KR20000024802A - Apparatus and method of adjusting convergence of projection visual display - Google Patents

Abstract

The disclosed convergence adjustment method and control device is to adjust the convergence of the R, G and B images displayed on the screen by projecting the R, G and B projectors in the projection image display.

The present invention allows one of the projectors located at the center of the R, G, and B projectors to display a predetermined cross hatch pattern on the screen, and manually adjust the convergence while the operator visually checks the cross hatch pattern displayed on the screen. Or adjusts the convergence automatically by controlling the convergence control unit according to the display state of the cross hatch pattern, and when the convergence adjustment of the cross hatch pattern indicated by one projector is completed The computer system recognizes the display position of the cross hatch pattern by inputting it, stores it as reference convergence data, and then sequentially displays the cross hatch patterns on the screen while operating the projectors located on both the left and right sides, and displays them on the screen. Cross hatch patterns taken with the camera and Searches the display position of the cross hatch pattern, compares the display position of the searched cross hatch pattern with the stored reference convergence data, and calculates the convergence error value. do.

Description

Convergence Control Method and Control Device of Projection Image Display

The present invention provides a projection image display such as a projection television receiver for projecting an image of R, G, and B with a projector of R, G, and B, and magnifying and displaying the image on the screen. The present invention relates to a convergence adjusting method and an adjusting apparatus of a projection image display device that matches and adjusts convergence.

In general, a projection image display includes a cathode ray tube on a projector of R, G, and B, or a flat panel display device such as a liquid crystal display (LCD) panel and a plasma display panel (PDP) to display images of R, G, and B, respectively. Doing.

The R, G, and B projectors project images of R, G, and B respectively displayed, and enlarge the projected images of R, G, and B through an optical system, and then display them on a screen to enlarge a predetermined image. To make the video visible.

In such a projected image display, when the images of R, G, and B respectively displayed on the R, G, and B projectors and enlarged on the screen do not coincide, one image is displayed in double and triple.

Therefore, the projection image indicator adjusts the convergence so that the images of R, G, and B are enlarged to match the screen.

In order to adjust the convergence of the projection image display, the operator conventionally displays a predetermined image on the screen, and adjusts the convergence while viewing the displayed image directly.

However, the above-described conventional technology requires the skill of the operator and has a problem in that a lot of work time is required.

Accordingly, an object of the present invention is to provide a method and apparatus for adjusting convergence of a projection image display that automatically adjusts convergence.

According to the convergence adjustment method and the adjustment device of the projection image display of the present invention for achieving this object, one projector located in the center of the R, G and B projectors to display a predetermined cross hatch pattern on the screen.

When the cross hatch pattern is displayed on the screen, the operator can adjust the convergence manually while watching the cross hatch pattern or control the convergence control according to the display state of the cross hatch pattern to adjust the convergence automatically. In this case, the computer system inputs an image of the cross hatch pattern photographed by the camera to recognize the display position of the cross hatch pattern, and stores it as reference convergence data.

Next, operate the projectors located on both the left and right sides sequentially to display the cross hatch pattern on the screen, shoot the cross hatch pattern displayed on the screen with the camera, search the display position of the cross hatch pattern, and display the retrieved cross hatch pattern. The convergence error value is calculated by comparing the position with the stored reference convergence data.

When the convergence error value is calculated, the convergence control is automatically adjusted by controlling the corresponding convergence control unit according to the calculated convergence error value.

1 is a view showing the configuration of the convergence control device of the present invention,

2 is a signal flow diagram illustrating a convergence adjustment method of the present invention;

3 is a signal flow diagram showing a position search routine for searching for the intersection position of the cross hatch pattern in FIG.

4 is a view for explaining a process of setting an inspection area in a cross hatch pattern displayed on the screen according to the convergence adjustment method of the present invention;

5 is a view for explaining an operation of setting the brightness calculation area in the inspection area according to the convergence adjustment method of the present invention;

6 and 7 are diagrams for explaining an operation of calculating the center coordinates in the brightness calculation area according to the convergence adjustment method of the present invention.

* Description of the symbols for the main parts of the drawings *

10, 12, 14: R, G, and B Projectors 20: Screen

21: cross hatch pattern 30: camera

40: computer system 50: key signal input unit

60, 62, 64: R, G, and B convergence controls

100: inspection area 110, 120, 130, 140: brightness calculation area

Hereinafter, a method and a control device for adjusting convergence of a projection image display according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing the configuration of the convergence control device of the present invention.

Here, reference numerals 10, 12, and 14 denote R images for displaying and projecting predetermined images of R, G, and B, that is, cross hatch patterns 21, on a built-in cathode ray tube or a flat panel display device such as an LCD panel and a PDP. G and B projectors, and reference numeral 20 denotes a screen displaying images of R, G, and B projected by the R, G, and B projectors 10, 12, 14.

Reference numeral 30 denotes a camera for capturing a predetermined image displayed on the screen 20.

Reference numeral 40 is a computer system for determining the error value of the convergence of the image of the R, G and B taken by the camera 40 and adjust the convergence according to the determined convergence error value.

Reference numeral 50 denotes a key signal input unit which outputs an operation command according to the operator's operation and inputs it to the computer system 40.

Reference numerals 60, 62, and 64 respectively control the convergence of the R, G, and B images projected by the R, G, and B projectors 10, 12, 14 according to the output signal of the computer system 40, respectively. R, G and B convergence controls.

In the convergence control device of the present invention having such a configuration, any one of the R, G, and B projectors 10, 12, and 14 projectors, preferably one projector positioned at the center, cross-hatches the screen 20. Display the pattern 21.

That is, a projection image display device is typically provided with a G projector 12 at the center to display a G image, and R and B projectors 10 and 14 are provided at both left and right sides of the G projector to respectively display images of R and B. It is configured to display the G projector 12 located at the center first so as to display the G cross hatch pattern 21 on the screen 20.

In this way, when the G cross hatch pattern 21 of the G projector 12 located at the center is displayed on the screen 20, the convergence adjustment operation of the G cross hatch pattern 21 is performed.

The convergence adjustment operation of the G cross hatch pattern 21 is performed manually or automatically.

For example, in the manual adjustment operation, the operator operates the key signal input unit 50 while checking the G cross hatch pattern 21 displayed on the screen 20, and according to the output signal of the key signal input unit 50, the computer system. 40 controls the G convergence adjusting unit 62 to adjust the convergence to a value according to the user's operation.

And the automatic adjustment operation, the G cross hatch pattern 21 displayed on the screen 20 by the camera 30, the computer system 30 inputs the G cross hatch pattern 21 taken by the camera 30 By adjusting the convergence by controlling the G convergence control unit 62 according to the error value while comparing with the preset data.

When the convergence adjustment of the G convergence adjustment unit 62 is completed in this manner, the computer system 30 photographs the G cross hatch pattern 21 displayed on the screen 20 with the camera 30 and inputs it again. The display position of the G cross hatch pattern 21 is retrieved and stored as reference convergence data.

When the convergence adjustment of the G convergence adjustment unit 62 is completed and the reference convergence data is stored as described above, the R and B projectors 10 and 14 located on both left and right sides of the G projector 12 are sequentially operated to display the screen 20. ) And the cross hatch pattern 21 of R and B are sequentially displayed, and the computer system 40 inputs the cross hatch pattern 21 of R and B photographed by the camera 30.

Then, the cross hatch pattern 21 of the input R and B is compared with the reference convergence data to detect a convergence error value, and control the R and B convergence adjusting units 60 and 64 according to the detected convergence error value. Adjust the convergence of R and B.

2 is a signal flow diagram illustrating a convergence adjustment method of the present invention.

As shown therein, the computer system 40 performs an initialization operation in step S10, and determines whether the adjustment operation of convergence is performed in step S12.

In the case of adjusting the convergence in step S12, the computer system 40 operates the projector located at the center in step S14 to display the cross hatch pattern 21 on the screen 20.

That is, the G projector 12 is operated so that the G cross hatch pattern 21 is displayed on the screen 20.

In this state, the camera 30 photographs the G cross hatch pattern 21 displayed on the screen 20, and inputs the photographed G cross hatch pattern 21 to the computer system 40.

In this way, while operating the G projector 12 to display the G cross hatch pattern 21 on the screen 20, the convergence of the G cross hatch pattern 21 is adjusted in step S16, and in step S18. Determine if the convergence adjustment is complete.

That is, the convergence of the G cross hatch pattern 21 is adjusted by the operator operating the key signal input unit 50 manually, or the G cross hatch pattern 21 input by the camera 30 is inputted by the computer system ( 40) Automatically performs convergence adjustment while reading.

When the adjustment of the convergence is completed as described above, in the next step S20, the position of the intersection point P of the G cross hatch pattern 21 is searched and the position of the found intersection point is stored as reference convergence data.

The search for the intersection point P is performed by capturing and inputting the cross hatch pattern 21 displayed on the screen 20 with the camera 30 in step S40 as shown in FIG. 3, and inputting in step S42. Profile the brightness of one cross hatch pattern image in the transverse and longitudinal directions.

That is, the area where the cross hatch pattern 21 is displayed is bright and the area where the cross hatch pattern 21 is not displayed is dark. As shown in FIG. 4, the brightness of the cross hatch pattern image input is laterally profiled. In addition, the horizontal brightness curve H is detected, and the longitudinal brightness curve V is detected by profile in the longitudinal direction.

When the transverse brightness curve H and the longitudinal brightness curve V are detected in this manner, the intersection point P of the peak value among the transverse brightness curve H and the longitudinal brightness curve V in step S44. Set.

That is, the crossing point 21 of the cross hatch pattern 21 is detected.

When the intersection point P is detected in this manner, in step S46, the areas of P ± a and P ± b are set as the inspection area 100 for each intersection P as shown in FIG. 5.

When the inspection area 100 is set in this way, the computer system 40 checks the outline VL (VR) HU (HL) of the inspection area 100 of P ± a and P ± b in step S48. Each position is searched for brightness above the preset threshold while moving horizontally and vertically toward the intersection point P.

That is, as shown in FIG. 6 while the horizontal line VL (VR) of the inspection area 100 of P ± a is horizontally moved in the direction of the crossing point P, as shown in FIG. 6, a position where the brightness is equal to or greater than a preset threshold value. Locate (VLH) (VRH), and move the outline HU (HL) of the inspection area 100 of P ± b in the direction of the crossing point P, and as shown in FIG. Find the position HUH (HLH) that is greater than or equal to the preset threshold value.

When the horizontal position VLH VRH and the vertical position HUH HLH whose brightness is equal to or greater than the preset threshold value are found in step S48, the computer system 40 detects the horizontal position found in step S50. An area having a predetermined width is set as the brightness calculation area on the basis of the (VLH) (VRH) and the vertical position (HUH) (HLH).

That is, as shown in FIG. 6, a region having a width d from the horizontal position VLH (VRH) searched in the inspection region 100 is set as Y-axis brightness calculation regions 110 and 120, and FIG. 7. As shown in FIG. 3, the area having a width d is set as the X-axis brightness calculation areas 130 and 140 at the searched vertical position HUH HUH in the inspection area 100.

As such, when the X-axis brightness calculation regions 110 and 120 and the Y-axis brightness calculation regions 130 and 140 are set, the computer system 40 sets the X-axis brightness calculation region 110 ( 120 and the brightness average values of the Y-axis brightness calculation regions 130 and 140 in the vertical and horizontal directions.

That is, the X-axis brightness calculation regions 110 and 120 profile the brightness average value in the vertical direction, and the Y-axis brightness calculation regions 130 and 140 profile the brightness average value in the horizontal direction.

In this manner, when the average brightness values of the X-axis brightness calculation regions 110 and 120 and the Y-axis brightness calculation regions 130 and 140 are profiled, the computer system 40 displays the brightness as shown in Equation 1 in step S54. Calculate the location of your center of gravity.

Where I is the average value of the profiled brightness. L is the Y-axis and X-axis positions of the X-axis brightness calculation regions 110 and 120 and the Y-axis brightness calculation regions 130 and 140.

When the position of the center of gravity of the brightness is calculated in step S54, the midpoint coordinates of the calculated center of gravity position are calculated.

That is, it is assumed that the positions of the center of gravity of the X-axis brightness calculation regions 110 and 120 are C1 and C2, and the positions of the center of gravity of the Y-axis brightness calculation regions 130 and 140 are C3 and C4, respectively. The midpoint coordinates (C _X , C _Y ) are calculated as in Equations 2 and 3 below.

When the midpoint coordinates C _X and C _Y are calculated in this manner, the calculated midpoint coordinates C _X and C _Y are set to the intersection point position P of the cross hatch pattern 21.

When the position of the intersection point P is set in this way, the position of each intersection point P is stored as reference convergence data in step S20.

When the reference convergence data is stored as described above, the R (or B) on the screen 20 is operated by operating the projector located at the left (or right), that is, the R projector 10 (or B projector 14), in the next step S22. ) Cross hatch pattern 21 is displayed, and the intersection point P position of the R (or B) cross hatch pattern 21 indicated in step S24 is retrieved as shown in FIG. 3, and in step S26, An error value is calculated by comparing with the stored reference convergence data, and the convergence of the R (or B) cross hatch pattern 21 is automatically adjusted according to the calculated error value.

In operation S30, the B (or R) cross hatch pattern 21 is displayed on the screen 20 by operating the projector located at the right (or left), that is, the B projector 14 (or the R projector 10). After searching for the position of the intersection point P of the B (or R) cross hatch pattern 21 indicated in step S32 as shown in FIG. 3, the reference convergence data stored in the step S34 is searched. Comparing with the error value is calculated, and the convergence of the B (or R) cross hatch pattern 21 is automatically adjusted according to the calculated error value.

As described above, according to the present invention, the cross hatch pattern is displayed on the screen through one projector, and after adjusting the convergence, the intersection point of the cross hatch pattern is retrieved and stored as reference convergence data, and the screen is displayed through the other two projectors. R, G, and B projected by R, G, and B projectors by displaying a cross hatch pattern on and searching for intersections, and detecting and adjusting error values by comparing the detected intersections with the stored reference convergence data. It is possible to accurately adjust the convergence of the image, as well as to automatically perform this effect of reducing the adjustment work time of convergence.

Claims (6)

A first process in which one of the projectors of R, G, and B displays a cross hatch pattern on the screen; A second process of adjusting the convergence of the cross hatch pattern displayed in the first process and storing the adjusted cross hatch pattern as reference convergence data; A third step of displaying a cross hatch pattern on a screen while sequentially operating two different projectors when the storing of the reference convergence data is completed in the second step; A fourth step of searching for a position of the cross hatch pattern displayed in the third step; A fifth process of calculating an error value by comparing the position of the cross hatch pattern displayed in the fourth process with reference convergence data stored in the second process; And And a sixth step of adjusting convergence according to the error value calculated in the fifth step. The method of claim 1, wherein the first process comprises; Among the R, G and B projectors, operate the projector located at the center to display the cross hatch pattern, The third process is; A method of controlling the convergence of a projection image display, characterized by adjusting the convergence while displaying the cross hatch pattern by operating the projectors located at the left and right sides. The method of claim 1, A method of controlling the convergence of a projection image display, characterized in that the cross hatch pattern is searched for, stored as reference convergence data, and the convergence is adjusted. 4. The method of claim 3, wherein the intersection search of the cross hatch pattern comprises; An eleventh process of photographing and inputting an image of a cross hatch pattern displayed on a screen; A twelfth step of profiling the brightness of the crosshatch pattern image input in the eleventh step in the horizontal and vertical directions; A thirteenth step of setting intersection positions of peak values in the transverse brightness curve and the longitudinal brightness curve profiled in the twelfth process; A fourteenth step of setting an inspection area based on the location of the intersection point set in the thirteenth step; A fifteenth step of searching for a position where brightness is equal to or greater than a preset threshold value while horizontally and vertically moving the upper and lower and left and right outlines of the inspection area set in the fourteenth step in the direction of the intersection; Setting a brightness calculation area of the left and right sides of the X-axis and a brightness calculation area of the upper and lower parts of the Y-axis on the basis of the horizontal position and the vertical position that are equal to or greater than the threshold value retrieved in the fifteenth step; A seventeenth step of profiling a brightness average value of the brightness calculation area set in the sixteenth step; An eighteenth step of calculating a gravity center position of the brightness average value profiled in the seventeenth step; And And a nineteenth step of calculating a midpoint coordinate of the center of gravity calculated in the eighteenth step and setting the center point as an intersection point. The method of claim 4, wherein the eighteenth process comprises: And calculating the center of gravity of the average brightness value. Where I is the average value of the profiled brightness. L is the position of the brightness calculation area. R, G, and B projectors that project R, G, and B cross hatch patterns, respectively; A screen displaying a cross hatch pattern of R, G and B projected by the R, G and B projectors; A camera for capturing a predetermined image displayed on the screen; A computer system for determining an error value of convergence based on the images of R, G, and B captured by the camera, and adjusting the convergence according to the determined convergence error value; A key signal input unit which outputs an operation command according to an operator's operation and inputs it to the computer system; And Convergence adjustment of the projection image display, characterized in that the R, G and B convergence control unit for adjusting the convergence of the R, G and B images projected by the R, G and B projectors according to the output signal of the computer system Device.