KR100346544B1 - Auto gamma level controll driver of beam index tube - Google Patents

Abstract

The present invention improves the reduction of the luminance ratio due to the DC current level that must be maintained in order to obtain the minimum beam current by the index stripe when there is no signal in the beam index tube, and gamma according to the luminance level of the image signal input upon inputting the image signal. The present invention relates to an automatic gamma level driving circuit of a beam index tube, which actively adjusts characteristics to favor a contrast ratio, thereby improving image sharpness.

According to the present invention, an index stripe signal detected from a beam index tube is detected by a photo detector, and the detected index signal is filtered through a band pass filter and a limiter to filter a predetermined band, and the filtered signal is passed through a phase loop circuit. Index signal processing for generating switching pulses for serial output of G and B color signals; A gamma level adjusting unit which adjusts the color difference signal processed by receiving an image signal to the gamma level and the driving level of each color signal; Amplifying each color signal of the driving level adjusted by the gamma level adjusting unit and a switching pulse processed by the index signal processing unit to output an index beam current, and convert the output index beam current and the minimum beam current into voltage to convert an image signal. Characterized in that the beam current output converter for varying the gamma level of the set value.

Description

AUTO GAMMA LEVEL CONTROLL DRIVER OF BEAM INDEX TUBE}

The present invention relates to an automatic gamma level control driving circuit of a beam index tube, and more particularly, a luminance ratio is reduced due to a DC current level that must be maintained to obtain a minimum beam current by an index stripe when no signal is present in the beam index tube. The automatic gamma level driving circuit of the beam index tube improves the image quality by adjusting the gamma characteristic according to the luminance level of the image signal input at the time of inputting the image signal to favor the contrast ratio. .

In general, color cathode ray tubes which are widely used at present have various advantages due to their low price and relatively sharp image quality.

However, due to the shadow mask functioning as a color screening function, there is a manufacturing limitation because a high current region and a large screen size cause thermal expansion to lower color purity.

In addition, since the electron beam is affected by the geomagnetic field, it shields the geomagnetic field with an inner shield inside the color cathode ray tube, and also requires a degaussing circuit and a coil in the TV receiver. There are several problems.

In order to improve the disadvantage of the color cathode ray tube, a beam index cathode ray tube without shadow mask and inner shield has been developed.

As shown in FIG. 1, the beam index cathode ray tube includes: a tube having a fluorescent surface and an index stripe inside the front surface thereof; An electron gun which emits an electron beam at the rear end of the tube; A deflection yoke for deflecting the electron beam magnetically in the neck portion of the tube; A condenser plate for condensing and detecting ultraviolet rays emitted from the index stripe on the curved portion of the tube; A photo detector for detecting the focused optical signal; An indexing circuit converts an optical signal detected by the photo detector and outputs an image signal in synchronization with the input R, G, B color signal switching pulses.

The beam index cathode ray tube configured as described above detects light output from the index stripe in which the electron beam emitted from the electron gun is formed on the fluorescent surface of the tube.

The optical output detected by the photodetector detects an index signal excited by the detected electron beam after the voltage conversion and synchronizes with the color signal so that the desired color can be always driven at the position of the electron beam. have.

Therefore, the index stripe beam current Ib is constantly present in the beam index tube, thereby enabling indexing.

However, the beam index tube driven as described above is screened in the absence of an image signal (no signal) due to a DC current level that maintains at least the beam current for an index stripe beam current that is constantly present regardless of the image signal input or not. Since the black level is higher than the conventional shadow mask type cathode ray tube, there is a problem that the contrast ratio on the image quality is reduced by the rising black level, resulting in deterioration of sharpness.

Therefore, an object of the present invention is to reduce the contrast ratio, which is lowered due to the increase of the black level due to the DC current level, which is constantly supplied regardless of the image signal input, to be below a predetermined appropriate value of the luminance signal arbitrarily. The gamma curve characteristic of the image luminance signal of the set value is actively changed at all times, and the sharpness in image quality is improved by improving the contrast ratio having a level difference between the high luminance portion and the low luminance portion.

1 is a schematic control block diagram of a general beam index tube;

2 is an automatic gamma level control driving circuit diagram of a beam index tube of the present invention.

Figure 3 is a characteristic diagram of each beam current of the beam index tube of the present invention

4 (a) and (b) are gamma level adjustment characteristics in the beam current input region of FIG.

In order to realize the above object, the present invention detects an index stripe signal detected from a beam index tube with a photodetector, filters the detected index signal through a band pass filter and a limiter, and filters the filtered signal. An index signal processor for generating a switching pulse for serial output of the R, G, and B color signals through a phase loop circuit; A gamma level adjusting unit configured to receive and input an image signal to adjust the color difference signal processed by the image to a gamma level and a driving level of each color signal; Amplifying each color signal of the driving level adjusted by the gamma level adjusting unit and a switching pulse processed by the index signal processing unit to output an index beam current, and convert the output index beam current and the minimum beam current into voltage to convert an image signal. Characterized in that the beam current output converter for varying the gamma level of the set value.

Therefore, according to the present invention, the driving level is adjusted with respect to the received image color signal, and the driving level is detected by the index beam current value and the minimum beam current value applied to the beam index tube, and the pre-adjusted value to the image driving level by the detected current value. The gamma curve characteristic of the video luminance signal set by the controller is always actively varied, so that there is a level difference between the high luminance portion and the low luminance portion, and is lowered as the minimum current level to obtain a predetermined index stripe beam current. By improving the contrast ratio, it is possible to increase the high definition of image quality.

Hereinafter, described in detail with reference to the accompanying drawings, preferred embodiments of the present invention.

2 is an automatic gamma level control driving circuit of the beam index tube according to the present invention, wherein an index stripe signal excited to a stripe from the beam index tube 100 is detected by a photo detector, and the detected index stripe signal is band-passed and limited. An index signal processor (10) for filtering a predetermined band through the signal and generating a stable switching pulse for the serial output of the R, G, and B color signals through the phase-locked loop circuit; When the video signal is received and outputs, the color difference signal interface outputs the color difference signal RY (BY) and outputs the output color difference signal RY (BY) as R, G, B color signals through the matrix block. 20); The gamma level control unit 30 sets R, G, and B color signals output from the color difference signal interface 20 as image driving levels by preset adjustment values, and adjusts the driving level and gamma level of each set color signal. Wow; Amplifying each color signal of the driving level adjusted by the gamma level control unit 30 and a switching pulse processed by the index signal processing unit 10 to output an index beam current, and output the index beam current and the minimum beam current. And a beam current output converter 40 for converting the voltage into a voltage to vary the gamma level set value of the video signal.

The gamma level control unit 30 includes a clamp 31 for clamping the R, G, B color signals output from the color difference signal interface 20 to an appropriate DC level; A drive level unit 32 for presetting and setting an image drive level suitable for a predetermined level arbitrarily set to a DC level clamped by the clamp 31; A gamma level unit 33 which receives a drive level adjusted by the drive level unit 32 to a proper level and varies a gamma cover according to an input video signal; The R, G, and B drivers 34 driving and outputting R, G, and B color signals corresponding to the gamma level variable from the gamma level unit 33 are configured.

The beam current output converter 40 amplifies each R, G, B color signal output from the index signal processor 10 to output an index beam current Ii, and an index beam current output stage 41 and a luminance level. A minimum beam current output value output stage 42 for processing and outputting the minimum beam current value Ib according to the change of? A current / voltage converter converting an output current value into a voltage from the index beam current output stage 41 and the minimum beam current output stage processing output stage 42.

43; The controller 44 is configured to control the gamma level by the voltage output from the current / voltage converter 43 and output the set gamma level.

According to the present invention configured as described above, the video signal received and input is first subjected to image processing to become a color difference signal (R-Y) (B-Y), and the color difference signal (R-Y) (B-Y) is a color difference signal interface.

It is inputted to (20) and outputted as R, G, B color signals through the matrix.

The R, G, and B color signals output in this way are input to the gamma level control unit 30 to clamp the unit.

The clamped R, G, and B color signals are inputted to the drive level unit 32 by the pre-adjustment values to be arbitrarily set to the predetermined image drive level through the gamma level unit (31). 33).

In the gamma level unit 33, each of the R, G, and G color signals set according to the pre-adjustment values is adjusted as a driving level.

The corresponding beam current Ic is continuously input to the R, G, and B driving units 34 from the high level of the (WHITE-CLIP) to the low level of the low illumination level, and the input beam current Ic flows. ) Is amplified through the color signal switch 14 and the amplifier 15 of the index signal processing unit 10 to flow the beam current Ii to the beam index tube 5.

In this case, since the cut-off voltage and the R, G, and B signals applied to the cathode of the beam index tube 5 are applied in series, in order to apply the R, G, and B signals in series, multiple pulses or color signal switches 14 are applied. ) Detects the beam reflected by the index stripe formed on the fluorescent surface of the beam index tube 5 with the photodetector 11, and passes through the band pass filter and the limiter 12 through the frequency pass and amplitude limitation of the predetermined band. After processing at a stabilized frequency with the phase synchronization loop 13, a switching pulse for serial output of the R, G, and B color signals is generated.

On the other hand, in the gamma level unit 33, the R, G, and B color signals are adjusted by the beam current output converter 40 with respect to the index beam current amplified and output from the amplifier 15 of the index signal processor 10. The minimum beam current output value Ib is outputted from the minimum beam current output value output terminal 42, and the index beam current value output terminal 41 outputs the beam current value Ii according to the change of the luminance level.

Each output current value is converted into a voltage through the current / voltage converter 43 and input to the controller 44. The controller 44 adjusts the gamma control value Gγ when controlling the gamma level of the converted voltage. In this case, as shown in FIG. 3, the current value Ii also increases as the current value Ic increases, and a predetermined value or more should be limited.

Here, two current values indicate that a signal corresponding to a part is being input and processed.

(Ii) (Ib) If the controller 44 determines from the drive level unit 32 of the R, G, B color signals, the controller 44 responds as shown in Fig. 4 (a) (b). The gamma level control unit 33 outputs a control voltage Gγ for adjusting gamma γ that varies up to 1/2 point b of the signal luminance gradation in the following direction a.

This operation is continuously and actively performed according to the level of the input video.

Therefore, by adjusting the gamma curve according to the level difference of the signal constituting one screen, the level difference between the luminance component below the signal 1/2 point and the luminance component above the signal becomes wider, and further, the region itself of FIG. 3 is minimized. By pulling down to the region of the index stripe beam current Ib, the image quality of the beam index tube can be improved, that is, the contrast ratio can be improved.

As described above, the present invention always actively modulates a gamma curve characteristic of an image luminance signal whose value is set to be below an appropriate value of the luminance signal while the driving level of the received image color signal is adjusted. By providing a level difference between the high luminance portion and the low luminance portion, the contrast ratio lowered as the minimum current level in order to obtain a predetermined index stripe beam current can be improved, thereby improving the high definition of image quality.

Claims (3)

An index signal processor for detecting an index stripe signal excited to the stripe from the (correction) beam index tube and filtering the detected index stripe signal to produce a stable switching pulse for serial output of R, G, and B color signals ; A color difference signal interface for outputting image processing as R, G, and B color signals through a matrix block when an image signal is received; A gamma level control unit configured to set R, G, and B color signals output from the color difference signal interface as image driving levels by a preset adjustment value, and to adjust the driving level and gamma level of each of the set color signals; Wherein the drive levels controlled from the gamma level control unit of each color signal, and amplifies the switching pulse processed in the index signal processing, and outputs the index beam current, the output index a beam current and a video signal by converting the minimum beam current into a voltage An automatic gamma level control driving circuit of a beam index tube, characterized in that it is composed of a beam current output converting unit that varies a gamma level setting value of the beam index tube. (Correction) The method according to claim 1, wherein the gamma level adjusting unit includes: a clamp for clamping the R, G, and B color signals output from the color difference signal interface to an appropriate DC level; A driving level unit which adjusts and sets in advance an image driving level suitable for a predetermined level, the DC level clamped by the clamp ; A gamma level unit which receives a drive level adjusted by the drive level unit to a proper level and varies a gamma cover according to an input video signal; And an R, G, and B driver for driving and outputting R, G, and B color signals corresponding to the gamma level varied from the gamma level unit. (Correct) The index of claim 1, wherein the beam current output converting unit amplifies each of the R, G, and B color signals output from the index signal processing unit and outputs an index beam current Ii according to a change in luminance level. A minimum beam current output stage for outputting a beam current output stage and a minimum beam current value Ib; A current / voltage converter converting an output current value into a voltage from the index beam current output terminal and the minimum beam current output terminal; And a gamma level controller configured to set and control a gamma level with a voltage output from the current / voltage converter, and output the set gamma level.