KR100671889B1 - Method for auto-adjusting convergence of projection television - Google Patents

Abstract

The present invention relates to a method for automatically adjusting convergence of a projection television. When the convergence adjustment of a projection television is performed, the test pattern is circulated from the outside of the pattern to the center one by one while gradually reducing the thickness by a predetermined thickness while leaving the measurement range of the photo sensor. Through the measurement of the convergence error value, the convergence adjustment can be automatically performed, and there is an advantage that the adjustment time can be shortened by preventing the frequent convergence adjustment.

Projection, Convergence, Test Patterns, and Photo Sensors

Description

How to adjust the automatic convergence of a projection television {METHOD FOR AUTO-ADJUSTING CONVERGENCE OF PROJECTION TELEVISION}             

1 is a block diagram showing a convergence adjustment circuit of a general projection television.

2 is a flowchart illustrating an automatic convergence adjustment method of a projection television according to the present invention.

3 to 4 are diagrams for explaining a process adjusted by the automatic convergence adjustment method of the projection television according to the present invention.

   -Explanation of symbols for the main parts of the drawings-

10: pattern generator 20: switching / amplifier

32, 34, 36: R, G, B CRT 39: Convergence York

40: Screen 50,52,54,56,58: Photo sensor

60: convergence correction unit 70: test pattern

The present invention relates to an automatic convergence adjustment method of a projection television, and more particularly, the measurement range of the photo sensor while reducing the size of the test pattern by a predetermined thickness while circulating the size of the test pattern sequentially from the outer side to the center side when adjusting the convergence of the projection television. The present invention relates to an automatic convergence adjustment method of a projection television that measures convergence error values through a time deviating to automatically perform convergence adjustment.

In general, a projection television emits three special cathode ray tubes having three primary colors of red (R), green (G), and blue (B) light, and projects and enlarges an image by using an enlarged lens and a reflector. Speak television system to get the screen. Projection televisions are different from conventional televisions in that they form an image and display it on a separate image screen.

In projection television, the light (scanning beam) generated by the special cathode ray tubes of R, G, and B passes through the projection lens and passes through the projection lens, and the light reflected by the reflector reflects R, G, B The image is formed on a large screen installed separately from the cathode ray tube.

However, when the scanning beams of R, G and B are exactly matched on the large screen, a clear and clear screen is reproduced. Convergence adjustments must be performed.

A method of adjusting convergence of a conventional projection television will be described in detail as follows.

First, when the user selects the automatic convergence function to adjust the convergence through the menu, the digital convergence unit generates a cross pattern signal of each R, G, and B, and each of the R, G, and B through the video switch and the video amplifier. Drive the CRT to display the test pattern on the screen.

Then, each photo sensor mounted on the screen detects the cross pattern signals of each of R, G, and B, outputs them to the current / voltage converter, converts them into voltage values, and converts them into digital signals through the A / D converter. The digital convergence unit receives the digital signal and calculates the position data of the signal detected by each photosensor so that the signals of each R, G, and B line up at the photosensor points on the screen in a straight line. By changing the G, B output signals, the R, G and B signals on the screen are matched and the convergence is automatically adjusted.

However, such a conventional convergence adjustment method has a problem such as recognizing a test pattern and judging its position to match the photo sensor points, such that the adjustment efficiency is low and the adjustment time is excessively required. That is, the conventional convergence adjustment method forms a predetermined width of the test pattern, and then moves it to the left or right (up or down) to repeat the operation of detecting the test pattern by the photosensor and the left and right (up and down). By gradually decreasing the travel width, the test pattern was eventually aligned with each photo sensor point on the screen.

1 is a block diagram showing a convergence adjustment circuit of a general projection television.

As shown here, the pattern generator for generating a test pattern for convergence and the signal of the video signal or the pattern generator 10 are amplified after receiving the signals of the R, G, and B CRTs (32, 34). And a switching / amplifier 20 to be provided to the 36, and R, G, and B CRTs 32, 34 and 36 that receive and display RGB signals, respectively, and a screen 40 and a visible screen of the screen 40. (42) Photoelectric sensors (52, 54, 56, 58) installed at a predetermined position around the periphery to detect the position of the alignment pattern, and the convergence yoke (38) in accordance with the output of the photo sensors (52, 54, 56, 58). Convergence correction unit 60 for controlling.

Therefore, the position value is obtained from the output signals of the photosensors 52, 54, 56, and 58 provided at the periphery of the visible screen 42 of the screen 40, and the convergence error value is calculated using the position value. Correct the convergence according to the convergence error value.

Such a method has a problem in that it takes too much time as the repetitive movement of the test pattern to find the position of the photosensor and the test pattern not only increases convergence adjustment time but also decreases the adjustment efficiency.

The present invention was created to solve the above problems, and an object of the present invention is to reduce the size of the test pattern by a predetermined thickness while sequentially circulating the size of the test pattern from the outer side of the pattern to the center when adjusting the convergence of the projection television. The present invention provides an automatic convergence adjustment method of a projection television that measures convergence error values through a time point outside the measurement range of the sensor so that convergence adjustment can be automatically performed.

In order to achieve the above object, the present invention provides a projection television having an automatic convergence adjustment function, each of which displays a test pattern having a predetermined size so that the photosensors installed at the periphery of the visible screen of the screen are located at the center, respectively, and the sample is located at the center of the screen. Displaying a pattern, detecting a test pattern from photosensors by circulating the size of the test pattern sequentially from one side to the center of the pattern without moving the sample pattern by a predetermined thickness, and then detecting the test pattern from the photosensors. When the test pattern is not detected and the test pattern is not detected, storing the corresponding position through a wrong value with the photosensor, and calculating a correction value according to the stored position, and performing convergence correction.

In the present invention, the sample pattern and the test pattern is characterized in that the OSD pattern.

In addition, the present invention is characterized in that the minimum size of the test pattern is set to switch to the user adjustment mode below the corresponding size.

In addition, in the present invention, after performing the convergence correction, it is characterized by repeating the entire process to confirm the correction state.

The present invention made as described above displays a test pattern of a certain size so that the photosensors installed in the periphery of the screen is located in the center of the test pattern, and the sample pattern is displayed on the center of the screen, and then the size of the test pattern is moved from the outside of the pattern without moving the sample pattern. It detects the test patterns from the photosensors by sequentially circulating one side to the center and decreases them by a predetermined thickness to determine the position where the test patterns are distorted from the photosensors, calculates the convergence correction value, and automatically performs the convergence correction. By setting the size of the test pattern to be reduced, the user can fine tune by switching to the user mode after repeating the predetermined number of times.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. In addition, the present embodiment is not intended to limit the scope of the present invention, but is presented by way of example only and the same parts as in the conventional configuration using the same reference numerals and names.

2 is a flowchart illustrating an automatic convergence adjustment method of a projection television according to the present invention.

First, in the state in which the projection television having the automatic convergence adjustment function is turned on (S10), the photo sensors 52, 54, 56, and 58 installed around the visible screen 42 of the screen 40 are connected to the test pattern 70. Each of the test patterns 70 having a predetermined size is displayed so as to be located at the center of the display panel, and a sample pattern is displayed at the center of the screen 40 (S12).

In this case, when the convergence is not matched and is misconverged, the test pattern 70 is displayed in a state in which the photosensor 50 is biased to one side of the test pattern 70 as shown in FIGS. 3 to 4.

In this case, the sample pattern may display a phrase or a company logo indicating that automatic convergence is being performed.

After displaying the test pattern 70 and the sample pattern as described above, the size of the test pattern 70 is sequentially circulated from one side to the center of the pattern without movement of the sample pattern, and then reduced by a predetermined thickness while the photo sensor 52, 54, The test pattern 70 is detected from 56 and 58 (S12) (S14) and S16.

That is, as shown in FIG. 3A, when the photosensor 50 is formed at the lower right side of the test pattern 70, the size of the test pattern 70 is sequentially circulated from one side to the center from the outside of the pattern. If the predetermined thickness is decreased by a predetermined thickness, reducing the predetermined thickness of the upper side from the test pattern 70 of (a) results in the test pattern 70 as shown in (b), and reducing the predetermined thickness of the right side again results in the test pattern 70 as shown in (c). Becomes

As described above, when the size of the test pattern 70 is sequentially reduced, the test pattern 70 may not be detected from the photosensor 50 when the test pattern 70 as shown in (c) (S12) (S14). (S16).

Therefore, the converged error value can be grasped from the central part through the value at this time, thereby calculating the convergence correction value (S18).

The convergence correction is performed using the calculated correction value so as to be positioned at the center of the left and right sides as shown in FIG. 4 (S20).

However, if the difference in position is not only right and left, but also up and down, even if the left and right correction as shown in Figure 4, because the top and bottom correction is not made, by repeating the above process, it is possible to correct the wrong position difference of the left and right .

Therefore, the above process is repeated if the correction is normally performed.

At this time, as shown in (a) of FIG. 4, the photosensor 50 is displayed to be located at the center of the test pattern 70, but since it may be located at the bottom, the size of the test pattern 70 is again patterned according to the above process. Reducing the predetermined thickness while circulating sequentially from the outer side to the central portion by one side results in a test pattern 70 as shown in (b), and again reduces the predetermined thickness in the lower side to a test pattern 70 as shown in (c).

As described above, when the size of the test pattern 70 is sequentially reduced, the test pattern 70 may not be detected from the photosensor 50 when the test pattern 70 as shown in (c) (S12) (S14). (S16).

Therefore, the converged error value can be grasped from the central part through the value at this time, thereby calculating the convergence correction value (S18).

After performing the first convergence correction as described above, it is possible to correct the distorted position up, down, left, and right by checking the corrected state (S20).

The same process is performed for each RGB.

On the other hand, when reducing the test pattern 70 may be set to the minimum size of the test pattern 70 to be switched to the user adjustment mode to be finely adjusted by the user.

That is, when the convergence error value is large, the convergence correction is automatically performed, and when the convergence error value is small, the user can finely adjust.

As described above, the present invention measures the convergence error value through a time point outside the measurement range of the photo sensor while decreasing the predetermined thickness while circulating the test pattern size one side from the outside to the center of the pattern in order to adjust the convergence of the projection television. There is an advantage in that the convergence adjustment can be performed automatically.

In addition, since the convergence error value is measured while decreasing the size of the test pattern step by step, there is an advantage that the adjustment time can be shortened by preventing frequent convergence adjustment.

Claims (4)

In a projection television with an automatic convergence adjustment function, Displaying a test pattern of a predetermined size and displaying a sample pattern at the center of the screen so that the photosensors installed at the periphery of the visible screen of the screen are respectively positioned at the center; Detecting the test pattern from the photosensors while circulating the size of the test pattern sequentially from one side to the center without moving the sample pattern by a predetermined thickness; Detecting a test pattern from the photosensors and storing a corresponding position through a wrong value with the photosensor if the test pattern is not detected; Performing convergence correction by calculating the correction value according to the stored position Automatic convergence adjustment method of the projection television, characterized in that consisting of. The method of claim 1, wherein the sample pattern and the test pattern are OSD patterns. The method of claim 1, wherein the minimum size of the test pattern is set to be changed to a user adjustment mode below the corresponding size. The method of claim 1, wherein after performing the convergence correction, the entire process is repeated to confirm the correction state.

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