KR100860698B1 - Apparatus and method for allocating sub channels in a communication system - Google Patents

Abstract

According to the present invention, in a signal transmission apparatus of a communication system, an entire frequency band is divided into m subchannel groups, each of the m subchannel groups has a subchannel group index, and one subchannel is a subchannel group index. In the case of including n subcarriers selected from each of the m subchannel groups according to a sequence, when a signal identical to a signal transmitted from a first time point to a second time point needs to be transmitted, a first time point is transmitted from the first time point. Allocating a first subchannel by using a subchannel group index sequence, wherein the first subchannel group index sequence is a second subchannel group index used when allocating a second subchannel at the second time point. It is characterized by different sequences.

Subchannel, time-frequency domain, two-dimensional subchannel allocation, galoa field, subchannel allocator, group index interleaving, diversity gain

Description

Apparatus and method for allocating subchannels in a communication system {APPARATUS AND METHOD FOR ALLOCATING SUB CHANNELS IN A COMMUNICATION SYSTEM}

The present invention allocates a subchannel in a communication system (hereinafter referred to as an "OFDMA communication system") using an Orthogonal Frequency Division Multiple Access (OFDMA) scheme. An apparatus and method are provided.

In general, the 4th Generation (4G) mobile communication system is not only a simple wireless communication service like the previous generation mobile communication systems, but is standardized for efficient interworking and integration services between the wired communication network and the wireless communication network. have. Therefore, there is a demand for a technology for transmitting a large amount of data close to the capacity of a wired communication network in a wireless communication network.

Therefore, the fourth generation mobile communication system is actively studying orthogonal frequency division multiplexing (OFDM) scheme as a useful method for high-speed data transmission in wired and wireless channels. The OFDM method is a method of transmitting data using a multi-carrier, and a plurality of sub-carriers having mutual orthogonality to each other by converting symbol strings serially input in parallel. ), That is, a type of multi-carrier modulation (MCM) that modulates and transmits a plurality of sub-carrier channels.

The system applying the multicarrier modulation scheme was first applied to military HF radio in the late 1950s, and the OFDM scheme of superimposing a plurality of orthogonal subcarriers started to develop in the 1970s, but the implementation of orthogonal modulation between multicarriers was implemented. Since this was a difficult problem, there was a limit to the actual system application. However, in 1971, Weinstein et al. Announced that modulation and demodulation using the OFDM scheme can be efficiently processed using a Discrete Fourier Transform (DFT). In addition, the use of guard intervals and the introduction of guard intervals, such as cyclic prefixes, have further reduced the negative impact of the system on multipath and delay spread. Thus, this OFDM technology is a digital transmission technology such as digital audio broadcasting (DAB), digital television, wireless local area network (WLAN), and wireless asynchronous transfer mode (WATM). It is widely applied to. In other words, due to hardware complexity, it is not widely used, but is recently called a Fast Fourier Transform (FFT) and an Inverse Fast Fourier Transform (IFFT). The development of various digital signal processing technologies, including IFFT " The OFDM scheme is similar to the conventional Frequency Division Multiplexing (FDM) scheme, but most of all, an optimal transmission efficiency can be obtained during high-speed data transmission by maintaining orthogonality among a plurality of subcarriers. In addition, the frequency usage efficiency is good and multi-path fading is strong, so that the optimum transmission efficiency can be obtained in high-speed data transmission. In addition, because the frequency spectrum is superimposed, frequency use is efficient, strong in frequency selective fading, strong in multipath fading, and protection intervals can be used to reduce the effects of inter symbol interference (ISI). In addition, it is possible to simply design the equalizer structure in terms of hardware and has the advantage of being resistant to impulsive noise, and thus it is being actively used in the communication system structure.

Meanwhile, the multiple access scheme based on the OFDM scheme is the OFDMA scheme. In the OFDMA scheme, sub-carriers within one OFDM symbol are divided and used by a plurality of users, that is, a plurality of terminals. As the communication system using the OFDMA scheme, there are an Institute of Electrical and Electronics Engineers (IEEE) 802.16a communication system and an IEEE 802.16e communication system. Here, the IEEE 802.16a communication system is a fixed broadband wireless access (BWA) communication system using the OFDMA scheme. In addition, the IEEE 802.16e communication system is a system that considers the mobility of the terminal in the IEEE 802.16a communication system, the current IEEE 802.16a communication system and IEEE 802.16e communication system 2048-point (2048-point) inverse fast Fourier transform ( IFFT: Inverse Fast Fourier Transform (hereinafter referred to as "IFFT") is used, and 1702 subcarriers are used. The IEEE 802.16a communication system and the IEEE 802.16e communication system use 166 subcarriers of the 1702 subcarriers as pilot subcarriers, and 1536 subcarriers except the 166 subcarriers are used for data ( data) subcarriers. In addition, the 1536 data subcarriers are classified into 48 groups to generate 32 sub-channels, and the sub channels are allocated to a plurality of users according to a system situation. Here, the sub-channel refers to a channel composed of a plurality of subcarriers, where 48 subcarriers constitute one subchannel. As a result, the OFDMA communication system is a communication system for the purpose of obtaining frequency diversity gain by distributing all subcarriers, particularly data subcarriers used in the system, over the entire frequency band.

Meanwhile, a method of dynamically changing subcarriers allocated to a specific terminal is called a frequency hopping (FH) method. The FH-OFDM scheme is a combination of the FH scheme and the OFDM scheme. A communication system using the FH-OFDM scheme (hereinafter referred to as an "FH-OFDM communications system") leaps the frequency bands of subcarriers allocated to terminals using the FH scheme. That is, the FH-OFDM communication system is also a communication system for the purpose of obtaining a frequency diversity gain by distributing all subcarriers, particularly data subcarriers, over all frequency bands.

As described above, the IEEE 802.16a communication system and the IEEE 802.16e communication system are systems that use a broadband, for example, 10 [MHz] broadband divided into subchannel units only in a frequency domain. The IEEE 802.16a communication system and the IEEE 802.16e communication system use 1702 subcarriers per OFDM symbol using a 2048 point IFFT. Therefore, when a subchannel is allocated using a Reed Solomon (RS) sequence having a relatively good inter-channel collision characteristic in a multi-cell environment, since 41 * 40 = 1640, approximately 40 cells are used. It is possible to distinguish between cells. For example, when using the Reed Solomon sequence defined in Galois Field (hereinafter referred to as "Galois Field") (Q), the total used subcarriers are defined as Q * (Q-1). Therefore, when using 1600 subcarriers as in 802.16a / e, 41 is selected from 37, 41, and 43, which are prime numbers near 40. This creates a system with 1640 subcarriers. Therefore, in the case of 802.16a / e, the number of subcarriers per subchannel is maintained at 48, resulting in poor inter-channel collision characteristics. Here, since the Galois Field will be described below, detailed description thereof will be omitted.

However, in order to facilitate network design with the development of a communication system, the number of distinguishable cells needs to be increased to at least 100. In terms of the number of distinguishable cells, the OFDMA scheme of configuring a subchannel only in the frequency domain has a limitation. Meanwhile, the Flash-OFDM scheme using a narrow band of 1.25 [MHz] uses a 128-point IFFT to perform a 113 hopping sequence that hops different subcarriers in one period of 113 OFDM symbols. Defines hopping sequence as basic resource allocation unit. The communication system using the Flash-OFDM scheme (hereinafter referred to as a "Flash-OFDM communication system") distinguishes 113 different cells by defining the hopping sequence differently for each of 113 cells when designing a network. It is possible to do However, the Flash-OFDM scheme is also a narrowband-only scheme and has a problem in that it cannot contribute to the capacity increase that is currently in need.

Accordingly, the present invention proposes an apparatus and method for generating a subchannel in a communication system.

In addition, the present invention proposes a subchannel configuration system and method in an OFDMA communication system.

In addition, the present invention proposes a time-frequency two-dimensional subchannel configuration system and method in an OFDMA communication system.

In addition, the present invention proposes a subchannel configuration system and method for base station identification in an OFDMA communication system.

The present invention also provides a subchannel configuration system and method for minimizing collisions between subchannels of adjacent base stations in an OFDM communication system.

The present invention also proposes a subchannel configuration system and method for obtaining diversity gain in an OFDM communication system.

The method proposed in the present invention; A method for allocating subchannels in a signal transmission apparatus of a communication system, wherein the entire frequency band is divided into m subchannel groups, and each of the m subchannel groups has a subchannel group index and one subchannel In the case where the subcarrier includes n subcarriers selected from each of the m subchannel groups according to the subchannel group index sequence, the same signal as that transmitted from the first time point to the second time point should be transmitted. Allocating a first subchannel using a first subchannel group index sequence at a first time point, wherein the first subchannel group index sequence is used to allocate a second subchannel at the second time point. 2 sub channel group index sequence.

Another method proposed by the present invention is a method for receiving a subchannel in a signal receiving apparatus of a communication system, wherein an entire frequency band is divided into m subchannel groups, and each of the m subchannel groups is a subchannel. When the sub-channel has a group index and one subchannel includes n subcarriers selected from each of the m subchannel groups corresponding to the subchannel group index sequence, a first signal from the signal transmitting apparatus corresponding to the signal receiving apparatus is determined. And receiving a sub-channel, wherein the first sub channel is configured to transmit a signal identical to a signal transmitted from a first time point to a second time point by the signal transmission apparatus. The first sub-channel group index sequence is assigned by the signal transmission apparatus. And in the second time point to the second sub-channel group index sequence and wherein the phase that was used to assign the second sub-channel.

The device proposed in the present invention; In an apparatus for allocating subchannels in a signal transmission apparatus of a communication system, an entire frequency band is divided into m subchannel groups, and each of the m subchannel groups has a subchannel group index and one subchannel In the case of including n subcarriers selected from each of the m subchannel groups according to the subchannel group index sequence, the signal transmission apparatus should transmit the same signal as the signal transmitted from the first time point to the second time point. The subchannel allocator may be configured to allocate a first subchannel using a first subchannel group index sequence at the first time point, and the first subchannel group index sequence may include a second subchannel at the second time point. It is characterized in that it is different from the second sub-channel group index sequence used when assigning.

Another apparatus proposed by the present invention; The entire frequency band is divided into m subchannel groups, each of the m subchannel groups having a subchannel group index, and one subchannel corresponding to the m subchannel groups according to a subchannel group index sequence. In the case of including the n selected sub-carriers in each, includes a signal receiving device that is assigned a first sub-channel from the signal transmission device, the first sub-channel is transmitted by the signal transmission device from the first time point to the second time point If it is necessary to transmit the same signal as one signal, the first sub-channel group index sequence is allocated using the first sub-channel group index sequence at the first time point, and the first sub-channel group index sequence is assigned by the signal transmission apparatus at the second time point. And a second sub channel group index sequence used when allocating two sub channels.

The present invention has the advantage of enabling subchannel allocation to maximize the number of distinguishable base stations in a communication system using the OFDMA scheme. In addition, the subchannel allocation according to the present invention has an advantage of minimizing the probability of collision between subchannels of adjacent base stations, thereby preventing system performance degradation due to subchannel collision. In addition, the present invention has the advantage of maximizing the efficiency of cell search and channel estimation by configuring some of the assigned subchannels as pilot channels. In addition, the present invention has the advantage that the diversity gain can be obtained by differently setting the subcarrier group to which each of the subcarriers constituting the subchannel belongs at every subchannel allocation.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.

The present invention relates to a time-frequency domain in a communication system (hereinafter referred to as an " OFDMA communication system ") using an Orthogonal Frequency Division Multiple Access (OFDMA) scheme. A sub-channel is configured in a two-dimensional region of a time-frequency domain. Thus, the present invention increases the number of distinguishable cells, that is, base stations (BSs) in the OFDMA communication system, and minimizes collisions between subchannels between adjacent base stations. In addition, the present invention configures a subchannel to minimize the occurrence of burst errors in an OFDMA communication system. Here, the base station may serve and manage one cell, and may serve and manage a plurality of cells, but for convenience of description, it is assumed that one base station manages only one cell.

Next, a structure of a first transmitter of an OFDMA communication system according to an embodiment of the present invention will be described with reference to FIG. 1.

1 is a diagram schematically illustrating a structure of a first transmitter of an OFDMA communication system for performing a function in an embodiment of the present invention.

Referring to FIG. 1, first, a first transmitter of the OFDMA communication system includes a Cyclic Redundancy Check (CRC) inserter (111) and an encoder ( encoder 113, symbol mapper 115, sub-channel allocator 117, serial to parallel converter 119, pilot A pilot symbol inserter 121, an Inverse Fast Fourier Transform (IFFT) 123, and a parallel to serial converter Reference numeral 125 denotes a guard interval inserter 127, a digital to analog converter 129, and a radio frequency (RF). A processor 131.

First, when user data bits and control data bits to be transmitted are generated, the user data bits and the control data bits are input to the CRC inserter 111. Here, the user data bits and the control data bits will be referred to as "information data bits". The CRC inserter 111 inputs the information data bit, inserts the CRC bit, and outputs the CRC bit to the encoder 113. The encoder 113 inputs the signal output from the CRC inserter 111, codes the signal by a preset coding scheme, and outputs the encoded signal to the symbol mapper 115. Here, the coding scheme may be a turbo coding scheme or a convolutional coding scheme having a predetermined coding rate.

The symbol mapper 115 modulates the coded bits output from the encoder 113 by using a preset modulation scheme to generate a modulated symbol and outputs the modulated symbols to the subchannel allocator 117. do. Here, the modulation scheme includes a Quadrature Phase Shift Keying (QPSK) scheme, a Quadrature Amplitude Modulation (QAM) scheme, a Quadrature Amplitude Modulation (16QAM) scheme, and the like. The subchannel allocator 117 inputs the modulation symbols output from the symbol mapper 115 to allocate a subchannel and outputs the subchannels to the serial / parallel converter 119. Here, the subchannel allocation operation of the subchannel allocator 117 is performed according to the subchannel allocation method proposed by the present invention, and the subchannel allocation method proposed by the present invention will be described below. Will be omitted. The serial / parallel converter 119 inputs the serial modulation symbols to which the subchannels output from the subchannel allocator 117 are allocated, converts them in parallel, and then outputs them to the pilot symbol inserter 121. The pilot symbol inserter 121 inserts pilot symbols into the parallel-converted modulated symbols output from the serial / parallel converter 119 and outputs the pilot symbols to the IFFT unit 123.

The IFFT unit 123 inputs the signal output from the pilot symbol inserter 121 to perform an N-point IFFT and then outputs it to the parallel / serial converter 125. The parallel / serial converter 125 inputs the signal output from the IFFT device 123, converts the signal in series, and outputs the serial signal to the guard interval inserter 127. The guard interval inserter 127 inputs a signal output from the parallel / serial converter 125 to insert a guard interval signal and then outputs the guard interval signal to the digital / analog converter 129. Here, the guard interval is inserted to remove interference between the OFDM symbol transmitted at the previous OFDM symbol time and the current OFDM symbol transmitted at the current OFDM symbol time when the OFDM symbol is transmitted in the OFDMA communication system. In addition, the guard interval has been proposed in the form of inserting null data of a predetermined interval, but in the form of transmitting null data in the guard interval is the interference between the sub-carriers when the receiver incorrectly estimates the start point of the OFDM symbol There is a disadvantage in that the probability of misjudgment of the received OFDM symbol increases. Therefore, the cyclic prefix method of copying the last constant samples of the OFDM symbols in the time domain and inserting them into the valid OFDM symbols or copying the first constant samples of the OFDM symbols in the time domain is effective. It can be used in a cyclic prefix manner that inserts into an OFDM symbol.

The digital-to-analog converter 129 inputs the signal output from the guard interval inserter 127 and performs analog conversion, and then outputs the signal to the RF processor 131. The RF processor 131 may include components such as a filter and a front end unit, and may transmit a signal output from the digital-to-analog converter 129 on an actual air. After the RF process, the transmission is performed on the air through a Tx antenna.

Next, the subchannel allocation proposed in the present invention and a method of using the allocated subchannels will be described.

(1) Subchannel Allocation Method in Time-Frequency 2D Domain

Indexes of subcarriers constituting the subchannel are allocated using a Reed Solomon (RS) sequence, and the subchannels are configured with subcarriers corresponding to the allocated subcarrier indices. do. The total subcarriers constituting the OFDMA communication system are classified into Q-1 groups, that is, subcarrier groups, and each of the Q-1 subcarrier groups includes Q consecutive subcarriers.

Meanwhile, the Reed Solomon sequence is defined in a Galois field (hereinafter, referred to as "Galois Field") Q, and the Galois Field Q is Q elements {0, 1, 2, ..., Q-1}. Here, Q represents the size of the Galois Field, and when the Q is a prime number, the addition operation and the multiplication operation in the Galois Field (Q) are defined as in Equation 1 below.

On the other hand, the sequence S defined in the Galois Field (Q) is a sub-channel sequence indicating the positions of the sub-carriers constituting the sub-channel, allocated in each of the Q-1 sub-carrier groups. The indices of subcarriers constituting the subchannel are represented by Equation 2 below.

In Equation 2, i represents a subcarrier group index indicating which subcarrier group among all Q-1 subcarrier groups of the OFDMA communication system, and the subcarrier group index i represents It has one of 0, 1, ..., Q-2. In addition, in Equation 2, S (i) is the (i + 1) th element of the permutation S and indicates the positions of subcarriers of the corresponding subcarrier group.

When a sequence as shown in Equation 2, that is, a sequence representing indexes of subcarriers constituting the subchannel is defined, a subchannel corresponding to the sequence may be defined. For example, assuming that all subcarriers of the OFDMA communication system are 42 of {0, 1, 2, ..., 41}, the 42 subcarriers may be classified into 6 subcarrier groups. . In addition, six subcarriers constituting a specific subchannel may be allocated using a sequence having a length of six. That is, if the sub channel sequence S is given as {3, 2, 6, 4, 5, 1}, the corresponding sub channel is composed of subcarriers {3, 9, 20, 25, 33, 36}.

Further, the division of any base station and subchannels in any base station uses the permutation and offset of the base sequence. Here, the basic sequence is defined as "S ₀ ", and the basic sequence S ₀ is represented by Equation 3 below.

for

). 상기 Galois Field의 크기 Q가 7인 경우(Q = 7) 3이 프리미티브 엘리먼트 α가 되며, 기본 시퀀스(S₀)는, S₀ = {3, 3², 3³, ... , 3⁵, 3⁶} mod 7 = { 3, 2, 6, 4, 5, 1}이 된다. 여기서, 상기 기본 시퀀스 S₀는 상기 OFDMA 통신 시스템을 구성하는 다수의 기지국들중 기준이 되는 기준 기지국의 0번 서브 채널에 할당되는 시퀀스를 나타낸다. 여기서, 상기 기준 기지국은 0번 기지국이라 가정하기로 하며, 상기 0번 기지국이 상기 OFDMA 통신 시스템을 구성하는 기지국들중 제1기지국이 되는 것이다. 또한, 상기 0번 서브 채널이 Q개의 서브 채널들중 제1서브 채널이 되는 것이다. In Equation 3, α represents a primitive element of Galois Field (Q) (

for

). When the size Q of the Galois Field is 7 (Q = 7), 3 becomes the primitive element α, and the basic sequence S ₀ is S ₀ = {3, 3 ² , 3 ³ , ..., 3 ⁵ , 3 ⁶ } mod 7 = {3, 2, 6, 4, 5, 1} Here, the basic sequence S ₀ represents a sequence allocated to subchannel 0 of a reference base station, which is a reference among a plurality of base stations constituting the OFDMA communication system. Herein, it is assumed that the reference base station is base station 0, and the base station 0 becomes a first base station among base stations constituting the OFDMA communication system. Also, the 0 subchannel becomes the first subchannel among the Q subchannels.

In addition, the sequence S _m allocated to an arbitrary cell _m is a sequence obtained by cycling the base sequence S ₀ m times, and is represented by Equation 4 below.

Here, S _m represents a sequence allocated to subchannel 0 of base station m.

In addition, the sequence S _{m , β} for defining each of the sub-channels in the base station _m is a form of adding the offset β to the sequence S _m allocated to the sub-channel 0 of the cell _m , the number m The sequence S _{m , β} for defining each of the subchannels in the base station is expressed by Equation 5 below.

In Equation 5, GF (Q) represents Galois Field (Q).

In this way, subchannel allocation is possible for each of the Q-1 base stations of the entire OFDMA communication system, and thus Q subchannel sequences can be obtained for each of the Q-1 base stations. The subchannel sequences obtained as described above have the possibility of causing only a maximum of one subchannel collision between adjacent cells, that is, adjacent base stations, and thus have an advantage of preventing system performance degradation due to subchannel collision. Then, with reference to Tables 1 and 2 below, the size Q of the Galois Field is 7 (Galois Field (Q) = 7), and the primitive element (α) of the Galois Field (Q) is 3 (α = 3), Sequences for each base station for subchannel 0 when the basic sequence S ₀ = {3, 2, 6,4, 5, 1} and sequences for designating each subchannel in base station 0 will be described. .

Table 1 shows sequences for allocating subchannels 0 of different cells, and Table 2 shows sequences for allocating subchannels in base station 0. As shown in Table 1 above, there is a possibility that only a maximum of one subchannel may cause a collision, so that a degradation in system performance due to a subchannel collision is prevented.

Meanwhile, in a cellular communication system having a frequency reuse of 1, the number of distinguishable base stations in the entire system must be increased to facilitate network design, that is, to facilitate base station installation. In order to increase the number of distinguishable base stations, it is necessary to increase the Q value of the Galois Field (Q). In addition, the present invention proposes a two-dimensional subchannel allocation scheme in consideration of not only a frequency domain but also a time domain in order to increase the number of distinguishable base stations. For example, suppose that 1552 = 97 * 16 subcarriers are transmitted per OFDM symbol, and when 6 OFDM symbols are used as one subcarrier allocation unit, 97 * 16 * 6 = 97 * 96 data subcarriers are used. Can be considered to be used. In this case, if the subchannel sequence is defined on the Galois Field 97, 97 subchannels may be allocated to each of 96 cells. Basic sequence with a primitive element of 5 on the Galois Field (97) S ₀ can be calculated by substituting the above equation 3 Q = 97, α = 5 , the basic sequence S ₀ is expressed as Equation 6 .

Next, a process of allocating subchannels in a time-frequency two-dimensional region will be described with reference to FIG. 2.

2 is a diagram schematically illustrating a process of allocating subchannels in a time-frequency two-dimensional region according to an embodiment of the present invention.

Before describing FIG. 2, as described above, in the OFDMA communication system, 96 base stations can be distinguished and 97 subchannels are allocated to each of the 96 base stations. Let's assume. That is, as shown in FIG. 2, 97 * 96 subcarriers are configured for 96 subcarrier groups for 6 OFDM symbol intervals in the time-frequency domain, and 97 consecutive subbands are provided for each of the 96 subcarrier groups. Place the carriers. In FIG. 2, the vertical axis represents a sub-carrier index in the frequency domain, and the horizontal axis represents an OFDM symbol index in the time domain.

를 생성할 수 있다. 이에 따라 96개의 기지국들 각각에 대해서 97개의 서브 채널들을 할당할 수 있다.In FIG. 2, since the size Q of the Galois Field is 97, using the basic sequence S ₀ of Equation 6 and Equations 4 and 5, each of the subchannels in the base station m is defined. Sequence for

Can be generated. Accordingly, 97 subchannels can be allocated to each of the 96 base stations.

Meanwhile, when using Q * (Q-1) subcarriers in the OFDMA communication system, N subcarrier groups are configured using Q * N subcarriers in one OFDM symbol (Q-1 In case of using) / N OFDM symbols, an index of subcarriers constituting each of the subchannels is represented by Equation 7 below.

는 x보다 작거나 같은 최대 정수를 나타낸다. 상기 도 2에서는 Q = 97, N = 16이므로 상기 서브 캐리어 그룹 인덱스 i는 0 내지 Q-2, 즉 0 내지 95까지의 값들중 어느 한 값을 가지며, 상기 심벌 인덱스 n은 0에서 5의 값들중 어느 한값을 가지게 된다. 또한, 0번 기지국의 0번 서브 채널의 부반송파 인덱스는 다음과 같다.In Equation 7,

Denotes the largest integer less than or equal to x. In FIG. 2, since Q = 97 and N = 16, the subcarrier group index i has any one of values from 0 to Q-2, that is, 0 to 95, and the symbol index n has a value from 0 to 5 It will have a value. In addition, the subcarrier index of subchannel 0 of base station 0 is as follows.

<Subchannel subcarrier index 0 of base station 0>

Symbols 0: 5, 122, 222, 334, 409, 493, 622, 685, 806, 926, 1041, 1131, 1193, 1309, 1404, 1491

Symbol 1: 83, 124, 232, 384, 465, 579, 664, 701, 789, 938, 1004, 1140, 1238, 1340, 1365, 1490

Symbol 2: 78, 99, 204, 341, 444, 571, 624, 695, 856, 885, 1030, 1076, 1209, 1292, 1416, 1551

Symbol 3: 92, 169, 263, 345, 464, 574, 639, 770, 843, 917, 996, 1100, 1232, 1310, 1409, 1516

Symbol 4: 14, 167, 253, 295, 408, 488, 597, 754, 860, 905, 1033, 1091, 1187, 1279, 1448, 1517

Symbol 5: 19, 192, 281, 338, 429, 496, 637, 760, 793, 958, 1007, 1155, 1216, 1327, 1397, 1456

When the subcarriers are allocated in this way, as described above, there is a probability that a collision occurs only in one subchannel between subchannels belonging to different cells, and this collision occurrence probability is much higher than that of existing communication systems. It is a low probability. For example, the Institute of Electrical and Electronics Engineers (IEEE) 802.16a communication system described in the prior art portion may allocate 32 subchannels to each cell, and subchannels of the different cells may be 0 to 5 subcarriers. A collision occurs at the location. Meanwhile, when subcarriers are allocated as in the present invention, the number of collisions between subcarriers constituting the subchannels is reduced to 0 or 1.

For example, when using the Reed Solomon sequence, since there are Q-1 subcarriers for each subchannel, and the number of collisions of subcarriers constituting subchannels of different cells is 1, the ratio of collision subcarriers is The maximum is 1 / (Q-1), and this value decreases as the Q value is increased. Therefore, the time-frequency two-dimensional subcarrier allocation scheme proposed in the present invention has an advantage of minimizing the ratio of collision subcarriers as well as increasing the number of distinguishable cells.

(2) Subchannel Allocation Method for Data Transmission

A first transmitter, that is, a base station, of the OFDMA communication system transmits data by allocating a part or one or more subchannels of one subchannel according to a decoding delay time and an amount of data to be transmitted. For example, a total of Q data allocation units may be configured by inserting data to be transmitted in sub channel units to transmit the data. Here, the data allocation refers to a resource allocation unit using the same channel coding scheme and modulation scheme. It is assumed that a 1/2 turbo coding scheme is used as the channel coding scheme, and a QPSK scheme is used as the modulation scheme. In addition, coding gain is generally increased as the length of the codeword increases, and when the size of the information bits included in the codeword is 1000 bits or more, performance saturation occurs, so that 96 subcarriers per subchannel In the case of using the QPSK method and the 1/2 channel code as the modulation method, channel coding is performed by combining about 10 subchannels to maximize the coding gain.

Next, a process of allocating subchannels for data transmission will be described with reference to FIG. 3.

3 is a diagram illustrating a subchannel allocation process for data transmission according to an embodiment of the present invention.

Before describing FIG. 3, first, as described with reference to FIG. 2, 96 base stations can be distinguished and 97 subchannels can be allocated to each of the 96 base stations. Assume the case. 3 illustrates an example in which subchannels when Q = 97, that is, when the number of distinguishable subchannels in one cell is 97, are allocated according to the purpose of use.

Referring to FIG. 3, a unit rectangle is composed of 16 subcarriers, and when the unit rectangles are grouped into 6 OFDM symbol intervals on a time axis, one subchannel is generated, and is denoted as “Td”. Here, a unit rectangle representing 16 subcarriers, which are some subcarriers constituting the subchannel, will be referred to as a "sub-channel unit". The one subchannel is composed of six subchannel units.

On the other hand, when the amount of data to be transmitted is large, two or more subchannels are bundled and used to transmit the data. In FIG. 3, subchannels used for the data transmission are denoted by "Tb". That is, four subchannels of subchannel 93 (SC 93) to subchannel 96 (SC 96) are used to transmit the data. Here, the maximum number of collisions between subcarriers constituting the subchannel unit is equal to the number of subchannel indexes used in the frequency domain. In addition, the subchannel denoted by Td and some subchannel denoted by Ts (three subchannel units) each have a maximum number of subcarrier collisions between adjacent cells, and subchannel units and Tb of different subchannels denoted by Tc. The subchannels denoted by have the maximum collision counts 3 and 4, respectively.

The maximum number of collisions of subcarriers belonging to the subchannels denoted by Td, the subchannel units of different subchannels denoted by Tc, the subchannel units denoted by Ts, the subchannels denoted by Tb, and the denoted Td The subchannels, the subchannel units of different subchannels denoted Tc, the subchannel units denoted Ts, and the number of OFDM symbols belonging to the subchannels denoted Tb are described in terms of decoding delay. The subchannels denoted by Td and the subchannel units of different subchannels denoted by Tc use the same area, that is, the same number of subcarriers, and the subchannel denoted by Td collides with the subchannel denoted by Td of an adjacent cell. This occurs up to once, and the decoding delay is 6 OFDM symbols. In contrast, subchannel units of different subchannels denoted Tc collide with subchannel units of different subchannels denoted Tc of an adjacent cell at most three times and the decoding delay is 2 OFDM symbols.

That is, there is some trade-off relationship between the maximum collision count and decoding delay of the subcarriers constituting the subchannel unit in the two-dimensional region of the subchannel index SC and the time index t, and is less than 6 OFDM symbol intervals. If data is transmitted during the interval, the coding rate must be increased. Subchannel units of different subchannels denoted Tc, that is, subchannel 3 and subchannel 4 and subchannel 5 are used for 2 OFDM symbols, and subchannel units denoted Ts, that is, subchannel 92 The use for 3 OFDM symbols is effective for transmitting data that must be relatively short in length and low in decoding delay. In this case, the data that should be relatively short and the decoding delay is small may include, for example, paging channel data. As described above, how to use a subchannel in the two-dimensional region of the subchannel index SC and the time index t, that is, which subchannel to allocate when transmitting data, control channel and data in the OFDMA communication system It may be different depending on how the data channel is configured.

(3) Subchannel Allocation Scenarios in Cellular Environments

4 is a flowchart illustrating a subcarrier allocation process according to an embodiment of the present invention.

Referring to FIG. 4, first, the base station determines parameters Q, i.e., the size of the Galois Field, necessary for allocating subcarriers in step 411, and a variable N indicating the number of subcarrier groups in an OFDM symbol. And the variable α representing the primitive element of the Galois Field (Q). In addition, the base station determines the initialized variables in step 411, that is, a variable Q indicating the size of the Galois Field, a variable N indicating the number of subcarrier groups in one OFDM symbol, and a primitive element of the Galois Field (Q). After the basic sequence S ₀ is generated using the variable α, the process proceeds to step 413. Here, since the process of generating the basic sequence S ₀ is the same as that described in Equation 3, a detailed description thereof will be omitted.

In step 413, the base station generates a sequence {S _{m , β} } for defining each of the subchannels in the base station to which the subcarriers are allocated, for example, base station _{m ,} and proceeds to step 415. Herein, the process of generating the sequence {Sm, β} for defining each of the subchannels in the base station m is first performed as described in Equation 4 and Equation 5 above. generating a sequence s _m having a sequence s ₀ m time cycle, the second in the basic sequence s ₀ to m times, each of the sub-channel of the m time base domestic as circular adding the offset β in which the sequence s _m the form Create a sequence {S _{m , β} } to define. Here, the process of generating the sequence {S _{m , β} } for defining each of the sub-channels in the base station _m is the same as described in the equations (4) and (5) will not be described in detail here . In addition, the base station may perform the same operation as step 415 each time a situation occurs, or may be stored in a table form in advance and used in the form of reading from the table whenever a situation occurs. .

In step 415, the base station allocates the allocated subchannels to be used for the data transmission in consideration of data to be transmitted and ends. Here, the base station allocates subchannels to be used for the data transmission using a usage rule as described in Equation 7, and a detailed description thereof will be omitted.

(4) pilot channel configuration in a cellular environment

In general, a cellular communication system uses pilot subcarriers for channel estimation and cell classification. The present invention proposes a method of using some of the subchannels as pilot channels. In order to maintain collision characteristics between subchannels in the OFDMA communication system, the positions of subcarriers constituting each of the subchannels must not be changed even after inserting pilot subcarriers into the subchannels.

Therefore, the present invention proposes a method of using some of the sub-channels defined in the time-frequency two-dimensional region as a pilot channel. When some of the subchannels are used as pilot channels, the collision of subcarriers occurs at most once between the subchannels allocated as the pilot channel, which is very efficient for a cellular system having a frequency reuse ratio of 1. In addition, the terminal may identify the cell by looking at the pattern of the pilot subcarriers during an initial cell search or handoff, and also have a relative signal of a neighbor cell with the pilot subcarriers. The size can be determined. That is, since the location of the pilot subcarriers is different for each cell, the terminal may perform cell search based on the location of the pilot subcarriers boosted from the data subcarriers. Here, the pilot subcarrier is boosted by about 3 to 6 [dB] than the data subcarrier so that the terminal can easily distinguish the pilot subcarrier. That is, the pilot signal is a reference signal for sorting base stations and channel estimation.

(5) Subchannel Allocation Method for Acquiring Diversity Gain

In the OFDMA communication system, the same codeword as the codeword previously transmitted is retransmitted at the next time point, that is, the same codeword as the previously transmitted codeword is temporally separated and retransmitted as an independent signal, or the same codeword is identical. There may be a case of repeatedly transmitting at a time point. For example, in the OFDMA communication system, a preamble sequence is used to acquire synchronization between a base station and a terminal. Since the preamble sequence has a form in which codewords having the same length are repeated, the same codeword is repeatedly transmitted as described above. In addition, when the same codeword needs to be retransmitted, an error occurs in a codeword that was previously transmitted and the same codeword must be retransmitted.

As described above, the present invention proposes a subchannel allocation scheme for obtaining diversity gain in the time domain and the frequency domain in the case of retransmitting the same codeword or repeatedly transmitting the same codeword. That is, the present invention configures a subchannel such that each of the bits constituting each of the same codewords repeated to obtain the diversity gain is transmitted through subcarriers belonging to different subcarrier groups. In addition, the present invention provides a subchannel such that each of the bits constituting the codeword to be retransmitted to obtain the diversity gain belongs to a subcarrier group different from the subcarriers that were transmitted immediately before. Configure.

Unlike the subchannel configuration method described with reference to FIG. 2 to obtain the diversity gain as described above, the present invention provides a subcarrier group to which each of the subcarriers constituting the subchannel belongs each time a subchannel is configured. Control them to be set randomly.

That is, in the subchannel allocation scheme described with reference to FIG. 2, the subchannel β is allocated in a reference time period preset for an arbitrary base station at an arbitrary time point, that is, in 6 OFDM symbol intervals as shown in FIG. 2. Subcarrier group indexes to which each of the 96 subcarriers constituting the subchannel β belong, and 96 subcarriers constituting the subchannel β when allocating the subchannel β at a point immediately after the arbitrary time point. The subcarrier group indexes to which each of them belong are the same.

However, in order to obtain the diversity gain, in the present invention, when allocating subchannel β at an arbitrary time point, subcarrier group indexes to which each of 96 subcarriers constituting the subchannel β belong, and the arbitrary time point When the subchannel β is allocated at the next time point, the subcarrier group indexes are randomly interleaved so that the subcarrier group indexes to which each of the 96 subcarriers constituting the subchannel β belong are different.

For example, when allocating the subchannel β at an arbitrary time point, the subcarrier group indices to which each of the 96 subcarriers constituting the subchannel β belong are 0, 1, 2, 3, ..., 93, 94, Assuming 95, when the subchannel β is allocated at a point immediately after the arbitrary time point, the subcarrier group indices to which each of the 96 subcarriers constituting the subchannel β belong are 1, 2, 3, 4,... Control to be, 94, 95, 0. As another example, when allocating the subchannel β at an arbitrary time point, the subcarrier group indices to which each of the 96 subcarriers constituting the subchannel β belong are 0, 1, 2, 3, ..., 93, 94 , Assuming that 95, the subcarrier group indexes belonging to each of the 96 subcarriers constituting the subchannel β are 3, 11, 1, 7,. .., 90, 78, 36.

In the first example, when a subchannel is allocated, a diversity gain is obtained by cyclically shifting subcarrier group indices to which subcarriers constituting a subchannel belong. On the contrary, in the second example, the diversity gain is obtained by randomly generating subcarrier group indices to which each of the subcarriers constituting the subchannel belongs.

As described above, the present invention controls the subcarrier group indexes to which each of the subcarriers constituting the subchannel are set differently from the previous subchannel allocation in order to obtain diversity gain. In the above description, a case in which subcarrier group indices per se belonging to each of the subcarriers constituting the subchannel are set differently for each subchannel configuration has been described as an example. The diversity gain may be obtained by allocating and interleaving a subcarrier group index to which each subcarrier constituting the allocated subchannel belongs through an interleaver (not shown). That is, an interleaver is connected between the subchannel allocator 117 and the serial / parallel converter 119 of FIG. 1 and each of the subcarriers constituting the subchannel allocated by the subchannel allocator 117 belongs. Interleaving of subcarrier group indices in the interleaver.

In summary, when retransmitting or repeatedly transmitting the same codeword, the same codeword bit should be transmitted through subcarriers belonging to different subcarrier groups in order to obtain diversity gain in the time domain and the frequency domain. Generally, in this case, diversity is obtained by interleaving the codewords at the bit level. In contrast, the present invention proposes a method in which the sub-channel allocator 117 changes the group index shown in FIG. 2 for each sub-channel. This operation may be described as group index interleaving, and any interleaver used for channel encoding may be used as the interleaver.

로 변하게 되며, 이는 하기 수학식 8과 같이 표현할 수 있다.For example, if a co-prime interleaver is used as the interleaver, the subcarrier group index of the k-th subcarrier constituting the subchannel β is determined according to the interleaving operation.

It will be changed to, which can be expressed as Equation 8 below.

In Equation 8, a and b may be selected from (Q-1) and an integer that is a prime integer, that is, an integer having a greatest common divisor of 1. In addition, the same effect can be obtained even if the role of the sub-channel β and the k in Equation 8 is changed.

As described above, an operation of interleaving the group index through the interleaver will be described with reference to FIG. 5.

FIG. 5 is a diagram schematically illustrating a structure of a second transmitter of an OFDMA communication system for performing a function in an embodiment of the present invention.

Referring to FIG. 5, a second transmitter of the OFDMA communication system first includes a CRC inserter 511, an encoder 513, a symbol mapper 515, a subchannel allocator 517, and an interleaver 519. ), Serial / parallel converter 521, pilot symbol inserter 523, IFFT unit 525, parallel / serial converter 527, guard interval inserter 529, digital / analog converter 531 and an RF processor 533. The CRC inserter 511, encoder 513, symbol mapper 515, serial / parallel converter 521, pilot symbol inserter 523, IFFT 525, and parallel / The serial converter 527, the guard interval inserter 529, the digital-to-analog converter 531, and the RF processor 533 are composed of the CRC inserter 111 and the encoder 113 described with reference to FIG. 1. And a symbol mapper 115, a serial / parallel converter 119, a pilot symbol inserter 121, an IFFT device 123, a parallel / serial converter 125, and a guard interval inserter 127 ), The digital-to-analog converter 129, and the RF processor 131 are the same as the detailed description thereof.

However, in FIG. 5, whenever the subchannel allocator allocates a subchannel to obtain diversity gain, the subchannel allocator 517 may select a subcarrier group to which each of the subcarriers constituting the subchannel belongs. It may be set differently, and since this has been described above, a detailed description thereof will be omitted. In addition, the subchannel allocator 517 allocates a subchannel in the same manner as the subchannel allocator 117 described with reference to FIG. 1 and the subchannel allocated by the subchannel allocator 517 in the interleaver 519. An index of a subcarrier group to which each of the subcarriers constituting a subcarrier belongs may be interleaved. Since this is also described above, a detailed description thereof will be omitted.

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

1 schematically illustrates a structure of a first transmitter of an OFDMA communication system for performing a function in an embodiment of the present invention.

2 is a diagram schematically illustrating a process of allocating subchannels in a time-frequency two-dimensional region according to an embodiment of the present invention.

3 is a diagram schematically illustrating a subchannel allocation process for data transmission according to an embodiment of the present invention.

4 is a flowchart illustrating a subcarrier allocation process according to an embodiment of the present invention.

5 is a diagram schematically illustrating a structure of a second transmitter of an OFDMA communication system for performing a function in an embodiment of the present invention.

Claims (16)

delete A method for allocating subchannels in a signal transmission apparatus of a communication system, The entire frequency band is divided into m subchannel groups, each of the m subchannel groups having a subchannel group index, and one subchannel corresponding to the m subchannel groups according to a subchannel group index sequence. In case of including n selected subcarriers in each, If it is necessary to transmit a signal identical to the signal transmitted from the first time point to the second time point, assigning a first sub channel using the first sub channel group index sequence at the first time point, The first sub channel group index sequence is different from the second sub channel group index sequence used when allocating a second sub channel at the second time point. The first sub channel group index sequence is generated by interleaving the second sub channel group index sequence. A method for allocating subchannels in a signal transmission apparatus of a communication system, The entire frequency band is divided into m subchannel groups, each of the m subchannel groups having a subchannel group index, and one subchannel corresponding to the m subchannel groups according to a subchannel group index sequence. In case of including n selected subcarriers in each, If it is necessary to transmit a signal identical to the signal transmitted from the first time point to the second time point, assigning a first sub channel using the first sub channel group index sequence at the first time point, The first sub channel group index sequence is different from the second sub channel group index sequence used when the second sub channel is allocated at the second time point. The first sub channel group index sequence is generated by interleaving the second sub channel group index sequence according to the following equation. Equation

Β represents the subchannel index of the first subchannel,

Denotes a subchannel group index including the k-th subcarrier included in the first subchannel, a and b denote integers having a greatest common divisor, and Q denotes the size of the galoa field. A method for allocating subchannels in a signal transmission apparatus of a communication system, The entire frequency band is divided into m subchannel groups, each of the m subchannel groups having a subchannel group index, and one subchannel corresponding to the m subchannel groups according to a subchannel group index sequence. In case of including n selected subcarriers in each, If it is necessary to transmit a signal identical to the signal transmitted from the first time point to the second time point, assigning a first sub channel using the first sub channel group index sequence at the first time point, The first sub channel group index sequence is different from the second sub channel group index sequence used when the second sub channel is allocated at the second time point. And wherein the first sub channel group index sequence is generated by cyclically shifting the second sub channel group index sequence. delete delete delete delete delete An apparatus for allocating subchannels in a signal transmission apparatus of a communication system, The entire frequency band is divided into m subchannel groups, each of the m subchannel groups having a subchannel group index, and one subchannel corresponding to the m subchannel groups according to a subchannel group index sequence. In case of including n selected subcarriers in each, When the signal transmission apparatus needs to transmit the same signal as the signal transmitted from the first time point to the second time point, the sub-channel allocation for allocating the first sub channel using the first sub channel group index sequence at the first time point Including a flag, The first sub channel group index sequence is different from the second sub channel group index sequence used when the second sub channel is allocated at the second time point. And the first sub channel group index sequence is generated by interleaving the second sub channel group index sequence. An apparatus for allocating subchannels in a signal transmission apparatus of a communication system, The entire frequency band is divided into m subchannel groups, each of the m subchannel groups having a subchannel group index, and one subchannel corresponding to the m subchannel groups according to a subchannel group index sequence. In case of including n selected subcarriers in each, When the signal transmission apparatus needs to transmit the same signal as the signal transmitted from the first time point to the second time point, the sub-channel allocation for allocating the first sub channel using the first sub channel group index sequence at the first time point Including a flag, The first sub channel group index sequence is different from the second sub channel group index sequence used when the second sub channel is allocated at the second time point. And the first sub channel group index sequence is generated by interleaving the second sub channel group index sequence according to the following equation. Equation

Β represents the subchannel index of the first subchannel, Denotes a subchannel group index including the k-th subcarrier included in the first subchannel, a and b denote integers having a greatest common divisor, and Q denotes the size of the galoa field. An apparatus for allocating subchannels in a signal transmission apparatus of a communication system, The entire frequency band is divided into m subchannel groups, each of the m subchannel groups having a subchannel group index, and one subchannel corresponding to the m subchannel groups according to a subchannel group index sequence. In case of including n selected subcarriers in each, When the signal transmission apparatus needs to transmit the same signal as the signal transmitted from the first time point to the second time point, the sub-channel allocation for allocating the first sub channel using the first sub channel group index sequence at the first time point Including a flag, The first sub channel group index sequence is different from the second sub channel group index sequence used when the second sub channel is allocated at the second time point. And the first sub channel group index sequence is generated by cyclically shifting the second sub channel group index sequence. delete delete delete delete

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