KR0146220B1 - The horizontal deflection circuit of monitor - Google Patents

Abstract

The present invention implements a horizontal deflection protection circuit that operates for a predetermined period of time after the mode conversion in the MOS switching stage of the horizontal deflection circuit, in order to prevent a defect in the horizontal deflection circuit of the monitor due to the abnormal overcurrent generated during the mode conversion, The present invention relates to a method of turning on transistors by applying a constant voltage to the gates of all MOS transistors of a mode switching stage, thereby allowing an abnormal overcurrent to be evenly distributed through a capacitor connected to the transistor.

Description

Horizontal deflection circuit of the monitor

1 is a circuit diagram showing a horizontal deflection circuit of a conventional monitor.

2 is a circuit diagram showing a horizontal deflection circuit including a horizontal deflection protection circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

11: horizontal drive stage 12: horizontal output stage

13 mode switching stage 14 horizontal deflection protection circuit

The present invention provides a monitor for displaying information on a screen at various resolutions, in order to prevent defects in the elements constituting the horizontal deflection circuit due to the inflow of instantaneous current generated when the resolution of the monitor is converted as necessary. The horizontal deflection protection circuit implemented.

In recent years, as the demand for multimedia that satisfies various functions with a single computer is rapidly increasing, not only a computer body but also peripheral devices are being developed to display still images and moving images having high resolution. Among them, a monitor having various resolution characteristics for displaying information efficiently according to a user's request is widely used.

In general, a monitor is an electron beam whose vertical or horizontal movement path is determined by an electric field, and stimulates a fluorescent material applied to a display plate, which is one end of a Cathode-Ray Tube (CRT). The R (Red; Red), G (Green; Green), B (Blue; Blue) signals, which represent the color transmitted from the main body, are used to recognize the output of the signal. When moved by the electron beam is carried together with the electron beam to stimulate the corresponding color material on the display panel to provide a clear color screen.

In order to deflect horizontally, especially in the path of movement of the electron beam, a circuit for inducing an electromagnetic field when the electron beam is emitted from one end of the cathode ray tube is required, which is called a horizontal deflection circuit and is implemented on the main board of the monitor The resolution characteristic is influenced by the frequency characteristic of the current signal output from the horizontal deflection circuit. That is, as the frequency of the output increases, scan lines corresponding to the corresponding frequencies (phenomena caused by the collision of electron beams) are generated on the display panel, so that a clearer screen can be expected, and when the frequency of the output decreases, the density of the corresponding scan lines decreases on the contrary. Falls.

However, since the word processor does not actually require high resolution among the tasks performed using the computer, the high resolution is required for the graphic work, and therefore, horizontal signals of various sizes are input from the computer main body to the monitor screen controller as needed. Adjust the resolution on the monitor.

Changing the frequency of the horizontal deflection signal output by the horizontal signal is called mode conversion, and one monitor is designed to automatically perform mode conversion depending on whether it is performing word processing or graphic work. Therefore, at least 20 Hz to 86 Hz can be compatible depending on the characteristics of each signal.

However, when the mode is shifted from a low frequency band to a high frequency band or a mode change from a high frequency band to a low frequency band, the system itself may become unstable, which may cause an unexpected situation, which is usually necessary for circuits involved in mode change. Instantaneous currents of magnitude higher than the current may be applied, causing serious defects in the components of the circuit.

FIG. 1 is a horizontal deflection circuit which is a circuit for outputting a horizontal deflection signal, which is one of circuits susceptible to overcurrent caused by mode switching.

In general, a horizontal deflection circuit for controlling the horizontal movement of the electron beam is connected to a horizontal drive end 11 and the horizontal drive end 11, as shown in FIG. 1, and a horizontal output end that actually outputs a horizontal deflection signal. And a signal CS0, CS1, CS2, CS3, and CS4 connected to the horizontal output terminal 12 to detect a mode change and output from the microprocessor unit (not shown) according to the corresponding mode. The mode switching stage 13 in which the operation is controlled is included.

The microprocessor unit is implemented on the main board of the monitor and serves as a center for controlling all functions related to the operation of the monitor by receiving vertical and horizontal signals transmitted from the computer main body.

The operation of each of the parts is first converted into a signal having a constant frequency while passing through a horizontal oscillator (not shown), the pulse width modulation signal transmitted from the computer main body through the microprocessor unit, and then the signal is The bipolar transistor Q1 of the output terminal 12 is operated by being converted back into a triangular wave having a current characteristic through the horizontal driving stage 11. Since the magnitude of the current flowing in the horizontal coil DY changes with time according to the signal applied to the base, the transistor Q1 induces an electric field around the coil DY due to various characteristics of the coil. The electron beam passing through the cathode ray tube is deflected horizontally by the electric field.

As described above, the electric field is induced around the coil DY of the horizontal output terminal 12, but the microprocessor that detects this when the mode is changed by changing the magnitude of the horizontal signal transmitted from the main body to adjust the resolution of the monitor. The mode switching stage 13 adjusts the load of the horizontal output stage 12 by a combination of signals CS0, CS1, CS2, CS3, and CS4 output from the negative portion.

The combination of the mode change detection signals CS0 to CS4 according to the frequency of each mode is shown in detail in Table 1, and the operation of the mode switching stage 13 related thereto will be described with reference to Table 2.

The structure of the mode switching stage 13 is a pair of resistance components R1 and R6, R2 and R7, R3 and R8, R4 and R9, which distribute the voltage of the signal at an appropriate ratio when the signals CS0 to CS4 transmitted from the microprocessor are applied. Some or all of the MOS transistors T1, T2, T3, T4, and T5 are operated by R5 and R10 so that the capacitor components C1, C2, C3, C4, and C5 connected to the MOS transistors can function properly. As a result, it acts as a load having a parallel structure with CS, which is a capacitor rod of the horizontal output terminal 12.

For example, in the case of each mode, first, when the horizontal deflection frequency fh leaked from the horizontal signal is less than 27 Hz, the signals CS0 to CS4 are all applied in a high state to turn all of the MOS transistors T1 to T5. Turn on so the capacitor load on the horizontal output stage

CT = CS + C1 + C2 + C3 + C4 + C5

Becomes On the other hand, when the horizontal deflection frequency (fh) is 70 Hz or more, the signals CS0 to CS4 are all applied in a low state to turn off all of the MOS transistors T1 to T5, so that the capacitor load of the horizontal output stage is applied. Is just CT = CS.

If the frequency is all present between 27 kHz and 70 kHz, the operation is performed as shown in Tables 1 and 2 above.

By varying the capacitor load of the horizontal output stage 12 in accordance with the horizontal deflection frequency by using the mode switching stage 13, a high pressure is not applied to the capacitor at the high frequency, but at a low frequency. This is to obtain the effect of distributing the current using multiple capacitors because the capacitor is subjected to considerable pressure when a high current is applied to one capacitor.

Tables 1 and 2 exemplify cases in which the monitor is compatible with at least 20 Hz to 86 Hz, as described above. The capacitor load portion of the mode switching stage 13 shown in FIG. The number of can be adjusted.

However, when the mode switching stage 13 is operated as described in Tables 1 and 2 with the structure as shown in FIG. 1, the abnormal instantaneous current that occurs at the moment when the mode is changed generally occurs in the horizontal output stage 12. When applied to the mode switching stage 13 through the rod portion, there is a problem that the elements constituting the mode switching stage 13 are destroyed to cause serious defects in the circuit.

Accordingly, an object of the present invention is to implement a horizontal deflection protection circuit that operates for a certain period of time during mode switching, thereby preventing defects occurring in the horizontal deflection circuit due to an instantaneous overcurrent applied during mode switching.

In order to achieve the above object, in the present invention, by turning on the transistors by applying a constant voltage to the gates of all MOS transistors of the mode switching stage for a certain period during the mode conversion, the abnormal overcurrent is evenly distributed through the capacitor connected to the transistor. To be dispensed.

The horizontal deflection protection circuit for applying a constant voltage to the MOS transistor is connected to a bipolar transistor which is operated by receiving a signal causing a state change for a predetermined period at the time of mode conversion from the microprocessor unit, and the emitter terminal of the bipolar transistor. And a diode component for applying a voltage to the gate of each transistor of the mode switching stage by constantly reducing the voltage applied through the bipolar transistor, and each load added to facilitate operation of a circuit composed of the bipolar transistor and the diode component. Contains ingredients

Hereinafter, the present invention will be described in detail with reference to the attached second drawings and Tables 1 and 2 above.

The basic circuits constituting the horizontal deflection circuit are the same as those shown in FIG. 1, and the operation of the mode switching stage 13 after the normal mode conversion is as described with Tables 1 and 2, and therefore, the operation according to the present invention will be described below. I will mainly mention the differences in configuration.

In the configuration of the horizontal deflection protection circuit 14 according to the present invention, the microprocessor unit output signal MCS transmitted through the resistance component R11 is applied to the base N3 to control its operation, and the collector is operated at a high voltage. A bipolar transistor Q11 to which Vc is applied, a resistor component R12 and a capacitor component C11 implemented between the emitter node N2 and the ground voltage of the transistor Q11 to serve as a load, and The resistor component R13 connected between the node N2 and the node N1 and the diode component D1 connected to the gates of the MOS transistors T1 to T5 of the mode switching terminal 13 at the node N1. To D5).

Since the signal MCS applied to the horizontal deflection protection circuit 14 is output in a low state when the horizontal deflection circuit is normally operated, the MOS switching stage 13 is turned off by turning off the bipolar transistor Q11. It works the same as described in Tables 1 and 2. On the other hand, since the signal MCS is output in a high state for a certain period of time that the mode is switched, the transistor Q11 is turned on, so that the high voltage Vc is transmitted through the diode components D1 to D5. The gates of the MOS transistors T1 to T5 of the mode switching stage 13 are applied to turn on all of the transistors T1 to T5 while the signal MCS is kept high.

The signal MCS transmitted from the microprocessor unit is controlled by the microprocessor unit to maintain the enabled high state unconditionally for a period of time during which the screen is stabilized after the mode is changed regardless of the frequency.

Since the horizontal deflection protection circuit does not operate after the instantaneous overcurrent disappears after a certain period of time to stabilize the screen, the horizontal deflection circuit operates normally as described in FIG. 1.

Therefore, when the monitor operation is controlled by including the horizontal deflection protection circuit according to the present invention in the horizontal deflection circuit, it is possible to prevent the elements constituting the circuit from being destroyed due to the overcurrent generated during the mode conversion. Even if the system becomes unstable, the operation of the horizontal deflection circuit that controls the horizontal movement of the electron beam moving in the cathode ray tube maintains a stable operation regardless of the mode change, and thus the overall operation of the monitor can be stabilized. There is an effect that can use the computer without recognizing the unstable state of the screen.

Claims (3)

A horizontal drive stage for outputting a triangular wave of a current characteristic, a horizontal output stage for receiving a triangular wave that is an output of the horizontal drive stage and inducing an electromagnetic field to the coil, and a capacitor rod portion of the horizontal output stage, A mode switching stage for connecting capacitor components of various sizes in parallel to the rod portion so as to distribute the current transmitted from the output stage, and a current applied through the horizontal output stage for a certain period of time during which the screen is stabilized after mode conversion. And a horizontal deflection protection circuit for operating all switching elements of the mode switching stage for a predetermined period to be distributed to each capacitor component of the mode switching stage. 2. The horizontal deflection protection circuit of claim 1, wherein the horizontal deflection protection circuit is turned on by a signal that maintains an enabled state for a period of time at the time of mode conversion, and is connected to a transfer transistor for applying a high voltage to a next stage; And a diode component for applying a turn-on voltage to each switching element of the mode switching stage by constantly depressurizing a voltage applied through the transfer transistor, and smoothly operating a circuit composed of the transfer transistor and the diode component. A horizontal deflection circuit of the monitor, characterized in that it comprises a rod component added for the purpose. The horizontal deflection circuit of a monitor according to claim 2, wherein a signal for maintaining an enabled state for a predetermined period of time at the time of mode conversion is applied from a microprocessor unit which controls the overall operation of the monitor.