KR100701766B1 - Frame synchronization method for mobile communication systems - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a frame synchronization method in a mobile communication system and a computer-readable recording medium having recorded thereon a program for realizing the method.

2. The technical problem to be solved by the invention

An object of the present invention is to provide a frame synchronization method for an MC-CDMA mobile communication system in an uplink asynchronous channel (or downlink synchronization channel) and a computer-readable recording medium having recorded thereon a program for realizing the method.

3. Summary of Solution to Invention

The present invention relates to a method for synchronizing frames at a receiving end of a multi-carrier code division multiple access (MC-CDMA) mobile communication system, comprising a transform and despreading (TD) time domain sequence using a user-spread spreading code from transmitted data symbols. And transform the input signal into the frequency domain using the TD time-domain sequence as the coefficient of the TD filter before despreading , where the output of the filter is the result of converting the input signal into the frequency domain. Same as output of transform and despread when entered- characterized in that the signal of the target user can be obtained by finding the maximum output instance of the TD filter for the target user.

4. Important uses of the invention

The present invention is used in MC-CDMA and the like under an uplink asynchronous transmission environment.

MC-CDMA, Uplink, Asynchronous Channel, Frame Sync, Data Symbol

Description

Frame synchronization method for mobile communication systems             

1 is an exemplary diagram illustrating a transmission process of an MC-CDMA mobile communication system for explaining a frame synchronization method according to the present invention.

2 is an exemplary view illustrating a reception process of an MC-CDMA mobile communication system for explaining a frame synchronization method according to the present invention.

3 is a signal distribution diagram of a frequency domain according to an embodiment of the present invention.

The present invention relates to a frame synchronization method for a code division multiple access (CDMA) mobile communication system in an uplink asynchronous channel (or downlink synchronization channel), and to a computer readable recording program for realizing the method. It relates to a recording medium.

Synchronization in the downlink channel uses the repeatability of the cyclic prefix, which can be used as the synchronization method in the orthogonal frequency division multiplexing (OFDM) method, but it is simultaneously asynchronously accessed by multiple users in the uplink channel. In this case, there is a problem that cannot be applied because the signals cannot be distinguished between users.

On the other hand, a method of inserting a special signal for frame synchronization in the first half of the frame may be applied, but in this case, there is a problem that the efficiency of the transmission signal has to be changed because the data structure of the transmission signal must be changed.

Therefore, a method that can be applied to multi-carrier code division multiple access (MC-CDMA: Multi-carrier CDMA) in an uplink channel is essential as a new frame synchronization scheme suitable for an asynchronous environment.

SUMMARY OF THE INVENTION The present invention devised to meet the above demands is directed to a computer recording a frame synchronization method for a MC-CDMA mobile communication system and a program for realizing the method in an uplink asynchronous channel (or downlink synchronization channel). The purpose is to provide a readable recording medium.

In order to achieve the above object, the present invention provides a method for synchronizing frames at a receiving end of a multi-carrier code division multiple access (MC-CDMA) mobile communication system. (TD) a time-domain sequence is obtained and the input signal is converted into a frequency domain using the TD time-domain sequence as a coefficient of the TD filter before despreading, wherein the output of the filter is a result of converting the input signal into the frequency domain, When the input signal enters the filter, the same as the output of the transformation and despreading , the signal of the target user can be obtained by finding the maximum output instance of the TD filter for the target user.

In addition, the present invention relates to a receiving end of a multi-carrier code division multiple access (MC-CDMA) mobile communication system having a processor for converting and despreading (TD) time domain sequences using user-spread spreading codes from transmitted data symbols. And convert the input signal into the frequency domain using the TD time-domain sequence as the coefficient of the TD filter before despreading , where the output of the filter is the result of converting the input signal into the frequency domain and the input signal enters the filter. Is the same as the output of the transformation and despreading when reading the maximum output instance of the TD filter for the target user, thereby reading a target user's signal. To provide.

The present invention proposes a new frame synchronization scheme for a CDMA mobile communication system in an uplink asynchronous channel. In this case, we introduce a time-domain sequence called TD (Transform and Despread) using a user-specific spreading code. The TD sequence is used as a coefficient of the TD filter, and the output of the TD filter corresponds to a result of converting an input signal into a frequency domain.

The frame synchronization process is divided into a Data-Aided (DA) acquisition process and a Non Data-Aided (NDA) tracking process. In the present invention, a signal of the target user can be obtained by proposing a TD sequence suitable for each process and finding an instance of the maximum output of the TD filter for the target user. This shows that the proposed frame synchronization scheme is effectively used in an asynchronous transmission environment.

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.

The MC-CDMA mobile communication system uses OFDM as a transmission method.

Therefore, as in an OFDM system, frame synchronization is very important and must be performed as the first process of demodulation at the receiver as in FIG.

A frame synchronization scheme designed for an OFDM system in a synchronous transmission environment in downlink may be applied using a cyclic prefix as a guard interval or using a synchronous burst signal. This is because the base station collects spread data of each user and transmits the data added as one OFDM signal.

However, although the mobile station can simultaneously transmit the user's data, each user's signal arrives at the base station with a different delay due to the difference in the transmission path.

In conclusion, the base station should be able to distinguish the signal of the user from the signal of the other user, and also to match the frame synchronization for each user's signal.

The frame synchronization technique using the cyclic prefix uses that the cyclic prefix is a repetition of the lower part of the OFDM frame. However, every user's signal in the uplink channel has its own cyclic prefix. And, this synchronization technique does not provide any way to distinguish the target user's data from other users.

Another way to use a synchronous burst signal is to distinguish data from each other user as long as each user has a unique synchronous burst sequence.

In contrast, in the present embodiment, the uplink asynchronous transmission environment is applied, but the same method may be applied to the downlink synchronization channel.

A block diagram of the system to be considered in this embodiment is shown in FIG. Consider an MC-CDMA system that uses N subcarriers in one frame and carries M symbols. Here, the diffusion factor SF is N / M.

The spread signal is multiplexed in the frequency domain, and the spread signal modulated by one symbol is transmitted on the subcarriers having the maximum frequency spacing for the benefit of frequency diversity.

The sample of the base signal to be transmitted in the j-th frame by the user i is expressed by Equation 1 below.

In Equation (1), a _{i, j} (m) represents the m th data symbol in the j th frame of the user i, 1 + j, 1-j, -1 + j, -1 having the same probability has one of -j (QPSK). And c _i (k) represents the spreading sequence of user i of length SF. Also, N _G is the number of samples in the guard interval used to remove the interference between symbols. This sample within the guard interval is the same as the lower part of the frame and is called the cyclic prefix. Figure 3 shows the distribution of the transmission signal in the frequency domain.

Then, the frame synchronization method at the receiving end for the MC-CDMA mobile communication system in the uplink asynchronous channel will be described in more detail.

If the frame synchronization method is largely divided into two stages, it may be divided into a process of acquiring a "data-aided" (DA) frame and a process of tracking a "non-data-aided" (NDA).

In the DA frame acquisition process, it is assumed that the receiver knows the transmitted data symbols. Using this line knowledge, the starting point of the MC-CDMA frame is obtained, after which the NDA tracking process begins.

In the NDA tracking process, the frame synchronizer finds a frame starting point in the vicinity of the region from which the frame is extracted, while the incoming signal carries user data, but the receiver does not know what is transmitted.

First, the DA acquisition process will be described in more detail.

In a code division multiple access (CDMA) mobile communication system, code acquisition can be obtained by correlating an incoming signal with a user specific spreading code. This can also be applied to MC-CDMA mobile communication systems.

However, in the MC-CDMA mobile communication system, the signal is spread in the frequency domain. Therefore, the signal input before despreading must be converted into the frequency domain.

In this embodiment, instead of using a complicated process of transform and despreading, a method of using a filter is proposed. That is, a transformed and despreading (TD) time domain sequence using a user-spread spreading code is obtained from the transmitted data symbols, and the input signal is transformed into a frequency domain using the TD time domain sequence as a coefficient of the TD filter before despreading ( At this time, the output of the filter is the result of converting the input signal into the frequency domain, and the same as the output of the transform and despread when the input signal enters the filter), by finding the maximum output instance of the TD filter for the target user, The signal of the target user can be obtained.

That is, the output of the filter is the same as the output of transform and despread when the input signal enters the filter. The coefficients for this filter make up a unique sequence for each user in the system. This user specific sequence, i.e. the transform and despread sequence TD, is given as a discrete Fourier transform of a spread signal made of suitable data symbols in the same way as signal generation at the transmitting end. The data symbol used in the TD sequence is a conjugate complex number of complex user data symbols known to the receiver. This filter, given its coefficients as a TD sequence, is hereinafter referred to as a TD filter.

Considering a system using 256 subcarriers and 32 spread length sequences, 8 symbols can be transmitted in one frame. The data symbols to be transmitted to the receiver in advance are (1 + j, -1-j, 1 + j, -1-j, 1 + j, -1-j, 1 + j, -1-j), and user i The TD sequence of is expressed as Equation 2 below.

In Equation 2, a ^* _i (m) is a conjugate complex number of the m th transmission symbol of user i known to the receiver. By using data symbols with cross phases, cross-carrier interference due to carrier frequency offset can be reduced.

When there is no frame mismatch with the signal input from user i, the output of the TD filter for user i is expressed as (Equation 3).

In equation (3), | c _i (k) | ² is equal to one. Assuming there is a frame shift and includes a portion of the guard interval of the frame, the output of the TD filter is expressed as (Equation 4).

는 1과 같다. 다른 사용자의 신호에 대한 TD 필터의 출력이 확산코드의 직교성에 의해 타겟 사용자의 것보다 훨씬 적다.In equation (4), n _d is the distance from the exact frame start point, and M · SF is equal to N. so,

Is equal to 1. The output of the TD filter for the signal of another user is much less than that of the target user due to the orthogonality of the spreading code.

Meanwhile, the NDA tracking process will be described in more detail as follows.

The frame start point may change depending on channel changes or possible sample clock offsets. Therefore, the receiver should be able to perform the synchronization process so that it can be continuously adapted to the time varying channel environment. This is the purpose of the tracking process.

In the NDA tracking process, the receiver does not assume to know the symbol to be transmitted, but assumes that the estimated frame start point is in the correct frame region. Since not all data symbols are known here, only one of the data symbols in a frame should be considered for conversion and despreading.

In the system under consideration, the spread signal for one symbol is carried out by subcarriers of the largest possible frequency interval. Therefore, the first of the data symbols to be transmitted in the frame is carried by the 0 ^th , 8 ^th , 16 ^th , ..., and 248 ^th subcarriers, and the second one is 1 ^th , 9 ^th , 17 ^th , .. , And 249 ^th subcarriers, the rest in this way.

For converting the received signal into the frequency domain and despreading it for the first symbol of user i, for user i the following TD sequence is needed.

The above sequence is the sum of sine waves, and the frequency of the sine wave that transmits the spread signal of the first data symbol corresponds to the subcarrier.

It can be seen that the above TD sequence is periodic and its period is SF. For other data symbols, the TD sequence is also periodic except for some phase rotation. Therefore, the first SF sample of the TD sequence only needs a TD filter instead of the full length TD sequence. That is, the delay line and the linear combiner, which is a filter having SF taps, may be replaced by a filter having N taps. This periodicity must be in the region of the correct frame, estimated by the previous step, and must be less than ± SF / 2 from the exact frame start.

The output of the NDA TD filter near the beginning of the exact frame is given in a manner similar to that of the DA TD filter in the acquisition process.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains, and the above-described embodiments and accompanying It is not limited to the drawing.

As described above, the present invention has an effect of providing an efficient frame synchronization scheme in an MC-CDMA mobile communication system in an asynchronous transmission environment.

Claims (4)

A method for synchronizing frames at a receiving end of a multi-carrier code division multiple access (MC-CDMA) mobile communication system, Obtaining the conversion and de-spread (TD) time-domain sequence using a user distinguish the spreading code from the transmitted data symbols, by the TD time-domain sequence by a factor of TD filter before despreading and converts the input signal into a frequency domain wherein, The output of the filter is the result of transforming the input signal into the frequency domain and is equal to the output of the transform and despread when the input signal enters the filter- by finding the maximum output instance of the TD filter for the target user, Frame synchronization method in a mobile communication system, characterized in that the user's signal can be obtained. The method of claim 1, The transform and despread (TD) time domain sequence is It is given by the discrete Fourier transform of a spreading signal made up of data symbols having a cross-phase in the same way as the signal generation at the transmitting end, wherein the data symbols used as the transform and despreading (TD) time domain sequences are complex user data known to the receiving end. A frame synchronization method in a mobile communication system, characterized in that it is a conjugate complex number of symbols. The method according to claim 1 or 2, The multi-carrier code division multiple access (MC-CDMA) mobile communication system, Frame synchronization method in a mobile communication system, characterized in that applicable to any one of an uplink asynchronous channel or a downlink synchronization channel environment. At the receiving end of a multi-carrier code division multiple access (MC-CDMA) mobile communication system having a processor, Obtaining the conversion and de-spread (TD) time-domain sequence using a user distinguish the spreading code from the transmitted data symbols, by the TD time-domain sequence by a factor of TD filter before despreading and converts the input signal into a frequency domain wherein, The output of the filter is the result of transforming the input signal into the frequency domain and is equal to the output of the transform and despread when the input signal enters the filter- by finding the maximum output instance of the TD filter for the target user, A computer-readable recording medium that records a program for realizing a function for obtaining a user signal.

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