KR100235104B1 - A circuit of controlling a horizontal linearity in a multi-mode monitor - Google Patents

Abstract

The horizontal linearity adjustment circuit of the multi-mode monitor is connected in series to the horizontal deflection coil (H.DY), and generates a magnetic field according to the magnitude of the current flowing, thereby adjusting the right and left deflection of the electron beam, And a control unit 20 for outputting a control signal of a DC voltage having a variable level according to the determined mode, and a current supply unit 30 for limiting a current flowing through the correction coil unit 1 according to the control signal. By changing the current flowing in the correction coil part in accordance with the change of the frequency supported by the monitor, as a result, the right and left symmetry of the screen width can be accurately matched in any mode by flowing the appropriate current strength to the horizontal deflection coil in the entire series-parallel resonance circuit. Horizontal linearity can be maintained.

Description

A circuit of controlling a horizontal linearity in a multi-mode monitor

The present invention relates to a horizontal linearity adjusting circuit, and in particular, in a multi-mode monitor, the current flows through the current correction coil in accordance with the horizontal frequency for each mode. It relates to a horizontal linearity adjustment circuit of a multi-mode monitor which is adapted to be precise.

In general, a multimode monitor reproduces a video image in accordance with a signal received from a video card in a computer, which requires adjustment of each part of the circuit according to the timing parameter of the received signal. Here, look at the classification of the monitor according to the video mode through Table 1.

TABLE 1

As shown in Table 1, the horizontal and vertical frequencies are different according to the modes supported by the video card, and in particular, the video card supporting various modes, for example, a video card supporting VGA, SVGA, and high resolution only modes, is mounted on the monitor. If so, the range of the horizontal frequency of each mode is about 30 to 75 kHz.

That is, when the mode is changed in the multi-mode monitor, there are parts that need to be changed in the internal circuits of the monitor. For example, image size and position change, horizontal / vertical synchronization and deflection optimization, and various deflection corrections. The circuit must be readjusted. In particular, readjustment of the deflection correction circuit is very important in relation to the linearity of the screen.

On the other hand, looking at the principle of deflection of a general monitor, electrons emitted from the cathode of the monitor are accelerated through the grid, and move the light spot of the fluorescent surface by changing the course by the electromagnetic action of the magnetic field of the deflection coil.

At this time, the deflection distance is proportional to the strength of the magnetic field, and the magnetic field is proportional to the current of the deflection coil, so that the monitor scans at a constant speed from left to right and returns very quickly from right to left. To this end, a horizontal deflection coil for moving the light spot in the horizontal direction (left and right) and a vertical deflection coil for moving the light spot in the vertical direction (up and down) are used.

When a current flows through the deflection coil, an electromagnetic force acts to bend the path of the straight electron beam, which depends on the direction and magnitude of the current flowing through the deflection coil.

In other words, when a sawtooth wave current as shown in Fig. 1 flows through the horizontal deflection coil, a force acting to deflect the electron beam to the leftmost direction at the point a, and at the point b, the electron beam moves straight because no current flows. From point b to point c, the current that causes the electron beam to bend to the right gradually increases, and at point c, the electron beam is deflected to the right, and then the current rapidly decreases and repeats from point a.

Next, the deflection circuit operation of the general monitor will be briefly described with reference to the horizontal deflection circuit of FIG.

The horizontal synchronizing signal H.sync output from the video card is appropriately signal-modulated from the horizontal oscillation IC to the horizontal driving signal H.drive and supplied to the horizontal driving transistor TR1. The horizontal driving signal H.drive turns on the horizontal driving transistor TR1 and supplies current to the base terminal of the horizontal output transistor TR2 through the horizontal driving transformer HDT.

When the horizontal output transistor TR2 is turned on by receiving sufficient base current, the B ⁺ power supply current of the flyback transformer FRT flows to the horizontal output transistor TR2 through the horizontal deflection coil HD.Y.

In this way, while the horizontal output transistor TR2 is turned on, it corresponds to the second half of the effective scanning period of the horizontal sawtooth wave, and then the horizontal deflection coil is rapidly turned off according to the horizontal drive signal H.drive. The current accumulated in (HD.Y) charges the retrace capacitor (RE.C).

When the retrace capacitor RE.C is fully charged, it is discharged back to the horizontal deflection coil HD.Y, and thus current is accumulated in the horizontal deflection coil HD.Y. As a result, the retrace period is determined between the charging and discharging of the retrace capacitor RE.C.

When energy is accumulated in the horizontal deflection coil HD.Y and the deflection coil voltage reaches a degree of applying a forward bias to the damper diode D, the damper diode D is turned on and flows through the deflection coil HD.Y. The current drops to zero. At this time, the current flowing through the damper diode D corresponds to the first half of the effective scanning period of the horizontal sawtooth wave.

As described above, when the current becomes zero, the horizontal output transistor TR2 is turned on again by the horizontal drive signal H. drive, and the sawtooth current flows through the horizontal deflection coil HD.Y while repeating the above process. A horizontal deflection is made and a horizontal scan is made.

At this time, in order to correct the horizontal linearity of the screen, a monitor generally includes a horizontal linearity adjusting circuit 100.

That is, horizontal frequency per mode

As the scan interval narrows, the scan interval narrows to one end of the fluorescent surface, resulting in a misalignment of the horizontal width. Therefore, the correction coils L1 and L1 + L2 are connected in series with the horizontal deflection coil HD.Y to change the inductance value according to the mode so that the horizontal width is symmetrical.

As shown in FIG. 2, after the microcomputer receives the horizontal synchronization signal to determine the mode, the microcomputer outputs a correction coil selection signal according to the determined mode, and selectively performs on / off operation according to the selection signal. The relay selects the correction coils L1 and L1 + L2, the resistors R4 and R5 and the capacitors C2 and C3 to change the strength of the current flowing through the deflection coil HD.Y. Match symmetry

However, the conventional horizontal linearity adjusting circuit is composed of a three-terminal relay and two coils (L1, L2). When the reference frequency is lower than the reference frequency based on the intermediate frequency of the horizontal frequency, the coil L1 is selected and the reference frequency is selected. Since the coil L2 is selected when the error is abnormal, there is a problem in that a proper mode linearity cannot be maintained when the mode is changed in a multi-mode monitor with frequent horizontal frequency fluctuations.

The present invention is designed to solve the above problems, and by adjusting the current flowing through the correction coil connected in series with the horizontal deflection coil for each mode, the horizontal width is symmetrically symmetrical. The purpose is to provide a linearity adjusting circuit.

The horizontal linearity adjustment circuit of the multi-mode monitor of the present invention for achieving the above object is connected in series to the horizontal deflection coil, and a correction code for adjusting the left and right deflection of the electron beam by issuing a magnetic field according to the magnitude of the flowing current. In part, the control unit may be configured to output a control signal of a DC voltage having a variable level according to the determined mode, and a current supply unit to limit a current flowing in the correction coil unit according to the control signal.

That is, by connecting the correction coil in series with the horizontal deflection coil to change the magnitude of the current flowing through the correction coil according to the mode determined by the control unit to match the left and right symmetry of the screen horizontal width.

1 is a graph showing the sawtooth wave current supplied to the horizontal deflection coil,

2 is a circuit diagram showing a horizontal linearity adjusting circuit of a general monitor;

3 is a circuit diagram showing a horizontal linearity adjusting circuit of the multi-mode monitor according to the present invention.

* Explanation of symbols for main parts of the drawings

1: horizontal deflection circuit 10: correction coil part

20: control unit 30: current supply unit

H.TR: Horizontal Output Transistor D.D: Damper Diode

RE.C: Return capacitor H.DY: Horizontal deflection coil

FBT: Flyback Transformer T: Transformer

OP1, 2: first and second op amp TR: transistor

D1, 2: diodes C1 to C5: capacitors

R1 to R11: resistance

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

As shown in FIG. 3, the horizontal linearity adjusting circuit of the multi-mode monitor according to the present invention has a horizontal deflection circuit 1, a horizontal deflection coil HD.Y and a flyback transformer FBT. And a correction coil unit 10, a control unit 20, and a current supply unit 30.

Here, the correction coil unit 10 is a transformer T in which a primary winding is connected between the current supply unit 30 and a ground, and a secondary winding is connected between a horizontal deflection coil HD.Y and a ground. It is.

In addition, the control unit 20 detects the B ⁺ voltage of the flyback transformer (FBT), compares it with an internal reference voltage, and outputs a control signal.

In addition, the current supply unit 30 has a base terminal receives a control signal from the control unit 20, the collector terminal is connected to the power supply voltage (12V), the emitter terminal is connected to the primary winding of the transformer (T) It consists of the transistor TR.

Next, the operation and effects of the apparatus according to the present invention configured as described above are as follows.

As shown in FIG. 3, the control unit 20 is composed of a first OP amplifier OP1 and a second OP amplifier OP2, and the resistors R5 and R6 are applied to the B ⁺ voltage which is most sensitive to the horizontal frequency change. After the voltage drop is appropriately set, the reference voltage of the second OP amplifier OP2 is set.

In other words, when the horizontal frequency increases, the scan interval is narrowed, so that much B ⁺ voltage is consumed. Accordingly, the degree of change in the horizontal frequency can be measured by sensing the B ⁺ voltage.

Accordingly, the power supply voltage 24V is appropriately voltage-dropped through the diode D1, the capacitor C1, and the resistors R1, R2, and R3 to be input to the positive input terminal of the first OP amplifier OP1 and the first OP. By feedbacking the output voltage of the amplifier OP1 to the negative input terminal, the input voltage is buffered through the first OP amplifier OP1, and then the output voltage of the first OP amplifier OP1 is output through the resistor R4. 2 Input it to the negative input terminal of the OP amplifier OP2 and use it as the reference voltage of the second OP amplifier OP2.

Accordingly, the second OP amplifier OP2 compares the reference voltage with the B ⁺ voltage, and determines the output voltage by comparing how large or how small the B ⁺ voltage with respect to the reference voltage.

Since the output voltage of the second OP amplifier OP2 is applied to the base terminal of the transistor TR, the magnitude of the base current of the transistor TR varies according to the B ⁺ voltage. For example, when the B ⁺ voltage is greater than the reference voltage, the output voltage of the second OP amplifier OP2 is smaller than during normal operation because the B ⁺ voltage is larger than the reference voltage.

As a result, the base current supplied to the base of the transistor TR decreases, and thus the collector current decreases, and the current flowing through the primary winding of the transformer T also decreases. Becomes smaller. That is, the higher the horizontal frequency, the more the current flowing through the correction coil unit 10 is reduced than during normal operation, thereby correcting the horizontal linearity to accurately match the left and right symmetry of the horizontal width.

On the contrary, when the horizontal frequency is low, the output voltage of the second OP amplifier OP2 is larger than that in the normal operation because B ⁺ voltage is smaller than the reference voltage, so that the base current supplied to the base terminal of the transistor TR becomes larger and thus the transformer ( The current induced in the secondary winding of T) becomes larger than during normal operation. That is, as the horizontal frequency is lowered, the current flowing through the correction coil unit 10 is increased than in normal operation, so that the left and right symmetry of the horizontal width can be accurately matched.

At this time, the resistors R7 and R8 prevent the second OP amplifier OP2 from being cleared when the B ⁺ voltage, which is the ^positive input voltage of the second OP amplifier OP2, is zero (0), thereby preventing the transistor TR. To protect. Resistor R9 and capacitor C4 are also used as circuit protection devices.

As described above, according to the present invention, the current flowing in the correction coil part is changed in accordance with the change of the frequency supported by the multi-mode monitor, and as a result, a mode current is transmitted to the horizontal deflection coil in a suitable parallel strength parallel circuit. Even in the horizontal horizontal symmetry of the screen can be accurately matched to maintain the horizontal linearity.

Claims (2)

A correction coil unit 10 connected in series to the horizontal deflection coil HD.Y to generate a magnetic field according to the magnitude of the flowing current to adjust the left and right deflection of the electron beam; A control unit 20 for detecting a B ⁺ voltage of the flyback transformer FBT and outputting a control signal of a DC voltage whose level is variable according to a mode determined by comparing with a predetermined reference voltage; And a current supply unit 30 for limiting a current flowing through the correction coil unit 10 according to a control signal, wherein the correction coil unit 10 has a primary winding connected between the current supply unit 30 and the ground. And a secondary winding having a transformer connected between the horizontal deflection coil and ground, wherein the control unit 20 has a power supply voltage 24V input to a positive input terminal and an output voltage negative input terminal. A first OP amplifier OP1 fed back into; And a second output voltage of the first OP amplifier OP1 is input to a negative input terminal, a B ⁺ voltage is input to a positive input terminal, and an output voltage is supplied as a control signal of the current supply unit 30. Horizontal linearity adjustment circuit of a multi-mode monitor, characterized by comprising an OP amplifier (OP2). According to claim 1, wherein the current supply unit 30, the base terminal receives a control signal from the control unit 20, the collector terminal is connected to the power supply voltage (12V), the emitter terminal of the transformer (T) A horizontal linearity adjustment circuit of a multi-mode monitor, characterized by comprising a transistor (TR) connected to a primary winding.