KR950004401B1 - Cathode electrode driving method for electron gun - Google Patents

Abstract

The method is to drive the cathode of electron gun for preventing the difference in the brightness between the center and edge of a braun tube screen. Luminance signal detector(303) detects and sends luminance signal from complex image signal. The luminance correction signal device(301) generates luminance correction signal. Signal mixing device(302) mixes threshold voltage, luminance signal and luminance correction signal, and send the mixed signal to the cathode. Luminance correction signal is the maximum at the start and at the end point of horizontal scanning period and the minimum at the central point. It decreases in the first half period and increases in the second half period.

Description

Driving method of cathode electrode of electron gun and driving waveform generator

1 is a schematic diagram of an electron gun for explaining the operation principle of the electron gun.

2 is a diagram illustrating the electrodes constituting the electron gun.

3 is a block diagram of the cathode electrode driving waveform generator of the electron gun according to the present invention.

FIG. 4 shows an embodiment of the waveform diagram of each part in FIG.

5 shows another embodiment of the waveform diagram of each part in FIG.

6 is a block diagram according to an embodiment of the luminance correction signal generator.

FIG. 7 shows the waveform diagrams of the parts in FIG. 6.

8 is a block diagram according to another embodiment of the luminance correction signal generator.

FIG. 9 shows the waveform diagram of each part of FIG. 8.

* Explanation of symbols for the main parts of the drawings

301: luminance correction signal generator 302: signal synthesis unit

303: luminance signal extracting unit 603: selection means

604: multiplexer 605: monostable multivibrator

810: horizontal deflection signal generator 802: absolute value converter

803: level transition

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electron gun, and more particularly, to a method of driving a cathode electrode for the correction of the gray tube of a cathode ray tube and an apparatus for generating such a driving waveform.

In general, a screen display device having a cathode driving electron gun has a problem in that luminance of the edge of the screen is significantly lower than that of the center of the screen due to the geometry of the CRT. That is, when the same amount of electrons are emitted from the cathode electrode according to the same luminance signal, the luminance appearing at the center of the screen and the luminance appearing at the edge of the screen are measured, and the ratio is about 100: 80 to 100: 50. Will cause distortion.

Accordingly, it is an object of the present invention to provide a cathode electrode driving method of an electron gun which can improve the distortion of the luminance appearing in the center and the screen edge of the CRT.

Another object of the present invention is to provide an electron gun cathode electrode driving waveform generator for generating a signal according to the driving method.

In order to achieve the above object, the cathode electrode driving method of the electron gun of the present invention is a method of driving the cathode electrode in an image display apparatus having a cathode driving electron gun, the starting point and the ending point of the horizontal scanning period. The luminance compensation signal generation process that generates the luminance correction signal which shows the highest value at, and the lowest value at the mid-point point, and monotonically decreases in the first half period of the horizontal scanning period and monotonically increases in the second half period. ; A signal synthesizing process of synthesizing the image signal corresponding to one horizontal scanning period and the luminance correction signal to generate a luminance synthesis signal; And a cathode voltage generating process of adding the threshold voltage value of the cathode electrode to the brightness synthesis signal and applying the same to the cathode electrode.

In order to achieve the above object, the electron gun cathode electrode driving waveform generator of the present invention has a maximum value at the starting point and the ending point of the horizontal scanning period in the cathode driving electron gun, and the lowest value at the intermediate point, and the horizontal A luminance correction signal generating means for generating a luminance correction signal that is monotonically reduced in the first half period between the syringes and monotonically increased in the second half period; A luminance signal extraction unit for extracting and outputting a luminance signal from the composite video signal; And a signal synthesizing unit for synthesizing the luminance signal outputted from the luminance signal extracting unit and the luminance correction signal and adding the threshold voltage value of the cathode to the cathode.

Next, the present invention will be described in more detail with reference to the accompanying drawings.

FIG. 1 is a schematic view of an electron gun for explaining the operation principle of the electron gun, showing the side surface thereof, and FIG. 2 showing the configuration of the plane, and the electron gun is the cathode electrode K and the four grid electrodes G1, G2, G3, G4). The role of the electron gun in the CRT is basically to emit electrons. In this case, the amount of electrons emitted is controlled by the cathode electrode, the first grid electrode Gl, and the second grid electrode G2, and the path of the emitted electrons is the third grid electrode G3 and the fourth grid electrode ( Controlled by G4). That is, hot electrons are emitted from the surface of the cathode electrode K according to an external signal applied to the cathode electrode K, and the emitted hot electrons are holes of the first grid electrode G1 and the second grid electrode G2. Will pass through. The electrons passing through the hole are pre-focused by a prefocus lens formed of the second grid electrode G2 and the third grid electrode G3, and then the third grid electrode G3 and the fourth. The fine electron beam is formed by the main lens formed by the grid electrode G4. In this case, a sum of the voltage according to the luminance signal separated from the composite image signal and the threshold voltage E _K of the cathode electrode K was applied to the cathode electrode K.

3 is a block diagram of the cathode electrode driving waveform generator of the electron gun according to the present invention, and includes a luminance correction signal generator 301, a luminance signal extractor 303, and a signal synthesizer 302.

In FIG. 3, the singular luminance correction signal generation unit 301 shows the highest value at the starting point and the ending point of the horizontal scanning period, and the lowest value at the midpoint, respectively, in the first half period of the horizontal scanning period. Forging is reduced and the second half period (second half period) to perform the function of generating a luminance correction signal that increases monotonic. The luminance signal extracting unit 303 extracts and outputs a gray level signal from the composite video signal, and the signal synthesizing unit 302 synthesizes the luminance signal output from the luminance signal extracting unit 303 and the luminance correction signal. After that, the threshold voltage of the cathode is added to the cathode. In this case, the signal synthesizing unit 302 may have various methods of synthesizing the luminance signal and the luminance correction signal. For example, there may be a first addition method and a second multiplication method. The level of the luminance correction signal output from the luminance correction signal generator 301 is determined according to which method is used.

First, a case in which the luminance signal and the luminance correction signal are synthesized using the method added by the signal synthesis unit 302 will be described. For example, when the same amount of electron beam is scanned from the cathode electrode K of the electron gun to each part of the CRT, the luminance measured at the edge of the screen is 80% of the luminance measured at the center of the screen. The signal generator 301 has a maximum value for compensating for the loss of 20% when scanning the edge of the screen, and has a minimum value of "0" when scanning the center of the screen. The luminance correction signal having such a property is simply added to the luminance signal by the signal synthesizing unit 302, and then the threshold voltage E _{K of the} cathode electrode K is added to the cathode electrode K. do. Here, the signal synthesis process is performed only when the signal level of the luminance signal is not "0".

Second, in the case of synthesizing the luminance signal and the luminance correction signal through the method of multiplying by the signal synthesis unit 302, the luminance correction signal generator 301 compensates the loss of 20% at the edge of the screen. It has the maximum value to have and the value of "1" which is the lowest value in the middle of the screen. More specifically, if the luminance signal is equal to A in the entire screen, 1A / (0.8) + threshold voltage (E _K ) = 1 at the edge of the screen. A value of 25A + threshold voltage E _K is applied to the cathode electrode _K , and a value of A + threshold voltage E _K is applied to the cathode electrode at the center of the screen. In this case, the amount of electron beam emitted from the electron gun is proportional to the amount initially emitted, so the method of synthesizing the signal in the signal synthesizing unit 302 is preferably multiplied, but the function can be sufficiently achieved through the addition method. have.

FIG. 4 shows an embodiment of the waveform diagram of each part in FIG. 3, in which the luminance signal and the luminance correction signal are synthesized by the multiplication method in the signal synthesizing unit 302. FIG.

In Fig. 4, the retrace pulse is a period during which the electron beam emission from the electron gun is stopped during the period of "high" level, and the image according to the image signal is displayed during the period of "low" level. Therefore, the luminance correction signal has a maximum value at the point where the retrace pulse starts at the "low" level and at the end of the "low" level, and has a minimum value at the midpoint of the period where the retrace pulse is at the "low" level. do. In the figure, the α value is 1 / (0.8) = 1 when the measurement luminance of the screen edge is 80% of the measurement frequency of the wavefront center as described above. 25.

FIG. 5 shows another embodiment of the angular waveform diagram in FIG. 3, and in FIG. 4, the reduction and increase are not linear but parabolic. This reflects the parabolic form of the CRT in a typical television.

6 is a block diagram according to an embodiment of the luminance correction signal generator, and includes a first lamp waveform generator 60l, a second lamp waveform generator 602, and a selection means 609. 609 includes a multiplexer 604 and a monostable multivibrator (MM) 605.

In FIG. 6, the first lamp waveform generator 601 generates a ramp waveform that gradually increases in synchronization with one horizontal scanning period. In other words, the ramp waveform gradually increases in response to the falling edge of the retrace pulse. The second ramp waveform generating unit 602 generates a ramp waveform that gradually decreases in synchronization with one horizontal scanning period. The second ramp waveform generating unit 602 gradually decreases in response to the falling edge of the retrace pulse, similar to the first ramp waveform generating unit 601. Ramp waveform is generated. Here, since the period in which the retrace pulse is "high" is a period in which no image is displayed, the output of the first lamp waveform generator 601 and the second lamp waveform generator 602 may have any value.

In FIG. 6, the selecting means 609 selects the output of the second ramp waveform generating means during the first half period in one horizontal scanning period and the first during the second half period. It performs the function of selecting the output of the ramp waveform generating means. That is, the monostable multivibrator (MM) 605 generates pulses that are enabled for half a period in one horizontal scanning period in response to the falling edge of the retrace pulse, and the multiplexer 604 selects and controls the output signal of the monostable multivibrator. A terminal is input, and outputs of the first lamp waveform generator 601 and the second lamp waveform generator 602 are input to two input terminals.

FIG. 7 shows the waveform diagram of each part in FIG. 6, and the signal 609 output from the multiplexer 604 has its lowest value at the midpoint of the period in which the retrace pulse is "low", that is, in the horizontal scanning period.

8 is a block diagram according to another embodiment of the luminance correction signal generator, and includes an absolute value converter 802 and a level shifter 803.

In FIG. 8, the absolute value converting unit 802 inputs a sawtooth wave-shaped horizontal deflection signal generated to deflect the electron beam of the CRT in the horizontal direction from the horizontal deflection signal generator 801 to reference the intermediate voltage level. Function to convert to absolute value by level. The level shifter 803 adds the predetermined value so that the lowest value of the signal output from the absolute value converter 802 becomes a predetermined value, and the maximum value and the minimum value of the output of the absolute value converter 802 are added. When the difference is αA, the predetermined value is set to "A". In other words, when the measured luminance of the edge of the screen relative to the center of the screen is 0.8 as described above, if the difference between the maximum value and the minimum value of the output of the absolute value converter 802 is 1.25A, the level shifter ( 803 performs a function of adding an A value. In this case, the signal synthesizing unit 302 performs the same method as the luminance signal x 1 / A x luminance correction signal in multiplying the luminance signal with the luminance correction signal. At this time, the waveform of each block is shown in FIG.

As described above, the present invention has an effect of improving the distortion of the luminance due to the geometry of the CRT, and when it is implemented in digital, it can be implemented as a very simple device.

Claims (8)

In the method of driving the cathode electrode in an image display apparatus having a cathode driving electron gun, each of the maximum value at the start point and the end point of the horizontal scan period and the lowest value at the intermediate point, respectively, A luminance correction signal generation process of generating a luminance correction signal that monotonically decreases in the first half period and monotonically increases in the second half period; A signal synthesizing process of synthesizing the image signal corresponding to one horizontal scanning period and the luminance correction signal to generate a luminance synthesis signal; And a cathode voltage generation process of adding the threshold voltage value of the cathode electrode to the cathode composite signal to the brightness synthesis signal. 2. The method of driving a cathode of an electron gun according to claim 1, wherein the lowest value of said luminance correction signal is one. 3. The method according to claim 2, wherein the signal synthesis process multiplies the image signal corresponding to one horizontal scanning period by the luminance correction signal. The method of claim 1, wherein the signal synthesis process adds an image signal corresponding to one horizontal scanning period and the luminance correction signal. In the cathode-powered electron gun, the maximum value is shown at the starting and ending points of the horizontal scanning period, the lowest value at the intermediate point, and monotonically reduced during the flrst half period of the horizontal scanning period. in half period) luminance luminance signal generating means for generating monotonically increasing luminance correction signal; A luminance signal extraction unit for extracting and outputting a luminance signal from the composite video signal; And a signal synthesizing unit for synthesizing the luminance signal outputted from the luminance signal extracting unit and the luminance correction signal, and adding the threshold voltage value of the cathode to the cathode to apply the electron gun cathode electrode. Waveform Generator. 6. The apparatus of claim 5, wherein the luminance correction signal generating means comprises: first lamp waveform generating means for generating a ramp waveform which gradually increases in synchronization with one horizontal scanning period; Second lamp waveform generating means for generating a ramp waveform which gradually decreases in synchronization with one horizontal scanning period; Selecting means for selecting an output of the second lamp waveform generating means during a first half period in one horizontal scanning period and selecting an output of the first lamp waveform generating means during a second half period; Electron gun cathode electrode drive waveform generator characterized in that it comprises. 7. The monostable multivibrator according to claim 6, wherein said selecting means generates a pulse that is enabled for half a period in one horizontal scanning period in response to the falling edge of the retrace pulse, and selects and outputs the output signal of the monostable multivibrator. And a multiplexer for inputting a terminal and inputting the outputs of the first lamp waveform generating means and the second lamp waveform generating means to two input terminals. 6. The apparatus of claim 5, wherein the luminance correction signal generating means inputs a sawtooth wave-shaped horizontal deflection signal, which is generated to deflect the electron beam of the CRT in the horizontal direction, from the horizontal deflection signal generator, and sets the intermediate voltage level as a reference level. Absolute value conversion unit to convert to; And a level transition section for adding the predetermined value so that the lowest value of the signal output from the absolute value converting portion becomes a predetermined value.