KR100226841B1 - Dc error correcting method of ghost cancellation device - Google Patents

Abstract

The present invention relates to an error correction method of a ghost elimination device, and more particularly, to a DC error correction method of a ghost elimination device for correcting a DC error mixed in the ghost elimination device.

In the prior art, the ghost elimination device calculates an abnormal coefficient due to a DC error, so that ghost elimination is not performed properly, resulting in a bad state of the screen after ghost elimination, and the vertical synchronization is shaken to further deteriorate the performance of the ghost elimination device.

A feature of the DC error correction method of the ghost elimination apparatus according to the present invention is to obtain an average value within a given DC specific range in a specific line of every field of an image signal, and to store a value equal to the number N of predetermined fields; Determining whether a DC error value is mixed in the specific line from the stored value and correcting the DC error value, and correcting the DC value to a desired level when the correctable DC error value is mixed. When input from the broadcasting line, it is corrected to prevent erroneous counting operation, to improve the screen state after ghost removal, and to ensure stable ghost elimination performance.

Description

DC error correction method of ghost eliminator

The present invention relates to an error correction method of a ghost removal device, and more particularly, to a DC error correction method of a ghost removal device for correcting a DC error mixed in the ghost removal device.

Referring to FIG. 1, a general ghost elimination device is described. A clock generator 11 outputs a signal necessary for the entire system from an input composite video signal, and the input composite video signal is output from the clock generator 11. An analog / digital (A / D) converter 12 for converting and outputting an analog signal into a digital video signal in synchronization with the synchronous signal; and a digital video signal output from the A / D converter 12; A first-in first-out (FIFO) 13 for storing and outputting one horizontal line of a ghost-inserted video signal in synchronization with the start signal of the ghost removal signal outputted from (11) and the four-time synchronization signal, and the FIFO 13 A digital signal processor (DSP) 14 for supplying filter coefficients using a ghost removal reference signal (GCR) outputted by the < RTI ID = 0.0 >), < / RTI > Using the filter coefficients of the DSP 14 A filter unit 15 for removing and outputting ghosts, and a digital / analog (D / A) converter 16 for converting and outputting a digital composite video signal from which ghosts are removed from the filter unit 15 to an analog composite video signal. It is composed of

In the general ghost elimination device configured as described above, the clock generator 11 receives the signals necessary for the entire system from the input composite video signal, i.e., the 4x synchronization signal (4fsc), the horizontal synchronization signal, the vertical synchronization signal, and the field corresponding to the color synchronization signal. It generates and supplies the discrimination signal and the start signal of the ghost elimination reference signal.

The A / D converter 12 converts the analog video signal into a digital video signal in synchronization with the quadrupole signal input from the clock generator 11 and converts the analog video signal into a digital video signal. It supplies to 15 each.

The FIFO 13 inserts a ghost removal reference signal in synchronization with the start signal of the ghost removal reference signal supplied from the clock generator 11 and a four-time synchronization signal among the digital image signals input from the A / D converter 12. One horizontal line of the received video signal.

Then, the DCP 14 receives the input ghost elimination reference signal stored in the FIFO 13, compares the ghost elimination reference signal with each other, calculates a coefficient, and outputs the coefficient to the filter unit 15.

The filter unit 15 supplied with the filter coefficients from the DSP 14 uses a built-in multiplier and an adder (not shown) to input ghosted digital image signals and filter coefficients from the A / D converter 12. Multiply by and add the output to remove the ghost through the filtering process.

The digital video signal from which the ghost is removed through the filter unit 15 is input to the D / A converter 16 to be converted into an analog composite video signal and output.

In this case, the DSP 14 reads the ghost removal reference signal, which is a reference signal, from the baseband image signal to which the FIFO 13 is applied to calculate a filter coefficient for ghost removal using the FIFO 13 memory.

In this way, the data applied to each field is taken as the odd field and the even field-to accumulate a predetermined number to obtain final data.

Acquiring data using the multiple fields is to average noise and reduce various errors.

The reason why the radix field is + and the even field is-is that the radix field is + and the even field is inserted as-in the video section. It is for.

In the ideal case, the final data obtained above has a reference level of 0 as shown in FIG. 2, but additionally includes noise.

However, rather than this noise, the input signal itself is greatly shaken or the DC error caused by the A / D unit 12 not working properly further weakens the performance of the ghost eliminator.

In the prior art, the ghost elimination device calculates an abnormal coefficient due to a DC error, so that ghost elimination is not performed properly, resulting in a bad state of the screen after ghost elimination, and a vertical synchronization caused by the ghost elimination device.

The present invention has been made in order to solve the problems of the prior art as described above by checking the DC of the input ghost removal reference signal to determine whether the DC mixing, and to correct.

1 is a block diagram showing the configuration of a general ghost removal device

2 is a diagram of data of an ideal case of a typical input GCR line.

3 is a diagram of a DC measurement range in a GCR line according to the present invention.

4 is a flowchart of a DC error correction method according to the present invention.

The DC error correction method of the ghost elimination apparatus according to the present invention obtains an average value within a given DC measurement range in a specific line of every field of an image signal, stores a value equal to the number N of predetermined fields, and stores the value from the stored value. After the DC error value is mixed in the line to determine whether it is possible to correct, and if a correctable DC error value is mixed, the DC value is corrected to a desired level.

Hereinafter, a DC error correction method of a ghost removing device according to the present invention will be described with reference to the accompanying drawings.

FIG. 3 is a diagram of a DC measurement range in a GCR line according to the present invention, and illustrates a range of DC measurement in an odd field ghost removal reference signal line of an actual video signal including noise.

The DC specification is practically difficult to perform on the entire line into which the ghost cancellation reference signal is inserted.

This is because the ghost elimination reference signal itself does not have a constant DC characteristic when averaged.

Since the ghost removal reference signal is not ideally applied without ghost, it does not use the ghost removal reference signal, but uses the average value of the applied values thereafter.

The range of use is variable but preferably wide, starting as far after the ghost removal reference signal as the situation permits.

This minimizes the effects of ghosts and noise, and the DC measurements are made every field to increase the accuracy of the measurements.

Hereinafter, the DC error correction method of the ghost removing device according to the present invention will be described in detail with reference to the flowchart of the DC error correction method according to the present invention of FIG. 4.

First, an average value of DC values within a given DC measurement range, that is, a DC value, is obtained from each data of each field of the applied ghost removal reference signal GCR, and the value of the desired number of fields N is stored (S41).

The N data consists of data of N / 2 radix fields (O1, O2, ..., ON / 2) and data of N / 2 even fields (E1, E2, ... EN / 2). .

When each data stored in the step S41 is O1, O2, ... ON / 2 and E1, E2, ... EN / 2, the average OA, O2, ... ON / 2 And the average (EA) and the variance of the variances, E1, E2, ..., EN / 2, respectively (S42).

If the variances obtained above are equal to or greater than a certain threshold, it is determined that the data is difficult to correct. If the variances are less than a certain threshold (S43), the averages O1, O2, ... ON / 2 of EE1, The DC difference is obtained by subtracting the average (EA) of E2, ..., EN / 2 (S44).

Thereafter, the DC difference obtained in the above step is compared with a predetermined threshold, and when the difference OA-EA between two values OA and EA is greater than or equal to a predetermined threshold, it is determined that the data is difficult to correct.

On the other hand, if the difference between the two values (OA, EA) (OA-EA: DA) is less than a predetermined threshold value, the value of OA-EA is determined as the DC value, and DC is corrected by subtracting DA from all applied GCR lines. The generated data.

As described above, the DC error correction method of the ghost elimination device according to the present invention corrects the ghost elimination reference signal including DC in the ghost elimination device when it is input from a broadcasting line, thereby preventing erroneous counting operation, and after ghost elimination. It improves the screen condition and guarantees stable ghost elimination performance.

Claims (6)

Obtaining an average value within a given DC measurement range in a specific line of every field of the video signal and storing a value equal to the number of preset fields (N), and storing each of the odd field data and the even field data from the stored values. After calculating the difference between the variance, the average of the odd field data, and the average of the even field data, respectively, the variance and the difference value are respectively compared with a predetermined threshold value, and a DC error value correctable in the specific line is mixed. Determining whether there is an error, and correcting the DC value to a desired level when the correctable DC error value is mixed. The method of claim 1, wherein the specific line is a line through which a ghost removal reference signal is transmitted. The method of claim 1, wherein the number N of the fields comprises data of N / 2 radix fields and data of N / 2 wood fields. The method of claim 1, wherein the DC measurement range is a range excluding a ghost removal reference signal. The method of claim 1, wherein the determining of whether the correction is possible comprises: comparing the respective variances with the constant threshold value and comparing the difference value with the constant threshold value when the variance is less than or equal to the constant threshold value. And determining that the difference value can be corrected when the difference is less than or equal to the predetermined threshold value. The method of claim 1, wherein the correcting of the DC value comprises: subtracting the difference value from the entire ghost removal reference signal line to obtain corrected data of the DC value. Way.