KR0179978B1 - Vertical convergence compensation circuit for projection tv - Google Patents

Abstract

The present invention relates to a vertical convergence correction circuit of a projection television, but the conventional convergence correction uses a separate convergence correction circuit but has a problem of difficulty in convergence correction and generation of heat. .

Therefore, in the present invention, the red, green, and blue deflection coils of the projection television are separated, and a vertical deflection waveform is applied to each deflection coil through a vertical amplifier provided separately, and the keystone correction waveform is applied to the red deflection coil. By adding and applying, main deflection and convergence correction are performed at the same time so that convergence correction is easy and there is no heat dissipation problem.

Description

Projection Television's Vertical Convergence Correction Circuit

1 is a conventional vertical deflection circuit.

2 (a) is an explanatory diagram of the CRT position of the projection television.

(b) is a figure on a screen before convergence correction.

3 is a circuit diagram of the present invention.

(A) of FIG. 4 is a keystone correction waveform diagram.

(b) is a red keystone correction waveform diagram.

(c) is a blue keystone correction waveform diagram.

5 is a shape on the screen according to the present invention.

6 is a detailed circuit diagram of the keystone waveform generation and correction unit of the present invention.

* Explanation of symbols for main parts of the drawings

4: screen 5: deflection IC

6: amplifier 7, 8, 9: deflection coil

10: keystone waveform generation and correction unit 11, 17: amplifier

12, 13 amplification part 14: adder

15: level limit VR ₁ -VR ₃ : variable resistance

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vertical convergence correction circuit of a projection television that adds a keystone correction waveform to a main deflection circuit to correct vertical convergence.

Projection televisions are provided with three CRTs for displaying the same image as blue, green, and red images, and then enlarges and displays the image displayed on each CRT onto one screen.

That is, as shown in FIG. 2A, three CRTs (1), (2), and (3) which display images in red, green, and blue are arranged in a line, and the CRTs (1), (2), (3) ) Is projected on the screen (4).

Therefore, the projection television can provide a much larger screen than the CRT television, but the structure is complicated, especially the convergence adjustment is difficult.

In other words, the three CRTs (1), (2), (3) are arranged in a row, and then the images of the CRTs (1), (2), (3) are placed in the center due to the mechanical arrangement structure in which the screen 4 is formed. The green image by the green CRT 2 has no problem as shown in (b) of FIG. 2 when it is displayed on the screen 4, but the red and blue CRTs (1) arranged on the side of the green CRT (2). When the red and blue images by (3) are displayed on the screen (4), distortion occurs as one side is distorted as shown in (b) of FIG.

If the projection TV does not correct the distortion on the red and blue screens, the image formed on the screen 4 may not be clear. Therefore, in order to solve this problem, a conventional convergence correction circuit is provided. Convergence correction was performed in the voltage correction circuit.

However, in the separate convergence correction circuit, the convergence correction is performed by using the convergence correction amplifier. Accordingly, excessive convergence correction is performed, resulting in problems such as saturation distortion and high heat generation.

In this way, the projection television is provided with a separate convergence correction circuit for the convergence correction, while having a deflection circuit as shown in FIG. 1 for the deflection operation of the image.

Biasing circuit of the projection television deflection IC (5) when the output of the deflection waveform vertical amplifier 6 that after a load resistance (R ₁₎ red, green, and blue deflection coil 7 is connected in series to the amplifying it from (8) ( 9), basic deflection is performed.

In this case, resistor R ₂ is used for DC feedback, resistor R ₃ and capacitor C ₂ are used for AC feedback, and resistors R ₁ to R ₆ are used for damping.

That is, in the conventional deflection circuit, the deflection coils 7, 8, and 9 are connected in series, and the deflection waveforms having the same current value of the same waveform are uniformly applied to the deflection coils 7, 8, and 9 described above. By doing so, only basic deflection operation is performed and convergence correction generated according to the mechanical position of the CRT (1) (2) (3) cannot be performed as described above.

Therefore, the convergence correction of the projection television is made entirely by a separate convergence correction circuit, and the convergence correction circuit is overhauled by using a high gain amplifier, which is satuated or crushed at the end of the screen. The problem is that the heat sink must be designed quite large to prevent the high heat generated by the high gain of the amplifier.

In the present invention, the vertical deflection is performed by adding the keystone correction waveform to the vertical deflection waveform of the projection television, so that the convergence correction is performed together with the vertical deflection.

As described above, the present invention, which aims to achieve convergence correction with vertical deflection in a vertical deflection circuit of a projection television, separately installs red, green, and blue deflection coils, and then a vertical deflection waveform is applied to each vertical amplifier. After the amplification, it is applied to each deflection coil, and the red and blue deflection coils are applied by adding the keystone correction waveform output from the keystone waveform generation and correction unit together with the vertical waveform.

According to the present invention, red, green, and blue deflection coils are separated from each other, and each deflection coil is applied with a vertical deflection waveform through a vertical amplifier separately provided. The red deflection coil is added with a keystone correction waveform and a vertical correction waveform. By applying red and blue vertical deflection and convergence correction are performed at the same time.

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

3 is an implementation circuit diagram of the present invention, wherein the deflection waveform of the deflection IC 5 is applied to the red deflection oil 7 through the vertical amplifier 6 while generating a keystone waveform by inputting the vertical and horizontal pulses. The keystone waveform generator and the keystone correction waveform of the correction unit 10 are applied to the red deflection coil 7 through the amplifier 11.

The above configuration shows the configuration of the vertical deflection waveform and the keystone correction waveform applied to the red deflection coil 7. The vertical deflection waveform is applied to the blue deflection coil (not shown) through the same vertical amplifier while the keystone is applied. The keystone correction waveform of the waveform generation and correction unit is also applied through a separate amplifier.

However, only the vertical deflection waveform is applied through the separate amplifier without applying the keystone correction waveform to the green deflection coil.

That is, the present invention separates the red, green, and blue deflection coils of the conventional projection television so that the vertical deflection waveform is applied to the red, green, and blue deflection coils described above through different vertical amplifiers, but only the red, blue deflection coils are keystones. The keystone correction waveform generated by the waveform generation and correction unit 10 is configured to be applied through different vertical amplifiers.

The keystone waveform generation and correction unit 10 generates a keystone correction waveform as shown in (a) of FIG. 4 and adjusts it to apply a keystone correction waveform as shown in (b) of FIG. 4 to the red deflection coil, and to the blue deflection coil. A keystone correction waveform as shown in FIG. 4C is applied.

The keystone waveform generation and correction unit 10 is shown in a detailed circuit diagram in FIG.

The keystone waveform generation and correction unit 10 inputs a vertical pulse and a horizontal pulse and finally applies a keystone correction waveform to each of the red and blue deflection coils as shown in FIG. 4 (b) and (c). The amplification unit 12 composed of the transistor Q1 and its peripheral elements is amplified, and the horizontal pulse is inverted and non-inverted amplified by the amplifier 13 composed of the transistor Q4 and its peripheral elements.

The vertical and horizontal pulses amplified by the amplifiers 12 and 13 are added to the keystone correction waveform by the diodes D1-D4 of the adder 14, and the balance of the added keystone correction waveform is adjusted. Is performed by a change in the resistance value of the variable resistor VR ₁ .

The keystone correction waveform of the adder 14 is level-limited by the level limiter 15 consisting of the transistor Q2 and the zener diode D5 and then applied to the amplifier 16 consisting of the transistor Q3 and its peripheral elements. .

The keystone correction waveforms amplified by the amplifying unit 16 are applied to the variable resistors VR ₂ and VR ₃ , respectively, and the red and blue deflections are applied through the respective amplifiers 11 and 17 after the keystone correction amount is finally adjusted. In addition to the vertical deflection waveform is applied to the coil.

The keystone waveform generation and correction unit 10 outputs the keystone correction waveform as shown in FIG. 4B through the amplifier 11 based on the above-described configuration, and through the amplifier 17, FIG. Outputs a keystone correction waveform such as

The keystone correction waveform output from the amplifier 11 is applied to the red deflection coil 7 as shown in FIG. 3 and the keystone correction waveform output from the amplifier 17 is provided separately from the red deflection coil 7. It is applied to the blue deflection coil.

At this time, since the deflection waveform output from the deflection IC 5 is applied to the red deflection coil 7 through the amplifier 6, the deflection waveform and the keystone correction waveform are added to the red deflection coil 7.

Therefore, the red deflection coil 7 performs red deflection and at the same time performs keystone correction of the red image.

The blue deflection coil is applied with a deflection waveform through an amplifier installed separately from the amplifier 6, and the keystone correction waveform is applied through the amplifier 17 to perform blue deflection in the blue deflection coil and simultaneously correct keystone correction of the blue image. Will be done.

However, the green image does not need keystone correction, so only the deflection waveform is applied to the green deflection coil through a separate amplifier.

As described above, as shown in FIG. 1, a single vertical amplifier 6 is used to perform a deflection operation of the red, green, and blue deflection coils 7, 8, and 9 connected in series to separate the vertical deflection circuit. Could not apply the keystone correction waveform.

Therefore, the convergence correction is over-compensated by a separate convergence correction amplifier circuit, which causes problems such as crushed or saturated ends, and heat is generated due to the high gain of the amplifier. There is a problem with installing.

In the present invention, as shown in FIG. 3, a deflection waveform is applied to each of the red, green, and blue deflection coils through separate vertical amplifiers, and then a separate keystone correction waveform is added to the deflection waveform only to the red and blue deflection coils. In addition, convergence correction can be performed in the main deflection circuit together with the main deflection.

When convergence correction is performed together with the deflection operation, red, green, and blue images projected on the screen are projected as a complete image without distortion as shown in FIG.

In the present invention, since three vertical amplifiers are used for each deflection coil, the heat sink may be reduced. In particular, the convergence adjustment is made in the main deflection circuit, so the reliability of the adjustment of the convergence is high and the convergence is changed during use. There will be no.

As described above, the present invention allows the convergence adjustment to be made in the main deflection circuit, which greatly reduces the adjustment time due to the convergence adjustment, while at least the size of the heat sink is reduced and does not require a heat dissipation fan. It can greatly reduce the temperature.

Claims (2)

In the convergence correction circuit of a projection television, red, green, and blue deflection coils are separately installed and the vertical deflection waveforms of the deflection IC are amplified by the vertical amplifiers installed for each deflection coil and applied to each deflection coil. However, the vertical deflection waveform is directly applied to the green deflection coil, and the red and blue deflection coil is applied to the vertical deflection waveform together with the keystone waveform generation and output keystone correction waveforms output from the correction unit. Version correction circuit. 2. The apparatus of claim 1, wherein the keystone waveform generating and correcting unit comprises: an amplifying unit for amplifying the vertical pulse and the horizontal pulse input, an adder for adding the vertical and horizontal pulses output from each amplifying unit and adjusting the keystone balance; A level limiter for level-limiting the keystone correction waveform of the adder, a variable resistor for adjusting the keystone correction amount of the level-limited keystone correction waveform, and an amplifier for amplifying the keystone correction waveform and applying it to each of the red and blue deflection coils. Vertical convergence correction circuit in projection television.