JPH01147968A - Dynamic focus circuit - Google Patents

Abstract

PURPOSE:To attain adjustment with high accuracy by switching the gain of the amplifier system for an H-parabolic signal and a V-parabolic signal composing a dynamic focus voltage so as to obtain an optimum dynamic focus voltage. CONSTITUTION:When an overscan mode signal is outputted from an over-scan/ underscan switching signal generation circuit 7, the H-parabolic gain control circuit 8 and the V-parabolic gain control circuit 9 control respectively the gain of an H-parabolic amplifier circuit 2 and a V-parabolic amplifier circuit 4 to output parabolic signals b, d. The parabolic signals b, d are summed by an adder circuit 5 and amplified up to a large amplitude by a dynamic focus waveform drive circuit 6 to be a parabolic waveform dynamic focus voltage (f). which is fed to a focus electrode.

Description

DETAILED DESCRIPTION OF THE INVENTION [Prior to Industrial Use] The present invention relates to a dynamic focus circuit for a cathode ray tube display device.

[Prior Art J] FIG. 4 is a block circuit diagram of a conventional dynamic focus circuit. In the figure, (1) is the horizontal parabola (hereinafter referred to as "■-parabola") signal generation F11 path, (2)
(3) is a vertical parabola (hereinafter referred to as "V-parabola")
) signal generation circuit, (4) is a V-parabolic amplifier circuit in which V-parabolic conversion is performed manually, and (5) is the output signal of 1■-parabolic amplifier circuit (2) and V-parabolic amplifier circuit (4). (6) is a dynamic focus waveform drive circuit which receives output No. 3 of the adder circuit (5) as an input.

Next, the operation will be explained.

II-The fifth output from the parabolic signal generation circuit (1)
The 11-parabolic signal a shown in FIG.
The V-parabolic signal C not shown in FIG. 5(c) outputted from the ■-parabolic signal generation circuit (3) is amplified by the ■-parabolic amplifier circuit (4), and the V-parabolic signal C shown in FIG. A V-parabolic signal d with a waveform is obtained.These two parabolic signals S and d are added by an adder circuit (5) to obtain a parabolic signal e with a waveform as shown in FIG. 5(e).
It is amplified to a large amplitude by the dynamic focus waveform drive circuit (6), becomes a dynamic focus voltage as shown in FIG.

The conventional dynamic focus circuit operates in the same manner during overscan and underscan, and the signal waveforms of each part are exactly the same as those described above.

Figure 6 shows the dimensions of the display surface of the cathode ray tube in the X and Y axes a
b and raster dimension at overscan ×b+
and raster dimensions azXt)z during underscanning
FIG.

In addition, FIG. 7 shows the dynamic focus voltage value during overscan of the conventional dynamic focus circuit,
This figure shows the relationship between the dynamic focus voltage value during underscanning and the optimal dynamic focus voltage value with respect to the position of the display surface on the X and Y axes, and shows the case where the optimal dynamic voltage value is set during overscanning. Figure (a) shows the direction of the X-axis (hydraulic deflection).
, the same figure (b) shows the voltage value in the Y-axis direction (Tr! direct deflection). In this case, during underscanning, a focus voltage higher than the optimal dynamic focus voltage value is applied in the peripheral area, and the display Blooming occurs around the surface.

[Problem that the invention seeks to solve]

Conventional dynamic focus circuits are configured to apply dynamic focus voltages of the same amplitude during overscan and underscan.
There is a problem in that optimum focus cannot be obtained both during overscan and underscan.

This invention was made to solve the problems mentioned in 1), and the purpose is to obtain a dynamic focus circuit that can output an optimal focus voltage value for the screen even during overscan and underscan. shall be.

[Means for Solving the Problems] The dynamic focus circuit according to the present invention manually controls the dynamic focus waveform drive circuit during overscan and underscan. The device is characterized in that it includes a means for switching the levels to a level at which an optimum dynamic voltage can be obtained.

[Function] The level and switching means for the 1-parabola signal and V-parabola signal in this invention changes the level of the H-parabola signal and V-parabola signal input to the dynamic focus waveform drive circuit from the time of overscan. The amplification factor of the amplification system is switched so that it is lower by a predetermined value during underscanning.

[Embodiments of the invention]

An embodiment of the present invention will be described below with reference to the drawings. 1st
In the figure, the same reference numerals as in Fig. 4 indicate the same components, and (7) indicates the overscan mode,
Overscan/underscan switching signal generation circuit that outputs underscan mode switching No. 43, (8
) switches the amplification factor of the parabolic amplifier circuit (2) in accordance with the manually inputted gain switching signal No. 43 [I-parabolic gain control circuit; This is a V-parabolic gain control circuit that switches the gain of the parabolic amplifier circuit (4).

Next, the operation of this embodiment will be explained starting from the operation during overscan.

When the overscan mode signal is output from the overscan/underscan switching signal generation circuit (7), the H-parabolic gain control circuit (8) and the V-parabolic gain control circuit (9) change to +1-
Parabolic amplifier circuit (2) and ■-parabolic amplifier circuit (
Figure 5 (b) by controlling the gains of 4).
and outputs the parabolic signal S, (1) shown in FIG. Focus waveform drive circuit (6)
The dynamic focus voltage is amplified to a large amplitude by , and is applied to the focus electrode as a dynamic focus voltage with a parabolic waveform as shown in FIG. 5(f).

The waveform of this dynamic focus voltage f is shown in Figure 3 (
As shown in a) and (b), to match the waveform of the optimal dynamic focus voltage value.

The gains of the 11-parabolic amplifier circuit (2) and the V-parabolic amplifier circuit (4) are controlled by the gain control circuit (8
), (set by 91.

Next, the operation during underscanning will be explained.

When the underscan mode signal is output from the overscan/underscan switching signal generation circuit (7), the H-parabola gain control circuit (8) and
- Parabolic gain control circuit (9) includes H-parabolic amplifier circuit <21 and V-parabolic amplifier circuit (4)
Figure 2 (a),
The parabola signals bu and du shown in and (bl are outputted. The parabola 4.\'Jbur du u are added by the adder circuit (5) to become the parabola signal cu shown in FIG. 6(c), and the dynamic focus The waveform drive circuit (6) amplifies it to a large amplitude, and the second
The dynamic focus voltage “U” with a waveform as shown in the figure (dl) is applied to the focus electrode.

The waveform of the dynamic focus voltage [U during underscanning is as shown in Figure 3 1c) and (d), the H-parabolic amplifier circuit (2) and -The gain of the parabolic amplifier circuit (4) is the gain control circuit + 8)
, (set by 91.

According to this embodiment, optimum dynamic focus voltage values can be obtained in both overscan mode and underscan mode.

In addition, in the embodiment described above, 11-parabolic amplifier circuit (2),
The configuration is such that the gain of the V-parabolic amplifier circuit (4) is switched, but two or more types of water 1
11-Parabola AGC
Even if the circuit is configured with a -parabolic AGC circuit, the same effects as in the embodiment L can be obtained.

Effects of the Invention As described above, according to the present invention, in the overscan mode and the underscan mode, the 11-parabolic and V
- Since the configuration is configured to obtain the optimum dynamic focus voltage by switching the gain of the parabolic signal amplification system, it is possible to obtain a dynamic focus circuit with highly accurate dynamic focus characteristics in both overscan mode and underscan mode. be.

[Brief explanation of the drawing]

Fig. 1 is a block circuit diagram of an embodiment of the present invention, Fig. 2 is a signal waveform diagram of each part in underscan mode of this embodiment, and Fig. 3 is a diagram of overscan and underscan of this embodiment. A diagram showing the dynamic focus voltage value and optimal dynamic voltage value at each deflection position, Figure 4 is a block circuit diagram of a conventional dynamic focus circuit, Figure 5 is a signal waveform diagram of each part of this conventional example, and Figure 6 is a cathode ray Size of display surface of tube a. xb. , the raster size a, Xb during overscan, and the raster size aiXbz during underscan. FIG. 3 is a diagram showing a relationship between a dynamic focus voltage value and an optimal dynamic focus voltage value. +1)...11-parabolic number generation circuit, (2).
・・II-parabolic amplifier circuit, (3)・-V-parabolic signal generation circuit, (4)・-V-parabolic amplifier circuit, (5
)...Adder, (6)...Dynamic focus waveform drive circuit, (7)...Overscan-underscan switching signal generation circuit, (8)・-1-1-
Parabolic gain control circuit, (91-...V-parabolic gain control circuit. In each figure, the same reference numerals indicate the same or equivalent parts.

Claims (1)

[Claims] (1) A dynamic focus circuit for a cathode ray tube display device that can switch the deflection operation between overscan mode and underscan mode, which is an amplification system for the horizontal parabolic signal and vertical parabolic signal that are the basis of the dynamic focus voltage waveform. 1. A dynamic focus circuit comprising means for switching gain between an overscan mode and an underscan mode, and configured to obtain an optimum dynamic focus voltage value in each mode.