KR100308259B1 - Digital convergence corrector - Google Patents

Abstract

PURPOSE: A digital convergence corrector is provided to reduce the time for convergence correction and to offer convenience to a user by deciding twist based on respective adjusting points and correcting the convergence correction data with a specific correction coefficient. CONSTITUTION: A digital convergence corrector comprises an EEPROM(Electrically Erasable and Programmable Read-Only Memory)(6) storing convergence correction data, a micro computer reading the convergence correction data of the EEPROM with response to the selection of convergence correction by a user, a memory(2) storing the correction data read by the micro computer, an address generating unit(3) generating an address by synchronizing signals, a convergence correction control unit(4) outputting the correction data to a digital/analog converting unit(8), a pattern generating unit(5) generating a pattern or a cursor by the synchronizing signals, a video processing unit(7) outputting a reference pattern processing signal by processing a reference pattern signal of the pattern generating unit, an adjusting point window generating a window pulse corresponding to the pattern reference signal, an adjustment deciding unit(12) deciding the coefficient adjustment of an adjusting point by comparing the signal of the video processing unit to a reference signal, and a coefficient correcting unit(13) correcting the convergence correction data corresponding to the outputs(S1,S2,Gd) of the adjustment deciding unit.

Description

Digital convergence correction device

1 is a block diagram of a conventional digital convergence correction device.

2 is a block diagram of a digital convergence correction device of the present invention.

3 is an exemplary view of a test pattern in FIG.

4 is a waveform diagram showing coefficient correction in FIG.

5 is a waveform diagram according to adjustment completion determination in FIG.

6 is a block diagram of an adjustment discriminating unit in FIG. 2;

7 is a block diagram of a coefficient correcting unit in FIG. 2;

<Description of the symbols for the main parts of the drawings>

1: microcomputer 2: memory

3: address generator 4: convergence correction controller

5: pattern generator 6: EEPROM

7 video processing unit 8 digital / analog conversion unit

11: adjustment point window 12: adjustment determination unit

13: coefficient correction unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to digital convergence, and more particularly, to a digital convergence device for displaying a screen clearly by automatically adjusting digital convergence correction data in a large display device.

1 is a block diagram of a conventional digital convergence correction device, as shown therein, an EEPROM 6 storing convergence correction data, and the EPIROM 6 according to a user's correction setting. A microcomputer 1 which reads the convergence correction data and generates an address corresponding to the convergence correction data, and a memory 2 which stores the correction data generated by the microcomputer 1 in the designated area. and, adjustment and in that mode, the horizontal and vertical synchronizing signals (V _P), the test pattern generating section 5 for generating a test pattern displayed on the screen in accordance with (H _P), the synchronization with the system horizontal and vertical sync signals ( The address generator 3 generates vertical and horizontal addresses according to V _P ) (H _P ), and the address generator 3 of the address generator 3 to correct an adjustment point at which the output of the test pattern generator 5 is displayed. The address specified above After reading the data area of the memory (2) in series in parallel conversion it consists of a memory control unit (4) for outputting in real time the digital / analog converter (figure not yet displayed).

Referring to the operation of the conventional device configured as described above are as follows.

First, when the user sets convergence correction, the microcomputer 1 generates an address corresponding to each adjustment point, reads and outputs correction data of each adjustment point from the ypyrom 6, and the memory 2 The correction data is stored in the designated area corresponding to the address generated in the microcomputer 1.

Here, the microcomputer 1 controls the memory 2 to control the output of the stored data to the convergence correction control unit 4.

At this time, when the convergence adjustment mode is set, the address generator 3 receives the convergence correction data stored in the memory 2 as the vertical and horizontal synchronization signals V _P (H _P ) synchronized with the system are input. The memory 2 generates horizontal and vertical addresses for reading in real time.

In addition, the pattern generator 5 generates a pattern and a cursor synchronized with the vertical and horizontal synchronization signals V _P (H _P ) synchronized to the system, thereby generating a test pattern displayed on the screen in the adjustment mode. do.

Here, the test pattern signal generated by the pattern generator 5 is a signal for generating a Hatch pattern and a dot / cross pattern to facilitate convergence adjustment.

Accordingly, when the test pattern generated by the test pattern generator 5 is displayed on the screen, the convergence correction controller 4 outputs the data MD output from the memory 2 by the output of the address generator 3. ) Is read in series, and the data read in this series (R _H , G _H , B _H , R _V , G _V , B _V ) are converted in parallel and output to the digital / analog converter (not shown) in real time. Thus, the convergence is corrected by controlling the current of the yoke coil (not shown) for the convergence correction.

The above operation is repeated for each adjustment point on the screen until the convergence adjustment is completed, and when the convergence correction is completed, the microcomputer 1 controls the EEPROM 6 to control each adjustment point. Will store the calibration data.

In the related art, since the entire screen has to be adjusted at each adjustment position during convergence adjustment, there is a problem that it takes not only a lot of adjustment time but also a simple operation.

In order to solve this problem, the present invention determines the correction state of each adjustment point according to the convergence correction, adjusts and stores the correction coefficients of each adjustment point, and then repeats the adjustment correction. To solve the inconvenience of manually adjusting the same time and to create a digital convergence correction device for reducing the working time, it will be described in detail with reference to the accompanying drawings as follows.

The present invention relates to a first memory for storing convergence correction data, and to read convergence correction data of the first memory in accordance with a user's convergence correction selection to correspond to the correction data. A microcomputer for generating an address, a second memory for storing correction data read by the microcomputer, address generating means for generating an address in accordance with a synchronization signal V _P (H _P ) synchronized with the system, and this address reading the correction data stored in the second memory corresponding to the output of the generating means the digital / con version's correction control means for outputting the analog conversion means, and the test pattern and the cursor in accordance with said synchronizing signal (V _P) (H _P) Pattern generating means for generating a signal; video processing means for processing an output of the pattern generating means and outputting a reference pattern processing signal; Adjustment point window means for generating a window pulse as the detection pattern based on the signal of the unit pattern generation and, as a control point is enabled to the output of the window means of the comparison signal (F _DET) the previous frame data of the video processing means based on And an adjustment discrimination means for discriminating whether or not the adjustment point coefficient is adjusted as compared with the signal Fref, and a coefficient correction means for correcting convergence correction data in accordance with the output of the adjustment discrimination means.

FIG. 2 is a block diagram showing an embodiment of the present invention, as shown therein, for example, the Y pyrom 6 storing convergence correction data, and the Y pyrom 6 according to the user's convergence correction selection. A microcomputer 1 for reading and outputting the convergence correction data, a memory 2 for storing the correction data read from the microcomputer 1, and a synchronization signal V _P (H _P ) synchronized with the system. An address generator 3 for generating an address, and a convergence correction for reading correction data stored in the memory 2 according to the output of the address generator 3 and outputting the correction data to the digital / analog converter 8; A reference pattern process by processing the control unit 4, a pattern generator 5 for generating a pattern and a cursor in accordance with the synchronization signal V _P (H _P ), and a reference pattern signal of the pattern generator 5 Of the video processor 7 for outputting a signal and the pattern generator 7 The control point window 11 generating a window pulse according to the pattern reference signal and the output of the control point window 11 are compared to compare the reference signal Ref and the reference signal of the video signal processor 7. An adjustment judging unit 12 for judging whether or not the adjustment point coefficient is adjusted accordingly; and a coefficient correcting unit for correcting convergence correction data according to the outputs S1, S2, and Gd of the adjustment judging unit 12 ( 13).

As illustrated in FIG. 6, the adjustment determining unit 12 is enabled by a window pulse of the adjustment point window 10 and outputs a reference signal f ₀ -f ₁₈ . Then, the output signal f ₀ -f ₁₈ of the reference signal output unit 121 is compared with the comparison signal that is the previous frame data of the video processing unit 7 to determine the discrimination signal S ₁ (S ₂ ) (Gd). It consists of the frequency discriminating part 122 which outputs to the part 13.

As shown in FIG. 7, the coefficient correcting unit 13 selects a step or a fine adjustment according to the determination signal S ₁ (S ₂ ) of the adjustment determining unit 12, and increases or decreases (+/−). A correction selector 131 which selects the &lt; RTI ID = 0.0 &gt; and &lt; / RTI &gt; and a correction calculator for fixing the coefficient by the determination signal Gd of the adjustment determining unit 12 and correcting the coefficient according to the adjustment selection of the adjustment selector 131 ( 132).

The coefficient correction data output from the correction calculator 132 is 35 pieces, such as the number of adjustment points (width: 7, length: 5).

Referring to the operation and effect of the present invention configured in this way in detail as follows.

First, when the user sets convergence correction, the microcomputer 1 generates an address corresponding to each adjustment point, reads and outputs correction data of each adjustment point from the ypyrom 6, and the memory 2 In the designated area corresponding to the address generated in the microcomputer 1, correction data read from the EPI rom 6 is stored.

Here, the microcomputer 1 controls so that the stored data of the memory 2 is not output to the convergence correction control unit 4 during the write operation of the memory 2.

At this time, when the vertical and horizontal synchronizing signals V _P (H _P ) synchronized with the system are input by the setting of the convergence adjustment mode, the address generator 3 returns the convergence correction data stored in the memory 2. The memory 2 generates horizontal and vertical addresses for reading in real time.

Accordingly, when the actual image is displayed on the screen when not in the adjustment mode, the convergence correction control unit 4 outputs the data MD output from the area of the memory 2 designated by the address generated by the address generation unit 3. Reads in serial and converts the serial data (R _H , G _H , B _H , R _V , G _V , B _V ) in parallel and converts them to a digital / analog converter (not shown) in real time. The convergence is corrected by controlling the current of the yoke coil (not shown) for the correction.

On the other hand, when the adjustment mode is entered, the pattern generator 5 displays a test pattern displayed on the screen in the adjustment mode by generating a pattern and a cursor synchronized with the vertical and horizontal synchronization signals V _P (H _P ) synchronized with the system. The pattern is generated and output to the video processor 7.

Here, the test pattern signal generated by the pattern generator 5 is a signal for generating a Hatch pattern and a dot / cross pattern to facilitate convergence adjustment.

In this case, when the reference pattern signal generated in the pattern generator 5 is input as shown in FIG. 3, the video processor 7 performs the video signal processing, and then outputs the reference pattern processing signal to the adjustment determination unit 12. When the window 11 detects the pattern reference signal of the pattern generator 5, the window 11 outputs a window pulse to the adjustment determination unit 12.

Accordingly, the adjustment determination unit 12 enabled to the window pulse of the adjustment point window 11 is a reference signal output unit 121 is a reference signal (corresponding to the window pulse of the reference signals f ₀ -f ₁₈ ) When Fref is outputted, the frequency discriminator 122 compares the comparison signal F _DET output from the video processor 7 to the comparison signal F _DET input from the video processor 7 rather than the reference signal Fref. Is high, the discrimination signal Gd is outputted to the coefficient correcting unit 13 to fix the coefficient correction value of the adjustment point, thereby indicating that the adjustment point is completed.

If the comparison signal F _DET is considerably lower than the reference signal Fref, the adjustment determination unit 12 outputs the selection signals S1 and S2 so that the coefficient correction unit 13 changes the correction data by one step. If the comparison signal (F _DET ) is similar to the reference signal (Fref), it is controlled to change minutely.

In addition, the adjustment determination unit 12 has a frequency value adjusted in the previous frame. When the comparison signal F _DET input in this frame is detected to be worse than the value of the adjustment point position of the previous frame, the adjustment determination unit 12 operates in the opposite direction. If the detection is successful, the selection signal S1 or S2 is output so that the coefficient correcting unit 13 operates in the forward direction.

Accordingly, when the determination signal Gd is input from the adjustment determining unit 12, the coefficient correcting unit 13 fixes the coefficient correcting value by the correction calculator 132, and the selection signal S1 in the adjustment determining unit 12. When S2 is input, the adjustment selector 131 selects step adjustment (rough) or fine adjustment, and selects the increase / decrease (+/-) in the adjustment direction.

That is, the coefficient correcting unit 13 is outputted to the outputs S1 and S2 of the adjustment discriminating unit 12 when it is shifted by the horizontal (x) and vertical (y) correction values from the reference adjustment point as shown in FIG. Accordingly, when the adjustment selector 131 selects fine adjustment or step adjustment, the correction calculator 132 corrects the distortion by adding the correction coefficient to the original coefficient value output from the convergence correction control unit 4 and outputting it.

Here, the correction coefficients are 35 when the number of adjustment points is, for example, '7' in the width and '5' in the length, and the data values are inherent real data.

At this time, when the coefficient correcting unit 13 outputs the corrected coefficient, the microcomputer 1 stores the memory 2 in the memory 2 and the stored data is converted into the digital / analog converting unit 8 through the convergence correction control unit 4. Is outputted to the controller to control the current of the convergence correction coil (not shown).

Therefore, if the adjustment determination unit 12 outputs the determination signal Gd to the coefficient correction unit 13 for all the correction coefficients by repeating the above operation, it means that the convergence correction is completed as shown in FIG. When the correction is completed, the correction data stored in the memory 2 is stored in the EPIROM 6 by the microcomputer 1 to terminate all convergence correction operations.

As described in detail above, the present invention shortens the convergence correction time by correcting the convergence correction data with a unique correction coefficient as it checks each adjustment point when the convergence is adjusted and determines the misalignment. It has the effect of providing convenience to the user by eliminating the repetition of simple tasks.

The present invention can be applied to a projection TV and a large TV as a core technology of a large display device.

Claims (3)

A first memory for storing the convergence correction data, a microcomputer that reads the convergence correction data of the first memory according to a user's convergence correction selection and generates an address corresponding to the correction data; corresponding to the second memory for storing the correction data read from the computer, an address generating means for generating an address according to the synchronization with the system synchronization signal (V _P) (H _P) and the output of the address generating means and the second Convergence correction control means for reading the correction data stored in the memory and outputting the correction data to the digital / analog conversion means, pattern generation means for generating a test pattern in accordance with the synchronization signal V _P (H _P ), and the pattern generation means. A video processing means for processing a reference pattern signal output from the apparatus and outputting a reference pattern processing signal, and a pattern reference of the pattern generating means Upon detection of a call compared to calibration point window means, is enabled to the output of the control point window means a reference signal (Fref) and a comparison signal (F _DET) the previous frame data of the video processing means for generating a window pulse as Digital discrimination means comprising: an adjustment discrimination means for discriminating whether or not the adjustment point coefficient is adjusted according to the present invention; and a coefficient correction means for correcting convergence correction data according to the outputs Gd (S1) and S2 of the adjustment discrimination means. Convergence correction device. 2. The reference discrimination means according to claim 1, wherein the adjustment discrimination means comprises a reference signal output portion (121) for enabling the window pulses of the adjustment point window means to output the reference signals (f _0- f ₁₈ ), and the reference signal output portion (121). The reference signal (Fref) of the output (f ₀ -f ₁₈ ) of the output signal is compared with the comparison signal (F _DET ), which is the previous frame data of the video processing means, to determine the discrimination signal (Gd) and the selection signal (S ₁ ) (S ₂ ) A digital convergence correction device, characterized by comprising a frequency discriminating unit (122) for outputting to the coefficient correcting means. The adjustment selector according to claim 1, wherein the coefficient correction means selects a step or fine adjustment in accordance with the selection signal S ₁ (S ₂ ) of the adjustment determination means and simultaneously selects an increase or decrease (+/-) in the adjustment direction ( 131 and the correction coefficient fixed by the determination signal Gd of the adjustment determining means, and the convergence correction data outputted from the convergence correction control means at the coefficient according to the adjustment selection of the adjustment selection unit 131. Digital convergence correction device, characterized in that consisting of a correction operator (132) for correcting the.