KR0173951B1 - S compensation circuit of CRT horizontal deflection output circuit - Google Patents

Abstract

The present invention relates to an S compensation circuit of a CRT horizontal deflection output circuit which enables an ideal S compensation by varying the voltage waveform of an amplifier in various forms.

The present invention relates to a CRT horizontal deflection output circuit including a horizontal deflection coil, comprising: a constant voltage power supply for supplying a constant voltage, an S compensation reference signal generator for generating a reference signal for S compensation, and an output from the S compensation reference signal generator And an amplifier for amplifying the S compensation reference signal and converting the waveform of the power applied to the horizontal deflection coil into an optimum compensation waveform by amplifying the S compensation reference signal.

Therefore, the present invention can obtain a high-definition image without distortion, regardless of the type of monitor or the type of video mode, and can be easily configured, thereby reducing the manufacturing cost.

Description

S compensation circuit of CRT horizontal deflection output circuit

1 is a block diagram of a horizontal deflection output circuit of a typical CRT.

2 is a signal waveform diagram of each part of FIG.

3 is a configuration diagram of an S compensation circuit of a conventional CRT horizontal deflection output circuit.

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

5 is a block diagram showing one basic concept of the S compensation circuit of the CRT horizontal deflection output circuit according to the present invention.

6 is a block diagram showing a concrete embodiment of the S compensation circuit of the CRT horizontal deflection output circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

1, 21: base driving unit 2, 22: horizontal output transistor

3, 23: diode 4, 12, 24: capacitor

5, 11, 25, 34: horizontal deflection coils 6, 14, 28, 35: constant voltage power supply

26: S compensation reference signal generator 27: power amplifier

31: microcomputer 32: D / A converter

33: amplifier 36: AC power

37: power supply

The present invention relates to an S compensation circuit of a CRT horizontal deflection output circuit, and more particularly, to an S compensation circuit of a CRT horizontal deflection output circuit capable of performing an ideal S compensation by changing a voltage waveform of an amplifier in various forms.

As the demand for high resolution graphics software increases, the spread of large monitors and high-definition monitors larger than 21 inches is on the rise. There are many factors that determine the picture quality of these monitors. In particular, uniform horizontal and vertical scanning is essential for high quality monitors.

Therefore, an appropriate compensation circuit for each deflection circuit must be added to realize uniform horizontal and vertical scanning of the entire screen.

In conventional large and high-definition monitors, these compensation circuits have many constraints due to the limitations of the compensation technique. In particular, very precise compensation is required for high definition, and the conventional compensation technique cannot prevent a significant increase in the number of components of the compensation circuit for a certain degree of precision compensation. For this reason, in order to realize high-definition monitors, an economical and novel technique for compensating horizontal and vertical deflection circuits is required.

In a typical CRT horizontal deflection output circuit, as shown in FIG. 1, the base driving unit 1 is connected to the base of the horizontal output transistor 2 consisting of npn transistors, and the emitter of the horizontal output transistor 2 is grounded. , The cathode of the damping diode 3 to the colleg of the horizontal output transistor 2, the ground to the anode of the damping diode 3, and the capacitor to the collector of the horizontal output transistor 2. 4), one end of the capacitor 4, the horizontal deflection coil 5 is connected in parallel, the other end of the capacitor 4 and the constant voltage power supply (6) supplying a constant voltage (Vcc) to the ground by Is done.

The operation of the horizontal flat output circuit of the general CRT configured as described above will be described with reference to FIG.

As shown in FIG. 2C, the base driving unit 1 supplies the base emitter voltage Vbe at a high level so that the horizontal deflection coil 1 is turned on when the horizontal output transistor 1 is turned on. The constant voltage power supply 6 is applied to (5), and the coil current IL flowing through the horizontal deflection coil 5 increases linearly as shown in FIG.

When the coil current IL flowing in the horizontal deflection coil 5 is above a certain value, the base driving unit 1 lowers the base emitter voltage Vbe as shown in FIG. 2C. Level output) to turn off the horizontal output transistor 2.

When the horizontal output transistor 2 is turned off, the horizontal deflection coil 5 and the capacitor 4 start to resonate. As the horizontal deflection coil 5 resonates, the damping diode 3 is turned on at the instant the coil voltage VL drops below −Vcc as shown in FIG. 2 (b).

When the damping diode 3 is turned on, the constant current Vcc is applied from the constant voltage power supply 6 to the horizontal deflection coil 5 and the coil current IL increases linearly again as shown in FIG. To start. If the base driving unit 1 supplies the high level base emitter voltage Vbe before the direction of the coil current IL is changed, the horizontal output transistor 2 is turned on in reverse mode, and the coil current IL is horizontal. It continues to increase as it flows to the output transistor 2.

When the base driving unit 1 supplies the low level base emitter voltage Vbe to the base of the horizontal output transistor 2 again, the above operation is repeated while the horizontal output transistor 2 is turned off. As a result, the sawtooth coil current IL flows through the horizontal deflection coil 5, so that the magnetic field of the horizontal deflection coil 5 also changes continuously.

The scan line from the CRT electron gun is horizontally deflected through the horizontal deflection coil to uniformly scan the fluorescent surface of the CRT.

In practice, however, CRTs are almost planar with only a slight curvature. Therefore, if the scanning line is deflected horizontally at a constant rate, the unit block size of the image is not constant. If the size of the unit block of the image is non-uniform, the screen is generally distorted. In order to prevent such distortion, the horizontal deflection angle is compensated for, so that an image block of a certain size is obtained as a whole.

That is, when the waveform of the coil current flowing through the horizontal deflection coil is changed to S-shape instead of sawtooth wave, and the current value at both ends becomes smaller, the magnetic field strength of the horizontal deflection coil is smaller and the deflection angle of the scan line is smaller, so that the image of the overall constant size You get a unit block.

Thus, the S compensation circuit of the conventional CRT horizontal deflection output circuit for changing the waveform of the coil current flowing through the horizontal deflection coil into an S-shape rather than a sawtooth wave is provided with the other end of the horizontal deflection coil 11 as shown in FIG. The capacitor 12 is connected to the ground, one end of the coil 13 is connected to the other end of the horizontal deflection coil 11, and the constant voltage power supply 14 which supplies the constant voltage Vcc to the other end of the coil 13 is connected. Make up

The operation of the S compensation circuit of the CRT horizontal deflection output circuit configured as described above will be described with reference to FIG.

The voltage Vc of the capacitor 12 has a sine wave ripple voltage based on the average value Vcc by charging and discharging the coil current IL flowing through the horizontal deflection coil 11 as shown in FIG. do. That is, when the coil current IL is negative, the capacitor 12 charges, and when the coil current IL is positive, the capacitor 12 discharges.

In other words, when the coil current IL passes '0', the capacitor voltage Vc has the highest value as shown in FIG. 4 (b). Since the rising slope of the coil current IL is proportional to the voltage VL of the horizontal deflection coil 11, as shown in FIG. 4A, the rising slope of the coil current IL has the highest slope when the coil current IL passes '0'. The slope decreases toward both ends. As a result, the waveform of the coil current IL is compensated as shown in FIG.

Therefore, when the waveform of the coil current IL flowing in the horizontal deflection coil 11 is changed into an S-shape rather than a sawtooth wave, the current value at both ends is reduced, so the strength of the magnetic field of the horizontal deflection coil 11 is also reduced and the deflection angle of the scan line is reduced. Becomes smaller. That is, the curvature of the scan line decreases toward both ends of the screen, thereby maintaining the image unit block size on the CRT surface constant.

The S compensation circuit of the horizontal deflection output circuit employed in the conventional CRT is mostly modified slightly based on the operation principle of the S compensation circuit of the conventional horizontal deflection output circuit shown in FIG. As described above, the S compensation circuit using the capacitor power source has a problem in that the circuit is more complicated than necessary because the capacitor and the switching element are increased for the local compensation of the coil current IL.

In particular, S compensation circuit using a capacitor power supply is limited in a place where a very sophisticated coil current (IL) compensation is required, such as a high definition large monitor. In addition, when using multiple video modes in the monitor, there is a problem that one compensation circuit cannot compensate optimally in different video modes.

An object of the present invention to solve the above problems is to provide a S compensation circuit of a CRT horizontal deflection output circuit for introducing a new concept of S compensation technique to obtain an optimal high quality in economical and various video modes.

One embodiment of the S compensation circuit of the CRT horizontal deflection output circuit according to the present invention for achieving the above object is a constant voltage power supply for supplying a constant voltage, S compensation in the CRT horizontal deflection output circuit comprising a horizontal deflection coil. S compensation reference signal generator for generating a reference signal for the power supply and the DC power supplied to the horizontal deflection coil by amplifying and adjusting the S compensation reference signal output from the S compensation reference signal generator by inputting the DC power supplied from the constant voltage power supply And a power amplifier for converting the waveform into an optimal compensation waveform.

Further, another embodiment of the S compensation circuit of the CRT horizontal deflection output circuit according to the present invention is a CRT horizontal deflection output circuit including a horizontal deflection coil, the microcomputer storing and outputting a voltage waveform, which is output from the micom. A D / A converter for converting a digital signal into an analog signal, an amplifier for amplifying a voltage waveform output from the microcomputer, and a waveform of a power applied to the horizontal deflection coil adjusted according to the output of the amplifier as an optimal compensation waveform. It characterized in that it comprises a power supply for converting and supplying.

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

One embodiment of the S compensation circuit of the CRT horizontal deflection output circuit according to the present invention is an S compensation reference signal generator 26 and a power amplifier 27 in the conventional CRT horizontal deflection output circuit of FIG. 1 as shown in FIG. ).

That is, one embodiment of the S compensation circuit of the CRT horizontal deflection output circuit according to the present invention connects the base of the horizontal output transistor 22 made of the npn transistor to the base driving unit 21 as shown in FIG. Connect the emitter of the horizontal output transistor 22 to ground, connect the cathode of the damping diode 23 to the collector of the horizontal output transistor 22, the ground to the anode of the damping diode 23, In the round tube horizontal deflection output circuit configured by connecting one end of the capacitor 24 to the collector of the horizontal output transistor 22 and parallel connecting the horizontal deflection coil 25 to both ends of the capacitor 24, the S compensation reference signal The other end of the generator 26 and the capacitor 24 is connected to the power amplifier 27, and is connected to a constant voltage power supply 28 for supplying a constant voltage (Vcc) to the power amplifier 27 is configured.

Here, the constant voltage power supply 28 supplies a constant voltage Vcc to the power amplifier 27 and combines the constant voltage Vcc with the output voltage of the power amplifier 27, and the S compensation reference signal generator 26 performs an S compensation. Generates a reference signal for the power amplifier 27 inputs a DC power supplied from the constant voltage power supply 28 to amplify and adjust the S compensation reference signal output from the S compensation reference signal generator 26 to adjust the horizontal deflection coil ( The waveform of the power source applied to 25) is converted into the optimal compensation waveform.

The S compensation circuit of the horizontal deflection output circuit according to the present invention changes the voltage waveform of the power amplifier 27 connected in series to the constant voltage power supply 28 in various forms, so that the current IL 'flowing in the horizontal deflection coil 25 is changed. The waveform is changed to obtain an ideal S compensation according to the type of monitor, the top view of image quality, the type of video mode, and the like.

That is, the S compensation circuit of the horizontal deflection output circuit according to the present invention changes the voltage waveform of the power amplifier 27 to an optimal compensation waveform according to the type of monitor, the clarity of the image quality, and the type of the video mode. The ideal S compensation can be obtained by compensating the waveform of the current IL 'flowing in 25).

The operation of one embodiment of the S compensation circuit of the CRT horizontal deflection output circuit according to the present invention configured as described above will be described in detail.

When the S compensation reference signal generator 26 generates a reference signal for ideal S compensation, the amplified output of the power amplifier is amplified by the power amplifier 27 and the DC power voltage supplied from the constant voltage power supply 28 accordingly. The voltages are combined to convert the waveform of the power applied to the horizontal deflection coil 25 into an optimal compensation waveform and applied to the horizontal deflection coil 25.

On the other hand, when the horizontal output transistor 21 is turned on by supplying the base emitter voltage Vbe to the high level from the base driving unit 21, the power amplifier 27 is supplied to the horizontal deflection coil 25. Power applied to the optimal compensation waveform is applied, and the coil current IL 'flowing in the horizontal deflection coil 25 increases in the S-compensated form.

When the coil current IL 'flowing through the horizontal deflection coil 25 is equal to or greater than a predetermined value, the base driving unit 21 supplies the base emitter voltage Vbe at a low level to supply the horizontal output transistor 22. ) Is turned off.

When the horizontal output transistor 22 is off, the horizontal deflection coil 25 and the capacitor 24 start to resonate. As the horizontal deflection coil 25 resonates, the damping diode 23 is turned on at the instant the coil voltage VL 'falls below -Vcc.

When the damping diode 23 is turned on, the coil current IL 'starts to increase in the S-compensated form while the power converted from the power amplifier 27 into the optimal compensation waveform is applied to the horizontal deflection coil 25. When the base driving unit 21 supplies the high level base emitter voltage Vbe before the direction of the coil current IL 'is changed, the horizontal output transistor 22 is turned on, and the coil current IL' is output horizontally. It continues to increase as it flows to the transistor 22.

When the base driving unit 21 supplies the low level base emitter voltage Vbe to the base of the horizontal output transistor 22 again, the above operation is repeated while the horizontal output transistor 22 is turned off. As a result, the S-compensated coil current IL 'flows to the horizontal deflection coil 25 so that the magnetic field of the horizontal deflection coil 25 also changes.

Therefore, since the waveform of the coil current IL 'flowing through the horizontal deflection coil 25 is changed into an S-shape, the current value at both ends becomes smaller, so that the magnetic field strength of the horizontal deflection coil 25 is smaller and the deflection angle of the scanning line is smaller. This results in a block of picture units of uniform size throughout.

Here, the S compensation reference signal generator 26 is composed of a microcomputer for storing and outputting the voltage waveform as digital data, the microcomputer is a D / A (Digital / Analog) for converting and outputting the voltage waveform stored as digital data to analog data Another embodiment of the S compensation circuit of the CRT horizontal deflection output circuit according to the present invention having the above configuration will be described.

Another embodiment of the S compensation circuit of the CRT horizontal deflection output circuit according to the present invention includes a microcomputer 31, a D / A converter 32, and a conventional CRT horizontal deflection output circuit as shown in FIG. And an amplifier 33 further configured.

That is, another embodiment of the S compensation circuit of the CRT horizontal deflection output circuit according to the present invention connects the D / A converter 32 to the microcomputer 31 as shown in FIG. Is connected to the amplifier 33, and the power supply 37 is connected to the amplifier 33 and the horizontal deflection coil 34, that is, a capacitor (not shown).

Here, the power supply 37 is adjusted according to the output of the amplifier 33 and converts and supplies the waveform of the power applied to the horizontal deflection coil 34 to an optimal compensation waveform, and according to the output of the amplifier 33. The waveform of the power supplied to the horizontal deflection coil 34 by combining with the AC power supply 36 with which the voltage waveform is adjusted and the voltage waveform supplied from the AC power supply 36 is converted into an optimal compensation waveform to make the horizontal deflection coil 34 It is composed of a constant voltage power supply 35 to be supplied to.

In addition, the microcomputer 31 stores and outputs the voltage waveform, that is, the voltage waveform of the AC power supply 36 as digital data. At this time, the microcomputer 31 may be configured to include a D / A converter 32 therein.

In addition, the amplifier 33 amplifies the voltage waveform output from the D / A converter 32 and outputs it to the AC power supply 36.

The operation of another embodiment of the S compensation circuit of the CRT horizontal deflection output circuit according to the present invention configured as described above will be described in detail.

The voltage waveform of the AC power source 36 is stored in the microcomputer 31 as digital data and is output when a signal is applied from the outside. At this time, since the voltage waveform output from the microcomputer 31 is digital data, it is converted into an amplified analog signal while striking the D / A converter 32 and the amplifier 33 and is applied to the AC power supply 36.

Accordingly, the AC power supply 36 is supplied to the constant voltage power supply 35 after the voltage waveform is adjusted, and is applied to the horizontal deflection coil 34 in accordance with the voltage waveform supplied from the AC power supply 36 in the constant voltage power supply 35. The waveform of the power supply is converted into an optimal compensation waveform and supplied to the horizontal deflection coil 34.

Therefore, since the waveform of the coil current IL 'flowing through the horizontal deflection coil 34 is optimally changed into a compensation waveform, that is, an S-shape, the current value at both ends becomes small and the strength of the magnetic field of the horizontal deflection coil 34 is also small. As a result, the deflection angle of the scanning line is also reduced, resulting in an image unit block of a uniform size as a whole.

Therefore, another embodiment of the S compensation circuit of the CRT horizontal deflection output circuit according to the present invention can store various types of voltage waveforms in the microcomputer 31, so that the monitor environment, that is, the type of monitor, the clarity of gray, and the video mode can be stored. The most optimal S compensation waveform can be obtained according to the type and the like, and the voltage waveform of the AC power supply 36 applied to the horizontal deflection coil 34 can be easily adjusted from the outside to obtain the most optimal S compensation waveform. Can give

As described above, the present invention can obtain a high-definition image without distortion, regardless of the type of monitor or the type of video mode, and can be easily configured to reduce the cost of manufacturing a monitor.

Claims (2)

A CRT horizontal deflection output circuit comprising a horizontal deflection coil (25), comprising: a constant voltage power supply (28) for supplying a constant voltage (Vcc); A microcomputer that outputs digital data on voltage signals for inputting the S-corrected signal to the horizontal deflection coil 25, and receives a digital data output from the microcomputer and converts the digital data into an analog signal to convert the reference signal for S compensation. An S-compensation reference signal generator 26 having a D / A converter for outputting the signal; The power supply amplifier 27 which receives a DC power supply from the constant voltage power supply 28, amplifies the S compensation reference signal output from the S compensation reference signal generator 26, and applies it to the horizontal deflection coil 25. S, the S compensation circuit of the CRT horizontal deflection output circuit, characterized in that for inputting the optimal S-compensated waveform to the horizontal deflection coil (25). A CRT horizontal deflection output circuit comprising a horizontal deflection coil 34, comprising: a microcomputer 31 for outputting digital data on voltage signals for inputting an S-corrected signal to the horizontal deflection coil 34; ; A D / A converter 32 which receives digital data output from the microcomputer 31 and converts the digital data into an analog signal; An amplifier (33) for amplifying and outputting an analog signal output from the D / A converter (32); An AC power supply 36 for receiving a duplicate analog signal through the amplifier 22 and outputting a voltage waveform corresponding thereto; The CRT horizontal, characterized in that it comprises a constant voltage power supply 35 for converting the waveform of the power applied to the horizontal deflection coil 34 according to the voltage waveform supplied from the AC power supply 36 into an optimal compensation waveform. S compensation circuit of deflection output circuit.