KR20020093313A - digital predistorter - Google Patents

Abstract

PURPOSE: A digital pre-compensator is provided to linearize a base station power amplifier capable of being installed on a unified board of a baseband and RF(Radio Frequency) up/down converter of a base station system. CONSTITUTION: A digital modulator(101) modulates data into a digitalized successive signal. An A/D converter(201) receives an analog baseband signal generated in the digital modulator(101) and converts the received analog baseband signal into a digital signal. A time delay(207) delays the distortion of the baseband digital signal of the A/D converter(201). A DSP(Digital Signal Processor) performs the pre-compensation of the digital signal of the A/D converter(201) by an adaptive algorithm(202b). A D/A converter(203) converts the baseband digital signal pre-compensated in the DSP(202) into an analog signal. An IF(Intermediate Frequency) local oscillator(104) generates an IF signal. An orthogonal modulator(102) converts the baseband signal of the D/A converter(203) into an IF signal by the IF signal generated in the IF local oscillator(104). An RF local oscillator(105) generates an RF signal. A frequency up-converter(103) converts the IF signal of the orthogonal modulator(102) into an RF signal by the RF signal generated in the RF local oscillator(105). A power amplifier(300) amplifies the RF signal of the frequency up-converter(103). A frequency down-converter(204) downs the output signal of the distributed power of the power amplifier(300) and generates an IF signal. An orthogonal demodulator(205) converts the IF signal of the frequency down-converter(204) into a baseband signal. An A/D converter(206) converts the analog baseband signal of the orthogonal demodulator(205) into a digital signal.

Description

Digital predistorter

The present invention relates to linearization of a high frequency power amplifier for a base station, and more particularly, to a digital predistorter having an improved linearization characteristic by mounting a digital predistorter on a BUDA board.

1 is a circuit diagram of a conventional digital predistorter, as shown therein, a digital modulator 11 for modulating data into a digitized continuous signal, an intermediate frequency local oscillator 14 for generating an intermediate frequency signal, and An orthogonal modulator 12 for converting a digital signal of the digital modulator 11 into an intermediate frequency by the intermediate frequency signal generated by the intermediate frequency local oscillator 14, a high frequency local oscillator 15 for generating a high frequency signal, And a frequency up converter 13 comprising a frequency up converter 13 for converting an intermediate frequency signal of the quadrature modulator 12 into a high frequency signal by a high frequency signal generated by the high frequency local oscillator 15. A frequency down converter 21 for generating an intermediate frequency by downgrading the high frequency signal of 13) and a baseband signal for the intermediate frequency of the frequency down converter 21; The orthogonal demodulator 22 to be generated, the A / D converter 23 for converting the analog baseband signal of the orthogonal demodulator 22 into a digital signal, and the distortion of the baseband digital signal of the A / D converter 23. A time delay 32 for delaying the signal, a DSP 24 for precompensating the digital signal of the A / D converter 23 by the adaptive algorithm 24b, and the DSP 24. D / A converter 25 for converting the predistorted baseband digital signal into an analog signal, and the intermediate frequency signal generated by the intermediate frequency local oscillator 34 in the baseband signal of the D / A converter 25. An orthogonal modulator 26 for converting the intermediate frequency signal into an intermediate frequency by the high frequency signal, and a frequency up converter 27 for converting the intermediate frequency signal of the orthogonal modulator 26 into a high frequency signal by the high frequency signal generated by the high frequency local oscillator 33; The high frequency signal of the frequency up converter 27 A power supply amplifier 28 for amplifying, a frequency down converter 29 for generating an intermediate frequency by lowering an output signal of the distributed power of the power amplifier 28, and an intermediate frequency of the frequency down converter 29 are based on. Single Channel Power Amplifier (SCPA) (or HPA) comprising an orthogonal demodulator 30 for generating a band signal and an A / D converter 31 for converting the analog baseband signal of the orthogonal demodulator 30 into a digital signal; It is configured to include a Multi Channel Power Amplifier (MCPA) (or LPA) 20, and will be described with reference to this.

In the BUDA board (referred to as the base board of the base station system and the integrated board of the high frequency up / down converter) 10, the band signal modulated by the digital modulator 11 is subjected to I & Q modulated intermediate through a quadrature modulator 12. After obtaining an Intermediate Frequency (IF) signal and generating a desired Radio Frequency (RF) signal through the frequency upconverter (13), a power amplifier of SCPA (or HPA) or MCPA (or LPA) 20 ( HPA, LPA) (28).

In order to precompensate the high frequency signal to the baseband signal in the HPA or LPA 20, the high frequency signal is converted into an intermediate frequency signal through the frequency downconverter 21 and then made into a baseband signal in the orthogonal demodulator 22, and A / Predistortion is performed by an adaptation algorithm 24b in a digital signal processor (DSP) 24 via a D / A converter 23, and the D / A converter 25 After converting into an intermediate frequency signal through the orthogonal modulator 26 and making it into a high frequency signal by the frequency up-converter 27, the power amplifier 28 has an output signal having a linearized characteristic.

The power is distributed from the output signal to form an intermediate frequency signal through the frequency downconverter 29, and then the baseband signal is made again using the quadrature demodulator 30, and then the time delay 32 through the A / D converter 31. By comparing the non-distorted input baseband with the digital signal processor 24, the decision data for the adaptive algorithm is generated.

The intermediate frequency local oscillator (OSC) 14, 34 and the high frequency local oscillator 15, 33 are all orthogonal modulators 12 and quadrature demodulators 22 and frequency upconverters 13 and frequencies. It acts as a local oscillator for driving the down converter 21.

As described above, although the BUDA board and HPA or LPA are conventionally independent, the up-converted high frequency signal is again converted into a baseband signal through a frequency downconverter and an orthogonal demodulator, and then pre-compensated by a digital signal processor and then up-converted by the quadrature modulator and the frequency up. Since a high frequency signal must be made through the converter and then the input of the power amplifier, the circuit is large and complicated due to the large overlapping function with the BUDA board, which makes it difficult to implement and increases the manufacturing cost.

In addition, the use of a mid-frequency, high-frequency local oscillator independent of the BUDA board can be implemented with localized digital predistortion for specific systems. That is, since it cannot be commonly applied to DCN, PCS, WLL, IMT-2000, etc., there is a problem in that separate digital predistortion must be designed and applied to each base station.

Accordingly, the present invention was devised to solve the above problems, and to linearize a base station power amplifier which can be mounted on an integrated board of a baseband of a base station system and a high frequency up / down converter using a frequency compatible universal digital predistorter. The purpose is.

1 is a circuit diagram of a conventional digital predistorter.

2 is a circuit diagram of a digital predistorter applied to the present invention.

<Explanation of symbols for the main parts of the drawings>

10, 100: BUDA board 11, 101: digital modulator

12, 22, 26, 102: Quadrature Modulator

13, 27, 103: frequency up converter

14, 34, 104: intermediate frequency local oscillator

15, 33, 105: high frequency local oscillator

20: SCPA or MCPA

21, 29, 204: Frequency Down Converter

23, 31, 201, 206: A / D converter

24, 202: digital signal processing unit

24a, 202a: Predistorter 24b, 202b: Adaptive Algorithm

25, 203: D / A converter 28, 300: power amplifier

30, 205: Orthogonal demodulator

32, 207: time delay 200: digital predistorter

ANT: Antenna

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Digital predistorter applied to the present invention,

A digital modulator for modulating data into a digitized continuous signal, an A / D converter for receiving an analog baseband signal generated by the digital modulator and converting the data into a digital signal, and a distortion of the baseband digital signal of the A / D converter A time delay for delaying the signal, a DSP for precompensating the digital signal of the A / D converter by an adaptive algorithm, and a preband compensated baseband digital signal of the DSP for converting the analog signal to an analog signal. A D / A converter, an intermediate frequency local oscillator for generating an intermediate frequency signal, an orthogonal modulator for converting the baseband signal of the D / A converter into an intermediate frequency by an intermediate frequency signal generated by the intermediate frequency local oscillator, A high frequency local oscillator for generating a high frequency signal, and an intermediate frequency signal of the quadrature modulator A frequency up converter for converting a high frequency signal by a high frequency signal generated by a true machine, a power amplifier for amplifying the high frequency signal of the frequency up converter, and down the output signal of the distributed power of the power amplifier to generate an intermediate frequency And a frequency down converter, an orthogonal demodulator for generating an intermediate frequency of the frequency down converter as a baseband signal, and an A / D converter for converting an analog baseband signal of the orthogonal demodulator into a digital signal.

The intermediate frequency local oscillator and the high frequency local oscillator are shared with the digital predistorter and the Buda board.

The digital predistorter may be mounted on a buddha board.

FIG. 2 is a circuit diagram of a digital predistorter applied to the present invention. As shown therein, a digital modulator 101 modulating data into a digitized continuous signal and an analog baseband signal generated by the digital modulator 101 are shown. An A / D converter 201 for receiving a signal and converting it into a digital signal, a time delay 207 for delaying distortion of the baseband digital signal of the A / D converter 201, and the A / D converter 201. (DSP) 202 for predistorting the digital signal of the digital signal by the adaptive algorithm 202b, and D / A for converting the predistorted baseband digital signal of the DSP 202 into an analog signal. A converter 203, an intermediate frequency local oscillator 104 for generating an intermediate frequency signal, and a baseband signal of the D / A converter 203 by an intermediate frequency signal generated by the intermediate frequency local oscillator 104. Intermediate frequency A quadrature modulator 102 for converting, a high frequency local oscillator 105 for generating a high frequency signal, and an intermediate frequency signal of the quadrature modulator 102 are converted into a high frequency signal by the high frequency signal generated by the high frequency local oscillator 105. A frequency up converter 103 for converting, a power amplifier 300 for amplifying a high frequency signal of the frequency up converter 103, and an output signal of the distributed power of the power amplifier 300 are down to generate an intermediate frequency. A frequency down converter 204, an orthogonal demodulator 205 for generating an intermediate frequency of the frequency down converter 204 as a baseband signal, and an analog baseband signal of the orthogonal demodulator 205 for digital signal conversion. It is configured to include the A / D converter 206, and will be described with reference to this.

The frequency-compatible universal digital predistorter 200 can be easily mounted on the BUDA board 100, and the baseband signal generated by the digital modulator 101 of the BUDA board 100 is connected to the quadrature modulator 102 through port 1. Imported into the digital predistorter 200 without going through the frequency up-converter 103, and predistorted by the adaptive algorithm 202b in the digital signal processor 202 via the A / D converter 201, which is then converted into a D / A converter ( After passing through 203, the port 2 is returned to the BUDA board 100.

The pre-compensated baseband signal is converted back to an intermediate frequency through an orthogonal modulator 102 and made into a high frequency signal by the frequency up-converter 103, and then amplified by the power amplifier 300 to have an output signal having a linearized characteristic. To have.

The power is distributed from the output signal through port 5 of the digital predistorter 200, the intermediate frequency signal is made through the frequency downconverter 204, and the baseband signal is again generated using the quadrature demodulator 205. The digital signal processor 202 compares the undistorted input baseband signal through the time delay 207 via the / D converter 206 to produce judgment data for performing the adaptive algorithm 202b.

In addition, an intermediate frequency local oscillator and a high frequency local oscillator are shared with the BUDA board 100 through ports 3 and 4.

As described above, the present invention mounts the digital predistorter on the BUDA board and uses the baseband signal generated by the digital modulator of the BUDA board through the port 1 and the port 2 to the digital predistorter without using an orthogonal modulator and a frequency upconverter. Redundant circuits can be reduced.

In addition, the present invention improves the problems of the predistorter linearizer in the predistorter linearization technique, and the digital predistorter having improved linearization characteristics can be miniaturized, low-cost, easy to install, and the frequency of DCN, PCS, WLL, IMT-2000, etc. Compatible for

As described above, according to the present invention, by using the digital predistorter, it is possible to reduce the size of the board by reducing redundant circuits, to implement a cheap digital predistortion, and to share the intermediate frequency and high frequency local oscillators with the BUDA board. By using it, it is possible to reduce the cost of materials and to make it compact, and to implement frequency-compatible general-purpose digital predistortion that can be used in any base station system.

Claims (3)

A digital modulator for modulating data into a digitized continuous signal, an A / D converter for receiving an analog baseband signal generated by the digital modulator and converting the data into a digital signal, and a distortion of the baseband digital signal of the A / D converter A time delay for delaying the signal, a DSP for precompensating the digital signal of the A / D converter by an adaptive algorithm, and a preband compensated baseband digital signal of the DSP for converting the analog signal to an analog signal. A D / A converter, an intermediate frequency local oscillator for generating an intermediate frequency signal, an orthogonal modulator for converting the baseband signal of the D / A converter into an intermediate frequency by an intermediate frequency signal generated by the intermediate frequency local oscillator, A high frequency local oscillator for generating a high frequency signal, and an intermediate frequency signal of the quadrature modulator A frequency up converter for converting a high frequency signal by a high frequency signal generated by a true machine, a power amplifier for amplifying the high frequency signal of the frequency up converter, and down the output signal of the distributed power of the power amplifier to generate an intermediate frequency And a frequency down converter, an orthogonal demodulator for generating an intermediate frequency of the frequency down converter as a baseband signal, and an A / D converter for converting an analog baseband signal of the orthogonal demodulator into a digital signal. Predistortion Compensator. The digital predistorter of claim 1, wherein the intermediate frequency local oscillator and the high frequency local oscillator are shared with the digital predistorter and the BUDA board. The digital predistorter of claim 2, wherein the digital predistorter can be mounted on a buddha board.