JPH11136534A - Power control method for horizontal deflection circuit, horizontal deflection circuit and display monitor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power control method of a horizontal deflection circuit, which can reduce transient overvoltage generated in a horizontal output circuit at the time of supplying power and at the time of switching the frequency of a horizontal synchronizing signal. SOLUTION: When the power of a display monitor using CRT is supplied (S10), a +B voltage generation circuit generating +B power voltage is started with generation voltage lower than that at the time of a regular operation (S16). A horizontal oscillation circuit is started at a horizontal oscillation frequency higher than that at the time of the regular operation (S18). Then, the generation voltage of the +B voltage generation circuit is boosted to that at the time of the regular operation (S24) after first prescribed time passes (S22). Then, the horizontal oscillation frequency of the horizontal oscillation circuit is dropped to that at the time of the regular operation (S30) after second prescribed time passes (S28).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power control method for a horizontal deflection circuit in a display monitor using a CRT (cathode ray tube), a horizontal deflection circuit for implementing the power control method, and a display monitor having the horizontal deflection circuit. Things.

[0002]

2. Description of the Related Art The configuration of a display monitor having a CRT used for a computer, a television, or the like is, for example, as shown in a block diagram of FIG. The display monitor is a computer display, and the computer 5 controls the color signals R, G, B, the horizontal synchronization signal _Hsync, and the vertical synchronization signal V
_{The sync} is output to the display monitor 1. Color signal R,
G and B are applied to the video circuit 25 and amplified, and the CRT
26. In the CRT 26, the color signals R, G, B
Is an electron beam corresponding to each intensity.

The horizontal synchronization signal _Hsync is _supplied to a microprocessor 11 and a horizontal oscillator 12 of the horizontal deflection circuit 2. The microprocessor 11 _{supplies the} horizontal oscillator 12 with a voltage F / V corresponding to the horizontal synchronization signal _Hsync to the horizontal oscillator 12.
A signal + B _cont for generating a + B voltage according to _sync is applied to the + B voltage generation circuit 18. Horizontal oscillator 1
2 is a frequency corresponding to the applied voltage F / V, and is a horizontal oscillation frequency signal H having the same phase as the horizontal synchronization signal _Hsync.
OSC is output and supplied to the horizontal drive circuit 13. The horizontal drive circuit 13 outputs a horizontal oscillation frequency signal HO of a rectangular wave.
The SC is amplified and applied to the base of the horizontal output transistor 14a of the horizontal output circuit 14.

A horizontal output circuit 14 has a horizontal output transistor 14a whose emitter is grounded, and an anode whose ground is grounded.
A cathode has a damper diode 14b connected to the collector of the horizontal output transistor 14a, and a resonance capacitor 14c connected in parallel to the damper diode 14b, and creates a sawtooth wave from the horizontal oscillation frequency signal HOSC to generate horizontal deflection. This is given to the coil 15. The horizontal deflection coil 15 is connected to an S-shaped correction capacitor 17 whose other end is grounded. The sawtooth wave applied to the horizontal deflection coil 15 scans the CRT 26 horizontally, and is boosted by a horizontal output transformer 16 (flyback transformer) using the retrace period (the voltage change rate is large). The boosted pulse is applied to the high voltage circuit 24 and the + B voltage generation circuit 18.

The high voltage circuit 24 converts the applied pulse into a DC high voltage by a voltage doubler rectifier circuit or the like, and applies the DC voltage to the anode of the CRT 26. The + B voltage generation circuit 18 converts the applied pulse into a DC voltage by a voltage doubler rectifier circuit or the like, and supplies the DC voltage as a power source to the heater of the CRT 26, the video circuit 25, the horizontal deflection circuit 2, and other circuits.

The vertical synchronization signal _Vsync is applied to a vertical deflection circuit 23. In the vertical deflection circuit 23, the vertical synchronization signal V
_The saw-tooth waveform is driven by the _sync , and the created saw-tooth waveform is applied to a vertical deflection coil (not shown) of the CRT 26 to scan the CRT 26 vertically.

[0007]

In the above-mentioned conventional display monitor, when the power is turned on, the starting time of each circuit is not controlled, so that each circuit starts all at once. Especially,
CRT 26 heater, video circuit 25, horizontal deflection circuit 2
Since the + B voltage and the horizontal oscillation frequency signal HOSC supplied as power for the other circuits rise immediately after the power is turned on, as shown in FIG. 7B, a pulse generated between the collector and the emitter of the horizontal output transistor 14a. In some cases, the voltage Vcp rises significantly and internal circuits such as the horizontal output transistor 14a are destroyed.

As a technique for controlling power-on, a technique of turning on the power of a DC power supply circuit a predetermined time after a microcomputer judges the power-on is described in Japanese Patent Laid-Open No. 7-7497.
Japanese Patent Application Laid-Open No. 8-289223 discloses a technique for gradually increasing the contrast from a value lower than a normal value in a transient state after turning on the power. The present invention has been made in view of the above-described circumstances, and a power supply control method for a horizontal deflection circuit that can reduce a transient overvoltage generated in a horizontal output circuit when power is turned on and when a frequency of a horizontal synchronization signal is switched. ,
It is an object of the present invention to provide a horizontal deflection circuit for implementing the power supply control method and a display monitor having the horizontal deflection circuit.

[0009]

According to a first aspect of the present invention, there is provided a method of controlling a power supply of a horizontal deflection circuit, which comprises a + B voltage generating circuit for generating a + B power supply voltage when a display monitor using a CRT is turned on. Starting at a lower generated voltage than at the time of operation, and starting the horizontal oscillation circuit at a higher horizontal oscillation frequency than at the time of normal operation;
The voltage generated by the voltage generation circuit is increased to a voltage during normal operation, and the horizontal oscillation frequency of the horizontal oscillation circuit is reduced to a frequency during normal operation after a second predetermined time.

A power supply control method for a horizontal deflection circuit according to a second aspect of the present invention is a method for generating a + B power supply voltage at a third predetermined time after a display monitor using a CRT is turned on.
The voltage generation circuit is started at a lower generation voltage than during normal operation, and the horizontal oscillation circuit is started at a higher horizontal oscillation frequency than during normal operation.
The voltage generated by the voltage generation circuit is increased to a voltage during normal operation, and the horizontal oscillation frequency of the horizontal oscillation circuit is reduced to a frequency during normal operation after a second predetermined time.

In the power supply control method for a horizontal deflection circuit according to a third aspect of the present invention, after the frequency of the horizontal synchronizing signal of the display monitor using the CRT is lowered, a fourth predetermined time later, + B
A voltage generated by a + B voltage generation circuit for generating a power supply voltage is reduced to a voltage corresponding to the reduced frequency, and further, after a fifth predetermined time, a horizontal oscillation frequency of the horizontal oscillation circuit is reduced to the reduced frequency. It is characterized by.

The power supply control method for a horizontal deflection circuit according to a fourth aspect of the present invention is the method of controlling the horizontal oscillation frequency of the horizontal oscillation circuit after a sixth predetermined time after the frequency of the horizontal synchronization signal of the display monitor using the CRT increases. The frequency is increased to the increased frequency, and further, after a seventh predetermined time, the voltage generated by the + B voltage generating circuit for generating the + B power supply voltage is increased to a voltage corresponding to the increased frequency.

A horizontal deflection circuit according to a fifth aspect of the present invention includes a detecting means for detecting that the power of a display monitor using a CRT is turned on, and a detecting means for detecting that the power is turned on. Means for starting a + B voltage generation circuit for generating a + B power supply voltage at a lower generation voltage than during normal operation; and, when the detecting means detects that the power is turned on, the horizontal oscillation circuit is set to a higher voltage than during normal operation. Means for starting at a horizontal oscillation frequency, means for counting a first predetermined time after the means has started the horizontal oscillation circuit, and means for counting the first time when the means has counted the first predetermined time.
Means for raising the generated voltage of the voltage generating circuit to the voltage at the time of normal operation, and after the means raises the generated voltage to the voltage,
Means for measuring a second predetermined time, and means for lowering the horizontal oscillation frequency of the horizontal oscillation circuit to a frequency during normal operation when the means has measured the second predetermined time. .

A horizontal deflection circuit according to a sixth aspect of the present invention comprises a detecting means for detecting that a display monitor using a CRT is turned on, and a detecting means for detecting that the power is turned on. A timer for measuring a third predetermined time; and + B when the timer measures a third predetermined time.
Means for starting a + B voltage generating circuit for generating a power supply voltage at a lower voltage than during normal operation;
Means for starting the horizontal oscillation circuit at a higher horizontal oscillation frequency than at the time of normal operation when the predetermined time is counted, means for counting a first predetermined time after the means starts the horizontal oscillation circuit, Means for increasing the generated voltage of the + B voltage generating circuit to a voltage for normal operation when the means has counted a first predetermined time; and a second predetermined means for increasing the generated voltage to the voltage during normal operation. Means for timing the time;
Means for lowering the horizontal oscillation frequency of the horizontal oscillation circuit to the frequency at the time of normal operation when the predetermined time is measured.

A horizontal deflection circuit according to a seventh aspect of the present invention includes a means for detecting a frequency of a horizontal synchronization signal of a display monitor using a CRT, a comparing means for comparing the frequencies detected by the means in time series, Means for measuring a fourth predetermined time when the frequency decreases as a result of the comparison by the means, and a voltage generated by a + B voltage generating circuit for generating a + B power supply voltage when the means measures the fourth predetermined time Means for reducing the voltage to a voltage corresponding to the reduced frequency, means for measuring a fifth predetermined time after the means reduces the generated voltage to the voltage, and means for measuring a fifth predetermined time Means for lowering the horizontal oscillation frequency of the horizontal oscillation circuit to the lowered frequency when the time is measured.

According to an eighth aspect of the present invention, there is provided a horizontal deflection circuit comprising: means for measuring a sixth predetermined time when the frequency is increased as a result of comparison by the comparing means; Means for increasing the horizontal oscillation frequency of the horizontal oscillation circuit to the increased frequency; means for measuring a seventh predetermined time after the means has increased the horizontal oscillation frequency to the frequency; When the predetermined time of 7 is counted, +
Means for increasing the voltage generated by the B voltage generation circuit to a voltage corresponding to the increased frequency.

A display monitor according to a ninth aspect is provided with the horizontal deflection circuit according to any one of claims 5 to 8.

[0018]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment 1 FIG. Hereinafter, the present invention will be described with reference to the drawings showing the embodiments. FIG. 1 is a block diagram showing a configuration of a first embodiment of a power control method for a horizontal deflection circuit, a horizontal deflection circuit, and a display monitor according to the present invention.
The display monitor 1a is a computer display, and the computer 5 outputs the color signals R, G, B, the horizontal synchronization signal _Hsync, and the vertical synchronization signal _Vsync of each pixel constituting the image to the display monitor 1a. The color signals R, G, B are provided to the video circuit 25 and amplified,
Input to the CRT 26. In the CRT 26, the color signals R,
G and B are electron beams corresponding to the respective intensities.

The horizontal synchronization signal _Hsync is _supplied to the horizontal deflection circuit 2a.
, A microprocessor 11a and a horizontal oscillator 12. The microprocessor 11a outputs the horizontal synchronization signal H
A signal + B for generating a voltage F / V according to _sync to the horizontal oscillator 12 and generating a + B voltage according to the horizontal synchronization signal _Hsync
cont is applied to the + B voltage generation circuit 18 respectively. The horizontal oscillator 12 has a frequency corresponding to the applied voltage F / V,
Phase outputs a horizontal oscillation frequency signal HOSC the same as the horizontal synchronizing signal H _sync, applied to the horizontal drive circuit 13. The horizontal drive circuit 13 amplifies the horizontal oscillation frequency signal HOSC of the rectangular wave and supplies the amplified signal to the base of the horizontal output transistor 14a of the horizontal output circuit 14.

The horizontal output circuit 14 has a horizontal output transistor 14a whose emitter is grounded, and an anode whose ground is grounded.
A cathode has a damper diode 14b connected to the collector of the horizontal output transistor 14a, and a resonance capacitor 14c connected in parallel to the damper diode 14b, and creates a sawtooth wave from the horizontal oscillation frequency signal HOSC to generate horizontal deflection. This is given to the coil 15. The horizontal deflection coil 15 is connected to an S-shaped correction capacitor 17 whose other end is grounded. The sawtooth wave applied to the horizontal deflection coil 15 scans the CRT 26 horizontally, and is boosted by a horizontal output transformer 16 (flyback transformer) using the retrace period (the voltage change rate is large). The boosted pulse is applied to the high voltage circuit 24 and the + B voltage generation circuit 18.

The high voltage circuit 24 converts the applied pulse into a DC high voltage by a voltage doubler rectifier circuit or the like, and applies the high voltage to the anode of the CRT 26. The + B voltage generation circuit 18 converts the applied pulse into a DC voltage by a voltage doubler rectifier circuit or the like, and supplies the DC voltage as a power source to the heater of the CRT 26, the video circuit 25, the horizontal deflection circuit 2, and other circuits. Microprocessor 11a, horizontal oscillator 12, horizontal drive circuit 1
3. The horizontal output circuit 14 and the + B voltage generation circuit 18 constitute a horizontal deflection circuit 2a.

The vertical synchronization signal _Vsync is _supplied to a vertical deflection circuit 23. In the vertical deflection circuit 23, the vertical synchronization signal V
_The saw-tooth waveform is driven by the _sync , and the created saw-tooth waveform is applied to a vertical deflection coil (not shown) of the CRT 26 to scan the CRT 26 vertically. The power supply circuit 6 supplies power to each circuit of the display monitor 1a when an internal power switch circuit (not shown) is turned on from the outside.

The horizontal deflection circuit 2 when the power is turned on in the display monitor 1a having such a configuration and operation will be described below.
The operation of a will be described with reference to the flowchart of FIG. The pulse voltage Vcp generated between the collector and the emitter of the horizontal output transistor 14a is as shown in the following (1).
It is known to be represented by an equation. Vcp = + B [(π / 2) ｛(ths / π (LC) ^1/2 ) −1} +1] (1) where: + B; output voltage of + B voltage generation circuit L; The combined impedance of the horizontal output transformer 16 C; the capacitance of the resonance capacitor 14c ths; the period of the horizontal oscillation frequency signal HOSC

In a transitional state such as when the power is turned on,
When + B and ths in the equation (1) are not controlled, the pulse voltage Vcp rises abnormally, and the horizontal output transistor 1
4a may be destroyed by a transient overvoltage. However, from equation (1), to lower the pulse voltage Vcp,
It can be seen that it is sufficient to lower the + B voltage and lower the ths (increase the horizontal oscillation frequency).

The microprocessor 11a includes a power supply circuit 6
When the power switch circuit is turned on in (S1
0), time measurement is started (S12), and when, for example, 0.5 seconds is measured (S14), a signal for setting the + B voltage to a minimum value +
B _cont is output, and as shown in FIG. 3B, the + B voltage generation circuit 18 starts to output the lowest + B voltage (S16). Further, a voltage F / V for setting the horizontal oscillation frequency signal HOSC to the highest frequency is output, and the horizontal oscillator 12 starts outputting the highest frequency horizontal oscillation frequency signal HOSC as shown in FIG. (S18).

When the microprocessor 11a outputs the voltage F / V for setting the frequency signal HOSC to the highest frequency (S18), it starts timing (S20).
When 0 seconds are counted (S22), a signal + B _cont for outputting the + B voltage to the voltage for the normal operation is output, and the + B voltage generation circuit 18 outputs the signal during the normal operation as shown in FIG. + B
The output of the voltage is started (S24).

When the microprocessor 11a outputs a signal + B _cont for _changing the + B voltage to a voltage for normal operation (S24), it starts timing (S26), for example, when it measures 80 ms (S28). Horizontal oscillation frequency signal HOSC
To output a horizontal oscillation frequency signal HOSC, which is a frequency at the time of normal operation, as shown in FIG. 3B. (S30), and returns. Thus, as shown in FIG. 3A, the pulse voltage Vcp generated between the collector and the emitter of the horizontal output transistor 14a does not exceed, for example, 1200 V during normal operation, and does not become a transient overvoltage.

Embodiment 2 FIG. 4 is a flowchart showing the operation of the horizontal deflection circuit when power is turned on in Embodiment 2 of the power supply control method for the horizontal deflection circuit, the horizontal deflection circuit, and the display monitor according to the present invention. The configuration and other operations of the horizontal deflection circuit and the display monitor are the same as the configurations and operations described in the first embodiment, and thus the description is omitted. Microprocessor 11
a is always detected frequency H ₁ of the horizontal sync signal (S3
2) The frequency H ₀ detected last time is read from the work memory (S33) and compared (S34).

[0029] As a result, when the frequency H ₁ detected this time is lower than the frequency H ₀ previously detected (S34), the microprocessor 11a starts the time counting (S36), for example, for the frequency of the horizontal synchronizing signal is stabilized When 300 ms has been counted (S38), the frequency H ₂ of the horizontal synchronization signal at that time is calculated.
Detects (S39), and outputs a signal + B _cont for the voltage corresponding to + B voltage to the frequency H ₂ (S40),
As shown in FIG. 5 (b), to output a low voltage corresponding to the frequency H ₂ to + B voltage generating circuit 18.

The microprocessor 11a has a frequency H ₂
After outputting the signal + B _{co nt} for the voltage corresponding to (S
40), timing is started (S42), and the + B voltage generation circuit 1
When the output voltage of the 8 that for example measures the 80m seconds for sufficiently lowered (S44), and outputs a voltage F / V for the horizontal oscillation frequency signal HOSC the frequency of H ₂ horizontal synchronizing signal, FIG. 5 (b), the horizontal oscillation frequency signal to start the output of HOSC (S46) is frequency H ₂ in the horizontal oscillator 12, to (S48) returns the frequency H ₂ as the frequency H ₀ previously detected. As a result, as shown in FIG. 5A, the pulse voltage Vcp generated between the collector and the emitter of the horizontal output transistor 14a does not exceed, for example, 1200 V during normal operation, and does not become a transient overvoltage.

The microprocessor 11a is detected this time (S32) frequency H ₁ and the results of comparing the frequency H ₀ previously detected (S34), when the frequency H ₁ detected this time is higher than the frequency H ₀ previously detected ( S34), the microprocessor 11a starts time measurement (S50), and measures, for example, 300 ms for stabilizing the frequency of the horizontal synchronization signal (S52).
₂ detects (S53), and outputs a voltage F / V for the horizontal oscillation frequency signal HOSC to the frequency H _2, FIG. 6
(B), the to start output of the horizontal oscillator 12 is a frequency H ₂ horizontal oscillator frequency signal HOSC (S
54).

The microprocessor 11a after outputting the voltage F / V for the horizontal oscillation frequency signal HOSC frequency H ₂ (S54), starts timing (S56), the frequency is the horizontal oscillation frequency signal HOSC H ₂ when counting for example, 200m seconds for stabilization (S58), and outputs a signal + B _cont for the voltage corresponding to the frequency H _2, FIG. 6
As shown in (b), the frequency H is applied to the + B voltage generation circuit 18.
To output a voltage corresponding to ₂ (S60), to (S48) returns the frequency H ₂ as the frequency H ₀ previously detected.
Thereby, the collector of the horizontal output transistor 14a is
As shown in FIG. 6A, the pulse voltage Vcp generated between the emitters does not exceed, for example, 1200 V during normal operation, and does not become a transient overvoltage.

[0033]

According to the power supply control method for the horizontal deflection circuit according to the first invention and the horizontal deflection circuit according to the fifth invention, a CRT is provided.
When the power of the display monitor is turned on, the + B voltage generating circuit for generating the + B power supply voltage is started at a lower voltage than during normal operation, and the horizontal oscillation circuit is set to a higher horizontal oscillation frequency than during normal operation. Start with
After the horizontal oscillation circuit is started, when a first predetermined time is measured, the voltage generated by the + B voltage generation circuit is increased to the voltage during normal operation. Next, when the second predetermined time is measured, the horizontal oscillation frequency of the horizontal oscillation circuit is reduced to the frequency during normal operation. Thereby, the transient overvoltage generated in the horizontal output circuit can be reduced.

According to the horizontal deflection circuit power supply control method of the second invention and the horizontal deflection circuit of the sixth invention, the third predetermined time is measured after the power of the display monitor using the CRT is turned on. Sometimes, the + B voltage generating circuit for generating the + B power supply voltage is started at a lower generation voltage than during the normal operation, and the horizontal oscillation circuit is started at a higher horizontal oscillation frequency than during the normal operation. After the horizontal oscillation circuit is started, when a first predetermined time is measured, the voltage generated by the + B voltage generation circuit is increased to the voltage during normal operation. Then
When the second predetermined time is measured, the horizontal oscillation frequency of the horizontal oscillation circuit is reduced to the frequency at the time of normal operation. Thereby, the transient overvoltage generated in the horizontal output circuit can be reduced.

According to the power supply control method for the horizontal deflection circuit according to the third invention and the horizontal deflection circuit according to the seventh invention, the detecting means detects the frequency of the horizontal synchronization signal of the display monitor using the CRT and compares the frequency. Means compares the detected frequencies in time series. As a result of comparison by the comparing means,
When the frequency decreases, the voltage generated by the + B voltage generating circuit that generates the + B power supply voltage is reduced to a voltage corresponding to the reduced frequency when a fourth predetermined time is measured.
Then, after the generated voltage is reduced to that voltage, when the fifth predetermined time is measured, the horizontal oscillation frequency of the horizontal oscillation circuit is reduced to the reduced frequency. Thereby, the transient overvoltage generated in the horizontal output circuit can be reduced.

According to the power control method for the horizontal deflection circuit according to the fourth invention and the horizontal deflection circuit according to the eighth invention, when the frequency is increased as a result of comparison by the comparison means, the sixth predetermined time is measured. At times, the horizontal oscillation frequency of the horizontal oscillation circuit is increased to the increased frequency. Then, after the horizontal oscillation frequency is increased to that frequency, when a seventh predetermined time is measured, the voltage generated by the + B voltage generation circuit is increased to a voltage corresponding to the increased frequency. Thereby, the transient overvoltage generated in the horizontal output circuit can be reduced.

According to the display monitor of the ninth aspect, since the horizontal deflection circuit according to any one of claims 5 to 8 is provided, a transient overvoltage generated in the horizontal output circuit can be reduced.

[Brief description of the drawings]

FIG. 1 is a power control method for a horizontal deflection circuit according to the present invention;
It is a block diagram showing composition of an embodiment of a horizontal deflection circuit and a display monitor.

FIG. 2 is a power control method for a horizontal deflection circuit according to the present invention;
5 is a flowchart illustrating an operation of the embodiment of the horizontal deflection circuit and the display monitor.

FIG. 3 is a power control method for a horizontal deflection circuit according to the present invention;
5 is a timing chart for explaining the operation of the embodiment of the horizontal deflection circuit and the display monitor.

FIG. 4 is a power control method for a horizontal deflection circuit according to the present invention;
5 is a flowchart illustrating an operation of the embodiment of the horizontal deflection circuit and the display monitor.

FIG. 5 is a power control method for a horizontal deflection circuit according to the present invention;
5 is a timing chart for explaining the operation of the embodiment of the horizontal deflection circuit and the display monitor.

FIG. 6 is a power control method for a horizontal deflection circuit according to the present invention;
5 is a timing chart for explaining the operation of the embodiment of the horizontal deflection circuit and the display monitor.

FIG. 7 is a timing chart for explaining the operation of a conventional horizontal deflection circuit and display monitor.

[Explanation of symbols]

1a display monitor, 2a horizontal deflection circuit, 6
Power supply circuit, 11a microprocessor, 12 horizontal oscillator, 13 horizontal drive circuit, 14 horizontal output circuit,
14a horizontal output transistor, 14c resonance capacitor, 15 horizontal deflection coil, 16 horizontal output transformer,
18 + B voltage generation circuit, 26 CRT.

Claims (9)

[Claims] When a power supply of a display monitor using a CRT is turned on, a + B power supply voltage is generated.
The voltage generation circuit is started at a lower generation voltage than during normal operation, the horizontal oscillation circuit is started at a higher horizontal oscillation frequency than during normal operation, and then, after a first predetermined time, the generation voltage of the + B voltage generation circuit is changed to normal. A power supply control method for a horizontal deflection circuit, comprising: increasing a voltage at the time of operation, and further reducing the horizontal oscillation frequency of the horizontal oscillation circuit to a frequency at the time of normal operation after a second predetermined time. 2. After a power supply of a display monitor using a CRT is turned on, a + B voltage generation circuit for generating a + B power supply voltage is started at a lower generation voltage than in a normal operation and a horizontal oscillation circuit is activated after a third predetermined time. Starting at a higher horizontal oscillation frequency than during normal operation, the voltage generated by the + B voltage generation circuit is increased to a voltage during normal operation after a first predetermined time, and the horizontal oscillation circuit is further increased after a second predetermined time. A power supply control method for a horizontal deflection circuit, wherein the horizontal oscillation frequency is reduced to a frequency during normal operation. 3. A fourth predetermined time after the frequency of the horizontal synchronizing signal of the display monitor using the CRT is lowered, the voltage generated by the + B voltage generating circuit for generating the + B power supply voltage is changed according to the lowered frequency. The horizontal oscillation frequency of the horizontal oscillation circuit is decreased to the decreased frequency after a fifth predetermined time. 4. A sixth predetermined time after the frequency of the horizontal synchronizing signal of the display monitor using the CRT increases, the horizontal oscillation frequency of the horizontal oscillation circuit is increased to the increased frequency, and further the seventh oscillation is performed. A power supply control method for a horizontal deflection circuit, comprising: increasing a voltage generated by a + B voltage generation circuit for generating a + B power supply voltage to a voltage corresponding to the increased frequency after a predetermined time. 5. A detecting means for detecting that the power of a display monitor using a CRT is turned on, and a + B voltage for generating a + B power supply voltage when the detecting means detects that the power is turned on. Means for starting the generation circuit at a lower generation voltage than during normal operation, and means for starting the horizontal oscillation circuit at a higher horizontal oscillation frequency than during normal operation when the detection means detects that the power is turned on. Means for counting a first predetermined time after the means has started the horizontal oscillation circuit, and means for measuring the voltage generated by the + B voltage generation circuit during normal operation when the means measures the first predetermined time. Means for increasing the generated voltage to the voltage, means for measuring a second predetermined time after the means has increased the generated voltage to the voltage, and means for measuring the second predetermined time after the means has measured the second predetermined time. Horizontal oscillation Means for reducing the wave number to the frequency at the time of normal operation. 6. A detecting means for detecting that the power of a display monitor using a CRT is turned on, and a clock for measuring a third predetermined time after the detecting means detects that the power is turned on. Means for starting a + B voltage generating circuit for generating a + B power supply voltage at a lower generation voltage than during normal operation when the timing means has counted a third predetermined time; and Means for starting the horizontal oscillation circuit at a higher horizontal oscillation frequency than during normal operation, and after the means starts the horizontal oscillation circuit,
Means for measuring a first predetermined time, means for increasing the voltage generated by the + B voltage generation circuit to a voltage during normal operation when the means has measured the first predetermined time, Means for counting a second predetermined time after the voltage has been increased, and means for lowering the horizontal oscillation frequency of the horizontal oscillation circuit to a frequency during normal operation when the means has counted the second predetermined time. And a horizontal deflection circuit. 7. A means for detecting a frequency of a horizontal synchronization signal of a display monitor using a CRT, a comparing means for comparing the frequencies detected by the means in a time series, and a result of comparison by the comparing means, Means for counting a fourth predetermined time when the voltage drops, and a voltage generated by a + B voltage generating circuit for generating a + B power supply voltage when the means clocks the fourth predetermined time, according to the lowered frequency. Means for reducing a generated voltage to the voltage, means for measuring a fifth predetermined time after the means reduces the generated voltage to the voltage, and means for measuring the fifth predetermined time when the means has measured the fifth predetermined time. Means for lowering the horizontal oscillation frequency to the lowered frequency. 8. A means for measuring a sixth predetermined time when the frequency increases as a result of comparison by the comparing means, and a means for measuring the horizontal oscillation frequency of the horizontal oscillation circuit when the means measures the sixth predetermined time. Means for increasing the frequency to the increased frequency, means for measuring the seventh predetermined time after the means has increased the horizontal oscillation frequency to the frequency, and means for measuring the seventh predetermined time. And a means for increasing the voltage generated by the + B voltage generating circuit to a voltage corresponding to the increased frequency. 9. A display monitor comprising the horizontal deflection circuit according to claim 5.