KR100337388B1 - Apparatus for acquisition of synchronization of PN signal using multi-channel signal in digital communication system and method therefor - Google Patents

Abstract

The present invention relates to an apparatus and method for acquiring a code synchronization in a digital communication system, comprising: an access channel code generator for generating a reverse pilot channel code and an access information channel code from a reverse PN code; An access information channel precode generator for generating an access information channel precode included in the access information channel from a reverse PN code; A reception signal generator for generating an access channel reception signal from a reverse pilot channel code and an access information channel code; A reverse pilot channel correlator for obtaining a correlation coefficient between a reverse pilot channel code and an access channel received signal and outputting a pilot channel correlation coefficient; An access information channel correlator which calculates a correlation coefficient between the access information channel code and the access channel received signal and outputs an access channel correlation coefficient in consideration of the access information channel prefix; An energy calculator for outputting code correlation energy according to a pilot channel correlation coefficient and an access channel correlation coefficient; And a code synchronization control unit for finding a code synchronization by finding a maximum value among code correlation energies. A simpler circuit can acquire synchronization within a shorter time, and reduces power consumption during access channel transmission. Can increase the channel capacity.

Description

Apparatus for acquisition of synchronization of PN signal using multi-channel signal in digital communication system and method therefor}

The present invention relates to an apparatus and method for acquiring code synchronization using a multi-channel signal in a digital communication system, and more particularly, to a base station in a wireless local loop (WLL) system of the Telecommunications Technology Association (TTA). A code synchronization acquisition apparatus and a method thereof.

In a code division multiple access (CDMA) communication system, in order for a terminal station to make a call or answer a call of a base station, an access message must be transmitted to the base station through an access channel. In order to demodulate the access channel message transmitted by the terminal station from the base station, code synchronization must be performed between the base station and the terminal station.

In the Wireless Local Loop (WLL) system of the Telecommunications Technology Association (TTA), a base station transmits a pilot channel along with an access channel so that a base station can perform code synchronization with a terminal station. Use The base station obtains the code synchronization by adjusting the synchronization of the base station code by the energy obtained by accumulating a correlation coefficient between the terminal station code transmitted through the pilot channel and the code generated internally by the base station for a predetermined period. . This energy value is proportional to the cumulative interval of power and correlation coefficient of the pilot channel transmitted from the terminal station.

Generally, a method used for code synchronization acquisition in a CDMA system includes a method of using a matched filter and a method of using sequential searching. A method of using a matched filter is to find out whether there is a code pattern for a correlation coefficient accumulated in a base station in a code transmitted through a pilot channel, and a method of using a sequential search sequentially sequentially codes one by one. While generating, it compares the successive codes with the code transmitted through the pilot channel during the correlation coefficient accumulation period, and if they do not match, it adjusts the code that is generated locally until it matches.

The method of using a matched filter has the advantage that the synchronization acquisition time is short because the codes of the correlation coefficient accumulation section are compared at the same time, but the circuit becomes large in proportion to the length of the correlation coefficient accumulation section. The method of using sequential search has a disadvantage in that the synchronization acquisition time is long in proportion to the length of the correlation coefficient cumulative interval because only one code correlation is calculated during one code length. There is an advantage that can be kept relatively small.

In a system using a method of transmitting a pilot channel and an access channel together in a terminal station such as a WLL system, the power of the pilot is limited because the channel capacity is reduced when the power of the pilot is increased. When the power of the pilot is limited, the signal-to-noise ratio (SNR) is deteriorated. Therefore, in order to obtain synchronization, the cumulative correlation coefficient should be large enough so that the signal and noise can be sufficiently separated. In the terminal station, a matching filter is used for fast access channel synchronization, but the base station generally acquires synchronization of an access channel received through multiple paths simultaneously using antenna diversity or sector antenna. Therefore, it is difficult to apply a matched filter method.

SUMMARY OF THE INVENTION The present invention provides a synchronization acquisition device and method for acquiring code synchronization in a terminal station in a shorter time as a simpler circuit by using an access information prefix transmitted through an access information channel as well as a reverse pilot channel. To provide.

1 is a functional block diagram illustrating a receiver of a general digital communication system.

FIG. 2A illustrates a frame structure of a reverse access channel of the WLL system, and FIG. 2B illustrates a frame structure of an access information channel.

3 is a block diagram illustrating a PN signal synchronization acquisition unit according to the present invention.

4 is a diagram illustrating a detailed configuration of the access channel code generator 31 of FIG. 3.

FIG. 5 is a diagram illustrating a detailed configuration of the reverse pilot channel correlator 35 of FIG. 3.

FIG. 6 is a diagram showing the detailed configuration of the reverse access information channel correlator 36 of FIG.

FIG. 7 is a diagram illustrating a detailed configuration diagram of the correlation coefficient accumulation unit 37 and the energy calculation unit 38 of FIG. 3.

8 is a graph for explaining the effect of the present invention.

In the digital communication system according to the present invention for achieving the above technical problem, the synchronous acquisition device of the spread signal,

An access channel code generator for generating a reverse pilot channel code and an access information channel code from the reverse PN code; An access information channel precode generator for generating an access information channel precode included in the access information channel from a reverse PN code; A reception signal generator for generating an access channel reception signal from the reverse pilot channel code and the access information channel code; A reverse pilot channel correlator for obtaining a correlation coefficient between the reverse pilot channel code and an access channel received signal and outputting a pilot channel correlation coefficient; An access information channel correlator which obtains a correlation coefficient between the access information channel code and an access channel received signal and outputs an access channel correlation coefficient in consideration of the access information channel prefix; An energy calculator configured to output a code correlation energy according to the pilot channel correlation coefficient and the access channel correlation coefficient; And a code synchronization controller for finding code synchronization by finding a maximum value among code correlation energies output from the energy calculation unit.

In the digital communication system according to the present invention for achieving the above technical problem, a synchronization signal acquisition method of the spread signal,

Generating a reverse pilot channel code and an access information channel code from the reverse PN code; Generating an access information channel prefix included in the access information channel from the reverse PN code; Generating an access channel received signal from the reverse pilot channel code and the access information channel code; Obtain a correlation coefficient between the reverse pilot channel code and the access channel received signal, output a pilot channel correlation coefficient, and obtain a correlation coefficient between the access information channel code and the access channel received signal in consideration of the access information channel prefix. Outputting a channel correlation coefficient; Outputting code correlation energy according to the pilot channel correlation coefficient and the access channel correlation coefficient; And finding a code synchronization by finding a maximum value among the code correlation energies.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

1 is a functional block diagram illustrating a receiver of a general digital communication system. PN signal synchronization is performed in two steps. In the first stage of synchronous acquisition, the received PN signal and the PN signal generated at the receiving end fall within one chip or less. In the second step, synchronization tracking, fine adjustments are made to match the phases of the two signals above.

The receiver performs PN synchronization acquisition, PN synchronization tracking, carrier recovery / tracking, band despreading, and signal demodulation. When the function of the PN signal synchronization acquisition unit 13 is performed Is generated. here, to be.

In order for the phase τ to be a value in the range of (τ ₁ -ΔT _c , τ ₁ + ΔT _c ), the synchronization acquisition unit 13 searches a series of phases and determines the value having the greatest correlation with the input PN signal. When the phase in the receiver is determined by the value in ΔT _c of the input signal, the PN signal synchronization tracking unit 12 attempts to set the phase difference to zero using a feedback loop circuit or the like. Carrier signal recovery / tracking unit 11 is a carrier signal from the input signal Extract The carrier signal obtained here and the PN signal obtained from the synchronization tracking section 12 are the estimated values of the data b (t) in the despreading / demodulation section 14. It is used in the despreading and demodulation process to obtain.

2A is a diagram illustrating a frame structure of a reverse access channel of a WLL system. The reverse channel includes an access channel and a reverse traffic channel. In the reverse traffic channel, there is a single signal mode using one terminal station for one user and a multiple signal mode using multiple terminal users connected to one terminal station. The access channel is composed of a reverse pilot channel 21 and a reverse access information channel 22, and up to 32 access information channels can be allocated to one paging channel.

The frame length of the access channel must satisfy 100 mod (ACCESS_ACQ_FRAMES + ACCESS_MSG_FRAMES) = 0. Information related to ACCESS_ACQ_FRAMES 23 and ACCESS_MSG_FRAMES 24 is received through a system information message of a paging channel. During the ACCESS_ACQ_FRAMES 23, the reverse access prefix is transmitted to the base station through the reverse access information channel. During this time, the base station detects the access channel and collects information for code synchronization and carrier synchronization. During the ACCESS_MSG_FRAMES 24, the reverse pilot channel and the access information channel are simultaneously transmitted to the base station. During this time, the base station obtains message information of the access channel.

(ACCESS_ACQ_FRAMES + ACCESS_MSG_FRAMES) The time is called an access channel slot (ACS). ACS should be aligned at 20 MS_BST, and ACS boundary should always be located at 2 S_BST. 2 The slot number of ACS starting from S_BST is 0.

The reverse pilot channel 21 transmits only '0' symbols. Through this channel, the base station obtains code synchronization and carrier phase synchronization information of an access channel. The reverse pilot channel 21 is direct sequence spread spectrum (DS / SS).

2B is a diagram illustrating a frame structure of an access information channel. The length of one frame of the access information channel is 160 bits (20ms), and one frame includes an encoder tail bit 28 composed of 152 bits of information bits 27 and 8 bits of '0' symbols. have. Encoder tail bits 28 should be at the end of the frame. The access information channel is convolutional channel coded.

The access information channel prefix consists of 20 ms frames. One frame consists of 160 bits of zeros. This code is transmitted along with the reverse pilot channel to the base station so that the base station can obtain the code synchronization and carrier phase information of the access channel of the terminal station. This prefix is transmitted to the base station for the first (20 x ACCESS_ACQ_FRAMES) ms of the ACS.

During ACCESS_ACQ_FRAMES, the terminal station sends the access information channel prefix to the base station through the access information channel, during which time the base station detects the access channel and collects information for code synchronization and carrier synchronization. During ACCESS_MSG_FRAMES, the terminal station transmits access information channel data to the base station, during which time the base station obtains access channel message information. In order for the base station to obtain the code synchronization and obtain the access channel message transmitted by the terminal station, it is important to obtain the code synchronization quickly because the base station must acquire the code synchronization transmitted through the pilot channel during ACCESS_ACQ_FRAMES.

3 is a block diagram illustrating a PN signal synchronization acquisition unit according to the present invention.

The access channel code generator 31 generates the reverse pilot channel I and Q channel codes and the access information channel I and Q channel codes from the reverse PN codes. The access information channel precode generator 32 generates the access information channel precode included in the access information channel from the reverse PN code. The I-channel received signal generator 33 generates an access channel I-channel received signal from the reverse pilot channel I channel code and the access information channel I channel code. The Q channel receive signal generator 34 generates an access channel Q channel received signal from the reverse pilot channel Q channel code and the access information channel Q channel code.

The reverse pilot channel correlator 35 obtains a correlation coefficient between the reverse pilot channel I and Q channel codes and the access channel I and Q channel received signals and outputs pilot I and Q channel correlation coefficients. The access information channel correlator 36 calculates a correlation coefficient between the access information channel I and Q channel codes and the access channel I and Q channel reception signals in consideration of the access information channel prefix, and outputs the access I and Q channel correlation coefficients.

The correlation coefficient accumulator 37 adds the pilot I channel correlation coefficient and the access I channel correlation coefficient and accumulates the added value for a predetermined period of time to output the I channel cumulative correlation coefficient, and outputs the pilot Q channel correlation coefficient and the access Q. The channel correlation coefficient is added and the accumulated value is accumulated for a predetermined time to output the Q channel accumulation correlation coefficient. The energy calculation unit 38 squares the I channel cumulative correlation coefficient, squares the Q channel cumulative correlation coefficient, and adds them to output the code correlation energy.

The code synchronization control unit 39 accumulates the correlation coefficient for the correlation coefficient accumulation period N and calculates the energy when the accumulation is completed, and the access channel code generator 31 whenever the correlation coefficient accumulation control signal N becomes the correlation coefficient accumulation period N. ) Generates a code generation control signal to delay the code by one code. The maximum value is found from the code correlation energy z (k) output from the energy calculation unit 38 to find the correct code synchronization.

In the code synchronization acquisition process at the base station, the energy is accumulated by accumulating the correlation coefficient for the accumulated period N for all possible code times corresponding to the radius of the base station, and the maximum code time is the code synchronization time of the terminal. . Therefore, the maximum time required for synchronization acquisition is proportional to the radius of the base station and the correlation accumulated time N.

Here, the access channel I channel received signal r _I (k) and the access channel Q channel received signal r _Q (k) are represented by the following equations (1) and (2). In this equation, however, it is assumed that there is no error in the frequency and phase of the carrier.

In Equations 1 and 2, E _p is the power of the pilot channel, p _I (k) is the pilot channel I channel code, E _a is the power of the access channel, d (n) is the data of the access information channel, a _I ( k) is the access information channel I channel code, n _I (k) is the noise of the I channel, p _Q (k) is the pilot channel Q channel code, a _Q (k) is the access information channel Q channel code, and n _Q ( k) represents the noise of the Q channel.

Since the access information channel prefix d (k) is defined in the WLL system standard as described above, it is possible to predict and generate the access information channel prefix corresponding to the time K.

4 is a diagram illustrating a detailed configuration of the access channel code generator 31 of FIG. 3.

The access channel code generator receives a reverse PN code to generate a reverse pilot channel code and an access information channel code, and includes a pilot channel code generator 41 and an access information channel code generator 45. The pilot channel code generator 41 multiplies the reverse PN code by the Hadamard code 0 by the multiplier 42 to generate the reverse pilot channel I channel code pI (k), and the reverse PN code by the multiplier 43. Multiply by Hadamard code 1 to generate the reverse pilot channel Q channel code pQ (k). The access information channel code generator 45 multiplies the reverse PN code by the Hadamard code 2 by the multiplier 46 to generate the access information channel I channel code aI (k) and the reverse PN by the multiplier 47. The code is multiplied by the complement of Hadamard code 3 to generate the access information channel Q channel code aQ (k). The reverse PN code is used to distinguish users, and the Hadamard code is used to distinguish I and Q channels of the reverse pilot channel and the I and Q channels of the access information channel.

5 is a diagram showing a detailed configuration of the reverse pilot channel correlator 35 of FIG.

The reverse pilot channel correlator receives the access channel I channel received signal r _I (k) and the access channel Q channel received signal r _Q (k), and the reverse pilot I channel code p _I (k) and the reverse pilot received at the base station at time k. Pilot I channel correlation coefficient with Q channel code p _Q (k) as input And pilot Q-channel correlation coefficients Outputs

Pilot I-channel correlation coefficient Multiplies the access channel I channel received signal r _I (k) by the multiplier 51 and the reverse pilot I channel code p _I (k), and also multiplies the access channel Q channel received signal r _Q (k) by the multiplier 52. Multiply the inverse pilot Q-channel code p _Q (k) and then add these outputs to each other in the adder 53.

Pilot Q channel correlation coefficient Multiplies the access channel I channel received signal r _I (k) by the multiplier 57 and the reverse pilot Q channel code p _Q (k), and also multiplies the access channel Q channel received signal r _Q (k) by the multiplier 56. And multiply the reverse pilot I channel code -p _I (k) inverted by the inverter 55, and then add these output values to each other in the adder 58.

Pilot I-channel correlation coefficient output of the reverse pilot channel correlator And pilot Q-channel correlation coefficients Is expressed by the following formula (3) and (4).

In Equation 3, 4, Is the pilot I-channel correlation coefficient at time k, Is the autocorrelation function of the pilot channel code, Is a correlation function of the pilot channel code and the access information channel code, and Is influenced by the noise of the pilot channel code and I channel, Is the pilot Q-channel correlation coefficient at time k, and Denotes the influence of the pilot channel code and the Q channel noise. here, Denotes a code time error between the terminal station and the base station.

Is a characteristic of pilot channel code Is a function that has a maximum value when is zero, that is, when there is no code time error between the terminal station and the base station. The farther away from zero the value rapidly converges to zero. Since the pilot channel code and the access information channel code are distinguished by different Hadamard codes having orthogonality, if the cumulative Hadamard code periods are accumulated, the value becomes zero.

FIG. 6 is a diagram illustrating a detailed configuration of the reverse access information channel correlator 36 of FIG. 3, which is similar to the structure of the reverse pilot channel correlator of FIG. 5, but allows an access information channel to obtain code synchronization through an access information channel. The difference is that the precode is multiplied by the received signal.

The backward access information channel correlator receives the access channel I channel received signal r _I (k) and the access channel Q channel received signal r _Q (k), the access information channel I channel code a _I (k) and the access received at the base station at time k. Access I channel correlation coefficient with input of information channel Q channel code a _Q (k) and access information channel prefix d (k) And access Q-channel correlation coefficients Outputs

Access I channel correlation coefficient The multiplier 62 multiplies the access channel I channel received signal r _I (k) by the access information channel prefix d (k) and multiplies the multiplier 64 by the access information channel I channel code a _I ( k), and the multiplier 63 multiplies the access channel Q channel received signal r _Q (k) by the access information channel prefix d (k), and then multiplies the multiplier 65 by the access information channel Q. Multiply by the channel code a _Q (k) and obtain the outputs of the multipliers 64, 65 by adding to each other in the adder 66.

Access Q channel correlation coefficient Multiplies the access channel I channel received signal r _I (k) by the multiplier 62 and the access information channel prefix d (k) and then multiplies the multiplier by the access information channel Q channel code a _q ( k), and the multiplier 63 multiplies the access channel Q channel received signal r _Q (k) by the access information channel prefix d (k), and then multiplies the multiplier 68 by the multiplier 68. Multiply the access information channel I channel code -a _I (k) inverted by & lt _; RTI ID = 0.0 > and & lt _; / RTI >

Access I-channel correlation coefficient that is the output of the access information channel correlator And access Q-channel correlation coefficients Is expressed by the following equations 5 and 6.

In Equation 5, 6, Is the access I-channel correlation coefficient at time k, Is an autocorrelation function of an access information channel code, Is influenced by noise of access information channel code and I channel, Is the access Q-channel correlation coefficient at time k, and Denotes the influence of noise of the access information channel code and the Q channel. here, Denotes a code time error between the terminal station and the base station.

Is Similar to the nature of the access channel code Is a function that has a maximum value when is zero, that is, when there is no code time error between the terminal station and the base station. The farther away from zero the value rapidly converges to zero.

FIG. 7 is a diagram illustrating a detailed configuration diagram of the correlation coefficient accumulation unit 37 and the energy calculation unit 38 of FIG. 3.

The correlation coefficient accumulator 71 is a pilot I-channel correlation coefficient in the adder 72 And access I-channel correlation coefficient Cumulative correlation coefficient by accumulating the accumulator 74 and accumulating it for a predetermined time N. And the pilot Q channel correlation coefficient in the adder 73 And access Q-channel correlation coefficient The cumulative correlation coefficient of the Q channel is added by accumulating and accumulating it in N for a predetermined time. Outputs

I-channel cumulative correlation coefficient And Q-channel cumulative correlation coefficient Is represented by the following equations (7) and (8).

here, Since N has a characteristic that if it accumulates as the period of Hadamard code, it becomes zero, so if N is a multiple of the code period, the value accumulated for N time becomes zero. Indicating the effect of noise Since N has a random characteristic, if N is large enough, the value accumulated during N becomes zero.

The energy calculator 76 calculates the I-channel cumulative correlation coefficient in the squarer 77. Squared and the Q-channel cumulative correlation coefficient at squarer (78) Squared and then added to the adder 79 to output a code correlation energy value z (k), which is expressed by Equation (9).

here, Indicates the effect of noise.

The magnitude of the code correlation energy increases as the power of the reverse pilot channel increases, the power of the access information channel increases, and as time N accumulates the correlation coefficient increases.

When the code correlation energy value is obtained using only the reverse pilot channel according to the conventional method, the influence of the access information channel Since the terms associated with are zero, the value is greatly reduced. There is no influence of noise, and the power of the reverse pilot channel is the same as that of the access information channel. Wow Is assumed to be equal, the code correlation energy obtained according to the present invention is increased by up to four times compared to the code correlation energy according to the conventional scheme. Therefore, while the correlation coefficient cumulative section N is halved compared with the conventional one, the same effect as the conventional one can be obtained. In the WLL system, since the reverse pilot channel code and the access information channel code differ only by the Hadamard code, Wow Represents almost the same value. In general, since the power of the access information channel is higher than that of the reverse pilot channel, the maximum value of the code correlation energy according to the present invention becomes larger than in the related art.

8 is a graph for explaining the effect of the present invention, and shows the relationship between the power (%) and the ratio of code correlation energy (dB) of the reverse pilot channel. In the figure, the horizontal axis represents the power of the reverse pilot channel as a percentage of the power of the entire received signal, and the vertical axis represents the ratio of the code correlation energy when the code synchronization matches the code correlation energy when the code synchronization does not match. It is expressed in dB. The correlation coefficient cumulative time N is set to 1024, and the power of the access information channel is assumed to be the same as that of the reverse pilot channel. In the figure, reference numeral 81 denotes a case according to a conventional scheme, and reference numeral 82 denotes a case according to the present invention.

As shown, according to the present invention, a larger code correlation energy value can be obtained for all intervals compared to the conventional method using only the pilot channel. Therefore, the same effect can be obtained with a shorter correlation accumulation time than the conventional method, and the time required for acquisition of synchronization can be reduced as the correlation accumulation time is reduced. In addition, when the correlation is accumulated for the same time as the conventional method, the present invention can achieve the same effect even with a smaller reverse pilot channel power, thereby reducing power consumption of the terminal station. Increasing capacity of the reverse channel can also be expected.

According to the synchronization acquisition apparatus and method according to the present invention as described above, by obtaining the code synchronization in the terminal station using the access information prefix transmitted through the access information channel as well as the reverse pilot channel, even a simpler circuit The synchronization can be obtained within a short time, and the base station can transmit the access channel using lower power, thereby reducing the power consumption of the access channel and increasing the channel capacity of the base station.

Claims (5)

An access channel code generator for generating a reverse pilot channel code and an access information channel code from the reverse PN code; An access information channel precode generator for generating an access information channel precode included in the access information channel from a reverse PN code; A reception signal generator for generating an access channel reception signal from the reverse pilot channel code and the access information channel code; A reverse pilot channel correlator for obtaining a correlation coefficient between the reverse pilot channel code and an access channel received signal and outputting a pilot channel correlation coefficient; An access information channel correlator which obtains a correlation coefficient between the access information channel code and an access channel received signal and outputs an access channel correlation coefficient in consideration of the access information channel prefix; An energy calculator configured to output a code correlation energy according to the pilot channel correlation coefficient and the access channel correlation coefficient; And And a code synchronization control unit for finding code synchronization by finding a maximum value among code correlation energies output from the energy calculation unit. The method of claim 1, wherein the code synchronization control unit A correlation coefficient accumulating unit and an energy calculating unit are controlled to accumulate a correlation coefficient during the accumulation period, and calculate a code correlation energy when the accumulation is completed, and generate a code by delaying one code for each accumulation period N. And a spreading signal acquisition device in a digital communication system, characterized in that the access channel code generator is controlled. The method of claim 1, wherein the reverse pilot channel correlator The pilot I-channel correlation coefficient is obtained by multiplying the access channel I-channel received signal by the reverse pilot I-channel code, multiplying the access channel Q-channel received signal by the reverse pilot Q-channel code, and then adding these outputs together. The pilot Q channel correlation coefficient is obtained by multiplying the access channel I channel received signal by the reverse pilot Q channel code, and also multiplying the access channel Q channel received signal by the inverted reverse pilot I channel code, and then adding these output values together. Synchronous acquisition device of spreading signal in a digital communication system. The method of claim 1, wherein the access information channel correlator The access I channel correlation coefficient is obtained by multiplying the access channel I channel received signal by the access information channel prefix and multiplying the multiplied value by the access information channel I channel code to obtain a first value. Also, the access channel Q channel received signal and the access information channel Multiply the prefix and then multiply the result by the access information channel Q channel code to obtain a second value, and add the first and second values to each other, The access Q channel correlation coefficient is obtained by multiplying the access channel I channel received signal by the access information channel prefix and multiplying the multiplied value by the access information channel Q channel code to obtain a third value, and also access channel Q channel received signal and access information channel. Acquiring a fourth value by multiplying the transposed code and multiplying the multiplied value by the inverted access information channel I channel code, and adding the fraudulent third and fourth values to each other to obtain synchronous acquisition of a spread signal in a digital communication system. Device. Generating a reverse pilot channel code and an access information channel code from the reverse PN code; Generating an access information channel prefix included in the access information channel from the reverse PN code; Generating an access channel received signal from the reverse pilot channel code and the access information channel code; Obtain a correlation coefficient between the reverse pilot channel code and the access channel received signal, output a pilot channel correlation coefficient, and obtain a correlation coefficient between the access information channel code and the access channel received signal in consideration of the access information channel prefix. Outputting a channel correlation coefficient; Outputting code correlation energy according to the pilot channel correlation coefficient and the access channel correlation coefficient; And And finding a code synchronization by finding a maximum value among the code correlation energies.