KR20040055363A - Convergence cntrol apparatus for Projection television having Multi mode and a method controlling thereof - Google Patents

Abstract

PURPOSE: An apparatus and a method for compensating convergence for a multimode projection television are provided to measure and store standard position data of reference patterns which are displayed in a production line after completing the convergence relating to anyone mode among multi modes, thereby reducing convergence control time and enhancing productivity. CONSTITUTION: The first storing unit(115) stores plural reference pattern corresponding multimode and data as the standard for calculating terrestrial magnetism effect compensation data. Light sensors(S1,S2,S3,S4) sense luminance of reference pattern corresponding to anyone mode among plural reference patterns formed a screen(140). An A/D(Analog/Digital) converter(111) converts the output voltage of the light sensors(S1,S2,S3,S4) into digital data. A convergence control unit(113) calculates a convergence compensating vector on the basis of data received from the A/D converter(111) and compensates terrestrial magnetism distortion by modes by using the calculated compensating vector.

Description

Convergence cntrol apparatus for Projection television having Multi mode and a method controlling

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and method for controlling convergence of a projection television, and more particularly, to a convergence compensator and a method for compensating for convergence automatically in a projection television supporting multi-mode.

Projection television using a CRT or liquid crystal display uses a method of expressing an image signal as a visually recognizable image by scanning a color corresponding to each of RGB (Red, Green, Blue) colors on the screen. At this time, by controlling the deflection of the cathode ray by applying a magnetic field to control the exact position of the cathode ray to be scanned. Therefore, the degree of deflection of the cathode ray is directly affected by the magnetic field.

Typically, when producing a projection television on a production line, the degree of deflection is adjusted so that the cathode ray can be accurately scanned at a desired position on the CRT screen. However, because the size of the geomagnetic field differs from that of the location where the production line exists, depending on the region and direction in which the projection television is actually installed, the size of the geomagnetic field will affect the exact image formation of the projection television. Given. That is, such a difference in the geomagnetic field causes distortion in the degree of deflection of the cathode ray so that an accurate image is not formed on the CRT screen. Therefore, in order to compensate for the influence of the geomagnetic field that varies from place to place, the projection television has a circuit for compensating for the influence of the geomagnetic field on its own, and this compensation circuit is called a convergence control circuit.

1 to 3 are diagrams for explaining a conventional convergence control method.

As shown in Fig. 1, the front surface of the case 10 of the projection television is equipped with a screen 140 for displaying an image formed by the CRTs. Predetermined reference patterns P _H and P _V are displayed on the screen 140, and a plurality of optical sensors S ₁ , S ₂ , S ₃ , and S ₄ are installed in the case 10.

The reference pattern is composed of a horizontal reference pattern (P _H ) displayed in the form of a horizontal line, and a vertical reference pattern (P _V ) displayed in the form of a vertical line. The horizontal reference pattern P _H is moved vertically from the top to the bottom of the screen 140 as indicated by the vertical arrow, and the vertical reference pattern P _V is displayed on the left side of the screen 140 as indicated by the horizontal arrow. From the horizontal direction toward the right.

The photosensors S ₁ , S ₂ , S ₃ , and S ₄ are respectively provided on the upper surface, the left surface, the lower surface, and the right surface of the screen 140. Position of each optical sensor (S ₁ , S ₂ , S ₃ , S ₄ ), namely (x ₁ , y ₁ ), (x ₂ , y ₂ ), (x ₃ , y ₃ ), (x ₄ , y ₄ ) Is stored in a microcomputer (not shown) in the projection television. Each optical sensor S ₁ , S ₂ , S ₃ , S ₄ measures the luminance of the reference patterns P _H and P _V moving in the horizontal and vertical directions. In this case, the first and third light sensors S ₁ and S ₃ measure the luminance of the vertical reference pattern P _V , and the second and fourth light sensors S ₂ and S ₄ are horizontal reference patterns P. _H ) is measured.

2 and 3 illustrate the voltage output from the first optical sensor S ₁ , that is, the voltage value of the luminance measurement result of the vertical reference pattern P _V. As shown in FIG. 2, in the state where convergence control is performed by reflecting the magnitude of the geomagnetic field in the production line, the output voltage of the first optical sensor S ₁ , which is the luminance measurement result of the vertical reference pattern P _V , is horizontal. It has a maximum at the x ₁ position in the direction. However, when a projection television is placed in a different location than the production line because the effect degree of system prophet vary, the position of the reference pattern as shown in Figure 3 is slightly off from the position being out as long as Δx ₁ from x _1, Therefore, the output voltage of the first optical sensor (S ₁₎ has a maximum value at a position off by Δx from ₁ x ₁ on the horizontal direction. The microcomputer in the projection television uses the deviation value to determine the magnitude of the geomagnetic field, and based on the determined result, the microcomputer compensates for the distorted picture by the influence of the geomagnetic field. As a result, an accurate image is formed on the screen of the TV.

As described above, the conventional convergence control apparatus of the projection television stores in the memory the exact position (x ₁ ) data measured by the optical sensor using the reference pattern data and the reference pattern in which the convergence is adjusted in the production line. Accordingly, in the case of a projection television that supports multi-modes such as NTSC, PAL, and DTV, the reference pattern data and the position-specific position data for each mode are stored in the memory.

In addition, even after the projection television is released, an operation of compensating convergence for each mode must be performed in the process of performing an automatic color matching mode that compensates for convergence, thereby storing the compensated mode-specific convergence data.

As such, the convergence compensation method of the projection television supporting the multi-mode has troublesome not only in the production line but also in the compensation process of the user.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide a convergence compensation device and a compensation method thereof, in which the compensation of multi-mode convergence is simple in a projection television capable of supporting multi-mode. .

1 is a diagram showing a screen displaying a reference pattern output for the geomagnetic field compensation of a typical projection television,

FIG. 2 is a graph illustrating a voltage output in a normal state of one of the photosensors shown in FIG. 1;

3 is a graph illustrating a voltage output by one of the optical sensors shown in FIG. 1 when the screen displayed on the screen is distorted by a geomagnetic field;

4 is a schematic block diagram of a projection television having a convergence compensation device according to the present invention;

5 is a flowchart illustrating a convergence control method according to the present invention, and

6 to 9 are conceptual views sequentially illustrating a process in which distortion of a reference pattern is compensated by the convergence control method according to the present invention.

Explanation of symbols on the main parts of the drawings

S ₁ , S ₂ , S ₃ , S ₄ : Optical sensor 111: A / D converter

113: convergence control unit 115: first storage unit

117: second storage unit 121: deflection control unit

131: main controller 123: deflection circuit

125: CRT 140: Screen

According to an aspect of the present invention, there is provided a convergence compensating apparatus for a multi-mode projection television, including: a first storage unit for storing a plurality of reference patterns corresponding to a plurality of modes, and any one of the plurality of reference patterns. A plurality of optical sensors which are respectively installed on opposite sides of the displayed screen to sense a change in luminance of the one reference pattern moved on the screen, a standard position for the one reference pattern and the one reference A convergence control unit for calculating compensation data based on the difference between the measurement positions at which the maximum luminance is measured by the optical sensor for the pattern, and a second storage unit for storing the calculated compensation data, wherein the convergence control unit stores the stored Based on the compensation data, the plurality of reference patterns corresponding to the plurality of modes are applied to the geomagnetic field. The deflection circuit is controlled so that the distorted error is compensated for.

The compensation data calculated by the convergence controller is data for compensating an angular error and a position error in which any one of the reference patterns is distorted by a geomagnetic field, and the convergence controller is configured to calculate the angular error and the position error. Compensation vectors are calculated based on the respective compensation data. The compensation vector is stored in the second storage unit.

The convergence controller compensates for the angular error and the position error of each of the plurality of reference patterns corresponding to a plurality of modes by using the compensation vector corresponding to one of the previously stored reference patterns.

At least two pairs of the optical sensors are respectively provided on the upper and lower sides and the left and right sides of the screen, whereby the angular errors and the position errors are detected for the horizontal and vertical directions on the screen, respectively.

On the other hand, the multi-mode projection television convergence compensation method according to the present invention is to measure the luminance change of any one of the reference pattern while the reference pattern of any of the plurality of reference patterns corresponding to the plurality of modes are moved on the screen. Calculating compensation data based on a difference between a standard position for the one reference pattern and a measurement position at which the maximum luminance is measured by the optical sensor for the one reference pattern, and the calculated compensation data And compensating for an error in which the plurality of reference patterns corresponding to the plurality of modes are distorted by a geomagnetic field, based on the stored compensation data.

The calculating step includes calculating compensation data for an angular error and a position error in which one of the reference patterns is distorted by a geomagnetic field, and calculating a compensation vector based on the calculated compensation data for the angular error and the position error. It further includes the step of calculating. In the storage step, the compensation vector is stored.

The compensating step compensates for the angular error and the position error of each of the plurality of reference patterns corresponding to a plurality of modes by using the compensation vector corresponding to one of the previously stored reference patterns.

The angular error and the position error of the calculating step are respectively detected in the horizontal and vertical directions on the screen by the optical sensors provided on the upper and lower sides and the left and right sides on the screen.

Therefore, first, productivity is reduced by measuring and storing the standard position data of the maximum luminance of the reference pattern (P _H , P _V ) displayed after the completion of the convergence control in the production line in only one of the multi modes. Can be improved.

Second, by calculating the convergence compensation value for any one of the multi-mode after the release and storing the compensation vector, the convergence compensation value for each of the multi-modes can be obtained by the stored compensation vector. This makes it possible to reduce the amount of stored data more efficiently than existing systems that store respective convergence compensation values for multimode.

Hereinafter, with reference to the drawings will be described the present invention in more detail. In the description of the present invention, the configuration of the reference pattern, the screen on which the reference pattern is displayed, and the optical sensor installed on the screen are the same as in FIG. Quote with reference sign.

4 is a schematic block diagram of a projection television with a convergence control device according to the present invention. The projection television controls the image forming operation by adjusting the CRT 125 for reproducing the video signal to form an image, the screen 140 for displaying the image formed by the CRT 125, and the degree of cathode ray deflection of the CRT 125. It has a deflection circuit 123. Projection televisions have three CRTs 125 that display images independently for each of the colors R, G, and B. The image formed by each CRT 125 is reflected by a mirror (not shown), and the reflected image is displayed on the screen 140. A projection television may employ a liquid crystal display or the like in addition to the CRT 125 as an image display device.

In addition, the projection television includes a plurality of reference patterns formed on the first storage unit 115 and the screen 140 for storing data which are a reference for the calculation operation of the geomagnetic field influence compensation data and a plurality of reference patterns corresponding to the multi-mode. The output voltages of the light sensors S ₁ , S ₂ , S ₃ , and S ₄ and the light sensors S ₁ , S ₂ , S ₃ , and S ₄ that detect the luminance of the reference pattern corresponding to any one of the modes Based on the data received from the A / D converter 111 and the A / D converter 111 for converting to digital data, the compensation vector for convergence compensation is calculated and the geodesic of the reference pattern for each mode using the calculated compensation vector. A convergence control unit 113 for compensating the system distortion, a second storage unit 117 for storing the calculated compensation vector of the convergence control unit 113, an input unit 110 for inputting the user's mode-specific convergence compensation command, mode Convergence compensation is provided in response to a separate convergence compensation command. Has a deflection control unit 121 for controlling the operation of the bias circuit 123 according to control of the main controller for controlling the overall system to line 131, the main control section 131 and the convergence control section 113.

As described above in the description of the related art, the first storage unit 115 stores a plurality of reference patterns for the convergence control reference pattern corresponding to the multi-mode, and the reference pattern P displayed after the convergence control in the production line is completed. The maximum luminance output position of _H , P _V ), that is, the standard position of the reference pattern P _H , P _V (hereinafter, referred to as the “standard position”) is stored. Here, the stored standard positions are standard positions of the reference patterns P _H and P _V corresponding to any one of the plurality of reference patterns corresponding to the multi-mode.

When a user's convergence adjustment command (hereinafter, referred to as an 'automatic matching command') is input through the input unit 110, the main control unit 131 may generate a reference pattern P corresponding to a standard position stored in the first storage unit 115. _H , P _V ) are displayed on the screen 140.

The photosensors S ₁ , S ₂ , S ₃ , and S ₄ detect the luminance of the reference patterns P _H and P _V irradiated to the screen 140 and output a voltage corresponding to the luminance. The voltages output by the photosensors S ₁ , S ₂ , S ₃ , and S ₄ are converted into digital data by the A / D converter 111.

The convergence control unit 113 is a position at which the photosensors S ₁ , S ₂ , S ₃ , and S ₄ output the maximum voltage value based on the data of the A / D converter 111, that is, the photosensor S ₁ ,. S ₂ , S ₃ , and S ₄ ) detect the maximum luminance measurement position (hereinafter, referred to as 'measurement position'), which is a position where the luminance of the reference patterns P _H and P _V is measured as the maximum. The convergence control unit 113 compares the detected measurement position with a standard position previously stored in the first storage unit 115, detects the degree of distortion of the reference patterns P _H and P _V by the geomagnetic field, and compensates the compensation vector. To calculate. The compensation vector calculated as described above is stored in the second storage unit 117.

The convergence control unit 113 calculates the compensation data by adding the compensation vector stored in the second storage unit 117 to the reference patterns P _H and P _V. The convergence controller 113 controls the deflection controller 121 according to the compensation data so that the deflection circuit 123 compensates for the influence of the geomagnetic field applied to the CRT 125.

In addition, when an automatic color matching command for a multi-mode other than the mode corresponding to the reference patterns P _H and P _V is input through the input unit 110, the convergence control unit 113 sends the first storage unit 115 to the first storage unit 115. Compensation data for each mode is calculated by adding the compensation vector stored in the second storage unit 117 to the reference pattern corresponding to each stored mode. Thereafter, the convergence control unit 113 controls the deflection control unit 121 according to the compensation data to compensate the influence of the geomagnetic field applied to the CRT 125 by the deflection circuit 123 for each mode.

Hereinafter, the convergence compensation method according to the present invention will be described with reference to FIGS. 5 to 9.

When power is supplied to the projection television, a convergence control method is performed before outputting the tuned broadcast signal on the CRT 125, or when an automatic color matching command is input by a user as in the present invention.

When the automatic color matching command input through the input unit 110, first, the main control unit 131 is first stored predetermined reference pattern (P _V, P _H) of the plurality of reference patterns to the section 115, for example, a multi-mode The reference patterns P _V and P _H corresponding to the first mode are displayed on the screen 140 (S10). Of course, the first mode is a mode corresponding to the standard position previously stored in the first storage unit 115. The reference patterns P _V and P _H corresponding to the first mode are reflected by a mirror (not shown) and displayed on the screen 140. The reference patterns P _V and P _H are moved in the vertical and horizontal directions on the screen 140. First, horizontal convergence control is performed while the vertical reference pattern P _V is moved in the horizontal direction, and then vertical convergence control is performed while the horizontal reference pattern P _H is moved in the vertical direction. Horizontal convergence control and vertical convergence control may be performed at the same time. 5 illustrates a process of performing convergence control in the horizontal direction, which will be described in detail as follows.

While the vertical reference pattern P _V is moved in the horizontal direction, the first optical sensor S ₁ and the third optical sensor S ₃ installed on opposite sides of the screen 140, that is, the upper side and the lower side, respectively. ) Measures the luminance change in the horizontal direction of the vertical reference pattern (P _V ) (S20). On the basis of the measured luminance change, as described above in the description of the prior art, the 'measuring position' at which the maximum luminance is output is detected (S30), and the measurement position is stored in the 'standard storage unit 115'. The distance difference on the upper side and the distance difference on the lower side on the screen 140 are calculated, respectively. That is, for a standard position of the vertical reference pattern perpendicular to the reference pattern (P _V) by the effect of the system measuring positions prophet of (P _V), so inclined at a predetermined angle, for example, screen (140 as shown in Figure 6 The vertical reference pattern (P _V ) actually displayed on the) has a distance difference of ΔX ₁ to the right of the upper side of the screen 140 with respect to the vertical reference pattern of the production line, and to the left of the lower side of the screen 140. _There is a distance difference of ΔX ₃ .

The convergence control unit 113 calculates an angular error of the vertical reference pattern P _V using the distance differences ΔX ₁ and ΔX ₃ (S40), and calculates compensation data for each error (S50). This process is described in detail as follows.

That is, the convergence control unit 113 is a vertical reference pattern actually displayed on the screen 140 as (P _V), where the upper and lower surfaces ΔX (both the average value of the distance in from the _first screen 140 shown in FIG. 7 Compensation data is calculated to be + ΔX ₃ ) / 2. To this end, the convergence control unit 113 calculates compensation data that can be deflected so that the vertical reference pattern P _V is moved by ΔX ₁ − (ΔX ₁ + ΔX ₃ ) / 2. For example, if ΔX ₁ = 3 and ΔX ₃ = 1 in FIG. 6, the average value is (3 + 1) / 2 = 2, and the compensation data is 3−2 = 1.

Then, the (P _V) perpendicular to the reference pattern as shown in Figure 8 calculates the compensation data to be placed in the rotated position by the resolution difference. To this end, the compensation data is calculated so that the degree of compensation increases in proportion to the distance from the center portion in the vertical direction in the screen 140. For example, in FIG. 7, since there is no position error at the intersection point between the standard position of the reference pattern and the measurement position of the reference pattern, distortion compensation is not performed, and the compensation degree is increased in proportion to the distance from the intersection point to the upper surface of the screen 140. In the upper surface, compensation data is calculated such that compensation is performed by an average value ((ΔX ₁ + ΔX ₃ ) / 2) = 2.

In this manner, the compensation data θ for the angle error for calculating the state shown in FIG. 6 to the state shown in FIG. 8 is calculated.

On the other hand, as described above, the projection television has three CRTs 125 for outputting colors of R, G, and B, and the reference patterns of the colors are different in degree to which they are deflected by the geomagnetic field. Therefore, when the same compensation data is calculated to compensate for the angular error as described above, the actual compensation degree according to the distortion compensation process for each color is different. Therefore, after the distortion compensation for the angular error is performed, as shown in FIG. 8, the position of the vertical reference pattern P _V may have a predetermined position error ΔX ′ in the horizontal direction according to the color. . The convergence control unit 113 calculates such a position error ΔX 'based on the output values of the photosensors S ₁ and S ₃ (S60), and the compensation data Δ for compensating the calculated position error ΔX'. ) Is calculated (S70). That is, the compensation data for compensating for the position error in the state as shown in FIG. 9 in the state as shown in FIG. 8 is calculated. In this case, the compensation data Δ of the position error ΔX ′ is calculated for each color. That is, the position error [Delta] X 'is measured for each CRT 125 that outputs blue, red and green, and the compensation data is calculated.

In this manner, the convergence control unit 113 calculates the compensation vectors θ and Δ using the compensation data calculated for the angular error and the position error (S80). Accordingly, the convergence control unit 113 controls the deflection circuit 123 through the deflection control unit 121 to compensate for the distortion caused by the geomagnetic field according to the compensation vectors θ and Δ.

Meanwhile, the convergence control unit 113 stores the calculated compensation vectors θ and Δ in the second storage unit 117 (S90).

Thereafter, when an automatic color matching command for the second mode is input by the user through the input unit 110, the convergence control unit 113 may compensate the compensation vector θ, stored in the second storage unit 117. Compensation data for the second mode is calculated by adding?) To the reference pattern corresponding to the second mode. The convergence control unit 113 controls the deflection circuit 123 through the deflection control unit 121 so that distortion caused by the geomagnetic field in the second mode is compensated based on the compensation data (S100).

When the automatic color matching command is input for each mode in this manner, the convergence control unit 113 uses the compensation vectors θ and Δ stored in the second storage unit 117 to convergence for each mode. Will be rewarded. Alternatively, when the automatic color matching command is input in the first mode, convergence compensation of all modes may be performed at once using the compensation vectors θ and Δ for all modes.

In the above description of FIGS. 5 to 9, a process of compensating convergence for the multi-mode by calculating a compensation vector using the vertical reference pattern P _V is described. However, the compensation is performed using the horizontal reference pattern P _H. Compensation by calculating the vector is also performed using the second and fourth optical sensors S ₂ and S ₄ according to the same process as described above.

Therefore, after calculating the compensation vector using the standard position and the measurement position data for one of the multi-mode, it is possible to compensate the convergence for each of the multi-mode using the compensation vector.

According to the present invention, first, shorten the convergence adjustment time by measuring and storing the standard position data of the maximum luminance of the reference pattern (P _H , P _V ) displayed after the convergence control is completed in the production line in only one of the multi modes. By this, productivity can be improved.

Second, by calculating the convergence compensation value for any one of the multi-mode after the release and storing the compensation vector, the convergence compensation value for each of the multi-modes can be obtained by the stored compensation vector. This makes it possible to reduce the amount of stored data more efficiently than existing systems that store respective convergence compensation values for multimode.

Although the above has been illustrated and described with respect to the preferred embodiment of the present invention, the present invention is not limited to the specific preferred embodiment described above, the present invention without departing from the gist of the invention claimed in the claims Various modifications can be made by those skilled in the art, and such changes are within the scope of the claims.

Claims (10)

A first storage unit which stores a plurality of reference patterns corresponding to a plurality of modes; A plurality of optical sensors installed on opposite sides of a screen on which one reference pattern of the plurality of reference patterns is displayed to sense a change in luminance of the one reference pattern moved on the screen; A convergence control unit configured to calculate compensation data based on a difference between a standard position for the one reference pattern and a measurement position at which the maximum luminance is measured by the optical sensor for the one reference pattern; And And a second storage unit for storing the calculated compensation data. And the convergence control unit controls a deflection circuit so that an error in which the plurality of reference patterns corresponding to the plurality of modes are distorted by a geomagnetic field is compensated for, based on the stored compensation data. The method of claim 1, The compensation data calculated by the convergence control unit, The one reference pattern is distorted by a geomagnetic field based on a difference between a standard position for the one reference pattern and a measurement position at which the maximum luminance is measured by the optical sensor for the one reference pattern. A convergence compensation device for a projection television, characterized in that the data is for compensating for a difference in position and difference. The method of claim 2, The convergence control unit, Calculating a compensation vector based on the calculated compensation data for the angular error and the position error; And the compensation vector is stored in the second storage unit. The method according to claim 1 or 3, The convergence control unit, And a compensation for the angular error and the position error of each of the plurality of reference patterns corresponding to a plurality of modes by using the compensation vector corresponding to any one of the previously stored reference patterns. The method according to claim 1 or 2, At least two pairs of the optical sensors are respectively installed on the upper and lower sides and the left and right sides of the screen, Thereby, the angular error and the position error are respectively detected for the horizontal direction and the vertical direction on the screen. Measuring a luminance change of any one of the reference patterns while one of the reference patterns corresponding to the plurality of modes is moved on the screen; Calculating compensation data based on a difference between a standard position for the one reference pattern and a measurement position at which the maximum luminance is measured by the optical sensor for the one reference pattern; Storing the calculated compensation data; And And compensating for the error in which the plurality of reference patterns corresponding to the plurality of modes are distorted by a geomagnetic field based on the stored compensation data. The method of claim 6, The calculating step, The one reference pattern is a geomagnetic field based on a difference between a standard position of any one of the plurality of reference patterns and a measurement position at which the maximum luminance is measured by the optical sensor for the one reference pattern. Calculating the compensation data for the distorted angular error and the position error. The method of claim 6, The calculating step, Calculating a compensation vector based on the compensation data for the angular error and the position error; And in the storing step, the compensation vector is stored. The method according to claim 6 or 8, The compensation step, The method of claim 1, wherein the angle error and the position error of each of the plurality of reference patterns corresponding to the plurality of modes are compensated by using the compensation vector corresponding to the one reference pattern stored in advance. The method according to claim 6 or 7, The angular error and the position error of the calculating step, And the optical sensors provided on the upper, lower, left, and right sides of the screen detect the horizontal and vertical directions on the screen, respectively.