KR0134271B1 - Improved ghost cancelling method - Google Patents

Abstract

The present invention relates to an improved ghost removal method, wherein a ghost removal reference signal having a different length on the transmitting side is first characterized by a channel characterization using a ghost removal reference signal having a relatively short length on the transmitting side. If there is a long ghost in the range where the removal reference signal cannot be detected, the ghost is continuously removed by using a relatively short ghost removal reference signal.If there is no long ghost, a relatively long ghost having a large signal energy is present. By removing the ghost using the removal reference signal, the ghost can be removed more adaptively.

Description

Improved Ghost Removal

1 is a schematic block diagram of a typical typical ghost cancellation reference signal transmitter.

2 is a waveform diagram illustrating a ghost elimination reference signal of a relatively long length and a ghost elimination reference signal of a relatively short length divided into four fields as an example of a ghost elimination reference signal transmitted from a transmitting side according to the present invention.

3 is a schematic block diagram of a typical ghost elimination device for removing ghost by receiving a ghost elimination reference signal transmitted from a transmitting side.

* Explanation of symbols for main parts of the drawings

10: GCR signal insertion unit 20: modulator

30: transmitter 310: AD converter

320: FIFO (FIRST IN FIRST OUT) 330: RAM

340: ROM 350: Microcomputer

360: filter unit 370: DA conversion unit

TECHNICAL FIELD The present invention relates to a ghost removal method, and more particularly, to an improved ghost removal method for more adaptively removing ghosts.

In general, while a broadcast signal from a broadcasting station is transmitted, it is reflected by an obstacle such as a mountain or a building and received by a receiving antenna, or reflected without an impedance matching of a transmission path to form a multipath channel (MULTIPLE CHANNEL). As a result, a phenomenon in which a reflected broadcast signal other than the original broadcast signal is weakly superimposed on the monitor of the television is called Ghost.

As described above, as part of a method for eliminating ghosts generated by a multipath channel, a ghost removal criterion sent to a broadcast signal transmitting a ghost removal reference signal from a broadcasting station and stored in a ghost elimination device on a receiving side in advance. The ghost is removed by filtering the received broadcast signal by finding a characteristic of the transmission line and comparing the signal with a filter to compensate for the characteristic of the transmission line.

FIG. 1 is a schematic block diagram of a ghost elimination reference signal transmitting apparatus at the transmitting side, and is composed of a ghost eliminating reference signal inserting unit 10, a modulator 20, and a transmitter 30. As shown in FIG.

In the same figure, the ghost removal reference signal inserting unit 10 inputs a projection signal to insert a ghost removal reference signal, and the modulator 20 mixes the production signal and the ghost removal reference signal. The signal is modulated to the correct frequency of the channel, and the transmitter 30 transmits the modulated signal through an antenna.

According to the conventional method of transmitting a ghost removal reference signal having a configuration as described above using a transmitter, a ghost removal reference signal of the same length is generated by the ghost removal reference signal insertion unit 10. It is inserted into a predetermined portion of the video signal, for example, the 20th line 20H by the SEQUENCE or 8FIELD SEQUENCE method, and is modulated at the frequency corresponding to the channel through the modulator 30 and then transmitted through the transmitter 30.

3 is a schematic block diagram of the ghost elimination device on the receiving side. As can be seen from the figure, the ghost elimination device includes an AD converter 310, a FIFO 320, a ROM 340, a microcomputer 350, a filter 360, and a DA converter 370.

In the drawing, the AD converter 310 converts an input video signal into a digital signal, and the FIFO 320 sequentially processes a predetermined portion 20H into which a ghost removal reference signal is inserted among the input video signals. And input sequentially. The RAM 330 stores a synchronous addition ghost removal reference signal, and the ROM 340 stores a ghost removal reference signal and a predetermined time set by the receiver.

In addition, the microcomputer 350 characterizes the channel through correlation of the ghost added reference signal stored in the RAM 330 and the ghost removal reference signal stored in the ROM 340. Compute and transmit filter coefficients to compensate. The DA converter 370 converts the video signal converted into the digital signal into an analog signal.

Next, a conventional typical method of removing ghosts by using the transmitter and receiver on the transmitting side and the receiving side as described above will be described in detail with reference to FIGS.

First, the ghost removal reference signal of the same length is inserted into the video signal by the ghost removal reference signal inserter 10 at the transmitting side, and modulated at the frequency corresponding to the channel in the modulator 20, and then through the transmitter 30. The video signal into which the ghost removal reference signal is inserted is output.

Next, the video signal received through the receiving side antenna is converted into a digital signal through the AD converter 310, and a ghost removal reference signal is included in the video signal converted into the digital signal by the FIFO 320. When the inserted small diameter portion 20H is sequentially input and output to the microcomputer 350, the microcomputer 350 synchronously adds the predetermined portion 20H for a predetermined time and erupts the ghost removal reference signal. The memory is stored in the RAM 330, and the channel characterization is performed through correlation between a ghost elimination reference signal stored in the RAM 330 and a ghost elimination reference signal stored in the ROM 340.

Next, the microcomputer 350 calculates a filter coefficient for compensating the channel characterization result and provides the filter coefficient to the filter unit 60 so that the input video signal is filtered through the filter unit 60 to obtain a ghost. After the removal, the signal is converted back into an analog signal through the DA converter 370.

However, in the conventional conventional technology, since the ghost removal reference signal having the same length is transmitted from the transmitting side and the ghost removal reference signal having the same length is also removed from the receiving side, the ghost removal reference signal at the receiving side is detected. There is a problem in that long ghosts existing on the law cannot be detected.

In more detail, the FIFO 320 of the ghost elimination device on the receiving side may store only a predetermined portion 20H into which the ghost elimination reference signal is inserted among the input image signals. The range is 63usec and the number of samples is 910. At this time, the sampling frequency is 4fsc = 14.32MHz.

On the other hand, in the case of correlation for channel characterization, the cost detectable range is the number of samples of the 910-ghost cancellation reference signal. Therefore, if the length of the ghost removal reference signal is determined, the ghost detectable range is also determined, so that long ghosts existing outside the ghost detectable range are not detected.

For example, if the number of samples of the ghost removal reference signal is 200, long ghosts are not detected if the total number of samples 910 is subtracted from the number of samples 200, that is, the number of samples is 710 or more and 910 or less.

Accordingly, the present invention has been devised in view of the above problems, and provides an improved ghost removal method that can increase ghost removal rate by adaptively removing ghosts by using ghost removal reference signals having different lengths. It is.

In order to achieve the above object, the present invention inserts and transmits a ghost removal reference signal to a predetermined portion of the Youngsan signal at the transmitting side, and performs correlation between the ghost removal reference signal received at the receiving side and the previously stored ghost removal reference signal. In the ghost removal method for calculating a filter coefficient for filtering by characterizing the channel through the channel, the transmitting side repeatedly inserts and outputs a plurality of ghost removal reference signals having different lengths into the video signal for a predetermined number of times. The side provides an improved ghost removal method characterized in that the ghost is removed by selectively applying a ghost removal reference signal suitable for a channel condition among the plurality of ghost removal reference signals having different lengths.

Other objects and various advantages of the present invention will become more apparent from the preferred embodiments of the invention described below with reference to the accompanying drawings by those skilled in the art.

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

First, as shown in FIG. 2 at the transmitting side, the ghost elimination reference signal inserter 10 has a length relatively different from a ghost elimination reference signal having a different length, for example, a relatively long ghost elimination reference signal GI. Inserts the short ghost removal reference signal Gs into the video signal by the 4FIELS SEQUENCE method and modulates it.

The relatively long ghost removal reference signal and the relatively short ghost removal reference signal are also stored in the ROM 340 in the ghost removal apparatus.

4 is a diagram illustrating a range in which ghost detection is possible when ghost removal is performed using ghost removal reference signals having different lengths, and (a) and (b) use ghost removal reference signals having relatively short lengths. In this case, an example showing a ghost detectable range is shown, and (c) and (d) show an example showing a ghost detectable range when a relatively long ghost removal reference signal is used.

As can be seen from (b) of FIG. 4, when the ghost is detected using a relatively short ghost removal reference signal, the ghost detection range becomes long, so the relatively long ghost removal shown in (d) is shown. When the ghost is detected using the reference signal, the long ghost existing in the range not detected can also be detected.

As described above, when the video signal mixed with the ghost removal reference signals having different lengths is input to the ghost removal reference signal on the receiving side, the signal is converted into a digital signal through the AD conversion unit 310, and the FIFO The input unit 320 first inputs a predetermined portion in which the relatively short ghost removal reference signal is inserted among the converted video signals and is output to the microcomputer 350.

Next, the microcomputer 350 extracts the relatively short ghost removal reference signal to the RAM 330 by synchronously adding a zeroing signal into which a relatively short ghost removal reference signal is inserted for a predetermined time. And a channel characterization through correlation between the relatively short ghost removal reference signal stored in the RAM 330 and the relatively short ghost removal reference signal stored in the ROM 340.

On the other hand, if the mongost does not exist, the channel characterization is performed by correlating the relatively long ghost removal reference signal inserted in the inputted product signal and the ghost removal reference signal stored in the ROM 340. The ghost is removed by calculating a filter coefficient to compensate and filtering the input video signal.

Here, when the mongost is up, removing the ghost using the relatively long ghost removal reference signal means that the relatively long ghost removal reference signal has a large signal energy, thereby removing ghost. Because this is good.

Therefore, by using the improved ghost removal method of the present invention, the ghost can be removed more efficiently by using the ghost removal reference signal according to the presence range of the ghost.

Claims (3)

Transmitter inserts and outputs the ghost elimination reference signal to the predetermined part of the product signal, and performs channel characterization through correlation between the ghost elimination reference signal and the pre-stored ghost elimination reference signal at the receiver to filter the filter coefficient for filtering. In the ghost removal method for removing the ghost to the new generation, the transmitting side repeatedly inserts and outputs a plurality of ghost elimination reference signals having different lengths, respectively for a predetermined number of times, and the receiving side has different lengths. The ghost is removed by selectively applying a ghost removal reference signal suitable for a channel condition among the plurality of ghost removal reference signals, and the ghost is removed based on the ghost removal reference signal having a short length for the long ghost among the ghosts. The long ghost is not included If, on the basis of the length of the long ghost removal reference signal to remove the ghost improvement characterized in that for removing ghost. 2. The improved ghost removal method according to claim 1, wherein a ghost removal reference signal having a relatively short length among the plurality of ghost removal reference signals is applied prior to channel characterization. 3. The improved ghost removal method according to claim 2, wherein the plurality of ghost removal reference signals are repeated in units of four fields.