JPH0371784A - Video output circuit - Google Patents

Abstract

PURPOSE:To prevent deterioration in the picture quality by providing a clip circuit clipped when a voltage of a video signal inputted to a video amplifier transistor(TR) rises up to a prescribed voltage or over. CONSTITUTION:When a beam current with respect to a cathode voltage of a cathode ray tube 1 is decreased, the amplitude and a DC level of a video signal outputted from an automatic white balance adjustment circuit 5 are increased, the collector voltage of the video amplifier TR is decreased. When the beam current with respect to the cathode voltage of the cathode ray tube 1 is further decreased and the amplitude and the DC level of the video signal outputted from the automatic white balance adjustment circuit 5 are increased, Zener diodes 21-23 are conductive and the base of video amplifier TRs 11-13 is clipped so as not to be increased over a prescribed voltage. Since the collector voltage of the video amplifier TRs 11-13 is not decreased below a prescribed voltage, the saturation is prevented and the picture quality deterioration is prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a video output circuit in a television receiver or the like, and particularly to prevention of saturation of a video output circuit that drives a cathode of a cathode ray tube.

[Conventional technology]

It is known that when a television receiver is used for a long period of time, the electron emission from the cathode ray tube deteriorates.

In television receivers, which have a circuit that detects the red, green, and blue beam currents on the cathode ray tube cathode and automatically adjusts the white balance by controlling the voltages of the red, green, and blue cathodes, cathode emission deterioration occurs. In this case, the beam current decreases, so the cathode amplitude is increased to keep the beam current constant.

Therefore, as cathode emission deterioration progresses, the collector voltage of the video output transistor drops below the base voltage, resulting in a saturated state.

When saturation occurs, the storage time of the transistor becomes longer and the image quality deteriorates significantly.

In addition, when the power switch is turned on, the cathode ray tube heater is ignited and the beam current decreases during the transient period until it is sufficiently warmed up, so the cathode amplitude increases and saturates, based on the same principle as cathode emission deterioration. be.

In the conventional device, as shown in Japanese Patent Application No. 1988-199194, a clip circuit is added to the collector of the video output transistor to prevent the collector voltage from dropping to the saturation region.

[Problem to be solved by the invention]

The above conventional technology uses the junction capacitance of the clip diode,
There is a risk that the high frequency components of the video signal will decrease and the image quality will deteriorate.

SUMMARY OF THE INVENTION An object of the present invention is to provide a video output circuit that can prevent image quality from deteriorating due to a decrease in high frequency components of a video signal, and can also prevent the collector voltage from dropping to the saturation region. .

[Means to solve the problem]

(1) The above object is achieved by providing means for clipping the voltages of the red, green, and blue primary color video signals input to the video output circuit so that they do not exceed a certain voltage.

(2) The above purpose also includes the red input to the video output circuit.
Detects the voltage of green and blue primary color video signals.

This is achieved by providing means for superimposing this voltage waveform on the contrast control f# voltage/color saturation control voltage with a polarity that increases the cathode ray tube cathode voltage.

(3) Furthermore, the above purpose is to
This is achieved by detecting the voltage of the green and blue primary color video signals and superimposing this voltage waveform on the bias voltage connected to the emitter resistor of the video output circuit with a polarity that increases the cathode ray tube cathode voltage. Ru.

[Effect]

(1) When the video signal input to the video output circuit increases, the clip circuit operates to prevent the voltage from rising above a certain level. Thereby, the video output circuit can be prevented from reaching the saturation region.

(2) Detects the video signal input to the video output circuit, and when this detected voltage exceeds a certain voltage, it operates to suppress color saturation and contrast, and the voltage of the video signal input to the video output circuit exceeds a certain voltage. Make sure that it does not rise to the top. Thereby, the video output circuit can be prevented from reaching the saturation region.

(3) Detects the video signal input to the video output circuit, and when this detected voltage exceeds a certain voltage, the bias voltage connected to the emitter resistor of the video output circuit increases, and the current flowing through the emitter resistor decreases. works. Thereby, the video output circuit can be prevented from reaching the saturation region.

〔Example〕

A first embodiment of the present invention will be described below with reference to FIG.

In FIG. 1, 2 to 4 are circuits for detecting beam currents flowing to the red, green, and blue cathodes, and 5 is a circuit for detecting the amplitude and amplitude of the red, green, and blue primary color video signals input to the bases of the video amplification transistors 11 to 13. This is an automatic white balance adjustment circuit that controls the DC level and the beam current flowing to each cathode to obtain a constant white balance.

The video signal output from the automatic mortar balance gR adjustment circuit 5 is amplified by video amplification transistors 11 to 13, passes through beam current detection circuits 2 to 4, and is input to the cathode of the cathode ray tube 1. When the beam current with respect to the cathode voltage of the cathode ray tube 1 decreases, the amplitude and DC level of the video signal output from the automatic white balance adjustment circuit 5 are increased, so that the collector voltage of the video amplification transistor decreases. When the beam current relative to the cathode voltage of the cathode ray tube 1 further decreases and the amplitude and DC level of the video signal output from the automatic white balance adjustment circuit 5 increases (the voltage becomes higher), the Zener diodes 21 to 23 become conductive. Since the collector voltage of the chrysalis 13 does not fall below a certain voltage just as the bases of the video amplification transistors 11 to 13 do not rise above a certain voltage, saturation can be prevented.

As a method of clipping the voltage of the video signal input to the video amplification transistors 11 to 13 so that it does not rise above a certain voltage, as shown in FIG.
A method using the voltage source 42 is also conceivable.

Next, a second embodiment will be explained using FIG. 3.

In FIG. 3, 2 to 4 are circuits for detecting beam currents flowing to red, green, and blue cathodes, and 5 is a red circuit that is input to the bases of video amplification transistors 11 to 13.

An automatic white balance adjustment circuit for controlling the amplitude and DC level of the green and blue primary color video signals and controlling the beam current flowing to each cathode to obtain a constant white balance; 6 is a color saturation adjustment circuit; 7 is a color saturation adjustment circuit; In the contrast adjustment circuit, 81 is a color saturation variable resistor VR182 is a contrast variable resistor VR.

The red, green, and blue primary color video signals output from the automatic white balance adjustment circuit 5 are input to the bases of the video amplification transistors 11 to 13, and the highest color video signals among the three color video signals are inputted to the bases of the video amplification transistors 11 to 13 by the diodes 34 to 36. Detect voltage. This voltage is shifted to a DC voltage by the Zener diode 24 and inputted to the base of the transistor 14.15. When the voltage of the video signal output from the automatic white balance adjustment circuit 5 increases and the detection voltage exceeds a certain voltage, the transistors 14 and 15 turn on, and the color saturation adjustment circuit 6
It also operates to lower the color saturation and contrast control voltages input to the contrast adjustment circuit 7. This reduces the color saturation gain and contrast gain, and suppresses the voltage rise of the video signal input to the bases of the video signal transistors 11 to 13.

It is possible to prevent the collector voltages of the video amplifying transistors 11 to 13 from dropping to the saturation region.

The voltage at which the color saturation and contrast control voltages start to decrease can be set by changing the Zener voltage of the Zener diode 24, but in some cases, instead of the Zener diode 24, a voltage source can be connected between the resistor 66, 67 and ground. Naturally, there are other ways to add it. Also, for the sake of explanation,
Although the gain reduction operation was performed for both the color saturation and the contrast, it can be seen that depending on the case, the gain reduction operation for either one may be sufficient.

Next, a third embodiment will be described using FIGS. 4 and 5.

In FIG. 4, 2 to 4 are circuits for detecting beam currents flowing to the red, green, and blue cathodes, and 5 is a circuit for detecting the amplitude and amplitude of the red, green, and blue primary color video signals input to the bases of the video amplification transistors 11 to 13. This is an automatic white balance adjustment circuit that controls the DC level and the beam current flowing to each cathode to obtain a constant white balance. A bias circuit composed of transistors 18, 19, resistor 73, and voltage g43 is connected to resistors 54-56 connected to video amplification transistors 11-13.

The red, green, and blue primary color video signals output from the automatic white balance adjustment circuit 5 are input to the bases of the video amplification transistors 11-13, and the highest color video signals among the three color video signals are inputted to the bases of the video amplification transistors 11-13. Detect voltage. The detected voltage waveform is shown in Figure 5 (■).

This voltage is shifted as a DC voltage by the Zener diode 24, inverted by the transistor 16, and inputted to the base of the transistor 17.

Normally, when the detection voltage is low, the base voltage of the transistor 17 is high and the current flowing from the collector of the transistor 17 to the resistor 73 is small, so the transistor 18 is turned on, and the base of the transistor 19 is turned on.
The voltage is 0.7V lower than the voltage of the voltage source 43.

When the voltage input to the bases of the transistors 11 to 13 increases and the detected voltage becomes higher, the base voltage of the transistor 17 decreases, and the current flowing from the collector of the transistor 17 to the resistor 73 increases. When this current exceeds a certain value, the transistor 18 enters a cut-off state, and the voltage at the base of the transistor 19 increases.

Therefore, by modulating the base voltage of the transistor 19 as shown in FIG. 5, the emitter voltage is also modulated.
Since the voltage difference across the resistors 54 to 56 decreases and the collector current of the video amplification transistors 11 to 13 decreases, it is possible to prevent the collector voltage from decreasing to the saturation region, as shown in FIG.

As a result, even if the video signal output from the automatic white balance adjustment circuit 5 increases when the emission of the cathode ray tube cathode deteriorates, saturation can be prevented by increasing the bias voltage.

In this circuit, the automatic white balance adjustment circuit 5 detects the voltage of the output video signal and increases the common bias voltage for the three colors, so there is little change in white balance and the screen display signal is not superimposed on the video signal. The same anti-saturation effect can be achieved even when

The voltage that starts increasing the bias voltage can be set by changing the Zener voltage of the Zener diode 24. Also, instead of the Zener diode 24, it is natural to think of ways to add a voltage source between the resistor 69 connected to the emitter of the transistor 16 and the ground, or to change the voltage of the power supply connected to the resistors 70 and 72. It will be done.

Furthermore, it is naturally possible to realize one or more of the principles and configurations shown above by incorporating them into an IC (integrated circuit).

〔Effect of the invention〕

According to the present invention, even when the emission of the cathode ray tube cathode deteriorates and the video signal input to the video amplification transistor increases, the video amplification transistor does not reach the saturation region, so a good image can be obtained.

Furthermore, even when the beam current is decreasing after the power is turned on until the cathode ray tube heater is sufficiently warmed up, the image amplifying transistor does not reach the saturation region, so a good image can be obtained.

[Brief explanation of drawings]

1 to 4 are circuit diagrams each showing an embodiment of the present invention, and FIG. 5 is a voltage waveform diagram of each part in the circuit of FIG. 4,
It is. DESCRIPTION OF SYMBOLS 1... Braun tube, 2-4... Beam current detection circuit, 5... Automatic white balance adjustment circuit, 6... Color saturation adjustment circuit, 7... Contrast adjustment circuit, ll-19
... Transistor, 21-24... Zener diode, 31-36... Diode, 41-43... Voltage source, 5 - 73... Resistor, 81-82... Variable resistor.

Claims (1)

[Scope of Claims] 1. In a video output circuit that drives cathode electrodes corresponding to red, green, and blue arranged on a cathode ray tube with video output via a video amplification transistor, a video signal input to the video amplification transistor. 1. A video output circuit comprising a clip circuit that detects and clips when the voltage of the video amplifying transistor is about to rise above a certain voltage, thereby preventing the collector voltage of the video amplifying transistor from reaching a saturation region. 2. In a video output circuit that drives cathode electrodes corresponding to red, green, and blue arranged on a cathode ray tube with video output via a video amplification transistor, detecting the voltage of a video signal input to the video amplification transistor; This detection voltage is set to a control voltage of a color saturation adjustment circuit that adjusts the color saturation of the video signal, and a control voltage of a contrast adjustment circuit that adjusts the contrast of the video signal. 2. A video output circuit comprising: means for superimposing video signals on and off, thereby suppressing the voltage of a video signal input to the video amplification transistor to prevent the collector voltage of the transistor from reaching a saturation region. 3. In a video output circuit that drives cathode electrodes corresponding to red, green, and blue arranged on a cathode ray tube with video output via a video amplification transistor, detecting the voltage of a video signal input to the video amplification transistor; This detected voltage is input to a bias circuit connected to the emitter resistor of the video amplification transistor,
A video output device comprising bias voltage control means for controlling the bias voltage with a polarity such that the current flowing through the emitter resistor decreases, thereby preventing the collector voltage of the video amplification transistor from reaching a saturation region. circuit.