when the interference between the streams is small according to the channel environment of the streams, the multi-antenna system may obtain the capacity gain by using the spatial multiplexing transmission scheme. If the multi-antenna system does not have a good channel condition and uses the spatial multiplexing transmission scheme in a channel environment where inter-stream interference is large, the system may reduce capacity gain due to the inter-stream interference. In this case, the multi-antenna system can obtain a stable link although the capacity gain is not large by using a diversity transmission scheme.

As described above, the multi-antenna system has a difference in gain obtained by using a diversity transmission method and a spatial multiplexing transmission method according to a channel environment. Therefore, the multi-antenna system needs a technique for selectively using a transmission scheme according to a channel environment.

Accordingly, an object of the present invention is to provide an apparatus and method for selecting a transmission scheme according to a modulation order product code rate (MPR) in a multi-antenna system.

Another object of the present invention is to provide an apparatus and method for selecting a transmission scheme using MPR according to a multiple antenna transmission scheme at a receiving end of a multiple antenna system.

Another object of the present invention is to provide an apparatus and method for selecting the transmission scheme by comparing the MPR before and after the transmission scheme change in the transmission stage when the receiver requests a change of the multiple antenna transmission scheme in the multiple antenna system. In providing.

According to a first aspect of the present invention for achieving the above object, a method for selecting a transmission scheme at a receiving end of a multiple antenna system, each of the transmission scheme using a signal received through at least one antenna from the transmitting end Checking the channel information of the receiver, checking the Modulation Order Product Code Rate (MPR) according to each transmission scheme using the channel information, and comparing the MPR according to the transmission scheme to transmit the high MPR. And selecting a method, and transmitting the selected transmission method to the transmitter.

According to a second aspect of the present invention, a method for selecting a transmission method in a transmitting end of a multi-antenna system includes: checking a transmission method requested by the receiving end in a signal received from a receiving end; When the transmission method is changed, a process of transmitting a signal to the receiving end by changing the transmission method, checking and comparing a Modulation Order Product Code Rate (MPR) before and after the transmission method is changed, and changing the transmission method If the previous MPR is larger than the changed MPR, the method may include changing the transmission scheme before the change of the transmission scheme.

According to a third aspect of the present invention, a receiving end device of a multi-antenna system includes a receiver for receiving a signal through at least one antenna, and a channel estimator for checking channel information according to each transmission method using the received signal. A transmission method determiner for determining a transmission method using a modulation order product code rate (MPR) according to each transmission method identified using the channel information, and a feedback control unit for transmitting the determined transmission method to the transmitting end; Characterized in that comprises a.

According to a fourth aspect of the present invention, a transmitting end apparatus of a multi-antenna system includes a feedback receiving unit receiving a feedback signal from a receiving end and confirming a transmission method, and controlling the transmitting unit according to the confirmed transmission method, Is changed, the transmission control unit for resetting the transmission method by comparing the modulation order product code rate (MPR) before and after the change, and the signal to the receiving end using at least two transmission antennas under the control of the transmission control unit Characterized in that it comprises a transmission unit for transmitting.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, a description will be given of a technique for selecting the transmission scheme according to a modulation order product code rate (MPR) according to a multiple antenna transmission scheme in a multi-antenna system.

In the multi-antenna system, a UE uses a preamble or pilot signal received from a base station to determine a carrier to interference and noise ratio (hereinafter referred to as CINR) of the diversity transmission method and the spatial multiplexing transmission method. Can be calculated. In other words, the base station transmits the preamble and the pilot in the same structure regardless of the multiple antenna transmission scheme. That is, the base station transmits only traffic differently according to the multi-antenna transmission scheme. Accordingly, the terminal can estimate the CINR of the diversity transmission method and the spatial multiplexing transmission method through the preamble or the pilot signal.

Accordingly, in the following description, the terminal selects the multi-antenna transmission method by comparing the diversity transmission scheme identified through the received signal with the MPR according to the CINR of the spatial multiplexing transmission scheme.

1 is a block diagram of a terminal in a multi-antenna system according to the present invention.

As shown in FIG. 1, the terminal includes a multi-antenna receiver 101, a demodulator 103, a decoder 105, a channel estimator 107, a transmission mode determiner 109, and a feedback controller 111. do.

The multi-antenna receiver 101 detects reception information from a signal received through the reception antennas from the base station. For example, when the base station transmits a signal using a diversity transmission scheme, the multi-antenna receiver 101 detects the reception information using the diversity transmission scheme. If the base station transmits a signal using the spatial multiplexing transmission scheme, the multi-antenna receiver 101 detects the reception information using the spatial multiplexing transmission scheme.

The demodulator 103 demodulates the received signal provided from the multi-antenna receiver 101 according to the MPR. The decoder 105 decodes the demodulated signal provided from the demodulator 103 according to the MPR.

The channel estimator 107 calculates a CINR of a diversity transmission method and a spatial multiplexing transmission method by using a preamble or a pilot signal of the received signal detected by the multi-antenna receiver 101. For example, the channel estimator 107 may calculate the CINR of the diversity transmission method using Equation 1 using channel information estimated through the preamble or pilot signal.

Here, the CINR _D represents the CINR of the diversity transmission scheme, the H _i represents a channel of the i-th stream, and the W _i represents a weight of the i-th stream.

The CINR calculated using Equation 1 has a CINR characteristic similar to that of a single input multiple output (hereinafter referred to as SIMO). That is, when the diversity transmission scheme is used in the multi-antenna system, as shown in FIG. 6, the multi-antenna system has a CINR characteristic similar to that of the SIMO scheme.

6 illustrates a signal to interference and noise ratio graph in a multi-antenna system according to an exemplary embodiment of the present invention. Here, the horizontal axis represents CINR and the vertical axis represents Cumulative Density Function.

Referring to FIG. 6, (a) and (b) of FIG. 6 compare CINRs of the SIMO scheme, diversity transmission scheme or spatial multiplex transmission scheme when the frequency reuse factor is 1.

6 (c) and 6 (d) compare CINRs of the SIMO scheme, the diversity scheme or the spatial multiplexing scheme when the frequency reuse factor is three.

As shown in (a) and (c) of FIG. 6, when the diversity transmission scheme is used in the multi-antenna system, it has a CINR similar to that of the SIMO scheme.

As shown in (b) and (d) of FIG. 6, when the spatial multiplexing transmission scheme is used in the multi-antenna system, interference between the streams has a lower CINR than that of the SIMO scheme.

As described above, when the diversity transmission scheme is used in the multi-antenna system, the channel estimator 107 has a CINR of the diversity transmission scheme as shown in Equation 2 since it has a CINR characteristic similar to that of the SIMO scheme. Can be calculated.

Here, the CINR _D represents the CINR of the diversity transmission scheme, the H represents a channel with the base station, and the h _i represents a channel of the i-th stream.

In addition, the channel estimator 107 may calculate the CINR of the spatial multiplex transmission scheme as shown in Equation 3 using channel information estimated through the preamble or pilot signal.

Here, the CINR _i represents the CINR of the i-th stream, and the CINR _AVR is the CINR of the spatial multiplexing transmission scheme, and represents the average of the CINRs of the first and second streams. In addition, H _i represents the channel of the i-th stream, and W _i represents the weight of the i-th stream.

The transmission mode determiner 109 determines the MPR according to the CINR of the diversity transmission scheme and the spatial multiplexing transmission scheme provided from the channel estimator 107 and determines the multi-antenna transmission scheme to request to the base station. For example, the transmission mode determiner 109 uses a MPR graph according to the CINR as shown in FIG. 7 to provide a multi-antenna transmission scheme having a higher MPR according to the CINR of the diversity transmission method and the spatial multiplexing transmission method. Select.

7 illustrates an MPR graph according to signal-to-interference and noise ratio according to an embodiment of the present invention. Here, the horizontal axis represents CINR and the vertical axis represents MPR.

Referring to FIG. 7, (a) of FIG. 7 shows an MPR according to the CINR of the diversity transmission scheme, and (b) of FIG. 7 shows an MPR according to the CINR of the spatial multiplex transmission scheme. In this case, the MPR of the spatial multiplexing transmission method represents N × MPR because different data is transmitted for each stream.

As shown in (a) and (b) of FIG. 7, the diversity transmission scheme and the spatial multiplexing transmission scheme in each CINR have different MPRs.

Accordingly, the transmission mode determiner 109 may determine the multi-antenna transmission method using the MPR identified in FIGS. 7A and 7B.

The feedback controller 111 feeds back the multiple antenna transmission scheme determined by the transmission mode determiner 109 to the base station.

2 is a block diagram of a base station in a multiple antenna system according to the present invention.

As shown in FIG. 2, the base station includes an encoder 201, a modulator 203, a de-multiplexer 205, a multiple antenna transmitter 207, a transmission mode controller 209, and a feedback receiver 211. It is configured to include).

The encoder 201 codes and outputs data to be transmitted to the terminal according to the MPR. The modulator 203 modulates and outputs the signal provided from the encoder 201 according to the MPR.

The demultiplexer 205 demultiplexes the complex signals provided from the modulator 203 to transmit through N _T transmit antennas.

The multi-antenna transmitter 207 transmits a signal provided from the demultiplexer 205 to the terminal through the transmit antennas under the control of the transmission mode controller 209. That is, the multi-antenna transmitter 207 modulates and transmits the signal provided from the demultiplexer 205 in the diversity transmission method or the spatial multiplex transmission method under the control of the transmission mode controller 209.

The transmission mode control unit 209 controls the multi-antenna transmission method of the multi-antenna transmission unit 207 by comparing the MPR according to the multi-antenna transmission mode and the multi-antenna transmission method provided from the feedback receiver 211. At this time, the transmission mode control unit 209 is configured as shown in FIG.

3 is a detailed block diagram of a transmission mode control unit in a multiple antenna system according to the present invention.

As shown in FIG. 3, the transmission mode controller 209 includes an MPR checker 310, an MPR comparator 320, and a transmission mode determiner 330.

When the terminal transmits the multi-antenna transmission scheme change signal according to the multi-antenna transmission scheme information provided from the feedback receiver 111, the MPR checker 310 determines the MPR before and after the change of the multi-antenna transmission scheme. Check it. At this time, the MPR checking unit 310 checks the MPR using the CQI (Channel Quality Indicator) fed back from the terminal before and after the change of the multi-antenna transmission scheme in the MPR table shown in FIG. Here, the MPR checker 310 calculates an average of the MPR for a predetermined time.

For example, when the base station is requested to use the spatial multiplexing transmission scheme from the terminal when using the diversity transmission scheme, the base station operates in the spatial multiplexing transmission scheme. In this case, the MPR checker 310 calculates an MPR average for the diversity transmission method using the CQI fed back from the terminal for a predetermined time before the change to the spatial multiplexing transmission method. Thereafter, the MPR checking unit 310 calculates an MPR average for the spatial multiplexing transmission method by using the CQI fed back from the terminal for a predetermined time after the change to the spatial multiplexing transmission method.

The MPR comparator 320 compares the spatial multiplexing transmission scheme received from the MPR verification unit 310 with the MPR of the diversity transmission scheme and provides the MPR comparison unit to the transmission mode determination unit 330.

The transmission mode determiner 330 determines the multi-antenna transmission method of the multi-antenna transmitter 207 according to the multi-antenna transmission method desired by the terminal provided from the feedback receiver 111. Thereafter, the multi-antenna transmission method of the multi-antenna transmission unit 207 is determined again according to the MPR comparison value of the spatial multiplexing transmission method and the diversity transmission method provided from the MPR comparison unit 320. For example, when the base station receives a request for using the spatial multiplexing transmission scheme from the terminal when using the diversity transmission scheme, the transmission mode determination unit 330 determines the multiple antenna transmission scheme as the spatial multiplexing scheme and performs the multiplexing. The antenna transmitter 207 is controlled. Thereafter, the transmission mode determining unit 330 determines that the multi-antenna transmission method is a diversity transmission method when the MPR comparison value provided from the MPR comparison unit 320 is the MPR of the diversity transmission method. The multi-antenna transmitter 207 is controlled.

If the MPR comparison value provided from the MPR comparator 320 is larger than the MPR of the spatial multiplexing transmission scheme, the transmission mode determination unit 330 may be configured to maintain the spatial multiplexing transmission scheme. ).

The feedback receiving unit 211 checks the multi-antenna transmission mode desired by the terminal from the feedback signal received from the terminal and provides it to the transmission mode control unit 209.

Hereinafter, a description will be given of an operation method of a base station and a terminal of a multi-antenna system configured as described above.

4 is a flowchart illustrating an operation procedure of a terminal in a multi-antenna system according to an exemplary embodiment of the present invention.

Referring to FIG. 4, first, the terminal determines whether a signal is received from the base station in step 401.

If the signal is received, the terminal proceeds to step 403 to calculate a CINR according to a multi-antenna transmission scheme using a preamble or a pilot signal of the received signal. That is, the terminal calculates the CINR of the diversity transmission method and the spatial multiplexing transmission method by using the preamble or pilot signal included in the received signal. Here, the terminal calculates the CINR of the diversity transmission method using Equation 1 or Equation 2, and calculates the CINR of the spatial multiplexing transmission method using Equation 3. .

After calculating the CINR according to the multi-antenna transmission scheme, the terminal proceeds to step 405 to identify the MPR according to the CINR of each of the multi-antenna transmission schemes. Here, the terminal checks the MPR according to the CINR of the multi-antenna transmission method using the MPR graph according to the CINR shown in FIG. 7. In this case, the terminal may use the MPR table according to the CINR or calculate the MPR according to the CINR.

In step 407, the terminal compares the MPR of the diversity transmission scheme with the MPR of the spatial multiplex transmission scheme in order to select a multiple antenna transmission scheme.

If the MPR of the spatial multiplexing transmission scheme is larger than the MPR of the diversity transmission scheme (MPR _SM > MPR _D ), the terminal proceeds to step 409 and selects the multiple antenna transmission scheme as the spatial multiplexing transmission scheme.

On the other hand, if the MPR of the spatial multiplexing transmission scheme is less than or equal to the MPR of the diversity transmission scheme (MPR _SM ≤ MPR _D ), the terminal proceeds to step 413 to select the multi-antenna transmission scheme as the diversity transmission scheme. do.

After the multi-antenna transmission scheme is selected, the terminal proceeds to step 411 to feed back the selected multi-antenna transmission scheme to the base station.

Thereafter, the terminal terminates the present algorithm.

5 is a flowchart illustrating an operation procedure of a base station in a multi-antenna system according to an exemplary embodiment of the present invention.

Referring to FIG. 5, the base station proceeds to step 501 and checks whether a feedback signal is received from the terminal.

When the feedback signal is received, the base station proceeds to step 503 to identify the multi-antenna transmission method requested by the terminal in the feedback signal.

In step 505, the base station determines whether the multi-antenna transmission scheme is changed.

If the multi-antenna transmission scheme is changed, the base station proceeds to step 507 and switches the multi-antenna transmission scheme to the multi-antenna transmission scheme requested by the terminal.

After changing the multi-antenna transmission scheme, the base station checks the MPR before and after changing the transmission scheme in step 509. That is, the base station identifies the MPR using the CQI fed back from the terminal before and after the change of the multi-antenna transmission scheme in the MPR table as shown in FIG. Here, the MPR means an average of the MPR identified for a certain time. For example, when the base station is requested to use the spatial multiplexing transmission scheme from the terminal when using the diversity transmission scheme, the base station operates in the spatial multiplexing transmission scheme. In this case, the base station calculates an MPR average for the diversity transmission method by using the CQI fed back from the terminal for a predetermined time before changing to the spatial multiplexing transmission method. In addition, the base station calculates an MPR average for the spatial multiplexing transmission scheme using the CINR received from the terminal for a predetermined time after the change to the spatial multiplexing transmission scheme.

After checking the MPR before and after changing the multi-antenna transmission scheme, the base station proceeds to step 511 and compares the identified MPR to determine whether to maintain the changed multi-antenna transmission scheme at the request of the terminal.

If the MPR (= MPR ₁ ) before the multi-antenna transmission scheme change is greater than the MPR (= MPR ₂ ) after the change (MPR ₁ > MPR ₂ ), the base station proceeds to step 515 to resume the multi-antenna transmission scheme. Change it. For example, when the base station is requested to use the spatial multiplexing transmission scheme from the terminal when using the diversity transmission scheme, the base station changes the multiple antenna transmission scheme to the spatial multiplexing scheme. Thereafter, the base station compares the MPR of the diversity transmission scheme before the change of the multi-antenna transmission scheme with the MPR of the spatial multiplex transmission scheme after the change and maintains the spatial multiplexing transmission scheme when the MPR of the spatial multiplexing transmission scheme is large. .

If the MPR of the diversity transmission method is large, the base station changes the multi-antenna transmission method back to the diversity transmission method.

The base station then terminates this algorithm.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, in the multi-antenna system, a multi-antenna transmission method is selected by using the multi-antenna transmission method by comparing the modulation order product code rate (MPR) according to the channel state of the multi-antenna transmission method. There is an advantage that can be applied to increase the capacity gain of the system.

Claims (26)

In the method for selecting a transmission method at the receiving end of a multi-antenna system, Checking channel information of each transmission scheme by using a signal received from at least one antenna from a transmitting end; Identifying a Modulation Order Product Code Rate (MPR) according to each transmission scheme using the channel information; Comparing the MPR according to the transmission method to select a transmission method having a high MPR; And transmitting the selected transmission scheme to the transmitting end. The method of claim 1, The transmission method may include at least one of a diversity method and a spatial multiplexing method. The method of claim 1, The process of checking the channel information, Calculating a signal-to-interference and noise ratio (CINR) for each of the transmission schemes using the received signal. The method of claim 3, wherein The CINR of the diversity transmission method among the transmission methods is calculated using a CINR calculation method using a single input multiple output method. The method of claim 3, The CINR is calculated using a preamble or pilot included in the received signal. The method of claim 1, The MPR is identified in a table including the MPR for each channel information of the transmission scheme. The method of claim 1, The process of selecting the transmission method, When the MPR of the diversity transmission method is greater than or equal to the MPR of the spatial multiplexing transmission method, selecting the diversity transmission method; If the MPR of the spatial multiplexing transmission method is larger than the MPR of the diversity transmission method, selecting the spatial multiplexing transmission method. In the method for selecting a transmission method at the transmitting end of a multi-antenna system, Checking a transmission scheme requested by the receiver from a signal received from a receiver; When the transmission method is changed, changing the transmission method and transmitting a signal to the receiving end; Checking and comparing the Modulation Order Product Code Rate (MPR) before and after the transmission scheme is changed; If the MPR before the change of the transmission method is larger than the MPR after the change, changing the transmission method before the change of the transmission method. The method of claim 8, The transmission method may include at least one of a diversity method and a spatial multiplexing method. The method of claim 8, The process of checking the MPR, If the transmission method is changed, checking the MPR before changing the transmission method by using channel information received from the receiver before the transmission method is changed; And after the transmission method is changed, checking the MPR after the transmission method is changed by using channel information received from the receiving end. The method of claim 8, The MPR is characterized in that the average of the MPR to the channel information received from the receiving end for a predetermined time. The method of claim 8, The MPR is identified in a table including the MPR for each channel information of the transmission scheme. The method of claim 8, And if the MPR before the change of the transmission method is less than or equal to the MPR after the change, maintaining the transmission method. In the receiving end device of a multi-antenna system, A receiver which receives a signal through at least one antenna, A channel estimator for checking channel information according to each transmission method using the received signal; A transmission method determiner for determining a transmission method using a modulation order product code rate (MPR) according to each transmission method identified using the channel information; And a feedback controller for transmitting the determined transmission scheme to the transmitter. The method of claim 14, The transmission method may include at least one of a diversity method and a spatial multiplexing method. The method of claim 14, The channel estimator, And calculating a signal-to-interference and noise ratio (CINR) for each of the transmission schemes using the received signal. The method of claim 16, The channel estimator is characterized in that for calculating the CINR for the diversity transmission method using a CINR calculation method of a single input multiple output (Single Input Multiple Output) method. The method of claim 14, The channel estimator, characterized in that for verifying the channel information for each of the transmission scheme using a preamble (Preamble) or a pilot (Pilot) included in the received signal. The method of claim 14, The transmission method determiner, Identify the MPR for each transmission scheme in a table including the MPR for each channel information of the transmission scheme, Compare the MPR to the transmission scheme and select a transmission scheme with a higher MPR. In the transmitting end device of a multi-antenna system, A feedback receiver for receiving a feedback signal from a receiver and confirming a transmission method; A transmission control unit for controlling the transmission unit according to the confirmed transmission method and resetting the transmission method by comparing a Modulation Order Product Code Rate (MPR) before and after the change when the transmission method is changed; And a transmitter for transmitting a signal to the receiver by using at least two transmit antennas under the control of the transmission controller. The method of claim 20, The transmission method may include at least one of a diversity method and a spatial multiplexing method. The method of claim 20, The transmission control unit, A transmission method determination unit which determines the transmission method of the transmitter according to the transmission method confirmed by the feedback control unit, and when the transmission method is changed, compares the MPR before and after the change and determines the transmission method again; If the transmission method is changed, the apparatus comprising a MPR check unit for checking the MPR before and after the transmission method is not changed to provide to the transmission method determination unit. The method of claim 22, The transmission method determination unit, When the transmission method is changed, comparing the MPR before and after the transmission method change received from the MPR checking unit, and if the MPR before the transmission method change is larger than the MPR after the change, changing to the transmission method before the change of the transmission method Device characterized in that. The method of claim 23, wherein The transmission method determination unit, If the transmission method is changed, And if the MPR before the transmission method change is less than or equal to the MPR after the change, the transmission method is maintained. The method of claim 22, The MPR check unit, When the transmission method is changed, confirm the channel information before and after the change of the transmission method provided from the feedback control unit, And applying the channel information to a table including the MPR for each channel information of the transmission scheme to identify the MPR before and after the transmission scheme change. The method of claim 22, The MPR check unit, characterized in that for calculating a mean of the MPR for the channel information received from the receiving end for a predetermined time.

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