KR930007346Y1 - Mode auto-selecting circuit of monitor - Google Patents

Abstract

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Description

Mode automatic switching circuit of monitor

1 is a conventional mode switching circuit diagram.

2 and 3 are diagrams of input and output waveforms at the time of mode switching by a horizontal synchronization signal.

4 is a mode automatic switching circuit diagram of the present invention monitor.

5 to 7 are diagrams of input and output waveforms at the time of mode switching by the vertical synchronization signal.

* Explanation of symbols for main parts of the drawings

11,15: first and second integrating circuit section 12,16: first and second mode switching control section

13 mode switching unit 14 vertical size control unit

MM ₂₁ , MM ₂₂ : Monostable multivibrator R ₂₁ to R ₂₆ : Resistance

TR ₂₁ , TR ₂₂ : transistors C _{21 to} C ₂₃ : capacitors

VDY: Vertical Deflection Coil

The present invention relates to a mode automatic switching circuit of a monitor. In particular, a signal input from the monitor, that is, a vertical synchronization signal of 60 Hz positive polarity and a horizontal synchronization signal of 15.75 KHz mode 1 and a vertical synchronization signal of 60 Hz negative polarity. Mode automatically switches to monitor mode according to mode 2 signal with horizontal sync signal 21.85KHz and mode 3 with vertical sync signal 54Hz negative and horizontal sync signal 21.85KHz It is about a circuit.

As shown in FIG. 1, the conventional mode switching circuit integrates when a horizontal synchronization signal is input and outputs a constant level proportional to the synchronization signal, and a signal input from the integration circuit unit 1; The mode switching control unit 2 performs mode switching control by adjusting the pulse widths of the resistors R2 (R3) and the condenser C2 (C3), and the mode control signal adjusted through the mode switching control unit 2. Accordingly, the mode switching unit 3 controls the transistors TR1 and TR2 to selectively switch between mode 1 or mode 2, and the level of the vertical output signal input in accordance with the mode switching through the mode switching unit 3. It is composed of a level adjusting unit 4 for adjusting the vertical size.

The conventional circuit configured as described above has a low frequency (pulse width) as shown in FIG. 2A at the horizontal synchronous signal input terminal HS1 in the state where power is applied to each element from the power supply terminals Vcc ₁ and Vcc ₂ . When the signal of this large) mode 1 is input, the horizontal synchronous signal of the mode 1 is integrated in the integrating circuit section 1 through the resistor R ₁ and the condenser C ₁ and is monostable in the mode switching control section 2. Since it is input to the input terminal of the multivibrator MM ₁ , its output terminal Q ₁ has a constant pulse width determined according to the time constants of the resistor R ₂ and the capacitor C ₂ , as shown in FIG. 2B. When the high potential signal is output and the low potential signal is output, the output signal is input again to the input terminal of the monostable multivibrator MM ₂ .

At this time, since the time constant by the resistor R ₃ and the capacitor C ₃ is larger than the pulse width of the horizontal synchronous signal of mode 1, its inverted output terminal As shown in FIG. 2C, the low-potential mode control signal is output, so that the transistor TR ₁ of the mode switching unit 13 is turned off by the low-potential mode control signal to supply power to the power supply terminal Vcc ₂ . As applied to the base of the transistor TR ₂ through the resistor R ₅ , the transistor TR ₂ is turned on so that the mode switching signal output terminal Mo ₂ has no output, and the mode switching signal output terminal Mo ₁ is output. Is switched to the mode 1 signal, and the power of the power supply terminal Vcc ₂ is applied to the base of the transistor TR ₃ through the resistor R ₆ , so that the transistor TR ₃ is turned on. Since the transistor TR ₂ is turned on, a low signal is applied to the base of the transistor TR ₄ through the resistor R ₈ , and thus the transistor TR ₄ is turned off.

Accordingly, the vertical output signal inputted to the vertical output signal input terminal VOI of the level adjuster 4 includes the vertical deflection coil VDY, the capacitor C ₄ , the resistor R ₉ , R ₁₁ , and the variable resistor VR. ₂ ) through the transistor (TR ₃ ) in accordance with the variable resistance of the variable resistor (VR ₂ ) through the vertical output signal through the capacitor (C ₅ ) and resistor (R ₁₂ ) in the vertical oscillating integrated circuit accordingly Adjust the vertical size.

Then, as shown in FIG. 3A, when the horizontal synchronizing signal of Mode 2 having a high frequency (small pulse width) is input to the horizontal synchronizing signal input terminal HSI, the signal is transmitted through the integrating circuit unit 1. It is applied to the input side of the monostable multi-vibrator MM ₁ of the mode switching control part 2 by making it constant level proportional to.

Then, the monostable of the multivibrator (MM ₁₎ the resistance (R ₂₎ and capacitor (C ₂₎ a monostable multivibrator (MM ₁₎ time constant mode 2 because of the larger set the pulse width of the horizontal synchronization signal by As shown in FIG. 3B through the output terminal Q ₁ , the high potential signal is applied to the input side of the monostable multivibrator MM ₂ .

However, since there is no input of the trigger pulse signal at the input of the monostable multivibrator MM ₂ , the low output signal is output to its output terminal Q ₂ , so the inverted output terminal As shown in Fig. 3C, a high potential mode control signal is output. Therefore, the transistor TR ₁ of the mode switching unit 3 is turned on and the transistor TR ₂ (TR ₃ ) is turned off by the high-potential mode control signal, so that the power supply of the power supply terminal Vcc ₂ is turned off by the resistor R _7. After outputting the signal through the mode switching signal output terminal Mo ₂ , the transistor TR ₄ is turned on again through the resistor R ₈ .

Therefore, the vertical output signal inputted to the vertical output signal input terminal (VOI) is converted through the vertical deflection coil (VDY), capacitor (C ₄ ), resistor (R ₉ ) (R ₁₀ ), and variable resistor (VR ₁ ). The vertical oscillating integrated circuit is grounded through the transistor TR ₄ according to the change of the resistor VR ₁ , and the vertical oscillating integrated circuit receives the vertical output signal input through the capacitor C ₅ , C ₄ , and the resistor R ₉ , R ₁₂ , respectively. Adjust the vertical size for.

However, although the conventional circuit is configured for dual mode and is suitable for PC / AT models, it cannot be used for computer monitors in which the Hangul and Hanja modes are added. That is, it is applied to computer monitors in which the Hangul and Hanja modes are added. In this case, since the vertical display period is much larger than the mode 1 signal and the mode 2 signal, there is a problem in that the quality of the monitor is deteriorated and the quality is degraded due to the problem that the vertical size is very large.

In view of the above-mentioned deficiencies, the present invention provides a mode automatic switching circuit of a monitor that detects a pulse width from a vertical synchronous signal according to signals of modes 1, 2, and 3, and automatically switches between three modes. When described in detail by the accompanying drawings as follows.

4 is a mode automatic switching circuit diagram of the monitor according to the present invention. The first and second integrating circuits 11 and 15 outputting a predetermined level proportional to the synchronization signal by integrating the horizontal and vertical synchronization signals inputted as shown therein. And first and second mode switching controllers 12 and 16 for adjusting the pulse widths of the signals output from the first and second integrating circuits 11 and 15 to control according to the mode switching. A mode switching unit 13 for selecting and switching each mode according to a mode control signal generated from the first and mode switching control unit 12, and outputs of the second mode switching control unit 16 and the mode switching unit 13; And a vertical size control unit 14 for level conversion to adjust the vertical size of the vertical output signal to a variable value.

Referring to the operation and effects of the present invention configured as described above in detail.

The horizontal synchronizing signal is a horizontal synchronizing signal of 15.75 Hz and the vertical synchronizing signal is 60 Hz positive in the horizontal synchronizing signal input terminal (HSI) when the power is supplied to the power terminal (Vcc ₁ ) (Vcc ₂ ). When the horizontal synchronizing signal as shown in FIG. Is inputted, the horizontal synchronizing signal becomes a constant level proportional to the synchronizing signal through the integrating circuit unit 11 as described in the prior art, so that the monostable stability of the first mode switching control unit 12 is achieved. Through the multivibrator MM ₁ (MM ₂ ) in sequence, the pulse width is adjusted by the resistors R ₂ (R ₃ ) and the capacitors C ₂ (C ₃ ) as shown in Figs. 2b and c. When the potential signal is outputted to the base side of the transistor TR ₁ of the mode switching unit 13, the transistor TR ₁ of the mode switching unit 13 is turned off to turn off the transistor TR ₂ and the vertical size control unit 14. The transistor TR ₃ is turned on. In addition, since the power of the power supply terminal Vcc ₂ through the resistor R ₅ is output to the mode switching signal output terminal Mo ₁ , a mode size signal is switched while the transistor TR ₂ is turned on. The transistor TR ₄ of 14 is turned off.

At this time, if the vertical synchronous signal of positive polarity as shown in FIG. 5A among the signals of mode 1 is input to the vertical synchronous signal input terminal VSI, the vertical synchronous signal is integrated through the resistor R ₂₁ and the capacitor C ₂₁ . When outputting a signal of a constant level proportional to the synchronous signal, the monostable multivibrator MM _{21 in} the second mode switching controller 16 generates a constant pulse according to the time constant by the resistor R ₂₂ and the capacitor C ₂₂ . A signal as shown in Fig. 5B having a width is output. When the output pulse is input to the monostable multivibrator MM ₂₂ again, the time constant by the resistor R ₂₃ and the condenser C ₂₃ is greater than the pulse width of the vertical synchronization signal of mode 1, and thus the monostable multivibrator. A mode control signal of high potential is output as shown in FIG. 5C through an output terminal Q ₂₂ of MM ₂₂ .

Therefore, since the high potential mode control signal is applied to the base of the transistor TR ₂₁ in the vertical size control unit 14, the transistor TR ₂₁ is turned on as a power supply Vcc ₂ through the resistors R ₂₄ and R ₂₅ . The transistor TR ₂₂ is turned on. Accordingly, the vertical output signal input to the vertical output signal input terminal VOI is a signal that is changed through the vertical deflection coil VDY, the capacitor C ₄ , the resistor R ₉ , R ₁₁ , and the variable resistor VR ₂ . Is grounded through the transistor TR ₃ so that the vertical oscillating integrated circuit adjusts the vertical size accordingly.

When the horizontal synchronous signal is input to the horizontal synchronous signal input terminal HSI as shown in FIG. 3a, the horizontal synchronous signal is 21.85 KHz and the vertical synchronous signal is 60 Hz, as shown in FIG. 3a. The transistor TR ₁ of the mode switching unit 13 is turned on by outputting a high potential signal through the monostable multivibrator MM ₁ (MM ₂ ) of the mode switching controller 12, and the transistor TR ₁ is turned on. As it is turned on, the transistor TR ₂ and the transistor TR ₃ of the vertical size control unit 14 are turned off so that the power supply of the power supply terminal Vcc ₂ through the resistor R ₇ is applied to the mode switching signal output terminal Mo ₂ . Since it is outputted, it is switched to the mode 2 signal while the transistor TR ₄ of the vertical size control unit 14 is turned on.

At this time, if a negative vertical synchronous signal as shown in FIG. 6a among the signals of mode 2 is input to the vertical synchronous signal input terminal VSI, the rising point of the input signal is the same as the vertical synchronous signal of the mode 1 signal described above. The output terminal Q ₂₁ (Q ₂₂ ) of the monostable mult vibrator MM ₂₁ (MM ₂₂ ) in the second mode switching control unit 16 generates a high potential signal as shown in FIGS. a low potential signal, and so continue to output the high potential signal transistor (TR ₂₁₎ is turned on, so is the low potential signal to the base shaft of the transistor (TR ₂₂₎ the transistor (TR ₂₂₎ is turned off. Then, the vertical output signal inputted to the vertical output signal input terminal VOI is a signal that is changed through the vertical deflection coil VDY, the capacitor C ₄ , the resistor R ₉ , the R ₁₀ , and the variable resistor VR ₁ . Is grounded through transistor TR ₄ (TR ₂₁ ) so that the vertical oscillating integrated circuit adjusts the vertical size accordingly.

In addition, when the horizontal synchronous signal is 21.85 Hz and the vertical synchronous signal is 54 Hz negative, the horizontal synchronous signal is the same as the horizontal synchronous signal of mode 2, so the horizontal synchronous signal of mode 2 described above is the same. Output terminal of monostable multivibrator (MM ₂ ) same as signal In since the high potential signal output transistor (TR ₁₎ is a transistor (TR ₂₎ as the on and the transistor (TR ₁₎ of the mode switching section 13 is turned on (TR ₃₎ is turned off the power supply terminal (Vcc ₂₎ Since the power is supplied to the mode switching signal output terminal Mo through the resistor R ₇ , it is switched to the mode 2 signal while the transistor TR ₄ of the vertical size control unit 14 is turned on.

At this time, if the vertical synchronous signal of negative polarity as shown in FIG. 7a among the signals of the mode 3 is input to the vertical synchronous signal input terminal VOI, the vertical synchronous signal is transmitted through the resistor R ₂₁ and the capacitor C ₂₁ . Time constant by the resistor R ₂₂ and the capacitor C ₂₂ is applied to the input side of the monostable multivibrator MM ₂₁ of the second mode switching controller 16 because it is integrated to become a constant level proportional to the synchronization signal. Since it is set larger than the pulse width of the vertical synchronizing signal of, the high potential signal is output to its output terminal Q ₂₁ as shown in FIG. 7B, and the high potential signal is input to the monostable multivibrator MM ₂₂ . Although the signal is applied to the trigger pulse signal, since there is no input of the trigger pulse signal, the high potential signal is maintained during the time constants of the resistor R ₂₃ and the capacitor C ₂₃ , and the output terminal Q _{22 thereof} has a low potential signal as shown in FIG. Is output, and its low potential A transistor (TR ₂₁₎ by the arc is turned off is the so that the power terminal (Vcc ₂₎ applied to the base of the transistor (TR ₂₂₎ via a resistor (R ₂₄₎ (R ₂₅₎ the transistor (TR ₂₂₎ on .

Therefore, the vertical output signal inputted to the vertical output signal input terminal VOI is passed through the vertical deflection coil VDY, the capacitor C ₄ , and the resistor R ₉ , R ₂₆ , and then through the variable resistor VR ₂₁ . The vertical oscillating integrated circuit adjusts the vertical size according to the variable resistor VR ₂₁ .

As described above, the three system modes are automatically switched by using the pulse widths of the vertical synchronization signals of modes 1, 2, and 3 input at different frequencies, and thus the vertical size can be maintained regardless of the mode switching. There is an effect of improving the compatibility and reliability of the monitor.

Claims (2)

From the first and second integrator circuits 11 and 15 for integrating the horizontal and vertical synchronization signals inputted and outputting a constant level proportional to the synchronization signal, and from the first and second integrators 11 and 15, respectively. According to the mode control signals generated from the first and second mode switching controllers 12 and 16 and the first and second mode switching controllers 12 for controlling the pulse width of the output signal. Level conversion to adjust the vertical size of the vertical output signal to a variable value according to the output of the mode switching unit 13 and the second mode switching control unit 16 and the mode switching unit 13 for selecting and switching each mode. A mode automatic switching circuit of the monitor constituted by the vertical size control unit (14). The method of claim 1, wherein the vertical size control unit 14 receives the output of the second mode switching control unit 16 to the base side, the collector of the transistor (TR ₂₁ ) to turn on, off the power through the resistor (R ₂₄ ) connected to the voltage terminal (Vcc ₂₎ as well as being connected to the emitter teocheuk of the transistor (TR _4), said transistor (TR ₂₁₎ the collector of the (TR ₄₎ - through the emitter connection point is the resistance (R ₂₅₎ transistor (TR ₂₂ And the collector-base connection point of the transistors TR ₁ and TR ₂ in the mode switching unit 13 are connected to the base side of the transistor TR3 through the resistor R6. The collectors of TR ₃ ) (TR ₄ ) (TR ₂₂ ) are connected to each other via variable resistor VR ₂ (VR ₁ ) (VR ₂₁ ) and resistor R ₁₁ (R ₁₀ ) (R | ₂₆ ), junction capacitor (C ₅₎ and a resistor and connected sequentially to the (R ₁₂₎ as well as a resistance (R _9), a capacitor (C ₄₎ and a vertical output signal input via the vertical deflection coil (VDY) Mode of the monitor, characterized in that configured is connected to the automatic switch circuit VOI.