KR101696464B1 - Method and apparatus for transmitting pilot in wireless communication system - Google Patents

Abstract

A method and apparatus for pilot transmission in a wireless communication system are provided. The base station includes a pilot generating section for generating pilots, a transmitting circuit for transmitting the pilots and a radio signal, and a processor connected to the pilot generating section. Wherein the processor assigns a first index and a second index to a plurality of pilot patterns, and a first selection index and a second selection index, which are calculated based on a cell ID (cell ID) of the plurality of pilot patterns, 1 index and the second index, and maps the generated pilot to resource elements based on the selected pilot pattern.

Description

Field of the Invention [0001] The present invention relates to a method and apparatus for transmitting pilot in a wireless communication system,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to wireless communication, and more particularly, to a pilot transmission method and apparatus in a wireless communication system.

The Institute of Electrical and Electronics Engineers (IEEE) 802.16e standard is a sixth standard for IMT (International Mobile Telecommunication) -2000 in ITU-R (ITU-R) under ITU (International Telecommunication Union) OFDMA TDD '. ITU-R is preparing the IMT-Advanced system as the next generation 4G mobile communication standard after IMT-2000. The IEEE 802.16 WG (Working Group) decided to implement the IEEE 802.16m project with the goal of preparing the amendment specification of the existing IEEE 802.16e as the standard for the IMT-Advanced system at the end of 2006. As can be seen from the above objectives, the IEEE 802.16m standard contains two aspects: continuity of the past, which is the modification of the IEEE 802.16e standard, and future continuity of the standards for the next generation IMT-Advanced system. Therefore, the IEEE 802.16m standard is required to satisfy all the advanced requirements for the IMT-Advanced system while maintaining compatibility with the Mobile WiMAX system based on the IEEE 802.16e standard.

In the case of a broadband wireless communication system, effective transmission and reception techniques and utilization methods have been proposed to maximize the efficiency of limited radio resources. One of the systems considered in the next generation wireless communication system is an Orthogonal Frequency Division Multiplexing (OFDM) system capable of attenuating the inter-symbol interference (ISI) effect with low complexity. OFDM converts serial data symbols into N parallel data symbols, and transmits the data symbols on N separate subcarriers. The subcarriers maintain orthogonality at the frequency dimension. Each of the orthogonal channels experiences mutually independent frequency selective fading, thereby reducing the complexity at the receiving end and increasing the interval of transmitted symbols, thereby minimizing intersymbol interference.

Orthogonal frequency division multiple access (OFDMA) refers to a multiple access method in which a part of subcarriers available in a system using OFDM as a modulation scheme is independently provided to each user to realize multiple access. OFDMA provides a frequency resource called a subcarrier to each user, and each frequency resource is provided independently to a plurality of users and is not overlapped with each other. Consequently, frequency resources are allocated mutually exclusively for each user. Frequency diversity for multiple users can be obtained through frequency selective scheduling in an OFDMA system and subcarriers can be allocated in various forms according to a permutation scheme for subcarriers. And the efficiency of spatial domain can be improved by spatial multiplexing technique using multiple antennas.

Meanwhile, a pilot may be transmitted from the base station to the terminal through the downlink. The pilot may be referred to as a reference signal or the like depending on the wireless communication system. The channel estimation can be performed using the pilot, or the CQI (Channel Quality Indicator) can be measured. The CQI may include SINR, frequency offset estimation, and the like. In order to optimize the performance of the system in different transmission environments, the 802.16m system provides a common pilot structure and a dedicated pilot structure. The public pilot structure and the dedicated pilot structure can be distinguished according to the resources used. Public pilot can be used by all terminals. The dedicated pilot can be used by the terminal to which the specific resource is assigned. Therefore, the dedicated pilot can be precoded or beamformed in the same manner as a data subcarrier. The pilot structure can be defined up to 8 transport streams and can have a unified pilot structure according to the public pilot and the dedicated pilot.

SUMMARY OF THE INVENTION The present invention provides a pilot transmission method and apparatus in a wireless communication system.

In an aspect, a pilot transmission apparatus is provided in a wireless communication system. The pilot transmission apparatus includes a pilot generating unit for generating a pilot, a transmitting circuit for transmitting the pilot and the radio signal, and a processor coupled to the pilot generating unit, Allocating a first index and a second index, and calculating a first selection index and a second selection index, which are calculated based on a cell ID (cell ID) among the plurality of pilot patterns, And maps the generated pilot to a resource element based on the selected pilot pattern. The plurality of pilot patterns may include six pilot patterns. The first selection index can be calculated by the equation p _k = floor (k, c / i). Here, p _k is the first selection index, k is the cell ID, c is the total number of cell IDs, and i is the number of integers that can be the first index. C = 768, and i = 3. The second selection index can be calculated by the formula of s _n = mod (n, j). s _n is the second selection index, n is the cell ID, and j is the number of integers that can be the second index. J = 2. The pilot patterns having the same first index and different from the second index may be cyclic shifted to the frequency domain and the pilot patterns having the same second index and different from the first index may be cyclically shifted to the time domain Can be circularly shifted.

In another aspect, a pilot receiving apparatus is provided in a wireless communication system. The pilot reception apparatus includes a reception circuit for receiving a pilot and a radio signal, a channel estimation unit for estimating a channel using the pilot, and a processor for processing the radio signal using the estimated channel, A first selection index and a second selection index, which are calculated based on cell IDs among a plurality of pilot patterns, are assigned to respective pilot patterns, And the first index and the second index are the same pilot pattern. The first selection index can be calculated by the equation p _k = floor (k, 256). p _k is the first selection index, and k is the cell ID. The second selection index may be calculated by the formula s _n = mod (n, 2). s _n is the second selection index, and n is the cell ID.

In another aspect, a method of transmitting a pilot in a wireless communication system is provided. The method includes generating a pilot, assigning a first index and a second index to a plurality of pilot patterns, calculating a first selection index and a second selection index based on a cell ID of the plurality of pilot patterns, The index determines the same select pilot pattern as the first index and the second index, and maps the generated pilot to a resource element based on the select pilot pattern and transmits the result. The first selection index can be calculated by the equation p _k = floor (k, 256). p _k is the first selection index, and k is the cell ID. The second selection index may be calculated by the formula s _n = mod (n, 2). s _n is the second selection index, and n is the cell ID.

When the number of downlink transport streams is one, the pilot can be efficiently transmitted in each cell or each sector without collision without changing the frequency reuse factor.

1 shows a wireless communication system.
2 is a block diagram illustrating a transmitter and a receiver in which an embodiment of the present invention is implemented.
Fig. 3 shows an example of a frame structure.
4 shows an example of a method of dividing an entire frequency band into a plurality of frequency partitions.
5 shows an example of a cellular system in which the FFR technique is used.
6 shows an example of a downlink resource structure.
Figs. 7 to 10 show an example of a pilot pattern in one PRU.
11 shows an embodiment of the proposed pilot transmission method.
12 to 14 show an example of a staggered pilot pattern according to the proposed pilot transmission method when the data stream is one.

The following description will be made on the assumption that the present invention is applicable to a CDMA system such as Code Division Multiple Access (CDMA), Frequency Division Multiple Access (FDMA), Time Division Multiple Access (TDMA), Orthogonal Frequency Division Multiple Access (OFDMA), and Single Carrier Frequency Division Multiple Access And can be used in various wireless communication systems. CDMA may be implemented in radio technology such as Universal Terrestrial Radio Access (UTRA) or CDMA2000. The TDMA may be implemented in a wireless technology such as Global System for Mobile communications (GSM) / General Packet Radio Service (GPRS) / Enhanced Data Rates for GSM Evolution (EDGE). OFDMA may be implemented in wireless technologies such as IEEE 802.11 (Wi-Fi), IEEE 802.16 (WiMAX), IEEE 802-20, and Evolved UTRA (E-UTRA). IEEE 802.16m is an evolution of IEEE 802.16e, providing backward compatibility with systems based on IEEE 802.16e. UTRA is part of the Universal Mobile Telecommunications System (UMTS). The 3rd Generation Partnership Project (3GPP) LTE (Long Term Evolution) is a part of E-UMTS (Evolved UMTS) using Evolved-UMTS Terrestrial Radio Access (E-UTRA). It adopts OFDMA in downlink and SC -FDMA is adopted. LTE-A (Advanced) is the evolution of 3GPP LTE.

For clarity of description, IEEE 802.16m is mainly described, but the technical idea of the present invention is not limited thereto.

1 shows a wireless communication system.

The wireless communication system 10 includes at least one base station 11 (BS). Each base station 11 provides a communication service to a specific geographical area (generally called a cell) 15a, 15b, 15c. The cell may again be divided into multiple regions (referred to as sectors). A user equipment (UE) 12 may be fixed or mobile and may be a mobile station, a mobile terminal, a user terminal, a subscriber station, a wireless device, a PDA The base station 11 generally refers to a fixed station that communicates with the terminal 12, and may be referred to as a " mobile station " an eNB (evolved-NodeB), a base transceiver system (BTS), an access point, and the like.

A UE belongs to one cell, and a cell to which the UE belongs is called a serving cell. A base station providing a communication service to a serving cell is called a serving BS. Since the wireless communication system is a cellular system, there are other cells adjacent to the serving cell. Another cell adjacent to the serving cell is called a neighbor cell. A base station that provides communication services to neighbor cells is called a neighbor BS. The serving cell and the neighboring cell are relatively determined based on the terminal.

This technique can be used for a downlink or an uplink. Generally, downlink refers to communication from the base station 11 to the terminal 12, and uplink refers to communication from the terminal 12 to the base station 11. In the downlink, the transmitter may be part of the base station 11, and the receiver may be part of the terminal 12. In the uplink, the transmitter may be part of the terminal 12 and the receiver may be part of the base station 11.

2 is a block diagram illustrating a transmitter and a receiver in which an embodiment of the present invention is implemented.

The transmitter 200 includes a pilot generating unit 210, a processor 220, and a transmit circuitry 230. The pilot generation unit 210 and the processor 220 implement the proposed functions, procedures, and / or methods. Embodiments in which the pilot generating unit 210 and the processor 220 implement the proposed functions and methods will be described later. The pilot generating unit 210 generates pilots. The processor 220 determines one pilot pattern among a plurality of pilot patterns, and maps the generated pilot to resource elements based on the one pilot pattern. Transmission circuitry 230 is coupled to processor 220 to transmit and / or receive pilot and radio signals.

The receiver 300 includes a channel estimator 310, a processor 320, and a receiver circuit 330. Receiving circuit 330 transmits and / or receives pilot and radio signals. The channel estimation unit 310 estimates a channel using the pilot. Processor 320 processes the radio signal using the estimated channel. The pilot is mapped to a resource element based on a pilot pattern determined by a transmitter and transmitted.

The pilot or radio signal received at the receiver 300 is transmitted to the processor 320 through decoding and demodulation. The receiver 300 is connected to a receiving antenna 390, and the receiving antenna 390 may be a plurality of antennas. A sequence of a signal received through a receive antenna is restored to a baseband signal, and then multiplexed and channel demodulated to recover data that the transmitter 200 originally intended to transmit. The receiver 300 may include a signal restoring unit for restoring the received signal into a baseband signal, a multiplexing unit for combining and multiplexing the received signals, and a channel demodulating unit for restoring the signal sequence into data. The signal restoring unit, the multiplexing unit, and the channel demodulating unit may be composed of one integrated module or each independent module performing the functions.

Fig. 3 shows an example of a frame structure.

Referring to FIG. 3, a superframe (SF) includes a superframe header (SFH) and four frames (F0, F1, F2, F3). The length of each frame in a superframe may be the same. The size of each super frame is 20 ms, and the size of each frame is 5 ms, but the present invention is not limited thereto. The length of the superframe, the number of frames included in the superframe, the number of subframes included in the frame, and the like can be variously changed. The number of subframes included in the frame may be variously changed according to the channel bandwidth and the length of the cyclic prefix (CP).

The superframe header can carry essential system parameters and system configuration information. The superframe header may be located in the first subframe within the superframe. The superframe header can be classified into a primary SFH (P-SFH) and a secondary SFH (S-SFH). P-SFH and S-SFH can be transmitted every super frame.

One frame includes a plurality of subframes (subframes SF0, SF1, SF2, SF3, SF4, SF5, SF6, SF7). Each subframe may be used for uplink or downlink transmission. One subframe includes a plurality of orthogonal frequency division multiplexing (OFDM) symbols in a time domain and includes a plurality of subcarriers in a frequency domain. An OFDM symbol represents one symbol period and may be called another name such as an OFDMA symbol or an SC-FDMA symbol according to a multiple access scheme. The subframe may be composed of 5, 6, 7 or 9 OFDM symbols, but this is only an example and the number of OFDM symbols included in the subframe is not limited. The number of OFDM symbols included in the subframe may be variously changed according to the channel bandwidth and the length of the CP. The type of the subframe can be defined according to the number of OFDM symbols included in the subframe. For example, a Type-1 subframe may be defined to include 6 OFDM symbols, a Type-2 subframe may include 7 OFDM symbols, a Type-3 subframe may include 5 OFDM symbols, and a Type-4 subframe may include 9 OFDM symbols have. One frame may include all subframes of the same type. Or one frame may include different types of subframes. That is, the number of OFDM symbols included in each subframe in one frame may be all the same or different. Alternatively, the number of OFDM symbols in at least one subframe in one frame may be different from the number of OFDM symbols in the remaining subframes in the frame.

A TDD (Time Division Duplexing) scheme or an FDD (Frequency Division Duplexing) scheme may be applied to the frame. In the TDD scheme, each subframe is used for uplink transmission or downlink transmission at different times at the same frequency. That is, the subframes in the TDD frame are divided into the uplink subframe and the downlink subframe in the time domain. In the FDD scheme, each subframe is used for uplink transmission or downlink transmission at different frequencies of the same time. That is, subframes in a frame of the FDD scheme are divided into an uplink subframe and a downlink subframe in the frequency domain. The uplink transmission and the downlink transmission occupy different frequency bands and can be performed at the same time.

The subframe includes a plurality of physical resource units (PRU) in the frequency domain. A PRU is a basic physical unit for resource allocation, consisting of a plurality of consecutive OFDM symbols in the time domain, and a plurality of consecutive subcarriers in the frequency domain. The number of OFDM symbols included in the PRU may be equal to the number of OFDM symbols included in one subframe. Therefore, the number of OFDM symbols in the PRU can be determined according to the type of the subframe. For example, when one subframe is composed of 6 OFDM symbols, the PRU can be defined as 18 subcarriers and 6 OFDM symbols.

 A logical resource unit (LRU) is a basic logical unit for distributed resource allocation and contiguous resource allocation. The LRU is defined as a plurality of OFDM symbols and a plurality of subcarriers, and includes pilots used in the PRU. Therefore, the number of suitable subcarriers in one LRU depends on the number of allocated pilots.

A Distributed Logical Resource Unit (DLRU) can be used to obtain a frequency diversity gain. The DRU includes subcarrier groups distributed in one frequency partition. The size of the DRU is equal to the size of the PRU. The minimum unit forming the DRU is one subcarrier.

A contiguous logical resource unit (CLRU) may be used to obtain a frequency selective scheduling gain. The CRU includes a local subcarrier group. The size of the CRU is equal to the size of the PRU.

Meanwhile, a fractional frequency reuse (FFR) scheme may be used in a multi-cell cellular system. The FFR technique is a technique of dividing an entire frequency band into a plurality of frequency partitions (FPs) and assigning frequency partitions to each cell. Different frequency partitions may be allocated between adjacent cells through the FFR technique, and the same frequency partitions may be allocated among the far-away cells. Therefore, inter-cell interference (ICI) can be reduced and performance of the cell edge terminal can be enhanced.

4 shows an example of a method of dividing an entire frequency band into a plurality of frequency partitions.

Referring to FIG. 4, the entire frequency band is divided into a first frequency partition FP0, a second frequency partition FP1, a third frequency partition FP2, and a fourth frequency partition FP3. Each frequency partition may be partitioned logically and / or physically from the entire frequency band.

5 shows an example of a cellular system in which the FFR technique is used.

Referring to FIG. 5, each cell is divided into an inner cell and a cell edge. Each cell is divided into three sectors. The entire frequency band is divided into four frequency partitions (FP0, FP1, FP2, FP3).

A first frequency partition (FP0) is allocated to the inside of the cell. Each sector of the cell edge is assigned either the second frequency partition (FP1) to the fourth frequency partition (FP3). At this time, different frequency partitions are allocated between adjacent cells. Hereinafter, an assigned frequency partition is referred to as an active frequency partition, and an unallocated frequency partition is referred to as an inactive frequency partition. For example, if a second frequency partition FP1 is allocated, the second frequency partition is the active frequency partition, and the third frequency partition FP2 and the fourth frequency partition FP3 are inactive frequency partitions.

The frequency reuse factor (FRF) can be defined as how many cells (or sectors) the entire frequency band can be divided into. In this case, the frequency reuse coefficient inside the cell is 1, and the frequency reuse factor of each sector of the cell edge can be 3.

6 shows an example of a downlink resource structure.

Referring to FIG. 6, the downlink subframe may be divided into at least one frequency partition. Here, although the subframe is divided into two frequency partitions FP1 and FP2 by way of example, the number of frequency partitions in a subframe is not limited thereto. Each frequency partition can be used for other purposes such as FFR.

Each frequency partition is composed of at least one PRU. Each frequency partition may include distributed resource allocation and / or contiguous resource allocation. The distributed resource allocation may be a DLRU, and the contiguous resource allocation may be a CLRU. Here, the second frequency partition FP2 includes distributed resource allocation and consecutive resource allocation. 'Sc' means a subcarrier.

The base station can transmit a pilot to the terminal through the downlink. The channel estimation can be performed using the pilot, or the CQI (Channel Quality Indicator) can be measured. The CQI may include SINR, frequency offset estimation, and the like. Pilots can be mapped to specific resource elements on the resource area and transmitted. A pilot structure in the resource region up to a maximum of eight antennas can be defined. Each transport stream may have the same density of pilot densities, but not all OFDM symbols in the downlink subframe need to have the same density pilot density. In addition, each PRU allocated to one terminal in one subframe may include the same number of pilots.

The pilot pattern can be defined in one PRU.

7 shows an example of a pilot pattern in one PRU.

7 shows a pilot pattern when data is transmitted through one transport stream in the downlink transmission. This may correspond to the default pilot pattern. One PRU may include 6 OFDM symbols and 18 subcarriers. The index of the OFDM symbol increases from left to right in one PRU, and the index of the subcarrier increases as the distance from the top increases. 7 (a) shows a pilot pattern for a first transport stream, and Fig. 7 (b) shows a pilot pattern for a second transport stream. Within the PRU, all OFDM symbols may include at least one pilot.

Fig. 8 shows another example of the pilot pattern in one PRU.

8 shows an example of a pilot pattern when data is transmitted through two transport streams in downlink transmission. FIG. 8- (a) shows a pattern of a pilot (hereinafter referred to as 'first pilot') for a first transport stream. '1' indicates a resource element to which the first pilot is mapped. FIG. 8- (b) shows a pattern of a pilot (hereinafter referred to as 'second pilot') for the second transport stream. '2' indicates a resource element to which the second pilot is mapped. No data or pilot may be mapped to the resource element to which the second pilot is mapped in the first transport stream and no data or pilot may be mapped to the resource element to which the first pilot is mapped in the second transport stream . If the subframe includes five OFDM symbols, the last OFDM symbol in the pilot pattern of FIG. 8 may be omitted. When the subframe includes seven OFDM symbols, the pilot transmitted in the seventh OFDM symbol in the pilot pattern of FIG. 8 may have the same pattern as the pilot transmitted in the first OFDM symbol.

9 and 10 show another example of a pilot pattern in one PRU.

Figures 9 and 10 illustrate an example of an interlaced pilot pattern for two transport streams. The staggered pilot patterns of FIGS. 9 and 10 can be obtained by cyclic-shifting the basic pilot pattern of FIG. The staggered pilot pattern may be used by one base station for one or two transport streams, respectively. 9 shows an example of a pilot pattern for a first transport stream. 9- (a) is a pilot pattern set 0, FIG. 9 (b) is a pilot pattern set 1, and FIG. 9 (b) is an interlaced pattern. (c) shows the pilot pattern set 2.

10 shows an example of a pilot pattern for a second transport stream. Fig. 10- (a) shows a pilot pattern set 0, Fig. 10 (b) shows a pilot pattern set 1, Fig. 10 - (c) shows the pilot pattern set 2. Each base station may select one index of the pilot pattern set from among the set of staggered pilot patterns shown in FIGS. 9 and 10 to transmit the first pilot and the second pilot. For example, the first pilot and the second pilot can be transmitted by selecting the pilot pattern set 0 of FIGS. 9- (a) and 10- (a). 9- (a), 10- (b), 10- (b) and 9- (c) c and a pilot pattern set respectively.

The index of the pilot pattern set selected by each base station can be determined by Equation (1).

In Equation (1), p _k is an index of a pilot pattern set selected by each base station. k is the cell ID. c is the total number of cell IDs. i is the number of sets of pilot patterns. For example, if the total number of cell IDs is 768 and the number of pilot pattern sets is 3, Equation 1 can be expressed as p _k = floor (k, 256). floor (k, 256) is the largest integer less than the quotient of k divided by 256. and p _k may be any of 0 to 2.

The index of the pilot pattern set selected by each base station can also be determined by Equation (2).

In Equation (2), p _k is an index of a set of staggered pilot patterns selected by each base station. k is the cell ID. i is the number of pilot pattern sets. For example, if the number of pilot pattern sets is three, the above equation (2) can be expressed as p _k = mod (k, 3). mod (k, 3) is the remainder of dividing k by 3. Therefore, p _k can be any of 0 to 2.

Although FIGS. 9 and 10 illustrate the pilot pattern for two transport streams, a staggered pilot pattern may be used for one transport stream.

11 shows an embodiment of the proposed pilot transmission method.

In step S100, the base station generates a pilot for one transport stream.

In step S110, the base station determines one of the plurality of pilot patterns. In determining the one selected pilot pattern, the base station allocates a first index and a second index to a plurality of pilot patterns, respectively, and selects a first selection index calculated based on a cell ID (cell ID) And the second selection index may be the same as the first index and the second index, respectively.

12 to 14 show an example of a staggered pilot pattern according to the proposed pilot transmission method when the data stream is one.

12- (a), 12- (b), 13- (a), 13- (b), and 14- ) Constitute a pilot pattern set, respectively. In the case of one data stream, the pilot pattern is the same as that shown in Figs. 12 (a), 12 (b), 13 (a), 13 (b), 14 ). ≪ / RTI >

Each base station can select a pilot pattern using an index of a pilot pattern set and an index of a stream set in selecting any one of the six pilot patterns.

The base station first determines the index of the pilot pattern set. The index of the pilot pattern set selected by each base station can be determined by Equation (3).

In Equation (3), p _k is an index of a pilot pattern set selected by each base station. k may be a cell ID. c is the total number of cell IDs. i is the number of pilot pattern aggregates or the total number of segments. A segment means each group when a plurality of cells are divided into several groups. For example, if the total number of cell IDs is 768 and the number of staggered pilot pattern sets is 3, Equation 1 can be expressed as p _k = floor (k, 256). floor (k, 256) is the largest integer less than the quotient of k divided by 256. and p _k may be any of 0 to 2. The indexes of the set of pilot patterns in FIGS. 12A, 12B, 13A, 13B, 14A and 14B are respectively 0, 1, and 2, respectively.

The base station then determines the index of the stream set. The index of the stream set selected by each base station can be determined by Equation (4).

s _n is the index of the stream set selected by each base station. j is the number of possible streams. The number of possible streams is determined by the number of total streams and the number of streams for which downlink transmission is currently performed. For example, if the total number of streams is two and the downlink transmission is performed through one stream at present, the number of possible streams is two. mod (n, 2) is the remainder of dividing n by 2. n may be a cell ID. Here, s _n may have a value of 0 or 1. For each set of staggered pilot patterns, there may be two sets of streams. For example, the pilot pattern of FIG. 12- (a) may be a 0-th stream set of pilot pattern set 0 and the pilot pattern of FIG. 12- (b) may be a 1-th stream set of pilot pattern set 0. Similarly, the pilot pattern of 13- (a) is the 0th stream set of the pilot pattern set 1 and the pilot pattern of FIG. 13- (b) may be the 1-th stream pattern of the pilot pattern set 1. The pilot pattern of 14- (a) is the 0th stream set of the pilot pattern set 2 and the pilot pattern of FIG. 14- (b) may be the 1-th stream set of the pilot pattern set 2. In Equation (4), n may be the ID of the terminal to which the pilot is transmitted.

When the frequency reuse factor is 3 (that is, when the number of pilot pattern sets is 3), the existing two streams are transmitted by selecting the pilot pattern using the cell ID using Equation (3) and Equation (4) It is possible to further reduce the probability of collision of pilots transmitted from different base stations when one stream is transmitted. That is, when the frequency reuse coefficient of the pilot pattern is 3, each base station selects one of the pilot pattern sets 0 to 2 of FIGS. 12 to 14 according to the cell ID, and again selects a stream set in the selected pilot pattern set The collision of pilots can be prevented as much as possible. In addition, the staggered pilot patterns shown in FIGS. 12 to 14 can be extended to a case where the frequency reuse factor is six. When the subframe includes 7 OFDM symbols in the example of the staggered pilot patterns shown in FIGS. 12 to 14, pilots transmitted in the 7th OFDM symbol in the pilot patterns of FIGS. 12 to 14 are transmitted in the 1st OFDM symbol It can have the same pattern as the pilot.

Alternatively, the index of the set of staggered pilot patterns selected by each base station can be determined by Equation (5).

In Equation (5), p _k is an index of a pilot pattern set selected by each base station. k may be a cell ID. mod (k, 6) is the remainder of dividing k by 6. p _k may be any one of 0 to 5. The index of the set of staggered pilot patterns in Figs. 12- (a), 12- (b), 13- (a), 13- (b), 14- Can be 0, 1, 2, 3, 4, 5, respectively.

Referring again to FIG. 11, in step S120, the base station maps the generated pilot to a resource element based on the selected pilot pattern, and transmits the mapped pilot to the terminal.

An embodiment of the invention of FIG. 11 can be described again through a transmitter and a receiver in which an embodiment of the present invention of FIG. 2 is implemented.

The pilot generator 210 of the transmitter 200 generates pilots.

The processor 220 determines one pilot pattern among a plurality of pilot patterns, and maps the generated pilot to resource elements based on the one pilot pattern. In determining the one selected pilot pattern, the processor 220 selects the selected pilot pattern based on the first selected index and / or the second selected index calculated based on the cell ID (cell ID) among the plurality of pilot patterns. . The transmitter 200 may transmit data by selecting any one of the six pilot patterns shown in FIGS. 12 to 14 when the data stream has one data stream. The different pilot patterns are cyclically shifted to the frequency domain or the time domain. For example, Figures 12- (a), 12- (b), 13- (a), 13- (b), 14- The pilot is shifted and mapped to the resource area. 12 (a), 13 (a), 14 (a) and 12 (b), 13 (b) and 14 (b) Is mapped to the resource area. The pilot patterns of Figures 12-14 may be pre-stored in the memory of the transmitter 200 or receiver 300 and may be known by receiving information about the pilot pattern through signaling from the transmitter 200 in the case of the receiver 300 .

The processor 220 of the transmitter 200 selects a pilot pattern by calculating the first selection index value and the second selection index value. The first selection index can be determined by the formula p _k = floor (k, c / i). Where p _k is the first selection index, k is the cell ID, c is the total number of cell IDs, i is the number of pilot patterns or the total number of segments. to be. floor (k, c / i) is the largest integer less than the quotient of k divided by c / i. For example, in a case where the number c of total cell IDs is c = 768 and the number of pilot pattern sets i = 3, a cell having a cell ID of 0 to 255 can select any one of 12 pilot patterns as a pilot pattern, A cell having a cell ID of 511 can select any one of 13 pilot patterns as a pilot pattern and a cell having a cell ID of 512 to 767 can select any one of 14 pilot patterns as a pilot pattern. Also, the second selection index may be determined by an equation of s _n = mod (n, j). Where s _n is the second selection index, n is the cell ID, and j is the number of sets of staggered pilot patterns. mod (n, 2) is the remainder of dividing n by 2.

Transmission circuitry 230 is coupled to processor 220 to transmit and / or receive pilot and radio signals.

The receiving circuit 330 of the receiver 300 transmits and / or receives pilot and radio signals. The channel estimation unit 310 estimates a channel using the pilot. Processor 320 processes the radio signal using the estimated channel. In order for the receiver 300 to decode the data transmitted from the transmitter 200, it is necessary to know which pilot pattern is selected among a plurality of pilot patterns.

The cell ID must be detected to know which cell the data was sent from. The cell ID can be calculated by Equation (6).

n is a preamble carrier set index having a value of 0, 1, or 2 and indicates a segment ID. A segment means each group when a plurality of cells are divided into several groups. q is a preamble sequence index and may have an integer value from 0 to 255. For example, if there are 768 cells in total and n has a value between 0 and 2, 768 cells can be divided into 3 segments. Cell IDs 0-255 can belong to segment 0, cell IDs 256-511 can belong to segment 1, and cell IDs 512-767 can belong to segment 2, respectively. q defines different cells within each segment. Each cell can be distinguished from each other by different preamble sequences. Each segment has 256 different preamble carrier sets, and 256 preamble sequences belonging to each segment correspond to q, respectively.

Tables 1 to 3 show the preamble carrier set of each segment. Table 1 shows a preamble carrier set of a segment with n = 0, Table 2 shows a segment with n = 1, and Table 3 shows a preamble carrier set with a segment with n = 2. However, a complex conjugate value of a preamble carrier set in which q is 0 to 127 can be used for a preamble carrier set with q of 128 to 255. Each preamble is formed based on subblocks A through H, and the subblock may be partially or totally combined or repeated depending on the FFT size (e.g., 512 FFT / 1024 FFT, 2048 FFT).

q / blk A B C D E F G H 0 314C8648F 18BC23543 06361E654 27C552A2D 3A7C69A77 011B29374 277D31A46 14B032757 One 281E84559 1A0CDDF7E 2473A5D5B 2C6439AB8 1CA9304C1 0AC3BECD0 34122C7F5 25362F596 2 00577AC77 38F9CBBC6 04DBCCB40 33CDC6E42 181114BE4 0766079FA 2DD2F5450 13E0508B2 3 3BE4056D1 2C7953467 0E5F0DE66 03C9B2E7D 1857FD2E3 15A276D4F 210F282AF 27CE61310 4 3DBAAE31E 254AE8A85 168B63A64 05FDF74FB 3948B6856 33656C528 1799C9BA1 004E0B673 5 177CE8FBC 21CEE7F09 397CD6551 01D4A1A10 1730F9049 067D89EA9 3AC141077 3D7AD6888 6 3B78215A1 17F921D66 385006FDC 011432C9D 24ED16EA6 0A54922F1 02067E65D 0FEC2128D 7 01FF4E172 2A704C742 3A58705E1 3F3F66CD2 07CA4C462 1854C8AA3 03F576092 06A989824 8 1A5B7278E 1630D0D82 3001EF613 34CCF51A1 2120C250A 06893FA2D 156073692 07178CFA7 9 032E31906 2DD318EAA 1DE55B14D 0EF4B6FB3 27DED0610 1BC8440D3 0ED86BF8D 14FAFDE2C 10 174725FFD 0D2FB1732 124470F56 292D9912B 1571408A7 227197AE9 2430BC576 0B67304E0 11 1F1DCD669 293DD1701 0C34F1B84 28496EE51 3DC41327F 071C06523 28E1657B6 02588FED 12 22E4AA041 3810362F1 1955F1DE7 0D6D2F8BE 11F31358E 3EB27BB12 1F4E60111 119BDA927 13 14300B522 152E6D482 168DF6E43 0740B7AE0 14FE7DCDD 0FA092626 23697615A 1F1331EB8 14 12C65ED00 317643CD7 2C637A415 15E3E5185 0F5CBB9E0 23290B156 26F37EFE8 1AA174793 15 1DD6453F0 032C4BD39 082659BD5 320C5E691 224E555B2 3A9615A8D 1BED03424 28E6A9CED 16 068AE7EE9 16F724910 3803DD9BD 2A31A2FFB 010BF5237 33CB067E6 0280C28B7 184417B94 17 1D651280A 2C7BCF443 17324EFB0 236E5C411 381215183 2F076E64E 0A6F2EE74 3DA4196B7 18 27341650F 1B520099C 09AC91114 000A5F48B 30AB4B9B6 2D0DB0DE6 1CF57978A 2D424406B 19 3A01E2FB2 0DF5B257B 019D1C63A 0EA7DCDDB 242D96605 2DA675F15 1DEC54193 3B6341C16 20 2DDFAEB05 21D0A1700 0FA09BB78 17DA7F8BB 06E883B3F 02E6B929B 2C1C413B4 030E46DD1 21 1B625E3F9 0F708F756 00CD97B18 3F036B4DF 2CF08C3E5 213A5A681 14A298D91 3D2ED63BC 22 2DA48D5A9 0C085BD17 01903428A 3DF2A30D9 29061309A 16F7DC40E 2AF88A583 27C1DA5E9 23 30DBAC784 20C3B4C56 0F1538CB7 0DDE7E1BE 2C312903B 0FF21E6C2 032C15DE3 26C9A6BA4 24 3188E8100 385FEFE2D 3967B56C7 3F62D246B 1826A755E 2CDA895EA 2FAB77825 1B525FF88 25 339467175 2DE49506B 27B7282A9 0254470A3 3374310AF 2DF20FD64 3848A6806 11C183E49 26 02AFA38DC 0F2AFDDF4 1A05650E2 061439F88 11C275BE0 30C41DEC9 119E070E9 1E76542C1 27 1B364E155 086FF808C 29F1BA9DC 0A830C788 2E70D0B3A 34EA776B1 3D13615C0 15FC708D4 28 38ECFC198 07034E9B3 2340F86B3 07562464C 22823E455 1F68D29E9 257BB66C6 1083992F1 29 375C4F5AB 3C0F5A212 0EA21BC30 13E8A26F2 17C039773 283AD6662 1F63AB833 2DE933CAF 30 2B773E3C5 3849BBE6C 1CAD2E5AB 0405FA1DE 1B27B4269 3B3BF258F 300E77286 39599C4B1 31 1E878F0BE 0AE5267EC 376F42154 1CD517CC2 302781C47 123FEC7E0 16664D3D8 24B871A55 32 20E200C0A 1C94D2FF1 213F8F01B 369A536E0 161588399 29389C7FC 259855CAC 06025DCE2 33 28D2E001C 3C51C3727 106F37D0E 1FB0EFDD1 2CD9D33C3 1EA190527 0BB5A6F9E 074867D50 34 08EFC44B5 1B484EABE 05FEB2DE2 211AF91B5 0CF52B1E1 002B5C978 11D6E5138 0D402BDD2 35 337C618F4 0A4C31DDA 1D93003D6 006D7D088 348043A6D 325E05758 2C53EEEB8 15ED8E614 36 38375C2FF 18C78FD02 30C11EF53 3916581DD 1B75263FF 2D8DFD6A9 00C4E8482 1D201F96A 37 2E10B0D05 2EF203893 2491D95F1 34D995B51 32214BDF5 3E45674B1 3E74AC66E 1B813A999 38 153E7269D 2391C7BFC 1ADD3A595 0EFD3086E 00AD88A8E 0D8B007CA 0F22C5F9D 010E86385 39 3B58C7BFF 0BA76496E 3AD0B7BBF 1D6D10FB3 3A607BEFC 28F122A95 057950727 179449CB7 40 37AC5194A 390BD9C00 3A48C0461 12FBCE4C6 2A8DD4171 10E9F1E34 251F5D167 1124E96B1 41 0FEF20C67 31EC9EA3F 275B31143 22DA4F02B 352C0F648 21FF5B9F3 3E5BC2372 0A1AE08FE 42 080EDC49B 17AD7F7BA 390775B3C 1380B00DA 2477FF17C 2E6D9E5AF 05381F2DD 26143CC17 43 2DB485795 1B3252799 39AD0211C 3AAE31B76 30532A187 1C8EA5F5A 2EA6E4D6B 30570A2E4 44 11BB4F78A 12CCE1428 2C67EEF99 20E3F841A 20CFCD5F2 1618A7B94 111FF6092 2ED034E06 45 1C66335E5 0CA9B9BD2 3213028AE 15542DD28 290F7DAE2 2137F02D5 17DF9445D 24F162FFB 46 360FB966B 17D878955 1C1D67093 065B84F3A 1A1D955E3 24C73C11E 270EA9EB2 114DCA02C 47 002CE84DD 0616DD253 3EB188345 1FF852926 37E160F00 040DF51EC 1857A33BA 230FD8A0D 48 233C0A71F 22E428104 0325F8170 39566B188 32DA16A4A 039FDF1DC 27A3E946C 0D69F26D9 49 0583F9F73 378380CB6 059D8A960 3E3442C7F 026138ADB 25F370F1E 09D3EB2CC 2D37D50C0 50 08DF9CC66 2C2E7AA8F 3CB241ED2 03216B4D2 39736B451 25F6F113F 08FD2AC3C 1974574FD 51 3D1FF6041 2CE2AB97F 01A734F3B 1DCF9F3C5 268D595CA 1FBD2A8B8 0F1449F86 370C352FD 52 123218E40 3AA057589 20F73A16F 26E3BCA5F 3A7330DC6 12C659384 39D99FF1B 276DFC540 53 185AEDEA4 0418B3643 382F7700A 3FC35ED60 07BA2F838 1BC840C93 2469A41EC 0CE7B4CB0 54 2E194E2BF 3302A0B28 1836001EE 154A4738A 36A3BBD72 23CCD0EB1 044B3A13B 2B50C8057 55 0B76405D3 231AAA728 0EE05E9B6 0093A21F2 2065A01D0 1F2B810D4 1082F3A73 1DAFEA492 56 07AD23A3A 2091957F1 3B9D8CBF0 21E4160BE 1BFB25224 3D9085D16 03076DD39 1DBCF8D03 57 226D70EBF 3ED15246C 364130C46 22F6D4AA3 3FCC9A71B 3B9283111 0484F0E58 14574BD47 58 3F49B0987 305231FA6 0CF4F6788 3B9296AED 2346190C5 3365711F4 078900D4A 352686E95 59 1D62AC9A4 104EDD1F5 1B0E77300 1CED8E7F0 388E8002C 1FE6199F4 02239CB15 1FE5D49A2 60 21314C269 28600D12A 22E4F1BAA 044E211B1 0DECFE1B4 3E5B208CC 1CFC91293 21E7A906B 61 02C029E33 1BA88BE4D 3742AE82F 21EF0810F 17D23F465 240446FB5 17CCE51D9 2C0B0E252 62 16F9D2976 10185ECE6 2821673FD 02674271C 3A8A75B7C 226D4BF0F 2216004E5 0E8605674 63 06E4CB337 32A31755D 062BE7F99 1417A922D 2271C07E5 24D6111FA 3F2639C75 0CE2BB3A0 64 18D139446 2426B2EA8 352F18410 1133C535E 10CC1A28F 1A8B54749 22A54A6F4 2F1920F40 65 22443017D 2265A18F5 14E1DAE70 11AC6EA79 31A740502 3B14311E7 3AA31686D 26A3A961C 66 2018F4CA9 3A0129A26 39BDA332E 1941B7B49 03BBCE0D8 20E65BD62 2E4A6EE6C 3B095CCB3 67 0CC97E07D 11371E5FF 31DFF2F50 17D46E889 352B75BEA 1F1529893 21E6F4950 1BD034D98 68 275B00B72 125F0FE20 0FB6DE016 0C2E8C780 3026E5719 119910F5F 3B647515B 1D49FED6F 69 250616E04 0882F53BF 11518A028 3E9C4149D 09F72A7FB 0CC6F4F74 2838C3FD1 08E87689B 70 212957CC2 03DD3475B 044836A0B 2463B52C0 0342FB4B0 34AD95E9B 2936E2045 3B0592D99 71 2922BD856 22E06C30C 390070AED 09D6DC54F 3485FA515 064D60376 07E8288B3 3DD3141BF 72 29CB07995 007EE4B8B 16E787603 07C219E93 1031B93DD 23DEFF60B 30F1D7F67 0EFE02882 73 11F3A0A2F 38C598A57 3FE72D35B 1F655E0D1 0B3AC0D92 3430DDB1A 3BAADBF42 02D6124C0 74 05FC8085D 345A5C470 07DAAE1E9 0D7150B88 25D2A5B10 16F8E5021 3240EFC71 0F0F5922D 75 399F32F6E 2EEB17A8E 0D61665D0 2138EE96F 3F8119063 01B5048F7 27075153D 265DF8280 76 3962CC581 2337D2983 286FD7BBA 185126E0E 1F95AD927 0F7EBC374 1E3A4B6FF 20CA9B9BD 77 1C85C13AF 290C37167 1FDD26E8F 0C38736B8 0174DB972 0A921E3CC 097557C9D 09452C1E6 78 2D48D6C00 2D9BC8DFE 10FF1E128 25C96BA85 0FB071B8E 0F09B3C9C 1A3E11441 38EDDA03D 79 396B88B2F 0029F4BDB 30D098CAD 0D54D12CB 1D0823F55 2DC53B9AA 11BCF7438 33F6EC091 80 21E03CD65 1A2FE5B92 2851F8445 0251E386C 1468950D8 1A8B39748 001B42236 26CD82DA5 81 2CEA1E6BB 006C97E74 00C2B887D 23461AF95 0E9CB2BD2 0B0EA3022 1FB56A7A3 25A7FA625 82 208FC2A1F 381C5733A 03F11D7E3 07ED6A7B7 1FEC85E09 3D61E0440 356F4B1C3 3756E5042 83 2061E47F0 22EAA0AD3 24796BB65 03C59B4D8 32A75E105 22155381B 23E5F041C 155D2D7F9 84 381AFFB73 212B5E400 1F1FE108E 04BF2C90D 3C1A949D9 2854A9B45 001B09322 3A9372CC1 85 058B23433 0904C6684 158CADB9E 11BA4B978 1854368F4 1919ECEA7 147F1FD34 2E228AA3C 86 34857F3DB 2CB44F7BF 111A065D3 1BEAB392E 27F081ED8 3E67D1186 0F6265AC5 27716FAF9 87 38EBB8BF1 32ED6E78F 2B0BA4966 2188282AA 00D49B758 1765BA752 2B50AFDCC 068C82450 88 234F0B406 02FB239CD 15AD61139 2250A5A05 1CD8117E0 0D849163F 268C7A5A6 22A802020 89 2D0FE8D16 0C14E3771 07DE5320C 0640C2762 1CBD9FF4E 37A91986D 2024DA401 164D4A84C 90 3225B4D60 3013B75F2 2A77AE5C5 2C25377EE 03C8DF835 346E80FCB 116B79FA5 356D2B604 91 0D55231FD 247907F31 0CFA0B049 36D069A95 10D4CDE71 1A32544D7 38336885F 173ECC08D 92 207420EAC 26FCFE182 3FE7B31C6 15B320E13 187AA34A8 1B52253BF 1FA16669D 3725A81A5 93 3C9C7404A 092B77FEB 3B9865B46 349456F61 39B7C6A66 3075EC990 01BE637DF 330897B17 94 1CA4C048D 2B4D50621 2BF917627 3EA2CC5E1 33EC0A1E3 05FE0F747 349553D72 396077301 95 04CEC1C82 1F828DD00 30122C790 1AD8A7895 1CE0912C0 298382F37 2D4D33F06 001364B36 96 37F8BB035 2F0897994 333F5F096 0F28AB363 20036829F 338017E2D 3A5A05D76 0CC02E5E0 97 02FD351E6 03E316288 2FCAEB4F8 1C5A80CE3 3D3AC3FDD 3E456746D 119A5381F 1581C894E 98 1623B3D0F 103224DB0 0FB936BC8 2EED7F082 26C91513A 2F12E4C31 290F3AEF2 392CBFF67 99 02F75DE8F 2E61A834D 02A692866 1F21044A3 2D7881A95 18651EE05 11FE3D308 39EED56DA 100 3A858659E 2F7A87BE0 135FD561D 27B3B651A 05E131CB9 0D5865123 2CD6991E5 3EE6DF705 101 3F3B247E1 32D02B245 16B98A593 1E4CCFF18 0C4A9D285 06D519FE2 023A336CD 1B20E999E 102 3A9E8B49B 239656AD1 3396D1C51 06F4DCF40 15D819D3F 2A3061144 20BD2A33E 2FFB139CD 103 38622F3AF 24BF9BB7F 1D2729010 15877B93A 00376B0E7 0FF064887 3505CFD9B 354C366B6 104 2A0AB7033 1AFA65DE1 1198D0AD6 38E80C86A 27693D541 3BB26F3D4 39154881C 0E7DD6B6B 105 1B0DE4333 27FE0F6D1 0F00B2888 0BDA322FF 2759B5A4F 0543A2D27 0C36DD1E5 04E9A262D 106 1C7E636BF 000E9C271 2B44F4F30 28255BF77 1CC4D69CE 03F4C57B2 3E926D59B 00AA39BDB 107 1FDE98AE0 0CD076B07 171124FB5 33F098288 1E0B3043E 39731D117 3E7ABC2C8 19CC50279 108 28EE855ED 2A704C371 03288F4B0 3C83E26C2 0A905148B 18C66BB94 1BCC32537 10D71AB44 109 26238A065 0FBD7BCDD 02507CF76 059F69484 3FE0D6F77 2466A50DB 3C07A75B2 2DC0F099E 110 3CDCD6CBE 1446783DA 1626C83F9 2FD4C4DF3 13A59A2D1 2C903D2A3 0FD37F076 0B1039EDD 111 043B07DD7 28D9C2155 2CCEF57A8 34254C1B7 09B933B2F 1FA410127 10BD5E9E6 010EC6389 112 345E8FCAC 226BD7EFA 27341A51C 23854F031 04C297212 044DED8E8 319B3BFB8 37DBBBF57 113 16FBEFA72 1B5EF9484 2DEE7A5BF 097695C12 08AEAD5E8 3DA7C1327 2B81F3E2D 31AFBED32 114 3484086B1 2DFA56B9E 226E8AFE5 285F45484 3E69AC8E1 1CB33645F 2DE53BC30 2F6ED567E 115 1117B5E7D 122A4D471 1AC936544 267010D71 10428CA47 24B72A000 2E27FE185 1E62C1403 116 0B3161E37 038C3DC98 100793647 1A95D8D36 399668787 06C0D4922 25F48AA58 2DFFF1789 117 04FEF7231 381910B63 298783078 30CE5EC1C 29F6F299D 3C34CA770 37BAAB139 3D2069B65 118 18F644052 2051880EC 23ADBF949 04237280A 18304E663 287364EFF 314698D78 149A21E51 119 39E14BBCB 1DBDA9EF4 3ECCAD8D3 1BA3EF99D 26D85CEBF 270547292 0FB3C7826 0131E73D6 120 2DD6F3F93 0FC282088 14A143DDD 0AB840813 0B973037C 29535C9AB 0DF8DA2AC 271CBC095 121 1C1D063F9 3F4EF6DCC 00128D932 145E31F97 0B21590D1 38F1602D8 3AC2EBB74 2320957C5 122 3383C846F 12128F29B 19985CE7D 2834CBBF2 1E1513B3D 364DB5800 33EE3F46C 01A865277 123 0129D260B 238A85BA0 2D81AA924 3917048B6 36F857692 1D2F813C3 0505FB48B 3DC438BC5 124 05E0F8BDC 3D978C1F1 266F83FCA 0E89D715A 01821DEA4 12D9AE517 22F8EAC2C 3C098DA58 125 1575D1CE9 26F291851 3A7BB6D2C 12CC21A3A 2975589B0 39CF607FF 388ABF183 3D3BAAB0B 126 101E5EC7A 0B75BCF3B 13ED25A86 35FC032B6 2F6209FF0 13C7B2041 1F2791466 3A759A6C2 127 1EF89091A 11A653D2C 223FC1F42 2F7B97B31 2CA4EE011 00F68767D 10FE34682 018339212

q / blk A B C D E F G H 0 20A601017 10D0A84DE 0A8C74995 07B9C4C42 23DB99BF9 12114A3F5 25341EDB0 362D37C00 One 1364F32EC 0C4648173 08C12DA0C 19BD8D33A 3F5F0DDA6 24F99C596 026976120 3B40418C7 2 1C6548078 0A0D98F3C 0AC496588 38CBF2572 22D7DA300 1CCEAF135 356CA0CCF 093983370 3 03A8E3621 2D2042AF5 2AB5CC93B 05A0B2E2E 0B603C09E 117AC5C94 2D9DEA5A0 0BDFF0D89 4 07C4F8A63 3E6F78118 32CCD25F2 1792A7B61 0A8659788 1F9708C04 086AF6E64 040B9CD78 5 2D7EE485A 2C3347A25 3B98E86AF 242706DC3 1CEF639AF 2E1B0D6A9 3E9F78BC1 0FB31275F 6 0307936D0 21CE15F03 392655B2D 17BE2DE53 3718F9AB8 01A986D24 077BDA4EB 1D670A3A6 7 05A10F7B7 31900ACE0 28DCA8010 2D927ABE5 370B33E05 31E57BCBE 030DC5FE1 093FDB77B 8 092C4FED1 268BF6E42 24576811F 09F2DAA7F 24EFFC8B1 21C205A90 1E7A58A84 048C453EB 9 29F162A99 1F739A8BF 09F684599 1BEC37264 38ED51986 286325300 344FC460A 3907B1161 10 0E4616304 0FABDCD08 0F6D6BE23 1B0E7FEDD 0047DE6C2 36742C0C6 2D7ABB967 10D5481DF 11 32DD51790 237D6ACFA 2F691197A 16724EA58 149143636 3810C6EE1 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3997FC7B7 06E414374 180DCD64F 108 18399ED59 224E6C2FF 3450F1BB7 27A1CA959 21B5E00F8 13B67DAE8 0B14C022E 0E41BBEE2 109 318D94D05 2EBB53B17 331C3E6F4 0FBCD71ED 380FF18B8 3E3C75B26 0E0088A18 17553D2A2 110 37AC7E5D5 27C9EADFA 3FC47B5E4 38699BB57 1564F8B27 3579C7FEB 13401BD88 0DB519DE0 111 0FF4D6F22 3C84242F3 2DEAE40AD 305F320A5 244CB97B0 0892DA905 3F09D5CB5 332E7DB02 112 31479E580 1B6AD13E0 16A1CF9E2 33A0A119A 1AC8388E9 3D4105F37 226501835 27AF1310F 113 1CBDAFE39 3E5A30C1C 236E9A029 063430D97 0CD91A825 02F335D7E 1989FE0BE 13C4E2A20 114 10B393370 33CB79316 2CEB44FC0 236019420 248F95ACB 35034B6F0 365691771 34A8FBCB6 115 25463FC5F 082FC0ED2 038ACE1CC 3E959B49D 21B8C04F5 08633F3A0 3A5D18159 12B3EC4C7 116 167B32C3E 06FF88387 34C3F468B 3239005B2 121C913AF 21C90CE16 28B54D557 3811CB0A9 117 221BD0503 0AF619499 21F8D40C1 1B3DA7AEE 3FA2E3B05 348466C50 10F12A28D 0E70B26AB 118 1D79A57C5 315D2460F 1402B8222 28DC66FEA 1BCF748F9 2AD5D4227 0094D2CAD 25EA22A58 119 062B39CFB 310E8818D 0F2D0A235 3F6468866 33F86F342 39CAB5BBC 2E7D6A8BF 3E9218162 120 2FCDEA0E0 1BDD766A4 2827B99BB 0B5F04CC9 1C9E02A9A 1A6675ED4 033497A06 07D4ADD44 121 3CD46CD9D 311A64A85 24DDFE6FF 3411C6FE5 0D0613CDA 0E9276056 178ACC4F8 23DEA3CB0 122 2762D6A40 306FE3843 1402589C8 382B07654 160BA3DEA 3815B54C8 273960105 2076A15E5 123 1C593A744 1562487F6 0C38617B4 2CA68266A 071C4BF93 2593F0BDC 1562436E5 199BEEA49 124 35B8C7503 278F57EAA 34A804061 19C657A74 385734710 3FAC27628 0707BED4E 32F20F45E 125 34994C46C 1C6B99499 1AF24D850 11AD795D3 19288BFE9 1360C1B96 3B5D8DBC0 2554E72D6 126 22D7095A4 34B70502A 3F0CB27D2 04FC214E6 24C0B80C5 03D6F4DC8 1432A099E 26300D70E 127 21C33416F 18B894695 3AC062614 3537CF601 00A20A8B8 1CD10BAF5 394DF1DC0 0925851ED

The processor 220 detects a preamble through auto-correlation or cross-correlation and obtains n and q values, and detects a cell ID based on the n and q values. The processor 220 may determine a pilot pattern based on the cell ID and Equations (3) and (4).

The present invention may be implemented in hardware, software, or a combination thereof. (DSP), a programmable logic device (PLD), a field programmable gate array (FPGA), a processor, a controller, a microprocessor, and the like, which are designed to perform the above- , Other electronic units, or a combination thereof. In software implementation, it may be implemented as a module that performs the above-described functions. The software may be stored in a memory unit and executed by a processor. The memory unit or processor may employ various means well known to those skilled in the art.

In the above-described exemplary system, the methods are described on the basis of a flowchart as a series of steps or blocks, but the present invention is not limited to the order of the steps, and some steps may occur in different orders . It will also be understood by those skilled in the art that the steps shown in the flowchart are not exclusive and that other steps may be included or that one or more steps in the flowchart may be deleted without affecting the scope of the invention.

The above-described embodiments include examples of various aspects. While it is not possible to describe every possible combination for expressing various aspects, one of ordinary skill in the art will recognize that other combinations are possible. Accordingly, it is intended that the invention include all alternatives, modifications and variations that fall within the scope of the following claims.

Claims (14)

A base station in a wireless communication system,
A pilot generator for generating a pilot for one data stream;
A transmission circuit for transmitting the generated pilot and radio signals; And
A processor coupled to the pilot generator and the transmission circuit,
The processor comprising:
Generate interlaced pilot patterns;
Selecting a set of one of the plurality of sets of pilot patterns;
Selecting one set of streams from among a plurality of sets of streams within the selected one set of pilot patterns; And
And mapping the generated pilot to resource elements based on the selected one pilot pattern set and the selected pilot pattern corresponding to the selected one stream among the staggered pilot patterns,
The index of the selected one pilot pattern set is determined by the following equation,
p _k = floor (k, c / i)
However, p _k is an index of the selected one pilot pattern set. k is a cell identifier. c is the total number of cell IDs. i is the number of sets of the plurality of pilot patterns. floor (k, c / i) is the largest integer less than the quotient of k divided by c / i,
Wherein the index of the selected one stream set is determined by the following equation:
s _n = mod (n, j)
Where s _n is the index of the selected one stream set. n is the cell ID. j is the number of the plurality of stream sets. mod (n, j) is the remainder of dividing n by j. The method according to claim 1,
Wherein the number of the staggered pilot patterns is six. delete The method according to claim 1,
Wherein c = 768 and i = 3. delete The method according to claim 1,
Wherein j = 2. The method according to claim 1,
Wherein the pilot patterns corresponding to the plurality of stream sets in the selected one pilot pattern set are cyclic shifted in the frequency domain. The method according to claim 1,
Wherein pilot patterns having the same stream set index and different pilot pattern set indexes are cyclically shifted in the time domain. A terminal in a wireless communication system,
A receiving circuit for receiving a pilot and a radio signal for one data stream;
A channel estimator for estimating a channel using the received pilot; And
And a processor for processing the received radio signal using the estimated channel,
The pilot is mapped to a resource element based on a pilot pattern selected in a transmitter,
Wherein the selected pilot pattern corresponds to a selected one of a plurality of pilot pattern sets and a selected one of a plurality of stream sets,
The index of the selected one pilot pattern set is determined by the following equation,
p _k = floor (k, c / i)
However, p _k is an index of the selected one pilot pattern set. k is a cell identifier. c is the total number of cell IDs. i is the number of sets of the plurality of pilot patterns. floor (k, c / i) is the largest integer less than the quotient of k divided by c / i,
Wherein the index of the selected one stream set is determined by the following equation.
s _n = mod (n, j)
Where s _n is the index of the selected one stream set. n is the cell ID. j is the number of the plurality of stream sets. mod (n, j) is the remainder of dividing n by j. delete 10. The method of claim 9,
Wherein c = 768 and i = 3. delete 10. The method of claim 9,
Wherein j = 2. delete

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