KR100406529B1 - Smart antenna base station system and the method of chip level beamforming based and his action method to use standard signal production apparatus and the method and he - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a reference signal generator and a method thereof, and a smart antenna base station system based on a chip level beam former using the same and a method of operating the same.

2. The technical problem to be solved by the invention

The present invention generates a reference signal suitable for a channel estimator and a chip level beamformer by using a decision-directed mode in which DPDCH / DPCCH symbols estimated by a discriminator after rake synthesis are generated, thereby only referring to pilot symbols. Reference signal generator and method for increasing channel capacity and beamforming more accurately than when used as a signal, and a method and method thereof, and a smart antenna base station system based on a chip level beam former using the same To provide a method of operation and a computer readable recording medium having recorded thereon a program for realizing the above methods.

3. Summary of Solution to Invention

A smart antenna base station system based on a chip level beamformer having a decision directing mode, comprising: signal converting means for converting a signal received through an array antenna into a baseband signal; Multipath searching means for detecting multipath from the baseband signal of the signal conversion means and estimating a delay time of each path; Reference signal generating means for generating a reference signal for channel estimation and chip level beam forming on the basis of the multipath delay time information searched by the multipath searching means; Chip level beamforming means for generating a chip level beamforming weight vector and forming beams for each path based on the chip level reference signal of the reference signal generating means; Channel separation means for despreading the output of the chip level beam forming means to separate crystal directing channels (DPDCH, DPCCH); Channel estimating and compensating means for estimating a channel based on the decision directing control channel (DPCCH) of the channel separating means and the symbol level reference signal of the reference signal, and compensating the channel using the channel estimation value; Channel synthesis means for synthesizing the decision-oriented data channel (DPDCH) and the decision-oriented control channel (DPCCH) for each path; And symbol discrimination means for discriminating a symbol for each decision-oriented channel.

4. Important uses of the invention

The present invention is used in the smart antenna base station system and the like.

Description

Smart antenna base station system and the method of chip level beamforming based and his action method to use standard signal production apparatus and the method and he}

The present invention relates to a reference signal generating device and a method thereof, a smart antenna base station system based on a chip level beam former using the same, and a method of operating the same, and a computer-readable recording medium recording a program for implementing the methods. In the wideband code division multiple access (WCDMA) smart antenna base station system, a channel estimator and a chip level beam are obtained by using the symbols of the dedicated data channel and the dedicated control channel estimated by the discriminator after rake finger synthesis and using a spreading code and a scrambling code. A reference signal generator and a method for generating a reference signal suitable for a forming machine, a smart antenna base station system based on a chip level beam former using the same, a method of operating the same, and a computer readable recording recording a program for realizing the methods. In the medium It is about.

In a mobile communication base station system using an array antenna, through various beamforming algorithms, the antenna gain is increased for a desired user signal and the antenna gain is reduced for a user acting as an interference signal, thereby increasing the overall system capacity.

In particular, asynchronous wideband code division multiple access (WCDMA) smart antenna base station systems employing a chip level beamformer require multiplication of beamforming vectors on a chip-by-chip basis compared to systems based on symbol level beamformers. Therefore, there is a disadvantage in that power consumption is large and calculation amount is large. However, since the number of orthogonal / phase (I / Q) correlators required is low, the additional hardware implementation complexity is low, and the problem of power consumption is not large in the base station system.

In the uplink of the WCDMA mobile communication system, a dedicated physical data channel (DPDCH) and a dedicated physical control channel (DPCCH) are transmitted in parallel.

Here, the DPDCH carries data sent by the user to the base station, and the DPCCH carries control information necessary for transmitting coherent demodulation by transmitting the DPDCH. Pilot symbols occupy a portion in the DPCCH. As a beamforming algorithm that can be used in the chip level beamformer of the WCDMA smart antenna base station system, an algorithm for obtaining a beamforming weight vector using a reference signal (pilot) is typical. The reference signal used in the chip level beamformer spreads a pilot symbol known by the base station to form a chip level sequence, uses it as a reference signal, and calculates a beamforming weight vector using a pilot chip level sequence of the received DPCCH. .

In WCDMA uplink, the chip power of DPDCH and DPCCH is determined by the spreading factor of each channel. The spreading factor of DPCCH is always 256, and the spreading factor of DPDCH is 4 ~ 256, depending on the data transmission rate. If 960kbps high-speed data is transmitted, the spreading factor of the DPDCH is 4, and the chip power of the DPDCH is 8 times higher than the chip power of the DPCCH. When the difference between the chip power of the DPDCH and the DPCCH is large, there may be a limit in accurately obtaining the beamforming weight vector using only the pilot chip sequence.

For reference, the smart antenna base station system will be described in more detail as follows.

First, the "code division multiple access smart antenna system" (Korean Patent Application No. "10-2000-0062843 ', 2000.10.25) with respect to the smart antenna base station system is as follows.

In order to reduce beamforming error caused by relatively low power of the pilot channel compared to the power of the traffic channel in the CDMA system, the patent feedbacks and respreads some symbols of the traffic channel estimated by the discriminator after rake synthesis to re-spread the reference signal. The method of use was presented.

In the uplink of the CDMA system considered in the above patent, a traffic channel for transmitting data and a continuous pilot channel are simultaneously transmitted. However, in the uplink of a WCDMA system, the pilot is not continuously transmitted with data, and the slot occupied by the pilot in the slot (10 bits) DPCCH differs for each slot type. Since the maximum 5 bits and the minimum 3 bits, the reference signal generator having a structure different from the above patent should be considered.

Particularly, in the compression mode, since the pilot has only at least 3 bits, the beamforming weight vector is obtained using only the pilot symbol or the channel estimation cannot accurately obtain the beamforming weight vector, and the channel estimation error is increased. do.

Therefore, in the current technical field, a channel estimator and chip level beamformer of a WCDMA smart antenna base station system using a feedback of a symbol of a dedicated data channel and a dedicated control channel estimated by a discriminator after rake finger synthesis and a spreading code and a scrambling code There is a need for a method of generating a reference signal suitable for the present invention.

The present invention has been proposed in order to meet the above-mentioned requirements. The channel estimator and the chip level beam are made by using a decision-directed mode in which DPDCH / DPCCH symbols are estimated by the discriminator after rake synthesis. By generating a reference signal suitable for the shaper, the reference signal generator and its method for increasing the system capacity and the effective range of the base station by more accurately channel estimation and beam shaping than when only the pilot symbol is used as the reference signal, and a method thereof It is an object of the present invention to provide a smart antenna base station system based on a chip level beam former, a method of operating the same, and a computer readable recording medium recording a program for implementing the methods.

1 is a block diagram of an embodiment of a chip level beamformer based WCDMA smart antenna base station system with a decision directing mode in accordance with the present invention;

2 is a diagram illustrating an embodiment of a reference signal generator in a chip level beamformer based WCDMA smart antenna base station system having a decision directing mode according to the present invention;

3 is a flow diagram of an embodiment of a method for operating a chip level beamformer based WCDMA smart antenna base station system with a decision directing mode in accordance with the present invention;

* Explanation of symbols for the main parts of the drawings

101: array antenna 102: RF receiver

103: multipath explorer 104: rake finger

105: chip level beam former 106: despreader

107: channel estimator 108: channel compensator

109: rake synthesizer 110: discriminator

111: reference signal generator

According to an aspect of the present invention, there is provided a chip level beamformer based smart antenna base station system having a decision directing mode, comprising: signal converting means for converting a signal received through an array antenna into a baseband signal; Multipath searching means for detecting multipath from the baseband signal of the signal conversion means and estimating a delay time of each path; Reference signal generating means for generating a reference signal for channel estimation and chip level beam forming on the basis of the multipath delay time information searched by the multipath searching means; Chip level beamforming means for generating a chip level beamforming weight vector and forming beams for each path based on the chip level reference signal of the reference signal generating means; Channel separation means for despreading the output of the chip level beam forming means to separate crystal directing channels (DPDCH, DPCCH); Channel estimating and compensating means for estimating a channel based on the decision directing control channel (DPCCH) of the channel separating means and the symbol level reference signal of the reference signal, and compensating the channel using the channel estimation value; Channel synthesis means for synthesizing the decision-oriented data channel (DPDCH) and the decision-oriented control channel (DPCCH) for each path; And a symbol discrimination means for discriminating a symbol for each decision-oriented channel.

In addition, the present invention, in the reference signal generator for channel estimation and chip level beam forming, DPCCH slot for forming a slot using a decision-oriented control channel (DPCCH) excluding the pilot symbol and the pilot symbol of the slot First reference signal generating means for generating a symbol level reference signal including a configurator; According to the output signal of the first reference signal generating means, multiply the DPCCH channel code by 90 degrees, multiply by the scrambling code of the corresponding user, and output the delayed by the corresponding multipath delay time to output the DPCCH-based chip level reference signal. Second reference signal generating means for generating a signal; And a DPDCH-based chip level reference signal by multiplying the DPDCH channel code and the scrambling code of the user corresponding to the decision-oriented data channel (DPDCH) by delaying the multipath delay time and adding the DPCCH-based chip level reference signal. And a reference signal generator for channel estimation and chip level beam formation including a third reference signal generator for generating a signal.

In addition, the present invention provides a method of operating a chip level beamformer based smart antenna base station system having a decision directing mode, comprising: a first step of converting a signal received through an array antenna into a baseband signal; Detecting a multipath from the converted baseband signal and estimating a delay time of each path to search for the multipath; Generating a reference signal for channel estimation and chip level beamforming based on the found multipath delay time information; A fourth step of generating a chip level beamforming weight vector based on the generated reference signal and despreading the output of the chip level beam former for forming beams for each path to separate the crystal directing channels (DPDCH and DPCCH); ; A fifth step of estimating a channel based on the separated decision oriented control channel (DPCCH) and the symbol level reference signal of the reference signal and compensating the channel using the channel estimate value; Synthesizing the decision-oriented data channel (DPDCH) and the decision-oriented control channel (DPCCH) for each path; And a seventh step of determining a symbol for each decision-oriented channel.

In addition, the present invention, in the method for generating a reference signal for channel estimation and chip level beam forming, the slot is configured by using a decision-directed control channel (DPCCH) excluding the pilot symbol and the pilot symbol of the slot, the symbol level reference signal Generating a first step; A second step of generating a DPCCH-based chip level reference signal by outputting a multiplying DPCCH channel code by 90 degrees and multiplying the phase by 90 degrees according to the symbol level reference signal and multiplying the scrambling code of the corresponding user by the multipath delay time. step; And a DPDCH-based chip level reference signal by multiplying the DPDCH channel code and the scrambling code of the user corresponding to the decision-oriented data channel (DPDCH) by delaying the multipath delay time and adding the DPCCH-based chip level reference signal. Characterized in that it comprises a third step of generating a.

The present invention also provides a smart antenna base station system including a processor, comprising: a first function of converting a signal received through an array antenna into a baseband signal; A second function of detecting a multipath from the converted baseband signal and searching for the multipath by estimating a delay time of each path; A third function of generating a reference signal for channel estimation and chip level beamforming based on the found multipath delay time information; A fourth function of generating a chip level beamforming weight vector based on the generated reference signal and despreading the output of the chip level beam former for forming the beam for each path to separate the crystal directing channels (DPDCH, DPCCH); ; A fifth function of estimating a channel based on the separated decision oriented control channel (DPCCH) and the symbol level reference signal of the reference signal, and compensating for the channel using a channel estimate value; A sixth function of synthesizing the decision-oriented data channel (DPDCH) and the decision-oriented control channel (DPCCH) for each path; And a computer-readable recording medium having recorded thereon a program for realizing a seventh function of discriminating symbols for each decision-oriented channel.

The present invention also provides a first function for generating a symbol level reference signal by configuring a slot in a reference signal generator having a processor using a decision oriented control channel (DPCCH) excluding a pilot symbol and a pilot symbol of a corresponding slot. ; A second step of generating a DPCCH-based chip level reference signal by outputting a multiplying DPCCH channel code by 90 degrees and multiplying the phase by 90 degrees according to the symbol level reference signal and multiplying the scrambling code of the corresponding user by the multipath delay time. function; And a DPDCH-based chip level reference signal by multiplying the DPDCH channel code and the scrambling code of the user corresponding to the decision-oriented data channel (DPDCH) by delaying the multipath delay time and adding the DPCCH-based chip level reference signal. A computer readable recording medium having recorded thereon a program for realizing a third function of generating a memory device.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of an embodiment of a chip level beamformer based WCDMA smart antenna base station system with a decision directing mode according to the present invention.

As shown in FIG. 1, a WCDMA smart antenna base station system based on a chip level beam former is a radio frequency (RF) for converting a signal received through an array antenna 101 into a digital baseband signal sampled for each antenna. A multipath searcher 103 for detecting a multipath by receiving a digital baseband signal through the receiver 102 and the RF receiver 102, and estimating a delay time for each multipath, and the multipath searcher ( The chip-level beamforming weight vector is calculated in units of slots based on the reference signal delayed by the estimated delay time for each multipath through data 103 and the data received from the array antenna 101, and the input of the array antenna 101 is performed. The chip level beamformer 105 multiplying the signal vector and the data transmitted through the chip level beamformer 105 are used to despread each multipath to perform DPDCH and DPCCH. A channel estimator 107 for estimating a channel from a desired user to the base station array antenna 101 by using the despreader 106 for separating the signal, the DPCCH and the pilot symbol separated through the despreader 106, and A channel compensator 108 for compensating DPDCH and DPCCH of each rake finger 104 using the channel estimate estimated by the channel estimator 107, and a rake for synthesizing the DPDCH and DPCCH from each rake finger 104 The spreader of the synthesizer 109, the discriminator (DPDCH, DPCCH) 110 for discriminating the symbols of DPDCH and DPCCH, and the DPDCH symbol, DPCCH symbol, pilot and despreader 106 determined from the discriminator 110. A reference signal generator 111 for receiving a code and a scrambling code and generating a reference signal used in the channel estimator 107 and the chip level beam former 105 is provided.

Here, the reference signal generator 111 generates a symbol level reference signal for the channel estimator 107 and a chip level reference signal for the chip level beam former 105 for the corresponding slot.

The chip level beam former based WCDMA smart antenna base station system having the structure as described above and a method of operation thereof will be described in detail as follows.

First, a signal input from the base station array antenna 101 having M antenna array elements is synchronized through the RF receiver 102, sampled for each antenna, and for each antenna through an A / D converter having a chip rate. Obtain the chip-level baseband input signal vector. A buffer corresponding to one slot time is then placed inside the RF receiver 102 to demodulate the received signal again with the reference signal obtained by applying the decision directing mode.

The multipath searcher 103 receives the input signal vector received for each antenna for a predetermined time, detects the multipath, estimates the delay time for each multipath signal, and then the rake finger 104 according to the estimated delay time. The delay time information is provided to each rake finger 104 and the reference signal generator 111.

Each rake finger 104 is largely comprised of a chip level beamformer 105 and a despreader 106, a channel estimator 107, a channel compensator 108, and a reference signal generator 111.

After being assigned the rake finger 104 from the multipath searcher 103, the input signal vector of the antenna enters the input of the chip level beamformer 105 of each rake finger 104.

Meanwhile, the chip level beam former 105 which receives the reference signal from the reference signal generator 111 calculates the beamforming weight vector in units of slots and multiplies the input signal vector of the antenna. As the beamforming algorithm, all algorithms requiring a reference signal such as a sample matrix inversion (SMI) algorithm, a normalized LMS (N-LMS), or a recursive least square (RLS) algorithm may be used.

The reference signal generator 111 is responsible for generating the reference signals used in the channel estimator 107 and the chip level beam former 105.

The despreader 106 is responsible for despreading the beamformed received signal from the chip level beamformer 105 to separate and demodulate the DPDCH and DPCCH transmitted by the desired user. In addition, the spreading signal and the scrambling code necessary to generate the chip level reference signal are provided to the reference signal generator 111.

The channel estimator 107 is responsible for estimating the channel from the desired user to the array antenna 101 using the DPCCH and pilot symbols despread from the despreader 106, and the channel compensator 108 performs a channel estimator ( It is responsible for compensating for the DPDCH and DPCCH of each rake finger 104 using the channel estimate estimated from 107.

The rake synthesizer 109 is responsible for synthesizing the DPDCH and DPCCH from each rake finger 104.

The discriminator (DPDCH, DPCCH) 110 is responsible for determining the sign of the DPDCH and DPCCH symbols synthesized from the rake synthesizer 109.

2 is a diagram illustrating an embodiment of a reference signal generator in a chip level beamformer based WCDMA smart antenna base station system having a decision directing mode according to the present invention.

As shown in FIG. 2, the reference signal generator 111 according to the present invention is a DPCCH slot configuration that forms a slot using a decision-oriented DPCCH symbol except a pilot symbol and a pilot symbol of a corresponding slot as a DPCCH-based reference signal. A symbol level reference signal generator 204 for generating a symbol level reference signal and a output signal of the symbol level reference signal generator 204, multiply the DPCCH channel code by 90 degrees, and multiply it by the scrambling code of the corresponding user. After that, the DPCCH-based chip level reference signal generator 203 for outputting the delayed by the corresponding multipath delay time to generate the DPCCH-based chip level reference signal, and the user's DPDCH channel code and scrambling corresponding to the decision-oriented DPDCH After multiplying the code, output by delaying by multipath delay time plus DPCCH based chip level reference signal And a chip-level reference signal generator 111 based on the DPDCH for generating a chip-level reference signal of the W-based DPDCH.

Here, the reference signal generator 111 according to the present invention is a DPDCH-based chip level reference signal generator 111, where the DPCCH-based reference signal generator 203 is operated when the decision-oriented DPDCH is not used, and the DPCCH slot configurator is operated. If only 201 passes, the symbol level reference signal generator 204 is operated.

That is, the mode of the DPDCH-based chip level reference signal generator 111 and the DPCCH-based chip level reference signal generator 203 is determined by a switch. For example, the switch is turned on when the DPDCH-based reference signal is generated to drive the DPDCH-based chip level reference signal generator 111, and is turned off when the DPCCH-based chip level reference signal is generated to be turned off (DPCCH-based chip level). The reference signal generator 203 is driven. On the other hand, irrespective of the switch, the symbol level reference signal is generated when only the DPCCH slot configurator 201 passes.

Now, the operation of the reference signal generator according to the present invention having the structure as described above will be described in detail.

The WCDMA smart antenna base station system requires a reference signal to be used in the channel estimator 107 and a reference signal to be used in the chip level beamformer 105.

The reference signal of the channel estimator 107 for reducing the channel estimation error is to use all the symbols in one slot of the DPCCH by applying the decision directing mode. The DPCCH-based symbol level reference signal is composed of one slot by adding a pilot, which is already known in the base station demodulator, of the one slot of the DPCCH through the DPCCH slot configurator 201 and adding a portion of the decision-oriented DPCCH except for the pilot. . For the 0 th user, the DPCCH based symbol level reference signal configured through the DPCCH slot configurator 201 for the n th slot may be represented by Equation 1 below.

Denotes the k th decision oriented DPCCH symbol of the 0 th user in the slot. Denotes the kth pilot in the nth slot of the 0th user, and N _pilot denotes the number of pilots in one slot corresponding to the DPCCH slot format of the 0th user.

In addition, there are two methods for generating a reference signal suitable for the chip level beamformer 105 to which the crystal directivity mode is applied.

In the first method, the DPCCH-based symbol level reference signal r _s configured through the DPCCH slot configurator 201 is a channel code of the DPCCH. Multiply by to make a phase change of 90 °, then multiply the scrambling code S (0) by the 0th user to create a chip-level signal. This is passed through the chip unit delay unit 202 to delay as much as the multipath delay time of each rake finger 104. This generates a chip level reference signal based on the DPCCH, and is configured using only the pilot and the decision-oriented DPCCH.

The second way, the decision-oriented DPDCH 0th user's channel code Times r _s , a symbol level reference signal based on DPCCH. Multiply by and add the 90 ° phase shift. Thereafter, a chip level signal is generated by multiplying the scrambling code s ⁽⁰⁾ of the 0 th user, and then passed through the chip unit delay unit 202 to delay the multipath delay time of each rake finger 104. . In this method, the chip level signal based on the DPCCH and the chip level signal based on the DPDCH are synthesized and used as a reference signal.

Channel code of the DPDCH in the above schemes Since the spreading coefficient may change according to the amount of data of the user, it may not be possible to generate a channel code at each rake finger 104 of the base station. In this case, despreading is performed with a spreading factor of 4, and a code having a spreading factor of 4 is also used to generate a reference signal. Since all of these codes are used in the despreader 106, the code written in the despreader 106 can be used as it is and no additional hardware implementation is required. The channel code of the DPCCH Since the spreading factor is 256 and the sequence is all '1', the code is already known by the base station, and the scrambling code of the 0th user is assigned a scrambling code by the base station before opening the call state with the 0th user. It may already be generated by the base station demodulator.

3 is a flowchart illustrating a method of operating a WCDMA smart antenna base station system based on a chip level beamformer having a decision directing mode according to the present invention, and a signal in a base station system of a baseband input signal vector corresponding to a 0 th slot. The process is shown.

As shown in FIG. 3, the dotted line in the figure corresponds to a preprocessing process to obtain a decision-oriented DPDCH and a decision-oriented DPCCH of the corresponding slot, and this process causes a delay of one slot. Therefore, in order to apply the decision-oriented mode, the baseband input signal vector of the corresponding slot must be stored in the buffer for each slot before performing the preprocessing process. The reference signal used in the preprocessing is generated using only the pilot. The reference signal used by the channel estimator 107 configures and uses one slot of the DPCCH using only pilot symbols, which can be expressed by Equation 2 below.

In the pre-processing process, the chip level beam former 105 multiplies the channel code of DPCCH by Equation 2 to change the phase to 90 °, and multiplies the scrambling code S ⁽⁰⁾ of the 0 th user to create a chip level signal. Thereafter, this is passed through the chip unit delay unit 202 and delayed as much as the multipath delay time of each rake finger 104 is used as the chip level reference signal.

The decision-oriented DPDCH and DPCCH obtained in the preprocessing process enter the input of the reference signal generator 111 described in FIG. 2 to generate a DPCCH-based symbol level reference signal and a chip level reference signal or a DPDCH-based chip level reference signal and store them in a buffer. It demodulates the baseband input signal vector of the corresponding slot.

The method of the present invention as described above may be implemented as a program and stored in a computer-readable recording medium (CD-ROM, RAM, ROM, floppy disk, hard disk, magneto-optical disk, etc.).

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

As described above, the present invention can not only increase the channel estimation effect through the WCDMA smart antenna base station system based on the chip level beam former having the crystal directivity mode, but also obtain the beamforming weight vector more accurately. In addition, it is possible to increase the system capacity and the coverage area of the base station.

In addition, since the codes used in the reference signal generator can use all the codes used in the despreader, the present invention does not require additional hardware implementation.

Claims (11)

A smart antenna base station system based on chip level beamformer, Signal conversion means for converting a signal received through the array antenna into a baseband signal; Multipath searching means for detecting multipath from the baseband signal of the signal conversion means and estimating a delay time of each path; Reference signal generating means for generating a reference signal for channel estimation and chip level beam forming on the basis of the multipath delay time information searched by the multipath searching means; Chip level beamforming means for generating a chip level beamforming weight vector and forming beams for each path based on the chip level reference signal of the reference signal generating means; Channel separation means for despreading the output of the chip level beam forming means to separate crystal directing channels (DPDCH, DPCCH); Channel estimating and compensating means for estimating a channel based on the decision directing control channel (DPCCH) of the channel separating means and the symbol level reference signal of the reference signal, and compensating the channel using the channel estimation value; Channel synthesis means for synthesizing the decision-oriented data channel (DPDCH) and the decision-oriented control channel (DPCCH) for each path; And Symbol discrimination means for discriminating a symbol for each decision-oriented channel Chip level beamformer based smart antenna base station system comprising a. The method of claim 1, The reference signal generating means, Receiving the DPDCH symbol, the DPCCH symbol, the pilot, the spreading code of the channel separating means, and the scrambling code determined by the symbol discriminating means, the symbol level reference signal to be used in the channel estimating means for the corresponding slot, and the chip level beam And a chip level reference signal based on the DPCCH and the chip level reference signal based on the DPDCH to be used in the forming means. The method of claim 2, The reference signal of the symbol level, A chip level beamformer based smart antenna base station system comprising a DPCCH slot configurator for forming a slot using a decision oriented DPCCH symbol excluding a pilot symbol and a pilot symbol of a corresponding slot. The method of claim 2, The DPCCH-based chip level reference signal, Based on the chip level beamformer, the output of the symbol level reference signal is multiplied by a DPCCH channel code, changed by 90 °, multiplied by the user's scrambling code, and delayed by the corresponding multipath delay time. Smart antenna base station system. The method of claim 2, The DPDCH-based chip level reference signal, Chip level beamformer based smart, characterized in that multiplying the decision-oriented DPDCH by the user's DPDCH channel code and scrambling code, and then delayed by the multipath delay time and the DPCCH-based chip level reference signal is output. Antenna base station system. A method for operating a smart antenna base station system based on a chip level beamformer, Converting a signal received through the array antenna into a baseband signal; Detecting a multipath from the converted baseband signal and estimating a delay time of each path to search for the multipath; Generating a reference signal for channel estimation and chip level beamforming based on the found multipath delay time information; A fourth step of generating a chip level beamforming weight vector based on the generated reference signal and despreading the output of the chip level beam former for forming beams for each path to separate the crystal directing channels (DPDCH and DPCCH); ; A fifth step of estimating a channel based on the separated decision oriented control channel (DPCCH) and the symbol level reference signal of the reference signal and compensating the channel using the channel estimate value; Synthesizing the decision-oriented data channel (DPDCH) and the decision-oriented control channel (DPCCH) for each path; And 7th step of determining a symbol for each decision-oriented channel Method of operation of a chip-level beamformer based smart antenna base station system comprising a. The method of claim 6, The reference signal of the third step, Receiving the DPDCH symbol, the DPCCH symbol, the pilot, the spreading code of the channel separating means, and the scrambling code determined by the symbol discriminating means, the symbol level reference signal to be used in the channel estimating means for the corresponding slot, and the chip level beam And generating the chip level reference signal based on the DPCCH and the chip level reference signal based on the DPDCH to be used in the forming means. A reference signal generator for channel estimation and chip level beamforming, First reference signal generating means for generating a symbol level reference signal including a DPCCH slot configurator for forming a slot using a decision oriented control channel (DPCCH) excluding a pilot symbol and a pilot symbol of the corresponding slot; According to the output signal of the first reference signal generating means, multiply the DPCCH channel code by 90 degrees, multiply by the scrambling code of the corresponding user, and output the delayed by the corresponding multipath delay time to output the DPCCH-based chip level reference signal. Second reference signal generating means for generating a signal; And After multiplying the DPDCH channel code and the scrambling code of the user corresponding to the decision-oriented data channel (DPDCH) by outputting the delayed by the multi-path delay time plus the DPCCH-based chip level reference signal to output the DPDCH-based chip level reference signal Third reference signal generating means for generating Reference signal generator for channel estimation and chip level beam forming comprising a. A method of generating a reference signal for channel estimation and chip level beamforming, A first step of generating a symbol level reference signal by configuring a slot using a decision oriented control channel (DPCCH) excluding a pilot symbol and a pilot symbol of the corresponding slot; A second step of generating a DPCCH-based chip level reference signal by outputting a multiplying DPCCH channel code by 90 degrees and multiplying the phase by 90 degrees according to the symbol level reference signal and multiplying the scrambling code of the corresponding user by the multipath delay time. step; And After multiplying the DPDCH channel code and the scrambling code of the user corresponding to the decision-oriented data channel (DPDCH) by outputting the delayed by the multi-path delay time plus the DPCCH-based chip level reference signal to output the DPDCH-based chip level reference signal 3rd step to generate Method for generating a reference signal for channel estimation and chip level beam forming comprising a. In a smart antenna base station system having a processor, A first function of converting a signal received through the array antenna into a baseband signal; A second function of detecting a multipath from the converted baseband signal and searching for the multipath by estimating a delay time of each path; A third function of generating a reference signal for channel estimation and chip level beamforming based on the found multipath delay time information; A fourth function of generating a chip level beamforming weight vector based on the generated reference signal and despreading the output of the chip level beam former for forming the beam for each path to separate the crystal directing channels (DPDCH, DPCCH); ; A fifth function of estimating a channel based on the separated decision oriented control channel (DPCCH) and the symbol level reference signal of the reference signal and compensating the channel using the channel estimate value; A sixth function of synthesizing the decision-oriented data channel (DPDCH) and the decision-oriented control channel (DPCCH) for each path; And 7th function for discriminating a symbol for each decision-oriented channel A computer-readable recording medium having recorded thereon a program for realizing this. In a reference signal generator having a processor, A first function of generating a symbol level reference signal by configuring a slot using a decision oriented control channel (DPCCH) excluding a pilot symbol and a pilot symbol of the corresponding slot; A second to multiply the DPCCH channel code by 90 degrees according to the symbol level reference signal, multiply it by 90 degrees, and multiply it with the scrambling code of the corresponding user, and output the delayed by the corresponding multipath delay time to generate the DPCCH based chip level reference signal function; And After multiplying the DPDCH channel code and the scrambling code of the user corresponding to the decision-oriented data channel (DPDCH) by outputting the delayed by the multi-path delay time plus the DPCCH-based chip level reference signal to output the DPDCH-based chip level reference signal 3rd function to generate A computer-readable recording medium having recorded thereon a program for realizing this.