KR101618075B1 - Apparatus and method for trnasmitting preamble in wireless communication system - Google Patents

Abstract

The present invention relates to an apparatus and method for reducing the PAPR of an SA preamble in a wireless communication system. In this case, a method for transmitting an SA preamble, a process for determining an SA preamble according to a frequency band to be used for transmitting information, and a process for determining an SA preamble PAPR ( The method includes the steps of determining a sequence to reduce a Peak to Average Power Ratio (PDU), updating a sequence of the SA preamble using the determined sequence, and transmitting the updated SA preamble to a receiving end do.

SA Preamble, Orthogonal Frequency Division Multiplexing (OFDM), Tone Dropping (TD), Peak to Average Power Ratio (PAPR), Block Cover Sequence (BCS)

Description

[0001] APPARATUS AND METHOD FOR TRANSMITTING PREAMBLE IN WIRELESS COMMUNICATION SYSTEM [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a preamble of a wireless communication system, and more particularly to a preamble of a secondary preamble (PAPR) for distinguishing a cell identifier in an OFDM (Orthogonal Frequency Division Multiplexing) To an apparatus and a method for reducing a peak to average power ratio.

Today, many wireless communication technologies are proposed as candidates for high-speed mobile communication. Among them, orthogonal frequency division multiplexing (OFDM) is recognized as the most promising next generation wireless communication technology. The OFDM scheme is a scheme for transmitting data using a multi-carrier. In this case, the transmitting end transmits a single data stream through a plurality of subcarriers, and thus has a problem of having a high PAPR characteristic.

When the OFDM scheme is used, the base station transmits a synchronization channel to the mobile station in order to distinguish between time synchronization and base station. Herein, the synchronization channel is referred to as a preamble.

In this case, the terminal acquires time synchronization with the base station through the synchronization channel received from the base station, and can identify the base station to which the terminal belongs. At this time, the location where the synchronization channel is transmitted is predefined between the BS and the MS. For example, the Institute of Electrical and Electronics Engineers (IEEE) 802.16m, which adopts OFDM technology as a standard, uses a PA (Primary Advanced) preamble and an SA preamble. At this time, the PA preamble is used for time synchronization, and the SA preamble is used for demarcating the base station.

As described above, when a preamble is transmitted for time synchronization and base station identification of a base station, the base station converts the sequence constituting the preamble into an OFDM symbol and transmits the OFDM symbol. This causes a problem that the PAPR of the SA preamble transmitted by the base station is high.

Accordingly, it is an object of the present invention to provide an apparatus and a method for reducing a Peak to Average Power Ratio (PAPR) of an SA preamble in a wireless communication system.

It is another object of the present invention to provide an apparatus and a method for designing a BCS (Block Cover Sequence) for reducing PAPR of an SA preamble in a wireless communication system.

It is still another object of the present invention to provide an apparatus and method for designing a BCS for reducing PAPR of an SA preamble when TD (tone dropping) is applied in a wireless communication system.

According to a first aspect of the present invention, there is provided a method for transmitting an SA preamble in a wireless communication system, the method comprising: determining an SA preamble according to a frequency band to be used for transmitting information; Determining a sequence for reducing a Peak to Average Power Ratio (PAPR) of an SA preamble in consideration of at least one of frequency bands, segments, and the number of antennas transmitting an SA preamble; Updating the sequence of the SA preamble, and transmitting the updated SA preamble to a receiving end.

According to a second aspect of the present invention, an apparatus for transmitting an SA preamble in a wireless communication system includes a preamble generator for determining an SA preamble according to a frequency band to be used for transmitting information, A sequence generator for determining a sequence for reducing a Peak to Average Power Ratio (PAPR) of an SA preamble in consideration of at least one of the number of antennas transmitting an SA preamble; And a transmitter for transmitting the updated SA preamble to a receiving end.

As described above, the PAPR of the SA preamble is reduced by transmitting the SA preamble using a BCS (Block Cover Sequence) designed to reduce the Peak to Average Power Ratio (PAPR) of the SA preamble in the wireless communication system There is an advantage to be able to.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

Hereinafter, a technique for reducing a Peak to Average Power Ratio (PAPR) of an SA preamble in a wireless communication system will be described.

In the following description, it is assumed that the wireless communication system uses the Institute of Electrical and Electronics Engineers (IEEE) 802.16m standard, but the present invention can be similarly applied to other wireless communication systems using the orthogonal frequency division multiplexing method.

Assuming that a fast Fourier transform (FFT) of 512 sizes is used when the frequency band used in the following description is 5 MHz, and assuming that a frequency band of 102 MHz is used when the frequency band used is 10 MHz, , And assumes that a 2048-size FFT is used when the frequency band used is 20 MHz. In the following description, the size and the frequency band of the FFT are used in the same sense.

FIG. 1 shows a configuration of an SA preamble in a wireless communication system according to an embodiment of the present invention.

1, the SA preamble 100 is composed of 8 subblocks (a, b, c, d, e, f, g, h) when the size of the FFT is 512. FIG. Here, the sub-block is composed of a binary sequence or a quarter sequence. For example, when the sub-block is composed of binary sequences, the sub-block is composed of a binary sequence having a length of 18. In another example, when the subblock is composed of a quarter sequence, the subblock may be composed of modulation symbols obtained by modulating a binary sequence with a QPSK modulation scheme.

When the size of the FFT is extended, the SA preamble used in the extended FFT is configured such that the subblocks constituting the SA preamble 100 used in the FFT size of 512 are repeated. That is, when the frequency band is extended, the SA preamble used in the extended frequency band has a structure in which subblocks constituting the SA preamble 100 used at 5 MHz are repeated. For example, when the size of the FFT is 1024, the SA preamble 110 is configured by repeating eight subblocks constituting the SA preamble 100 used in the FFT size of 512 times.

For example, when the size of the FFT is 2048, the SA preamble 120 is configured by repeating eight subblocks constituting the SA preamble 100 used in the FFT size of 512 times three times.

As described above, the SA preamble has a structure in which subblocks are repeated. In this case, the transmitting end designates the BCS to reduce the PAPR of the SA preamble and applies it to the SA preamble. That is, each bit of the BCS is applied to each sub-block constituting the SA preamble. Accordingly, when the SA preamble of 5 MHz bandwidth is composed of 8 subblocks, the BCS is composed of 8 bits. When the SA preamble of 10 MHz bandwidth is composed of 16 subblocks, the BCS is composed of 16 bits. When the SA preamble is composed of 32 subblocks, the BCS is composed of 32 bits.

The BCS is designed as shown in Table 1 below considering the FFT size, the number of segments and the number of antennas transmitting the SA preamble.

FFT, number of antennas Segment ID 0 One 2 (512, 1) 00 00 00 (512, 2) 22 22 37 (512, 4) 09 01 07 (512, 8) 00 00 00 (1024, 1) 0FFF 555A 000F (1024, 2) 7373 3030 0000 (1024, 4) 3333 2D2D 2727 (1024, 8) 0F0F 0404 0606 (2048, 1) 08691485 1E862658 4D901481 (2048, 2) 7F55AA42 4216CC47 3A5A26D9 (2048, 4) 6F73730E 1F30305A 77000013 (2048, 8) 2F333319 0B2D2D03 0127271F

Table 1 shows BCS in hexadecimal. For example, when the size of the FFT to be used is 512, the segment is 0, and the SA preamble is transmitted using one antenna, the BCS for the corresponding SA preamble is 00. Here, 00, which is a hexadecimal number, can be expressed as '00000000' as a binary number. At this time, the transmitting end applies each bit of the BCS to each sub-block constituting the SA preamble. That is, the transmitting end applies 0, which is located at the first position of the BCS, to a, which constitutes the SA preamble used in the 512-size FFT, applies 0 to b, which is located at the second position, c, each bit of the BCS is sequentially applied to each sub-block constituting the SA preamble.

As described above, when each bit of the BCS is applied to each subblock constituting the SA preamble, if the subblock is composed of a binary sequence, the transmitting end transmits the sequence value of the subblock constituting the SA preamble and the bit value of the BCS 1 " to " 1 ". Then, the transmitting end multiplies the sequence value of the transformed sub-block by the bit value of the transformed BCS, and updates the SA preamble so that the PAPR is reduced.

On the other hand, when the subblock is composed of a quarter sequence, the transmitting end may apply the BCS bits to each subblock constituting the SA preamble to update the SA preamble so that the PAPR is reduced.

The wireless communication system can maintain the same subcarrier spacing in different frequency bands using tone dropping (TD).

Generally, the size of the FFT increases by a factor of two. That is, the size of the FFT increases from 512 to 1024 and increases from 1024 to 2048.

Accordingly, the wireless communication system can use a 512-sized FFT when using a frequency band of 5 MHz and maintain the same sub-carrier spacing using a 1024-sized FFT when using a frequency band of 10 MHz.

However, in the case of using the frequency band of 8.75 MHz, the transmitting end can not transmit information in the 8.75 MHz band using the FFT size of 1024 at sub-carrier intervals equal to the sub-carrier intervals when using 5 MHz and 10 MHz. In this case, the transmitting end can transmit information in the 8.75 MHz band using the same sub-carrier spacing as the sub-carrier spacing when using 5 MHz and 10 MHz using the TD scheme. For example, a transmitter using 8.75 MHz may have the same subcarrier spacing as that used in the 10 MHz band because it transmits information only in the 8.75 MHz band at 10 MHz and does not transmit information in the rest of the band. That is, the transmitter can map the information to only a portion corresponding to 8.75 MHz in the FFT used for information transmission, and can have the same subcarrier interval as that used in the 10 MHz band.

When TD is used as described above, the transmitting end can use the SA preamble configured as shown in FIG. 1 for classifying the BS. For example, if the used frequency band is 5 MHz or more and less than 10 MHz, the transmitting end uses the SA preamble 100 of the FFT size of 512 of FIG. 1. Also, when the frequency band used is 10 MHz or more and less than 20 MHz, the transmitting end uses the SA preamble 110 of the FFT size of 1024 in FIG. In this case, the transmitting end may use the BCS designed as shown in Table 1 to reduce the PAPR of the SA preamble.

As another example, when TD is used, the transmitting end may use an SA preamble configured as shown in FIG. 2 below.

FIG. 2 shows a configuration of an SA preamble when TD is used in a wireless communication system according to an embodiment of the present invention.

2, the SA preamble 200 is composed of 8 subblocks (a, b, c, d, e, f, g, h) when the size of the FFT is 512. FIG. Here, the sub-block is composed of a binary sequence or a quarter sequence. For example, when the sub-block is composed of binary sequences, the sub-block is composed of a binary sequence having a length of 18. In another example, when the subblock is composed of a quarter sequence, the subblock may be composed of modulation symbols obtained by modulating a binary sequence with a QPSK modulation scheme.

When the frequency band exceeding 5 MHz and less than 10 MHz is used in TD, the SA preamble is configured by expanding the SA preamble 200 used in the FFT size of 512 in units of subblocks at both ends with respect to DC. For example, if the frequency band exceeds 5 MHz and is 6.25 MHz or less, the SA preamble 202 adds one subblock to both ends of the subblocks constituting the SA preamble 200 of the FFT size of 512 . For example, if the frequency band is more than 6.25 MHz and less than or equal to 7.5 MHz, the SA preamble 204 is divided into two subblocks at both ends of the subblocks constituting the SA preamble 200 of the FFT size of 512, . For example, if the frequency band is more than 7.5 MHz and less than 10 MHz, the SA preamble 206 is divided into three subblocks at both ends of the subblocks constituting the SA preamble 200 of the FFT size of 512, .

When the size of the FFT is 1024, the SA preamble 210 consists of 8 subblocks constituting the SA preamble 200 of the FFT size of 512 times.

When using a frequency band exceeding 10 MHz and less than 20 MHz through TD, the SA preamble is constructed by expanding the SA preamble 210 of the FFT size of 1024 on both sides of the DC in units of subblocks. For example, when the frequency band is more than 10 MHz and less than or equal to 11.25 MHz, the SA preamble 210 adds one subblock to both ends of the subblocks constituting the SA preamble 210 of the FFT size of 1024 .

When the size of the FFT is 2048, the SA preamble 220 is configured by repeating eight sub-blocks constituting the SA preamble 200 of the FFT size of 512 three times.

When TD is used in the above-described embodiment, since the frequency band is extended in units of two sub-blocks, the frequency band is extended in units of 1.25 MHz and the same SA preamble is used in units of 1.25 MHz. That is, in the case of using the 7 MHz frequency band, the SA preamble 204 when the frequency band exceeds 6.25 MHz and is 7.5 MHz or less is used.

When TD is used as described above, the SA preamble is configured to be extended in units of subblocks. In this case, the transmitting end designates the BCS to reduce the PAPR of the SA preamble and applies it to the SA preamble. That is, each bit of the BCS is applied to each sub-block constituting the SA preamble. Accordingly, when TD is used, the BCS is designed to expand based on two sub-block units. For example, when the BCS for the SA preamble in the 5 MHz frequency band is composed of 8 bits, the BCS of the SA preamble 202 exceeding 5 MHz and used below 6.25 MHz is composed of 10 bits. In addition, the BCS of the SA preamble 204 exceeding 6.25 MHz and below 7.5 MHz is composed of 12 bits, and the BCS of the SA preamble 206 exceeding 7.5 MHz and used below 10 MHz is composed of 14 bits.

When TD is used as described above, the BCS may be composed of 10 bits, 12 bits, 14 bits according to the frequency band used. However, the BCS is represented by 16 bits as shown in Table 2 below. Accordingly, the BCS is set to a binary value of 0 for the remaining bits except for the bits (for example, 10 bits or 12 bits or 14 bits) constituting itself according to the used frequency band among 16 bits expressing itself.

For another example, when TD is used in a frequency band lower than 20 MHz, the BCS is extended to 18 bits, 20 bits, 22 bits, 24 bits, 26 bits, 28 bits, and 30 bits in the same manner as described above. However, the BCS is represented by 32 bits as shown in Table 2 below. Accordingly, the BCS is set to a binary value of 0 for the remaining bits excluding the bits constituting itself according to the frequency band used among the 32 bits expressing itself.

When TD is used, the BCS is designed as shown in Table 2 below, taking into consideration the bandwidth, the segment and the number of antennas transmitting the SA preamble.

BW _min , number of antennas Segment ID 0 One 2 (5, 1) 00 00 00 (5,2) 33 25 40 (5, 4) 14 40 51 (5,8) 00 00 00 (6.25,1) 0AA0 0FF8 0008 (6.25,2) 0F68 0650 0458 (6.25, 4) 0300 0300 0908 (6.25,8) 0140 0000 0100 (7.5,1) 000C 1008 0990 (7.5, 2) 0C24 1558 0F58 (7.5, 4) 1B08 030C 1904 (7.5, 8) 0140 0400 0510 (8.75,1) 0C10 229A 2554 (8.75,2) 335A 146C 3C10 (8.75, 4) 1320 0252 2406 (8.75, 8) 0140 0404 1514 (10, 1) 0FFF 555A 000F (10, 2) 7373 3030 0000 (10,4) 2323 5252 0404 (10,8) 4141 0404 1515 (11.25, 1) F7FDCEF3 29D51936 6B59CC03 (11.25, 2) 005A0F80 00000000 00000000 (11.25, 4) 00AF6A80 00E65280 00A45900 (11.25, 8) 00230000 00A30200 00090800 (12.5, 1) AC1AD967 602F7D20 96771160 (12.5, 2) 000F7000 01FF0000 00000040 (12.5, 4) 00AF6A80 00E65040 00C45900 (12.5, 8) 015B0940 00030C40 01190540 (13.75, 1) 4F56FD74 C0F7EEAD 55459EDB (13.75, 2) 012C1BA0 030177A0 02266200 (13.75, 4) 024C2400 03155920 01CF59A0 (13.75, 8) 009B0800 02830D20 02190420 (15, 1) DAD99B4F 96771160 CCF40660 (15, 2) 00CC5AB0 015411D0 020E0050 (15, 4) 038C2470 02D559C0 048F58D0 (15, 8) 009B0820 02830D10 06190420 (16.25, 1) 492F4A63 3785F431 AFCB95FD (16.25, 2) 065A5AD0 06543808 080F4C50 (16.25, 4) 0D335A70 01146C70 053C10D8 (16.25, 8) 09932018 0D025248 00240640 (17.5, 1) DD37B03D 81418C78 A47BAAA9 (17.5, 2) 10C36614 1B553644 0F9A5524 (17.5, 4) 19B35A4C 13146C44 03BC1030 (17.5, 8) 1223234C 09525248 1B04042C (18.75, 1) 56849127 7EBE7387 4B958D3A (18.75, 2) 2BA55AD4 029C6D58 13590072 (18.75, 4) 3D73734C 0F30306C 2B00000E (18.75, 8) 05232312 21525272 04040414

Table 2 represents BCS in hexadecimal. For example, when the bandwidth used is 6.25 MHz, the segment is 0, and the SA preamble is transmitted using one antenna, the BCS for the corresponding SA preamble becomes 0AA0. Here, 0AA0, which is a hexadecimal number, can be represented by '0000 1010 1010 0000' in binary numbers.

In the above-described embodiment, the transmitting end applies the newly designed BCS to the SA preamble for the SA preamble extended by using the TD.

In another embodiment, the transmission end may selectively use the BCS according to the bandwidth to which the SA preamble is transmitted or the number of subblocks used for data transmission in the BCS designed as shown in Table 2 above. For example, if the frequency band used is 10 MHz, but the bandwidth at which the SA preamble is transmitted is 6.25 MHz, the transmit end can use the BCS for 6.25 MHz. For another example, if the frequency band used is 10 MHz, but the number of subblocks to which the SA preamble is transmitted is equal to the number of subblocks corresponding to 6.25 MHz, the transmitting end may use the BCS for 6.25 MHz.

The following description explains a method for transmitting the PAPR of the SA preamble by lowering the BAP using the BCS at the transmitting end.

FIG. 3 shows a procedure for transmitting an SA preamble in a wireless communication system according to an embodiment of the present invention.

Referring to FIG. 3, the transmitting end determines a sequence of an SA preamble according to a frequency band to be used for transmitting information in step 301. FIG. For example, as shown in FIG. 1, the transmitting end repeats the subblocks constituting the SA preamble of the 5 MHz band to generate an SA preamble of the corresponding frequency band. As another example, the transmitting end may generate an SA preamble by expanding the frequency band extended through the used TD, in units of subblocks at both ends with respect to DC, as shown in FIG.

After determining the sequence of the SA preamble, the transmitter proceeds to step 303 and checks the size of the FFT, the segment, and the number of antennas that transmitted the SA preamble. Here, the size of the FFT means a used frequency band.

Then, the transmitting terminal proceeds to step 305 and checks whether the TD is used.

If the TD is used, the transmitting end proceeds to step 307 and determines the size of the FFT, the segment, and the number of antennas that transmit the SA preamble in the BCS table configured as shown in Table 2, Select BCS to reduce PAPR.

If the TD is not used, the transmitting end proceeds to step 313 and calculates the size of the FFT, the segment, and the number of antennas transmitting the SA preamble in the BCS table configured as shown in Table 1, The BCS is selected to reduce the PAPR.

After selecting the BCS for the SA preamble, the transmitting end proceeds to step 309 and applies each bit constituting the BCS to each subblock constituting the SA preamble. For example, an SA preamble transmitted using one antenna with a frequency band of 5 MHz and a segment of 0 is composed of eight subblocks (a, b, c, d, e, f, g and h) , And BCS has a value of 11011110 in binary number. In this case, the transmitting end applies 0, which is located first in the BCS, to a that constitutes the SA preamble, 0 is applied to the second position, and 0 is applied to the third position, Sequentially apply each bit of the BCS to each sub-block constituting the SA preamble.

After applying the BCS to the SA preamble, the transmitting end proceeds to step 311 and transmits the SA preamble to which the BCS is applied to the receiving end.

Thereafter, the transmitting end ends the present algorithm.

In the above embodiment, the transmitting end selects a BCS for reducing the PAPR of the SA preamble in consideration of the size of the FFT, the segment, and the number of antennas transmitting the SA preamble.

In another embodiment, the transmitting end may select a BCS to reduce the PAPR of the SA preamble in consideration of the bandwidth to which the SA preamble is transmitted, the segment, and the number of antennas that have transmitted the SA preamble.

In another embodiment, the transmitting end may select a BCS for reducing the PAPR of the SA preamble in consideration of the number of subblocks to which the SA preamble is transmitted, the number of segments and the number of antennas transmitting the SA preamble.

As described above, when each bit of the BCS is applied to each subblock constituting the SA preamble, the transmitting end converts 0 to 1 in the sequence value of the subblock constituting the SA preamble and the bits of the BCS, -1. Thereafter, the transmitting end multiplies the converted sequence value by the converted bit value, and updates the SA preamble so that the PAPR is reduced.

The following description explains the configuration of a transmitting end for transmitting the PAPR of the SA preamble by lowering using the BCS.

4 shows a block diagram of a transmission end for transmitting an SA preamble according to the present invention.

4, the transmission terminal includes a duplexer 400, a receiver 410, a controller 420, and a transmitter 430.

The duplexer 400 transmits a transmission signal provided from the transmitter 430 through the antenna according to the duplexing scheme and provides a reception signal from the antenna to the receiver 410. [

The receiver 410 includes an RF processor 411, an analog / digital converter (ADC) 413, an OFDM demodulator 415, and a decoder 417.

The RF processor 411 converts the high frequency signal received from the duplexer 400 into a baseband analog signal. The analog-to-digital converter 413 converts the analog signal provided from the RF processor 411 into digital sample data and outputs the digital sample data.

The OFDM demodulator 415 converts the time-domain sample data supplied from the A / D converter 413 through the Fourier transform to frequency-domain data and outputs the data. For example, the OFDM demodulator 415 transforms time-domain sample data into frequency-domain data through fast Fourier transform.

The decoder 417 demodulates and decodes the signal provided from the OFDM demodulator 415 according to a predetermined modulation level (MCS level).

The control unit 420 controls the overall operation of the transmission terminal and transmission of control information. For example, the controller 420 controls to apply the BCS provided from the BCS generator 424 to the SA preamble provided from the preamble generator 422. For example, the control unit 420 applies each bit constituting the BCS to each sub-block constituting the SA preamble. For example, an SA preamble transmitted using one antenna with a frequency band of 5 MHz and a segment of 0 is composed of eight subblocks (a, b, c, d, e, f, g and h) , And BCS is a binary number having a value of 00000000. At this time, the controller 420 applies 0, which is the first bit of the BCS, to the a that constitutes the SA preamble, 0 that is the second bit is applied to b, and 0 that is the third bit is applied to c Sequentially applies each bit of the BCS to each sub-block constituting the SA preamble.

When applying each bit of the BCS to each subblock constituting the SA preamble, the controller 420 converts 0 to 1 in the sequence value of the subblock constituting the SA preamble and the bit value of the BCS, -1. Thereafter, the control unit 420 multiplies the converted sequence value by the converted bit value, and updates the SA preamble so that the PAPR is reduced.

The preamble generator 422 generates an PA preamble for time synchronization of a receiving end and an SA preamble for identification of the PA preamble. For example, as shown in FIG. 1, the preamble generator 422 repeats the subblocks constituting the SA preamble of the 5 MHz band to generate an SA preamble of the corresponding frequency band. For example, the preamble generator 422 may generate an SA preamble by expanding the frequency band extended through the TD used in units of subblocks on both sides of the DC have. At this time, the preamble generator 422 receives the sub-block information constituting the SA preamble from the storage unit 426. Here, the size of the FFT is used in the same meaning as the frequency band.

The BCS generator 424 calculates the number of antennas that transmit the size of the FFT, the number of segments and the number of antennas that transmit the SA preamble, and outputs the preamble to the preamble generator 422 among the BCSs included in the BCS table provided from the storage unit 426 Select the BCS for the generated SA preamble. For example, when TD is not used, the BCS generator 424 calculates the size of the FFT, the number of segments and the number of antennas that transmit the SA preamble in the BCS table configured as shown in Table 1, The BCS is selected to reduce the PAPR. Here, the size of the FFT is used in the same meaning as the frequency band.

Meanwhile, when TD is used, the BCS generator 424 calculates the PAPR of the SA preamble in consideration of the size of the FFT, the segment, and the number of antennas that transmit the SA preamble in the BCS table configured as shown in Table 2 Select the BCS to reduce.

The storage unit 426 stores sub-block information and a BCS table for generating an SA preamble.

The transmitter 430 includes an encoder 431, an OFDM modulator 433, a digital / analog converter (DAC) 435, and an RF processor 437.

The encoder 431 codes and modulates a transmission signal or control information according to a modulation level (MCS level). For example, the encoder 431 codes and modulates an SA preamble applied with the BCS provided from the controller 420 according to a modulation level (MCS level).

The OFDM modulator 433 converts the frequency domain data provided from the encoder 431 into sample data (OFDM symbol) in the time domain through an inverse Fourier transform and outputs the transformed data. For example, the OFDM modulator 433 transforms the frequency domain data into the time domain sample data (OFDM symbol) through an inverse fast Fourier transform.

The digital-to-analog converter 435 converts the sample data supplied from the OFDM modulator 433 into an analog signal and outputs the analog signal. The RF processor 437 converts the baseband analog signal supplied from the digital-to-analog converter 433 into a high frequency signal and outputs the converted high frequency signal.

In the above-described embodiment, the wireless communication system can maintain the same subcarrier interval in different frequency bands using TD. At this time, since the inverse of the subcarrier space represents a symbol duration, the subcarrier space may be expressed as a symbol interval. That is, the wireless communication system can maintain the same symbol interval in different frequency bands using TD.

In addition, in the above-described embodiment, the BCS generator 424 calculates the number of BCSs included in the BCS table provided from the storage unit 426, considering the size of the FFT, the segment and the number of antennas transmitting the SA preamble, And selects a BCS for the SA preamble generated by the preamble generating unit 422. [

In another embodiment, the BCS generator 424 may calculate the BCS of the BCS included in the BCS table provided from the storage unit 426 considering the bandwidth, the segment, and the number of antennas transmitting the SA preamble, The BCS for the SA preamble generated by the preamble generator 422 can be selected.

In another embodiment, the BCS generator 424 may include a BCS table provided from the storage unit 426 in consideration of the number of subblocks to which the SA preamble is transmitted, the number of segments and the number of antennas that transmit the SA preamble, The BCS for the SA preamble generated by the preamble generator 422 among the BCSs may be selected.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. Therefore, the scope of the present invention should not be limited by the illustrated embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

1 is a diagram showing a configuration of an SA preamble in a wireless communication system according to an embodiment of the present invention;

2 is a diagram illustrating a configuration of an SA preamble when a TD is used in a wireless communication system according to an embodiment of the present invention;

3 is a diagram illustrating a procedure for transmitting an SA preamble in a wireless communication system according to an embodiment of the present invention, and Fig.

4 is a block diagram of a transmission end for transmitting an SA preamble according to the present invention;

Claims (21)

A method for transmitting a secondary preamble (SA) in a wireless communication system, Determining an SA preamble configured in units of subblocks according to an FFT size to be used for transmitting information; Determining a block cover sequence based on the FFT size, the segment ID, and the number of antennas; Updating the SA preamble using the determined block cover sequence; And transmitting the updated SA preamble. 2. The method of claim 1, wherein the step of determining the SA preamble comprises: Repeating basic sub-blocks according to the FFT size; And generating the SA preamble including the repeated basic subblocks. 2. The method of claim 1, wherein the step of determining the SA preamble comprises: And generating the SA preamble by removing subblocks at both ends of the SA preamble in the reference frequency band according to the FFT size when tone dropping (TD) is used. The apparatus of claim 3, wherein the SA preamble of the reference frequency band comprises: A SA preamble in the 10 MHz band, and an SA preamble in the 20 MHz band. 2. The method of claim 1, wherein the step of determining the block cover sequence comprises: Checking whether tone dropping (TD) is used, Selecting one of at least two tables including a block cover sequence according to whether the TD is used; Selecting a block cover sequence in consideration of the FFT size, the segment ID, and the number of antennas transmitting the SA preamble in the selected table. 6. The method of claim 5, If TD is not used, a table configured as shown in Table 3 below, which includes a block cover sequence defined by the FFT size, the segment ID, and the number of antennas transmitting the SA preambles, is selected &Lt; / RTI > FFT, number of antennas Segment ID 0 One 2 (512, 1) 00 00 00 (512, 2) 22 22 37 (512, 4) 09 01 07 (512, 8) 00 00 00 (1024, 1) 0FFF 555A 000F (1024, 2) 7373 3030 0000 (1024, 4) 3333 2D2D 2727 (1024, 8) 0F0F 0404 0606 (2048, 1) 08691485 1E862658 4D901481 (2048, 2) 7F55AA42 4216CC47 3A5A26D9 (2048, 4) 6F73730E 1F30305A 77000013 (2048, 8) 2F333319 0B2D2D03 0127271F 6. The method of claim 5, Table 4 < tb > &lt; TABLE &gt; Id = Table 4 Columns = 4 &lt; tb &gt; &lt; tb &gt; &lt; TABLE &gt; And selecting the table. BW _min , number of antennas Segment ID 0 One 2 (5, 1) 00 00 00 (5,2) 33 25 40 (5, 4) 14 40 51 (5,8) 00 00 00 (6.25,1) 0AA0 0FF8 0008 (6.25,2) 0F68 0650 0458 (6.25, 4) 0300 0300 0908 (6.25,8) 0140 0000 0100 (7.5,1) 000C 1008 0990 (7.5, 2) 0C24 1558 0F58 (7.5, 4) 1B08 030C 1904 (7.5, 8) 0140 0400 0510 (8.75,1) 0C10 229A 2554 (8.75,2) 335A 146C 3C10 (8.75, 4) 1320 0252 2406 (8.75, 8) 0140 0404 1514 (10, 1) 0FFF 555A 000F (10, 2) 7373 3030 0000 (10,4) 2323 5252 0404 (10,8) 4141 0404 1515 (11.25, 1) F7FDCEF3 29D51936 6B59CC03 (11.25, 2) 005A0F80 00000000 00000000 (11.25, 4) 00AF6A80 00E65280 00A45900 (11.25, 8) 00230000 00A30200 00090800 (12.5, 1) AC1AD967 602F7D20 96771160 (12.5, 2) 000F7000 01FF0000 00000040 (12.5, 4) 00AF6A80 00E65040 00C45900 (12.5, 8) 015B0940 00030C40 01190540 (13.75, 1) 4F56FD74 C0F7EEAD 55459EDB (13.75, 2) 012C1BA0 030177A0 02266200 (13.75, 4) 024C2400 03155920 01CF59A0 (13.75, 8) 009B0800 02830D20 02190420 (15, 1) DAD99B4F 96771160 CCF40660 (15, 2) 00CC5AB0 015411D0 020E0050 (15, 4) 038C2470 02D559C0 048F58D0 (15, 8) 009B0820 02830D10 06190420 (16.25, 1) 492F4A63 3785F431 AFCB95FD (16.25, 2) 065A5AD0 06543808 080F4C50 (16.25, 4) 0D335A70 01146C70 053C10D8 (16.25, 8) 09932018 0D025248 00240640 (17.5, 1) DD37B03D 81418C78 A47BAAA9 (17.5, 2) 10C36614 1B553644 0F9A5524 (17.5, 4) 19B35A4C 13146C44 03BC1030 (17.5, 8) 1223234C 09525248 1B04042C (18.75, 1) 56849127 7EBE7387 4B958D3A (18.75, 2) 2BA55AD4 029C6D58 13590072 (18.75, 4) 3D73734C 0F30306C 2B00000E (18.75, 8) 05232312 21525272 04040414 The method of claim 1, wherein the updating of the SA preamble comprises: And updating the SA preamble by applying the determined block cover sequence to each subblock constituting the SA preamble. The method of claim 8, wherein the updating of the SA preamble comprises: Mapping each bit {0, 1} of the block cover sequence to a real number {+ 1, -1} And multiplying each bit of the block cover sequence by all sub-carriers in a corresponding sub-block of the SA preamble. An apparatus for transmitting a secondary preamble (SA) in a wireless communication system, A preamble generator for determining an SA preamble configured in units of subblocks according to an FFT size to be used for transmitting information, A sequence generator for determining a block cover sequence based on the FFT size, the segment ID, and the number of antennas; A controller for updating the SA preamble using the determined block cover sequence; And a transmitter for transmitting the updated SA preamble. The apparatus of claim 10, wherein the preamble generator comprises: Repeats the basic sub-blocks according to the FFT size, and generates the SA preamble including the repeated basic sub-blocks. The apparatus of claim 10, wherein the preamble generator comprises: Wherein when the tone dropping (TD) is used, subblocks at both ends of the SA preamble of the reference frequency band are removed based on the FFT size to generate an SA preamble of the corresponding frequency band. 13. The apparatus of claim 12, wherein the preamble generator comprises: And generates an SA preamble when TD is used by using at least one of the SA preamble of the 10 MHz band and the SA preamble of the 20 MHz band as the SA preamble of the reference frequency band. 11. The apparatus of claim 10, wherein the sequence generator comprises: Considering the FFT size, the segment ID, and the number of antennas transmitting the SA preamble in one table among at least two tables including a block cover sequence depending on whether tone dropping (TD) is used, And selects a cover sequence. 15. The apparatus of claim 14, wherein the sequence generator comprises: Table 5 < tb > &lt; TABLE &gt; Id = TABLE SA Columns = And selects a sequence for reducing the PAPR of the preamble. FFT, number of antennas Segment ID 0 One 2 (512, 1) 00 00 00 (512, 2) 22 22 37 (512, 4) 09 01 07 (512, 8) 00 00 00 (1024, 1) 0FFF 555A 000F (1024, 2) 7373 3030 0000 (1024, 4) 3333 2D2D 2727 (1024, 8) 0F0F 0404 0606 (2048, 1) 08691485 1E862658 4D901481 (2048, 2) 7F55AA42 4216CC47 3A5A26D9 (2048, 4) 6F73730E 1F30305A 77000013 (2048, 8) 2F333319 0B2D2D03 0127271F 11. The apparatus of claim 10, wherein the sequence generator comprises: Table 6 below shows a block cover sequence defined by the minimum value Bwmin of the channel bandwidth range when the TD is used, the segment ID, and the number of the antennas transmitting the SA preambles. And selects a sequence for reducing the PAPR of the SA preamble in the table. BW _min , number of antennas Segment ID 0 One 2 (5, 1) 00 00 00 (5,2) 33 25 40 (5, 4) 14 40 51 (5,8) 00 00 00 (6.25,1) 0AA0 0FF8 0008 (6.25,2) 0F68 0650 0458 (6.25, 4) 0300 0300 0908 (6.25,8) 0140 0000 0100 (7.5,1) 000C 1008 0990 (7.5, 2) 0C24 1558 0F58 (7.5, 4) 1B08 030C 1904 (7.5, 8) 0140 0400 0510 (8.75,1) 0C10 229A 2554 (8.75,2) 335A 146C 3C10 (8.75, 4) 1320 0252 2406 (8.75, 8) 0140 0404 1514 (10, 1) 0FFF 555A 000F (10, 2) 7373 3030 0000 (10,4) 2323 5252 0404 (10,8) 4141 0404 1515 (11.25, 1) F7FDCEF3 29D51936 6B59CC03 (11.25, 2) 005A0F80 00000000 00000000 (11.25, 4) 00AF6A80 00E65280 00A45900 (11.25, 8) 00230000 00A30200 00090800 (12.5, 1) AC1AD967 602F7D20 96771160 (12.5, 2) 000F7000 01FF0000 00000040 (12.5, 4) 00AF6A80 00E65040 00C45900 (12.5, 8) 015B0940 00030C40 01190540 (13.75, 1) 4F56FD74 C0F7EEAD 55459EDB (13.75, 2) 012C1BA0 030177A0 02266200 (13.75, 4) 024C2400 03155920 01CF59A0 (13.75, 8) 009B0800 02830D20 02190420 (15, 1) DAD99B4F 96771160 CCF40660 (15, 2) 00CC5AB0 015411D0 020E0050 (15, 4) 038C2470 02D559C0 048F58D0 (15, 8) 009B0820 02830D10 06190420 (16.25, 1) 492F4A63 3785F431 AFCB95FD (16.25, 2) 065A5AD0 06543808 080F4C50 (16.25, 4) 0D335A70 01146C70 053C10D8 (16.25, 8) 09932018 0D025248 00240640 (17.5, 1) DD37B03D 81418C78 A47BAAA9 (17.5, 2) 10C36614 1B553644 0F9A5524 (17.5, 4) 19B35A4C 13146C44 03BC1030 (17.5, 8) 1223234C 09525248 1B04042C (18.75, 1) 56849127 7EBE7387 4B958D3A (18.75, 2) 2BA55AD4 029C6D58 13590072 (18.75, 4) 3D73734C 0F30306C 2B00000E (18.75, 8) 05232312 21525272 04040414 11. The apparatus according to claim 10, And updates the SA preamble by applying the determined block cover sequence to each subblock constituting the SA preamble. 18. The apparatus of claim 17, Mapping each bit {0,1} of the block cover sequence to a real number {+ 1, -1}, and adding each bit of the block cover sequence to all subcarriers in a corresponding subblock of the SA preamble Thereby updating the SA preamble. 11. The apparatus of claim 10, further comprising: a storage unit including a table of block cover sequences for reducing at least two sub-block information constituting an SA preamble and a PAPR of at least one SA preamble. 3. The method of claim 2, wherein repeating the basic sub- When the FFT size is expanded from an FFT size of 512 to an FFT size of 1024, it includes one iteration, Wherein the FFT size comprises three iterations when extending from an FFT size of 512 to an FFT size of 2048. The method of claim &lt; RTI ID = 0.0 &gt; 1, &lt; / RTI &gt; 12. The apparatus of claim 11, wherein the preamble generator comprises: When the FFT size is expanded from an FFT size of 512 to an FFT size of 1024, the basic subblocks are repeated once, Wherein when the FFT size is expanded from an FFT size of 512 to an FFT size of 2048, the basic subblocks are repeated three times.

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