KR100209876B1 - Device for transmitting filter coefficient of ghost canceller - Google Patents

Abstract

The present invention relates to a filter coefficient transmission device of a ghost eliminator for removing ghosts generated by reflected waves during the terrestrial broadcast transmission of a TV signal. The filter coefficient transmission device of the present invention is located between a digital signal processor and a transversal digital filter. A vertical blanking unit for separating only the vertical blanking signal from the composite synchronous signal; A control signal generator for generating a filter coefficient transmission control signal synchronized with the vertical synchronization signal in the vertical blanking signal thus separated; A filter coefficient buffer for buffering the filter coefficient output from the digital signal processor according to the separated vertical blanking signal; In accordance with the filter coefficient transmission generated by the control signal generator, the filter coefficient latch unit transmits the filter coefficient only during the vertical blanking period, and transmits the filter coefficients only during the vertical blanking period of the video signal. Prevents instantaneous image quality deterioration caused by flickering or noise.

Description

Filter Coefficient Transmitter of Ghost Eliminator

1 is an overall block diagram of a typical ghost eliminator.

2 is a block diagram showing a first embodiment of the filter coefficient transmission apparatus of the present invention.

3 is each sub waveform diagram of the first embodiment of the filter coefficient transmission device of the present invention.

4 is a block diagram showing a second practical example of the filter coefficient transmission device of the present invention.

5 is each sub waveform diagram of a second embodiment of a filter coefficient transmission device of the present invention.

* Explanation of symbols for main parts of the drawings

10 digital signal processor 21 vertical blanking separator

22: control signal generator 23: filter coefficient latch

24: filter coefficient buffer 25: inverter

30: transversal digital filter

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ghost canceller that removes multiple images (hereinafter referred to as ghosts) generated by reflected waves during the terrestrial broadcast of television signals. The present invention relates to a filter coefficient transmission device of a ghost eliminator that enables transmission to a digital filter without using a filter.

As the current TV broadcast signal is a terrestrial broadcast signal, the signal is distorted due to the reflection of the transmission signal by the reflector, the distortion caused by the non-ideal channel characteristics of the air, the transmission medium, and additional noise. As the TV broadcast signal passes through a multipath channel, a difference in time delay and attenuation of a signal occurs along a path, and as a result, a ghost phenomenon occurs in which several images are simultaneously overlapped on a main image of a TV screen. This ghost phenomenon has a greater impact on image quality than other additive noise. In particular, more serious problems may occur in the case of information service media such as text multiplexing. That is, if a transmission code is misinterpreted as another code by a ghost signal, wrong letters or figures appear.

The research on the technology for eliminating such ghost phenomenon has been steadily progressed, and one of them is the transmission of a ghost cancellation reference signal (GCR signal) when transmitting a TV broadcast signal. By detecting this GCR signal on the receiving side, a study of a technique of removing the ghost component by analyzing the distortion degree of the signal due to the multipath channel characteristics has been conducted.

1 is a block diagram of a general ghost eliminator, briefly explaining its operation as follows.

When the analog composite video signal is input to the ghost eliminator, the synchronous signals separated by the synchronous segregation clock generator are input to the system controller and used as a reference signal for controlling the ghost eliminator as a whole.

The input analog composite video signal is inputted to the transversal filter 30 through an A / D converter and corrected and output as a video signal from which ghosts are removed by filter coefficients transmitted from the digital signal processor 10.

On the other hand, the digital signal processor 10 reads the GCR signal (initial) passed through the multi-path of the video signal detected by the FIFO, the GCR signal from which the ghost is removed, and the reference GCR signal stored in the ROM to process the signal for characterizing the channel. Perform the operation to get the digital filter coefficients needed for ghost rejection. These digital filter coefficients are transmitted to the transversal digital filter 30 to output an image signal from which ghosts are removed by the transversal digital filter 30.

Conventionally, in transmitting the digital filter coefficient required for ghost elimination, the digital signal processor 10 immediately transmits the filter coefficient to the transverse digital filter 30 so that the screen flickers due to the transmission of the filter coefficient on the TV screen. Or noise appeared, causing a problem of instantaneous image quality deterioration. Therefore, in order to solve this conventional problem, an object of the present invention is to allow the filter coefficient to be transmitted only during the vertical blanking period.

In order to achieve the above object, the filter coefficient transmission device of the present invention is positioned between the digital signal processor 10 and the transversal digital filter 30, and a vertical blanking separator for separating only the vertical blanking signal from the composite synchronous signal. ; A control signal generator for generating a filter coefficient transmission control signal synchronized with the vertical synchronization signal in the separated vertical blanking signal; A filter coefficient buffer for buffering the filter coefficient output from the digital signal processor according to the separated vertical blanking signal; And a filter coefficient latch unit for transmitting the filter coefficient only during the vertical blanking period according to the filter coefficient transmission control signal generated by the control signal generator.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 2 through 5.

[First Embodiment]

FIG. 2 is a block diagram showing a first embodiment of the filter coefficient transmission device of the present invention, and FIG. 3 shows each sub waveform of FIG. 2 with respect to the first embodiment of the filter coefficient transmission device of the present invention.

When the composite synchronous signal of the TV signal as shown in FIG. 3 is input to the input terminal of the vertical blanking separator 21 of FIG. 2, the vertical blanking signal of the waveform shown in FIG. The vertical blanking signal ⓑ thus separated is input to the control signal input terminals of the filter coefficient transmission control signal generator 22 and the low level active pin filter coefficient buffer unit 24. The vertical blanking signal input to the filter coefficient transmission control signal generator 22 is generated by a control signal generator as a signal such as? In FIG. 3 synchronized with the vertical synchronous signal Vsync during the vertical blanking period, and thus the filter coefficient latching unit 23 is used. It is input to the clock input terminal of.

On the other hand, the digital signal processor (DSP) receives various signals, calculates the digital filter coefficient required for ghost removal, inputs it to the data input terminal of the filter coefficient buffer unit 24, and the input signal is input to the control signal of the filter coefficient buffer unit. It is controlled by the vertical blanking signal inputted to the terminal. The filter coefficient buffer 24 outputs the filter coefficients to the output terminal only when the signal ⓑ of FIG. 3 is at a low level. The filter coefficients passing through the buffer part are input to the data input terminal of the filter coefficient latch unit 23, and then the rising edge of the filter coefficient is input by the? Signal of FIG. Rising Edge) is output to the output terminal. The signal thus output is a filter coefficient of the ghost eliminator and is input to the instrument input terminal of the ghost elimination transversal digital filter 30. The transmitted filter coefficients are applied to the transverse digital filter 30 to remove ghosts.

The above description will be described below with reference to FIG. 3. The signal ⓐ is a composite synchronization signal of the TV signal; The ⓑ signal is a vertical blanking signal of the composite synchronous signal of the TV signal and is input to the control signal input terminal of the filter coefficient buffer unit so that the digital filter coefficient passes through the filter coefficient buffer unit only at a low level. ; The signal ⓒ is a filter coefficient transmission control signal synchronized with the vertical synchronization signal during the vertical blanking period, and is input to the clock input terminal of the filter coefficient latching unit 23 so that the filter coefficient is converted at the rising edge of the signal. To the digital filter 30. In general, the filter coefficient transmission speed of the digital signal processor is much faster than the vertical blanking signal period of the video signal. Therefore, generating a control signal with a narrow pulse width such as ⓒ to control the transmission of the filter coefficient to prevent unnecessary malfunctions is efficient. Can be. As described above, by the filter coefficient transmission device of the present invention, the ghost removal filter coefficient is transmitted only during the vertical blanking period of the video signal.

Second Embodiment

FIG. 4 is a block diagram showing a second embodiment of the filter coefficient transmission device of the present invention, and FIG. 5 shows each of the sub-waveforms of FIG. 4 with respect to the second embodiment of the filter coefficient transmission device of the present invention.

Compared to the first embodiment, the second embodiment adds an inverter 25 for inverting the vertical blanking signal and uses a filter coefficient buffer that is high level active. Hereinafter, a second embodiment of the present invention will be described with reference to FIGS. 4 and 5.

When the composite synchronous signal of the TV signal as shown in FIG. 5 is input to the input terminal of the vertical blanking separator 21 in FIG. 4, the vertical blanking signal having the waveform as shown in FIG. Only output The vertical blanking signal ⓑ thus separated is input to the filter coefficient transmission control signal generator 22 and the inverter 25. The signal input to the filter coefficient transmission control signal generator 22 is generated by the control signal generator as a signal such as ⓒ of FIG. 5 in synchronization with the vertical synchronization signal Vsync, and is a clock input terminal of the filter coefficient latching unit 23. On the other hand, the vertical blanking signal input to the inverter 25 becomes a signal of FIG. 5, and is input to the control signal input terminal of the filter coefficient buffer 24 having high level active.

On the other hand, the digital signal processor 10 receives various signals, calculates digital filter coefficients necessary for ghost elimination, inputs them to the data input terminal of the filter coefficient buffer 24, and inputs the input signal to the filter coefficient buffer 24. Controlled by ⓓ of FIG. 5 input to the control signal input terminal of the filter, the filter coefficient is passed through the filter coefficient buffer 24 and output to the output terminal only when the signal of ⓓ of FIG. 5 is high level. The filter coefficients passing through the buffer part are input to the data input terminal of the filter coefficient latch unit 23, and then the rising edge is increased by the? Signal of FIG. 5, which is a filter coefficient transmission control signal input to the clock input terminal of the filter coefficient latch unit. The output signal is inputted to the coefficient input terminal of the ghost elimination strong-reversal digital filter 30 as a filter coefficient of the ghost eliminator. The transmitted filter coefficients are applied to the transversal digital filter 30 to remove ghosts.

The above description will be described below with reference to FIG. 5. The signal ⓐ is a composite synchronization signal of the TV signal; The ⓑ signal is input to the control signal generator 22 and the inverter 25 as a vertical blanking signal among the composite synchronization signals of the TV signal. ; The signal ⓓ is the inverted vertical blanking signal and is input to the control signal input terminal of the filter coefficient buffer 24 having high level active, so that the filter coefficients are passed only when the signal ⓓ is high level. ; © signal is a filter coefficient transmission control signal synchronized with the vertical synchronization signal during the vertical blanking period, and is input to the clock input terminal of the filter coefficient latch unit 23 so that the filter coefficient is converted at the rising edge of the signal. To the digital filter 30.

As described above, the filter coefficient is transmitted at the rising edge of the ⓒ signal of FIGS. 3 and 5 by the digital filter coefficient transmission device of the present invention, and at this moment, the ⓑ signal of FIGS. 3 and 5 is transmitted. It is within the vertical blanking period as shown in. Therefore, the filter coefficient transmitting device of the present invention transmits the ghost elimination filter coefficient to the transversal digital filter 30 only during the vertical blanking period of the video signal that does not appear on the TV screen, thereby causing flicker of the screen according to the filter coefficient transmission. Instantaneous quality deterioration such as noise or noise can be prevented.

Claims (3)

An apparatus for transmitting filter coefficients from a digital signal processor in a ghost elimination device to a transversal digital filter, comprising: a vertical blanking separator for separating only a vertical blanking signal from a composite synchronous signal of a video signal; A control signal generator for generating a filter coefficient transmission control signal synchronized with the forward simultaneous signal from the vertical blanking signal; A filter coefficient buffer for buffering the filter coefficient output from the digital signal processor; And a filter coefficient latch for transmitting the buffered filter coefficient only in the vertical blanking signal period and preventing the transmission in other periods according to the filter coefficient transmission control signal generator. The ghost agent according to claim 1, wherein the filter coefficients pass through the filter coefficient buffer only when the vertical blanking signal is at a low level by using the filter coefficient buffer as low level active. There is a filter coefficient transmission device. 2. The filter according to claim 1, wherein the filter coefficient buffer unit is of high level active and the filter is only used when the inverted vertical blanking signal is high level by adding an inverter between the vertical blanking unit and the filter coefficient buffer unit. Filter coefficient transmission device of the ghost eliminator, characterized in that the coefficients pass through the filter coefficient buffer.