KR20050062973A - Apparatus for frequency domain equalization in mobile communication system using code division multiplexing and method thereof - Google Patents

Abstract

The present invention relates to a mobile communication system for communicating by a code division multiple access method between a predetermined base station and one or more terminals within a cell area covered by the base station. A method of classifying channels and transmitting a code division multiplexed signal for each channel, the method comprising: determining whether to transmit gating of the signal according to a channel state between the base station and the terminals; And gating and transmitting the transmission signal.

Description

Apparatus and method for frequency domain equalization in code division multiplexing mobile communication system {APPARATUS FOR FREQUENCY DOMAIN EQUALIZATION IN MOBILE COMMUNICATION SYSTEM USING CODE DIVISION MULTIPLEXING AND METHOD THEREOF}

The present invention relates to a mobile communication system, and more particularly, to an apparatus and method for transmitting and receiving data in a mobile communication system using a code division multiplexing scheme.

The 3rd Gereration mobile communication system is aimed at supporting multimedia services such as data and video, away from mobile communication as a simple means of voice transmission. However, due to the explosive growth of the Internet and the remarkable development of the wired network, the user's requirements are much higher than before, and the 3rd generation mobile communication system is not satisfying the user, and commercialization is sluggish.

Hereinafter, a conventional general third generation mobile communication method will be described with reference to FIGS. 1 to 3.

1 is a diagram illustrating a transmitter structure of a general code division multiplexing system.

Referring to FIG. 1, first, data of each channel u ₁ , u _2, and u ₃ to be transmitted are input to channel encoders 101a to 101n and channel encoded. The channel-specific data may be signals such as a pilot channel, a common channel, a circuit channel, and a packet channel. The channel encoders 101a to 101n are encoding apparatuses for increasing the transmission rate of input data, for example, convolutional encoding, turbo encoding, and low density parity check encoding. And the like can be used.

The data encoded by the channel encoders 101a through 101n are interleaved through the interleavers 103a through 103n, and spread through the spreaders 105a through 105n, respectively. In this case, each of the spreaders 105 serves to spread the input signal by multiplying an input signal by an orthogonal code having a predetermined length. Further, by multiplying different orthogonal codes by the respective spreaders, the receiving side distinguishes transmission data by the orthogonal code used at the transmitting side. As the orthogonal code, a Walsh code or an Orthogonal Variable Spreading Factor (OVSF) code may be used.

The transmission data spread by the orthogonal codes through the respective spreaders 105a through 105n are synthesized by a predetermined signal synthesizer 107 and multiplied by a predetermined scramble code by the multiplier 109 to perform an antenna 111. Is transmitted to the receiving side through.

That is, the above-described downlink CDMA system mixes and transmits data of the various channels by a code division multiplexing scheme that separates each channel signal by orthogonal codes.

2 is a diagram illustrating a channel structure using an OVSF code in a general code division multiplexing scheme.

Referring to FIG. 2, in the code division multiplexing scheme, classification of each channel is performed by the orthogonal code described above with reference to FIG. For example, in the high-speed packet transmission system such as the above-described Evolution Data and Voice (EVDV) and High-Speed Downlink Packet Access (HSDPA), a pilot channel channel, a common channel, Shared code channels (e.g., Walsh codes for EVDV systems, OVSF codes for HSDPA systems), etc., are used for the circuit channels (Circuit Channel). Packet data channel (PDCH) in EVDV system and downlink shared channel (HS-DSCH) in HSPDA system are allocated to transmit data in time division multiplexing.

3 is a diagram illustrating a receiver structure of a general code division multiplexing system.

Referring to FIG. 3, the CDMA receiver has a form of a rake receiver and despreads and combines a signal received through the antenna 301 through a plurality of fingers 303a to 303n. do. The fingers are configured to receive each received signal received by a transmission signal through a multipath according to each path, and each finger 303a to 303n receives an orthogonal code for each channel used during the transmission. To despread the received signal.

The multipath signals despread by each of the fingers are combined at a combiner 305 and deinterleaved at a deinterleaver 307 according to an interleaving method by an interleaver 103 at a transmitting side. Interleaving The deinterleaved signal is decoded by a channel decoder 309 according to a channel coding scheme of the transmitting side.

In the above-described CDMA system, down-link signals are high-speed data in a high order modulation method (for example, 16QAM, 64QAM, etc.) for a user located in a good channel state such as near a base station. Although transmission is implemented, there is a problem that interference by multi-path reduces the performance of the rake receiver described above, making high-speed transmission difficult.

On the other hand, synchronous Evolution Data and Voice (cdma2000 1x Release C) and asynchronous HSDPA (High-Speed Downlink Packet Access, 3GPP WCDMA Release 5), the 3rd generation mobile communication standards to date, are both code division multiple access ( Code Division Multiple Access (hereinafter referred to as 'CDMA') scheme, which uses Code Division Multiplexing (hereinafter referred to as 'CDM') scheme for high speed data transmission. It has a fatal weakness that it is vulnerable to multipath interference. Accordingly, research into direct generation to the fourth generation is being actively conducted due to the sluggishness of the third generation mobile communication, and most of them consider a physical layer different from the CDMA.

Currently, the most attention-oriented method of the fourth generation mobile communication physical layer is orthogonal frequency division multiplexing (hereinafter, referred to as 'OFDM'). The OFDM scheme is considered to be an excellent system in an environment in which there are many multipath interferences by implementing an efficient equalizer using a fast Fourier transform (hereinafter, referred to as 'FFT').

The OFDM method is a method of transmitting data using a multi-carrier, and a plurality of sub-carriers having mutual orthogonality to each other by converting symbol strings serially input in parallel. ), That is, a type of multi-carrier modulation (MCM) that modulates and transmits a plurality of sub-carrier channels.

The system applying the multicarrier modulation scheme was first applied to military HF radio in the late 1950s, and the OFDM scheme of overlapping a plurality of orthogonal subcarriers started to develop in the 1970s, but the implementation of orthogonal modulation between subcarriers was implemented. Since this was a difficult problem, there was a limit to the actual system application. However, in 1971, Weinstein et al. Announced that modulation and demodulation using the OFDM scheme can be efficiently processed using a Discrete Fourier Transform (DFT). In addition, the use of guard intervals and the insertion of cyclic prefix (CP) guard intervals have become known, further improving the system's negative effects on multipath and delay spread. Was reduced.

Accordingly, the OFDM scheme is applied to digital transmission technologies such as digital audio broadcasting (DAB), digital television, wireless local area network (WLAN), and wireless asynchronous transfer mode (WATM). It is widely applied. In other words, due to hardware complexity, it is not widely used, but is recently called a Fast Fourier Transform (FFT) and an Inverse Fast Fourier Transform (IFFT). Various digital signal processing technologies, including the above, can be realized.

Although the OFDM scheme is similar to the conventional Frequency Division Multiplexing (FDM) scheme, the OFDM scheme maintains orthogonality among a plurality of subcarriers and transmits the optimal transmission efficiency in high-speed data transmission. In addition, the frequency usage efficiency is good and multi-path fading is strong, so that the optimum transmission efficiency can be obtained in high-speed data transmission.

In addition, because the frequency spectrum is superimposed, frequency use is efficient, strong in frequency selective fading, strong in multipath fading, and protection intervals can be used to reduce the effects of inter symbol interference (ISI). In addition, it is possible to simply design the equalizer structure in terms of hardware and has the advantage of being resistant to impulsive noise, and thus it is being actively used in the communication system structure.

On the other hand, the OFDM scheme is capable of high-speed data transmission compared to the CDMA scheme, but until now, it has been mainly used in a stationary wireless communication system and has not been verified whether it can be used without problems in a cellular system. In addition, the CDMA system has an advantage of supporting a large cell radius, a large delay spread, and a high-speed mobile while operating at a frequency reuse factor of 1, but such an extreme in the OFDM system. It is not very easy to support the environment.

Accordingly, a lot of researches have been conducted to combine the above two schemes to support both the performance of the OFDM scheme in a good environment and the flexibility of the CDMA scheme in a poor environment.

Combining methods of the OFDM scheme and the CDMA scheme, which are currently discussed, include a multi-carrier-CDMA (hereinafter referred to as MC-CDMA) scheme and a frequency-hopping OFDM scheme. FH-OFDM '), and most of the proposed schemes try to have the characteristics of CDMA at the cell border based on OFDM. However, since the methods are based on the OFDM scheme, it is still difficult to simultaneously support large cell radius, large delay spread, high-speed mobile, and frequency recycling efficiency 1 which are advantages of the above-described CDMA scheme.

Accordingly, an object of the present invention is to provide a transmission and reception apparatus and method for supporting high-speed data transmission using frequency domain equalization in a code division multiplexing mobile communication system.

It is also an object of the present invention to provide a fast data transmission / reception apparatus and method that is resistant to multipath interference using frequency domain equalization in a code division multiplexing mobile communication system.

The transmission method of the present invention for achieving the above object; In a mobile communication system in which a predetermined base station communicates with one or more terminals within a cell area covered by the base station in a code division multiple access scheme, one or more channels are classified according to the type of data to be transmitted and the receiving terminals. A method of transmitting a code division multiplexed signal for each channel, the method comprising: determining whether to transmit the gating of the signal according to a channel state between the base station and the terminals, and gating the transmission signal according to the determination. Characterized in that the transmission process.

Receiving method of the present invention for achieving the above object; In a mobile communication system in which a predetermined base station communicates with one or more terminals within a cell area covered by the base station in a code division multiple access scheme, one or more channels are classified according to the type of data to be transmitted and the receiving terminals. A method of receiving a signal transmitted by code division multiplexing for each channel, the method comprising: determining an equalization method of a received signal according to a channel state between the base station and a terminal; and performing channel equalization in a frequency domain according to the determination. And despreading the channel equalized signal in the frequency domain by a finger.

The transmission device of the present invention for achieving the above object; In a mobile communication system in which a predetermined base station communicates with one or more terminals within a cell area covered by the base station in a code division multiple access scheme, one or more channels are classified according to the type of data to be transmitted and the receiving terminals. In the apparatus for transmitting the code division multiplexed signal for each channel, a controller for determining whether or not gating transmission of the signal in accordance with the channel state between the base station and the terminals, and by gating the transmission signal according to the determination of the controller And a signal interrupter for transmitting.

The receiving device of the present invention for achieving the above object; In a mobile communication system in which a predetermined base station communicates with one or more terminals within a cell area covered by the base station in a code division multiple access scheme, one or more channels are classified according to the type of data to be transmitted and the receiving terminals. An apparatus for receiving a signal transmitted by code division multiplexing for each channel, the apparatus comprising: a controller for determining an equalization method of a received signal according to a channel state between the base station and a terminal; and in a frequency domain according to an equalization method of the controller And a finger for despreading the channel equalized signal in the frequency domain by the frequency domain receiver.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted without departing from the scope of the present invention.

The present invention proposes a new physical layer (Physical Layer) method that can be used in the fourth generation mobile communication system. The method according to the present invention combines the advantages of the above-described OFDM scheme and the CDMA scheme, but is based on the CDMA scheme, unlike the previous methods based on the OFDM scheme, and in a poor environment such as a cell border. While operating in the CDMA scheme, when the environment is near the base station, the performance is similar to that of the OFDM scheme. In addition, the greatest advantage in the method according to the present invention to be described later is that it is compatible with the EVDV and HSDPA system of the conventional third generation technology, it is possible to utilize the conventional technology without modification.

In the present invention, the terminal operates as a rake receiver in a CDMA scheme at a cell edge far from the base station, and uses an equalizer using an FFT as in the OFDM scheme near the base station. Accordingly, high speed data transmission, which is difficult to implement in a conventional CDMA system, is possible. On the other hand, the system proposed in the present invention performs the equalization in the frequency domain using the FFT as an equalization method used on the receiving side. In the following description, the system according to the present invention will be referred to as a Code Division Multiplexing with Frequency Domain Equalization (hereinafter referred to as CDM-FDE) system.

Hereinafter, a transmitter according to an exemplary embodiment of the present invention will be described with reference to FIGS. 4 to 7, and a receiver will be described with reference to FIGS. 8 and 9. First, the structure of a transmission apparatus according to an embodiment of the present invention will be described with reference to FIG. 4.

4 is a diagram illustrating a transmitter structure of a code division multiplexing-frequency domain equalization scheme according to an embodiment of the present invention.

Referring to FIG. 4, the transmitter of the code division multiplexing-frequency domain equalization method according to an embodiment of the present invention includes channel encoders 401a to 401n, interleavers 403a to 403n, spreaders 405a to 405n, and adders 407. ), A multiplier 409, a controller 411, a switch 413, an antenna 415, and the like. On the other hand, since the processes from the channel encoders 401a to 401n to the multiplier 409 are the same as the prior art described with reference to FIG. 1, the description thereof will be omitted.

Data to be multiplied by the scramble code via the multiplier 409 is gated by the controller 411 in accordance with the present invention. That is, the switch 413 is turned on or off by a gating control signal output from the controller 411 to gate a signal to be transmitted. On the other hand, the structure gated by the switch 413 is configured to facilitate the understanding of the present invention, it can be realized using any method implemented to gate the transmission signal by the control signal in accordance with the present invention Self-explanatory Accordingly, the switch 413 may be replaced by a signal interrupter (not shown) that is controlled by a control signal of the controller 411 to intermittently transmit (ie, gate) a transmission signal.

Meanwhile, the control signal output from the controller 411 for the gating is a signal for determining whether to gating according to the channel state according to the embodiment of the present invention.

That is, the structure of the transmitter according to the embodiment of the present invention has a form similar to the structure of a transmitter of a general code division multiple access method, and when the channel is poor and is transmitted at a low data rate, the transmitter is a general code. Operates as a transmitter in a split multiple access scheme. However, when the channel is in good condition to operate at a high data rate, the data to be transmitted is intermittently not transmitted by intermittently transmitting, ie gating, the transmission signal as described above.

As described above, a channel structure in which data to be transmitted is gated and transmitted will be described with reference to FIG. 5. 5 is a diagram illustrating a channel structure according to an OVSF code in a code division multiplexing-frequency domain equalization scheme according to an embodiment of the present invention.

Referring to FIG. 5, the transmission data for each channel to be transmitted are transmitted by orthogonal code division multiplexing such as an OVSF code at the same time. Accordingly, when gating is performed for a predetermined time according to the embodiment of the present invention, the data to be transmitted are not transmitted during the gating time. In this case, the time at which the data is transmitted is called a 'gate on' section, and the time at which data is not transmitted by the gating is called a 'gate off' section.

Since the data is continuously generated even in the gate-off period in which the data is not transmitted and is simply not transmitted, the untransmitted data is lost and has an effect such as puncturing. In this case, the loss due to the punctured data is overcome by channel encoding and interleaving.

On the other hand, as shown in FIG. 5, the length of the gate-on period in which data is transmitted and the length of the gate-off period in which transmission is stopped do not have a fixed value, as shown in Equations 1 and 2 below. It is desirable to satisfy the relationship.

That is, according to Equation 1 and Equation 2, the gating-on period is the FFT of the frequency domain channel equalizer of the receiver for the frequency domain channel equalization of the receiver according to an embodiment of the present invention to be described later. It is desirable not to exceed the size. In addition, in order to overcome the delay caused by the multi-pass, the gating off period is preferably set to have a delay spread larger than the length. That is, the setting of the gating off period may be set in consideration of the delay spread.

Hereinafter, an example of the method for determining whether to gating according to the present invention will be described.

If the terminal is close to the base station, the signal to noise ratio (hereinafter referred to as "SNR") is good, so it is preferable to use frequency domain equalization for high-speed data transmission and reception. On the other hand, if the terminal has a large inter-cell interference at the cell boundary, frequency domain equalization may be advantageous because it is difficult to accurately estimate the channel.

Meanwhile, as shown in FIG. 5, gating is equally applied to all terminals in the corresponding cell. Therefore, if any one of the channels that are code division multiplexed is to use frequency domain equalization, it is preferable to transmit by gating according to the present invention. When all the terminals receive the rake receiver because the channel state of all terminals is not good, the gating is performed. It is desirable to transmit without.

In addition, when the base station gates and transmits data to be transmitted according to an embodiment of the present invention, the terminal may receive the received signal by any method among a method of receiving by a rake receiver and a frequency domain equalization method, and different for each channel. It is also possible to choose to receive the method.

On the other hand, there is no problem in receiving data even if the terminal does not know whether gating is performed in the transmitting method and the length of the gate-on or gate-off period, which gives a great degree of freedom and flexibility in the implementation of the system. do.

Hereinafter, a method of determining the gate on period and the gate off period will be described.

First, a method of determining a gate off period will be described. The size of the gate off period is determined by a delay spread as described above. The delay spread is briefly described as follows.

Signals arriving at receivers through different paths have different magnitudes and time delays. As such, a signal reaching a receiver through several paths is called a multipath phenomenon. In this case, if the transmitter transmits an impulse signal of size a at a time t = 0, the signal reaching the receiver through the multipath is received with a time difference even though one impulse signal is transmitted. In general, a relatively large signal arrives first, and a small signal arrives late. This is because a late incoming signal travels through more paths, reducing the size of the signal along that path. As described above, the transmission and reception of delayed and attenuated signals into multiple signals along multiple paths is called delay spreading.

That is, the gate off period according to the embodiment of the present invention is determined by the delay spread, and the maximum delay spread value may be determined according to the size and environment of the cell. For example, when the size of the cell is small, the size of the delay spread value is also reduced. On the contrary, when the size of the cell is large, the size of the delay spread value is also increased. Accordingly, the maximum delay spread value may have a different value for each cell and may have a different value depending on the position of the terminal. That is, it may have a different value depending on whether the terminal is close to the base station.

As a result, the gate-off period is determined according to the size of the cell covered by the base station as described above, or the delay spread values actually measured by each terminal in the cell is reported to the base station, and each reported terminal It may be set to reflect the delay spread values.

The method of setting the gate-off period has been described above, and the method of setting the gate-on period is described next.

It is preferable to set the gate-on period not to be larger than the size of the FFT block as described above in Equation 1, and in general, it is preferable to set the gate-on period according to the size of the FFT block. However, it does not matter even if the size of the gate-on period is smaller than the size of the FFT block.

Hereinafter, a reception method according to the size of a gate-on period will be described with reference to FIGS. 6 and 7.

6 is a diagram illustrating a process of removing a guard interval in a time domain when the gate-on interval is equal to the FFT size according to an embodiment of the present invention.

Referring to FIG. 6, when the gate-on period 601 is equal to the FFT block size, the data received in the gate-off period 603 that does not transmit data after the gate-on period 601 may be generated in a typical OFDM system. Like the guard period, the signal is added to the front part signal of the gate-on period 601 and processed. That is, the channel estimation can be performed according to the FFT block size at the receiving side by the gated transmission signal.

On the other hand, Figure 7 is a view showing a process of removing the guard interval in the time domain when the gate-on interval is smaller than the FFT size according to an embodiment of the present invention.

Referring to FIG. 7, the gate on period 703 starting after the predetermined gate off period 701 is smaller than the FFT block size, and the gate off period 705 starting after the gate on period 703. In the case of smaller than the size of the FFT block even if considering (), a zero value is inserted by the zero insertion block 709. That is, since the size of the gate-on period 703 is equal to or smaller than the size of the FFT block as described above, the gate-on period 703 and the gate-off period 705 are input to the FFT block, the FFT block A value of 0 is entered in the remaining input portion of the block. Another gate on period 707 which starts after the gate off period 705 is processed by the same method as above in the next processing FFT processing block.

On the other hand, in the third generation synchronous EVDV system, the packet length of the packet data channel (hereinafter referred to as 'PDCH') is 1.25, 2.5 and 5ms, and the high speed downlink packet transmission system (HSDPA) The high-speed dedicated channel (HS-DSCH) is determined to be 2 ms. Therefore, if the gate-on and gate-off periods are determined by the packet period, the last data block may be smaller than the length of the FFT block. In addition, when the terminal moves at a high speed, when the gate-on period is large, there is a problem that the channel is changed in the block. In this case, the problem may be solved by reducing the gate-on period.

The data transmission method in the transmitter according to the embodiment of the present invention has been described above. Hereinafter, a method of receiving gating and transmitting data as described above with reference to FIGS. 8 and 9 will be described.

8 is a diagram illustrating a receiver structure of a code division multiplexing-frequency domain equalization scheme according to an embodiment of the present invention.

Referring to FIG. 8, data received through an antenna is wirelessly processed by a wireless processor (not shown) and input to the selector 801. At this time, the selector 801 receives the received signal to the rake receiver according to the general code division multiple access scheme under the control of the controller 821 or the frequency domain receiver 830 according to the present invention. Select. Meanwhile, the received data may be classified for each channel signal, and the method may be selected and processed differently for each channel.

When the selector 801 selects to receive the received data through the rake receiver, the received data is input to the respective fingers 813b to 813n of the rake receiver. The received data input to each of the fingers 813b to 813n is processed in the same manner as the method described above with reference to FIG. 3. That is, each of the fingers 813b to 813n detects a received signal for each multipath, and the combiner 815 combines the detected multipath signals. Then, as described above, the deinterleaver 817 and the channel decoder 819 recover the transmission signal.

On the other hand, if the selector 810 selects to receive the received data using the frequency domain receiver 830, the received data is the guard interval remover 803 and the channel estimator 807 of the frequency domain receiver 830. Is entered.

The received signal input to the guard interval remover 803 is a gate off period, that is, a guard interval added by gating at the time of transmission is removed, and the received signal is subjected to fast Fourier transform by the FFT 805 to frequency Convert to a signal in the area. In this case, an output signal of the FFT 805 is input to a frequency domain equalizer 809, and the frequency domain equalizer 809 estimates a received signal converted into a frequency domain signal by the channel estimator 807. Equalization in the frequency domain is performed according to the calculated values.

The frequency domain equalized signal by the frequency domain equalizer 809 is inverse fast Fourier transformed by the IFFT 811 and then converted into a signal in the time domain. At this time, since the equalized data is transmitted by code division multiplexing at the transmitting side, the equalized data is inputted to a predetermined finger 813a of the rake receiver to perform despreading.

Meanwhile, according to an embodiment of the present invention, the controller 821 controls the selector 801 and the combiner 815 by determining whether to receive a received signal by a frequency domain equalization method or a general rake receiver. Done. As described above, the reception method may be set differently for each channel.

Hereinafter, a process of the controller 821 determining the reception method will be described. As described above, the selection of the reception method is preferably determined according to the channel state (eg, SNR of the received signal) of each terminal. That is, when the terminal is close to the base station and the channel condition is good, the frequency domain receiver 830 is preferably used. On the other hand, when the terminal is located in the cell boundary area and the channel condition is not good, it is preferable to use a general rake receiver.

Therefore, it is preferable that the channel state is measured by the SNR value of the received signal of each terminal, and the controller 821 determines the method of receiving the received signal according to the measured channel state value. In this case, as described above, the reception method or the SNR values of the respective terminals may be fed back to the base station and transmitted, and may be referred to as data for determining whether the aforementioned transmission method is gating. That is, the determination of whether the gating is determined by the cell radius, it can be determined as the channel information fed back by the respective terminals. Therefore, even if one terminal has a good channel condition and uses the frequency domain equalization method, it is preferable that the transmitting side gating and transmitting according to the above-described method.

In the meantime, in the case where the terminal receives a signal transmitted by the general rake reception method due to the bad channel condition, a frame error rate (hereinafter referred to as 'FER') of the received signal by the gating is received. Although there may be some degradation, since the gating ratio (ie, the ratio of the gate off period to the gate on period) is low (generally, the gate off period is about 1/4 to 1/8 of the gate on period), The degradation can be said to be insignificant compared to the effect obtained according to the embodiment of the present invention.

As a method different from that shown in FIG. 8, the received signal is first processed by the two methods (ie, the equalization method by the frequency domain receiver 830 and the reception method by the rake receiver), and then the processing. One of the two methods can be used to choose the result of a better method. That is, there is no selection process by the selector 801 of FIG. 8, and the received signal is input to each of the fingers 813b to 813n of the frequency domain receiver 830 and the rake receiver, and the combiner 815 By comparing the result values according to each reception method, it is possible to select and output a result with better performance.

In FIG. 8, the first finger 813a of the fingers 813a to 813n is used for equalization of the frequency domain, and the second fingers 813b to 813n are equalized in the time domain for rake reception. Although it is expressed to use, it is obvious that the first finger 813a can be used to equalize even in the time domain for receiving the rake.

Hereinafter, a structure of the channel estimator 807 in the frequency domain used for frequency domain equalization in the frequency domain receiver 830 will be described with reference to FIG. 9.

9 illustrates a structure of a frequency domain channel estimator according to an embodiment of the present invention.

Referring to FIG. 9, the received signal input to the channel estimator 807 is a multiplier 905a through the values stored in the scramble code generator 901 in the shift register 903 and delay spread according to the values stored in the shift register 903. 905n).

The scramble code generated by the scramble code generator 901 is a scramble code generated by the above-described transmitter, and the generated scramble code is stored in a predetermined shift register 903. The received signal is multiplied by a plurality of multipliers 905a through 905n provided according to the size of the delay spread and the scramble code stored in the shift register 903, and filters 907a through according to the delay spread size. 907n).

The signals filtered by the filters are input to the FFT unit 909 and converted into channel estimation signals in the frequency domain. In this case, the number of the filters 907a to 907n is related to the size of the delay spread as described above, and is also determined according to the size of the guard interval, so that it is generally smaller than the number of input points of the FFT unit 909. . Therefore, it is preferable to input a value of 0 to the points where the output values of the filters 907a to 907n are not input among the input points of the FFT unit 909.

On the other hand, the output value of the FFT 909 is input to the frequency domain equalizer 809 of FIG. 8 as a channel estimation value in the frequency domain and used to equalize the received signal in the frequency domain.

Hereinafter, a transmission method and a reception method according to an embodiment of the present invention will be described with reference to FIGS. 10 and 11. First, a transmission method according to an embodiment of the present invention will be described with reference to FIG. 10.

10 is a flowchart illustrating a transmission method in a code division multiplexing-frequency domain equalization scheme according to an embodiment of the present invention.

Referring to FIG. 10, first, channel state information is received from each terminal to determine whether to gating (step 1001). On the other hand, whether the gating may be determined in consideration of the information received from the terminals, or may be determined only through the information according to the cell characteristics.

Based on the above information, it is determined whether a signal to be transmitted is gated (step 1003). If the terminal decides not to gating due to poor channel conditions (step 1005), data is transmitted (step 1007) in a general data transmission method.

On the other hand, when gating according to an embodiment of the present invention in step (step 1005), the data to be transmitted is determined by gating on and gating off periods (step 1009). If the transmission period is a gate-on period (step 1011), the data is transmitted (step 1015). On the contrary, if the transmission period is a gate-off period (step 1011), the data is not transmitted (step 1013). ).

11 is a flowchart illustrating a reception method in a code division multiplexing-frequency domain equalization scheme according to an embodiment of the present invention.

Referring to FIG. 11, the receiver receives the data transmitted by the method of FIG. 10 (step 1101), and determines a reception method. First, the receiver measures the channel state from the received signal (step 1103), and determines the reception method according to the measured channel state (step 1105).

If the determined reception method is not an equalization method in the frequency domain according to an embodiment of the present invention but is a reception method by a general rake receiver (step 1107), channel estimation is performed in the time domain from the received data ( After the step 1109, the rake reception method is performed on each of the fingers despread along the multipath based on the channel estimated value (step 1111).

On the other hand, if the determined reception method is an equalization method in the frequency domain according to an embodiment of the present invention (step 1107), first perform channel estimation (step 1113) in the frequency domain from the received signal and perform the channel estimation. By the value, the received signal is equalized in the frequency domain (step 1115).

The received data, which are channel compensated by the equalization method in the frequency domain or the reception method by the rake receiver, is decoded by the deinterleaver and the channel decoder (step 1117) to restore the data transmitted during transmission.

<Experiment Result>

Hereinafter, the method according to the embodiment of the present invention and the prior art are compared with each experimental data.

In the experiments described below, a comparison between the general CDMA transmission method and the CDM-FDE transmission method FER according to an embodiment of the present invention was performed. In this case, we used convolutional code of length 7, code rate 1/2, CDM-FDE with FFT size of 256, protection interval of 32, and channel 0, 1, 2, 3 chip delay. A multipath fading channel with powers of 0, -3, -6 and -9 dB at the location was used.

In addition, four codes are assigned to the circuit channel and 28 codes are assigned to the packet channel using a spreading factor 32 as a code division multiplexing method. On the other hand, the distinction between the circuit channel and the packet channel does not reflect the actual system, but for the convenience of experiments, the packet channel is intended to show the superiority of the frequency domain equalization. This is to see what effect the reception with the rake receiver will have. Here, the circuit channel uses only QPSK modulation and the packet channel uses QPSK and 16QAM modulation.

In this case, the CDMA and the CDM-FDE generate data in the same manner, and in the case of the CDM-FDE, the 256 chip section sends data and the 32 chip section stops transmitting data. In other words, the FFT size in the experiment is 256. On the other hand, the CDMA transmission (that is, when there is no gate off period) is received by the rake receiver, and in the CDM-FDE transmission, the packet channel uses a frequency domain equalizer and the circuit channel uses a rake receiver.

12 and 13 illustrate the FER performance of the packet channel when the power ratio per unit code of the circuit channel and the packet channel is 1: 1 and the modulation scheme of the packet channel is QPSK and 16QAM, respectively. As shown in FIG. 12 and FIG. 13, the CDMA transmission scheme is difficult to show good performance due to multipath interference, whereas the CDM-FDE scheme using frequency domain equalization has a very good performance even when a higher-order modulation scheme is used. Is showing.

In addition, Figures 14 and 15 show the FER performance of the circuit channel in the environment of Figures 12 and 13, respectively. In this case, it is assumed that the circuit channel uses a rake receiver for both CDMA transmission and CDM-FDE transmission. In the CDM-FDE transmission, since there is a section in which no data is sent (gate off section), performance is degraded when received by the rake receiver. However, such a performance degradation is very slight as shown in FIGS. 14 and 15 and can be easily overcome by a slight power increase.

Meanwhile, FIGS. 16 to 19 show the above-described case in which the power ratio per unit code of the circuit channel and the packet channel is increased to 4: 1. As shown in the graph, assuming that the circuit channel uses more power per unit code than the packet channel for stable operation, the CDMA scheme increases the amount of interference in the packet channel, resulting in a large performance degradation. In CDM-FDE, there is no performance reduction because there is no interference by multiple codes. In addition, in the case of the circuit channel, since the power of the other code is relatively small even when received by the rake receiver, it can be seen that very good performance is obtained without causing any interference.

On the other hand, in the case of the CDM-FDE, the code is divided into several parts to increase the power per unit code to the terminal where the channel environment is not good, such as cell border, and transmit the power to the rake receiver stably, and the base station has a good channel environment. A nearby terminal can assign a large number of codes at a relatively low transmission power to send data with higher-order modulation and frequency-domain equalization for high speed transmission.

20 and 21 are used to divide the packet channel into two parts in the case of FIGS. 12 and 13 to use 14 codes, respectively. Referring to the graphs, neither the case of the CDMA nor the CDM-FDE shows no change. That is, even in the case of the CDM-FDE, even if a plurality of users are used by code division multiplexing, the CDM-FDE does not have any influence, and each terminal receives data in an advantageous manner during rake receiver and frequency domain equalization.

As shown in the above experimental results, the signal transmitted to the CDM-FDE according to the embodiment of the present invention can be received in two modes, CDMA and CDM-FDE. Therefore, when multiple channels are code-division multiplexed and transmitted to CDM-FDE, each terminal can receive data in an advantageous mode among CDMA and CDM-FDE, as well as terminals that do not have a frequency domain equalizer. It is possible. In addition, since the CDM-FDE terminal can receive the signal of the CDMA base station and the CDMA terminal can receive the signal of the CDM-FDE base station, it is possible to gradually evolve with compatibility with the existing system.

Meanwhile, the CDM-FDE according to the embodiment of the present invention is similar in terms of performance to Single Carrier with Frequency Domain Equalization (SC-FDE) or Cyclic Prefix CDMA (CP-CDMA). However, the SC-FDE scheme equalizes in the frequency domain as in general OFDM, but may lose some performance than OFDM because information on the frequency axis is lost in the process of moving to the time domain and thus the information on the frequency axis is not effectively used. Therefore, the CDM-FDE scheme is inferior in performance to that of general OFDM, but the difference is not large. On the other hand, in general OFDM, since a signal cannot be received without knowing the length of a cyclic prefix (hereinafter, referred to as 'CP'), there is a disadvantage in that a CP having a predetermined length must be used. In addition, the CP is determined by the maximum length of the delay spread, but it is not easy to determine the maximum length of the delay spread considering all possible circumstances.

If the length of the CP is too small, the performance may be very degraded in an environment in which the delay calculation exceeds the CP. On the contrary, when the length of the CP is taken as the maximum delay spread length in all possible environments, when the FFT size is small, the ratio of wasted by the CP is large, and when the FFT size is large, the OFDM symbol length is increased to increase the hardware. This causes a problem of complexity and channel change in OFDM symbols during high-speed movement. Thus, current cellular systems vary widely from very small cells to very large cells and thus it is not easy to determine the appropriate CP.

However, in the CDM-FDE system according to the embodiment of the present invention as described above, it is possible to receive in two modes, the gate on interval and the gate off interval is determined under the agreement of the base station and the terminal, according to each channel environment Make it work optimally. In addition, the CDM-FDE according to the embodiment of the present invention may compensate for the performance reduction for OFDM by operating with a short guard period (gate off period) in most environments compared to the general OFDM. In addition, since the gate-on period does not need to be large and the gate-on period can be arbitrarily reduced, a problem caused by a channel change in one OFDM symbol in a high-speed mobile unit such as OFDM can be easily avoided.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

The present invention as described above has the advantage of enabling the use of existing techniques without modification by operating as a rake receiver at the cell edge and high-speed data transmission using a frequency domain equalizer near the base station. In addition, in the method according to the present invention, each terminal has an advantage of being able to receive any one of a rake receiver and a frequency domain equalizer. This allows the system to be flexible so that the block size and the size of the guard interval can be changed to adapt to various environments and maintain the compatibility with the existing CDMA system to achieve a gradual development.

1 is a diagram illustrating a transmitter structure of a general code division multiplexing system.

2 is a view showing a channel structure by OVSF code in a general code division multiplexing scheme.

3 illustrates a receiver structure of a general code division multiplexing system.

4 is a diagram illustrating a transmitter structure of a code division multiplexing-frequency domain equalization scheme according to an embodiment of the present invention.

5 is a diagram illustrating a channel structure using an OVSF code in a code division multiplexing-frequency domain equalization scheme according to an embodiment of the present invention.

6 is a diagram illustrating a process of removing a guard interval in a time domain when the gate-on interval is equal to the FFT size according to an embodiment of the present invention.

7 is a diagram illustrating a process of removing a guard interval in a time domain when the gate-on interval is smaller than the FFT size according to an embodiment of the present invention.

8 is a diagram illustrating a receiver structure of a code division multiplexing-frequency domain equalization scheme according to an embodiment of the present invention.

9 illustrates a structure of a frequency domain channel estimator according to an embodiment of the present invention.

10 is a flowchart illustrating a transmission method in a code division multiplexing-frequency domain equalization scheme according to an embodiment of the present invention.

11 is a flowchart illustrating a reception method in a code division multiplexing-frequency domain equalization scheme according to an embodiment of the present invention.

12 to 21 is a graph comparing the performance of the embodiment of the present invention and the prior art.

Claims (20)

In a mobile communication system in which a predetermined base station communicates with one or more terminals within a cell area covered by the base station in a code division multiple access scheme, one or more channels are classified according to the type of data to be transmitted and the receiving terminals. In the method for transmitting the code division multiplexed signal for each channel, Determining whether or not gating is transmitted according to a channel state between the base station and the terminals; And gating and transmitting the transmission signal according to the determination. The method of claim 1, And determining whether to transmit the gating considering the cell radius. The method of claim 1, After determining whether to transmit the gating, And determining a length of a gating on period and a gating off period according to the gating transmission. The method of claim 3, And the gating-on period is set to a block size of a fast Fourier transformer for frequency domain equalization at a receiving side. The method of claim 3, The gating off period is determined by the delay spread value between the base station and the terminals. In a mobile communication system in which a predetermined base station communicates with one or more terminals within a cell area covered by the base station in a code division multiple access scheme, one or more channels are classified according to the type of data to be transmitted and the receiving terminals. In the method for receiving a signal transmitted by code division multiplexing for each channel, Determining an equalization method of a received signal according to a channel state between the base station and the terminal; Performing channel equalization in the frequency domain according to the determination; And despreading a channel equalized signal in the frequency domain by a finger. The method of claim 6, And if the signal-to-noise ratio of the received signal measured by the terminal is greater than or equal to a predetermined threshold, the equalization method is determined as channel equalization in the frequency domain. The method of claim 6, Performing channel equalization by a rake receiver having a plurality of fingers according to the determination; And combining and outputting the output values of the respective fingers. The method of claim 6, The process of performing channel equalization in the frequency domain according to the determination, Removing a guard interval of the received signal; Outputting the received signal from which the guard period has been removed by fast Fourier transforming the signal as a signal in a frequency domain; Channel equalizing the signal in the fast Fourier transformed frequency domain by a channel estimated value from the received signal; And outputting the channel equalized signal as an inverse fast Fourier transform as a signal in a time domain. The method of claim 9, Wherein the channel estimated value is a channel estimated value in a frequency domain obtained by fast Fourier transforming a channel estimated value in a time domain. In a mobile communication system in which a predetermined base station communicates with one or more terminals within a cell area covered by the base station in a code division multiple access scheme, one or more channels are classified according to the type of data to be transmitted and the receiving terminals. An apparatus for transmitting a code division multiplexed signal for each channel, A controller for determining whether to transmit gating of the signal according to a channel state between the base station and the terminals; And a signal interrupter for gating and transmitting the transmission signal according to the controller's decision. The method of claim 11, And determining the gating transmission by considering the cell radius. The method of claim 11, The controller, And determining a length of a gating on period and a gating off period according to the gating transmission. The method of claim 13, And the gating-on period is set to be equal to or smaller than a block size of a fast Fourier transformer for frequency domain equalization at a receiving side. The method of claim 13, The gating off period is determined by the delay spread value between the base station and the terminals. In a mobile communication system in which a predetermined base station communicates with one or more terminals within a cell area covered by the base station in a code division multiple access scheme, one or more channels are classified according to the type of data to be transmitted and the receiving terminals. An apparatus for receiving a signal transmitted by code division multiplexing for each channel, A controller for determining an equalization method of a received signal according to a channel state between the base station and the terminal; A frequency domain receiver for performing channel equalization in the frequency domain according to the determination of the equalization method of the controller; And a finger despreading a channel equalized signal in a frequency domain by the frequency domain receiver. The method of claim 16, The controller, And if the signal-to-noise ratio of the received signal measured by the terminal is greater than or equal to a predetermined threshold, the equalization method is determined as channel equalization in the frequency domain. The method of claim 16, The device, A plurality of fingers for performing channel equalization by the rake receiver according to the controller's decision; A combiner for combining the output values of the fingers And a channel decoder for channel decoding the signals combined by the combiner. The method of claim 16, The frequency domain receiver, A guard interval remover for removing the guard interval of the received signal; A fast Fourier transformer for fast Fourier transforming the received signal from which the guard period is removed and outputting the signal in a frequency domain; A frequency domain equalizer for channel equalizing the signal in the fast Fourier transformed frequency domain by a channel estimated value from the received signal, And an inverse fast Fourier transformer for converting the channel equalized signal into an inverse fast Fourier transform and outputting the signal as a time domain signal. The method of claim 19, The frequency domain receiver, And a frequency domain channel estimator for fast Fourier transforming the channel estimated value from the received signal and outputting the channel estimated value in the frequency domain.