KR200212012Y1 - Dynamic focus circuit of the monitor - Google Patents

Abstract

The present invention relates to a dynamic focus circuit of a monitor. The circuit of the present invention includes a capacitor (C11) for AC-coupling a parabolic waveform signal; A DC regulating amplifier Q11 for applying a variable DC voltage to a parabola waveform signal passing through the capacitor C11; An inverting amplifier (Q12) which receives a parabolic waveform signal from the direct current adjusting amplifier (Q11) to a base stage and inverts and amplifies the base stage; A cascode amplifier (Q13, 14) having an emitter stage receiving the amplified parabola waveform signal from the inverting amplifier (Q12) and outputting the amplified signal through the collector stage; An emitter follower (Q15, 16) whose base end receives and amplifies the parabola waveform signal amplified from the cascode amplifiers (Q13, 14); A non-inverting amplifier (Q17, 18) which the collector stage receives the DC high voltage and amplifies the DC high voltage by the base voltage and outputs it through the emitter stage; It is composed of a diode (D11-14) for DC coupling the DC high voltage amplified from the non-inverting amplifier (Q17, 18), the parabola waveform signal and diode output from the emitter follower (Q17, 18) By superimposing the DC high voltage output from (D11-14) and supplying it to the dynamic focus terminal of the flyback transformer (FBT), it improves the low impedance of the amplifying stage and matches the power impedance and load impedance to match the phase delay of the dynamic focus signal. The effect is to prevent waveform distortion.

Description

Dynamic focus circuit of a monitor

The present invention relates to a dynamic focus circuit of a monitor for compensating for a shift in focus when scanning the edge of a screen in a monitor.

In general, a water tube (CRT) used in a monitor focuses and accelerates hot electrons emitted from R, G, and B guns, and collides with R, G, and B fluorescent surfaces through a point on a shadow mask to form pixels. The sawtooth wave flows through the horizontal deflection coil to form a two-dimensional screen.

In order to operate the water tube (CRT), a heater voltage of about 6.3V is applied to the heater, and a focus grid voltage, a screen grid voltage, etc. are required for focusing the emitted hot electrons. High pressure of about 25KV is applied.

In this case, a focus grid for focusing the electron beam emitted from the cathode is divided into a static focus (S.FOCUS) grid and a dynamic focus (D.FOCUS) grid, and the dynamic focus grid includes a parabolic waveform signal for dynamic focusing. This is called a dynamic focus signal).

As is well known, the diameter of the electron beam in the receiving tube increases toward the periphery of the screen. That is, the focus at the edge is wider than the focus at the center of the monitor, so the sharpness is poor at the edge. To compensate for this, a high resolution monitor applies a compensation waveform, that is, the above-mentioned dynamic focus signal, so that the electron beam focuses exactly on the fluorescent surface of the receiving tube.

The dynamic focus signal depends on the combination of the receiving tube and the deflection coil. In general, as the screen of the receiving tube becomes larger, the voltage crest required for compensation tends to increase.

Therefore, a dynamic focus signal having a function of correcting a difference in focus caused by a difference in mileage between a center portion and a periphery of a water pipe requires a power source of several hundred volts, and such a power source is usually supplied from a flyback transformer (FBT). Obtained.

Referring to FIG. 1, a process of generating the parabola waveform dynamic focus signal is generated. The parabola generator 10 generates and outputs a convex parabola waveform as shown in FIG. The first transistor Q1 can drive the second transistor Q2 by small signal amplification of the parabola waveform, and the second transistor operates in the active region to amplify the parabola waveform and then the flyback transformer FBT It is applied to the dynamic focus terminal.

In this case, the resistor R1 is an emitter resistor of the first transistor Q1, the resistor R2 and the capacitor C1 filter out noise, and the resistor R3 is a bias resistor so that the second transistor Q2 is always present. In order to be able to operate in the active area, the capacitor C2 is a speed-up capacitor. In addition, diode D1 is connected for driving conditions associated with minority carrier removal and active region operation of the emitter-base end of second transistor Q2, and resistor R5 is connected to the base- of second transistor Q2. The collector-to-collector bias resistor, and the resistor R6 is a resistor for limiting the collector current of the second transistor (Q2).

In the dynamic focus circuit as described above, a signal applied to the dynamic focus terminal of the flyback transformer (FBT) becomes a concave parabolic waveform as shown in FIG. 2 (b), which compensates for the left and right edges of the screen. The horizontal dynamic focus signal is a parabolic waveform signal with a concave central portion generated by the horizontal period (1H) and has a peak voltage of about 300 V _PP. The vertical dynamic focus signal is used to compensate for the upper and lower edges of the screen. The central portion generated in the period 1V is a concave parabola waveform signal and has a peak voltage of about 150V _PP .

However, the conventional dynamic focusing circuit as described above has a problem that the impedance matching is not well performed during the amplification process, resulting in phase delay and waveform distortion of the dynamic focus signal.

Therefore, the present invention was devised to solve the above problems of the prior art. By combining the emitter follower with the cascode amplifier, the low impedance of the amplifier stage can be improved, and the power impedance and the load impedance are matched to match the dynamic focus signal. It is an object of the present invention to provide a dynamic focus circuit of a monitor, which is designed to prevent phase delay and waveform distortion of the monitor.

In order to achieve the above object, the circuit of the present invention,

A parabolic waveform generation unit for outputting a parabolic waveform signal in which a horizontal parabola waveform in which a center part is convex in a horizontal period and a vertical parabola waveform in which a center part is convex in a vertical period are output;

A capacitor for AC-coupling a parabola waveform signal output from the parabola waveform generator;

A DC regulating amplifier for applying a variable DC voltage to a parabolic waveform signal passing through the capacitor;

An inverting amplifier receiving a parabola waveform signal from the DC adjustment amplifier at the base end and inverting and amplifying the base end;

A cascode amplifier having an emitter stage receiving the amplified parabola waveform signal from the inverting amplifier and amplifying the amplified signal through the collector stage;

An emitter follower whose base stage receives the amplified parabola waveform signal from the cascode amplifier and amplifies and outputs it through the emitter stage;

A high voltage circuit converting and outputting the high voltage of the pulse waveform induced from the secondary side of the flyback transformer into a DC high voltage;

A non-inverting amplifier which the collector stage receives the DC high voltage from the high voltage circuit and amplifies the DC high voltage by the base voltage and outputs the same through the emitter stage; And

It is composed of a diode for DC coupling the DC high voltage amplified from the non-inverting amplifier,

The parabola waveform signal output from the emitter follower and the DC high voltage output from the diode are superimposed and supplied to the dynamic focus terminal of the flyback transformer.

1 is a circuit diagram showing a dynamic focus circuit of a general monitor;

FIG. 2 is a view of each sub waveform of FIG. 1;

3 is a circuit diagram showing a dynamic focus circuit of the monitor according to the present invention;

4 is a waveform diagram of each part of FIG. 1.

* Explanation of symbols for the main parts of the drawings

10: parabola waveform generation unit 20: high voltage circuit

Q11: DC adjustment amplifier Q12: Inverting amplifier

Q13, Q14: Cascode amplifier Q15, Q16: Emitter follower

Q17, Q18: Non-inverting amplifier C11: Capacitor for AC coupling

D11, D12, D13, D14: diode for DC coupling

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a circuit diagram illustrating a dynamic focus circuit of a monitor according to the present invention.

As shown in FIG. 3, the circuit of the present invention includes a parabolic waveform generating unit 10 for outputting a horizontal parabolic waveform in which a central portion is convex in a horizontal cycle and a parabola waveform signal in which a vertical parabola waveform in which a central portion is convex in a vertical cycle is superimposed. ; A capacitor C11 for AC-coupling a parabolic waveform signal output from the parabolic waveform generator 10; A DC regulating amplifier Q11 for applying a variable DC voltage to a parabolic waveform signal passing through the capacitor C11; An inverting amplifier (Q12) for receiving a parabolic waveform signal from the direct current adjusting amplifier (Q11) to a base end and inverting and amplifying the signal through a collector stage; A cascode amplifier (Q13, Q14) in which the emitter stage receives the amplified parabola waveform signal from the inverting amplifier (Q12) and outputs the amplified signal through the collector stage; An emitter follower Q15 and Q16 having a base end receiving the amplified parabola waveform signal from the cascode amplifiers Q13 and Q14 and outputting the amplified signal through the emitter stage; A high voltage circuit 20 for converting and outputting the high voltage of the pulse waveform induced from the secondary side of the flyback transformer FBT into a direct current high voltage; A non-inverting amplifier (Q17, Q18) that the collector stage receives the DC high voltage from the high voltage circuit (20) and amplifies the DC high voltage by the base voltage and outputs it through the emitter stage; And diodes D11, D12, D13, and D14 for DC-coupling the DC high voltage amplified from the non-inverting amplifiers Q17 and Q18, and are output from the emitter follower Q17 and Q18. The waveform signal and the DC high voltage output from the diodes D11, D12, D13, and D14 are superimposed and supplied to the dynamic focus terminal D. FOCUS of the flyback transformer FBT.

Next, the operation and effects of the circuit according to the present invention configured as described above will be described with reference to FIG. 4.

4 is a waveform diagram of each part of the circuit according to the present invention.

First, the parabola waveform generating unit 10 outputs a signal of a parabola waveform in which a horizontal parabola waveform in which a center part is convex in a horizontal period and a vertical parabola waveform in which a center part is convex in a vertical period are superimposed.

Recently, due to the development of semiconductor technology, chips capable of outputting various signals at once have been developed. In an embodiment of the present invention, Philips' automatic synchronization deflection controller 'TDA4854' is used. The 'TDA4854' receives a horizontal synchronizing signal and a vertical synchronizing signal, generates a horizontal driving signal for horizontal deflection, a vertical driving signal for vertical deflection, provides a parabolic waveform for dynamic focusing, and provides a pincushion correction signal. I can do it.

The parabola waveform signal output from the parabola waveform generator 10 is AC-coupled through the capacitor C11 and then applied to the base end of the DC regulator amplifier Q11.

The DC regulator amplifier Q11 loads a desired DC voltage Vcc into an AC-coupled parabola waveform signal and outputs the same through an emitter stage.

The parabola waveform signal output from the emitter stage of the DC adjustment amplifier Q12 is applied to the base stage of the inverting amplifier Q12, inverted and amplified and then output through the collector stage.

The parabolic waveform signal output from the collector stage of the inverting amplifier Q12 is applied to the emitter stages of the cascode amplifiers Q13 and Q14 and amplified and then output through the collector stage.

At this time, the cascode amplifiers Q13 and Q14 connect the other transistors in series on one transistor to improve the low impedance of the amplifier stage and the voltage gain.

The parabolic waveform signals output from the collector stages of the cascode amplifiers Q13 and Q14 are applied to the base stages of the emitter followers Q15 and Q16 and amplified and then output through the emitter stages.

The emitter followers Q15 and Q16 match power impedance and load impedance for impedance matching, and transmit maximum power to the load.

Accordingly, as shown in FIG. 4 (a), the parabolic waveform signal of the 4V _PP crest value loaded on the DC voltage of 2V output from the parabola waveform generator 10 is a capacitor as shown in FIG. After AC coupling through C11, the desired DC voltage is loaded by the DC adjustment amplifier Q11 as shown in FIG. 4C, and then the inverting amplifier Q12 as shown in FIG. 4D. ) And a cascode amplifier (Q13, Q14) and emitter follower (Q15, Q16) to amplify the parabola waveform signal with a parabolic waveform of 450V _PP crest on a DC voltage of 10V.

On the other hand, the high voltage circuit 20 converts and outputs the high voltage of the pulse waveform induced from the secondary side of the flyback transformer (FBT) into a DC high voltage of DC 600V, and the DC high voltage of 600V is a collector of the non-inverting amplifiers Q17 and Q18. Is applied to the stage.

In this case, since the DC voltage of 600 V is divided by the bias resistors R22 and R23 of the non-inverting amplifiers Q17 and Q18 and input to the base terminal of the non-inverting amplifiers Q17 and Q18, the non-inverting amplifiers Q17 and The 600V DC voltage applied to the collector stage by the base voltage of Q18) is amplified by about 1/2 times to 300V and output through the emitter stage.

At this time, two non-inverting amplifiers (Q17, Q18) are connected in series to withstand the withstand voltage against 600V DC voltage.

The DC voltage of 300 V output from the emitter terminals of the non-inverting amplifiers Q17 and Q18 is DC-coupled through the diodes D11, D12, D13, and D14.

At this time, four DC coupling diodes (D11, D12, D13, D14) are connected in series to withstand the withstand voltage with respect to 300V DC voltage.

Accordingly, the parabola waveform signal output from the emitter follower Q15 and Q16 and the DC voltage passing through the diodes D11, D12, D13, and D14 are superimposed so that the dynamic focus terminal D of the flyback transformer FBT is overlapped. .FOCUS).

The dynamic focus signal input to the dynamic focus terminal D.FOCUS of the flyback transformer FBT has a horizontal parabola waveform in which the center portion is concave at the horizontal period and the center portion is concave at the vertical period, as shown in FIG. The vertical parabola waveforms are superimposed and output.The dynamic focus signal has a peak voltage of 450V _PP (the horizontal parabola waveform has a peak value of 300V _PP and the vertical parabola waveform has a peak value of 150V _PP ), and the DC level is about 300V. Focus correction is made.

As described above, the circuit according to the present invention improves the low impedance of the amplifier stage by combining the emitter follower with the cascode amplifier, while matching the power impedance and the load impedance to prevent phase delay and waveform distortion of the dynamic focus signal. In addition, the DC voltage of the dynamic focus signal can be adjusted to a desired level, thereby making it possible to perform smooth dynamic focus correction.

Claims (1)

A parabolic waveform generating unit 10 for outputting a parabolic waveform signal in which a horizontal parabola waveform in which a central portion is convex in a horizontal cycle and a vertical parabola waveform in which a central portion is convex in a vertical cycle are superimposed; A capacitor C11 for AC-coupling a parabolic waveform signal output from the parabolic waveform generator 10; A DC regulating amplifier Q11 for applying a variable DC voltage to a parabolic waveform signal passing through the capacitor C11; An inverting amplifier (Q12) for receiving a parabolic waveform signal from the direct current adjusting amplifier (Q11) to a base end and inverting and amplifying the signal through a collector stage; A cascode amplifier (Q13, Q14) in which the emitter stage receives the amplified parabola waveform signal from the inverting amplifier (Q12) and outputs the amplified signal through the collector stage; An emitter follower Q15 and Q16 having a base end receiving the amplified parabola waveform signal from the cascode amplifiers Q13 and Q14 and outputting the amplified signal through the emitter stage; A high voltage circuit 20 for converting and outputting the high voltage of the pulse waveform induced from the secondary side of the flyback transformer FBT into a direct current high voltage; A non-inverting amplifier (Q17, Q18) that the collector stage receives the DC high voltage from the high voltage circuit (20) and amplifies the DC high voltage by the base voltage and outputs it through the emitter stage; And Diodes D11, D12, D13, and D14 for DC-coupling the DC high voltage amplified from the non-inverting amplifiers Q17 and Q18, The dynamic focus terminal D.FOCUS of the flyback transformer FBT overlaps the parabola waveform signal output from the emitter follower Q17 and Q18 and the direct current high voltage output from the diodes D11, D12, D13, and D14. The dynamic focus circuit of the monitor characterized by the above-mentioned.