KR940005385B1 - Shading compensation circuit of projection tv - Google Patents

Abstract

The shading correction circuit of projection television includes a pulse generating circuit for generating a horizontal parabola pulse and a horizontal sawtooth wave pulse having a 1-horizontal line period according to horizontal and vertical blanking signals, a pulse shaping circuit for generating first, second and third shading correction pulses, and a mixer circuit for mixing the first, second and third shading pulses with a luminance signal, thereby removing a shading phenomenon of projection television.

Description

Shading Correction Circuit of Projection TV

1 is an arrangement of red, green and blue cathode ray tubes and screens in a projection television.

2 is a block diagram of a shading correction circuit of a projection television according to the present invention.

3 is a waveform diagram of an essential part of a shading correction circuit of a projection television according to the present invention.

4A, 4B and 4C are state diagrams showing the state of the luminance signal corrected by the shading correction circuit of the projection television according to the present invention.

* Explanation of symbols for main parts of the drawings

1, 5: Voltage adder 2, 6: Level adjuster

3, 7: gain regulator 4: inverter

10: red signal pulse shaping section 20: green signal pulse shaping section

30: green signal pulse shaping unit 40, 50, 60: mixer

100: pulse generator circuit 200: pulse shaping circuit

300: mixed circuit

The present invention relates to a projection television, and more particularly, to a shading correction circuit of a projection television that prevents shading by mixing a correction pulse with a luminance signal.

As the technology for television develops, screens are being enlarged in order to provide a more realistic screen to users.

However, projection televisions have been developed due to certain limitations in enlarging the screens of current general televisions.

Projection televisions can be made larger in size by forming cathode ray tubes for red, green, and blue signals differently from conventional televisions, and allowing the optical signals of the cathode ray tubes to be projected on a screen at a predetermined position.

In the case of the general direct view cathode ray tube, the red, green, and blue beams emitted from the electron gun have a short distance from the shadow tube to the phosphor of the cathode ray tube, so the shading phenomenon is not a problem. In the case of the distance between the red, green, blue signal cathode ray tube and the screen is relatively far, according to the relative position of the screen of the red, green, blue signal cathode ray tube, the optical signal projected on the screen from the red, green, blue signal cathode ray tube The shading phenomenon in which the brightness of the screen becomes unclear due to the difference in energy between the left and right sides of the screen occurs.

That is, as shown in FIG. 1, the amount of energy of the red signal projected from the red cathode ray tube R to the screen S is closer to the red signal cathode ray tube R than the portion of the screen S, so that the red signal energy of the portion A Is more than the c part.

Similarly, the amount of energy of the green signal projected from the green signal cathode ray tube (G) to the screen (S) is relatively greater than that of b and b, and the energy of the green signal projected from the green signal cathode ray tube (B) to the screen (S). The quantity is greater in part c than in part a.

Therefore, the luminance signal formed by mixing the red, green, and blue signals does not form the original state, and the luminance is unclear due to the optical signal in which the energy amounts of the red, green, and blue signals are differently projected for each part of the screen S. There is a problem that a shading phenomenon for displaying an image having a state occurs.

SUMMARY OF THE INVENTION The present invention has been made to solve this problem, and an object of the present invention is to eliminate shading by synthesizing a predetermined pulse with a luminance signal so that the amount of energy projected from the red, green, and blue signal cathode ray tubes is the same over the entire screen. It is to provide a shading correction circuit of a projection television as much as possible.

A characteristic of the shading correction circuit of the projection television according to the present invention for achieving this object is to output horizontal parabolic pulses and horizontal sawtooth pulses having one horizontal line period in accordance with the horizontal blanking and vertical blanking signals HB and VB. A pulse generating circuit 100; A first shading correction pulse in which the horizontal sawtooth pulse pulse is level-adjusted and gain-adjusted, a second shading correction pulse in which the horizontal parabolic pulse is gain-adjusted, and the horizontal sawtooth wave pulse is inverted. A pulse shaping circuit 200 for outputting a third shading correction pulse after adjusting the level and gain; The mixing circuit 300 is connected to the pulse shaping circuit 200 and corrects a shading phenomenon as the first, second, and third shading correction pulses are mixed with the luminance signal and output.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of a shading correction circuit of a projection television according to the present invention, which comprises a pulse generating circuit 100, a pulse shaping circuit 200, and a mixing circuit 300. As shown in FIG.

Specifically, the pulse generation circuit 100 has a horizontal parabolic pulse P2 and a horizontal sawtooth wave pulse P1 corresponding to one horizontal line in accordance with the input horizontal blanking signal HB and the vertical blanking signal VB. )

The pulse shaping circuit 200 is configured to output a shading correction pulse by shaping a horizontal parabolic pulse P2 and a horizontal sawtooth pulse P1, which is a horizontal sawtooth wave of the terminal (a) of the pulse generating circuit 100. The green signal shading correction pulse is controlled by adjusting the gain of the red signal pulse shaping unit 10 that outputs the red signal shading correction pulse by shaping the pulse P1 and the horizontal parabolic pulse P2 of the terminal b of the pulse generating circuit 100. To the green signal pulse shaping section 30 that outputs the green signal pulse shaping section 20 and the horizontal sawtooth pulse P1 of the terminal (c) of the pulse generating circuit 100 to the green signal shading correction pulse. Is done.

At this time, a voltage adder 1 for applying a constant DC voltage of the red signal pulse shaping unit 10 to an input signal and outputting the same is connected to the terminal a of the pulse generating circuit 100.

In addition, the red signal pulse shaping unit 10 has a level adjuster 2 for bringing the output signal to a predetermined level by comparing the output signal with a reference voltage to the voltage adder 1 applying a constant voltage to the horizontal sawtooth pulse P1. It is connected, the output side of the level regulator 2 is connected to the gain controller (3) for controlling the output of the input signal.

In addition, the green signal pulse shaping unit 30 is connected to the terminal (c) of the pulse generating circuit 100 is connected to an inverter 4 for inverting and outputting the input horizontal sawtooth pulse P1, the inverter 4 On the output side of the same), the same voltage adder 5, level adjuster 6 and gain adjuster 7 are connected in series with the red signal pulse shaping section 10 in series.

The mixing circuit 300 is for correcting a shading phenomenon by mixing the shading correction pulse with the luminance signal Y, and the mixer 40 is connected to the red signal pulse shaping unit 10, and the mixer 50. Is connected to the green signal pulse shaping section 20, the mixer 60 is connected to the blue signal pulse shaping section (30).

In addition, the mixers 40, 50, and 60 are output of the red, green, and blue signal pulse shaping units 20, 30, and 40 and the luminance signal formed on the luminance signal input to each side. Outputs by mixing (Y).

In the shading correction circuit of the projection television according to the present invention, when the horizontal blanking signal HB and the vertical blanking signal VB are applied to the pulse generating circuit 100, the horizontal blanking signal HB and A horizontal sawtooth pulse P1 of FIG. 3 corresponding to the period 1H of one horizontal line of the video signal scanned on the screen using the vertical blanking signal VB is output through the terminals a and c. The horizontal parabolic pulse P2 is output through the terminal b.

The horizontal sawtooth pulse P1 of the terminal a is input to the voltage adder 1 of the red-signal pulse shaping section 10, and a predetermined DC voltage level preset in the voltage adder is applied. The output pulse of 1) is output as a sawtooth wave having a predetermined DC level L1 as in P3 of FIG.

Then, the pulse P3 is removed from the level adjuster 2 by a predetermined DC level and leveled with a sawtooth wave like the pulse P4, and the gain lost during this continuous process is compensated by the gain adjuster 7.

The gain-compensated horizontal sawtooth pulse P4 is applied to the mixer 40, and the luminance signal Y of one horizontal line such as P5 is applied to one side of the mixer 40, so that the mixer 40 gains. The compensated horizontal sawtooth pulse P4 and the waveform P5 which are luminance signals are mixed, and the luminance signal whose waveform is adjusted as in waveform P6 is output and applied to the red signal cathode ray tube R.

3 and 4a, the red signal luminance signal of the red signal cathode ray tube R corresponds to the c portion of the screen S, and the waveform P6 corresponds to the c portion of the screen S. The e part of) corresponds to the a part of the screen (S).

Accordingly, the portion of the screen S has a relatively long distance to the red signal cathode ray tube R, compared to the portion a, so that the energy projected from the red signal cathode ray tube R is relatively low.

However, if the modified luminance signal is increased by increasing the gain of the c portion of the screen S, which is far from the red signal cathode ray tube R, as in the waveform P6, the amount of energy of the red signal projected on the front surface of the screen S is reduced. The whole becomes the same.

That is, the energy amount of the red signal is the same as the a portion and the c portion of the screen (S).

In addition, the horizontal parabolic pulse P2 output from the terminal b of the pulse generating circuit 100 receives the waveform P5 from the second mixer 50 after the gain is adjusted in the green signal pulse shaping unit 20. The second mixer 50 applies the luminance signal Y having the waveform P7 to the green signal cathode ray tube G because it is mixed with the luminance signal Y having the same.

Therefore, the green signal cathode ray tube G is applied to the a and c portions of the screen S having a relatively far distance from the green signal cathode ray tube G, as shown in FIG. The green signal of is projected in the same amount of energy on the front of the screen (S).

In addition, since the horizontal sawtooth pulse P1 output from the terminal c of the pulse generating circuit 100 is inverted by the inverter 4 of the blue signal pulse shaping unit 30, the inverter 4 is The pulse P8 is output.

The pulse P8 is sawtooth pulses having a predetermined DC level by the voltage adder 5, and then adjusted to a predetermined level by the level adjuster 6 and outputted as a pulse P9.

In addition, since the pulse P1 is adjusted by the gain controller 7 and the waveform P5, which is the luminance signal, is mixed in the mixer 60, the mixer 60 transmits the modified luminance signal as shown in the waveform P10 to the green signal cathode ray tube ( Is applied to B).

Therefore, since the luminance signal of which the gain of the portion a is increased is applied to a portion of the screen S relatively far from the green signal cathode ray tube B, as shown in FIG. 4c, the green signal of the green signal cathode ray tube B is The same amount of energy is projected onto the front of the screen (S).

That is, in the present invention, the horizontal parabolic pulse and the horizontal sawtooth pulse output from the pulse generating circuit are optical signals due to the distance difference between the red, green, and acoustic cathode ray tubes (R), (G), (B) and the screen. Shading phenomenon can be prevented by shaping a pulse that can compensate for the amount of energy dissipation and mixing it with the luminance signal in the mixing circuit.

Claims (5)

A pulse generating circuit 100 for outputting horizontal parabolic pulses and horizontal sawtooth pulses having one horizontal line period in accordance with the horizontal blanking and vertical blanking signals HB and VB; A first shading correction pulse in which the horizontal sawtooth wave pulse is level-adjusted and gain-adjusted, a second shading correction pulse in which the horizontal parabolic pulse is gain-adjusted, and the horizontal sawtooth wave pulse is inverted. A pulse shaping circuit 200 for outputting a level-adjusted gain-adjusted third shading correction pulse after being adjusted; A projection circuit connected to the pulse shaping circuit 200 and configured to correct a shading phenomenon as the first, second, and third shading correction pulses are mixed with the luminance signal and outputted, respectively. TV shading correction circuit. The method of claim 1, wherein the pulse shaping circuit (200); A red signal pulse shaping unit (10) for outputting a first shading pulse of which the horizontal sawtooth pulse of the pulse generating circuit (100) is level-adjusted and gain-adjusted as a red signal shading correction pulse; A green signal pulse shaping unit 20 for outputting a second shading pulse whose gain of the horizontal parabolic pulse of the pulse generating circuit 100 is adjusted as a green signal shading correction pulse; Shading correction of the projection television, characterized in that it consists of a blue signal pulse shaping unit 30 for outputting the third shading pulse, the level control and gain-adjusted third shading pulse of the pulse generating circuit 100 as the green signal shading correction pulse. Circuit. 2. The mixing circuit (300) according to claim 1, wherein the mixing circuit (300) comprises: a first mixer (40) for mixing the red signal shading correction pulses output from the red signal pulse shaping unit (10) with a luminance signal and outputting the red signal as a red signal; A second mixer 50 for mixing the green signal shading correction pulse output from the signal pulse shaping unit 20 with the luminance signal and outputting the green signal as a green signal, and the blue signal shading correction output from the blue signal pulse shaping unit 30. And a third mixer (60) for mixing the pulses with the luminance signals and outputting them as blue signals. 3. The red-signal pulse shaping section (10) according to claim 2, wherein the red-signal pulse shaping section (10) includes a voltage adder (1) for applying a predetermined DC voltage to a horizontal sawtooth pulse of the pulse generating circuit (100). And a level regulator 2 for outputting the horizontal sawtooth pulse at a predetermined level by comparatively adjusting the output to a reference voltage, and a gain regulator 3 for adjusting and outputting a signal input from the level regulator 2. Shading correction circuit of a projection television. 3. The green signal pulse shaping unit 30 according to claim 2, wherein the blue signal pulse shaping section 30 is predetermined to an inverter 4 for inverting and outputting a horizontal sawtooth pulse of the pulse generating circuit 100, and an output sawtooth pulse of the inverter 4; A voltage adder 5 for adding a DC voltage, a level adjuster 6 for outputting a horizontal sawtooth pulse at a predetermined level by comparatively adjusting the output of the voltage adder 5 to a reference voltage, and the level adjuster ( 6) A shading correction circuit for a projection television, characterized in that it comprises a gain controller (7) for adjusting and outputting the gain of the signal output from the signal.

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