KR101286659B1 - Apparatus and method for complexity reduction of hybrid duplex scheme through selective antenna allocation in multiple antenna systems - Google Patents

Abstract

The present invention relates to an apparatus and a method for reducing complexity of a hybrid duplex through selective antenna allocation in a multi-antenna system, and more particularly, to a radio frequency (RF) chain for each antenna operating in a TDD (Time Division Duplex) band mode, An antenna selector for determining a set of reception antennas to be allocated to the TDD band and a reception RF chain for each antenna operating in a TDD band mode or an FDD (Frequency Division Duplex) band mode; (Hybrid Duplex) scheme can be implemented without increasing the number of RF chains by including a frequency generation and controller that generates TDD band frequencies with a reception RF chain and generates FDD band frequencies with reception RF chains of other reception antenna sets And the complexity of the base station and the terminal can be reduced.

Duplex, hybrid duplex, MIMO, selective antenna allocation

Description

[0001] APPARATUS AND METHOD FOR COMPLEXITY REDUCTION OF HYBRID DUPLEX SCHEME THROUGH SELECTIVE ANTENNA ALLOCATION IN MULTIPLE ANTENNA SYSTEMS [0002] BACKGROUND OF THE INVENTION [0003]

1 is a diagram showing a frame structure of an FDD, a TDD and an HD scheme according to the related art,

FIGS. 2ab and 2cd illustrate the structure of a conventional base station RF transceiver according to the conventional FDD, TDD, and HD schemes,

FIG. 3 is a block diagram illustrating a base station RF transceiver structure of a multi-antenna system according to the present invention.

4 is a block diagram illustrating a UE RF transceiver structure of a multi-antenna system according to the present invention, and FIG.

5 illustrates a procedure of an adaptive antenna allocation method in a base station of a multi-antenna system according to an embodiment of the present invention.

The present invention relates to a multi-antenna system, and more particularly, to an apparatus and method for hybrid-duplex complexity reduction through selective antenna allocation.

2. Description of the Related Art A two-way communication in a wireless communication system requires a duplex method capable of distinguishing between a downlink (DL) and an uplink (UL) transmission. 1, in the duplex method, frequency bands (f ₁ , f ₂ ) allocated to the DL 101 and the UL 103 are assigned to a frequency (frequency) that distinguishes the DL 101 from the UL 103 The DL 105 and the UL 107 share the same frequency band f ₁ and allocate different transmission intervals to the DL 105 And a time division duplex (TDD) scheme 1b for separating the UL 107 and the UL 107 from each other.

Here, in the case of the FDD scheme, a guard band must be provided between the DL band and the UL band in order to prevent interference between the DL and the UL. Also, since the ratio of the DL to the UL is fixed by the bandwidth, it is not suitable for accommodating asymmetric traffic between the DL and the UL. For this reason, the second-generation IS-95 and GSM system and most third-generation systems that provide voice-based services use the FDD scheme, but the FDD scheme is suitable for wireless communication systems that provide asymmetric data- The TDD scheme is adopted.

The biggest advantage of the TDD scheme is that the ratio of the DL and the UL can be flexibly adjusted, thereby effectively coping with asymmetric traffic. In addition, since the bi-directional link (DL, UL) uses the same band, the feedback overhead on the channel information can be reduced by using the reciprocity of the channel. Therefore, it is possible to effectively apply a technique for improving frequency use efficiency such as adaptive modulation and multi-antenna technology.

However, since DL and UL traffic rates are generally different for each cell, in order to perform efficient TDD operation, the switching point between DL and UL must be changed according to the traffic situation. In this case, a cross slot interval occurs in which a specific cell transmits a DL signal and another cell transmits a UL signal. In the cross slot period, interference between the base station and the base station belonging to different cells, which do not occur in the FDD scheme or the TDD scheme having the same switching time in all the cells, and interference between terminals and terminals belonging to different cells occur. This is referred to as cross slot interference, which can be a major cause of deterioration of the performance of a user, especially at the cell boundary.

To achieve the advantages of the TDD scheme while mitigating the cross slot interference problem of the TDD scheme, a Hybrid Duplex (HD) scheme 1c combining the TDD and the FDD has been proposed. In the HD scheme, the TDD band of the center frequency f ₁ using the TDD scheme and the FDD band of the center frequency f ₂ allocated for the UL are separated, and the DL transmission is divided into the DL region of the TDD band 109, and the UL transmission can selectively use the UL section 111 of the TDD band and the UL section 113 of the FDD band. As described above, the HD scheme has an advantage of reducing the influence of cross slot interference by using the UL of the FDD band to users located at the cell boundary while taking advantage of the TDD. Also, it is expected that the performance of the DL transmission can be improved by allocating the UL of the TDD band and the UL of the FDD band simultaneously to the users located inside the cell and enabling the high-speed feedback on the DL through the FDD UL.

However, since the HD scheme uses two different bands as UL, the UE requires an RF transmission chain for the two bands, and the base station requires an RF reception chain for the two bands. Here, FIGS. 2ab and 2cd illustrate the structure of a general base station RF transceiver of the FDD 2a, TDD 2b, and HD 2c systems when there is one transmitting / receiving antenna. The transmitter RF chain of the FDD 2a / TDD 2b / HD 2c system includes a digital-to-analog converter (DAC) 201/221/241, an I / Q modulator 202/222/242, an IF amplifier 203/223/243, a first IF mixer 204/224/244, a first IF filter 205/225/245, And a receiver RF chain includes RF low noise amplifiers 208 and 228 and 248. Each of the RF RF amplifiers 208 and 228 and 248 includes a mixer 206 / A second RF filter 211/231/251, a second RF mixer 212/232/252, a second IF filter 213/233/253, A second IF mixer 214/234/254, an IF LNA 215/235/255, an I / Q demodulator 216/336/256, an analog-to-digital converter (ADC) (217/237/257). Here, the FDD scheme 2a shares a transmitting / receiving antenna using a duplexer 209, and the transmitting / receiving antenna is shared using a switch 229 in the case of the TDD scheme 2b.

In the case of the FDD scheme 2a and the TDD scheme 2b, one RF chain is required for each of the transmitter and the receiver. However, in the HD scheme 2c, the receiver requires two RF chains. In other words, the HD system 2c includes a second RF LNA 259, a third RF filter 260, a third RF mixer 261, a third IF filter 262, a third IF mixer 263, A second IF LNA 264, a second I / Q demodulator 265, and a second ADC 266. The HD system 2c uses a duplexer 258 to share a transmitting / receiving antenna to distinguish UL / DL transmission in the TDD band from UL transmission in the FDD band, and a switch 249 To distinguish between UL transmission and DL transmission in the TDD band. In this case, the terminal also needs two transmit RF chains.

In order to solve the problem that the HD system 2c requires twice the reception RF chain, the reception RF chain for the TDD band and the FDD band is not separately implemented as in (2d) of FIG. 2, With possible RF (Reconfigurable RF), both bands can share the same RF chain. In other words, the transmitter RF chain includes a DAC 271, an I / Q modulator 272, an IF amplifier 273, a first IF mixer 274, a first IF filter 275, a first RF mixer 272, 276, a first RF filter 277 and an RF power amplifier 278. The receiver RF chain comprises RF LNA 280, a frequency generator and controller 281, a reconfigurable RF LNA / filter / mixer A second IF filter 283, a second IF mixer 284, an IF LNA 285, an I / Q demodulator 286 and an ADC 287. The hybrid duplexer / To share the transmitting / receiving antenna. In this case, the terminal may also share transmission RF chains for the two bands through the reconfigurable RF.

However, also in this case, when a signal is simultaneously transmitted through the TDD band and the FDD band in the UL transmission interval as in (1c) of FIG. 1, it is inevitable to use twice the RF chain. In other words, in order to transmit NxM multi-antenna signals simultaneously through the TDD band and the FDD band from the terminal to the base station in the NxM multi-transmission / reception antenna system in which the number of antennas is M and the number of antennas is N, The base station requires 2N receiving RF chains, which increases the complexity of the terminal and the base station.

It is therefore an object of the present invention to provide a hybrid duplex complexity reduction apparatus and method through selective antenna allocation in a multi-antenna system.

It is another object of the present invention to provide a reconfigurable RF chain of a terminal limited to a number of terminal antennas and a reconfigurable RF chain of a base station limited by the number of base station antennas when a UL signal is simultaneously transmitted through a TDD band and an FDD band in a multi- The present invention also provides an apparatus and a method for allocating the TDD band and the FDD band in a divided manner to implement the HD system without increasing the number of RF chains.

Another object of the present invention is to provide a multi-antenna system in which, when a UL signal is to be simultaneously transmitted through a TDD band and an FDD band, a terminal has M RF chains, some of M antennas are allocated to a TDD band, And a base station includes N RF chains, thereby allocating a part of N antennas to a TDD band and allocating the rest to an FDD band.

According to an aspect of the present invention, there is provided an apparatus for reducing a complexity of a hybrid duplex in a base station of a multi-antenna system, including: a transmission RF (Radio Frequency) chain for each antenna operating in a TDD (Time Division Duplex) A receiving RF chain for each antenna operating in a TDD band mode or a frequency division duplex (FDD) band mode according to a frequency at which a transmission RF chain for each antenna and an antenna selector for determining a receiving antenna set to be allocated to a TDD band, And a frequency generation and controller which generates a TDD band frequency as a reception RF chain of the reception antenna set and generates an FDD band frequency as a reception RF chain of the other reception antenna set.

According to an aspect of the present invention, there is provided an apparatus for reducing a complexity of a hybrid duplex in a terminal of a multi-antenna system, the apparatus comprising: a reception RF (Radio Frequency) chain for each antenna operating in a TDD (Time Division Duplex) An antenna selector for determining a transmission antenna set to be allocated to a TDD band and a transmission RF chain for each antenna operating in a TDD band mode or an FDD (Frequency Division Duplex) band mode according to a frequency, And a frequency generation and controller for generating a TDD band frequency in a transmission RF chain of the transmission antenna set and generating an FDD band frequency in a transmission RF chain of the other transmission antenna set.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an apparatus and method for reducing complexity of a hybrid duplex through selective antenna allocation in a multi-antenna system will be described.

3 is a block diagram illustrating a structure of a base station RF transceiver of a multi-antenna system according to the present invention. The base station includes a transmitter RF chain and a receiver RF chain, a frequency generator and controller 316, and an antenna selector 317, each of which is connected to the N antennas, assuming that the base station includes N antennas. Here, the first to N transmitter RF chains for the TDD band of the center frequency f ₁ are first to N DAC (Digital to Analog Converter) 301-1 to N, first to NI / Q N-1 IF mixers 304-1 to 304-N, first to Nth IF (Intermediate Frequency) amplifiers 303-1 to N, First to N-1 IF filters 305-1 to N, first to Nth RF (Radio Frequency) mixers 306-1 to N, first to Nth RF filters 307-1 to 307, 1 to N RF power amplifiers 308-1 to N, and the first to N receiver RF chains for the TDD band or the frequency division duplex (FDD) band of the center frequency f ₂ are constituted by first to N re- The first to N-2 IF filters 311-1 to 311-N, the first to N-2 IF mixers 312-1 to 312-N, the LNA (Low Noise Amplifier) / filter / mixer 310-1 to N, The first to Nth IF LNAs 313-1 to N, the first to NI / Q demodulators 314-1 to 314-N, and the first to Nth ADCs 315-1 to 315- And the transmission / reception antennas are shared using the first to N hybrid duplexers / switches 309-1 to 309-N. The.

3, the first to N-th transmitter RF (Radio Frequency) chains operate in the TDD band mode, and the first to N-th receiver RF chains are connected to the frequency generating and controlling unit 316 In the TDD band mode or the FDD band mode.

The first to N DACs 301-1 to 301-N of the first to N-th transmitter RF chains are connected to an I / Q modulator 302-1 To N). The first to NI / Q modulators 302-1 to 302-N convert input I-axis and Q-axis signals into high frequencies having a predetermined phase difference between the I-axis and Q-axis signals, To the IF amplifiers 303-1 to 303-N. The first to N-th IF amplifiers 303-1 to 303-N amplify the modulated signals by IF amplification and output them to IF mixers 304-1 to N, The mixers 304-1 to 304-N convert the IF-amplified signal to an IF band and up-convert the frequency to output IF filters 305-1 to 305-N. The first to N-1 IF filters 305-1 to 305-N output the frequency-converted signals to RF mixers 306-1 to 306-N, The first to Nth RF filters 307-1 to 30-N output the filtered IF signals to the RF filters 307-1 to 307, Converts only the desired channel from the frequency-converted signal, and outputs the RF-filtered signals to RF power amplifiers 308-1 to 308 connected thereto. The first to N-th RF power amplifiers 308-1 to 308 amplify the signal converted to the RF frequency to a high level so that the signal can be transmitted with sufficient power, and transmit the amplified signal to the receiving end through an antenna send.

The first to N reconstructing RF LNAs / filters / mixers 310-1 to 310-N of the first to N-th receiver RF chains are connected to a TDD band mode or an FDD Band mode, amplifies a signal received through a connected antenna to a predetermined level, filters only a desired signal from the amplified signal, and downconverts the filtered RF signal into an IF band, And outputs it to the filters 311-1 to 311-N. The first to N-2 IF filters 311-1 to 311-N filter the desired channel from the frequency-converted signals and output the filtered signals to IF mixers 312-1 to 312-N, The IF mixers 312-1 to 312-N convert the frequency-down-converted frequency of the filtered signal to IF LNAs 313-1 to 313-N, and the first to Nth IF LNAs 313-1 to 313- N amplifies the frequency-converted signal to a predetermined level and outputs it to the connected I / Q demodulators 314-1 to 314-N. The first to NI / Q demodulators 314-1 to 314-N convert the amplified signals into I-axis and Q-axis signals before modulation and output them to connected ADCs 315-1 to 315-N, To N ADCs 315-1 to 315-N convert the demodulated analog signal into a digital signal and output the digital signal to the baseband signal processor 300.

The first to Nth hybrid duplexers / switches 309-1 to 309 operate as a switch when connected to an antenna operating in a TDD band mode according to a control signal input from the frequency generation and controller 316, It operates as a duplexer.

The frequency generation and controller 316 uses the reception antenna index set for the TDD band input from the antenna selector 317 to divide the frequency of the RF chain connected to each antenna into the TDD band f ₁ and the FDD band f ₂ ) to the determined value. That is, in the case of the antenna belonging to the reception antenna set for the TDD band, the frequency of the RF chain connected to the antenna is switched to the TDD band f ₁ and the frequency of the RF chain for the other antennas is the FDD band f ₂ , . Also, a control signal is generated to operate as a switch for a hybrid duplexer / switch connected to an antenna operating in a TDD band mode, and a control signal is generated for a hybrid duplexer / switch connected to an antenna operating in an FDD band mode to operate as a duplexer do.

The antenna selector 317 estimates a channel for the TDD band and the FDD band using the uplink channel information for the TDD band and the FDD band of the UE input from the baseband signal processor 300, And determines a set of transmitting and receiving antennas to be allocated to the TDD band using the estimated channel information. Here, the transmission / reception antenna set can be determined using an antenna allocation algorithm that maximizes the overall transmission rate. Then, the determined transmit antenna set is transmitted to the corresponding terminal through the downlink control channel, and the determined set of receive antennas is output to the frequency generator and controller 316. For example, the antenna selection method can be fixedly assigned to the TDD band for the odd-numbered antenna and to the FDD band for the even-numbered antenna.

4 is a block diagram illustrating a structure of a terminal RF transceiver in a multi-antenna system according to the present invention. The terminal includes a transmitter RF chain and a receiver RF chain, a frequency generator and controller 416, and an antenna selector 417 connected to the M antennas, respectively, assuming that the terminal has M antennas. do. Here, the first to M receiver RF chains for the TDD band of the center frequency f ₁ include first to M ADCs 401-1 to M, first to MI / Q demodulators 402-1 to 402-M, M IF LNAs 403-1 to M, first to M-1 IF mixers 404-1 to M, first to M-1 IF filters 405-1 to M, first to M- RF mixer (406-1 ~ M), 1 ~ M the RF filter (407-1 ~ M), the 1 ~ M is configured to include the RF LNA (408-1 ~ M), TDD band or the center frequency f ₂ The first to M-th transmitter RF chains for the FDD band of the first to Mth reconfigured RF mixers / filters / amplifiers 410-1 to 410-M, the first to M-2 IF filters 411-1 to M, 1 to M-2 IF mixers 412-1 to M, first to M-th IF amplifiers 413-1 to M, first to MI / Q modulators 414-1 to 414M, And 415-1 to 415-M, and share transmission / reception antennas using the first to M hybrid duplexers / switches 409-1 to 409-M.

The first to M-1 IF filters 405-1 to 40-M, the first to M-1 IF mixers 404-1 to M, the first to M IF LNAs 403-1 to 403- The first to M-th IF demodulators 402-1 to 402-M and the first to Mth ADCs 401-1 to 401-M are the first to N-2th IF filters 311-1 to 311- The first to N-2 IF mixers 312-1 to 312-N, the first to Nth IF LNAs 313-1 to N, the first to NI / Q demodulators 314-1 to 314- The first to M-th DACs 415-1 to M, the first to MI / Q modulators 414-1 to 414-M of the first to M transmitter RF chains, The first to M-th IF amplifiers 413-1 to 413-M, the first to M-2 IF mixers 412-1 to 4-M and the first to M-2 IF filters 411-1 to 411- N transmitter RF chain comprises first to N DACs 301-1 to N, first to NI / Q modulators 302-1 to N, first to Nth IF amplifiers 303-1 to N, To-N -1 IF mixers 304-1 to N, and first to N-1th IF filters 305-1 to 305-N. Therefore, the detailed description will be omitted in the following description.

4, the first to N-th receiver RF (Radio Frequency) chains operate in the TDD band mode, and the first to N-th transmitter RF chains are connected to the frequency generating and controller 416 In the TDD band mode or the FDD band mode.

The first to M RF LNAs 408-1 to 408-M of the first to M receiver RF chains amplify a signal received through an antenna connected thereto to RF filters 407-1 to 407-M, The first to M RF filters 407-1 to 407-M selectively filter the desired signals from the amplified signals and output the filtered signals to the RF mixers 406-1 to 406-M, 406-1 to 406-1 to 406-M convert the filtered RF signal down to an IF band and output the down converted IF filters 405-1 to 405-M.

The first to M re-shaping RF mixers / filters / amplifiers 410-1 to 410-M of the first to M transmitter RF chains are connected to a frequency divider Converts the IF signal input from the IF filters 411-1 to 411-M to up-convert the frequency of the filtered IF signal into an RF band, filters only a desired channel from the frequency-converted signal, Amplifies the amplified signal to a high level so that the amplified signal can be transmitted with sufficient power, and transmits the amplified signal to the receiver through the connected antenna.

The first to M hybrid duplexers / switches 409-1 to 409-M operate as a switch when connected to an antenna operating in a TDD band mode according to a control signal input from the frequency generator and controller 416, It operates as a duplexer.

The frequency generator and controller 416 uses the transmit antenna index set for the TDD band input from the antenna selector 417 to set the frequency of the RF chain connected to each antenna to the TDD band f ₁ and the FDD band f ₂ ) To the determined value. That is, in the case of the antenna belonging to the transmission antenna set for the TDD band, the frequency of the RF chain connected to the antenna is switched to the TDD band f ₁ and the frequency of the RF chain for the other antennas is switched to the FDD band f ₂ , . Also, a control signal is generated to operate as a switch for a hybrid duplexer / switch connected to an antenna operating in a TDD band mode, and a control signal is generated for a hybrid duplexer / switch connected to an antenna operating in an FDD band mode to operate as a duplexer do.

The antenna selector 417 receives the TDD band transmission antenna selection information from the base station through the downlink control channel and transmits a transmission antenna index set for the TDD band included in the received antenna selection information to the frequency generation and controller 416 . Here, the antenna selection method may be performed using the antenna selection information received from the base station as described above. However, the TDD band may be allocated to the odd-numbered antenna and the FDD band may be allocated to the even- Various antenna selection methods for the band are possible.

5 is a diagram illustrating a procedure of an adaptive antenna allocation method in a base station of a multi-antenna system according to an embodiment of the present invention.

Referring to FIG. 5, in step 501, the BS determines whether a pilot signal for a DD band and an FDD band is received from an MS on an uplink pilot channel. When the pilot signal is received, the base station estimates channels H ₁ and H ₂ for the TDD band and the FDD band using the received pilot signal in step 503. Here, the N × M channel matrix from the UE to the base station for the TDD band is denoted by H ₁ , the N × M channel matrix from the UE to the base station for the FDD band is denoted as H ₂ , And the bandwidths of the bandwidths W _{1 and} W _{2 ,} respectively.

을 결정한다. 여기서, 상기 TDD 대역에 할당할 송수신 안테나 집합은 전체 전송률을 최대화하는 안테나 할당 알고리즘을 이용하여 결정할 수 있다. Then, in step 505, the BS determines a transmission / reception antenna set to be allocated to the TDD band using the channels H ₁ and H ₂ for the estimated TDD band and the FDD band

. Here, the transmission / reception antenna set to be allocated to the TDD band may be determined using an antenna allocation algorithm that maximizes the overall transmission rate.

이라 하고, FDD 대역에 할당되는 인덱스의 집합을

라 하면,

이 된다. 마찬가지로, 상기 기지국의 수신 안테나 인덱스 1~N 중 TDD 대역에 할당되는 인덱스의 집합을

, FDD 대역에 할당되는 인덱스의 집합을

라 하면,

이 된다. 여기서, 안테나 할당이

로 주어진 경우, 전체 전송률은 하기 <수학식 1>과 같이 표현할 수 있다.For the description of the antenna allocation algorithm, a set of indices allocated to the TDD band among the transmission antenna indices 1 to M of the UE

, And a set of indexes allocated to the FDD band

In other words,

. Similarly, a set of indices allocated to the TDD band among the reception antenna indices 1 to N of the base station

, A set of indexes allocated to the FDD band

In other words,

. Here,

The total transmission rate can be expressed by Equation (1). &Quot; (1) &quot;

행렬을 의미한다. 여기서, 상기

는 인덱스 집합 A의 원소의 수를 나타낸다. 마찬가지로, 상기 H₂(A_T2, A_R2)는 상기 H₂에서 A_T2에 속하는 인덱스에 해당하는 열들과 A_R2에 속하는 인덱스에 해당하는 행들만 취하여 이루어진

행렬을 의미한다. 상기 I_K 는 K×K 단위행렬을 나타내며, 상기 (·)^H는 공액 전치(conjugate transpose) 연산을 나타낸다. 여기서, 상기 전체 전송률을 최대화하는 안테나 할당

,

은 상기 <수학식 1>을 최대화하는 (A_T1, A_R1)의 조합을 찾음으로써 가능하다. 여기서, 이에 해당하는 FDD 대역에 대한 안테나 인덱스 집합은

,

로 결정된다. Here, the P / σ ² denotes the signal-to-noise ratio, wherein the H ₁ (A _T1, A _R1) is a row for the index belonging to the columns and A _R1 that corresponds to the index belonging to the A _T1 at the H ₁ Made up only of

Matrix. Here,

Represents the number of elements of index set A. Similarly, the H _{2 (T2} A, A _R2) is made by taking only those rows that correspond to the indexes belonging to the columns A and _R2 corresponding to the index belonging to A _T2 in the H ₂

Matrix. I _K denotes a K × K unit matrix, and (·) ^H denotes a conjugate transpose operation. Here, an antenna allocation for maximizing the total transmission rate

,

Is possible by finding a combination of (A _T1 , A _R1 ) that maximizes Equation ( ₁ ). Here, the antenna index set for the corresponding FDD band is

,

.

을 하향링크 제어 채널을 통해 상기 단말로 전송한다. 이때, 상기 단말은 상기 결정된 TDD 대역 송신 안테나 선택 정보를 이용하여 각 안테나에 연결된 RF 체인의 주파수를 TDD 대역(f₁), FDD 대역(f₂) 중 결정된 값으로 스위칭한다. Then, in step 507, the BS determines a transmit antenna index set for the determined TDD band as the TDD band transmit antenna selection information

To the UE through the downlink control channel. At this time, the UE uses the determined TDD band transmission antenna selection information to switch the frequency of the RF chain connected to each antenna to a determined value among the TDD band (f ₁ ) and the FDD band (f ₂ ).

을 이용하여 각 안테나에 연결된 RF 체인의 주파수를 TDD 대역(f₁), FDD 대역(f₂) 중 결정된 값으로 스위칭한다. In step 509, the BS calculates a reception antenna index set for the determined TDD band

, The frequency of the RF chain connected to each antenna is switched to a determined value among the TDD band (f ₁ ) and the FDD band (f ₂ ).

Meanwhile, in the above embodiment of the present invention, a method of maximizing the overall data rate using the antenna allocation method has been described. However, it is needless to say that various types of low-complexity antenna allocation methods are applicable.

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

In a multi-antenna system, when a UL signal is simultaneously transmitted through a TDD band and an FDD band, a reconfigurable RF chain of the terminal limited by the number of terminal antennas and a reconfigurable RF chain of the base station limited by the number of base station antennas are allocated to the TDD band And the FDD band, there is an advantage that the HD system can be realized without increasing the number of RF chains. That is, it is possible to reduce the complexity of the base station and the terminal using the same number of RF chains as in the conventional TDD or FDD scheme, and it is possible to minimize system performance degradation caused by sharing the two bands.

Claims (17)

In a hybrid duplex complexity reduction apparatus in a base station of a multi-antenna system, A transmission RF (Radio Frequency) chain for each antenna operating in a TDD (Time Division Duplex) band mode, A receiving RF chain for each antenna operating in a TDD band mode or an FDD (Frequency Division Duplex) band mode according to a generated frequency, An antenna selector for determining a set of reception antennas to be allocated to the TDD band, And a frequency generation and controller for generating a TDD band frequency by a reception RF chain of the transmission RF chain for each antenna and the reception RF chain of the determined reception antenna set and for generating an FDD band frequency by a reception RF chain of other reception antenna sets, . The method according to claim 1, Wherein the antenna selector estimates a channel for a TDD band and an FDD band using a pilot signal received from a terminal and determines an antenna set to be allocated to the TDD band using the estimated channel information. The method according to claim 1, Wherein the antenna selector determines a transmission antenna set to be allocated to the TDD band, and transmits the determined transmission antenna set to the terminal. The method according to claim 1, Wherein the antenna selector determines a transmit antenna set to be allocated to the TDD band as a set of antennas that maximizes an overall data rate. The method according to claim 1 or 4, Wherein a total transmission rate for each transmission and reception antenna allocation is expressed by Equation (2).

Here,

Denotes a set of indices allocated to the TDD band among the transmission antenna indexes 1 to M of the UE,

Denotes a set of indices allocated to the FDD band,

. remind

Denotes a set of indices assigned to the TDD band among the reception antenna indices 1 to N of the base station,

Denotes a set of indices allocated to the FDD band,

. Further, the P / σ ² denotes the signal-to-noise ratio, wherein the H ₁ (A _T1, A _R1) is a row for the index belonging to the columns and A _R1 that corresponds to the index belonging to the A _T1 at the H ₁ Made up only of

Matrix. Here,

Represents the number of elements of index set A. Similarly, the H _{2 (T2} A, A _R2) is made by taking only those rows that correspond to the indexes belonging to the columns A and _R2 corresponding to the index belonging to A _T2 in the H ₂

Means a matrix. The method according to claim 1, Wherein the antenna selector fixedly determines a set of reception antennas to be allocated to the TDD band. The method according to claim 1, Wherein the frequency generation and controller outputs a control signal for an operation mode for each antenna to a hybrid duplexer / switch. 8. The method of claim 7, The transmission RF chain and the reception RF chain connect the corresponding antenna and operate as a switch when connected to an antenna operating in a TDD band mode according to a control signal of the frequency generation and controller and connected to an antenna operating in an FDD band mode Further comprising the hybrid duplexer / switch operating as a duplexer. The method according to claim 1, The transmission RF chain for each antenna includes a digital to analog converter (DAC), an in / quadrature phase modulator, an IF (intermediate frequency) amplifier, an IF mixer, an IF filter, an RF mixer, And an amplifier. The method according to claim 1, The receive RF chain for each antenna includes a reconfigurable RF LNA (Low Noise Amplifier) / filter / mixer, an IF (Intermediate Frequency) filter, an IF mixer, an IF LNA, an I / Q (In / Quadrature Phase) demodulator, Converter). &Lt; Desc / Clms Page number 13 &gt; A hybrid duplex complexity reduction apparatus in a terminal of a multi-antenna system, A reception RF (Radio Frequency) chain for each antenna operating in a TDD (Time Division Duplex) band mode, A transmission RF chain for each antenna operating in a TDD band mode or an FDD (Frequency Division Duplex) band mode according to a generated frequency, An antenna selector for determining a transmission antenna set to be allocated to the TDD band, And a frequency generation and controller for generating a TDD band frequency in the reception RF chain for each antenna and a transmission RF chain for the determined transmission antenna set and for generating an FDD band frequency in a transmission RF chain for other transmission antenna sets . 12. The method of claim 11, Wherein the antenna selector receives a transmission antenna set to be allocated to the TDD band from the base station and determines the transmission antenna set. 12. The method of claim 11, Wherein the antenna selector fixedly determines a set of transmit antennas to be allocated to the TDD band. 12. The method of claim 11, Wherein the frequency generation and controller outputs a control signal for an operation mode for each antenna to a hybrid duplexer / switch. 15. The method of claim 14, The transmission RF chain and the reception RF chain connect the corresponding antenna and operate as a switch when connected to an antenna operating in a TDD band mode according to a control signal of the frequency generation and controller and connected to an antenna operating in an FDD band mode Further comprising the hybrid duplexer / switch operating as a duplexer. 12. The method of claim 11, The transmission RF chain for each antenna includes a digital to analog converter (DAC), an in / quadrature phase modulator, an intermediate frequency (IF) amplifier, an IF mixer, an IF filter, a reconfigurable RF mixer / &Lt; / RTI &gt; 12. The method of claim 11, The reception RF chain for each antenna may include an RF LNA (Low Noise Amplifier), an RF filter, an RF mixer, an IF filter, an IF mixer, an IF LNA, an I / Q (In / Quadrature Phase) demodulator, Converter). &Lt; Desc / Clms Page number 13 &gt;

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