KR910003475Y1 - Ttl video signal monitor test circuit - Google Patents

Abstract

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Description

Self-diagnosis circuit of TTL video signal monitor

1 is a circuit diagram of the present invention

* Explanation of symbols for main parts of the drawings

1: Video input signal part 2: OR circuit

3: Clamping Circuit 4: Buffer Circuit

IC ₁ , IC ₂ : Inverter circuit Q ₃ , Q ₅ : Contrast volume

R ₁ to R ₃ : Pull-up resistor R ₄ to R ₆ : Pull-down resistor

R ₇ to R ₁₀ : Resistor D ₁ to D ₃ : Diode

Vcc: Power R.G.B: Video Signal

I: Intensity signal

The present invention relates to a self-test circuit of a computer monitor, and more particularly to a circuit having a function capable of self-diagnosing the monitor regardless of the computer signal input.

In a conventional monitor, when there is no computer signal due to a pull-up resistor connected to an applied voltage during image signal input processing, the image signal input terminal becomes high and a contrast function and display are possible only at the time of signal input.

Therefore, if the computer signal is not connected, only the power indicator on the monitor is turned on and the display cannot be displayed on the CRT. Therefore, it is impossible to determine whether the monitor is operating or not. There is a problem in that thermal stability of all parameters of the constant cannot be obtained.

However, the present invention processes the conventional contrast function at the DC level, and the image signal RGB connects the pull-up and pull-down resistors to remove only the intensity signal I and the pull-down resistor. When there is no computer signal using the port, the input terminal of the intensity signal falls to the low level and the remaining image signal RGB input terminal is raised to the high level so that the self-diagnostic circuit of the monitor operates regardless of the computer signal. The purpose of the present invention is to compensate for all the problems.

Hereinafter, described in detail by the accompanying drawings as follows.

As shown in FIG. 1, pull-up resistors R ₁ (R ₂ ) (R ₃ ) and pull-down resistors R ₄ (R ₄ ) at respective stages of the image signal RGB of the image input signal unit I are shown in FIG. ₅ ) Connect the (R ₆ ) and the inverter circuit (IC ₁ ), respectively, and connect the pull-down resistor (R ₇ ) and the inverter circuit (IC ₂ ) to the intensity signal (I), while connecting the inverter circuit (IC ₁ ). The clamping circuit 3 and the buffer circuit 4 are connected to each other, and a NOT circuit Q _{5 to} which a blanking signal is input via the diodes D ₁ to D ₃ is connected to the inverter circuit IC ₂ . The OR circuit 2 is connected to the OR circuit 2 via a NOT circuit Q ₃ connected to Vcc. The output side of the OR circuit 2 is connected to the buffer circuit 4 through a transistor Q ₄ .

Referring to the operation and effects of the present invention made of the above configuration as follows.

In the absence of a computer signal, the transistor of the OR circuit (2) is made low after the input of the inverter circuit (IC ₁ ) is made low level due to the pull-down resistor (R ₇ ) connected to the intensity signal (I) terminal of the 16 color input circuit. The emitter voltage of the OR circuit 2 is varied by the DC voltage difference between (Q ₁ ) and (Q ₂ ).

At this time, the blanking signal in which the horizontal pulse applied to the base of the NOT circuit Q ₅ and the vertical output voltage pulse are combined is provided to each end of the buffer circuit 4 through the diodes D ₁ (D ₂ ) (D ₃ ). The blanking signal applied to the base of each transistor Q ₆ to Q ₈ of the buffer circuit 4 is clamped by the clamping circuit 3 so that the blanking signal level is the transistor Q of the OR circuit 2. ₁ ) The size of the glass is adjusted by the contrast volume VR connected to the brightness of the screen. On the other hand, when the intensity signal I is not input, the division resistor R ₇ (R ₈ connected to the NOT circuit Q ₃ ) becomes a low level at the point A and a high level at the point B of the inverter circuit IC ₂ . When a small amount of AC is applied to the base of the transistor Q ₂ , the OR circuit 2 is operated, and through the resistor R ₉ due to the voltage difference between the _two transistors Q ₁ (Q ₂ ). (Q ₄ ) is operated so that the magnitude of the pulse is controlled by the contrast volume VR connected to the power supply (Vcc) stage to have a self-diagnostic function.

If a pull-up resistor is connected to the intensity signal I, the contrast function cannot be achieved and thus the function of the self-diagnosis circuit cannot be achieved. The reason is the high level at point A and the low level at point B of the inverter circuit IC ₂ , and the NOT circuit Q ₃ becomes high level (because Q ₃ is off). Transistors Q ₁ and Q ₂ are both high and the emitter voltage cannot be variable, and the clamping circuit 3 is turned “off” so that the blanking signal once adjusted is applied as it is. Because you can't achieve it.

Increasing the resistance R ₁₀ connected to the NOT circuit Q ₅ decreases the amplitude of the blanking signal pulse, and decreases the amplitude.

As described above, the image signal RGB is connected to the pull-up resistor R ₁ (R ₂ ) (R ₃ ) and the pull-down resistor R ₄ (R ₅ ) (R ₆ ) and the intensity signal Only (I) uses the pull-down resistor (R ₇ ) to perform contrast function according to the voltage variation of the OR circuit (2), and performs self-diagnosis regardless of the computer signal input. In addition to being able to detect whether or not, it is a convenient and useful design to obtain the thermal stability of all parameters of the image circuit constant.

Claims (1)

In the conventional monitor self-diagnosis circuit, pull-up resistors R ₁ (R ₂ ) (R ₃ ) and pull-down resistors R ₄ at each stage of the image signal RGB of the input signal section I. While connecting (R ₅ ) and (R ₆ ) respectively, only pull-down resistor (R ₇ ) is connected to the intensity signal (I) stage, and OR circuit is connected to the power supply (Vcc) stage and NOT circuit (Q ₃ ). A self-diagnosis circuit of a TTL video signal monitor, characterized in that the monitor self-diagnosis circuit is performed regardless of the presence or absence of a computer signal according to the change of voltage generated by the voltage difference by the operation of (2).