KR960007920B1 - Power voltage control circuit of multi-mode monitor - Google Patents

Abstract

The circuit supplies stabilized power for multi-mode monitor by choosing appropriate voltage levels according to horizontal frequencies. It includes horizontal drive(1), horizontal output(2), monitor(3), power selection control(4), 1st switch(5), 2nd switch(6) and 3rd switch(7). The power selection control(4) receives monitor operation mode discriminant signals(M1)(M2) and controls switching to supply appropriate power for each mode. Controlled by the power choice selection(4), 1st, 2rd and 3rd switches(5)(6)(7) choose and supply 1st(B1+), 2nd(B2+) and 3rd(B3+) power of flyback trans.

Description

Supply voltage control circuit of multi-mode monitor

1 is a power supply circuit diagram of a conventional monitor.

2 is a power supply voltage control circuit diagram of a multi-mode monitor of the present invention.

3 is a diagram showing the operation relationship of the circuit of the present invention according to each mode.

* Explanation of symbols for main parts of the drawings

4: power selection control unit 5: first switching unit

6: 2nd switching part 7: 3rd switching part

The present invention relates to a power supply voltage control circuit of a multi-mode monitor that supplies a stabilized power supply by selecting a power supply (anode supply) high voltage supplied to the monitor according to various horizontal frequencies in a multi-sync mode monitor according to various modes. will be.

In the conventional monitor high voltage application circuit, referring to FIG. 1, the horizontal drive unit 1 receives a horizontal synchronous signal Hsync and outputs a horizontal drive pulse, and is switched by the horizontal drive pulse to provide horizontal deflection and monitor high pressure. And a monitor 3 for supplying a high voltage from the horizontal output unit 2 and displaying a video signal.

The operation of the conventional motor high voltage application circuit is as follows.

The horizontal driving unit 1 outputs a horizontal driving pulse for the input horizontal sync signal Hsync, and the horizontal output unit 2 is switched by the input horizontal driving pulse to perform horizontal deflection and high pressure supply.

That is, the horizontal output transistor Q1 is switched on / off by the horizontal driving pulse, and accordingly, the power supply B + supplied to the primary winding N1 of the flyback transformer FBT is switched to the horizontal deflection coil L1. The horizontal deflection current flows, and the high pressure is induced in the secondary winding N2 by the switching of the primary winding N1, and the induced high voltage is supplied to the anode of the monitor 3 through the diode D1. Will be.

Where C1 is a charge / discharge capacitor for horizontal deflection.

However, in the multi-mode monitor having various horizontal frequencies, the period of the horizontal synchronization signal Hsync input to the horizontal driver 1 varies according to each mode, and the switching period of the horizontal output unit 2 is changed accordingly, so that the monitor applied voltage This fluctuation causes a problem that a uniform deflection cannot be achieved.

That is, even if the power supply voltage (B +) of the flyback transformer (FBT) increases in proportion to the horizontal frequency, a uniform horizontal deflection can be achieved. When the high pressure is lowered there is a problem that the distortion of the image occurs.

The present invention stabilizes the high pressure supplied to the monitor anode on the secondary side of the flyback transformer by supplying various power levels to the flyback transformer according to the mode determination result of the multi-mode monitor regardless of the horizontal frequency change. It is an object of the present invention to provide a power supply voltage control circuit of a multi-mode monitor that can supply, thereby ensuring a uniform horizontal deflection and preventing screen distortion, and the configuration and operation of the present invention with reference to the accompanying drawings. The effect is as follows.

2 shows a configuration of a power supply voltage control circuit of the present invention for achieving the above object. Referring to this, the power supply voltage control circuit of the multi-mode monitor according to the present invention receives a horizontal synchronizing signal (Hsync) to generate a horizontal drive pulse. A horizontal drive unit 1 for outputting, a horizontal output unit 2 that is switched by the horizontal drive pulses to supply horizontal deflection and monitor high pressure, and a high voltage is supplied from the horizontal output unit 2 to display an image signal. A power selection controller 4 for receiving a monitor 3 to perform the operation mode determination signal M1 and M2 of the monitor and performing switching control to select and supply a power suitable for each board; and the power selection controller A first switching unit 5 which selects and supplies the first power B1 + of the flyback transformer FBT under the control of (4), and the flyback transformer FBT under the control of the power selection controller 4; Wire the second power supply (B2 +) A second switching unit 6 which selects and supplies a second switching unit 6 and a third switching unit 7 which selects and supplies a third power source B3 + of the flyback transformer FBT under the control of the power selection control unit 4. It is composed.

On the other hand, the power selection controller 4 inverts the transistor Q5 turned on and off by the input mode discrimination signal M1 and M2, and the third switching unit 7 by inverting the output of the transistor Q5. A transistor Q6 for on / off control, a transistor Q2 for on / off control of the second switching unit 6 by being turned on / off by the mode discrimination signal M2, and the mode discrimination signal M1 ( M2 is commonly supplied to the base of the transistor Q5, and diodes D2 and D3 for preventing the operation of the transistor Q2 by the mode discrimination signal M1 and resistors for bias supply of the respective transistors R1-R12, the first switching unit 5 is composed of a diode D8 for supplying a first power source B1 +, and the second switch unit 5 is formed of a second power source B2 +. consists of a transistor (Q3) (Q4) and the output diode (D5) for switching control of the supply path, the third switching unit 7 is supplied to the third power (B3 ⁺⁾ It consists of a transistor (Q7) (Q8) and an output diode (D7) for switching the control to.

In the figure, reference numeral C1 denotes a capacitor, L1 denotes a horizontal deflection coil, Q1 denotes a horizontal output transistor, and D1, D4, and D6 denote diodes. The power supply voltage control operation of the present invention configured as described above will be described with reference to FIGS. 2 and 3 as follows.

The horizontal driving unit 1 outputs a horizontal driving pulse for the input horizontal sync signal Hsync, and the horizontal output unit 2 is switched by the input horizontal driving pulse to perform horizontal deflection and high pressure supply.

That is, the horizontal output transistor Q1 is switched on / off by the horizontal driving pulse, and accordingly, the power supply B + supplied to the primary winding N1 of the flyback transformer FBT is switched to the horizontal deflection coil L1. The horizontal current flows, and the high pressure is induced in the secondary winding N2 by the switching of the primary winding N1, and the induced high voltage is supplied to the anode of the monitor 3 through the diode D1. Will be.

Where C1 is a charge / discharge condenser for horizontal deflection. At this time, the power supply B2 ⁺ supplied to the primary winding N1 of the flyback transformer FBT is either the first power source B1 ⁺ or the second power source B2 ⁺ in response to the horizontal frequency (monitor operation mode) change. One power is selected and supplied from the third power source B3 ⁺ , wherein the horizontal frequencies Hf1, Hf2, and Hf3 corresponding to each power supply are set in a relationship of B1 ⁺ B2 ⁺ B3 ⁺ , The power of the level corresponding to Hf1Hf2Hf3 and proportional to the horizontal frequency is supplied to the applied power B + of the flyback transformer FBT.

That is, the mode discrimination signal M1 (M2) according to the mode discrimination result in the conventional multi-mode monitor is high as shown in the diagram of FIG. 3 in response to the horizontal frequencies Hf1, Hf2 and Hf3 for each mode. It is input to the power supply selection control section 4 as a (H) or a low (L) signal.

The power selection control unit 4 turns off the second switching unit 6 and the third switching unit 7 when the input mode discrimination signals M1 and M2 are high (H) and low (L), respectively. As the second switching unit 6 and the third switching unit 7 are turned off, the first switching unit 5 is turned on so that the first power source B1 ⁺ is supplied to the power source B + of the flyback transformer FBT. Supplied. On the other hand, the power selection control unit 4 turns on the second switching unit 6 when the mode discrimination signals M1 and M2 are input to low L and high H, respectively, and the third switching unit 7 As the second switching unit 6 is turned off, the first switching unit 5 is turned off and the second power source B2 ⁺ is supplied to the power source B ⁺ of the flyback transformer FBT.

The power selection control unit 4 turns off the second switching unit 6 and turns on the third switching unit 7 when the mode discrimination signals M1 and M2 are input to the low level L, respectively. As the switching unit 7 is turned on, the first switching unit 5 is turned off so that the third power source B3 ⁺ is supplied to the power source B ⁺ of the flyback transformer FBT.

The above operation will be described with reference to the embodiment circuit configuration. First, when the mode discrimination signal M1 (M2) is input to the high (H) and the low (L), respectively, the transistor Q2 is turned off with the low signal (M2) input to the base and thus the transistor (Q3) (Q4). Is also off.

The mode discrimination signal M1 is supplied as a high signal to the base of the transistor Q5 through the diode D3 to turn on the transistor Q5. At this time, the high signal is blocked by the diode D2. Is not authorized. Since transistor Q6 is turned off as transistor Q5 is turned on, transistors Q7 and Q8 are also turned off. In this case, therefore, a forward bias is applied to the diode D8 and the diode D8 is turned on, so the first power source B21 ⁺ is selected and supplied.

On the other hand, when the mode discrimination signal M1 (M2) is input to the low (L) and high (H), respectively, the high signal (M2) is input to the base of the transistor (Q2), the transistor through the diode (D2) The high signal is also supplied to the base of Q5, and the transistor Q5 is turned on.

As the transistor Q2 is turned on, the transistor Q3 and Q4 are turned on or the second power source B2 ⁺ is supplied. At this time, the diode D8 is turned off and the first power source B1 ⁺ is cut off because it is B2B1 ⁺ . On the other hand, as the transistor Q5 is turned on, the transistors Q6, Q7 and Q8 are turned off, and the third power source B3 ⁺ is also cut off. When all of the morph discrimination signals M1 and M2 are input as the low signal, all of the transistors Q2 and Q5 are turned off, and as the transistor Q2 is turned off, the transistors Q3 and Q4 are turned off so that the second power source. (B2 ⁺⁾ is cut off, the transistor (Q5) is a transistor (Q6) (Q7) (Q8 ) as the on-off the third power source ⁽⁺ B3) is selected and supplied.

At this time, since B3 ⁺ B1 ⁺ , the diode D8 is turned off, and the first power source B1 ⁺ is cut off.

As described above, according to the present invention, since the multimode monitor supplies appropriate power corresponding to the horizontal frequency conversion, the monitor can be stabilized with high voltage, and the reliability of the horizontal deflection can be ensured. There is an effect that can be improved.

Claims (2)

A power selection control unit 4 which performs a switching control to receive the operation mode determination signals M1 and M2 of the monitor and selects a power suitable for each mode, and receives the control of the power selection control unit 4 The first switching unit 5 selects and supplies the first power B1 ⁺ of the flyback transformer FBT, and the second power source of the flyback transformer FBT under the control of the power selection control unit 4. A second switching unit 6 which selects and supplies B2 ⁺ ) and a third switching unit which selects and supplies a third power source B3 ⁺ of the flyback transformer FBT under the control of the power selection controller 4. A power supply voltage control circuit of a multi-mode monitor consisting of sections (7). The third switching unit of claim 1, wherein the power selection controller 4 inverts the transistor Q5 turned on and off by the input mode discrimination signal M1 and M2 and the output of the transistor Q5. A transistor Q6 for turning on / off control of (7), a transistor Q2 for turning on / off the second switching unit 6 by being turned on / off by the mode discriminating signal M2, and the mode discriminating signal (M1) A diode (D2) (D3) for supplying (M2) common to the base of the transistor (Q5) and preventing the operation of the transistor (Q2) by the mode discrimination signal (M1), and the bios supply of the respective transistors. The first switching unit 5 is composed of a diode (D8) for supplying a first power source (B1 ⁺ ), the second switching unit (5) is a second A transistor Q3 (Q4) and an output diode (D5) for switching the supply path of the power source (B2 ⁺ ) and the third switching unit (7) is a third A power supply voltage control circuit of a multi-mode monitor, comprising a transistor (Q7) (Q8) and an output diode (D7) for switching and controlling the supply path of the power supply (B3 ⁺ ).