KR19980051981A - Convergence Correction Device and Control Method in Projection TV - Google Patents

Abstract

The present invention relates to a digital convergence correction device in a projection TV,

In the conventional digital convergence correction device, the magnetic field is set to '0' in a separate geomagnetic field correction unit to prevent convergence due to the influence of the geomagnetic field, so that the center point of the screen, that is, the starting point of the horizontal and vertical phases, is adjusted. In the place where the system correction is not performed, as shown in FIG. 6, the center of the screen is moved along the east, west, north and north directions, and the convergence of the entire screen is distorted.

Accordingly, the present invention for solving the above problems is to install the light detecting means at the mechanical center of the screen to detect the horizontal and vertical phase error and to compensate the phase adjustment data by the detected error, so that the horizontal and It is a digital convergence correction device and its control method that can provide a clear image at all times by automatically correcting the convergence defect caused by the vertical phase change.

Description

Convergence Correction Device and Control Method in Projection TV

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for compensating digital convergence in a projection TV. In particular, a light detecting means is installed at a mechanical center point of a screen to detect errors in horizontal and vertical phases and compensate phase adjustment data by the detected errors. The present invention relates to a digital convergence correction apparatus and a control method thereof, which enable to automatically correct a convergence defect caused by a change in horizontal and vertical phases due to an effect, thereby always providing a clear image.

In general, convergence refers to an operation of controlling an image displayed on a screen to be clearly displayed while keeping the three electron beams scanned on the screen into one place so that the color of the image outputted from the screen does not shift.

1 shows a conventional digital convergence correction device, the configuration of which is as follows.

A horizontal and vertical adjustment pattern using a PLL unit 1 for generating a system clock according to the input horizontal blank signal H _BLK and a vertical blank signal V _BLK , and a system clock output from the PLL unit 1. And an adjustment pattern and an adjustment cursor generating unit 2 for generating a cursor indicating an adjustment point, an image processing unit 3 for outputting an input horizontal and vertical adjustment pattern and an adjustment point cursor, and an input system clock. An address generator 4 for generating horizontal and vertical addresses and supplying them to the memory 8, a key input unit 5 for adjusting convergence adjustment points, and an adjustment point according to the user's key input unit 5 operation. When adjusted, the controller 6 calculates and outputs correction data for all the regions according to a separate program, an EEPROM 7 in which the convergence adjustment data for the adjustment points is stored, and the address generator 4. Number input And a memory 8 for outputting data on convergence adjustment points corresponding to the vertical address, and an interpolation unit 9 for interpolating and calculating convergence adjustment data for all areas based on the adjustment point data output from the memory 8. ), A D / A converter 10 for converting the convergence adjustment data output from the interpolator 9 into an analog signal, and a low pass filter for removing noise from the signal output from the D / A converter 10. (Low Pass Filter) 11, an amplifier 12 for amplifying the filtered signal and flowing a current corresponding thereto to the convergence coil CY, and a convergence coil for correcting the convergence according to the input convergence adjustment current. CY).

The operation of the conventional digital convergence adjusting device configured as described above will be described with reference to FIGS. 1 to 6.

First, when power is supplied to the projection-type TV, the control unit 6 calculates the convergence adjustment data for the entire screen area by using the convergence adjustment data stored in the ypyrom 7 and stores it in the memory 8.

In addition, the PLL unit 1 generates a system clock according to the input horizontal blank signal and the vertical blank signal, and the adjustment pattern and the adjustment cursor generation unit 2 adjust the horizontal and vertical adjustment patterns and the adjustment points using the system clock. A cursor is generated to be output to the image processor 3 for display on the screen. The address generator 4 generates an address of horizontal and vertical convergence adjustment points using a system clock and supplies the address to the memory 8. .

At this time, the memory 8 transmits the data inputted from the address generator 4, that is, the convergence adjustment point (horizontal and vertical center points), to the interpolation unit 8 among the previously stored convergence adjustment data. The interpolation section 9 calculates the convergence adjustment data for the entire screen area by using the convergence data for the input convergence adjustment point, and outputs the D / A converter 10, the low pass filter 11, and the amplification. By supplying to the conversion scale CY through the unit 12, the convergence of the output image is adjusted.

On the other hand, when the user adjusts each convergence adjustment point through the key input unit 5, the control unit 6 stores the convergence adjustment data for the convergence adjustment point adjusted by the user's key operation in the YPIROM 7 By calculating and changing the data value of the memory 8 in accordance with a separate program, the convergence adjustment operation is performed on the convergence adjustment point changed by the user.

2 shows the configuration of the address generator 4 described above in detail.

The operation of the address generator 4 will be described with reference to FIG.

When the clock according to the horizontal blanking signal is generated in the PLL unit 1, the horizontal reference pulse generator generates a reference pulse having a 1H interval as shown in FIG. The adjustment counter counts the reference clock and supplies the counting value to the first comparator (see (b) of FIG. 4).

At this time, the horizontal phase address decoder reads the data output from the control unit 6 to the memory 8 and outputs a predetermined pulse to the horizontal phase data latch at the time when the horizontal phase data is present, and outputs from the memory 8 at this time. The convergence adjustment data to be supplied is supplied to the first comparator through the horizontal phase data latch (see (c) of FIG. 4).

The first comparator compares the counting value input from the horizontal phase adjustment counter and the signal input from the horizontal phase address latch and outputs a high pulse as shown in FIG.

The high pulse output from the first comparator is used as a reset signal of the horizontal address counter so that the horizontal address counter counts the reference clock again from the time of reset as shown in FIG. 4E and outputs the horizontal address to the memory 8.

If the user manipulates the key input unit 5 to adjust the horizontal position, the control unit 6 supplies the horizontal position adjustment data to a specific address of the memory 8, and the horizontal position adjustment data is provided through the horizontal phase data latch. Since the pulse output phase of the first comparator can be adjusted by being sent to the first comparator, convergence adjustment is made as a result.

As described above, the address generator 4 compensates for the delay time generated during the raster scan phase and convergence adjustment data processing in the CRT (Calti), and the position of the horizontal image. You can also adjust.

If the horizontal phase adjustment as described above is not properly performed, the image is abnormally output as shown in FIG. 5.

Since the vertical phase adjustment operation is similar to the horizontal phase adjustment operation described above, it will be omitted.

3 shows an adjustment pattern and an adjustment cursor generation unit 2, in which the horizontal pattern inputs the reference signals of the output signals a ₀ , a ₁ , a _2, and 2 MHz of the horizontal address counter to the first end gate. By operation A pulse having a width of 250 Hz is obtained, and a horizontal line is generated by supplying the pulse to the image processing unit 3.

However, in the first comparator, a negative pulse is output when the output signal a3 to a6 of the horizontal address counter and the latch data inputted from the horizontal phase data latch are output to eliminate the specified horizontal line, but the 4H width is applied to the oragate. By inputting and superimposing the clocks, one horizontal line appears as a dotted line.

The process of generating a vertical line by using the vertical address counter is similar to the process of generating the horizontal line as described above and thus will be omitted.

On the other hand, the horizontal and vertical adjustment patterns made as described above are supplied to the image processing unit 3 and appear as cross-hatches on the screen, and when the horizontal and vertical phases are adjusted, the cross-hatch patterns without adjustment points are displayed on the screen. And cross-hatch patterns with adjustment points appear when adjusting convergence.

However, in the conventional digital convergence correction device, in order to prevent the convergence shift caused by the influence of the geomagnetic field, the magnetic field is set to '0' in a separate geomagnetic field correction unit to match the center point of the screen, that is, the starting point of the horizontal and vertical phases. Even in the place where the geomagnetic field correction is not made, as shown in FIG. 6, the center of the screen is moved along the east, south, west and north directions, so that the entire screen is not converged and the screen is not clear.

In other words, when the center of the screen is moved, the position of the raster is moved on the CRT plane, so that the convergence is shifted at the periphery of the screen as much as it is moved, so that the color of the screen is tripled, such that the image is not clear.

Accordingly, the present invention for solving the above problems is to install the light detecting means at the mechanical center of the screen to detect the horizontal and vertical phase error and to compensate the phase adjustment data by the detected error, so that the horizontal and It is an object of the present invention to provide a digital convergence correction device and a control method thereof, which can automatically correct a convergence defect caused by a change in the vertical phase so that a clear image is always provided.

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

2 is a block diagram showing an address generator applied to conventional digital convergence;

3 is a block diagram showing an adjustment pattern and an adjustment point generator applied to a conventional digital convergence.

4 is a waveform diagram showing an output waveform of an address generator;

5 is a view showing a screen state when the horizontal phase is shifted.

6 is a view showing a problem of the conventional digital convergence correction device.

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

8 is a view showing an installation state of the light detector applied to the present invention.

9 is a view showing a movement state of the horizontal and vertical phase pattern according to the movement of the screen center.

10 is a flowchart showing a control process of the present invention.

The present invention for achieving the above object

PLL section 1 for generating a system clock, adjustment pattern and adjustment cursor generation section 2 for generating cursors indicating adjustment patterns and adjustment points, and addresses for generating horizontal and vertical addresses and supplying them to the memory 8. Digital convergence correction comprising a generation unit 4, a memory 8 for outputting data on convergence adjustment points, and an interpolation unit 9 for interpolating and calculating convergence adjustment data for all areas centered on the adjustment point data. In the apparatus,

It is installed at the mechanical center position of the screen, the light detector 20 for detecting the presence of light and converting it into a predetermined voltage, and the amplifier 21 for amplifying the voltage output from the light detector 20 at a predetermined amplification rate ), An A / D converter 22 for converting and leveling the voltage output from the amplifier 21 into a digital signal, and the light detector 20 as a signal input from the A / D converter 22. The control unit 23 determines whether light is detected in the control unit and controls the horizontal and vertical phase start points to be positioned at the correct positions according to the determination result, and a program for performing the horizontal and vertical phase start point control operations of the control unit 23. It characterized in that it further comprises an ypyrom 24 for storing.

The photodetector 20 includes a horizontal photodetector 20A installed above and below the mechanical center point of the screen, and a vertical photodetector 20B installed to the left and right sides of the mechanical center point of the screen. The same components are denoted by the same symbols.

Referring to the control method of the configured convergence compensation device,

A first step of determining whether light is detected by the horizontal photodetector 20A,

A second step of alternately moving the current horizontal phase starting point in left and right directions when no light is detected by the horizontal photodetector 20A;

A third step of storing current horizontal phase start point data when light is detected by the horizontal photodetector 20A during the second step;

A fourth step of determining whether light is detected in the vertical photodetector 20B,

A fifth step of alternately moving the current vertical phase starting point in an up and down direction when light is not detected from the vertical photodetector 20B,

A sixth step of storing current phase start point data when light is detected by the vertical photodetector 20B during the fifth step;

When light is detected by the horizontal and vertical photodetectors 20A and 20B in the first and fourth stages, the process proceeds to a seventh stage of terminating without performing a convergence compensation operation.

The operation of the present invention configured as described above will be described with reference to FIGS. 7 to 10.

When power is applied to the product, the horizontal photodetector 20A and the vertical photodetector 20B constituting the photodetector 20 convert the input light into a predetermined voltage and output the converted voltage, and the amplifier 21 is input. The voltage is amplified at a constant amplification factor and outputted to the A / D converter 22, and the A / D converter 22 converts the input voltage into a digital signal to be leveled and output to the controller 23.

The control unit 23 determines whether light is detected by the horizontal photodetector 20A and the vertical photodetector 20B constituting the photodetector 20 at the level of the digital signal input from the A / D converter 22. To judge.

If it is determined that the light is detected by the horizontal photodetector 20A and the vertical photodetector 20B, the control unit 23 sets the current horizontal and vertical phase patterns accurately so that the convergence adjustment point is precisely aligned with the center point of the screen. It is determined that it is turned off and does not perform the convergence compensation operation.

However, if it is determined that no light is detected by the horizontal photodetector 20A and the vertical photodetector 20B, the control unit 23 changes the starting point positions of the horizontal and vertical phase patterns and the horizontal photodetector 20A. The vertical pattern detector 20B stores phase pattern data at the point of time at which light is detected so that the starting point of the horizontal and vertical phase patterns is aligned with the center of the screen, so that the convergence is also adjusted.

The control operation of the controller 23 will be described in more detail as follows.

The controller 23 determines whether light is detected by the horizontal photodetector 20A and the vertical photodetector 20B based on data input from the A / D converter 22.

That is, the controller 23 determines that light is not detected by the light detector 20 when the level of the input data is lower than or equal to a predetermined level. When light is detected by the light detector 20 when the level of the input data is higher than or equal to the predetermined level, the controller 23 detects light. I do not think.

If it is determined that no light is detected by the horizontal photodetector 20A, the controller 23 stores the horizontal phase start point data supplied to the memory 8 so that the horizontal phase start point is alternately changed left and right. Adjust

If light is detected by the horizontal photodetector 20A while the horizontal phase pattern is moved left and right by the adjustment, the controller 23 determines that the current horizontal phase start point is aligned with the center of the screen and the current horizontal The phase data is stored in the memory 8.

On the other hand, if it is determined that the light is not detected by the vertical photodetector 20B, the controller 23 transfers the vertical phase starting point data to the memory 8 so that the vertical phase starting point is alternately changed up and down. Supply.

If light is detected by the vertical photodetector 20B while the vertical phase pattern is moved in the up and down directions by the adjustment, the controller 23 determines that the current vertical phase start point is aligned with the center of the screen. The vertical phase data of is stored in the memory 8 so that the convergence which is distorted by the influence of the geomagnetic field is correctly matched.

When the convergence of the projection TV is correctly matched, as shown in FIG. 9, the phase pattern is precisely matched to the photodetector 20 installed at the mechanical center point of the screen, that is, the horizontal photodetector 20A and the vertical photodetector 20B. .

However, when the horizontal and vertical phase patterns are shifted as shown by the dotted line shown in FIG. 9 due to the influence of the geomagnetic field, the center point of the phase is also shifted, so that the center point of the convergence that is correctly matched is distorted, so that the color of the image becomes more toward the outside of the screen. The smearing results in poor image quality.

At this time, if the convergence compensation operation as described above is executed, the phase pattern is set to the center point of the screen again so that the converged convergence is exactly matched.

The convergence compensation device of the present invention operating as described above automatically adjusts the convergence defect caused by the positional change of the phase pattern under the influence of the geomagnetic field, so that when the power is supplied to the product or the installation position of the product is changed. The control unit 23 is configured to execute automatically.

Meanwhile, as another embodiment of the present invention, when no light is detected in the photodetector 20, the controller 23 continuously changes the starting point position of the horizontal or vertical phase pattern in one direction, and changes the starting point position of the phase pattern. When light is detected by the photodetector 20, the phase pattern start point data at that time is stored in the memory 8 so that the phase pattern is aligned with the center point of the screen.

As described above, even if the starting point of the horizontal or vertical phase pattern is moved in one direction, the same result is obtained because the phase pattern returns to the current position after one cycle of movement.

In the description of the present invention, the shift of the starting point of the horizontal and vertical phase patterns in the convergence compensation operation can be arbitrarily determined by the reference clock. However, in the description of the present invention, the pattern width is assumed to be 250 mW and the pattern interval is 4 mW. It is assumed that the movement interval is 250㎱.

As described above, the present invention installs a photodetector at the mechanical center of the screen to detect horizontal and vertical phase errors and compensates the phase adjustment data by the detected errors, so that the horizontal and vertical phases are affected by the geomagnetic field. It is a digital convergence correction device and its control method that can automatically correct the convergence defect caused by the change and always provide a clear image.

Claims (4)

A light detecting means for detecting the presence of light and converting the light into a predetermined voltage, an amplifying means for amplifying the voltage output from the light detecting means at a predetermined amplification factor, and an output from the amplifying means. A / D conversion means for converting and leveling the voltage into a digital signal, and whether the light is detected by the light detection means by a signal input from the A / D conversion means, and the horizontal and vertical phase starting point according to the determination result. And a storage means for controlling the control means to be positioned at the correct position, and a storage means for storing a program for performing the horizontal and vertical phase starting point control operations of the control means. The projection type TV according to claim 1, wherein the light detecting means comprises a horizontal photodetector provided above and below the mechanical center point of the screen, and a vertical photodetector installed to the left and right of the mechanical center point of the screen. Convergence correction device in (TV). A first step of determining whether light is detected by the horizontal light detecting means, and if it is not detected, moving the current horizontal phase starting point alternately in left and right directions, and storing the current horizontal phase starting point data when light is detected; A second step of determining whether light is detected from the vertical light detecting means, and if not detected, moving the current vertical phase starting point alternately in the up and down directions, and if present, storing the current phase starting point data; And a third step of determining whether or not to perform the convergence compensation operation according to whether the light is detected from the horizontal and vertical light detection means. 4. The method of claim 3, wherein the horizontal phase starting point position in the first step is changed alternately in the left and right directions, and the vertical phase starting point position in the second step is changed in the up and down directions. Or changing the starting point position of the vertical phase pattern in a unidirectional direction.