KR101386214B1 - Transmission and reception method for ACK/NAK signaling in wireless communication systems - Google Patents

Abstract

The present invention proposes a more efficient ACK / NAK signal transmission method in a wireless communication system system. The present invention provides a method for transmitting an ACK / NAK signal in a wireless communication system, comprising: (a) a resource block occupying one symbol on the time axis and occupying N sub-carriers greater than 2 and even on the frequency axis; Allocating the first resource block and the second resource block neighboring each other on a time axis to the terminal based on a basic unit; (b) allocating a sequence orthogonal to the N sub-frequency on the frequency axis to the terminal, wherein different terminals in the same cell have the same index value of the sequence, Cyclic delay) index values assign the sequence differently; And (c) if the ACK / NAK bit value of the codeword received by the terminal is 0, transmit the sequence only with the first resource block, and if the ACK / NAK bit value is 1, transmit the sequence with only the second resource block. It characterized in that it comprises a.

We propose a more efficient ACK / NAK transmission scheme by allocating sequences orthogonal to each other on the time axis.

OFDM, ACK / NAK, Sequence Transmission

Description

Transmission and reception method for ACK / NAK signaling in wireless communication systems

The present invention relates to a method for transmitting an ACK / NAK signal for data received in a mobile communication system.

The present invention is derived from the research conducted as part of the IT new growth engine core technology development project of the Ministry of Information and Communication and the Ministry of Information and Communication Research and Development. ].

The receiving side receiving data in the wireless mobile communication system sends an ACK signal when the received data is successfully demodulated and a NAK signal when the demodulation fails. The ACK / NAK signal is represented by one bit per codeword.

The ACK / NAK signal must be able to be transmitted simultaneously by multiple users using a given time and frequency resource. Such multiplexing techniques include frequency division multiplexing (FDM) and code division multiplexing (CDM).

FDM means that different users use different time / frequency resources. CDM, on the other hand, allows different users to distinguish between different users by using the same time / frequency resources but multiplying and transmitting specific codes.

In the uplink, many Zadoff-Chu sequences with good PAPR (Peak to Average Power Ratio) characteristics are used. Using this sequence, we can create orthogonality between users by cyclic delay instead of multiplying a specific code in the frequency domain.

The following describes a scheme proposed by Texas Instruments (TI) for uplink ACK / NACK signaling. The characteristics of the TI method are as follows.

As shown in FIG. 1, different users (UE1, UE2, etc.) use resources in different time / frequency domains. Each terminal is assigned a specific sequence from the base station. The terminal transmits an orthogonal code index different from the cyclic delay value of a specific sequence according to the ACK / NAK bit value. The base station detects an ACK / NAK bit value by detecting an orthogonal code index value such as a cyclic delay.

2 shows an example of time / frequency resources used by a terminal for uplink ACK / NAK signaling. For example, in the OFDM system as shown in FIG. 2, a resource block for data transmission occupies N sub-carriers on the frequency axis and one OFDM symbol on the time axis. A sequence transmitted using this resource block adds a cyclic delay to the assigned base sequence according to the ACK / NAK bit value.

If a resource block has a total of N sub-carriers, a sequence having a total of N mutually orthogonal cyclic delays can be generated.

The Zadoff-Chu sequence is described as an example.

Equation 1 shows a Zadoff-Chu sequence having a length of N, a primary index of m, and a cyclic delay index of q.

를 전송한다. 예를 들어, 하향링크 전송이 한 개의 부호어를 사용하면ACK/NAK은 1 비트가 된다. N= 12 인 경우에 비트값이 0 이면 q = n, 비트값이 1 이면 q = n + 6 으로 전송한다. n 값은 0, 1,..., 5 중에 하나를 미리 정해 놓아서 기지국과 단말이 서로 알고 있어야 한다.The terminal receives and uses a specific basic index m. Two q values are allocated and the sequence is transmitted with the q value determined according to the ACK / NACK bit value. kth subfrequency is a symbol

. For example, if downlink transmission uses one codeword, ACK / NAK becomes 1 bit. In the case of N = 12, if bit value is 0, q = n, and if bit value is 1, q = n + 6 is transmitted. The n value is one of 0, 1, ..., 5 and is determined in advance so that the base station and the terminal should know each other.

3 shows an example of time / frequency resources used by a terminal for uplink ACK / NAK signal transmission. As shown in FIG. 3, a resource used for one control channel is composed of two resource blocks separated from each other. These two resource blocks each occupy N sub-carriers on the frequency axis and occupy seven OFDM symbols corresponding to slots on the time axis. One slot has a time length of 0.5 ms.

A plurality of terminals may use one control channel in common. That is, in FIG. 3, various terminals may use the control channel A or B together. At this time, in order to distinguish a plurality of different terminals using the same control channel, each terminal is pre-assigned a specific code sequence. That is, each terminal makes and transmits a signal spread on the frequency axis using the assigned specific code sequence.

Various methods have been proposed for transmitting ACK / NAK signals in a wireless communication system. However, there is a need for an ACK / NAK scheme that reduces interference while efficiently using sub-frequency resources. In particular, considering the diversity characteristics, it is necessary to consider such a scheme because wireless communication efficiency can be further improved. That is, when the signals of the plurality of terminals are distinguished from each other by using codes spread on the frequency axis, a method in which the terminal modulates the symbols corresponding to the ACK / NAK information and transmits the symbols on the time axis and the base station demodulates the received signals. There is a need for a method of efficiently detecting ACK / NAK information.

Accordingly, in order to solve the above technical problem, a method of transmitting an ACK / NAK signal of a wireless communication system system is provided, which method (a) occupies N sub-carriers greater than 2 and even on the frequency axis. Allocating a first resource block and a second resource block neighboring each other on a time axis to a single terminal among resource blocks occupying one symbol on a time axis; (b) allocating a sequence orthogonal to the N sub-frequency on the frequency axis to the terminal; And (c) if the ACK / NAK bit of the codeword received by the terminal has a first binary value, transmits the sequence using only the first resource block, and if the ACK / NAK bit has a second binary value, the second resource And transmitting the sequence only by a block.

Preferably, the sequence is any one of a Discrete Fourier Transformation (DFT) vector, a Walsh-Hadamard sequence, and a Zadoff-Chu sequence.

In order to achieve the technical problem according to the present invention, a method for transmitting an ACK / NAK signal of a wireless communication system system, comprising: (a) occupying N sub-carriers greater than or equal to 2 on the frequency axis and Allocating a first resource block and a second resource block among the resource blocks occupying two symbols; (b) assigning a terminal to a sequence orthogonal to the N sub-frequency on the frequency axis and orthogonal code indices a and b of the sequence; And (c) a sequence having the orthogonal code index a in the first resource block and the orthogonal code index b in the second resource block if the ACK / NAK bit of the codeword received by the terminal is a first binary value. And transmitting a sequence having the orthogonal code index b to the first resource block and the orthogonal code index a to the second resource block if a / NAK bit is a second binary value. In ACK / NAK signal transmission method is provided.

Preferably, the sequence is any one of a Discrete Fourier Transformation (DFT) vector, a Walsh-Hadamard sequence, and a Zadoff-Chu sequence.

In order to solve another technical problem, the method for transmitting an ACK / NAK signal in a wireless communication system includes (a) N _{t, which} is greater than 2 on the frequency axis and an even number of N sub-carriers and is greater than 2 on the time axis. Allocating a resource block occupying two symbols; (b) allocating an orthogonal sequence to the N sub-frequency, and assigning each orthogonal sequence to each terminal to a resource block occupying the N _t symbols on a time axis; (c) setting, by the base station and each terminal, which of the sequences on the time axis to transmit according to the ACK / NAK bits; And (d) transmitting one of the sequences previously set by the base station and the terminal among the sequences on the time axis according to the ACK / NAK bit value of the codeword received by the terminal. An ACK / NAK signal transmission method is provided.

Preferably, the orthogonal sequence on the time axis is any one of a Discrete Fourier Transformation (DFT) vector, a Walsh-Hadamard sequence, and a Zadoff-Chu sequence.

Preferably, the orthogonal sequence on the frequency axis is any one of a Discrete Fourier Transformation (DFT) vector, a Walsh-Hadamard sequence, and a Zadoff-Chu sequence.

개의 시간적 영역으로 나누는 단계; (c) 시간 축 상으로 상기 L_c 길이를 갖는 상호직교 시퀀스를 할당하는 단계; 및 (d) 단말이 수신하는 부호어의 ACK/NAK 비트 값에 따라 상기 시퀀스 중 기지국과 상기 단말이 미리 설정한 어느 하나의 시퀀스를 전송하는 단계;를 포함하는 것을 특징으로 하는 무선통신 시스템의 ACK/NAK 신호 송신 방법이 제공된다. In order to solve the technical problem of the present invention (a) allocates a resource block occupying N sub-carriers greater than or equal to 2 on the frequency axis and occupying N _t symbols greater than or equal to 2 on the time axis Allocating an orthogonal sequence to each of the terminals on the frequency axis; (b) the N _t a coherent time is longer than the occurrence of smaller size than the sequence symbols coherent occurrence time allocated to resource blocks on the time axis L _c Divided by unit, total

Dividing into three temporal domains; (c) assigning an orthogonal sequence having the length L _c on the time axis; And (d) transmitting, according to the ACK / NAK bit value of the codeword received by the terminal, one of the sequences set by the base station and the terminal in advance. A / NAK signal transmission method is provided.

Preferably, each L _c The sequence mapping on the time axis within the unit is characterized in that different.

Preferably, L _c Provided are a method for transmitting an ACK / NAK signal of a wireless communication system, wherein resource blocks of a unit are positioned at a distance of one or more sub-frequency.

Preferably, the orthogonal sequence on the time axis is any one of a Discrete Fourier Transformation (DFT) vector, a Walsh-Hadamard sequence, and a Zadoff-Chu sequence.

)로 분할하는 단계; (c) 상기 시퀀스 단위 내의 4개의 시퀀스는 각각 4차원 DFT 행렬의 열 벡터에 해당하도록 QPSK 심볼을 포함하는 시퀀스로 구성하는 단계를 포함하되, ACK/NAK 비트 (0, 0)에 해당하는 시퀀스와 ACK/NAK 비트 (1, 1)에 해당하는 시퀀스의 상대적 위상차이가 0 혹은 π 이도록 하고; 및 (d) 상기 단말이 수신하는 부호어의 ACK/NAK 비트 값에 대응되는 시간 축 상의 시퀀스를 전송하는 단계;를 포함하는 것을 특징으로 한다. A noncoherent ACK / NAK signal transmission method of a wireless communication system system for achieving the above technical problem, (a) occupies N sub-carriers greater than 2 and even number on the frequency axis and time Allocating a resource block occupying N _t symbols on the axes to the terminals; (b) converting the sequence on the N _t time axes into four sequence units (

Dividing by; (c) configuring the four sequences in the sequence unit into a sequence including QPSK symbols such that each corresponds to a column vector of a four-dimensional DFT matrix, and includes a sequence corresponding to ACK / NAK bits (0, 0) and The relative phase difference of the sequence corresponding to the ACK / NAK bits (1, 1) is 0 or π; And (d) transmitting a sequence on a time axis corresponding to the ACK / NAK bit value of the codeword received by the terminal.

)될 수 있는 것을 특징으로 한다.Preferably, in step (b), when N _t is not a multiple of 4, one or more sequences of the four sequences are overlapped by consecutive sequence units (

It can be characterized in that).

Also preferably, in the step (c), when the ACK / NAK bit is 1 bit, the four sequences may correspond to a sequence corresponding to the ACK / NAK bit (0, 0) and a sequence corresponding to (1, 1). It is characterized by using it.

Preferably, the four consecutive sequence units have the same code sequence.

Preferably, the four consecutive sequence units are characterized by having different code sequences.

Preferably, frequency hopping is performed in the N _t sequences on the time axis.

In order to solve another technical problem of the present invention, there is provided a scheduling request transmission method of a wireless communication system, characterized in that the scheduling request (SR) transmission using the method described above.

Preferably, the terminal transmits the allocated sequence only when the scheduling request is made.

)로 분할하는 단계; (c) 상기 시퀀스 단위 내의 4개의 시퀀스는 길이 4의 Walsh-Hadamard 시퀀스로 구성하여 단말들에 할당하는 단계를 포함하되, ACK/NAK 비트 (0, 0)에 해당하는 시퀀스와 ACK/NAK 비트 (1, 1)에 해당하는 시퀀스의 시간 축 심볼의 상대적 부호가 1,-1로 교대로 바뀌도록 하고; 및 (d) 각 단말이 수신하는 부호어의 ACK/NAK 비트 값에 대응되는 시간 축 상의 시퀀스를 전송하는 단계;를 포함하는 것을 특징으로 한다. The noncoherent ACK / NAK signal transmission method of a wireless communication system system for solving the technical problem of the present invention, (a) occupies N sub-carriers (greater than 2 and even number on the frequency axis) Allocating a resource block occupying N _t symbols to one or more terminals on a time axis; (b) converting the sequence on the N _t time axes into four sequence units (

Dividing by; (c) the four sequences in the sequence unit comprise a Walsh-Hadamard sequence having a length of 4 and assigning them to terminals, the sequence corresponding to the ACK / NAK bits (0, 0) and the ACK / NAK bits ( The relative signs of the time axis symbols of the sequence corresponding to 1, 1) are alternately changed to 1, -1; And (d) transmitting a sequence on a time axis corresponding to the ACK / NAK bit value of the codeword received by each terminal.

)될 수 있는 것을 특징으로 한다.Preferably, in step (b), when N _t is not a multiple of 4, at least one of the four sequences is overlapped by a sequence unit that is continuous (

It can be characterized in that).

Preferably, in the step (c), when the ACK / NAK bit is 1 bit, the four sequences may be selected by a sequence corresponding to the ACK / NAK bit (0, 0) and a sequence corresponding to (1, 1). It is characterized by using.

Preferably, the four consecutive sequence units have the same code sequence.

Preferably, the continuous four sequence unit has a different code sequence, characterized in that the non-coherent ACK / NAK signal transmission method of the wireless communication system.

Preferably, frequency hopping is performed in the N _t sequences on the time axis.

In order to solve another technical problem of the present invention, there is provided a scheduling request transmission method of a wireless communication system, characterized in that the scheduling request (SR) transmission using the method described above.

According to the present invention, it is possible to efficiently perform transmission and reception of ACK / NAK signals in a wireless communication system.

In particular, various methods for reducing interference and improving diversity performance by allocating sequences to be orthogonal to each other on the time axis have been proposed. As a result, an ACK / NAK signal transmission method and apparatus for reducing interference and noise have been proposed.

Hereinafter, an ACK / NAK signal transmission / reception method in a wireless communication system according to the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, 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 they may vary depending on the intentions or customs of the client, the operator, the user, and the like. Therefore, the definition should be based on the contents throughout this specification.

The case of the uplink proposed by the present invention will be described below. The contents of the present invention will be described for the convenience of uplink but may be equally applicable to downlink.

Each terminal is pre-assigned a specific sequence. When using the Zadoff-Chu sequence, the default index m and the cyclic delay index q are preassigned. Different terminals in the same cell have the same basic index values and different cyclic delay index values.

One reason for using the Zadoff-Chu sequence for spreading on the frequency axis is that the Zadoff-Chu sequence has good cross-correlation properties, which is advantageous for interference control between adjacent cells.

In order for the Zadoff-Chu sequence to maintain good cross-correlation properties, N must be a prime number in Equation 1. However, currently considered resource blocks of the control channel occupies N 'sub-frequency on the frequency axis, N' is an even number greater than 2. In order to maintain good cross-correlation of the Zadoff-Chu sequence, if N is kept as a prime number, N and N 'values must be different, resulting in loss of orthogonality between different terminals in the same cell. Occurs. To compensate for this, we propose to use the following form of sequence.

Using the sequence described by Equation 2 has the advantage that orthogonality between different terminals in the same cell is maintained while maintaining the cross-correlation characteristic of the Zadoff-Chu sequence.

First, a first method will be described in a method for transmitting an ACK / NAK signal in a wireless communication system proposed by the present invention (method I).

First, each terminal is pre-assigned a specific sequence. When using the Zadoff-Chu sequence, the default index m and the cyclic delay index q are preassigned.

Different terminals in the same cell have the same basic index value and allocate orthogonal code index values such as cyclic delay index values differently. Resources used for ACK / NAK are shown in FIG. 4 as an example. The sequence is transmitted using only one of two blocks according to the ACK / NAK bit value.

For example, if the bit value is 0, the sequence allocated to block # 0 is transmitted and block # 1 transmits nothing. If the bit value is 1, the sequence allocated to block # 1 is transmitted. In block # 0, nothing is transmitted. This is shown in the table below.

ACK / NAK bit value S ₀ S ₁ 0 One 0 One 0 One

That is, Table 1 shows values of symbols according to ACK / NAK values in FIG. 4.

When the performance needs to be improved, two neighboring blocks on the time axis are used as one basic unit resource, and several basic unit resources are allocated and transmitted repeatedly in the time / frequency resource space. The code sequence on the frequency axis used for the basic unit resource may be different for each basic unit resource. In this case, diversity is expected due to the use of other code sequences, thereby improving performance.

Basic unit resources do not need to be adjacent to each other. If basic unit resources are configured to be spaced apart from each other in time / frequency resource space, performance can be expected to be obtained by obtaining frequency and time diversity.

Now, a second method will be described in a method for transmitting an ACK / NAK signal in a wireless communication system proposed by the present invention (method II).

Each terminal is pre-assigned a specific sequence. In the case of using the Zadoff-Chu sequence, two basic index m values and cyclic delay index values a and b are assigned in advance.

Different terminals in the same cell have the same basic index values and different cyclic delay index values.

Transmission resources used may be two blocks adjacent to each other on the time axis as shown in FIG. 5 or two blocks spaced apart from each other on the time axis and the frequency axis.

Different cyclic delay indexes are transmitted to each block according to the ACK / NAK bit value. In the example of Table 2, if the bit value is 0, a sequence having a cyclic delay index a is transmitted to block # 0. In block # 1, a sequence having a cyclic delay index b is transmitted.

If the ACK / NAK bit value is 1, a sequence having a cyclic delay index b is transmitted to block # 0, and a sequence having a cyclic delay index a is transmitted to block # 1.

As described above, interference averaging can be achieved by varying cyclic delay indices transmitted to blocks # 0 and # 1 according to specific bit values, thereby improving performance.

ACK / NAK bit value p q 0 a b One b a

Table 2 shows a cyclic delay index for each transport block according to the ACK / NAK value.

Using two blocks that are spaced apart from each other on the time and frequency axes yields frequency and time diversity, which is expected to improve performance. Two blocks become one basic unit resource, and code sequences on two frequency axes used for the basic unit resource may be allocated differently for each basic unit resource. That is, diversity can be obtained by changing the code sequence used for each basic unit resource, thereby improving performance.

Now let's look at the third approach (method III).

Each terminal is pre-assigned a specific sequence. When using the Zadoff-Chu sequence, the default index m and the cyclic delay index q are preassigned.

로 표현되는 시퀀스를 적용하는 구조이다. As shown in FIG. 6, a structure in which a sequence and a symbol are mapped to each time / frequency resource may be considered. This structure uses the Zadoff-Chu sequence on the frequency axis and is also orthogonal on the time axis.

It is a structure that applies the sequence represented by.

It is a feature of the present invention to vary the time axis sequence to transmit according to the ACK / NAK bit value. The base station and the terminal should know in advance the sequence to be transmitted according to the ACK / NAK bit value. The time axis sequence uses an orthogonal sequence.

When the total number of OFDM symbols continuous on the time axis _t N clear up, and the length of the sequence of N _t N _t may create sequences satisfying a perpendicular relation with each other between sequences.

라고 표현할 때 상호직교는 다음과 같은 의미이다.i-th sequence of row vector

In this regard, mutual orthogonal means:

The code sequence used in the time domain may use a Discrete Fourier Transformation (DFT) vector of length N _t , a Walsh-Hadamard sequence, a Zadoff-Chu sequence, or the like.

For example, when N _t = 2, G ₀ = [1, 1] and G ₁ = [1, -1] can be considered as code sequences that are orthogonal to each other. If the ACK / NAK bit value is 0, then the signal is transmitted using G ₀ = [1, 1]. If the ACK / NAK bit value is 1, the signal can be transmitted using G ₁ = [1, -1]. In this case, the values of S ₀ and S ₁ transmitted according to the ACK / NAK bit value are determined as shown in Table 3.

ACK / NAK bit value S ₀ S ₁ 0 +1 +1 One +1 -One

That is, Table 3 shows values of symbols according to ACK / NAK values when N _t = 2 in FIG. 3.

In general, the coherence time on the time axis depends mainly on the speed of the terminal. If the speed of the terminal is high, the coherence time is reduced, and the mutual orthogonality between the sequences may be broken at the receiver. Therefore, it is not desirable to use long sequences on the time axis.

The following describes a case where a total number of OFDM symbols is allocated for the ACK / NAK signal and is continuous on the time axis.

See FIG. 7 for details. In FIG. 7, let N _t be the total number of consecutive OFDM symbols on the time axis. All N _t symbols are divided in units of L _c OFDM symbols that are temporally contiguous. L _c should be smaller than the coherence time.

개의 시간 영역으로 나뉜다. 각 시간 영역을 시간에 순차적 순서로

라고 표시하자. 이때 시간 축 상에 적용하는 코드 시퀀스의 길이는 L_c로 한다. Thus, total N _t OFDM symbol areas total

Time zones. Each time zone in sequential order in time

Let's say In this case, the length of the code sequence applied on the time axis is L _c .

라고 표현할 수 있다. 각 시간영역에 해당하는 코드 시퀀스는 ACK/NAK 비트 값에 따라서 미리 정해놓아서 단말과 기지국이 서로 알고 있어야 한다. Where the i th sequence is a row vector of length L _c

. The code sequence corresponding to each time domain is determined according to the ACK / NAK bit value in advance so that the terminal and the base station should know each other.

The code sequence on the time axis to transmit according to the ACK / NAK bit value may be set to have the same mapping relationship in each time domain or may have a different mapping relationship. Performance gains can be expected by increasing the diversity compared to having the same mapping relationship with different mapping relationships.

For example, two time domains exist when N _t = 4 and L _c = 2, and G ₀ = [1, 1] and G ₁ = [are code sequences on mutually orthogonal time axes used in each time domain. 1, -1].

In the time domain T ₀ , if the ACK / NAK bit value is 0, it is transmitted using G ₀ = [1, 1], and if it is 1, the sequence G ₁ = [1, -1] is transmitted. In the time domain T ₁ , when the ACK / NAK bit value is 0, the data is transmitted using G ₁ = [1, -1], and when 1, G ₀ = [1, 1]. That is, the mapping relationship between the ACK / NAK bit value and the code sequence on the time axis may be different for each time domain. In this case, the values of S ₀ , S ₁ , S ₂ , and S ₃ transmitted according to the ACK / NAK bit values are determined as shown in Table 4.

That is, Table 4 is an example of the case where the mapping is different for each time domain (T ₀ , T ₁ ) when N _t = 4 and L _c = 2.

Alternatively, the mapping relationship between the ACK / NAK bit value and the code sequence on the time axis may be equal in all time domains. That is, if the ACK / NAK bit value is 0 in T ₀ , T ₁ , G ₀ = [1, 1] is transmitted using G ₀ = [1, -1]. In this case, the values of S ₀ , S ₁ , S ₂ , and S ₃ transmitted according to the ACK / NAK bit values are determined as shown in Table 5.

That is, Table 5 shows the case where the mapping is the same for each time domain (T ₀ , T ₁ ) when N _t = 4 and L _c = 2.

As shown in the example of Table 4, when a different mapping relationship is provided for each time domain, performance gain can be expected by increasing the diversity compared to having a mapping relationship as shown in Table 5.

In FIG. 7, the OFDM symbols in each time domain are preferably continuous in time. However, the time domains do not necessarily have to be contiguous with each other in time / frequency space. That is, if each symbol time a bundle of continuous symbol L _c dog the tie formed by the present separated from each other in the time / frequency space can be expected to effect debugging city. This diversity effect leads to an improvement in performance gain.

In time code sequences on the frequency axis is used for each bundle of continuous symbols the symbol L _c dog a tie formed may be assigned different symbol for each bundle. In this case, since code sequences on different frequency axes are used for each symbol bundle, a diversity effect occurs, and thus a performance gain can be expected.

Next, a noncoherent ACK / NAK transmission scheme proposed by the present invention will be described.

로 표현되는 시퀀스를 적용하는 구조이다. When using code division multiplexing (CDM) to distinguish between terminals, a structure in which sequences and symbols are mapped to respective time / frequency resources as shown in FIG. 6 may be considered. This structure uses the Zadoff-Chu sequence on the frequency axis and on the time axis.

It is a structure that applies the sequence represented by.

It is a feature of the present invention to vary the time axis sequence to transmit according to the ACK / NAK bit value. The base station and the terminal must know in advance the sequence to transmit according to the ACK / NAK bit value. The time axis sequence uses an orthogonal sequence.

The code sequence used in the time domain may use a Discrete Fourier Transformation (DFT) vector having a length of N _t , a Walsh-Hadamard sequence, a Zadoff-Chu sequence, and the like.

As an example, denote ACK / NAK information having two bits as (b ₀ , b ₁ ). In addition, if the i-th codeword received by the terminal is ACK, b _i = 0 and NAK, b _i = 1. Similarly, let ACK / NAK information having one bit is defined as b _0, and d is shown terminal receives a code word (codeword) an ACK if b ₀ = 0 b ₀ = 1 and the NAK.

The terminal transmits a time axis code sequence corresponding to each case. As a specific example, when N _t = 7, a preferred embodiment can be considered as follows. Consider below how to use the DFT vector as a time axis.

를 도 8의 QPSK 심볼을 사용하여 나타내고 있다. 8 shows a Quadrature Phase Shift Keying (QPSK) symbol in symbol space. Table 5 shows the sequence on the corresponding time axis according to the ACK / NAK bit value when transmitting two ACK / NAK bit information.

Is shown using the QPSK symbol of FIG.

를 보여준다. 표 6에서 처음 4개 심볼

에 대응되는 시퀀스는 상수 위상 팩터 (constant phase factor)만 다를 뿐 다름아닌 4x4 DFT 메트릭스의 각 열 벡터에 해당함을 알 수 있다. 그리고, 다음 4개의 심볼

에 대응되는 시퀀스도 상수 위상 팩터 (constant phase factor)만 다를 뿐 다름아닌 4x4 DFT 메트릭스의 각 열 벡터에 해당함을 알 수 있다. Table 6 shows the sequence on the corresponding time axis according to the ACK / NAK bit value when transmitting one ACK / NAK bit information.

Lt; / RTI > First four symbols in Table 6

It can be seen that the corresponding sequence corresponds to each column vector of the 4x4 DFT matrix except that the constant phase factor is different. And the next four symbols

It can be seen that the corresponding sequence also corresponds to each column vector of the 4x4 DFT matrix, except that the constant phase factor is different.

In particular, when comparing the sequence corresponding to (0, 0) and the sequence corresponding to (1, 1) in Table 6, the phase of the sequence corresponding to (1, 1) is in the sequence corresponding to (0, 0). It can be seen that relative phase differences at each time axis symbol position are 0, π, 0, π. By doing so, it is possible to lower the probability of incorrectly receiving (1, 1) as (0, 0) as compared with the probability of incorrectly receiving (1, 1) as (1, 0) or (0, 1).

를 보여준다. 표 1의 (0, 0)과 (1, 1)에 해당하는 두 개 시퀀스를 골라내어 1 비트 ACK/NAK 전송에 이용한다. 물론, (0, 1)와 (1, 0)에 해당하는 두 개 시퀀스를 골라 사용할 수도 있다. Table 7 shows a sequence on the corresponding time axis according to the ACK / NAK bit value when transmitting one ACK / NAK bit information.

Lt; / RTI > Two sequences corresponding to (0, 0) and (1, 1) in Table 1 are selected and used for 1-bit ACK / NAK transmission. Of course, two sequences corresponding to (0, 1) and (1, 0) may be selected and used.

However, as described above, it is not preferable to use a sequence corresponding to (0, 0) and (0, 1) or (0, 1) and (1, 1) in Table 1.

The base station and the terminal should know in advance the sequence to be used according to the number and the value of the ACK / NAK bits. The base station should know in advance whether the terminal performs 1-bit ACK / NAK transmission or 2-bit ACK / NAK transmission and detect the received signal according to each situation.

DFT vector method: 2-bit ACK / NAK ACK / NAK
Bit value
(b ₀ , b ₁ ) S ₀ S ₁ S ₂ S ₃ S ₄ S ₅ S ₆ (0, 0) Q ₀ Q ₀ Q ₀ Q ₀ Q ₀ Q ₀ Q ₀ (0, 1) Q ₁ Q ₂ Q ₃ Q ₀ Q ₁ Q ₂ Q ₃ (1, 1) Q ₂ Q ₀ Q ₂ Q ₀ Q ₂ Q ₀ Q ₂ (1, 0) Q ₃ Q ₂ Q ₁ Q ₀ Q ₃ Q ₂ Q ₁

ACK / NAK
Bit value b ₀ S ₀ S ₁ S ₂ S ₃ S ₄ S ₅ S ₆ 0 Q ₀ Q ₀ Q ₀ Q ₀ Q ₀ Q ₀ Q ₀ One Q ₂ Q ₀ Q ₂ Q ₀ Q ₂ Q ₀ Q ₂

와 뒷 부분에 전송되는 코드 시퀀스

가 다르게 구성할 수도 있다. Code sequence transmitted earlier for each ACK / NAK bit case as shown in Table 8 and Table 9

Code sequences sent to and after

May be configured differently.

DFT vector method: 2-bit ACK / NAK ACK / NAK
Bit value
(b ₀ , b ₁ ) S ₀ S ₁ S ₂ S ₃ S ₄ S ₅ S ₆ (0, 0) Q ₀ Q ₀ Q ₀ Q ₀ Q ₁ Q ₂ Q ₃ (0, 1) Q ₁ Q ₂ Q ₃ Q ₀ Q ₂ Q ₀ Q ₂ (1, 1) Q ₂ Q ₀ Q ₂ Q ₀ Q ₃ Q ₂ Q ₁ (1, 0) Q ₃ Q ₂ Q ₁ Q ₀ Q ₀ Q ₀ Q ₀

ACK / NAK
Bit value b ₀ S ₀ S ₁ S ₂ S ₃ S ₄ S ₅ S ₆ 0 Q ₀ Q ₀ Q ₀ Q ₀ Q ₁ Q ₂ Q ₃ One Q ₂ Q ₀ Q ₂ Q ₀ Q ₃ Q ₂ Q ₁

Next, the sequence allocation method by Walsh-Hadamard code method is explained below.

를 보여준다. Table 10 shows the sequence on the corresponding time axis according to the ACK / NAK bit value when transmitting two ACK / NAK bit information.

Lt; / RTI >

를 보여준다. Table 11 shows the sequence on the corresponding time axis according to the ACK / NAK bit value when transmitting one ACK / NAK bit information.

Lt; / RTI >

ACK / NAK
Bit value
(b ₀ , b ₁ ) S ₀ S ₁ S ₂ S ₃ S ₄ S ₅ S ₆ (0, 0) One One One One One One One (0, 1) -One -One One One -One -One One (1, 1) -One One -One One -One One -One (1, 0) One -One -One One One -One -One

ACK / NAK
Bit value b ₀ S ₀ S ₁ S ₂ S ₃ S ₄ S ₅ S ₆ 0 One One One One One One One One -One One -One One -One One -One

에 대응되는 시퀀스는 다름아닌 길이 4인 Walsh-Hadamard 시퀀스에 해당한다. 그리고, 다음 4개의 심볼

에 대응되는 시퀀스도 길이 4인 Walsh-Hadamard 시퀀스에 해당함을 알 수 있다. First four symbols in Table 10

The corresponding sequence corresponds to Walsh-Hadamard sequence of length 4. And the next four symbols

The sequence corresponding to also corresponds to the Walsh-Hadamard sequence of length 4.

In Table 10, compare the sequence corresponding to (0, 0) and the sequence corresponding to (1, 1). It can be seen that the phase of the sequence corresponding to (1, 1) has a relative sign of 1, -1, 1, -1 at each time axis symbol position with respect to the sequence corresponding to (0, 0). In other words, one symbol is changed to the opposite sign as a unit. By doing so, it is possible to lower the probability of incorrectly receiving (1, 1) as (0, 0) as compared with the probability of incorrectly receiving (1, 1) as (1, 0) or (0, 1).

를 보여준다. 표 10의 (0, 0)과 (1, 1)에 해당하는 두 개 시퀀스를 골라내어 1 비트 ACK/NAK 전송에 이용한다. 물론, (0, 1)와 (1, 0)에 해당하는 두 개 시퀀스를 골라 사용할 수도 있다. 그러나, 앞에서 기술한 바와 같이 표 11에서 (0, 0) 과 (0, 1) 혹은 (0, 1) 과 (1, 1)에 해당하는 시퀀스를 골라 사용하는 것은 바람직하지 않다.Table 11 shows the sequence on the corresponding time axis according to the ACK / NAK bit value when one piece of ACK / NAK bit information is transmitted.

Lt; / RTI > Two sequences corresponding to (0, 0) and (1, 1) in Table 10 are selected and used for 1-bit ACK / NAK transmission. Of course, two sequences corresponding to (0, 1) and (1, 0) may be selected and used. However, as described above, it is not preferable to use a sequence corresponding to (0, 0) and (0, 1) or (0, 1) and (1, 1) in Table 11.

The base station and the terminal should know in advance the sequence to be used according to the number and the value of the ACK / NAK bits. The base station should know in advance whether the terminal performs 1-bit ACK / NAK transmission or 2-bit ACK / NAK transmission and detect the received signal according to each situation.

와 뒷 부분에 전송되는 코드 시퀀스

가 다르게 구성할 수도 있다. Code sequence transmitted earlier for each ACK / NAK bit as shown in Table 12 and Table 13.

Code sequences sent to and after

May be configured differently.

ACK / NAK
Bit value
(b ₀ , b ₁ ) S ₀ S ₁ S ₂ S ₃ S ₄ S ₅ S ₆ (0, 0) One One One One -One -One One (0, 1) -One -One One One -One One -One (1, 1) -One One -One One One -One One (1, 0) One -One -One One One One -One

ACK / NAK
Bit value b ₀ S ₀ S ₁ S ₂ S ₃ S ₄ S ₅ S ₆ 0 One One One One -One -One One One -One One -One One One -One -One

The sequence of the DFT vector method and Walsh code method used above can be used for on-off keying type ACK / NAK signal transmission or scheduling request (SR) transmission. Each terminal is assigned a frequency axis sequence and a time axis sequence.

In case of ACK / NAK transmission, the allocated sequence is transmitted when the UE needs to send ACK. In the case of SR transmission, the allocated sequence is transmitted only when the UE performs SR.

Table 14 and Table 15 show the case of using DFT vector and Walsh code, respectively.

DFT vector method S ₀ S ₁ S ₂ S ₃ S ₄ S ₅ S ₆ C0 Q ₀ Q ₀ Q ₀ Q ₀ Q ₀ Q ₀ Q ₀ C1 Q ₁ Q ₂ Q ₃ Q ₀ Q ₁ Q ₂ Q ₃ C2 Q ₂ Q ₀ Q ₂ Q ₀ Q ₂ Q ₀ Q ₂ C3 Q ₃ Q ₂ Q ₁ Q ₀ Q ₃ Q ₂ Q ₁

Walsh code method S ₀ S ₁ S ₂ S ₃ S ₄ S ₅ S ₆ C0 One One One One One One One C1 -One -One One One -One -One One C2 -One One -One One -One One -One C3 One -One -One One One -One -One

Each terminal transmits its assigned frequency axis and time axis sequences as needed. If there are N total Zadoff-Chu cyclic shifts available on the frequency axis, a total of 4xN orthogonal sequences are generated using the time axis codes of Table 14 or Table 15. Therefore, different sequences can be allocated to a total of 4xN terminals.

The structure that repeats and partially overlaps two short-length sequences of the structures shown in Table 14 and Table 15 shows good performance even for a high speed user.

To further improve performance, hopping of time axis sequences may be applied within one slot. Preferred examples thereof are shown in Tables 16 and 17.

In Table 16, it can be seen that the sequence of length 4 formed by S ₀ , S ₁ , S ₂ , and S ₃ is changed in S ₃ , S ₄ , S ₅ , and S ₆ . If the sequence is changed in this way, in Table 15, interference between terminals allocated to C0 and C1 may be large. In Table 17, interference is reduced. In Table 15, the orthogonality of C0 and C1 is S ₀ , S ₁ , S ₂ , S ₃ And cross correlation of length 4 for S ₃ , S ₄ , S ₅ , and S _6, respectively, but in Table 17, S ₃ , S ₄ , S ₅ , and S ₆ are partially length 2 This is because there is orthogonality even when cross correlation is performed for.

The Walsh code method is not limited to the example of Table 17 and can create various hopping rules that vary the orthogonal minimum length from S ₀ to S ₃ and S ₃ to S ₆ differently.

S ₀ S ₁ S ₂ S ₃ S ₄ S ₅ S ₆ C0 Q ₀ Q ₀ Q ₀ Q ₀ Q ₁ Q ₂ Q ₃ C1 Q ₁ Q ₂ Q ₃ Q ₀ Q ₂ Q ₀ Q ₂ C2 Q ₂ Q ₀ Q ₂ Q ₀ Q ₃ Q ₂ Q ₁ C3 Q ₃ Q ₂ Q ₁ Q ₀ Q ₀ Q ₀ Q ₀

For performance comparison with the coherent method, the following two coherent methods are considered.

First, the Coh2R method has two reference signal (RS) blocks per slot, and the slot structure is shown in FIG. 9. The other slot also has the same structure.

In addition, the Coh3RS scheme has three reference signal (RS) blocks per slot, and the structure of the slot is shown in FIG. The other slot also has the same structure.

The reference signal is used for channel estimation. Binary Phase Shift Keying (BPSK) modulation is transmitted when one ACK / NAK bit is transmitted, and QPSK modulation is transmitted when two ACK / NAK bits are transmitted.

The structure of a transmitter for performing the ACK / NAK transmission scheme proposed in the present invention is shown in FIG.

The time sequence generator 1110 generates a time axis sequence and determines which sequence to transmit through the ACK / NAK bit. The frequency sequency generator 1120 generates a sequence on the frequency axis and allocates the sequence to the terminal.

The CDM Mapper 1130 (CDM Mapper) allows different users to distinguish between different users by using the same time / frequency resources but multiplying a specific code that is orthogonal to each other. The signal passed through the inverse Fourier transform unit 1140 (IFFT) is added to the CP & P / S unit 1150 by adding a CP (Cyclic prefix) and converting the signal from a parallel signal to a serial signal to perform D / A conversion. The data is passed to the A converter 1160. The RF & D / A converter 1160 converts a digital signal into an analog signal and then performs RF transmission.

The structure of the receiver device according to the present invention is as shown in FIG.

After receiving data from the RF & A / D converter 1210 and converting an analog signal into a digital signal, the S / P & CP remover 1220 converts the signal back into a parallel signal and removes a cyclic prefix (CP). . The Fourier transform unit 1230 performs Fast Fourier transform (FFT) to take an ACK / NAK received signal in a desired resource allocation region.

For example, _if a received signal obtained from the i-th OFDM symbol among the received signals in a specific time domain T _k is R _i ^(k) , R _i ^(k) has a length equal to the number of sub-frequency N as shown in Equation 3 below. Can be represented as a vector. r _{i , l} ^(k) is a received signal corresponding to the first sub-frequency in the i-th OFDM symbol in the k-th time domain T _k .

Take a complex conjugate of the sequence on the frequency axis assigned to the desired user and multiply it to get

The time / frequency sequence extracting unit 1250 performs the preparation process for determining the ACK / NAK through a more detailed process as shown in FIG. 13 by inputting R _i ^(k) obtained above.

That is, in FIG. 13, the frequency domain sequence extractor 1252 and the time domain sequence extractor 1254 respectively extract a sequence on the frequency axis and a sequence on the time axis. Finally, non-coherent sums of values obtained for different time domains through the noncoherent adder 1256 are performed.

The mathematical development process is as follows.

Next, after taking a complex conjugate of a sequence on the time axis corresponding to each ACK / NAK bit value, the signal obtained above is multiplied as shown in Equation 5 below.

In the above formula, I is an index indicating an ACK / NAK bit value. That is, I can be ACK or NAK. Next, the values obtained above for different time domains are noncoherently summed as in Equation 6 below.

The index giving the largest value is found as in Equation 7. In FIG. 13, the output of the time and frequency extractor 1250 is the value of Equation 6, DEC _I. Value. Now, the ACK / NAK determination unit 1260 performs an ACK / NAK determination.

View J as the time base sequence index sent by the UE and take the corresponding ACK / NAK bit value.

In Equation 3, when a calculation is expressed by distinguishing it to correspond to an ACK / NAK bit value instead of the index I, it is developed as follows.

R _ACK and R _NAK are obtained by multiplying the sequence corresponding to the ACK / NAK bit value by the received signal on the time axis as shown in Equation 8 below.

The following equation (9) is obtained by multiplying the R _ACK , R _NAK obtained above by the sequence on the frequency axis assigned to the user.

Next, non-coherent sums of the values obtained above for different time domains.

The ACK / NAK determination unit 1260 determines that _ACK if SUM _ACK > SUM _NAK . On the other hand, if the SUM _ACK ≤SUM _NAK will be determined to NAK.

Simulation was performed to compare and evaluate the performance of the noncoherent and coherent methods proposed in the present invention.

Simulation conditions are as follows. The base station uses two reception antennas and the terminal uses one transmission antenna. The 10 MHz system band was considered and the control channel described in FIG. 3 was used. The upper and lower control channels each occupy 12 sub-frequency (N = 12). The simulation was performed using the TU (Typical Urban) model.

14 and 15 illustrate a case of transmitting 2-bit ACK / NAK information. The reception error rate of ACK / NAK information is shown as a function of signal to noise power ratio (SNR) per receiving antenna.

In FIG. 14 and FIG. 15, the speeds of the terminals correspond to 3 km / h and 360 km / h, respectively. In the figure, Coh_2RS is a coherent method having the structure of FIG. 9 and Coh_3RS is a coherent method having the structure of FIG.

NonCoh_DFT is a result of using the time axis sequence described in Table 6 and FIG. 8 in a DFT vector based manner. NonCoh_Walsh is a result obtained using the time base sequence described in Table 10 in a Walsh code based manner.

와

의 두 시간영역으로 나누어 신호검출을 수행한 결과이다. NonCoh_Walsh^*는 Walsh 코드 기반 방식으로 표 10으로 기술되는 시간축 시퀀스를 이용하되 수신측에서 한 개 슬롯 전체를 한 개의 시간영역으로 보고 신호검출을 수행한 결과이다. NonCoh_DFT and NonCoh_Walsh have one slot at the receiving end.

Wow

This is the result of signal detection divided into two time domains. NonCoh_Walsh ^* is a Walsh code-based method that uses the time-base sequence described in Table 10, but the receiver detects the entire slot and sees the entire slot as one time domain.

Receiving error rate is 10 ^-2 to 10 ^- this is the proposed method of this invention in the range from ³ it can be seen that the SNR gain of 2 - 3 dB compared with the coherent method.

16 and 17 show a reception error rate of ACK / NAK information as a function of signal to noise power ratio (SNR) per receiving antenna when transmitting 1 bit ACK / NAK information.

16 and 17 the speed of the terminal corresponds to 3 km / h, 360 km / h, respectively. Coh_2RS is a coherent method having the structure of FIG. 9 and Coh_3RS is a coherent method having the structure of FIG.

NonCoh_DFT is a result of using a time axis sequence described in Table 7 and FIG. 8 in a DFT vector based manner. NonCoh_Walsh is a result obtained using the time axis sequence described in Table 11 in a Walsh code based manner.

와

의 두 시간영역으로 나누어 신호검출을 수행한 결과이다. NonCoh_Walsh^*는 Walsh 코드 기반 방식으로 표 11로 기술되는 시간 축 시퀀스를 이용하되 수신측에서 한 개 슬롯 전체를 한 개의 시간영역으로 보고 신호검출을 수행한 결과이다. NonCoh_DFT and NonCoh_Walsh have one slot at the receiving end.

Wow

This is the result of signal detection divided into two time domains. NonCoh_Walsh ^* is a Walsh code-based method, which uses the time axis sequence described in Table 11, and shows the result of signal detection by seeing one slot as one time domain at the receiving side.

Reception error rate is 10 ^-2 to 10 ^{- 3} in the range proposed by the invention in a manner which can be seen the show a little better or a similar performance compared to a coherent manner.

The present invention can also be embodied as computer-readable codes on a computer-readable recording medium. A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer system is stored. Examples of the computer-readable recording medium include a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device, and the like, and may be implemented in the form of a carrier wave (for example, transmission via the Internet) . In addition, the computer-readable recording medium may be distributed over network-connected computer systems so that computer readable codes can be stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the present invention can be easily inferred by programmers in the art to which the present invention belongs.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. I will understand that. Accordingly, the true scope of the present invention should be determined by the appended claims.

1 is a diagram illustrating an example in which different terminals use resources in different time / frequency domains.

2 shows an example of time / frequency resources used by a terminal for ACK / NAK transmission according to the present invention.

3 is a diagram illustrating an example in which a control channel is located in a frequency-time resource space.

4 is a diagram illustrating a resource used for ACK / NAK according to the present invention.

FIG. 5 is a diagram for indicating that transmission resources used according to the present invention are two resource blocks adjacent to each other on a time axis.

6 is a diagram illustrating a code sequence and a symbol transmitted to each sub-frequency in a control channel occupying N sub-frequency on the frequency axis and N _t OFDM symbols on the time axis according to the present invention.

7 is L _c when the total number of consecutive OFDM symbols on the time axis is large according to the present invention. It is a figure which shows an example of dividing into pieces.

8 is a diagram for illustrating quadrature phase shift keying (QPSK) modulation in a complex symbol space according to the present invention.

9 is a view showing a coherent slot structure including two reference signals per slot according to the present invention.

FIG. 10 illustrates a coherent slot structure including three reference signals per slot according to the present invention.

11 shows a transmitter structure for ACK / NAK transmission according to the present invention.

12 illustrates a receiver structure for receiving ACK / NAK according to the present invention.

13 is a view showing in detail the structure of the time / frequency code sequence extractor of the receiver according to the present invention.

14 is a simulation result for performance comparison between a noncoherent and a coherent method according to the present invention, wherein the reception error rate of ACK / NAK information is determined by the signal to noise power ratio (SNR) per receiving antenna. Shown as a function, it is a case showing the case that the speed of the terminal corresponds to 3 km as transmitting 2 bits ACK / NAK information.

FIG. 15 is a simulation result for performance comparison between a noncoherent and a coherent method according to the present invention, wherein the reception error rate of ACK / NAK information is determined according to the signal to noise power ratio (SNR) per receiving antenna. Shown as a function, it is a case showing the case that the speed of the terminal corresponds to 360 km as transmitting a 2-bit ACK / NAK information.

FIG. 16 is a simulation result for performance comparison between a noncoherent and a coherent method according to the present invention, wherein the reception error rate of ACK / NAK information is determined by the signal to noise power ratio (SNR) per receiving antenna. Shown as a function, but when the 1-bit ACK / NAK information is transmitted is a diagram showing a case that the speed of the terminal corresponds to 3 km.

17 is a simulation result for comparing the performance of the non-coherent and coherent method according to the present invention, the reception error rate of the ACK / NAK information (Detection Error Rate) of the SNR (Signal to Noise power Ratio) per receiving antenna Shown as a function, but when the 1-bit ACK / NAK information is transmitted is a diagram showing a case where the speed of the terminal corresponds to 360 km.

Claims (27)

In the method of transmitting ACK / NAK signal of a wireless communication system system, (a) Among the resource blocks occupying N sub-carriers greater than 2 and even on the frequency axis and occupying one symbol on the time axis, the first resource block and the second resource block neighboring each other on the time axis Allocating to one terminal; (b) allocating a sequence orthogonal to the N sub-frequency on the frequency axis to the terminal; And (c) if the ACK / NAK bit of the codeword received by the terminal has a first binary value, transmit the sequence using only the first resource block; and if the ACK / NAK bit has a second binary value, the second resource block And transmitting the sequence only by ACK / NAK signal transmission method of a wireless communication system. delete In the method of transmitting ACK / NAK signal of a wireless communication system system, (a) allocating a first resource block and a second resource block among resource blocks occupying one or more N sub-carriers on the frequency axis and occupying one symbol on the time axis; (b) assigning a terminal to a sequence orthogonal to the N sub-frequency on the frequency axis and orthogonal code indices a and b of the sequence; And (c) a sequence having the orthogonal code index a in the first resource block and the orthogonal code index b in the second resource block if the ACK / NAK bit of the codeword received by the terminal is a first binary value, And transmitting a sequence having the orthogonal code index b to the first resource block and the orthogonal code index a to the second resource block if a NAK bit is a second binary value. ACK / NAK signal transmission method. delete In the method of transmitting ACK / NAK signal of a wireless communication system, (a) allocating a resource block occupying N sub-carriers greater than 2 and even on the frequency axis and occupying N _t symbols greater than 2 on the time axis; (b) allocating an orthogonal sequence to the N sub-frequency, and assigning each orthogonal sequence to each terminal to a resource block occupying the N _t symbols on a time axis; (c) setting, by the base station and each terminal, which of the sequences on the time axis to transmit according to the ACK / NAK bits; And (d) transmitting a sequence set by the base station and the terminal in advance among the sequences on the time axis according to the ACK / NAK bit value of the codeword received by the terminal; ACK / NAK signal transmission method. delete delete In the method of transmitting ACK / NAK signal of a wireless communication system, (a) Allocating a resource block occupying N sub-carriers greater than or equal to 2 on the frequency axis and occupying N _t symbols greater than or equal to 2 on the time axis and mutually assigning each of the UEs on the frequency axis Assigning an orthogonal sequence; (b) when N _t is longer than the coherence time, the sequence symbol allocated to the resource block on the time axis is smaller than the coherence time, L _c. Divided by unit, total

Dividing into three temporal domains; (c) assigning an orthogonal sequence having the length L _c on the time axis; And (d) transmitting an ACK / NAK bit value of a codeword received by the terminal according to the base station and one of the sequences previously set by the terminal; ACK / How to send NAK signal. delete delete delete In a non-coherent ACK / NAK signal transmission method of a wireless communication system system, (a) allocating resource blocks, which occupy N sub-carriers greater than 2 and even on the frequency axis and occupy N _t symbols on the time axis, to the UEs; (b) converting the sequence on the N _t time axes into four sequence units (

Dividing by; (c) configuring the four sequences in the sequence unit into a sequence including QPSK symbols such that each corresponds to a column vector of a four-dimensional DFT matrix, and includes a sequence corresponding to ACK / NAK bits (0, 0) and The relative phase difference of the sequence corresponding to the ACK / NAK bits (1, 1) is 0 or π; And and (d) transmitting the sequence on the time axis corresponding to the ACK / NAK bit value of the codeword received by the terminal. 12. The non-coherent ACK / NAK signal transmitting method of a wireless communication system, comprising: delete delete delete delete delete delete delete In a non-coherent ACK / NAK signal transmission method of a wireless communication system system, (a) allocating a resource block occupying N sub-carriers greater than 2 and even on the frequency axis and occupying N _t symbols on the time axis to one or more terminals; (b) converting the sequence on the N _t time axes into four sequence units (

Dividing by; (c) the four sequences in the sequence unit comprise a Walsh-Hadamard sequence having a length of 4 and assigning them to terminals, the sequence corresponding to the ACK / NAK bits (0, 0) and the ACK / NAK bits ( The relative signs of the time axis symbols of the sequence corresponding to 1, 1) are alternately changed to 1, -1; And and (d) transmitting a sequence on a time axis corresponding to the ACK / NAK bit value of the codeword received by each terminal. delete delete delete delete delete delete delete

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