KR20100082405A - Method and device for beam forming in mobile communication system - Google Patents

Abstract

PURPOSE: A method and a device for forming a beam in a mobile communication system are provided to estimate a downlink channel accurately by forming a downlink beam forming coefficient based on the channel information received through a downlink antenna. CONSTITUTION: A downlink antenna(220) receives channel information transmitted from a terminal, and transmits downlink data reflecting a beaming forming coefficient to a terminal. A channel estimator(260B) outputs a beam forming coefficient factor, and estimates a channel value by using channel information. A beam forming processor(260C) receives the beam forming coefficient factor to generate a beam forming coefficient, and performing beam forming for the downlink data to generate the downlink data reflecting the beam forming coefficient.

Description

Beamforming method and apparatus in mobile communication system {METHOD AND DEVICE FOR BEAM FORMING IN MOBILE COMMUNICATION SYSTEM}

The present invention relates to a beam forming method and apparatus in a mobile communication system. More specifically, the present invention relates to a beamforming method and apparatus for switching to receive channel information from a downlink antenna when a switch control signal is generated and generating beamforming coefficients using the channel information received through the downlink antenna. .

Techniques using multiple antennas (hereinafter referred to as 'MIMO') have been actively studied to increase capacity of high-speed data transmission and communication systems. In a MIMO system, a plurality of antennas receive different data through different spatial paths in a physical environment. Increasing the number of inputs and outputs within some limits increases the system's ability to improve data transfer capability by using multiple spatial paths. MIMO opens up a number of possibilities for improving high-speed data communications. Beam Forming is one of the most powerful technologies.

Beamforming technology sends data through an optimal path available between a transmitter (hereinafter referred to as a 'base station') and a receiver (hereinafter referred to as a 'terminal'). To find this path, the base station drives a number of antennas using a phase shift algorithm, which concentrates most of its wireless output towards the desired terminal.

The base station feeds back channel information from the terminal to form a beamforming coefficient for the beamforming. In the case of TDD (Time Division Duplexing), the channels are also the same because the frequencies used for the downlink and the uplink are the same. Therefore, in the case of the TDD, it is possible to apply the uplink channel estimation result to the downlink as it is.

On the other hand, in the case of frequency division duplexing (FDD), the base station includes a downlink antenna and an uplink antenna separately, and thus the characteristics of the frequency and the link used for the downlink and the uplink are different. Therefore, there is a limit in applying the uplink channel estimation result to the downlink as it is. In case of FDD, even though the base station receives the channel information from the terminal, the channel information received through the uplink antenna of the base station is used to form the downlink beamforming coefficient, so there is a problem that the error occurs and the reliability is lowered. do.

The present invention has been made to solve the above problems, and when a switch control signal is generated, the channel information transmitted from the terminal is received through the downlink antenna of the base station, and beamforming is performed using the received channel information. The purpose is to.

The beamforming apparatus of the present invention for solving the above problems, when receiving a channel information transmitted from the terminal, and transmits the downlink antenna reflecting the beamforming coefficient to the terminal, when generating a switch control signal, the A downlink antenna switch forming a transmission path of the channel information so that channel information received through a downlink antenna is transmitted to a channel estimator, a data processing unit generating the switch control signal and outputting downlink data to be transmitted to the terminal; Receives the channel estimator and the beamforming coefficient factor for estimating a channel value using the channel information received through the downlink antenna, and outputs a beamforming coefficient factor to generate a beamforming coefficient, and receives the downlink data. And beamforming to reflect the beamforming coefficients. And a beamforming processing unit for generating downlink data.

In the beamforming processing method for solving the above problem, when the switch control signal is generated, switching the downlink antenna switch so that channel information received through the downlink antenna is transmitted to the channel estimator, and receiving the received channel information. Estimating channel values and outputting beamforming coefficient factors, generating beamforming coefficients using the beamforming coefficient factors, generating downlink data reflecting the beamforming coefficients, and generating the beamforming coefficients. And transmitting the reflected downlink data to the terminal.

Since the present invention forms the downlink beamforming coefficients using the channel information received through the downlink antenna, it is more accurate than the prior art of forming the downlink beamforming coefficients using the channel information received through the uplink antenna. The downlink channel can be estimated. In addition, since downlink beamforming coefficients are generated based on the estimated downlink channel, more accurate beamforming may be performed.

Hereinafter, it is assumed that the beamforming apparatus described in the present invention uses a multiple antenna (MIMO).

In general, beamforming may be classified into downlink beamforming and uplink beamforming according to the beamforming direction. In this case, beamforming in the direction of the base station at the base station is called downlink beamforming, and beamforming in the direction of the base station at the terminal is called uplink beamforming. The beamforming described in the present invention below relates to downlink beamforming.

In addition, the beamforming may be classified into feedback beamforming and directional beamforming according to what information forms a beam. In this case, feedback beamforming in downlink beamforming is configured so that the terminal feeds back channel information necessary for beamforming to the base station, and in the directional beamforming, the base station measures the direction of the terminal without beaming by the terminal and beamforms it. The beamforming described in the present invention below relates to feedback beamforming.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. Further, the detailed description of well-known functions and constructions that may obscure the gist of the present invention will be omitted.

1 is a diagram illustrating a downlink beamforming process of a conventional base station 100.

In general, downlink beamforming performed by the base station 100 forms a beam using channel information fed back from the terminal. Thus, the performance of downlink beamforming is proportional to the accuracy of the channel information fed back from the terminal.

The base station 100 shown in FIG. 1 includes an uplink antenna 110, a duplexer 120, an RF transceiver 130, a controller 140, and a downlink antenna 150. Here, the RF transceiver 130 represents a functional block including elements such as an RF transmitter, an RF receiver, and an amplifier except for a filter (ie, a duplexer).

As shown in FIG. 1, the base station 100 receives channel information transmitted from a terminal through an uplink antenna for downlink beamforming (first step). The channel information received through the uplink antenna is transmitted to the controller 140 via the RF transceiver 130.

The controller 140 estimates a channel value using the transmitted channel information (second step). The controller 140 calculates an angle of arrival (AOA) and a time of arrival (TOA) based on the estimated channel value (step 3). Then, the controller 140 generates a beamforming coefficient using the calculated arrival angle and propagation arrival time and processes downlink data to be transmitted to the terminal.

The controller 140 transmits the processed downlink data to the terminal through the downlink antenna 150.

According to the prior art described above, the beamforming coefficients for the downlink data are generated from the channel information received through the uplink antenna 110. However, since the wireless environment between the uplink antenna 110 of the terminal and the base station and the wireless environment between the downlink antenna 150 of the terminal and the base station are different from each other, the channel value is also different.

Nevertheless, conventionally, beamforming coefficients for downlink data are generated based on channel information received through the uplink antenna 110. Therefore, there was a problem in that an accurate beamforming coefficient could not be generated because the channel and the wireless environment between the terminal and the downlink antenna 150 were not accurately reflected.

In the present invention is to solve the above problems. To this end, the base station of the present invention generates a beamforming coefficient for the downlink data based on channel information received through the downlink antenna). In other words, when the switching control signal is generated, the operation mode of the downlink antenna operating in the transmission mode (Tx Mode) is switched to the reception mode (Rx Mode). Then, the base station can receive the channel information transmitted from the terminal through the downlink antenna.

Accordingly, since downlink beamforming coefficients are generated based on channel information received through the downlink antenna, more accurate beamforming can be performed.

2 is a block diagram illustrating a structure of a base station 200 for performing beamforming according to an embodiment of the present invention. The base station 200 may include an uplink antenna 210, a downlink antenna 220, a duplexer 230, a downlink antenna switch 240, an RF transceiver 250, and a controller 260. Here, the RF transceiver 250 represents a functional block including an RF transmitter 250A, an amplifier 250B, and an RF receiver 250C except for a filter. The controller 260 may include a data processor 260A, a channel estimator 260B, and a beam forming processor 260C.

The uplink antenna 210 receives uplink data transmitted over the air from the terminal. In addition, according to an embodiment of the present invention, the uplink antenna 210 may receive channel information transmitted from the terminal. In this case, the channel information received through the uplink antenna 210 is transmitted to the RF receiver 250C.

The downlink antenna 220 radiates downlink data according to a corresponding frequency band to the air. Since the base station 200 according to the embodiment of the present invention performs downlink beamforming, the downlink beamforming coefficient is reflected in the downlink data transmitted through the downlink antenna 220.

In addition, in the downlink antenna 220 according to the embodiment of the present invention, when the switching control signal (SWC) is generated, the operation mode is switched to the reception mode (Rx Mode) simultaneously with the switching of the downlink antenna switch 240. Accordingly, channel information received through the downlink antenna 220 may be transmitted to the RF receiver 250C and the channel estimator 260B.

The duplexer 230 generally separates a transmission frequency and a reception frequency and may include a Tx unit in charge of transmission and an Rx unit in reception (not shown separately in the drawing). In this case, the Tx unit transmits a signal transmitted from the RF transmitter 250A to the terminal through the downlink antenna 220. In addition, the Rx unit transmits a signal received through the uplink antenna 210 to the RF receiver 250C.

According to an embodiment of the present invention, when the switching control signal SWC is generated, the duplexer 230 transmits channel information received through the downlink antenna 220 to the RF receiver 250C through the downlink antenna switch 240. To pass.

The downlink antenna switch 240 uses the downlink antenna 220 and the RF receiver 250C to transmit channel information received through the downlink antenna 220 to the RF receiver 250C when a switch control signal is generated. Connect the switching. Then, a path through which a signal can be transmitted is formed between the downlink antenna 220 and the RF receiver 250C, and channel information received through the downlink antenna 220 may be transferred to the RF receiver 250C. Thereafter, the channel information is input to the channel estimator 260B.

The RF transceiver 250 includes an RF transmitter 250A, an amplifier 250B, and an RF receiver 250C. The RF transceiver 250 represents a functional block including elements such as an RF transmitter 250A, an amplifier 250B, and an RF receiver 250C except for a filter (ie, a duplexer).

The RF transmitter 250A up-converts the beamformed downlink data to a transmission band frequency and transmits it to the amplifier 250B. The amplifier 250B then amplifies and transfers the gain of the up-converted downlink data to the duplexer 230.

The RF receiver 250C receives the uplink data received through the uplink antenna 210, and outputs down-converted frequency into the base band band.

The RF receiver 250C of the present invention receives the channel information received through the uplink antenna 210 before generating the switch control signal (SWC), frequency down-converts it, and outputs it to the beamforming processing unit 260C. When the switch control signal (SWC) is generated, the RF receiver 250C may also receive channel information received through the downlink antenna 220, and frequency down-convert the converted channel information to the channel estimator 260B. .

In other words, when the switch control signal (SWC) is generated, the RF receiver 250C outputs channel information received through the downlink antenna 220 to the channel estimator 260B, and through the uplink antenna 210. The received channel information is output to the beam forming processing unit 260C.

According to an exemplary embodiment of the present invention, when the switch control signal (SWC) is generated, the channel information received through the downlink antenna 220 is output to the channel estimator 260B, and the channel received through the uplink antenna 210. The information may be used to output a plurality of RF receivers 250C to the beam forming processor 260C. However, it is not necessarily limited to the above method to implement this.

The controller 260 may perform a function of controlling the overall operation of the base station 220 and the signal flow between the internal blocks of the base station 220. In more detail, the controller 260 may include a data processor 260A, a channel estimator 260B, and a beam forming processor 260C.

The data processing unit 260A may include a transmission data processing unit and a reception data processing unit (not shown in the figure). The transmission data processor may include a coder for encoding a signal to be transmitted, a modulator for modulating the encoded signal, and a digital-to-analog converter for converting the modulated signal into an analog signal. have. Here, the coder may include a data coder for processing packet data and the like, and an audio coder for processing audio signals such as voice. The transmission data processor outputs the encoded and modulated signal to the beamforming processor 260C.

The reception data processor includes an analog-to-digital converter for converting an analog signal output from the RF receiver 250C into a digital signal, a demodulator for demodulating a modulated signal, and a decoder for decoding the demodulated signal. decoder). The decoder may include a data decoder for processing packet data and the like, and an audio decoder for processing audio signals such as voice.

According to an exemplary embodiment of the present invention, the data processor 260A may generate a switch control signal SWC for controlling the downlink antenna switch 240. The data processor 260A may generate a switch control signal SWC when necessary, and control the downlink antenna switch 240 to switch between the downlink antenna 220 and the RF receiver 250C.

The data processor 260A may generate the switch control signal SWC periodically, or when more accurate beamforming is required or when downlink data is generated, but is not necessarily limited thereto.

In addition, the data processor 260A may signal-process channel information received through the uplink antenna 210 or the downlink antenna 220 and transmit the signal to the channel estimator 260B.

The channel estimator 260B estimates a channel value using the channel information transmitted from the terminal. The channel estimator 260B outputs the arrival angle and the propagation arrival time, which are factors used for generating the download beamforming coefficients, and transmits them to the beamforming processor 260C.

According to an embodiment of the present invention, the channel estimator 260B may receive channel information received through the downlink antenna 220 when the switch control signal SWC is generated. The channel estimator 260B then generates a beamforming coefficient using the channel information received through the downlink antenna. Accordingly, the channel estimator 260B may generate more accurate beamforming coefficients for the downlink channel.

The beamforming processing unit 260C controls a series of processes for the download beamforming processing of the base station 200. That is, the beamforming processing unit 260C receives a beamforming coefficient factor (ie, arrival angle and propagation arrival time) output from the channel estimating unit 260B. In this case, the beamforming coefficient factor is generated from the channel information received via the downlink antenna 220. The beamforming processing unit 260C simultaneously receives downlink data from the data processing unit 260A. Then, the beamforming processing unit 260C beamforms the downlink data and outputs downlink data in which beamforming coefficients are reflected. The downlink data generated through the above process is transmitted to the terminal through the downlink antenna 220.

3 is a diagram illustrating operation mode switching of a downlink antenna according to generation of a switching control signal according to an embodiment of the present invention.

As described above, the data processor 260A generates the switching control signal SWC during the 't1' time (hereinafter, 'switching on time') when necessary. The downlink antenna switch 240 then connects the downlink antenna 220 and the RF receiver 250C to form a path through which signals can be transmitted to each other.

Then, the operation mode of the downlink antenna 220 is switched from a transmission mode (Tx Mode) to a reception mode (Rx Mode) (B section) and receives channel information transmitted from the terminal. The received channel information is transmitted to the RF receiver 250C and the channel estimator 260B via the downlink antenna switch 240.

When the switching on time elapses, the downlink antenna switch 240 is grounded again. Accordingly, the downlink antenna 220 operates (C section) in the transmission mode (Tx).

This process may be repeated every time a switching control signal is generated. As described above, the switching control signal may occur periodically or when accurate downlink beamforming coefficients are required, but are not necessarily limited thereto.

 4 is a flowchart illustrating a process of performing downlink beamforming by acquiring channel information from a downlink antenna according to an embodiment of the present invention.

First, the base station 200 operates according to general uplink data and downlink data processing procedures before the switch control signal (SWC) is generated.

The data processor 260A of the base station 200 generates the switch control signal SWC in step S420 when it is determined that the switch control signal SWC needs to be generated. Then, the downlink antenna switch 240 switches the downlink antenna 220 and the RF receiver 250C in step S430 to form a path through which signals can be transmitted to each other. In this case, the operation mode of the downlink antenna 220 is switched from the transmission mode to the reception mode.

Then, the downlink antenna 220 may receive channel information transmitted from the terminal in step S440. After receiving the channel information, the operation mode of the downlink antenna 220 may be switched back from the reception mode to the transmission mode. In this case, the timing at which the operation mode of the downlink antenna 220 switches from the reception mode to the transmission mode is not necessarily limited immediately after receiving the channel information.

Channel information received through the downlink antenna 220 is input to the RF receiver 250C in step S450. The channel information input to the RF receiver 250C is frequency-down converted and input to the channel estimator 260B.

Then, the channel estimator 260B receives the channel information and estimates the channel value in step S460. The channel estimator 260B outputs an arrival angle and a propagation arrival time, which are downlink beamforming coefficient generation factors, based on the estimated channel value.

On the other hand, the beamforming processing unit 260C receives the arrival angle and the propagation arrival time output from the channel estimating unit 260B, and receives the downlink data to be transmitted from the data processing unit 260A to the terminal. Then, the beamforming processing unit 260C beamforms the downlink data in step S470 to output downlink data reflecting the beamforming coefficients.

Then, in step S480, the downlink data is transmitted to the terminal through the downlink antenna 220 according to the generated beamforming coefficients.

5 and 6 are flowcharts illustrating differences between the conventional technology and the present invention for processing beamforming based on channel information transmitted from a terminal. 5 and 6 illustrate signal flows inside a base station.

First, FIG. 5 is a flowchart illustrating a beamforming process of a conventional base station.

First, the uplink antenna of the base station receives channel information transmitted from the terminal in step S510. Then, the received channel information is input to the channel estimator in step S520. The channel estimator estimates a channel value based on the channel information input in step S530 and outputs an angle of arrival and propagation arrival time for forming a beamforming coefficient. The output arrival angle and propagation arrival time are transmitted to the beamforming processing unit in S540.

In step S550, the beamforming processing unit receives downlink data, an arrival angle, and a propagation arrival time. In operation S560, the beamforming processor generates a beamforming coefficient using the arrival angle and the propagation arrival time. The beamforming processing unit beamforms the downlink data by using the generated beamforming coefficients. The downlink data is then transmitted to the downlink antenna in step S570, and transmitted to the terminal in step S580.

That is, in the related art, since beamforming coefficients for the downlink data are generated based on channel information received through the uplink antenna, there is a limit to accurate beamforming.

6 is a flowchart illustrating a beamforming process of the base station 200 according to an embodiment of the present invention.

First, the base station 200 processes the uplink data and the downlink data according to general uplink and downlink procedures before the switch control signal (SWC) is generated. Thereafter, when the switch control signal SWC is generated, the downlink antenna 220 and the RF receiver 250C are connected to each other so that the operation mode of the downlink antenna 220 is switched from the transmission mode to the reception mode.

Then, the downlink antenna 220 receives the channel information transmitted from the terminal in step S610. The received channel information is input to the RF receiver 250C via the downlink antenna switch 240, and the input channel information is transmitted to the channel estimator 260B.

In other words, although the channel information transmitted to the channel estimator 260B is the channel information received through the uplink antenna, the channel information received through the downlink antenna in the present invention.

The channel estimator 260B estimates a channel value based on the input channel information in step S630. The channel estimator 260B outputs an angle of arrival and propagation arrival time, which are factors for generating the beamforming coefficients. The channel estimator 260B transmits the output angle of arrival and propagation arrival time to the beamforming processor 260C in operation S640.

In operation S6500, the beamforming processor generates a beamforming coefficient using the arrival angle and the propagation arrival time. The beamforming processing unit beamforms the downlink data by using the generated beamforming coefficients. Then, the downlink data is transmitted to the downlink antenna in step S670, and transmitted to the terminal in step S680.

In the beamforming method according to the present invention, since beamforming is processed using channel information received through a downlink antenna, more accurate beamforming may be performed.

The embodiments of the present invention disclosed in the present specification and drawings are merely illustrative of specific embodiments of the present invention and are not intended to limit the scope of the present invention in order to facilitate understanding of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention can be carried out in addition to the embodiments disclosed herein.

1 is a diagram illustrating a downlink beamforming process of a conventional base station 100.

2 is a block diagram illustrating a structure of a base station 200 for performing beamforming according to an embodiment of the present invention.

3 is a diagram illustrating operation mode switching of a downlink antenna according to generation of a switching control signal according to an embodiment of the present invention.

 4 is a flowchart illustrating a process of performing downlink beamforming by acquiring channel information from a downlink antenna according to an embodiment of the present invention.

5 is a flowchart illustrating a beamforming process of a conventional base station.

6 is a flowchart illustrating a beamforming process of the base station 200 according to an embodiment of the present invention.

Claims (6)

In the beamforming processing apparatus of a mobile communication system, A downlink antenna receiving channel information transmitted from a terminal and transmitting downlink data reflecting beamforming coefficients to the terminal; A downlink antenna switch forming a transmission path of the channel information so that channel information received through the downlink antenna is transmitted to a channel estimator when a switch control signal is generated; A data processor which generates the switch control signal and outputs downlink data to be transmitted to the terminal; The channel estimator for estimating a channel value using the channel information received through the downlink antenna and outputting a beamforming coefficient factor; And And a beamforming processing unit configured to generate the beamforming coefficients by receiving the beamforming coefficient factor, and to receive the downlink data and to perform beamforming to generate downlink data reflecting the beamforming coefficients. Processing unit. The method of claim 1, And the data processing unit generates the switch control signal periodically or when the downlink data is generated. The method of claim 2, And said beamforming coefficient factor comprises at least one of an angle of arrival or propagation arrival time. In the beamforming processing method of a mobile communication system, Switching the downlink antenna switch so that channel information received through the downlink antenna is transmitted to the channel estimator when the switch control signal is generated; Estimating a channel value by using the received channel information and outputting a beamforming coefficient factor; Generating a beamforming coefficient using the beamforming coefficient factor, and generating downlink data in which the beamforming coefficient is reflected; And And transmitting downlink data reflecting the beamforming coefficients to the terminal. The method of claim 4, wherein And the switch control signal is generated periodically or upon generation of the downlink data. The method of claim 5, And said beamforming coefficient factor comprises at least one of an angle of arrival or propagation arrival time.

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