KR20030052041A - Method for Automatic Compensating Linear in Digital Television Broadcasting System - Google Patents

Abstract

PURPOSE: A method for automatically compensating linearity in a digital television broadcasting system is provided to more accurately compensate linearity and non-linearity of a system far-end signal after compensating a linear error of a priority linear compensating receiver. CONSTITUTION: If ISA(Industry Standard Architecture) bus input I and Q digital input signals are inputted, it is judged whether an automatic alarm signal is generated(611). If so, a digital potentiometer step is adjusted(612). A reference signal is generated(613). An SNR(Signal-to-Noise Ratio) or an EVM(Error Vector Magnitude) is operated(614). It is judged whether the SNR or the EVM satisfies an ATSC standard(615). If so, it is judged whether the SNR or the EVM is executed five times(616). If so, the SNR or the EVM satisfies the ATSC standard five times(617). If not, the five-time count is set as '0'(619). If so, the automatic alarm signal is stopped and a coefficient generating signal is transmitted to linearity compensation software(618). If the SNR or the EVM does not satisfy the ATSC standard, a digital potentiometer step sweep algorithm is executed(620). The automatic alarm signal is generated and transmitted to linearity compensation software(621).

Description

Method for Automatic Compensating Linear in Digital Television Broadcasting System

The present invention has a complete linearity by compensating a system whose amplitude is not constant according to a frequency generated because a signal output from a transmitter or repeater system of a digital television broadcast is not complete in the frequency domain. It is a method to check linearly and automatically perform linearity compensation. In particular, the linearity and nonlinearity of the RF board affects the output data of the entire correlator. And an automatic compensation method for linearity and nonlinearity of a digital television broadcast transmitter or repeater system which can accurately extract nonlinearity.

In the conventional digital television broadcasting, the linearity compensation device using digital filter coefficients is as shown in FIG. 1.

Referring to FIG. 1, a conventional linearity compensation device using digital filter coefficients is a linear compensation device using an adaptive equalizer of a vector signal analysis instrument, and may be classified into a transmitter 1 and a linear compensation receiver 2. The transmitter 1 comprises a modulator 3, a digital filter 4, a frequency up-converter 5, a high output amplifier 6, a coupler 7, and an antenna 8. The linear compensation receiver 2 is composed of a vector signal analysis instrument 9 and a computer 10, and the vector signal analysis instrument 9 is composed of a demodulator 11 and a frequency down converter 12. Inside the computer 10 is included linear compensation software 13 to perform linear compensation.

The conventional linearity compensation device using the adaptive equalizer of the vector signal analysis instrument 9 operates as follows.

The broadcast data input from the broadcasting station is input to the modulator 3, and passes through a digital filter 4 having a function of eliminating interference between symbols through channel coding for error correction, pilot signal insertion, and waveform shaping in the modulator 3. Next, 8VSB (Vestigial SideBand) modulation is performed to convert to an intermediate frequency band of 44MHz. Here, the frequency of the intermediate frequency band signal output from the modulator 3 is up-converted via the frequency upconverter 5. This up-converted signal is made into a signal amplified by the high power amplifier 6 to deliver the digital television signal to the general subscriber via the antenna 8.

However, when passing through the high power amplifier 6, the signal is not completely linear and the spectrum is distorted. Therefore, the operator operating the transmitter or repeater always uses the vector signal analysis instrument 9 to output the high power amplifier. After checking the linearity of the digital ?? vision signal outputted through (6), linear compensation is operated. When the operator operates the linear compensation, the output signal of the high output amplifier 6 is received through the coupler 7 to the linear compensation receiver 2, and the demodulator 11 of the vector signal analyzer is included in the demodulator 11. The adaptive equalizer algorithm of the adaptive equalizer is used to generate coefficients of the equalizer that optimize the received signal.

The signal passing through the equalizer in the optimization process improves the signal-to-noise ratio (SNR), and the operator checks the signal-to-noise ratio value of the vector signal analyzer 9 to see if it is optimized with the received signal and then equalizes it. The 33 coefficients are transmitted to the linear compensation software 13 via a General Purpose Interface Bus (GPIB) interface. The linear compensation software 13 then makes 288 33 coefficients and sends them to the digital filter 4 inside the modulator 3 via an RS232 cable.

The equalizer coefficients transmitted to the digital filter 4 of the modulator 3 are to distort the modulated signal in advance so that the final antenna 8 outputs a clean signal with distortion compensated.

Since the software is operated by the operator, the operator uses the equalizer of the conventional vector signal analysis instrument, so the operator always checks the linearity of the high power amplifier. have.

That is, the linearity compensation device using the conventional digital filter coefficients cannot automatically compensate linear compensation.

Accordingly, an object of the present invention is to compensate for a system whose amplitude is not constant according to a frequency generated because a signal output from a transmitter or repeater system of a digital television broadcast is not perfect in the frequency domain of the transmitter or repeater. The present invention provides a method for automatically performing linearity compensation by periodically checking to have linearity.

In order to achieve the above object, the present invention converts the RF signal of the linear compensation receiver into an intermediate frequency to operate the linear compensation software for improving the linear characteristics of the high power amplifier in a transmitter or repeater system of a digital television broadcasting. And linearly extracting and correcting linearity of the linear compensation receiver generated in the process of demodulating the I and Q signals.

1 is a block diagram of a linearity compensation device using conventional digital filter coefficients.

2 is a block diagram of an automatic linearity compensation device according to the present invention.

3 shows signal band characteristics before and after compensation;

4 is a shape diagram of I and Q digital signals input through an ISA bus;

5 is a shape diagram of a reference signal made from I and Q digital signals input through an ISA bus.

6 is a compensation procedure according to the present invention.

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

2 is a block diagram of an automatic linearity compensation apparatus in a digital television broadcasting system according to the present invention, and includes a transmitter 14 and a linear compensation receiver 15.

Referring to FIG. 2, the transmitter 14 includes a modulator 16, a digital filter 17, a frequency up converter 18, a high output amplifier 19, a coupler 20, and an antenna 21. The linear compensation receiver 15 is composed of a correction board 22 and a computer 23, the correction board 22 includes a demodulator 24 and a frequency downconverter 25, and the computer 23 calibrates an RF board. 26 and linear compensation software 27.

First, broadcast data input from a broadcasting station is input to the modulator 16, and the modulator 16 receives a digital filter 17 having a function of eliminating interference between symbols through channel coding for error correction, pilot insertion, and waveform shaping. To pass. Next, 8VSB (Vestigial Side Band) modulation is performed and converted into an intermediate frequency band of 44 MHz, and the signal of the intermediate frequency band output from the modulator 16 is up-converted through the frequency upconverter 18. This up-converted frequency is made into a signal amplified by the high output amplifier 19 to deliver the digital television signal to the general subscriber via the antenna 21.

However, when passing through the high power amplifier 19, it does not have a perfect linearity and the spectrum is distorted.

The present invention inputs the signal of the high output amplifier 19 to the correction board 22 through the coupler 20, and then down-converts the attenuator and the up-converted frequency to an intermediate frequency of 44 MHz via the frequency down converter 25. Passing through demodulator 24 allows the extraction of digital signals I and Q. The extracted digital signal is input to the RF compensator 26 through an industry standard architecture (ISA) bus to calculate a signal-to-noise ratio and an error vector amplitude value.

If the signal-to-noise ratio or error vector amplitude value is out of ATSC standard (less than 29dB in case of signal-to-noise ratio), the clock of the digital potentiometer of the frequency down converter 25 is automatically changed. By applying the most suitable clock, the best signal-to-noise ratio EH is made to the error vector amplitude value and then linear compensation software 27 is operated to operate the adaptive equalizer contained within the software.

When the adaptive equalizer according to the present invention is operated, the signal-to-noise ratio is increased or the error vector amplitude value is decreased, which satisfies the ATSC standard. Before going through this series of linear compensation software, make the signal in Fig. 2A the ideal signal (i.e., make the signal in (A) the cleanest signal after the existing configuration and operation of linear and nonlinear compensation). Connect the signal to the linear compensation receiver 15, extract the linear data of the RF board from the ideal received signal, apply it to the RF board calibration 26, and then make the best signal-to-noise ratio or error vector amplitude value at the next stage. A process of adjusting the clock of the digital potential meter of the frequency down converter 25 is necessary.

That is, when the RF compensator 26 passes, the linear data error is RF compensated compared to the reference signal. After the linearity of the RF board is completely compensated, the signal of the high frequency amplifier 19 is linearly compensated. Will be added to

Then, since the linearity of this receiving RF board has already been compensated, the ideal signal level (input signal level when performing RF board compensation) and high frequency when the linear and nonlinearity of the high frequency amplifier 19 are purely extracted by the linear and nonlinear compensation software. The difference with the signal level of the amplifier 19 can be adjusted in 0.05 dB increments only by adjusting the digital potentiometer clock, which produces a difference in input level and can reduce the difference in the level.

The adjustment is done by calculating the signal-to-noise ratio at the end of the RF board adjustment, adjusting the input digital potentiometer to obtain the best signal-to-noise ratio, applying it to the digital potentiometer, and then applying linear compensation software to apply linear and nonlinear values. When extracted and downloaded to the modulator RS-232C of the transmitter and repeater, the signal-to-noise ratio of the high frequency amplifier 19 satisfies the ATSC standard.

When the RF board linearity data is extracted from the RF board calibration 26 and the RF board linearity data error compensation is performed, the linear compensation receiver 15 becomes a perfect received signal without linear error, and the signal from the high frequency amplifier 19 Upon entering the linear compensation receiver 15, the clock of the digital potentiometer of the frequency down converter 25 is inputted by a digital potentiometer step sweep algorithm after the RF board calibration 26. After making the best signal-to-noise ratio by adjusting, the linear and nonlinear data of the high frequency amplifier 19 is extracted by the linear compensation software 27, and the data is downloaded to the modulator 16 as RS-232, resulting in a clean signal.

Referring to Fig. 3, before performing linear compensation, the signal seen at the antenna final output is equal to (A), and when this signal is passed through the linear compensation software, it is adaptive equalized with the opposite characteristics of the original signal as (B). Q coefficients are created and applied to the digital filter of the modulator to output a clean signal band characteristic signal as shown in (C).

6 shows an automatic linearity compensation process according to the present invention.

2 and 6, when the ISA bus input I and Q digital input signals are input, it is determined whether an automatic alarm signal is generated in step 611. If it is determined that the automatic alarm signal has been generated, the digital potentiometer step is adjusted in step 612. In operation 613, a reference signal is generated, and in operation 614, a signal-to-noise ratio SNR or an error vector value EVM is calculated. In step 615, it is determined whether the ATSC rule (SNR or EVM) is satisfied.

If it is determined that the ATSC specification (SNR or EVM) is satisfied, it is determined whether or not it has been performed five times in step 616. If it is determined that five times have been performed, it is determined whether all five times of step 617 satisfy the ATSC rule. If it is determined that all five times do not satisfy the ATSC rule, in step 619, the count is set to zero.

On the other hand, if it is determined that all five times satisfy the ATSC specification, in step 618, the automatic alert signal stop and the coefficient generation signal are transmitted to the linear compensation software.

On the other hand, if it is determined that the ATSC rule is not satisfied, the digital potentiometer step sweep algorithm is performed in step 620, and the automatic alarm signal generation and linear compensation software is transmitted in step 621.

As described above, when the transmitter or repeater system of the digital television broadcast is operated, the linear compensation receiver is first detected by automatically detecting that the signal-to-noise ratio or error vector amplitude value of the final signal passing through the antenna exceeds the ATSC specification. After compensating for the linear error of, the linear and nonlinearity of the system termination signal can be compensated more accurately in linear compensation software.

Claims (2)

In the digital television broadcasting system, linearity automatic compensation method, Converting the high output amplifier output signal into a baseband signal as an input; Operating an adaptive equalizer according to a change in a signal-to-noise ratio or an error vector amplitude value of the converted signal; A method for automatically compensating for linearity in a digital television broadcasting system, comprising generating coefficients of a linearity compensation digital filter and performing linear compensation. In the digital television broadcasting system, linearity automatic compensation method, Automatically compensates linearity in digital television broadcasting systems, which converts the measured signal from the high-power amplifier output to a baseband signal, converts it to a baseband signal, and then performs RF board compensation of the linear compensation receiver and then digitally adjusts the level of the input signal. Way.