KR100390483B1 - Method for canceling ghost of tv - Google Patents

Abstract

PURPOSE: A method for canceling ghost of a TV is provided to accurately cancel ghost by high-pass filtering a coefficient of a finite impulse filter with a converse characteristic of aperture distortion and downloading the same to a digital filter, and reduce the cost by storing a ghost canceling reference signal preliminarily compensating an aperture distortion characteristic. CONSTITUTION: An anti-aliasing filter(100) cancels radio frequency signal components included in a baseband signal for preventing aliasing. An ADC(Analog-to-Digital Converter)(110) converts an analog output signal of the anti-aliasing filter into a digital signal. A timing generator(120) detects a line loading a ghost canceling reference signal from the baseband signal. A ROM(130) stores the ghost canceling reference signal. An operator(140) compares a data signal of the line loading the ghost canceling reference signal with the ghost canceling reference signal for high-pass filtering the data signal by a frequency characteristic which is a converse of an aperture distortion characteristic. A digital filter(150) filters an output signal of the ADC converter by an output signal of the operator for compensating aperture distortion. A DAC(Digital-to-Analog Converter)(160) converts a digital output signal of the digital filter into an analog signal. A reconstructing filter(170) low-pass filters the output signal of the DAC converter.

Description

TV Ghost Removal

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ghost elimination device for a TV, and in particular, to eliminate ghosting by correcting an aperture distortion, which is a frequency characteristic attenuation phenomenon generated during analog / digital conversion or digital / analog conversion. Relates to a device.

In the conventional ghost elimination device, since the aperture correction is not performed, the output of the ghost eliminating device usually attenuates the high frequency frequency near 4 MHz, so that the detail part is hard to see. Therefore, in order to perform the aperture correction, conventionally, the peaking is applied near 4 MHz, which has a problem in that the phase characteristic becomes nonlinear, and on the other hand, the low frequency filter is used to compensate the low frequency filter at the rear of the digital / analog converter. To do this, there was a problem of using an expensive filter.

The object of the present invention is to solve the conventional problems, high-pass filtering the coefficients of the finite-length impulse filter obtained from the calculator as the inverse characteristics of the aperture distortion, and then downloaded to the digital filter, or the aperture distortion characteristics of the ROM The ghost of the TV which can remove ghost accurately while saving the cost by storing the ghost removal reference signal filtered by the inverse frequency characteristic in advance and using it to obtain the coefficients of the finite field and infinite field impulse filter. To provide a method of removal.

The ghost removal method of the TV for achieving the object of the present invention includes a first step of removing the high-frequency signal components included in the baseband signal, and then converting them into a digital signal; The filter coefficient is obtained by comparing the data signal of the line carrying the ghost elimination reference signal among the converted digital signals with the ghost elimination reference signal stored in the ROM, and filtering the filter coefficient with a frequency characteristic which is the inverse of the aperture distortion characteristic. Outputting the second step; A third step of compensating and outputting aperture distortion by filtering the digital signal of the first step with the high-pass filtered filter coefficient of the second step; And a fourth step of converting the output signal of the third step into an analog signal and performing low pass filtering.

According to another aspect of the present invention, there is provided a ghost removal method of a TV, comprising: a first step of storing, in a ROM, a ghost removal reference signal filtered with a frequency characteristic that is the inverse of the aperture distortion characteristic; Removing a high frequency signal component included in the baseband signal and converting the high frequency signal component into a digital signal; A third step of outputting a filter coefficient subjected to filtering of a frequency characteristic which is the inverse of the aperture distortion characteristic by comparing the data signal of the line carrying the ghost elimination reference signal among the converted digital signals with the ghost elimination reference signal stored in the ROM; Wow; A fourth step of compensating and outputting aperture distortion by filtering the digital signal of the second step with the filter coefficient of the third step; And a fifth step of converting the output signal of the fourth step into an analog signal and low-pass filtering the output signal.

The ghost removal apparatus of the TV for explaining the present invention includes an anti-aliasing filter 100 for removing the high frequency signal components included in the baseband signal to prevent the alias effect as shown in FIG. 1; An analog / digital converter (110) for converting the analog output signal of the anti-aliasing filter (100) into a digital signal and outputting the digital signal; A timing generator (120) for detecting a line carrying the ghost cancellation reference signal in the baseband signal; A ROM 130 storing a ghost removal reference signal; Aperture distortion is obtained by receiving a data signal of a line carrying the ghost removal reference signal detected by the timing generator 120 from the analog / digital converter 110 and comparing it with the ghost removal reference signal stored in the ROM 130. Digital output that compensates for aperture distortion by filtering the output signal of the calculator 140 and the analog / digital converter 110 that are high-pass filtered to the frequency characteristic that is the inverse of the characteristic to the output signal of the calculator 140. A filter 150; A digital / analog converter (160) for converting the digital output signal of the digital filter (150) into an analog signal and outputting the analog signal; The reconstruction filter 170 performs low pass filtering on the output signal of the digital / analog converter 160.

A detailed description will be given with reference to FIG. 1 and FIG. 2 showing frequency characteristic diagrams of the aperture distortion.

First, aperture distortion occurs when the width of the sampling pulse does not become an impulse but has a finite value in the sampling process according to the analog / digital conversion.

Usually the value is equal to the length of each pulse in the sampling pulse train. If the width of the sampling pulse train is equal to the period, the reciprocal of the period is taken as the sampling frequency (fs), and the frequency characteristic H (f) of the aperture distortion is

Will follow.

2 is a frequency characteristic diagram of the spread distortion, and as shown therein, it can be seen that the signal is attenuated by about -1 dB at 4 MHz. Aperture distortion decreases with higher sampling frequencies and with narrower sampling pulses.

Aliasing refers to a phenomenon in which adjacent spectra overlap each other in the frequency domain when sampling at frequencies less than twice the maximum frequency of an analog signal.

In other words, when the analog signal is sampled, the baseband spectrum repeatedly appears at a sampling frequency in the frequency domain. At this time, if the overlap occurs, it is impossible to recover the original signal in the time domain because the low frequency filter process cannot separate the spectrum of the original signal.

To prevent this, during the analog / digital conversion, low-pass filter processing is performed on the analog signal in advance to cut off the frequency exceeding 1/2 of the sampling frequency. Thus, when performing sampling or sample reduction, the overlapping of the input signal is avoided. A filter that limits the bandwidth to less than half the sampling frequency is referred to as anti-aliasing filter 100.

In other words, when the baseband signal is input, the anti-aliasing filter 100 removes a high frequency signal component from the baseband signal to prevent an aliasing effect in which the high frequency signal is incorrectly reconstructed into a low frequency signal when reconstructed after digital / analog conversion. It is for.

In general, when sampling at 14.3 MHz, the cutoff frequency of the anti-aliasing filter 100 is set to about 4-6 MHz.

A sample / hold or track / hold circuit may be included between the anti-aliasing filter 100 and the analog / digital converter 110, but it is assumed that the anti-aliasing filter 100 and the analog / digital converter 110 are included in the analog / digital converter 110.

As such, when the anti-aliasing filter 100 removes and outputs a high frequency component of the baseband signal, the analog / digital converter 110 converts the output analog signal of the anti-aliasing filter 100 into a digital signal, thereby calculating the operation unit 140 and the digital signal. To the filter 150.

On the other hand, the timing generator 120 detects a line carrying the ghost removal reference signal included in the baseband signal and transmits it to the calculator 140.

Accordingly, the calculator 140 receives the data signal of the line detected by the timing generator 120 from the analog / digital converter 110 and compares it with the ghost elimination reference signal stored in the ROM 130 to obtain a corresponding signal. High-pass filtering is delivered to the digital filter 150.

In more detail with respect to the operator 140, the operator 140 is composed of a microprocessor or a digital signal processor, RAM, ROM 130, etc., the ghost removal reference signal specified by the timing generator 120 By comparing the line data signal x (n) of cylinder TV broadcasting with the ghost removal reference signal d (n) stored in the ROM 130, the digital filter 150 coefficient which can remove the ghost is calculated digitally. Download to filter 150.

That is, a _k (n), b _k (n) to the computing unit 140 to minimize the mean square error between the digital filter 150, the output y (n) and ghost removal reference signal d (n) of the ROM 130, Calculate offline.

As described above, the operator 140 removes all ghosts, near ghosts, and performs a filtering to emphasize the high range of the signal a _k (n), which is a finite field impulse response that serves to equalize the waveform, and then download it to the digital filter 150. give.

An important point here is that when calculating the reverse characteristic of the aperture distortion in the operator 140, the filtering to emphasize the high frequency portion below the appropriate frequency to maintain the maximum ghost removal performance to suppress the noise. The actual value is limited to, for example, 4.2MHz or less (for NTSC TVs) to suppress noise.

Accordingly, the digital filter 150 receives the output signal of the calculator 140 as described above and processes the output signal of the analog / digital converter 110 accordingly to restore the original signal.

The digital filter 150 is composed of a cascade of a finite field impulse response filter and an infinite field impulse response filter.

That is, the digital filter 150 has a finite field (length N) and an infinite field (length N-1) in which an impulse response to a ghosted baseband signal x (n) is a _k (n) b _k (n), respectively. The output y (n) subjected to impulse response filtering is operated in real time to be equal to the ghost removal reference signal d (n) stored in the ROM 130.

If this is expressed as an expression, it is expressed as Equation 1 below.

Where n is the time index and is given as the sampling period.

The digital / analog converter 160 converts the output signal of the digital filter 150 into an analog signal and outputs the analog signal. The reconstruction filter 170 low-pass filters the output signal of the digital / analog converter 160.

Another method for removing the ghost is to first store the ghost removal reference signal that compensates for the aperture distortion characteristic when the ghost removal reference signal is stored in the ROM 130.

In other words, the frequency characteristic that is the inverse of the aperture distortion characteristic, that is, the pre-emphasized d (n) is stored in the ROM 130.

In this way, the line data signal x (n) of the TV broadcast containing the ghost removal reference signal designated by the timing generator 120 in the calculator 140 is compared with the ghost removal reference signal d (n) stored in the ROM 130. Calculate the coefficient of the digital filter 150 to remove ghost off-line, and then download the finite field impulse response a _k (n) to the digital filter 150 without performing filtering to emphasize the high range. Can be.

In more detail, when the digital filter 150 receives the output signal of the calculator 140 and processes the output signal of the analog / digital converter 110 accordingly, the digital / analog converter 160 operates in the following manner. Even when aperture distortion occurs, the normal original signal is output by the inverse characteristic of the aperture distortion characteristic that is compensated in advance.

As described in detail above, the present invention can remove ghosts by downloading the coefficients of the finite field impulse filter obtained from the calculator into a digital filter after high pass filtering as an inverse characteristic of aperture distortion, and also store the ghost removal reference signal in the ROM. By storing the ghost elimination reference signal, which compensates the sea aperture distortion characteristics in advance, the digital / analog conversion eliminates the need for an expensive low pass filter, thereby reducing costs and accurately eliminating ghosts.

1 is a block diagram of a TV ghost removal device for explaining the present invention.

2 is a frequency characteristic diagram of aperture distortion.

*** Explanation of symbols for main parts of drawing ***

100: anti-aliasing filter 110: analog / digital converter

120: timing generator 130: ROM

140: calculator 150: digital filter

160: digital / analog converter 170: reconstruction filter

Claims (2)

Removing a high frequency signal component included in the baseband signal and converting the same into a digital signal; The filter coefficient is obtained by comparing the data signal of the line carrying the ghost elimination reference signal among the converted digital signals with the ghost elimination reference signal previously stored in the ROM, and filtering the filter coefficient by a frequency characteristic which is the inverse of the aperture distortion characteristic. Outputting a second step; A third step of compensating and outputting aperture distortion by filtering the digital signal of the first step with the high-pass filtered filter coefficient of the second step; And a fourth step of converting the output signal of the third step into an analog signal and low-pass filtering the output signal. A first step of storing, in the ROM, a ghost cancellation reference signal filtered with a frequency characteristic that is the inverse of the aperture distortion characteristic; Removing a high frequency signal component included in the baseband signal and converting the high frequency signal component into a digital signal; A third step of outputting a filter coefficient subjected to filtering of a frequency characteristic which is an inverse of the aperture distortion characteristic by comparing a data signal of a line carrying a ghost elimination reference signal among the converted digital signals with a ghost elimination reference signal stored in the ROM; Wow; A fourth step of compensating and outputting aperture distortion by filtering the digital signal of the second step with the filter coefficient of the third step; And a fifth step of converting the output signal of the fourth step into an analog signal and low-pass filtering the output signal.