KR100202563B1 - The image signal auto-correcting apparatus of tv - Google Patents

Abstract

The present invention relates to a device for automatically correcting a video signal of a TV. In the related art, when a bright screen is input, the ABL voltage is lowered, and at the same time, the voltage divided by the resistor is also lowered, so that the control level of contrast and bright is lowered. When a dark screen is input, when the ABL voltage increases, only the measurement part becomes a bright screen while most of the screen is dark, so peak value limit control is not possible and R, G, B color bleeding occurs at the end of the bright screen part. There is a problem that the image quality is deteriorated by. In order to solve such a conventional problem, the present invention has been devised to eliminate color bleeding and horizontal curling by correcting the fluctuation voltage by detecting the magnitude of the fluctuation of the ABL voltage. Is minimized by the level shifting means, and when the peak driving control output is maximized on a dark screen, the color shift of the primary color signals R, G and B is eliminated by limiting the level more than necessary among the R, G and B outputs. On-screen text blurring or horizontal curling caused when the screen changes, that is, when the screen is changed from a dark screen to a bright screen or a bright screen to a dark screen, can be removed.

Description

TV video signal automatic correction device

1 is a block diagram of a conventional video signal correction device.

2 is an exemplary diagram of an image processing signal.

3 is an exemplary view showing color bleeding.

4 is a circuit diagram of a video signal automatic correction device of the present invention.

5 is a waveform diagram showing a change in the ABL voltage in FIG.

6 is a waveform diagram according to the voltage variation recognition in FIG.

7 is a signal flowchart for automatically correcting an image signal of the present invention.

* Explanation of symbols for main parts of the drawings

210: image processing unit 210-1: color signal output unit

210-2: peak drive unit 220: microcomputer

220-1: control unit 220-2: beam recognition unit

230: signal level control unit 240: voltage comparison unit

250: voltage fluctuation recognition unit 260: level shift unit

270: delay unit 280: ABL unit

290: CPT amplification unit

The present invention relates to automatic correction of an image signal, and more particularly, to an automatic correction apparatus for a video signal of a TV, which is capable of automatically correcting a phenomenon in which color changes in accordance with the brightness of an image signal in a television.

1 is a block diagram of a conventional apparatus, as shown therein, an image processor 100 for outputting an image processed signal to a CPT amplifier 140 by inputting primary color signals R, G, and B, and a beam; The ABL unit 130 outputs a voltage changed by a current, and the control voltage output unit 120 controls the voltage of the ABL unit 130 to be input to the image processor 100.

The image processor 100 may include a color signal output unit 100-1 for adjusting contrast and bright of primary color signals R, G, and B, and a color signal output unit 100 at an output voltage of a control voltage output unit 130. And a peak value driver 100-2 for setting the contrast and bright level of -1).

Referring to the operation of the conventional device as follows.

In the image processing unit 100 that receives the primary color signals R, G, and B, the color signal output unit 100-1 adjusts the contrast and the brightness according to the contrast and the brightness level of the peak value driving unit 100-2. R1, R2, and R3 are respectively output to the CPT amplifier 140.

At this time, when the ABL unit 130 of the flyback transformer outputs a voltage changed according to the beam current, the control voltage output unit 120 passes through the diode D1 and the resistor R6 to the resistors R4 and R5, respectively. The divided voltage (about 4V) is controlled and the controlled voltage is input to the image processor 100.

Accordingly, the image processor 100 adjusts the contrast and brightness levels of the color signal processed by the color signal output unit 100-1 by the peak driver 100-2 receiving the control voltage of the control voltage output unit 120. Control.

However, in the related art, the deviation of the voltage divided by the resistors R4 and R5, that is, the voltage waveform changed in the ABL unit 103 is directly controlled through the diode D1 and the resistor R6, so that the deviation of the minimum voltage and the maximum voltage is reduced. It gets bad.

Therefore, in the related art, when the bright screen is input, the voltage of the ABL unit 130 is lowered, and at the same time, the voltage divided by the resistors R4 and R5 is also lowered, so that the control level of contrast and bright is lowered.

In addition, conventionally, when a dark screen is input, when the voltage of the ABL unit 130 rises (V _{R4 / R5} V _ABL ), most of the screen is dark when the voltage divided by the resistors R4 and R5 is input. Since only the measurement part is saturated as shown in Fig. 2 and becomes a bright screen, it is impossible to control the peak limit, and thus, the image quality is deteriorated by R, G, B color bleeding phenomenon as shown in Fig. 3 at the end of the bright screen part. .

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide an automatic image signal correcting apparatus of a TV, which is capable of eliminating color bleeding and horizontal curling by correcting a change in voltage by detecting a change in the ABL voltage to improve a conventional problem. have.

The present invention provides an image processing means for controlling the contrast and bright levels of the primary color signals R, G, and B to be input to the CPT amplification means, and to limit a predetermined level of the output voltage of the image processing means in order to achieve the above object. Signal level control means, an ABL means for outputting a voltage according to the beam current variation, a level shift means for dividing an output voltage of the ABL means, and a delay for delaying the instantaneous level rise of the input voltage of the level shift means. Means and the output voltage Va of the level shift means and the reference voltage Vc are compared to stop the operation of the signal level control means when the reference voltage Vc is greater than the output voltage Va of the level shift means. The voltage comparison means for operating the signal level control means and the output voltage Va of the level shift means A voltage fluctuation recognition means for firstly compensating the input voltage of the level shift means and a contrast and bright level of the image processing means by sensing the output voltage Va of the level shift means and correcting the voltage fluctuation recognition means And a control means for outputting a voltage to second-compensate the input voltage of the level shifting means.

The control means senses the output Va of the level shifting means and operates the image processing means normally when it falls within a predetermined range (V1V2V3), and when it is smaller than a predetermined voltage V1 (VaV1), adjusts the brightness level of the image processing means. When the voltage is lower than the predetermined voltage V2 (VaV2), an operation of limiting the peak voltage level of the image processing means is performed.

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

4 is a block diagram of the present invention, as shown therein, an image processing unit 210 for controlling the contrast and bright levels of the primary color signals R, G, and B to be input to the CPT amplifier 290, and this image. A signal level controller 230 for limiting a predetermined level among the output voltages of the processor 210, an ABL unit 280 for outputting a voltage according to a beam current variation, and a voltage divider for the output voltage of the ABL unit 280 A level shift unit 260, a delay unit 270 for delaying the level rise of the input voltage of the level shift unit 260 when the instantaneous level rise of the output voltage of the ABL unit 280 is delayed; A voltage comparator 240 for removing the saturation component of the primary color signals R, G, and B output from the signal level controller 230 by comparing the output voltage of the signal 260 with the reference voltage, and the level shifter 260. The input of the level shifter 260 is detected when the output of the signal senses that the output of the level is momentarily lowered. The contrast and brightness levels of the image processor 210 are controlled according to the voltage fluctuation recognition unit 250 and the output of the level shift unit 260, and the voltage fluctuation recognition unit 250 is compensated for. The microcomputer 220 is configured.

The image processor 210 includes a color signal output unit 210-1 and a peak value driver 210-2.

The microcomputer 220 supplies a compensation voltage to the voltage fluctuation recognizing unit 250 under the control of the controller 220-1 controlling the contrast and the bright level of the image processor 210 and the controller 220-1. It consists of the beam recognition unit 220-2 to be input.

The signal level controller 230 connects the Zener diodes ZD1, ZD2, and ZD3 in parallel to the output terminals R, G, and B of the image processor 210 in reverse directions, respectively. The anode is commonly connected and its connection point is commonly connected to a resistor R13 having a voltage Vcc connected to one side, a resistor R14 having one side grounded, and a collector of transistor TR1 having an emitter grounded, and the transistor TR1 connected. Is connected to the voltage comparator 240.

The voltage comparator 240 connects the voltage Vcc to the emitters of the transistors TR2 and TR3 to divide the voltage Vcc so that the connection point of the resistors R15 and R16 connected to the base ( The collector of TR2 is connected to the signal level controller 230 and grounded through the resistor R21, and the base of the transistor TR3 having the collector grounded is divided by the resistor R19 to divide the voltage Vcc. The connection points of the resistors R18 and R20 and the output terminals of the level shift unit 260 are connected to each other.

The voltage fluctuation recognition unit 250 connects the emitter of the transistor TR6 to which the output of the level shift unit 260 is connected to the base through the capacitor C4 and the pull-up resistor R29 is connected to the voltage Vcc. By connecting the collector of the transistor TR6 to which the ground resistor R28 is connected to the base of the transistor TR5 to which the collector is connected to the voltage Vcc, and the microcomputer 220 via the resistor R27. The cathode of the diode D3 is grounded by connecting an emitter of the transistor TR5 connected to the output terminal of the beam recognition unit 220-2 and the ground resistor R26 connected to the anode of the diode D3. It is connected to the condenser C3, and is connected to the input terminal of the level shift section 260 through the resistor R25.

The level shift unit 260 connects the collector of the transistor TR4 having the output terminal of the ABL unit 280 connected to the ground to the ground resistor R22, and the emitter of the transistor TR4 having one side grounded. And a terminal PM of the image processing unit 210, a terminal Ci of the microcomputer 220, and an input terminal of the voltage fluctuation recognition unit 250.

The delay unit 270 is configured by grounding the output terminal of the voltage variation recognizer 250, the input terminal of the level shift unit 260, and the output terminal of the ABL unit 280 through the capacitor C2 and the resistor R23 sequentially. .

Referring to the operation and effect of the present invention configured as described above are as follows.

In the ABL section 280 of the flyback transformer FBT, a voltage changed according to the beam current is input to the level shift section 260 through the diode D1 and the resistor R24 as shown in FIG. When applied to the base of TR4, the voltage Va from the emitter of the transistor TR4 is applied to the terminal PM of the image processor 210, the voltage comparator 240, and the terminal Ci of the microcomputer 220. And an input terminal of the voltage fluctuation recognition unit 250.

In this case, the waveforms of the base voltage and the emitter voltage of the transistor TR4 are as shown in FIG. 5 (a) and (b), and the maximum base voltage is greater than the voltage V _B of the ABL unit 280. The voltage V _B is divided by the resistances R18 and R20. V) -V _BE voltage is about 3.3V.

The minimum base voltage of the transistor TR4 is such that the voltage divided by the resistors R18 and R20 is the voltage of the diode D1 (D2), that is, V _D1 + V _D2 + V when the ABL voltage is smaller than the voltage V _B. About 2.1V as _ABL 2.3V.

Accordingly, the voltage comparator 240 controls when the voltage input from the level shifter 260 is low and high.

That is, when the input voltage is low, the voltage comparator 240 has an output voltage Va of the level shifter 260 that is larger than the voltage Vc divided by the parallel resistors R15 and R16. Since the transistor TR3 is turned off and the transistor TR3 is turned on, the voltage Vb of the collector b of the transistor TR2 becomes almost zero.

Accordingly, since the signal level controller 230 is in a non-operating state, that is, a condition such as no circuit, the current state operates in a normal condition, and the output signal of the image processor 210 is input to the CPT amplifier 290 as it is. Lose.

In addition, in the microcomputer 220, the control unit 220-1 that receives the output Va of the level shift unit 260 has a voltage of 3.3 V at the terminal Ci. The contrast and bright levels of the primary color signals R, G, and B are controlled by controlling the color signal output unit 210-1 and the peak value driver 210-1 of the image processor 210 under normal conditions by determining that the signal is 3.9V. Will be adjusted.

On the other hand, when the screen state is dark, the beam current is lowered while the ABL voltage is increased so that the base voltage V _BTR4 of the transistor TR4 is maintained at a maximum of 3.3 V and the output voltage Va is maximum at the level shift unit 260. The voltage is approximately 4V, and the image processor 210 receiving the output voltage Va controls the R, G, and B output levels to convert the primary color output signals R, G, and B into peak voltages as much as the input voltage level. V _PP ) will be output at the level.

At this time, since the output voltage Va of the level shift unit 260 is larger than the divided voltage Vc by the resistors R15 and R16, the voltage comparator 240 turns off the transistor TR3 and the transistor TR2. Is turned on to turn on the transistor TR1 of the signal level controller 230.

Accordingly, the signal level controller 230 turns on the zener diode ZD1 by turning on the transistor TR1. ZD3) operates to control the necessary components of the output signal components of the image processor 210, such as the third diagram generated when the R, G, and B signal components are saturated and cut out by the CPT amplifier 290 as shown in FIG. R, G, B bleeding can be prevented.

In addition, when controlling the R, G, and B spreading through the signal level controller 230, the microcomputer 220 receives the output voltage Va of the level shift unit 260 from the control unit 220-1. It is determined that the voltage Va of Ci is greater than 3.9V, and the data controlled by the peak value limit control stage is adjusted by adjusting the driving range of the peak value driver 210-2 of the image processor 210 through the I ² C line. The level of the primary color signals R, G, and B output from the processor 210 is adjusted.

Here, the driving range of the peak value driver 210-2 is adjusted to 3.7V when the peak value voltage V _PP is 4V.

Therefore, the primary level compensation is quickly processed through the signal level controller 230 and the voltage comparator 240, and the secondary compensation is processed to operate stably through the microcomputer 220.

In addition, when the light screen changes from the bright screen to the dark screen in an instant, the delay unit 270 including the capacitor C2 and the resistor R23 has a sharp base voltage V _BTR4 of the transistor TR4 of the level shift unit 260. To prevent it from rising.

Accordingly, when the on-screen text is displayed on the screen of the TV, when the screen is changed from a bright screen to a dark screen, the input voltage V _btr4 and the output voltage Va of the level shift unit 260 increase rapidly, and the on-screen text is instantaneously increased. To prevent smudges.

On the other hand, the dark screen (Va Bright screen (Va) in V In case of V), the momentary fluctuation causes the ABL voltage to become the minimum, and when the beam current flows to the maximum as shown in section (d) in FIG. Phenomenon occurs, in order to prevent this, transistors TR5 and TR6, capacitors C3 and C4 and resistors R25. The voltage fluctuation recognizing unit 250 composed of R31 is added.

That is, when the output voltage Va of the level shift unit 260 changes instantaneously, when the changed voltage is low, the beam current also changes normally so that normal operation is performed, but when the change of the screen changes from a dark to a bright screen. The beam current changes from minimum to maximum.

At this time, the voltage fluctuation recognition unit 250 that inputs the changed ABL voltage, that is, the output voltage Va of the level shift unit 260, may have a change voltage of about 7V _PP or more as shown in FIG. At this time, the transistor TR6 whose base voltage is 0.7 V _PP or less than the emitter voltage is turned on to apply the voltage Vd to the base of the transistor TR5.

Accordingly, the voltage Vd output through the transistor TR6 is input to the level shift unit 260 through a buffer composed of the transistor TR5 and the resistor R26, the diode D3, the resistor R25, and the like. The voltage applied to the base of the transistor TR4 primarily compensates for the ABL voltage level lowered momentarily.

When the output voltage Va of the level shift unit 260 changes from 4V to 3V, when the microcomputer 220 determines that the amount of change in voltage is above a certain set voltage, that is, the voltage of the terminal Ci is lowered by 1V. In this case, the controller 220-1 compensates the turn-on time of the transistor TR5 by inputting the output Bo of the beam recognizer 220-2 to the voltage fluctuation recognizer 250 for a predetermined time H so as to compensate for the turn-on time of the transistor TR5. Will be compensated secondarily.

Accordingly, the ABL voltage level compensation is somewhat unstable as the first compensation of the voltage fluctuation recognition unit 250 by the second compensation in the microcomputer 220 to stabilize the instantaneously from the dark screen to the bright screen. It can prevent the horizontal curl phenomenon that occurs when the change is made, so that a smooth screen can be obtained.

The operation of the microcomputer 220 is performed in the same manner as the signal flow of FIG.

As described in detail above, the present invention minimizes the change in the ABL voltage change through the level shift means and restricts the level of the R, G, and B outputs when the peak driving control output is maximum in a dark screen, thereby limiting the primary color signal. Eliminates color bleeding of (R, G, B), and also eliminates on-screen text bleeding or horizontal curling that occurs when a screen changes, that is, when changing from a dark screen to a bright screen or a bright screen to a dark screen. There is.

Claims (3)

Image processing means for controlling the contrast and bright levels of the primary color signals R, G, and B and inputting them to the CPT amplifying means, signal level control means for limiting a certain level of the output voltages of the image processing means, and beam current variation ABL means for outputting a voltage according to the above, level shifting means for dividing the output voltage of the ABL means, delay means for delaying the instantaneous level rise of the input voltage of the level shifting means, and output voltage of the level shifting means Voltage comparison means for controlling the signal level control means by comparing Va and the reference voltage Vc, and when the output voltage Va of the level shift means is momentarily leveled down, the input voltage of the level shift means is reduced. Contrast and bra of the image processing means by sensing voltage fluctuation recognition means for first compensation and output voltage Va of the level shift means. And a control means for controlling the level of the bit and outputting a correction voltage to the voltage fluctuation recognizing means to compensate the input voltage of the level shift means for the second time. The voltage comparing means is configured to stop the operation of the signal level control means when the reference voltage Vc is greater than the output voltage Va of the level shift means, and to operate the signal level control means when the reference voltage Vc is smaller. Automatic image signal correction of the TV. The image processing means according to claim 1, wherein the control means senses the output Va of the level shift means and normalizes the image processing means when it falls within a predetermined range (V1VaV2) and is smaller than a predetermined voltage V1 (VaV1). And lowering the bright level of the video signal (VaV2) when the voltage level is higher than the predetermined voltage (VaV2).