KR100227110B1 - Picture aspect adaptive anode voltage control apparatus of cathode ray tube - Google Patents

Abstract

The present invention relates to a non-adaptive CRT anode voltage control apparatus, and when the aspect ratio of an image is converted to the effective aspect ratio of the CRT apparatus, the vertical scanning device of the blanking area formed on the upper and lower sides or the left and right sides of the CRT apparatus. In order to minimize the voltage level applied to the anode electrode of the CRT device, the current on the primary side flows intermittently by the switching action of the horizontal output transistor 10, and the anode electrode of the CRT device 22 on the secondary side. In a television having a flyback transformer 18 at which a voltage level is applied to the terminal, the secondary side of the flyback transformer 18 is formed of first and second coils 18a and 18b, and the first and second The dichroic element 30 and the CRT apparatus 22 interposed between the two coils 18a and 18b to allow electrical connection / shorting of the second coil 18b to be performed with respect to the first coil 18a. And a controller 34 for controlling the voltage level applied to the anode electrode of the CRT device 22 by executing gate control of the die liquid element 30 based on the aspect ratio of the image displayed on The voltage of the anode electrode of the CRT apparatus 22 controlled by the controller 34 is converted to the aspect ratio of the CRT apparatus 22 in the blanking region of the upper side and the lower side or the left side and the lower side of the displayed image. It is set to the level induced by 18a.

Description

Aspect Ratio Adaptive Crt Anode Voltage Controller

The present invention relates to an aspect ratio adaptive CRT anode voltage control device applicable to a television, and more particularly, to a 16: 9 aspect ratio CRT apparatus or a 16: 9 aspect ratio CRT apparatus. Aspect ratio adaptive CRT anode voltage control to reduce power consumption and improve image quality by minimizing anode voltage of CRT device in the blanking area formed on the top, bottom, left and right of effective screen when 4: 3 aspect image is reproduced Relates to a device.

In general, a television that reproduces a video / audio signal transmitted from a broadcasting station or reproduces a video / audio signal transmitted by, for example, playing a videotape is equipped with a CRT device for outputting a video screen. The R / G / B electron gun causes the R / G / B color ratio emitted based on the color components of the image signal to reach the corresponding R / G / B pixels on the fluorescent panel to perform the reproduction of the color image.

In such a CRT apparatus, a very high voltage is applied to the anode electrode to accelerate the R / G / B electron beam. FIG. 1 schematically illustrates a power system of a television according to a conventional example.

In FIG. 1, reference numeral 10 denotes a horizontal output transistor which is switched ON / OFF by the horizontal drive signal Hs when the horizontal drive signal Hs is applied to the base from a horizontal drive end (not shown). Denotes a damping diode and a capacitor which are connected to the collector side of the horizontal output transistor 10 and perform a damping function against a sudden change in the collector current appearing on the collector side during the switching ON period of the horizontal output transistor 10. FIG. 16 is connected to the collector side of the horizontal output transistor 10, and the collector current determined by the switching ON / OFF action of the horizontal output transistor 10 radiates from the R / G / B electron gun to R / G / A horizontal deflection coil that performs horizontal deflection for the B color beam.

18, one end of the primary coil is connected to the collector side of the horizontal output transistor 10 so that the high voltage applied to the power supply for the operation of the television and the anode electrode of the CRT apparatus (22 in Fig. 1) in the secondary coil. As a flyback transformer generating (HV), at the other end of the primary coil of the flyback transformer 18, a video signal power source (DC; approximately 150V) applied to the R / G / B electron gun is obtained, while the flyback An anode electrode of the CRT device 22 is connected to the secondary coil of the transformer 18 through a high-voltage rectifier diode 20, and a variable voltage of the focus voltage applied to the focus electrode of the CRT device 22 is variably set. The variable resistor 24 and the variable resistor 26 for variably setting the screen voltage SCREEN applied to the screen electrode of the CRT apparatus 22 are connected.

Therefore, according to the power supply system, when the corresponding television is set to the power ON state, a horizontal drive signal Hs having a constant duty ratio is applied to the base of the horizontal output transistor 10 in the horizontal drive, and accordingly the horizontal The output transistor 10 switches according to the duty ratio of the horizontal drive signal Hs so that the collector current corresponding to the duty ratio of the horizontal drive signal Hs appears on the collector side.

Accordingly, the collector current due to the switching action of the horizontal output transistor 10 is applied to the horizontal deflection coil 16 in a state where a sudden fluctuation is damped by the damping circuits 12 and 14 so that the CRT device 22 is applied. The horizontal deflection action of the color beam emitted from the R / G / B electron gun is performed.

In addition, an image signal power source to be applied to the R / G / B electron gun of the CRT device 22 while the current flowing through the primary coil of the flyback transformer 18 is interrupted according to the switching action of the horizontal output transistor 10. While the DC is obtained, the secondary coil of the flyback transformer 18 obtains a high voltage HV applied to the anode electrode of the CRT apparatus 22, and a variable resistor connected to the high voltage HV. From 24, the focus voltage FOCUS applied to the focus electrode of the CRT apparatus 22 and the screen voltage SCREEN applied to the screen electrode of the CRT apparatus 22 from the variable resistor 26 are obtained.

Accordingly, the CRT apparatus 22 emits an R / G / B color beam from the R / G / B electron gun in response to the R / G / B signal processed by the image processing means by the image signal power supply DC, The R / G / B color beams are formed on the fluorescent panel depending on the high voltage (HV) applied to the anode electrode through a shadow mask (not shown) in a state where horizontal deflection is made by the horizontal deflection coil 16. When the R / G / B fluorescent point is reached, light is emitted, and thus, a color image is displayed on the CRT apparatus 22.

However, when the aspect ratio of the CRT device 22 is 4: 3 while the high voltage (HV) is applied to the anode electrode of the CRT device 22 shown in FIG. 1, the 4: 3 aspect ratio image is reproduced. As shown in FIG. 2A, a high-voltage (high pressure) is applied during the vertical scanning period to the anode electrode of the CRT apparatus 22 to display an image of a 4: 3 aspect ratio on the entire effective screen of the CRT apparatus 22 having a 4: 3 aspect ratio. HV) is not lost even when HV) is applied, but when the 16: 9 aspect ratio image is reproduced in the 4: 3 aspect ratio CRT device 22 as illustrated in FIG. A black color blanking area BLK is formed on the upper side and the lower side of the CRT apparatus 22 centered on an image having a 9 aspect ratio. Also, when a 4: 3 aspect ratio image is reproduced on a CRT device 22 'of a widescreen television developed to enable widescreen reception as illustrated in FIG. 2C, the 4: 3 aspect ratio image is centered. As a result, blanking areas BLK 'of black color are formed on the left and right sides.

That is, when a 16: 9 aspect ratio image or an 4: 3 aspect ratio image is reproduced on a CRT device 22 or 22 'with a 4: 3 aspect ratio or 16: 9 aspect ratio, the image is displayed on the upper side, the lower side, or the left side and the right side. In the blanking areas BLK and BLK 'formed, the high voltage HV obtained from the secondary side of the flyback transformer 22 is not applied to the anode electrode of the CRT device 22, although the image is not actually displayed. As it is continuously applied, an increase in power consumption is caused. In addition, when a high voltage (HV) is applied to the anode electrode of the CRT apparatus 22 in the vertical scanning period corresponding to the blanking areas BLK and BLK 'of the CRT apparatus 22, the R / G of the CRT apparatus 22 is applied. Residual components of the R / G / B color beam radiated from the / B electron gun are caused to be transferred in the blanking areas BLK and BLK 'of the CRT apparatus 22, so that, for example, white in the blanking areas BLK and BLK'. It will appear as noise.

Moreover, in such a case, high voltage HV is applied to the anode electrode of the CRT device 22 in the vertical scanning period corresponding to the blanking areas BLK and BLK 'formed by the aspect ratio change of the CRT device 22. Irradiation of the residual R / G / B color beams causes the R / G / B pixels at positions corresponding to the blanking areas BLK and BLK 'to deteriorate, resulting in a disadvantage of shortening the life of the CRT apparatus. do.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and the image of the CRT apparatus formed when the image reproduced in the 4: 3 aspect ratio or 16: 9 aspect ratio CRT apparatus is converted to 16: 9 aspect ratio or 4: 3 aspect ratio. In the vertical scanning period corresponding to the upper and lower sides or the left and right sides of the displayed effective screen area, the level of the high voltage applied to the anode electrode of the CRT device is minimized to reduce power consumption and increase the brightness on the effective screen area for the blanking area. It is an object of the present invention to provide a non-adaptive CRT anode voltage control device for the purpose.

In order to achieve the above object, according to a preferred embodiment of the present invention, a flyback in which the current of the primary side flows intermittently by the switching action of the horizontal output transistor, so that the voltage level applied to the anode electrode of the CRT apparatus is obtained on the secondary side. In a television with a transformer, the secondary side of the flyback transformer is formed of first and second coils and is interposed between the first and second coils to electrically connect the second coils to the first coils. And a controller for controlling the voltage level applied to the anode electrode of the CRT device by performing gate control of the die liquid element based on an aspect ratio of an image displayed on the CRT device. A configured non-adaptive CRT anode voltage control device is provided.

Preferably, the voltage of the anode electrode of the CRT apparatus controlled by the control unit is at a level induced by the first coil in the blanking region at the upper side and the lower side or the left side and the lower side of the image displayed by aspect ratio conversion on the CRT apparatus. Is set.

According to the non-adaptive CRT anode voltage control apparatus according to the present invention having the above-described configuration, the aspect ratio displayed on the CRT apparatus by the control unit is interposed between the first and second coils on the secondary side of the flyback transformer. When controlled to be converted, in the blanking area formed above and below or on the left and right sides of the effective screen area of the CRT device, the die liquid element is controlled to be in a non-conductive state so that the second coil is electrically shorted so that the anode of the CRT device is controlled. Only the voltage induced by the first coil is applied to the electrode.

1 is a view showing a power system of a television according to a conventional example;

FIG. 2A is a view for explaining a state in which an image of 4: 3 aspect ratio displayed on a 4: 3 aspect ratio CRT apparatus employed in a general television is reproduced; FIG.

FIG. 2B is a view for explaining a state in which a 16: 9 aspect ratio image is reproduced in a 4: 3 aspect ratio CRT apparatus shown in FIG. 1;

FIG. 2C is a diagram for explaining a state in which a 4: 3 aspect ratio image is reproduced in a CRT apparatus having a 16: 9 aspect ratio; FIG.

3 is a view showing the configuration of an aspect ratio adaptive CRT anode voltage control apparatus according to the present invention;

4A and 4B are waveform diagrams for explaining the operation of the aspect ratio adaptive CRT anode voltage control apparatus according to the present invention.

* Description of the symbols for the main parts of the drawings *

10: horizontal output transistor, 18: flyback transformer,

18a, 18b: first and second coils, 30: dichroic element,

32: horizontal / vertical synchronous signal detection unit, 34: control unit.

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

3 is a diagram illustrating an apparatus for controlling non-adaptive CRT anode voltage according to a preferred embodiment of the present invention, and the same components as those shown in FIG. 2 will be described with the same reference numerals.

That is, in FIG. 3, reference numeral 10 denotes a horizontal output transistor which is switched ON / OFF by a horizontal drive signal Hs applied to the base, and 12 and 14 denote a collector current appearing on the collector side of the horizontal output transistor 10. A damping diode and a capacitor, which perform a damping function against sudden fluctuations, 16, R / G / B radiated from the R / G / B electron gun to a collector current determined by the switching ON / OFF action of the horizontal output transistor 10. A horizontal deflection coil for performing horizontal deflection with respect to the color beam.

Unlike the configuration shown in FIG. 1, the flyback transformer designated by reference numeral 18 is formed of the first coil 18a and the second coil 18b on the secondary side thereof, and the first coil 18a and the second coil 18b. A diac element 30 is interposed between the coils 18b. Preferably, the first and second coils 18a and 18b have a winding ratio of approximately 1: 5 compared to that of the primary side coil, and the first and second coils 18a when the die liquid element 30 is connected to each other. 18b), while the conversion to the aspect ratio at which the blanking area is formed on the CRT apparatus 22 is controlled, for example, the second coil (1) is not conducting by the dichroic element 30. 18b) is electrically shorted so that only the voltage obtained by the first coil 18a is applied to the anode electrode of the CRT device 22.

3, the image signal power supply DC (approximately 150V) is also obtained in the flyback transformer 18, and the anode electrode of the CRT apparatus 22 is connected and applied to the focus electrode of the CRT apparatus 22. A variable resistor 24 for variably setting the focus voltage FOCUS to be used and a variable resistor 26 for variably setting the screen voltage SCREEN applied to the screen electrode of the CRT apparatus 22 are connected.

In FIG. 3, reference numeral 32 denotes a horizontal / vertical synchronization signal detection unit for detecting a horizontal / vertical synchronization signal (Hsync / Vsync) from an image signal to be displayed on the CRT apparatus 22, and 34 denotes the CRT apparatus 22. Is a 4: 3 or 16: 9 aspect ratio, the aspect ratio control signal for changing the aspect ratio of the video signal to be displayed on the CRT device 22 to 16: 9 or 4: 3 is applied from the remote control, for example The horizontal / vertical synchronous signal detection unit 32 receives the horizontal / vertical synchronous signal (Hsync / Vsync), and the CRT device is used in the blanking area (BLK of FIG. 2B or BLK 'of FIG. 2C) of the CRT device 22. While the level of the voltage applied to the anode electrode of 22 is minimized, in the effective screen region, the ratio of the dichroic element 30 is applied so that normal high voltage (HV) is applied to the anode electrode of the CRT apparatus 22. The control part which controls conduction / conduction is shown.

Therefore, the operation of the non-adaptive CRT anode voltage control device according to the present invention having the above-described configuration will be described with reference to the waveform diagram shown in FIG.

First, when the CRT device 22 is configured to display 4: 3 aspect ratio image by the aspect ratio control signal when the CRT device 22 has a 4: 3 aspect ratio, the horizontal / vertical synchronous signal detection unit 32 performs horizontal / vertical image signals. The vertical synchronization signal (Hsunc / Vsync) is detected and applied to the control unit 34. However, in this case, the display of the 4: 3 aspect ratio image to the CRT device 22 of 4: 3 aspect ratio is assumed. Accordingly, the control unit 34 applies, for example, a high level control signal to the gate of the die liquid element 30.

Therefore, when the die liquid element 30 is brought into a conductive state, the first and second coils 18a and 18b on the secondary side of the flyback transformer 18 are electrically connected, and thus the first and second coils are electrically connected. The voltage induced at 18a and 18b is applied to the anode electrode of the CRT apparatus 22 as a normal high voltage (HV) through the high voltage rectifying diode 20.

On the other hand, if an aspect ratio control signal is applied to the control unit 34 such that a 16: 9 aspect ratio image of the form illustrated in Fig. 2B is reproduced on a CRT device 22 having a 4: 3 aspect ratio, for example, shown in Fig. 4A. One image screen scanned by the vertical scanning signal is shown in FIG. 4B in the form of a blanking signal on the upper side of the CRT apparatus 22 at the rear end of the vertical synchronization signal (that is, on the screen of the CRT apparatus 22 at the time of screen conversion). After the predetermined period is introduced, a video signal to be displayed on the effective screen area is followed, and a blanking signal on the lower side of the CRT apparatus 22 is introduced following the video signal on the effective screen area. .

Accordingly, the control unit 34 may perform the blanking signal during the period of the vertical scan signal shown in FIG. 4A based on the horizontal / vertical synchronization signal Hsync / Vsync provided separately from the horizontal / vertical synchronization signal detection unit 32. When the section corresponding to the signal is determined, the level of the control signal applied to the gate of the die liquid element 30 is set to, for example, a low level. Accordingly, the first and second sides of the secondary side of the flyback transformer 18 are accordingly set. As the die liquid element 30 interposed between the coils 18a and 18b is in a non-conductive state, the second coil 18b is electrically shorted in the period of the blanking signal of FIG. 4B. In that case, only the voltage induced in the first coil 18a on the secondary side of the flyback transformer 18 is applied to the anode electrode of the CRT device 22 via the high voltage rectifier diode 20.

Then, in the period of the video signal of FIG. 4B, the die liquid element 30 is maintained in a conductive state as the controller 34 applies a trigger control signal to the gate of the die liquid element 30. The high-pressure rectifier diode is connected to the first and second coils 18a and 18b of the secondary side of the flyback transformer 18 and electrically connected to the first and second coils 18a and 18b. Via 20 is applied to the anode electrode of the CRT apparatus 22.

Then, in the period of the blanking signal subsequent to the video signal of FIG. 4B, the die liquid element 30 is kept in a non-conductive state under the control of the control unit 34, so that the secondary side of the flyback transformer 18 When the second coil 18b is electrically shorted, only the voltage induced in the first coil 18b on the secondary side of the flyback transformer 18 is applied to the anode electrode of the CRT device 22. Accordingly, only the lowest voltage is also applied to the lower blanking area BLK of the CRT apparatus 22 illustrated in FIG. 2B.

Therefore, when the image displayed on the 4: 3 aspect ratio CRT apparatus 22 is instructed to be converted to the aspect ratio of 16: 9, vertical scanning corresponding to the blanking area BLK of the upper and lower sides of the CRT apparatus 22 is performed. Since only the lowest voltage is applied to the anode electrode of the CRT device 22 during the period, power consumption can be reduced, and transfer of residual R / G / B color beams in the blanking area BLK is suppressed as much as possible. As a result, the brightness of the image of the effective screen area with respect to the blanking area is improved, and deterioration of the R / G / B color pixels corresponding to the blanking area BLK is also prevented.

Also, even when a 4: 3 aspect ratio is set for an image displayed on a CRT device 22 'with a 16: 9 aspect ratio illustrated in FIG. 2C, the left and right sides of the CRT apparatus 22' are controlled by the above-described process. The first and second coils 18a and 18b on the secondary side of the flyback transformer 18 shown in FIG. 3 in the blanking area BLK 'of the interconnection / disconnection by the gate control of the die liquid element 30 So that the level of the voltage applied to the anode electrode of the CRT apparatus 22 can be controlled. Even in this case, the power consumption is reduced and the brightness of the image of the effective screen area with respect to the blanking area is improved as well. Deterioration of the R / G / B color pixel corresponding to (BLK ') is also prevented.

As described above, according to the aspect-adaptive CRT anode voltage control device according to the present invention, when the aspect ratio of an image is specified to be converted with respect to the effective aspect ratio of the CRT apparatus, the CRT apparatus is formed on the upper and lower sides or the left and right sides of the CRT apparatus. In the vertical scanning period of the blanking area, power consumption is reduced by minimizing the voltage level applied to the anode electrode of the CRT device, and the deterioration of the R / G / B color pixels corresponding to the blanking area is prevented, and the blanking area is vertical. As the transfer of the residual R / G / B color beams between the syringes is prevented, the brightness of the image of the effective screen area can be improved in preparation for the blanking area.

Claims (2)

In a television equipped with a flyback transformer 18 in which a current on the primary side flows intermittently by a switching action of the horizontal output transistor 10, and a voltage level applied to the anode electrode of the CRT apparatus 22 on the secondary side is obtained. , The secondary side of the flyback transformer 18 is formed of first and second coils 18a, 18b, A diluent element 30 interposed between the first and second coils 18a and 18b to allow electrical connection / shorting of the second coil 18b to the first coil 18a; A control unit 34 for controlling the voltage level applied to the anode electrode of the CRT device 22 by executing gate control of the die liquid element 30 based on the aspect ratio of the image displayed on the CRT device 22; Non-adaptive CRT anode voltage control device, characterized in that configured to include. 2. The method of claim 1, wherein the voltage of the anode electrode of the CRT apparatus 22 controlled by the controller 34 is blanked on the upper side and the lower side, or the left side and the lower side of the image displayed by the aspect ratio conversion of the CRT apparatus 22. Non-adaptive CRT anode voltage control device, characterized in that the area is set to the level induced by the first coil (18a).

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