KR100659229B1 - methode for reducing peak to average power ratio in Multi-Carrier Direct Sequence Code Division Multiple Access Communication system, and transmitting and receving apparatus using the method - Google Patents

Abstract

The present invention relates to a method for reducing the maximum power to average power ratio of a signal in a multi-carrier direct sequence code division communication system, a transmitter, and a receiver using the same.

In the present invention, the efficiency of a power amplifier is increased by minimizing the peak power to average power ratio (PAPR) in a direct sequence code division multiple access communication system using multiple carriers. To this end, the tone reservation scheme proposed as a PAPR reduction scheme in an orthogonal frequency division multiplexing (OFDM) scheme is used. Specifically, a certain tone signal is transmitted and inserted into a multi-carrier signal to reduce the PAPR at the transmitting end, and the receiving end reduces the distortion of the received signal by removing it using a band limiting filter or an adaptive narrowband interference cancellation filter. Increase the power efficiency of the transmitter. Therefore, unlike the scheme of using the tone reservation scheme in conventional OFDM, it is possible to reduce the PAPR without reducing the transmission rate.

PAPR, Multicarrier, Direct Sequence Code Division Communication, Tone Reservation, Power Efficiency

Description

Method for reducing peak to average power ratio in multi-carrier direct sequence code division communication system, and transmitting and receiving device using the same method and multi-carrier direct sequence code division multiple access communication system, and transmitting and receving apparatus using the method}

1 illustrates a structure of a transmitter in a multicarrier direct sequence code division communication system according to an embodiment of the present invention.

FIG. 2 is a diagram illustrating a structure of the attenuation signal generator shown in FIG. 1.

3 is a flowchart illustrating a transmission method according to an embodiment of the present invention.

4A illustrates an example of a kernel signal generated by the attenuation signal generator.

4B shows an example of a multiple modulated signal in the time domain.

4C shows an example of a kernel signal that is scaled and shifted on the time axis.

4D shows an example of a transmitted signal with its maximum power removed by a time shifted and scaled kernel signal.

5 is a diagram illustrating a structure of a receiving apparatus using a tone removing filter bank according to an embodiment of the present invention.

6 is a flowchart illustrating a receiving method according to an embodiment of the present invention.

FIG. 7 is a structural example of a tone removing filter unit shown in FIG. 5.

8 is a diagram illustrating a structure of a receiving apparatus using an adaptive narrowband interference canceller according to an embodiment of the present invention.

The present invention relates to a code division multiple access communication system, and more particularly, to the maximum power of a signal in a multi-carrier direct sequence (CDMA) / code division multiple access (CDMA) communication system. The present invention relates to a method for reducing average power ratio, a transmitter and a receiver using the same.

Recently, a multi-carrier technology has been received and researched and developed as a method of increasing the data transmission speed in mobile communication. Multi-carrier systems have been discussed as a way to overcome the problem of overcoming the fading (fading channel) problem that is a problem when using a wide band using a single carrier. Representative of these methods is Orthogonal Frequency Division Multiplexing (OFDM) and multi-carrier direct sequence code division.

However, in these methods, since the phase change of each carrier is random, the Peak to Average Power Ratio (PAPR) is much higher than that of a single carrier system. Due to the high PAPR, high power linear amplifiers require a wide range of lines, which leads to corresponding cost and lower power efficiency. In the case of nonlinear amplifiers, in order to maintain the linearity of the signal, back-off is required to lower the operating point of the amplifier. This also causes a decrease in amplifier efficiency and increased power consumption. This problem may occur, in particular, in a mobile terminal using the battery as a power source, a phenomenon in which the battery use time is significantly shortened.

Although a lot of researches are mainly conducted in the OFDM field for reducing the PAPR, there are few techniques applied in the field of direct sequence code division communication. Conventionally, a method mainly applied to reduce PAPR in the direct sequence code division communication field uses a method of monitoring an output signal and simply clipping a signal to be transmitted when the linear region of the amplifier is exceeded. However, this approach can cause some in-band signal distortion and out-of-band radiation.

In addition, the Tone Reservation scheme applied to OFDM uses OFDM as an inverse fast fourier tramsform (IFFT) and fast fourier tramsform (FFT). That's the way. However, the disadvantage is that the data rate is reduced by the number of tones used in the kernel.

As such, in the conventional direct sequence code division communication using a multi-carrier, the ratio of the maximum and average power of a transmitted signal may be very high due to the phase difference of each carrier. In this case, the efficiency of the power amplifier is reduced or linear amplification is performed. This creates a problem that requires the use of expensive power amplifiers with large areas. In particular, in the case of a mobile terminal, the use time of the battery is reduced.

Therefore, the technical problem to be achieved by the present invention is to solve the conventional problems, in the direct sequence code division communication system, while reducing the maximum power to average power ratio while reducing out-of-band radiation without distorting the quality of the in-band signal as much as possible I'm trying to.

Another object of the present invention is to provide a method for reducing a maximum to average power ratio of a signal of a transmitter using an adaptive narrowband filter or a tone removing filter bank at a receiver, and a transmitter / receiver using the same.

According to an aspect of the present invention, there is provided a method for reducing the maximum power-to-average power ratio, in a method for reducing PAPR of a signal at a transmitting end in a direct sequence code division communication system using multiple carriers. Obtaining a spread modulated multiple modulated signal; b) measuring the magnitude of the maximum value beyond any threshold in the multiple modulated signal and measuring the time at which the maximum value is detected; c) summing several tone signals in the band to produce a kernel signal that is an impulsive pseudo noise in the time domain; d) changing the magnitude and time axis of the maximum value of the kernel signal according to the magnitude and time of the maximum value of the multiple modulated signal measured in step b) to generate an attenuation signal; And e) subtracting the attenuation signal from the multiple modulated signal and transmitting.

In this case, after receiving a signal transmitted from the transmitting end at the receiving end, demodulating the received signal for each carrier; And removing the tone signal component used in the kernel signal from the demodulated signal for each carrier using a tone removal filter.

According to another aspect of the present invention, there is provided a transmission apparatus comprising: a plurality of spreading and modulation units for spreading and modulating a plurality of data streams to be transmitted in a transmitting apparatus of a direct sequence code division communication system using multiple carriers; A plurality of signal multipliers for modulating each data stream using a carrier wave; A first signal adder configured to generate a multiple modulated signal by mixing signals output from the plurality of signal multipliers; An attenuation signal generator that uses the multiple modulated signal as an input signal and generates an attenuation signal based on the input signal; A second signal summing unit for mixing the attenuation signal and the multiple sign signal output from the first switch unit to output a maximum power removal signal; A PAPR reduction controller configured to compare the PAPR of the maximum power removal signal with a set threshold and selectively output the maximum power removal signal as a transmission signal; And a transmitter for processing and transmitting a transmission signal output from the PAPR reduction controller.

In addition, a receiving apparatus according to another aspect of the present invention is a receiving apparatus for receiving and processing a signal provided from a transmitting apparatus of a direct sequence code division communication system using a multicarrier, wherein the transmitting apparatus sums several tone signals in a band and includes a time domain. Generates a kernel signal which is an impulsive pseudo noise at, and generates an attenuation signal by changing the magnitude and time axis of the maximum value of the kernel signal according to the magnitude and time of the maximum value of the signal to be transmitted, and the signal to be transmitted. Subtracts the attenuated signal from the transmitter, and the receiver receives a signal transmitted from the transmitter, and multiplies and demodulates a carrier wave to N received signals obtained by separating the received signal for each carrier. ; A plurality of tone removal filters for removing tone signal components according to the kernel signal from demodulated N received signals; A plurality of matched filters for matching the received signal output from each tone rejection filter; A plurality of despreaders which despread each matched received signal; And a plurality of decoders for decoding the despread received signal.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention.

 1 is a structural diagram of a transmitter in a multi-carrier direct sequence code division multiple access communication system according to an embodiment of the present invention.

As shown in FIG. 1, a transmission device according to an embodiment of the present invention includes a plurality of spreading and modulation units 11 to 1N, spreading and modulating data streams, each spreading and modulating a plurality of data streams to be transmitted. A plurality of pulse shaping sections 21 to 2N for pulse shaping each, a plurality of signal multipliers 31 to 3 N for modulating each of the pulse shaped data streams using a carrier wave, and a signal output from a plurality of signal multiplication sections. The first signal summing unit 40 to generate a multi-modulated signal by mixing the first, the buffer 50 for storing the multi-modulated signal for a predetermined time, and drive in a predetermined unit to output the multi-modulated signal stored in the buffer 50 Attenuation signal generator 70 for generating attenuation signal based on the first switch unit 60 and the multiplexed modulation signal output from the first switch unit 60 as the input signal, and the attenuation A second signal summing unit 80 for mixing a call and the multiple sign signals output from the first switch unit to output a maximum power removal signal, and comparing the PAPR of the maximum power removal signal with a set threshold value to remove the maximum power; A PAPR reduction control unit 90 for selectively outputting a signal as a transmission signal, a transmission unit 110 for processing a transmission signal output from the PAPR reduction control unit and transmitting it over the air, and a transmission signal output from the PAPR reduction control unit Optionally includes a second switch unit 100 for transmitting to the transmitter 110. Here, the first switch unit 60 operates under the control of the PAPR reduction controller to select one of a signal output from the buffer 50 or a signal output from the PAPR reduction controller 90 to select the attenuation signal generator ( 70).

Meanwhile, the transmitter 110 is an RF / IF unit, and since such a technique is a known technique, a detailed description thereof will be omitted.

2 is a diagram showing the structure of the attenuation signal generator 70 in the transmission device having the structure as described above.

The attenuation signal generator 70 according to an embodiment of the present invention includes a kernel signal component consisting of K tones in the transmitted signal using a kernel signal formed of K tone signals to lower the PAPR of the transmitted signal. .

To this end, the attenuation signal generator 70, as shown in Figure 2, the kernel signal generator for generating an impulse pseudo-noise signal in the time domain by adding any K tone signal in the band where the N multi-carrier exists ( 71, a maximum power meter 72 measuring a magnitude of peak power of a signal input from the buffer 50 through the first switch unit 60, and measuring a time at which the maximum power is measured; The time base shifter 73 for removing the maximum power component of the input signal by moving the pseudo noise signal output from the kernel signal generator 71 to the time position according to the measured time, and the maximum power of the input signal. And a scaler 74 that scales the time-shifted kernel signal to be proportional to the difference between the value and the set maximum allowable power value, and outputs an attenuation signal.

Meanwhile, as shown in FIG. 2, the kernel signal generator 71 includes K tone signal generators 7111 to 711K for generating tone signals, and a mixer 712 for mixing the generated K tone signals and outputting them as kernel signals. Include.

Next, a transmission method for reducing the maximum power to average power ratio of a transmitted signal based on this structure will be described.

3 is a flowchart illustrating a transmission method according to an exemplary embodiment of the present invention.

As shown in FIG. 3, when N data streams equal to the number of carriers are applied from a data generating unit (not shown), each spreading and modulating unit 11 to 1N of the transmitting apparatus spreads each applied data stream. And modulate and output (S100 to S110). Hereinafter, the data stream is referred to as a data signal for convenience of description. The pulse shaping parts 21 to 2N pulse shape the data signals that are spread and modulated, respectively, in order to limit bands of the transmitted signals (S120). The spreading and modulation of the signal and the pulse shaping are well known techniques, and thus detailed descriptions are omitted.

The pulse-shaped N data signals are mixed and modulated with the carriers by the signal multipliers 31 to 3N, respectively, and output. Each of the modulated N data signals is combined by the first signal adder 40 to generate a multiple modulated signal (S130). The multiple modulated signal is stored in the buffer 50 for M symbol period M * T time for block processing (S140). In the case of using the time division duplex method, the multi-modulated signal may be stored in a buffer in units of time slots that are transmission / reception time change units instead of M times the symbol period.

 Thereafter, the first switch unit 60, which operates in units of M symbol intervals, is connected to the buffer 50 so that the multiple modulation signals stored in the buffer 50 are attenuated through the first switch unit 60. Is output.

The maximum power meter 72 of the attenuation signal generator 70 measures the maximum power of the multiple modulated signal input through the first switch unit 60, and the time axis shifter 73 determines that the measured maximum power is specified. Find the time and magnitude beyond the threshold. When the time and magnitude when the maximum power exceeds a specific threshold value are obtained, the time base shifter 73 moves the kernel signal provided from the kernel signal generator 71 to the same time position as the maximum power value, thereby multiplying the multiple values. Remove the maximum power value of the modulated signal. Thereafter, the scaler 74 scales the kernel signal shifted in time so as to be proportional to the difference between the maximum power value and the set maximum allowable power value and outputs the scaled kernel signal as an attenuation signal (S150).

The attenuation signal generated as described above is input to the second signal summing unit 80, and the second signal summing unit 80 receives the multi-modulation signal input through the attenuation signal and the first switch unit 60. By mixing, the attenuation signal is subtracted from the multiple modulated signal. The multi-modulated signal reduced by the attenuation signal as described above is called a maximum power removal signal (S160).

The maximum power removal signal is input to the PAPR reduction control unit 90, and the PAPR reduction control unit 90 measures the PAPR of the maximum power removal signal and compares the PAPR with a threshold value (S170 to S180). If the PAPR of the removal signal does not exceed the threshold value, the output signal is output to the second switch unit 100 as it is. Therefore, the maximum power removal signal is transmitted as a transmission signal through the transmitter 110 by the second switch unit 100 operating in the same time interval as the first switch unit 60 (S190 to S200).

However, when the PAPR of the maximum power removal signal exceeds the threshold in step S190, the PAPR reduction control unit 90 returns the maximum power removal signal to the first switch unit 60 so that the attenuation signal is reduced. It is input to the generator 70, so that the PAPR reduction operation by the attenuation signal generator 70 is repeatedly performed.

This process is repeated until the desired PAPR is obtained, and the second switch unit 100 outputs a transmission signal having the desired PAPR to the RF / IF stage every M * T symbol periods.

4A to 4D show graphs showing the waveforms of each signal obtained in the transmission process performed as described above. The transmission method will be described again with reference to FIGS. 4A to 4D as follows.

4A is a graph illustrating waveforms of kernel signals output from the kernel signal generator 71. The kernel signal generator 71 of the attenuation signal generator 70 adds arbitrary K tone signals within a band in which N multicarriers exist, and shows an impulsive pseudo noise signal (kernel signal) as shown in FIG. 4A in the time domain. 301 is generated.

4B is a graph showing the results of measuring the magnitude of the maximum power of the signal (multimodulated signal) input to the attenuation signal generator 70 output from the first switch unit 60 and the corresponding time. Here, in order to remove the maximum value 303 of the power value exceeding an arbitrary threshold value 302, the time base shifter 73 of the attenuation signal generator 70 may set the kernel signal which is the impulsive pseudo noise signal to the maximum value. Move to the same time position as (303). And scale the time shifted kernel signal to be proportional to the difference between the maximum value and the maximum allowable power value. As a result, an attenuation signal that is an output signal of the attenuation signal generator 70 is generated. 4C is a waveform diagram illustrating an attenuation signal output in the above manner.

Subsequently, removing the attenuation signal as shown in FIG. 4C from the multiple modulated signal as shown in FIG. 4B, the maximum power removal signal as shown in FIG. 4D is obtained. 4D is a waveform diagram of the maximum power removal signal. Referring to FIG. 4D, it can be seen that the maximum value is significantly reduced than the multiple modulated signal shown in FIG. 4B to obtain a maximum power removal signal having a reduced PAPR.

Next, the structure and operation of a receiving apparatus for receiving a signal to be transmitted as described above will be described.

Since the kernel signal formed by the K tone signals is used to lower the PAPR of the signal transmitted from the transmitter, the signal received by the receiver includes the kernel signal component consisting of the K tones. This will interfere with the desired signal and must be removed. To this end, the reception apparatus according to the embodiment of the present invention removes the kernel signal component included in the received signal by using a tone removal filter or an adaptive digital filter.

5 is a structural diagram of a receiving apparatus according to an embodiment of the present invention.

As shown in FIG. 5, the receiving apparatus according to the embodiment of the present invention, as shown in FIG. 5, multiple signals for multiplying and demodulating a carrier by N received signals obtained by separating the received signal for each carrier, respectively. Multipliers 121 to 12N, a plurality of tone rejection filter units 131 to 131N for removing kernel signal components from the demodulated N received signals, and a plurality of matched filters for matching the received signals output from the respective tone remove filters 141-14N, and a plurality of despreaders 151-15N for despreading each matched received signal and a plurality of decoders 161-16N for decoding the despread received signal. The tone removing filter unit 131 to 13N is a digital filter for removing L tone signals belonging to a corresponding carrier band among K tone signals.

The signal multiplier, matched filter, despreader, and decoder in a receiving device having such a structure are well known in the art, and thus detailed descriptions thereof are omitted here.

6 is a flowchart illustrating a receiving method according to an embodiment of the present invention.

In the receiving apparatus according to the embodiment of the present invention, as shown in FIGS. 5 and 6, the received signal demodulated for each carrier by the signal multipliers 121 to 12N is input to the tone removing filter parts 131 to 13N. (S300 to S310), the tone removing filter unit 131 to 13N removes the L tone signals belonging to the carrier band among the K tone signals, thereby preventing the performance from being degraded due to the transmission signal distortion caused by the kernel signal ( S320). The received signal from which the kernel signal component is removed is used after despreading and decoding (S330 to S340).

On the other hand, when the transmitter can transmit the information about the K tone frequencies used to generate the kernel signal to the receiver through the signaling channel, the tone removal filter unit 131 to 13N shown in FIG. The L tone cancellers (F1 to FL) filters connected in series can be used to remove the tone signals included in the received signal. FIG. 7 is an exemplary view showing the structure of the tone removing filter parts 131 to 13N shown in FIG. 5.

However, when the transmitter cannot transmit the tone information used to generate the kernel signal, as shown in FIG. 8, narrowband interference cancellation is performed by using an adaptive digital filter as a method for removing a large number of tones. can do. FIG. 8 is a diagram illustrating an example in which the tone removing filter units 131 ′ through 13 N ′ shown in FIG. 5 are implemented as an adaptive narrow band interference cancellation unit.

In FIG. 8, the narrowband interference cancellation unit may be easily implemented using an algorithm such as a least mean square (LMS) in the form of a finite impulse response (FIR) filter. The use of the narrowband interference canceller described above can be effectively applied to systems using direct sequence spread spectrum signals as is well known.

By using such a filter, if the tone signal is properly removed from the received signal so as not to affect the performance of the received signal, the PAPR of the signal can be lowered without loss of data rate as in OFDM.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

According to the embodiment of the present invention described above, unlike the tone reservation scheme of OFDM, by effectively eliminating the signal used in the receiver to reduce the PAPR of the transmission signal to the serial bank of the adaptive digital filter or tone rejection digital filter, PAPR can be effectively reduced without reducing the throughput.

Claims (14)

In the method for reducing the peak to average power ratio (PAPR) of the signal at the transmitting end of a direct sequence code division communication system using a multi-carrier a) obtaining a spread spectrum modulated multiple modulated signal; b) measuring the magnitude of the maximum value beyond any threshold in the multiple modulated signal and measuring the time at which the maximum value is detected; c) summing several tone signals in the band to produce a kernel signal that is an impulsive pseudo noise in the time domain; d) shift the time axis of the kernel signal to the time at which the maximum value of the multiple modulated signal measured in step b) is detected, and shift the magnitude of the kernel signal to the difference between the magnitude of the maximum value and the set maximum allowed power value. Varying proportionally to produce an attenuation signal; And e) subtracting the attenuation signal from the multiple modulated signal and transmitting Maximum power to average power ratio reduction method comprising a. The method of claim 1 Demodulating the received signal for each carrier after receiving a signal transmitted from the transmitter at a receiver; And Removing a tone signal component used in a kernel signal by using a tone removal filter on the demodulated signal for each carrier The maximum power to average power ratio reduction method further comprising. The method of claim 2 When information on the tone signal used when generating the kernel signal at the transmitting end is provided to the receiving end, the respective tone removing filters for removing the signal of the frequency corresponding to each of the used tone signals are connected in series to receive the received signal. A method of reducing the maximum power to average power ratio that removes the tone signal components from the signal. delete The method according to any one of claims 1 to 3 In step a), the multi-modulated signal is stored in a buffer for M symbol period M * T time and is output from the buffer in units of M symbol intervals. The method according to any one of claims 1 to 3 In the case of using the time division duplex method in step a), the method of reducing the maximum power to average power ratio of storing the multi-modulated signal in a buffer in time slots as a transmission / reception time change unit. In the transmitter of the direct sequence code division communication system using a multi-carrier, A plurality of spreading and modulating units respectively spreading and modulating a plurality of data streams to be transmitted; A plurality of signal multipliers for modulating each data stream using a carrier wave; A first signal adder configured to generate a multiple modulated signal by mixing signals output from the plurality of signal multipliers; An attenuation signal generator that uses the multiple modulated signal as an input signal and generates an attenuation signal based on the input signal; A second signal adder configured to mix the attenuation signal and the multiple sign signal output from the first signal adder to output a maximum power removal signal; A PAPR reduction controller configured to compare the PAPR of the maximum power removal signal with a set threshold and output the maximum power removal signal as a transmission signal when the PAPR of the maximum power removal signal does not exceed a set threshold; And A transmitter for processing and transmitting a transmission signal output from the PAPR reduction controller Transmission device comprising a. The method of claim 7, And the PAPR reduction controller returns the maximum power removal signal to the attenuation signal generator when the PAPR of the maximum power removal signal exceeds a set threshold. The method of claim 8 A first switch unit configured to drive a predetermined modulated signal stored in the buffer to the attenuation signal generator or to input the maximum power removal signal fed back from the PAPR reduction controller to the attenuation signal generator; And A second switch unit for transmitting a signal output from the PAPR reduction control unit as a transmission signal to the transmission unit Transmission device further comprising. The method according to any one of claims 7 to 9. The attenuation signal generator A kernel signal generator for generating an impulsive pseudo noise signal as a kernel signal in a time domain by adding arbitrary K tone signals in a band in which N multicarriers exist; A maximum power meter measuring a magnitude of a maximum power of a signal input from the buffer and measuring a time at which the maximum power is measured; A time axis mover for removing the maximum power component of the input signal by moving the kernel signal output from the kernel signal generator to the measured time position according to the measured time; And  A scaler for scaling the time-shifted kernel signal to be proportional to a difference between the maximum power value of the input signal and a set maximum allowable power value and outputting the attenuated signal Transmission device comprising a. The method of claim 10 The kernel signal generator K tone signal generators each generating a tone signal; And A mixer that mixes the generated K tone signals and outputs them as kernel signals Transmission device comprising a. In a receiving apparatus for receiving a signal transmitted from a transmitting apparatus of a direct sequence code division communication system using a multicarrier, The signal transmitted from the transmitting device is a signal obtained by subtracting an attenuation signal from a signal to be transmitted, the attenuation signal being generated by adding several tone signals in a band and based on a kernel signal which is an impulsive pseudo noise in the time domain. Is, The receiving device A plurality of signal multipliers for receiving a signal transmitted from the transmitting device and multiplying and demodulating a carrier by N received signals obtained by separating the received signal for each carrier; A plurality of tone removal filters for removing tone signal components according to the kernel signal from demodulated N received signals; A plurality of matched filters for matching the received signal output from each tone rejection filter; A plurality of despreaders which despread each matched received signal; And Multiple decoders to decode the despread received signal Receiving device comprising a. The method of claim 12, The tone rejection filter is a receiver that is connected in series with each filter for removing a signal of a frequency corresponding to each tone used to generate the kernel signal. delete

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