KR880001229B1 - Monitor circuit - Google Patents

Abstract

The circuit controlling the brightness of a monitor under 50% of maximum level and diagnosing a monitor malfunction includes a first switching cirtcuit (2), a second switching circuit (2), a switch (SW1) for self-diagnosing the monitor malfunction, and a volume (VR) for adjusting the brightness. Transistors (TR2, TR3) in the first switching circuit are turned on to control the transistor (TR6) when a beam current flows at more than a reference levle. When the brightness of the screen is over 50% of maximum level, transistors (TR4, TR5) are turned on to open an AND gate (AD2).

Description

DIM and special diagnostic raster circuits for high resolution monitors

1 is a circuit diagram showing an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1, 2: first and second switching circuit 3: interface

4 horizontal and vertical oscillation circuit 5, 6, 7 R. G. B image amplification circuit

8: CRT, FBT: Flyback Transformer VR: Variable Resistance

ZD ₁ to ZD ₃ : Zener diodes ND ₁ to ND ₅ : NAND gate

AD ₁ , AD ₂ : AND gate DR: Raster signal

IN: Input terminal SW ₁ : Special diagnostic switch

The present invention relates to a dim (DIM) and a special diagnostic raster circuit of a high resolution monitor. In particular, the brightness level of an image output signal according to an increase in beam current can be adjusted to a constant brightness level (when the maximum level is 50% or more). In addition, the present invention relates to a dim circuit and a special diagnostic raster circuit which can diagnose a failure of the monitor itself when connected to another personal computer system or when connected to another system.

In general, personal computers are connected with input and output devices that enable various inputs and outputs simultaneously. Among them, CRT displays, which are frequently used as output devices, are used to display characters or figures on the screen, such as TV receivers. This can be divided into character display and figure display. Here, the operation principle of the text display is that the characters are displayed by generating a bright dot constituting the text while moving the electron beam of the CRT display in the horizontal direction (raster scan method). In this case, if you connect the high resolution monitor CRT to a personal computer and use it for a long time at the level of 50% or more of the super high level without adjusting the screen brightness level of the high resolution monitor yourself, This was a problem, and there was a drawback that a means for detecting a failure of the monitor itself or a failure in connection with other systems was not installed in the high resolution monitor.

Accordingly, the present invention has been invented in view of the above circumstances, and the second switching circuit is provided with a dim raster signal supplied after adjusting a beam current increased from a certain reference level to a constant image signal with a first switching circuit. If the maximum brightness level of the screen is 50% or more with the logic circuit, it automatically reduces to 50% or less, reducing eye fatigue even when using the high-resolution monitor for a long time, as well as diagnosing the monitor itself or other system. Its purpose is to provide dim and special diagnostic raster circuits for high-resolution monitors that can be checked at any time, even when the monitor itself is broken.

Hereinafter, the configuration, operation, and effect of the present invention will be described in detail with reference to the accompanying drawings.

According to the present invention, a primary side of a flyback transformer (FBT) is sequentially connected to an input terminal IN to which a beam current is supplied through a transistor TR ₁ , a diode D ₁ , and a capacitor C ₁ , and the flyback On the secondary side of the transponder (FBT), the auto luminance limiting terminal (ABL) is connected through a parallel diode (D ₂ ) and a capacitor (C ₂ ), and the capacitor (C ₃ ) (C ₄ ) and the resistance ( A first switching circuit 1 consisting of R ₁ to R ₇ , a diode D ₃ , a zener diode ZD ₁ , and a transistor TR ₂ , TR ₃ is connected, and the first switching circuit 1 NAND gates ND ₁ to ND ₃ and RGB image amplification circuits 5, 6, and 7 are connected to transistors TR ₆ , respectively, and diodes D ₄ and resistors R ₈ to R are connected to each other. _10), consists of a variable resistor (VR) and a transistor (TR ₄₎ (TR ₅₎ of a brightness control, and the second switching circuit (2) which dimra raster signal is supplied to connection, the second switching circuit (2) special diagnostic switch (SW ₁₎ As the connected input-output terminal of the AND gate (AD ₁₎ is an input terminal connected to each of the (AD ₂₎ a NAND gate (ND ₁ ~ ND ₅₎ as an intermediate, the NAND gate (ND ₁ ~ ND _5), the interface 3 Are connected to each other so that the horizontal and vertical oscillation circuit 4 and the RGB image amplification circuits 5, 6 and 7 are respectively connected.

Unexplained symbols VS and HS are horizontal and vertical synchronization signals, R is a red signal, G is a green signal, B is a blue signal, and 8 is a CRT.

FIG. 1 is a circuit diagram of the present invention configured as described above. When a high resolution monitor is connected to a main body of a personal computer and a constant beam current is applied to the base of the transistor TR ₁ through the input terminal IN, FIG. As the transistor TR ₁ is turned on / off, the B ⁺ voltage is supplied to the capacitor C ₁ , the diode D ₁ , and the transistor TR ₁ through the primary side of the flyback transformer FBT and grounded. At this time, since the current is induced and sequentially supplied to the secondary side of the resistor R ₂ (R ₁ ) and the flyback transformer FBT, the current flows into the automatic luminance limit terminal ABL. In this way, the transistor TR ₂ in the first switching circuit 1 is turned on as the transistor TR ₁ connected to the primary of the drawing flyback transformer FBT is turned on so that the beam current increases above a certain reference level. The transistor's base potential is lowered to cause the transistor TR ₂ to be turned on, so that the voltage is sequentially supplied to the resistor R ₅ through the zener diode ZD ₁ , the resistor R ₃ , and the transistor TR ₂ . so that the base potential of the transistor (TR ₃₎ is to increase the transistor (TR ₃₎ is a turn-on state.

Thus transistor (TR ₃₎ low FIG base potential of the transistor (TR ₆₎ by being presented collector potential of the reduction of the transistor the transistor (TR ₆₎ of the turn-on status bar, from which is in the turn-on state (TR ₆₎ is a NAND gate (ND ₁ ~ ND ₃ ) to control the image output level supplied to the RGB image amplification circuit (5) (6) (7), so that the stable screen can be obtained in the high resolution monitor which is the CRT (8). The screen brightness can also be adjusted by a variable resistor (VR) to adjust the brightness. Therefore, it is possible not only to control the increase in the beam current supplied to the input terminal IN, but also to allow a constant image signal to flow to the CRT 8 through the RGB image amplification circuits 5, 6, and 7. You will get

On the other hand, when the positive TTL level signal (here, high state is 2.6-2.5V and low state is 0-0.5V) is supplied as a dim raster signal DR through a terminal such as a personal computer. The dim raster DR is applied to the base of the transistor TR ₅ via the clamp diode D ₄ and the resistor R _{8 in} the second switching circuit 2 to prevent ringing and the like. ₅₎ it attains a turned-oN state, from which the resistance (R _9), a V _CC voltage is supplied to the collector of the base and the transistor (TR ₅₎ of the transistor (TR ₄₎ through it lower the collector potential of the transistor (TR ₅₎ As a result, the transistor TR ₄ is turned on. Therefore, if the brightness of the screen other than the high resolution monitor is assumed to be at least 50% (except that the special diagnostic switch SW ₁ is set to ON), the screen brightness of the CRT (8) can be reduced by up to 50%. On the contrary, when the screen brightness of the CRT 8 is at a level of 50% or less due to the variable resistance VR of the erection adjustment, the dim raster signal DR is applied to the transistor TR ₅ of the second switching circuit 2. Even if supplied to), the above effect does not appear.

Therefore, since the dim raster signal DR is supplied even while the high resolution monitor CRT 8 is operating, the brightness level of 50% or more is automatically adjusted to reduce eyestrain of the user when watching for a long time. Since a constant RGB image signal level can be obtained through the interface 3, even if the beam current increases, the constant image output signal levels are transferred to the CRT 8 through the RGB image amplification circuits 5, 6 and 7. As it is supplied, a stable screen is obtained.

On the other hand, when the special diagnostic switch SW ₁ is in the ON state, the collector potential of the transistor TR ₄ becomes low level, and the signal is input to the AND gate AD ₁ (AD ₂ ), among which the AND gate. The output signal of (AD ₂ ) is a low state and is applied to the input terminals of the NAND gates (ND ₄ ) and (ND ₅ ), respectively, so that the TTL level polarity of the horizontal and vertical actuator signals (HS) (VS) output from the interface (3) Regardless, the output signals of the NAND gates ND ₄ and ND ₅ are supplied to the horizontal and vertical oscillation circuits 4, and since the signals input to the AND gate AD ₁ are low level, the output signals are low. As a level, they are respectively supplied to input terminals of the NAND gates ND ₁ to ND ₃ .

Therefore, the RGB image signal passing through the interface 3 is supplied to the CRT 8 through the image amplification circuits 5, 6 and 7 as the output signals of the NAND gates ND ₁ to ND ₃ . You get a screen.

If the special diagnostic switch SW ₁ is turned off, the collector voltage of the transistor TR ₄ in the second switching circuit 2 is at the high level, so that the brightness level is at the maximum point. Since the signal is input to the input terminal of the AND gate AD ₁ (AD ₂ ), respectively, the output signal of the AND gate AD ₂ is supplied to the input terminal of the NAND gate ND ₄ (ND ₅ ) as a high state. Accordingly, the horizontal and vertical synchronization signals HS and VS output from the interface 3 are not supplied to the horizontal and vertical oscillation circuits 4 through the NAND gates ND ₄ and ND ₅ . Similarly, since the input signal of the AND gate AD ₁ is supplied at a high level, the output signal is also supplied to the input terminals of the NAND gates ND ₁ to ND ₃ as a high level, thereby providing RGB through the interface 3. Since the video signal of is not transmitted as the output signal of the NAND gates ND ₁ to ND ₃ , free oscillation is performed so that the screen of the high-resolution monitor CRT 8 becomes a completely white pattern.

Therefore, if the special diagnostic switch (SW ₁ ) is in the ON state, the CRT (8), which is a high-resolution monitor, operates normally, but if the special diagnostic switch (SW ₁ ) is turned off to check whether the monitor itself is abnormal, Since a perfect white pattern is obtained, it is possible to check whether the CRT 8 itself is abnormal.

As described above, according to the present invention, when using a high-resolution monitor, a stable video signal can always be obtained by automatic brightness adjustment, and when a dim raster signal of TTL level is input, the screen brightness level (when the maximum level is 50% or more) In addition to automatically reducing the), depending on the position of the special diagnostic switch, it is possible to identify the fault of the monitor or when connecting to other systems.

Claims (1)

In a high resolution monitor composed of an interface 3, horizontal and vertical oscillation circuits 4, RGB image amplification circuits 5, 6, 7 and CRTs 8, The transistor TR ₂ (TR ₃ ) is turned on to control the transistor TR ₆ connected between the NAND gates ND ₁ to ND ₃ and the RGB image amplification circuits 5 to 6. 1 When the switching circuit 1 and the screen brightness are 50% or more, the transistors TR ₄ and TR ₅ are turned on and connected between the interface 3 and the NAND gates ND ₁ to ND ₅ . The second switching circuit 2 for controlling the output of the AND gate AD ₁ AD ₂ to reduce the screen brightness by 50%, and the second switching circuit to check whether the CRT 8 itself has an upper limit. circuit (2) and the aND gate (AD ₁₎ a variable resistor for adjusting the special diagnostic switch (SW ₁₎ and screen brightness to be connected to each period (AD ₂₎ (V) La dim and special diagnostic resolution of the monitor, characterized in that the circuit is configured as a master.

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