KR20080045941A - Method for multiplexing reference signals and method for allocating cazac sequence - Google Patents

Abstract

A method for multiplexing a reference signal and a method for allocating a CAZAC(Constant Amplitude Zero Auto-Correlation) sequence are provided to maintain orthogonality of a reference signal by using CDM(Code Division Multiplexing) even between cells or sectors having occupied data bandwidths of different sizes. A method for multiplexing a reference signal comprises the following steps of: preparing a basic pilot bandwidth; allocating a first occupied pilot bandwidth to a reference signal of a first area; and allocating a second occupied pilot bandwidth to a reference signal of a second area adjacent to the first area. The reference signal of the first area and the reference signal of the second area have orthogonality in a code area. The first and second occupied pilot bandwidths are an integer multiple of the basic pilot bandwidth.

Description

Method for multiplexing reference signals and method for allocating CAZAC sequence}

1 is an exemplary view showing a wireless communication system.

2 is an exemplary diagram for explaining multiplexing of a reference signal according to an embodiment of the present invention.

3 is an exemplary diagram for describing multiplexing of a reference signal according to another embodiment of the present invention.

4 is an exemplary diagram for describing multiplexing of a reference signal according to another embodiment of the present invention.

5 is an exemplary diagram illustrating multiplexing according to another embodiment of the present invention.

The present invention relates to wireless communication, and more particularly, to a multiplexing method of a reference signal having orthogonality and a method for allocating a constant amplitude zero auto-correlation (CAZAC) sequence.

The wireless communication system is partitioned into multiple areas for efficient system configuration. The area is called a cell or sector. In general, one base station is installed in one cell, and terminals in the cell exchange signals through the base station. One cell may be partitioned into multiple sectors. In general, one cell is divided into three sectors or six sectors.

When using the same resources in adjacent cells or sectors in a multi-cell or sector environment, inter-cell interference or inter-sector interference may appear. This interference phenomenon is particularly problematic in the terminal located at the edge of the cell or sector.

This inter-cell or inter-sector interference phenomenon will be described in relation to an Orthogonal Frequency Division Multiple Access (OFDMA) system. An OFDMA system is a multiple access system using Orthogonal Frequency Division Multiplexing (OFDM) as a modulation method. When an OFDMA system uses subcarriers of the same frequency band in adjacent cells and / or sectors, it may be a cause of inter-cell interference and / or inter-sector interference.

Meanwhile, in a wireless communication system, an efficient data restoration is required in a receiver. To this end, channel estimation for data demodulation and channel quality estimation for frequency selective scheduling are performed periodically. In general, channel estimation and channel quality measurement are performed by a reference signal or pilot known to both the base station and the terminal.

However, when the aforementioned inter-cell or inter-sector interference occurs, the inter-cell or inter-sector orthogonality of the reference signal is also broken. In this case, channel estimation and channel quality measurement using the reference signal are not properly performed, thereby degrading the performance of the wireless communication system.

As a method for preventing inter-cell interference and / or inter-sector interference of the reference signal, methods such as frequency division multiplexing (FDM) and code division multiplexing (CDM) have been proposed. The multiplexing method using FDM has a problem of lowering frequency efficiency.

The CDM uses orthogonal codes as reference signals to distinguish reference signals between cells or sectors. However, the size of the resource block allocated to the reference signal may be different between cells or between sectors. For example, a dedicated reference signal may be transmitted only within a resource block having data to be transmitted, that is, occupied data bandwidth. In this case, the size of the resource block allocated to the reference signal may be between cells or sectors. May vary.

When the size of the resource block of the cell or sector is different in this way, in the multiplexing method of the reference signal using the CDM, the length of the orthogonal code may vary depending on the cell or sector. However, in the orthogonal code, orthogonality may not be maintained between sequences having different lengths. In this case, cross-correlation between cells or sectors of the reference signal is broken, and an error occurs in channel estimation and / or channel quality measurement using the reference signal.

Accordingly, a technique for maintaining orthogonality of the reference signal is required even when the size of the resource block is different between cells or sectors.

An object of the present invention is to provide a multiplexing method of a reference signal and a CAZAC sequence allocation method capable of preventing intercell or sectoral interference of a reference signal.

The multiplexing method of the reference signal according to an aspect of the present invention for achieving the above technical problem prepares a basic pilot bandwidth. A first occupied pilot bandwidth is allocated to a reference signal of a first region, and the second occupied pilot bandwidth is allocated to a reference signal of a second region adjacent to the first region. Here, the reference signal of the first region and the reference signal of the second region have orthogonality in a code region, and the first occupied pilot bandwidth and the second occupied pilot bandwidth are integer multiples of the basic pilot bandwidth.

According to another aspect of the present invention, there is provided a method for allocating a constant amplitude zero auto-correlation (CAZAC) sequence to determine a basic CAZAC sequence, and to assign a first CAZAC sequence to a first region. A second CAZAC sequence is allocated to the second region adjacent to the second region. The first CAZAC sequence and the second CAZAC sequence are generated by repeating the base CAZAC sequence by an integer multiple.

According to another aspect of the present invention, an intercell interference prevention method for maintaining an orthogonality of a signal in a code region between cells according to another aspect of the present invention determines a basic orthogonal code and repeats the integer orthogonal multiple times the basic orthogonal code between adjacent cells. To maintain orthogonality of the signal.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like numbers refer to like elements throughout the specification.

1 is an exemplary view showing a wireless communication system. Wireless communication systems are widely deployed to provide various communication services using various data such as video, voice, text, and the like.

Referring to FIG. 1, peripheral cells C1,..., And C6 are disposed around a single cell C0. Base station 100 (BS) is arranged in cell C0, and base stations 101, ..., 106 are similarly arranged in neighboring cells C1, ..., C6, respectively. Here, six peripheral cells C1,... And C6 are shown for one cell C0, but this is not a limitation and the arrangement and number of peripheral cells C1,..., C6 may be changed in various ways. .

The base station 100 communicates with a user equipment (UE). Hereinafter, downlink means communication from the base station 100 to the terminal 200, and uplink means communication from the terminal 200 to the base station 100. The base station 100 generally refers to a fixed point for communicating with the terminal 200, and may be referred to in other terms such as a node-B, a base transceiver system (BTS), and an access point. The terminal 200 may be fixed or mobile, and may be referred to as other terms such as a user equipment (UE), a user terminal (UT), a subscriber station (SS), a wireless device, and the like.

The reference signal is data a priori known to both the base station 100 and the terminal 200. This is also called a pilot signal. Hereinafter, a reference signal disposed over the entire bandwidth of the system is called a common reference signal, and a reference signal disposed over the data bandwidth transmitted to the specific terminal 200 is called a dedicated reference channel. do. In general, the common reference signal is used for channel estimation for data demodulation and / or channel quality estimation for frequency selective scheduling, and the specific reference signal is used for channel estimation for data demodulation. The common reference signal may be transmitted through a downlink channel, and the specific reference signal may be transmitted through an uplink channel or a downlink channel.

In order to prevent intercell interference, orthogonality is required between reference signals between different cells. As shown in FIG. 1, when the terminal 200 is located at the edge of one cell C0, the terminal 200 may interfere with the reference signal of the neighboring cell C6 that is closest to each other. Therefore, orthogonality between reference signals is required for different cells.

Orthogonality is time domain orthogonality, frequency domain orthogonality, or code domain orthogonality. Frequency domain orthogonality is achieved by transmitting signals through different subcarriers for each terminal, and is called frequency division multiplexing (FDM). Code region orthogonality is achieved through orthogonal codes and is called Code Division Multiplexing (CDM).

Orthogonal Codes include the use of Orthogonal Variable Spreading Factor (OVSF) codes, the use of phase rotation, the use of cyclic shifts, and the use of Constant Amplitude Zero Auto-Correlation (CAZAC) sequences. There is this.

For clarity, the following description focuses on the CAZAC sequence.

There are two CAZAC sequences: generalized chirp like (GCL) CAZAC sequences and Zadoff-Chu CAZAC sequences. These two sequences are conjugated to each other. That is, the Zadoff-Chu CAZAC sequence is obtained by applying the conjugate to the GCL CAZAC sequence.

In the Zadoff-Chu CAZAC sequence, the k-th entry C _M (k) of the M-th CAZAC sequence may be represented by Equation 1 below.

Where N _z is the length of the CAZAC sequence, M is prime relative to N, and k = 0, ..., Nz-1. M is a sequence index, and reference signals of different cells have different sequence indices. The sequence index may be used as a cell identification.

The CAZAC sequence C _M (k) has the following three characteristics.

Equation 2 means that the CAZAC sequence is always 1 in size, and Equation 3 means that the auto correlation of the CAZAC sequence is represented by a Dirac-delta function. Here, cross correlation is based on cyclic correlation, and the length of the cyclic shifted CAZAC sequence is the same. Equation 4 means that cross correlation is always constant.

In the GCL CAZAC sequence, the k-th entry s _M (k) of the u-th GCL CAZAC sequence may be expressed by Equation 5 below.

Here, N _G is the smallest prime number larger than N _d when the length of the GCL CAZAC sequence is N _d , and k = 0, ..., N _G −1. u is a sequence index, and reference signals of different cells have different sequence indices. The sequence index may be used as a cell identification.

 Zadoff-Chu CAZAC sequences are described in D. C. Chu, “Polyphase codes with good periodic correlation properties,” IEEE Trans. Info. Theory, vol. IT-18, pp. 531-532, July 1972, the GCL CAZAC sequence is described in B.M. Popovic, “Generalized Chirp-like Polyphase Sequences with Optimal Correlation Properties,” IEEE Trans. Info. Theory, vol. 38, pp. 1406-1409, July 1992.

In a multi-carrier system such as OFDMA, since all subcarriers cannot be allocated to each terminal 200 independently, a plurality of subcarriers are bundled to form a plurality of resource blocks smaller than the total number of subcarriers. For example, 12 subcarriers are gathered into one resource block, which is the smallest resource allocation unit that can be given to one terminal 200. The base station 100 schedules a resource block allocated for each terminal 200.

The size of the resource block allocated to the reference signal may vary from cell to cell. For example, the size of the resource block allocated to a specific reference signal depends on the data bandwidth of the terminal 200. In addition, the size of the resource block of the common reference signal may be different between cells if the system bandwidth of the base station 100 is different.

CAZAC sequences do not maintain orthogonality among sequences having different lengths due to their characteristics. Therefore, specific reference signals between adjacent cells have different sizes of resource blocks to which they are allocated, and accordingly, CAZAC sequences may have different lengths and thus may not maintain orthogonality. In addition, even in the case of the common reference signal, orthogonality may not be maintained when system bandwidths of adjacent cells are different in size.

In order to multiplex the reference signal, a basic pilot bandwidth is first defined. The basic pilot bandwidth refers to the minimum bandwidth allocated to the reference signal to maintain orthogonality of the inter-cell reference signals. For a particular reference signal, the basic pilot bandwidth may occupy at least one resource block or may occupy two or more resource blocks. The basic pilot bandwidth is an integer multiple of the resource block. The number of resource blocks allocated to the basic pilot bandwidth may vary depending on the number of cells adjacent to each other, the channel environment, spacing of reference signals, and / or characteristics of a code sequence used as an orthogonal code.

In order to maintain orthogonality of the inter-cell reference signals by the CDM method, the length of an orthogonal code such as a CAZAC sequence should be greater than or equal to a predetermined value. For example, assume that an OFDMA system includes 12 subcarriers in one resource block. In this OFDMA system, only one resource block is allocated to a reference signal, and when a reference signal is arranged at intervals of six subcarriers in the frequency domain, a CAZAC sequence of length 2 is transmitted as a reference signal. Such a length 2 CAZAC sequence cannot be used to distinguish reference signals between three or more adjacent cells. Therefore, in order to maintain orthogonality of the reference signals between three adjacent cells, the length of the CAZAC sequence should be 3 or more. If reference signals are arranged at intervals of six subcarriers, the OFDMA system needs to be allocated a resource block having at least twice the size of the reference signal. In the present invention, the length of the minimum CAZAC sequence that can distinguish cells required for the system is obtained, and this is referred to as a basic pilot bandwidth.

Even if occupied data bandwidth is less than or equal to the basic pilot bandwidth, resource blocks corresponding to the basic pilot bandwidth are allocated to the reference signal. Here, the occupied data bandwidth refers to a bandwidth allocated for transmitting data, and the occupied pilot bandwidth refers to a bandwidth allocated for transmitting a reference signal. Even if the occupied data bandwidth is smaller than the basic pilot bandwidth, the reference signal is transmitted only through the basic pilot bandwidth, thereby securing a minimum bandwidth for preventing inter-cell interference of the reference signal. On the contrary, when the occupied data bandwidth is larger than the basic pilot bandwidth, the reference signal is allocated a bandwidth having an integer multiple of the basic pilot bandwidth, for example, 2 times, 3 times, or 4 times. In other words, the occupied pilot bandwidth is an integer multiple of the basic pilot bandwidth (n ≧ 1). The occupied pilot bandwidth is then equal to or greater than the occupied data bandwidth. In the reference signal, an orthogonal code having a length corresponding to the magnitude of the basic pilot bandwidth or longer is repeated twice, three times, four times, and the like. As a result, an orthogonal code is transmitted over the occupied pilot bandwidth in the form of repetition.

2 is an exemplary diagram for explaining multiplexing of a reference signal according to an embodiment of the present invention.

Referring to FIG. 2, two resource blocks 2RBs are allocated to three neighboring cells as basic pilot bandwidths. Occupied data bandwidths of different sizes may be allocated between cells. That is, the first cell has an occupied data bandwidth of 1RB, the second cell has an occupied data bandwidth of 4RB, and the third cell has an occupied data bandwidth of 6RB. This is merely an example and the occupied data bandwidth may be the same for each cell, or may be different. In addition, the basic pilot bandwidth is not limited to two resource blocks, and one or three or more resource blocks may be allocated. Here, the reference signal may be referred to as a specific reference signal because it is transmitted over a specific data bandwidth.

An orthogonal code having a length corresponding to 2 RB, which is a basic pilot bandwidth, is provided for transmitting a reference signal. The orthogonal code may be a CAZAC sequence. In order to achieve orthogonality of the CAZAC sequence, CAZAC sequences having the same sequence index may be generated between cells to allocate CAZAC sequences to have different cyclic shift values. Hereinafter, a CAZAC sequence having the same sequence index but not applying a cyclic shift value is called a CAZAC sequence # 0, a CAZAC sequence to which a first cyclic shift value is applied is called a CAZAC sequence # 1, and a second cyclic shift value. The CAZAC sequence to which is applied is called CAZAC sequence # 2. The cyclic shift value may vary depending on the number of cells adjacent to each other, the channel environment, the interval of the reference signal, and / or the characteristics of the code sequence used as the orthogonal code.

In the case of the first cell, a resource of 1 RB is allocated to a data signal to be transmitted, but a resource of 2 RB, which is a basic pilot bandwidth, is allocated to a reference signal. That is, if the basic pilot bandwidth is larger than the occupied data bandwidth, the occupied pilot bandwidth is the same as the basic pilot bandwidth. CAZAC sequence # 0 may be selected as a reference signal of the first cell, and the selected CAZAC sequence # 0 is transmitted over 2 RB which is a basic pilot bandwidth.

In the case of the second cell, 4 RB resources are allocated to both the data signal and the reference signal to be transmitted. Occupied data bandwidth and occupied pilot bandwidth are equal as 4RB. This is because the occupied pilot bandwidth is selected to have a minimum integer multiple of the fundamental pilot bandwidth while being equal to or greater than the occupied data bandwidth, so that 2 * 2 = 4RB. A code sequence index different from the code sequence index selected for the reference signal of the first cell is selected for the reference signal of the second cell. For example, CAZAC sequence # 1 may be selected for the second cell. The selected CAZAC sequence # 1 is transmitted over 2RB which is a basic pilot bandwidth, and the selected CAZAC sequence # 1 is repeatedly transmitted for the remaining 2RBs of the occupied pilot bandwidth. As a result, the CAZAC sequence # 1 is repeatedly transmitted twice for the occupied pilot bandwidth which is twice the basic pilot bandwidth.

In the case of the third cell, resources of 6 RB are allocated to both the data signal and the reference signal to be transmitted. This is because the occupied pilot bandwidth is selected to have a minimum integer multiple of the basic pilot bandwidth while being equal to or larger than the occupied data bandwidth of 6RB. One code sequence index different from the code sequence index selected for the reference signal of the first cell and the second cell is selected for the reference signal of the third cell. For example, CAZAC sequence # 2 may be selected for the third cell. The selected CAZAC sequence # 2 is transmitted over 2RB which is a basic pilot bandwidth, and the selected CAZAC sequence # 2 is transmitted twice for the remaining 4RBs of the occupied pilot bandwidth. As a result, the CAZAC sequence # 2 is repeatedly transmitted three times for the occupied pilot bandwidth which is three times the basic pilot bandwidth.

3 is an exemplary diagram for describing multiplexing of a reference signal according to another embodiment of the present invention.

Referring to FIG. 3, three resource blocks 3RBs are allocated to basic pilot bandwidths for three adjacent cells. The first cell has an occupied data bandwidth of 1RB, the second cell has an occupied data bandwidth of 4RB, and the third cell has an occupied data bandwidth of 3RB. Here, the reference signal may be referred to as a specific reference signal because it is transmitted over a specific data bandwidth.

An orthogonal code having a length corresponding to 3 RB, which is a basic pilot bandwidth, is provided for transmitting a reference signal. Hereinafter, a CAZAC sequence having the same index but not applying a cyclic shift value is called a CAZAC sequence # 0, a CAZAC sequence to which a first cyclic shift value is applied is called a CAZAC sequence # 1, and a first cyclic shift value is applied. The CAZAC sequence is called CAZAC sequence # 2.

In the case of the first cell, a resource of 1 RB is allocated to a data signal to be transmitted, but a resource of 3 RB, which is a basic pilot bandwidth, is allocated to a reference signal. That is, the occupied pilot bandwidth of the first cell is 3RB, which is equal to the basic pilot bandwidth. CAZAC sequence # 0 may be selected as a reference signal of the first cell, and the selected CAZAC sequence # 0 is transmitted over 3 RB which is a basic pilot bandwidth.

In the case of the second cell, 4 RB resources are allocated to the data signal to be transmitted, while 6 RB resources are allocated to the reference signal. This is because the occupied pilot bandwidth is selected to have a minimum integer multiple of the fundamental pilot bandwidth while being equal to or greater than the occupied data bandwidth 4RB, so that 2 * 3 = 6RB. A code sequence index different from the code sequence index selected for the reference signal of the first cell is selected for the reference signal of the second cell. For example, CAZAC sequence # 1 may be selected for the second cell. The selected CAZAC sequence # 1 is transmitted over 3RB which is a basic pilot bandwidth, and the selected CAZAC sequence # 1 is repeatedly transmitted for the remaining 3RBs of the occupied pilot bandwidth. As a result, the CAZAC sequence # 1 is repeatedly transmitted twice for the occupied pilot bandwidth which is twice the basic pilot bandwidth.

In the case of the third cell, resources of 3RB are allocated to both the data signal and the reference signal to be transmitted. One code sequence index different from the code sequence index selected for the reference signal of the first cell and the second cell is selected for the reference signal of the third cell. For example, CAZAC sequence # 2 may be selected for the third cell. The selected CAZAC sequence # 2 is transmitted over 3RB which is a basic pilot bandwidth.

In this way, when a reference signal is multiplexed and transmitted between cells, the receiver receives only an orthogonal code having a length corresponding to the basic pilot bandwidth. Can be distinguished. Therefore, even if the size of the occupied data bandwidth is different for each cell, the orthogonality of the inter-cell reference signals is maintained, and as a result, interference of the inter-cell reference signals can be prevented from occurring.

4 is an exemplary diagram for describing multiplexing of a reference signal according to another embodiment of the present invention.

Referring to FIG. 4, when three adjacent cells have different system bandwidths, the first cell has a system bandwidth of 1.25 MHz, the second cell has a system bandwidth of 5 MHz, and the third cell has a system bandwidth of 2.5 MHz. . Here, the reference signal may be referred to as a common reference signal because it is transmitted over a system bandwidth.

The default pilot bandwidth can take the smallest of each cell's system bandwidth. Or one of the common factors of the system bandwidth of each cell. Since the system frequency bandwidths of the first cell, the second cell, and the third cell are 1.25 MHz, 5 MHz, and 2.5 MHz, respectively, the maximum common divisor 1.25 MHz may be the basic pilot bandwidth.

An orthogonal code having a length corresponding to a basic pilot bandwidth of 1.25 MHz is provided for transmitting a reference signal. The CAZAC sequence to which the cyclic shift value is not applied is called CAZAC sequence # 0, the CAZAC sequence to which the first cyclic shift value is applied is called CAZAC sequence # 1, and the CAZAC sequence to which the second cyclic shift value is applied is CAZAC sequence # 2 It is called.

In the case of the first cell, the system bandwidth is 1.25 MHz, and the occupied pilot bandwidth is 1.25 MHz, which is equal to the basic pilot bandwidth. CAZAC sequence # 0 may be selected as a reference signal of the first cell, and the selected CAZAC sequence # 0 is transmitted over 1.25 MHz, which is a basic pilot bandwidth.

For the second cell the system bandwidth is 5 MHz and the occupied pilot bandwidth is 5 MHz. This is because the occupied pilot bandwidth is chosen to have a minimum integer multiple of the fundamental pilot bandwidth while being equal to or greater than the system bandwidth of 5 MHz, such that 1.25 * 4 = 5 MHz. A code sequence index different from the code sequence index selected for the reference signal of the first cell is selected for the reference signal of the second cell. For example, CAZAC sequence # 1 may be selected for the second cell. The selected CAZAC sequence # 1 is transmitted over 1.25 MHz, which is a basic pilot bandwidth, and the selected CAZAC sequence # 1 is repeatedly transmitted three times for the remaining 3.75 MHz of the occupied pilot bandwidth. As a result, the CAZAC sequence # 1 is transmitted four times for the occupied pilot bandwidth which is four times the basic pilot bandwidth.

In the case of the third cell, the system bandwidth is 2.5 MHz and the occupied pilot bandwidth is 2.5 MHz. This is because the occupied pilot bandwidth is chosen to have a minimum integer multiple of the fundamental pilot bandwidth while being equal to or greater than the system bandwidth of 2.5 MHz, such that 1.25 * 2 = 2.5 MHz. A code sequence index different from the code sequence index selected for the reference signal of the first cell and the second cell is selected for the reference signal of the third cell. For example, CAZAC sequence # 2 may be selected for the third cell. The selected CAZAC sequence # 2 is transmitted over 1.25 MHz, which is a basic pilot bandwidth, and the selected CAZAC sequence # 2 is repeatedly transmitted once for the remaining 1.25 MHz of the occupied pilot bandwidth. As a result, the CAZAC sequence # 2 is repeatedly transmitted twice for the occupied pilot bandwidth which is twice the basic pilot bandwidth.

 According to the present invention, even if the size of the system bandwidth is different for each cell, the orthogonality of the common reference signals between cells is maintained, and as a result, interference of the common reference signals between cells can be prevented from occurring.

Meanwhile, in order to achieve orthogonality of the CAZAC sequences, CAZAC sequences having different indices may be allocated between cells. The index may select one of two methods depending on the length of the CAZAC sequence. If the length N _z of the CAZAC sequence is not prime in Equation 1, the sequence index M may be selected from values smaller than N _z and prime. For example, if N _z = 10, the sequence index M may select one of 10 and 3, 7, 9, which are prime numbers. Or, if N is a prime _z smaller than the natural number N _z N _z and is both because the small number of each other, M may be selected from any value smaller than N _z. For example, if N _z = 13, the sequence index M can be selected from a number smaller than 10 digits. However, among these sequence indexes, there may be a pair with less interference, and a pair with relatively high interference, and a pair with less interference may be placed in a relatively adjacent cell.

Inter-cell interference can be prevented by allocating a CAZAC sequence having a different sequence index for each cell to the occupied pilot bandwidth. For example, a CAZAC sequence having a sequence index of 1 is called a CAZAC sequence # 0, a CAZAC sequence having a sequence index of 2 is called a CAZAC sequence # 1, and a CAZAC sequence having a sequence index of 3 is called a CAZAC sequence # 2. The same may be applied to one embodiment.

In the above, a method of multiplexing a signal when intercell interference occurs is disclosed. The present invention can be applied to multiplexing a signal in which interference occurs between two adjacent regions.

5 is an exemplary diagram illustrating multiplexing according to another embodiment of the present invention.

Referring to FIG. 5, one cell C0 ′ may be divided into a plurality of sectors S1, S2, and S3. In the drawing, three sectors S1, S2, and S3 are arranged, but this is not a limitation, and two or more sectors may be disposed.

In addition to inter-cell interference, reference signals may generate inter-sector interference. Therefore, the basic pilot bandwidth is determined, the occupied pilot bandwidth is taken as an integer multiple of the basic pilot bandwidth according to the occupied data bandwidth between sectors, and the reference code is repeatedly transmitted.

Meanwhile, intercell interference and intersector interference may exist simultaneously. Even in this case, the occupied pilot bandwidth is taken as an integer multiple of the basic pilot bandwidth, and the reference code is repeatedly transmitted to prevent the inter-cell and inter-sector interference. As a code sequence having orthogonality, a CAZAC sequence may be allocated. In one embodiment, CAZAC sequences having the same sequence index but having different cyclic shift values may be allocated between the inter-cell sectors. In another embodiment, CAZAC sequences having different sequence indices between intercell sectors may be allocated. In another embodiment, CAZAC sequences having identical sequence indices but different cyclic shift values may be allocated between cells, and CAZAC sequences having different sequence indices may be allocated among sectors. In another embodiment, CAZAC sequences having different sequence indices may be allocated between cells and CAZAC sequences having different sequence indices but different cyclic shift values may be allocated between sectors.

In addition to the above embodiments, the present invention can be applied to a technique requiring orthogonality of a reference signal. For example, in the case of dynamic beam forming, a reference signal is required for each beam, and beams in the same cell must have orthogonal reference signals with each other. For each beam, an orthogonal code corresponding to an integer multiple of the basic pilot bandwidth may be taken to maintain intercell and / or intersector orthogonality.

Or, in the case of multi-antenna transmission, an orthogonal reference signal is required for each antenna. When distinguishing antennas by CDM in a cell, orthogonality can be maintained by taking an orthogonal code corresponding to an integer multiple of the basic pilot bandwidth for each antenna. Even when the antennas are distinguished by FDM, orthogonal codes corresponding to integer multiples of the basic pilot bandwidth may be taken for each antenna to maintain orthogonality between cells and / or sectors.

According to the present invention, it is possible to maintain orthogonality of a reference signal using CDM even among cells or sectors having occupied data bandwidths of different sizes. In addition, even when the system bandwidths of adjacent cells are different from each other, it is possible to maintain orthogonality of the reference signals between cells using the CDM. By using a repeating CDM between reference signals, power consumption and overhead of the base station can be reduced to a minimum.

Claims (9)

Preparing a basic pilot bandwidth; Allocating a first occupied pilot bandwidth to a reference signal in the first region; And Allocating the second occupied pilot bandwidth to a reference signal of a second region adjacent to the first region, The reference signal of the first region and the reference signal of the second region have orthogonality in a code region, and the first occupied pilot bandwidth and the second occupied pilot bandwidth are integer multiples of the basic pilot bandwidth. The method of claim 1, The reference signals of the first region and the second region are specific reference signals, The first occupied pilot bandwidth is greater than or equal to the occupied data bandwidth of the first region, and the second occupied pilot bandwidth is greater than or equal to the occupied data bandwidth of the second region. The method of claim 1, The reference signals of the first region and the second region are common reference signals, And wherein the first occupied pilot bandwidth is greater than or equal to the system bandwidth of the first region and the second occupied pilot bandwidth is greater than or equal to the system bandwidth of the second region. The method of claim 1, The basic pilot bandwidth is assigned a basic length of an orthogonal code, And the orthogonal code is repeatedly allocated to the first occupied pilot bandwidth and the second occupied pilot bandwidth by an integer multiple of the basic pilot bandwidth. The method of claim 1, And the first region and the second region are cells. The method of claim 1, And the first area and the second area are sectors. Determining a basic Constant Amplitude Zero Auto-Correlation (CAZAC) sequence; Allocating a first CAZAC sequence to the first region; And Allocating a second CAZAC sequence to a second region adjacent to the first region, And generating the first CAZAC sequence and the second CAZAC sequence by repeating the base CAZAC sequence by an integer multiple. The method of claim 7, wherein And generating the second CAZAC sequence by repeating the basic CAZAC sequence cyclically and repeating the integer multiple times. In the inter-cell interference prevention method for maintaining the orthogonality of the signal in the code region between cells, Determining a basic orthogonal code; And And repeating the basic orthogonal code an integer multiple of adjacent cells to maintain orthogonality of the signal.

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