KR19990047985A - Vertical screen size correction device and method of cathode ray tube display device - Google Patents

Abstract

The disclosed vertical screen size correcting apparatus and method relate to being able to maintain a constant size by compensating and controlling the size of the vertical screen that changes according to the resolution with a microcomputer.

Vertical screen size correction device and method of the cathode ray and display device according to the present invention is a cathode ray tube display device having a vertical deflection circuit unit receives the vertical and horizontal synchronous signal corresponding to various resolutions, the vertical deflection frequency and the horizontal deflection frequency and the user, etc. The vertical hold voltage output from the microcomputer and the microcomputer that controls the calculation and output process of the vertical hold voltage, the vertical screen size correction value, and the pulse value corresponding to the vertical screen size value according to the vertical screen size control signal input from the outside. And a vertical oscillator, a vertical screen size corrector, and a vertical screen size adjuster for vertically deflecting the electron beam emitted from the cathode of the cathode ray tube by receiving the vertical screen size correction value and the vertical screen size value, respectively. It is done.

Therefore, the apparatus and method of the present invention can maintain the size of the vertical screen at all times regardless of the vertical and horizontal deflection frequencies according to various resolutions, thereby eliminating inconvenience in viewing and improving the performance of the product. Has the advantage.

Description

Vertical screen size correction device and method of cathode ray tube display device

The present invention relates to a vertical screen size correction apparatus and method of the cathode ray tube display device.

More specifically, the vertical screen size of a multi-sync (Multi sync) cathode ray tube display device that realizes high resolution through a circuit and method using a microcomputer is corrected according to the frequency according to the frequency. The present invention relates to a vertical screen size correction device and a method of a cathode ray tube display device capable of maintaining a vertical screen of a constant size.

In general, high resolution multi-mode cathode ray tube display devices operate over a wide vertical frequency range from 50 [Hz] to 160 [Hz], and the horizontal frequency ranges from 30 [Hz] to 110 [Hz] depending on the resolution to be implemented. Has a wide frequency band.

At this time, the vertical size of the screen is different for each mode, which is large in the low frequency band and small in the high frequency band.

1 is a block diagram schematically showing a vertical deflection circuit portion of a conventional cathode ray tube display device having such characteristics.

As shown, the vertical deflection circuit portion of the conventional cathode ray tube display device oscillates itself according to a time constant determined by a resistor R11 and a capacitor C11 connected to the outside, or an oscillation triggered by a vertical synchronization signal Vsync. The vertical oscillator 110 generates and outputs a frequency, a ramp waveform generator 120 that generates and outputs a ramp waveform matching the oscillation frequency input from the vertical oscillator 110, and a ramp waveform generator ( The vertical output circuit unit 130 receives the output waveform from the 120 and amplifies and outputs the current, and vertically deflects the electron beam that is driven by the output current of the vertical output circuit unit 130 and emitted from the cathode of the cathode ray tube. The main circuit includes a vertical deflection coil V-DY and a synchronization signal trigger unit 140 that receives the vertical synchronization signal Vsync and matches the output oscillation frequency of the vertical oscillator 110 with the vertical synchronization signal Vsync.

The operation of the vertical deflection circuit portion of the conventional cathode ray tube display device configured as described above is as follows.

First, when there is no vertical synchronization signal (Vsync), the oscillation frequency is generated by the self-oscillation by the time constant by the external resistor (R11) and the condenser (C11), the multivibrator (not shown) inside the vertical oscillator 110 When the vertical synchronization signal Vsync is input, the oscillation frequency triggered by the synchronization signal triggering unit 140 to the vertical synchronization signal Vsync is output.

As such, the oscillation frequency output from the vertical oscillator 110 is applied to the ramp waveform generator 120, and the ramp waveform generator 120 generates and outputs a ramp waveform matching the input oscillation frequency.

The vertical output circuit unit 130 receives the output waveform applied from the ramp waveform generating unit 120 and amplifies the current to supply it to the vertical deflection coil V-DY, and the vertical deflection coil V-DY is a vertical output circuit unit ( It is driven by the output current of 130 to vertically deflect the electron beam emitted from the cathode of the cathode ray tube.

Here, the ramp waveform generated by the ramp waveform generating unit 120 varies in size depending on the vertical frequency. Since the waveform is applied to the vertical deflection coil V-DY, the size of the vertical screen varies according to the frequency. do. Therefore, the vertical screen size control signal for controlling the size of a separate vertical screen is applied to the ramp waveform generator 120.

However, in the vertical deflection circuit portion of the conventional cathode ray tube display device having the configuration and operation as described above, the ramp waveform for the vertical deflection generated by the pulse waveform generator 120 has a different amplitude according to the input vertical frequency. .

That is, at low frequencies, the deflection time is long, and at high frequencies, it is small. As a result, the number of vertical scan lines is increased at low frequencies, and the size of the vertical screen is increased. At high frequencies, the number of vertical scan lines is reduced, and the size of the vertical screen is reduced.

Even if such a phenomenon occurs, even if the resolution range is low, even if the size of the vertical screen is fixed to a medium value, the change of the size is not so noticeable as to affect the performance of the product.

However, when high resolution or the screen size of the display device is enlarged, the deviation between the low frequency band and the high frequency band becomes very severe, and the size of the vertical screen becomes smaller in the high resolution mode and becomes larger in the low resolution mode. This was a disadvantage in viewing discomfort and performance evaluation of the product.

Accordingly, an object of the present invention is to provide an apparatus and method for correcting a vertical screen size of a cathode ray tube display device, which can be constantly maintained by compensating and controlling a size of a vertical screen that changes according to a resolution with a microcomputer.

1 is a block diagram schematically showing a conventional vertical deflection circuit portion.

Figure 2 is a block diagram showing an embodiment of a vertical deflection circuit unit with a vertical screen size correction device of the cathode ray tube display device of the present invention.

Figure 3 is a flow chart showing an embodiment of a vertical screen size correction method of the cathode ray tube display device to which the present invention is applied.

* Explanation of symbols for main parts of the drawings

210: microcomputer 220: AC-DC converter

230: vertical oscillation unit 240: ramp waveform generating unit

250: vertical screen size correction unit 260: vertical screen size adjustment unit

270: vertical output circuit section 280: synchronization signal trigger section

290: keypad R21, R22, R23: resistor

C21, C22, C23: Condenser V-DY: Vertical Deflection Coil

Vsync: Vertical Sync Signal Hsync: Horizontal Sync Signal

The vertical screen size correction device and method of the cathode ray tube display device according to the present invention for achieving the above object is characterized in that the cathode ray tube display device having a vertical deflection circuit portion receives the vertical and horizontal synchronous signal corresponding to various resolutions Microcomputer that controls the calculation and output process of vertical hold voltage, vertical screen size correction value and pulse value corresponding to vertical screen size value according to deflection frequency, horizontal deflection frequency and vertical screen size control signal input from outside by user Vertical oscillator, vertical screen size correction unit, and vertical for constant vertical deflection of the electron beam emitted from cathode of cathode ray tube by inputting vertical hold voltage, vertical screen size correction value and vertical screen size value respectively outputted from and microcomputer The screen size control unit is further provided.

Hereinafter, a preferred embodiment of the vertical screen size correcting apparatus and method of the cathode ray tube display device according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a block diagram showing an embodiment of a vertical deflection circuit unit with a vertical screen size correction device of the cathode ray tube display device of the present invention.

As shown, the vertical screen size correcting apparatus of the cathode ray tube display apparatus receives external commands and vertical and horizontal synchronization signals by the keypad 290 to the vertical deflection circuit portion of the conventional cathode ray tube display apparatus shown in FIG. , The microcomputer 210 for generating and outputting the vertical hold voltage pulse and the vertical screen size correction pulse and the vertical screen size pulse, and the vertical hold voltage pulse output from the microcomputer 210, the vertical screen size correction pulse, and the vertical screen size. The magnitude of the ramp waveform for vertical deflection is constant according to the AC-DC voltage converting unit 220 for converting the pulse into a DC voltage and outputting the same, and a vertical screen size correction value input from the AC-DC voltage converting unit 220. The vertical screen size correcting unit 250 to maintain and the vertical screen size correcting unit 250 according to the DC value of the vertical screen size input from the AC-DC voltage converter 220. The vertical screen size adjusting unit 260 for changing the period of the output ramp waveform of the configuration is further provided.

The operation of the vertical screen size correcting apparatus of the cathode ray tube display device to which the present invention having such a component is applied is as follows.

In the display device using the cathode ray tube, first, the microcomputer 210 receives the vertical sync signal (Vsync) and the horizontal sync signal (Hsync), and externally determines the vertical deflection frequency, the horizontal deflection frequency, and the size of the vertical screen. According to the control signal input by the user from the vertical hold voltage pulse, the vertical screen size correction pulse and the vertical screen size pulses are generated and output.

The vertical hold voltage pulse, the vertical screen size correction pulse, and the vertical screen size pulse output from the microcomputer 210 are converted into respective DC voltages by the AC-DC voltage converter 220 and output.

On the other hand, the vertical oscillator 230 generates a different oscillation frequency according to the magnitude of the vertical hold voltage (Vhold) input from the AC-DC converter 220 to generate a ramp waveform matching this oscillation frequency. It is applied to the ramp waveform generator 240.

The vertical screen size correcting unit 250 maintains a constant size of the ramp waveform input from the ramp waveform generating unit 240 according to the vertical screen size correcting value Vcomp input from the AC-DC voltage converter 220. The vertical screen size adjusting unit 260 adjusts the period of the output ramp waveform of the vertical screen size correcting unit 250 according to the DC value Vsize of the vertical screen size input from the AC-DC voltage converter 220. By adjusting the vertical screen size of the display device.

The vertical output circuit unit 270 receives the output signal of the vertical screen size adjusting unit 260 and amplifies the current to output the vertical deflection coil V-DY, and the vertical deflection coil V-DY is a vertical output circuit unit 270. It is driven by the output current of) to vertically deflect the electron beam emitted from the cathode of the cathode ray tube.

In addition, the synchronization signal triggering unit 280 receives the vertical synchronization signal (Vsync) to match the output oscillation frequency of the vertical oscillation unit 230 and the vertical synchronization signal (Vsync), the keypad 290 displays an external command Means for input.

Figure 3 is a flow chart showing an embodiment of a vertical screen size correction method of the cathode ray tube display device to which the present invention is applied.

As shown, the control process of the vertical screen size correction method of the cathode ray tube display device includes a vertical synchronization signal input determination process (S310) for determining whether the vertical synchronization signal (Vsync) is input to the microcomputer, and vertical synchronization As a result of the determination of whether the signal is input (S310), when the vertical synchronization signal (Vsync) is input, the vertical frequency calculation process (S320) for calculating the frequency f _V of the input vertical synchronization signal (Vsync), and the vertical frequency Determination process of the vertical frequency change to determine whether the vertical frequency (f _V ) calculated in the calculation process (S320) has a different value from the frequency of the vertical synchronization signal (Vsync) previously input (S340) and whether or not the vertical frequency change As a result of the determination in S340, when the vertical frequency f _V is changed, the vertical hold voltage Vhold corresponding to the new vertical frequency f _V is calculated and outputted in the form of a pulse waveform. Output and (S350) and, then calculates the vertical hold voltage (Vhold) output, calculating the vertical screen size correction value (Vcomp) which was kept constant by correcting the magnitude of the vertical screen according to the change in the horizontal frequency (f _H) After calculating and outputting the vertical screen size correction value outputting in the form of a pulse waveform (S360) and calculating the vertical screen size correction value (Vcomp), and then calculating the vertical screen size value (Vsize) of the pulse waveform It consists of the vertical screen size calculation and output process (S370) to output in the form.

Here, if the vertical frequency does not change as a result of the determination in the above-described vertical frequency change determination process (S340), whether the current horizontal frequency f _H has a value different from the frequency of the horizontal synchronization signal Hsync previously inputted. When the horizontal frequency f _H is changed, the horizontal frequency change determination process (S380) for performing the vertical screen size correction value calculation and output process (S360) is performed.

In addition, when the horizontal frequency (f _H ) is not changed as a result of the determination in the horizontal frequency change determination process (S380), it is determined whether or not a signal (Vsizeinput) for adjusting the vertical screen size is input by the user's adjustment. When the signal for adjusting the vertical screen size is input from the Vsizeinput, the vertical screen size control signal input determination process for performing the vertical screen size calculation and output process (S370) is performed (S390).

The vertical screen size correction method of the cathode ray tube display device configured as described above is controlled by the microcomputer 210 of FIG. 2 as follows.

In the process of determining whether the vertical synchronous signal is input (S310), whether or not the vertical synchronous signal (Vsync) is input to the microcomputer is continuously checked (Polling) at a predetermined time interval (S311) and judged (S312). If the signal Vsync is not input, a vertical deflection is performed by its oscillation frequency (S330), and if the vertical synchronization signal Vsync is input, the vertical synchronization signal Vsync input in the vertical frequency calculation process (S320). ) to calculate the frequency (f _V) of the.

In the determination of whether the vertical frequency is changed (S340), the vertical frequency is determined by determining whether the vertical frequency (f _V ) calculated in the vertical frequency calculation process (S320) has a value different from the frequency of the previously inputted vertical synchronization signal (Vsync). In case of change, a vertical hold voltage Vhold corresponding to the new vertical frequency f _V is calculated (S352), and the vertical hold voltage is calculated and output (S350), which is output in the form of a pulse waveform (S353).

Here, the vertical hold voltage Vhold may be calculated by applying interpolation to the vertical frequency f _V. As an example, the vertical hold voltage Vhold may be calculated by using the following equation.

[Equation 1]

In Equation 1, fv is the input vertical frequency, fvmax is the maximum value of the input vertical frequency, fvmin is the minimum value of the input vertical frequency, xmax is the DC voltage when the input vertical frequency is the maximum, xmin is the minimum of the input vertical frequency These values are set in advance and stored in the microcomputer 210 of FIG. 2 or in a separate memory device, and are read from the memory device when the vertical hold voltage Vhold is calculated (S351) and applied to the calculation. .

After the vertical hold voltage is calculated and output in the vertical hold voltage calculation and output process (S350), the vertical hold voltage is calculated and output (S360), and the vertical screen size correction value is calculated and output (S360). A vertical screen size correction value Vcomp for correcting and maintaining a constant size of the vertical screen according to the frequency f _H is calculated (S362) and output in the form of a pulse waveform (S363).

Here, the vertical screen size correction value Vcomp may be calculated by considering the number of vertical scan lines for different vertical screen sizes according to the horizontal frequency f _{H. As an} example, the vertical screen size correction value Vcomp may be calculated by using the following equation. .

[Equation 2]

Vcomp = (Midpoint -vlines) C

In Equation 2, Vcomp is a vertical screen size correction value, MinPoint is a number of vertical lines determined according to the vertical and horizontal frequency range, vlines is a horizontal frequency / vertical frequency, and C is a correction that determines a DC voltage value relative to the number of vertical lines. These values are set in advance and stored in the microcomputer 210 of FIG. 2 or in a separate memory device, and are read from the memory device when the vertical screen size correction value Vcomp is calculated (S361) and applied to the calculation.

In the vertical screen size calculation and output process (S370), after performing the vertical screen size correction value calculation and output process (S360), the vertical screen size value (Vsize) is calculated (S372) and output in the form of a pulse waveform (S373). Here, the vertical screen size (Vsize) can be calculated in consideration of the upper and lower limits and the resolution of the vertical screen size, as an example can be obtained by calculating as shown in the following equation.

[Equation 3]

In Equation 3, Vsizeinput denotes a vertical screen size determined according to a user's adjustment, Vsizemax denotes an upper limit of the vertical screen size at 256 levels, and Vsizemin denotes a lower limit of a vertical screen size at 256 levels. It is stored in the microcomputer 210 of FIG. 2 or in a separate storage device, and is read from the storage device when the Vsize, which is the vertical screen size, is calculated (S371) and applied to the calculation.

And, as a result of the determination in the vertical synchronization signal input determination process (S310), since the vertical synchronization signal (Vsync) is not input, the vertical deflection is performed by the oscillation frequency (S330), or the vertical screen size calculation and output process is performed. After performing operation S370, the process returns to the process of determining whether the vertical synchronization signal is input again (S310) and determines whether the vertical synchronization signal Vsync is input to the microcomputer.

If the vertical frequency f _V is not changed as determined by the vertical frequency change determination process (S340) while being controlled by the above process, whether the current horizontal frequency has a different value from the frequency of the previously input horizontal synchronization signal. If it is determined that the horizontal frequency (f _H ) is changed, it is controlled by the horizontal frequency change determination process (S380) to perform the vertical screen size correction value calculation and output process (S360).

When the horizontal frequency f _H does not change as a result of the determination in the horizontal frequency change determination process (S380), it is determined whether or not a signal (Vsizeinput) for adjusting the vertical screen size is input by the user. When a signal for adjusting the vertical screen size is input, the vertical screen size control signal input decision process (S390) for performing the vertical screen size calculation and output process (S370) is controlled.

Here, if the signal for adjusting the vertical screen size is not input by the user's adjustment, the process returns to the vertical synchronization signal input determination process S310 to determine whether the vertical synchronization signal Vsync is input to the microcomputer. To judge.

As described above, according to the apparatus and method for correcting the vertical screen size of the cathode ray tube display device according to the present invention, the size of the vertical screen which changes according to the vertical and horizontal deflection frequency is always kept constant so that inconvenience in viewing can be eliminated. As a result, it also has the effect of improving the performance of the product.

Claims (10)

In a display device using a cathode ray tube, a vertical and horizontal synchronous signal is input, a vertical hold voltage pulse according to a vertical deflection frequency, a vertical screen size correction pulse and a vertical screen to correct a size of a vertical screen according to a change in a horizontal frequency. A microcomputer that generates and outputs a vertical screen size pulse corresponding to a control signal input from an external source to determine the size of the output, a vertical hold voltage pulse, a vertical screen size correction pulse, and a vertical screen size pulse that are output from the microcomputer. AC-DC voltage converter for converting and outputting a voltage, vertical oscillator for generating and outputting different oscillation frequencies according to the magnitude of the vertical hold voltage input from the AC-DC voltage converter, and oscillation frequency input from the vertical oscillator Generates ramp waveform to generate and output ramp waveform matching A vertical screen size corrector configured to maintain a constant magnitude of the ramp waveform input from the ramp waveform generator according to the vertical screen size correction value input from the AC-DC voltage converter; Vertical screen size adjusting unit for changing the period of the output ramp waveform of the vertical screen size correction unit according to the DC value of the vertical screen size, Vertical output circuit unit for outputting the current amplified by receiving the output signal of the vertical screen size adjusting unit, the vertical Vertical deflection coils driven by the output current of the output circuit part to vertically deflect the electron beam emitted from the cathode of the cathode ray tube, and a synchronization signal trigger part for receiving a vertical synchronization signal and matching the output oscillation frequency of the vertical oscillation part to a vertical synchronization signal. And a keypad for inputting external commands to the display device. A vertical screen size compensation apparatus of a cathode ray tube display device. When the vertical synchronous signal is input, the vertical synchronous signal is inputted to determine whether or not the vertical synchronous signal is input to the microcomputer. When the vertical synchronous signal is input, the frequency of the vertical synchronous signal is calculated. In the vertical frequency calculation process, the vertical frequency change determination process for determining whether the vertical frequency calculated in the vertical frequency calculation process has a different value from the frequency of the vertical synchronization signal previously input, the vertical frequency change determination process As a result of the determination, when the vertical frequency is changed, the vertical hold voltage is calculated and outputted in the form of a pulse waveform after calculating the vertical hold voltage corresponding to the new vertical frequency, and the vertical hold voltage is calculated and outputted. By calculating the vertical screen size correction value that corrects the screen size and keeps it constant Calculation and output process of the vertical screen size correction value output in the form of spar, and the calculation and output process of the vertical screen size correction value, and the calculation and output process of the vertical screen size in the form of pulse waveform Vertical screen size correction method of the cathode ray tube display device characterized in that the control. According to claim 2, If the vertical frequency is not changed as a result of the determination in the vertical frequency change determination process, it is determined whether the current horizontal frequency has a different value from the frequency of the previously input horizontal synchronization signal, the horizontal frequency is If it is changed, the vertical screen size correction method of the cathode ray tube display device, characterized in that controlled by the horizontal frequency change whether the process of performing the calculation and output the vertical screen size correction value. According to claim 3, If the horizontal frequency does not change as a result of the determination in the horizontal frequency change determination process, it is determined whether the signal for adjusting the vertical screen size by the user's adjustment to determine the vertical screen size from the outside When the signal for adjustment is input, the vertical screen size correction method of the cathode ray tube display device, characterized in that the control is controlled by the vertical screen size control signal input determination process for performing the vertical screen size calculation and output process. The method according to claim 2, wherein the vertical synchronization signal input determination process is controlled to continuously check and determine whether the vertical synchronization signal is input at a predetermined time interval. The vertical screen of the cathode ray tube display apparatus of claim 2, wherein when the vertical synchronization signal is not determined, when the vertical synchronization signal is not input, a vertical deflection is performed by the oscillation frequency. How to correct size. The method of claim 2, wherein the vertical hold voltage of the vertical hold voltage calculation and output process is calculated by applying an interpolation method to the vertical frequency. 8. The method of claim 7, wherein the vertical hold voltage is calculated by the following equation. Where Vhold is the vertical hold voltage, fv is the input vertical frequency, fvmax is the maximum value of the input vertical frequency, fvmin is the minimum value of the input vertical frequency, xmax is the DC voltage at the maximum input vertical frequency, and xmin is the input vertical frequency. DC voltage at minimum. The vertical screen size correction method according to claim 2 or 3, wherein the vertical screen size correction value of the vertical screen size correction value calculation and output process is calculated and obtained by the following equation. Vcomp = (MidPoint-vlines) C Here, Vcomp is a vertical screen size correction value, MidPoint is a number of vertical lines determined according to the vertical and horizontal frequency ranges, vlines is a horizontal frequency / vertical frequency, and C is a correction constant that determines a DC voltage value relative to the number of vertical lines. The vertical screen size correcting method of claim 2 or 4, wherein the vertical screen size of the vertical screen size calculation and output process is calculated by the following equation. Here, Vsize is the vertical screen size, Vsizeinput is the vertical screen size determined by the user's adjustment, Vsizemax is the upper limit of the vertical screen size at 256 levels, and Vsizemin is the lower limit of the vertical screen size at 256 levels.