KR100245525B1 - Automatic pincushion regulating apparatus for television - Google Patents

Abstract

The present invention enables to detect the distortion state of the horizontal pincushion through the ABL voltage for automatic limitation of the luminance generated from the flyback transformer in the television, and to correct the pincushion distortion in response to the detected value. The present invention provides a pincushion auto-adjustment device for a television that stores the optimal pincushion correction data according to the automatic correction and can be used for correction of the automatic pincushion distortion.

To this end, the present invention is a flyback transformer 24 for generating the ABL voltage for automatic luminance restriction by the drive operation of the horizontal deflection drive unit 22, and the horizontal generated from the horizontal deflection drive unit 22 for the horizontal deflection operation In a television having a pincushion correction unit (40) for receiving a deflection drive signal and generating a pincushion correction signal, an ABL voltage from the flyback transformer (24) is applied to an ABL level detection signal in comparison with a reference voltage (Vref). ABL comparison means 26 for generating a signal, clock generating means 28 for performing phase detection and clock oscillation operation by receiving a horizontal synchronous signal separated from an image signal, and receiving the horizontal synchronous signal and receiving the clock generating means 28. Reference pulse generating means 30 for generating a reference pulse signal serving as a detection criterion of the pincushion distortion state on the basis of the clock signal CK generated from the reference pulse; and reference pulse from the reference pulse generating means 30. The pulse difference detection means 32 generating the pincushion distortion detection signal according to the pincushion distortion detection of the ABL level detection signal based on the clock pulse of the clock signal CK, and counting the horizontal synchronization signal N times. The counter means 34 for generating a counting output and the Nth horizontal scanning period due to the counting output of the counter means 34;

Description

Pin Cushion Automatic Control Device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pincushion automatic adjustment device for a television, and more particularly, to detect EW distortion (East-West distortion) appearing on a CRT screen on a television based on the detected value. A pincushion automatic adjustment device for a television for automatically performing distortion compensation.

Currently, televisions which are generally used employ a CRT device as a direct-view image display device to reproduce a color video signal according to a television broadcast of a predetermined channel tuned through a tuner. R / G / B injection beam is injected through the R / G / B electron gun, and the electron beam is injected through the R / G / B electron gun through the shadow mask in which a plurality of holes are perforated. A predetermined color image is reproducible while being irradiated to a CRT having a fluorescent surface coated with a plurality of fluorescent materials.

Also, for the R / G / B electron beam emitted through the R / G / B electron gun in the CRT of such a television, the scanning deflection for the vertical screen is synchronized with the vertical synchronization signal of 60 Hz by the vertical deflection coil installed in the CRT. In addition, the scanning deflection of the horizontal image can be adjusted in synchronization with the horizontal synchronization signal of the composite video signal by the horizontal deflection coil.

On the other hand, in such a CRT apparatus of a television, when the screen caused by the horizontal deflection output is lowered in the center of the screen than the upper and lower screen areas, and the horizontal amplitude is reduced, the center portion of the screen is reduced.

In the pincushion correction device, when a predetermined parabola wave is formed and applied through a horizontal deflection drive signal generated from the horizontal deflection drive circuit, a horizontal pincushion correction signal is generated and applied to the horizontal deflection coil according to a user's operation state. As a result, pincushion distortion appearing on the CRT screen is corrected to ensure correct deflection.

However, in such a pincushion correction device in the television, the distortion correction of the pincushion is performed by the user's manual operation. There is a disadvantage that this takes a long time.

Accordingly, the present invention has been made in view of the above circumstances, and the distortion state of the horizontal pincushion is detected through the ABL voltage for automatically limiting the luminance generated from the flyback transformer in the television, and the pincushion distortion corresponding to the detected value is detected. It is an object of the present invention to provide a pincushion automatic adjustment device for a television that enables correction.

Another object of the present invention is to provide an automatic pincushion adjustment apparatus for a television that stores the optimal pincushion correction data according to the automatic correction of the pincushion distortion and can be used for the correction of the automatic pincushion distortion.

According to the pin-cushion automatic adjustment device of the television according to the present invention to achieve the above object, by generating the ABL voltage for automatic brightness restriction by the drive operation of the horizontal deflection drive unit

According to the present invention configured as described above, a pincushion correction unit for correcting the pulse difference value by detecting the pulse difference value by comparing the ABL voltage generated from the flyback transformer with a preset reference pulse signal in the television The pincushion correction is applied gradually, and the correction control signal having the minimum pulse difference as a result of the pincushion correction is stored in the memory means, so that it can be utilized for the subsequent pincushion correction.

1 is a block diagram showing a pincushion automatic adjustment device for a television according to the present invention.

2 is a timing chart for explaining an operation of automatically adjusting pincushion distortion by the pincushion automatic adjustment device shown in FIG. 1 according to a preferred embodiment of the present invention.

3 is a schematic diagram showing a pincushion distortion state appearing on a CRT screen.

* Explanation of symbols for main parts of the drawings

2: reception antenna 4: tuner

6: Image IF unit 8: Image detector

10: image amplifier 12: image signal processing unit

14: video output unit 16: CRT

18: horizontal deflection coil 20: synchronization separator

22: horizontal deflection drive unit 24: flyback transformer (FBT)

26: comparator 28: phase detector / oscillator

30: reference pulse generator 32: pulse difference detection unit

34: counter 36: data memory

38: control unit 40: pincushion correction

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

1 is a block diagram showing a pincushion automatic adjustment apparatus for a television according to the present invention. In the apparatus of the present invention, reference numeral 4 is a channel selection data for tuning a predetermined channel from the control unit 38, which will be described later. And tuner for tuning the corresponding channel and mixing and outputting the broadcast RF signal tuned according to the channel tuning result with the local oscillation frequency signal generated by the channel tuning data. An image IF unit for intermediate frequency amplifying a television broadcast signal is shown.

Further, reference numeral 8 denotes an image detector for detecting and separating an image signal from the intermediate frequency-amplified television broadcast signal, and 10 denotes an image amplification of the detected image signal to a signal level capable of processing image signals, and the image. A video amplifier which performs contrast adjustment and brightness adjustment operation on the luminance signal from the signal, and 12 denotes a burst signal in the signal-amplified video signal and oscillates by the burst signal to generate a color subcarrier signal. In addition, the image signal processing unit outputs the R / G / B signal through color synchronization and color signal processing by the color subcarrier signal, and 14 denotes R / G / from the image signal processing unit 12. An image output unit for amplifying and driving the B signal by the luminance signal from the image amplifying unit 10 and outputting the screen signal through the CRT 16. Indicates.

Reference numeral 20 is used to separate the synchronization signal from the video signal of the video amplifier 10.

In addition, the reference numeral 24 generates a high voltage anode voltage, a cathode voltage, and the like on the CRT 16 by the horizontal deflection driving operation of the horizontal deflection driving unit 22, and the luminance of the image amplifying unit 10. Represents a flyback transformer that generates an ABL voltage for automatic luminance limitation of a signal.

In addition, reference numeral 26 denotes an ABL level detection signal (a) of FIG. 2a and 2b (b) according to the level comparison result by comparing the ABL voltage generated from the flyback transformer 24 with the reference voltage VreF. ) And ABL comparator for generating (c) of FIG. 2C, and 28 denotes a phase detection / oscillation unit for performing a phase detection operation and a clock oscillation operation by receiving a horizontal / vertical synchronization signal from the synchronization separation unit 20. 30 denotes a short pulse shape having the same pulse interval as that between syringes in accordance with the effective video region W (see FIG. 2) of the video signal in synchronization with the clock signal CK from the phase detector / oscillator 28. A reference pulse generator that generates a reference pulse signal of?

Reference numeral 32 denotes an ABL level detection signal from the ABL comparator 26 and a reference pulse signal from the reference pulse generator 30 in synchronization with the clock signal CK from the phase detector / oscillator 28. The pulse difference detection part which detects the pulse difference value (refer (a) of FIG. 2a, (b) and (c) of FIG. 2c) of FIG.

Reference numeral 34 denotes a counter that receives a vertical / horizontal synchronization signal from the synchronization separator 20 and generates a counting output signal counted in units of 4H, for example, and 36 denotes the pulse difference detector 32. A data memory consisting of, for example, an EEPROM that stores a correction control signal for optimal pincushion correction as a result of pincushion correction based on a pulse difference value from "

Further, reference numeral 38 receives a pulse difference value from the pulse difference detection unit 32 in units of predetermined syringes such as 4H by the counting output signal from the counter 34, and pincushions based on the pulse difference value. The control unit controls the pincushion correction unit 40 to correct the error, and stores the correction control signal in the data memory 36 in a state where the pulse difference value is minimized as a result of the progressive pincushion correction.

Here, the control unit 38 detects a pulse difference signal having a pulse difference value applied from the pulse difference detection unit 32 ((a) of FIG. 2a, (b) and (b) of FIG. 2b) The difference Td of the difference pulses is calculated by calculating the equation based on Td = T × (1 / Fc), where T is the number of clocks and Fc is the clock frequency. When the interval between the syringes is 58.5 μs and the number of steps ST to be arbitrarily applied is set to 0 to 63 steps, the pincushion variable M based on the gap Td of the difference pulses is M = ST × ( Td / 58.5) is used to generate a correction control signal in accordance with the calculation result.

Further, reference numeral 40 is a pincushion for an image on the screen of the CRT 16 in response to the correction control signal from the control unit 38 under the horizontal deflection drive of the horizontal deflection drive unit 22.

Next, the operation of the present invention made as described above will be described in detail with reference to the accompanying drawings.

First, when a television broadcast signal of a predetermined channel is tuned through the tuner 4 and amplified by an intermediate frequency through the image IF unit 6, the image detector 6 detects an image signal from the intermediate frequency amplified television broadcast signal. The image amplification unit 10 amplifies the detected image signal and performs contrast and luminance adjustment on the luminance signal, while the image signal processor 12 amplifies the signal. The image output unit 14 outputs the R / G signal as an R / G / B signal through color synchronization and color signal processing by restoring the color subcarrier frequency signal by detecting the burst signal. The / B signal is amplified and driven by the luminance signal from the image amplification unit 10 and outputted to enable screen reproduction through the CRT 16.

At this time, the sync separator 20 separates the sync signal from the video signal to extract the vertical / horizontal sync signal, and the horizontal deflection driver 22 performs the oscillation operation by the extracted horizontal sync signal to perform the horizontal deflection drive. As the horizontal deflection drive signal is generated, the horizontal deflection coil 18 of the CRT 16 performs the horizontal deflection operation on the R / G / B electron beam scanned on the image screen, and the flyback trans At 24, the high pressure is supplied to the CRT 16 side through the horizontal deflection driving operation of the horizontal deflection driving unit 22, and an ABL voltage is generated for automatic luminance restriction.

That is, the current flowing through the flyback transformer 24, for example, the variation of the CRT 16 anode current.

On the other hand, the phase detector / oscillator 28 receives the vertical / horizontal synchronization signal from the synchronization separator 20 to perform phase detection and clock oscillation to generate a clock signal, while the reference pulse generator 30 A reference pulse signal RP having a short pulse shape having the same pulse interval as that between syringes according to the effective image area W of the image signal synchronously with the clock signal CK by receiving the vertical / horizontal synchronization signal. ).

In this state, when pincushion distortion (PC1 or PC2) is generated for the left / right sides of the video screen of the CRT 16 as shown in FIG. 3, in the ABL comparator 26, the flyback transformer is used. Compare the ABL voltage from (24) with a preset reference voltage (Vref) and refer to the ABL level detection signal (a) (b) (c) according to the comparison result; see FIGS. 2a, 2b, and 2c. In this case, the ABL level detection signal is a signal generated according to a comparison operation between a predetermined reference voltage Vref and a predetermined time interval as described above.

That is, the ABL comparator 26 compares / detects the reference voltage Vref and the ABL voltage applied from the flyback transformer 24 at predetermined intervals through a continuous comparison operation, and accordingly, the reference voltage Vref and the predetermined ABL voltage are predetermined. An ABL level detection signal is generated which differs by a clock frequency.

Subsequently, in the pulse difference detection unit 32, as shown in FIG. 2A, the ABL level detection signal from the ABL comparator 26 and the reference pulse generator 30 are synchronized with the clock signal CK. Compare the reference pulse signal, and follow the pulse difference from the comparison operation.

In this state, the control unit 38 receives the pulse difference signal a from the pulse difference detection unit 32 as the 4H period of the video signal passes by the counting output signal according to the counting operation of the counter 34. The difference Td of the difference pulses is calculated as an operation operation based on the above-described difference difference interval Td = T x (1 / Fc), and the pincushion correction is performed based on the difference Td of the difference pulses. The variable amount M is calculated by the formula of 'step number x (Td / 58.5)' and the correction control signal is supplied to the pincushion correction unit 40 as a result of the calculation so as to correct the pincushion distortion. . For example, when a pincushion is generated in the course of driving a video signal normally according to a preset reference pulse as a predetermined control operation, the ABL level signal is detected in an operation state that causes the pincushion, and the ABL level signal is corrected to correct the pincushion. The difference between and the reference pulse signal is calculated by a calculation operation, and a correction signal is applied to the pincushion correction unit 40 so as to have the same pulse period as the reference pulse signal.

On the other hand, the control unit 38 is a pulse difference signal ((b); see also 2b) and pulse difference signal ((c); sequentially input from the pulse difference detection unit 32 in units of 4H periods, see also 2c ) Is gradually computed to obtain the pincushion correction amount M according to the gap Td of the difference pulse and the gap Td of the difference pulse, and the correction control signal according to the calculation result is sent to the pincushion correction unit 40. As a result of the application, the pincushion correction can be performed gradually and optimally, and the pincushion data which minimizes the difference (Td) between the optimally corrected correction control signal, for example, the reference pulse signal and the ABL level detection signal, is stored. It is stored in the memory 36, and can be utilized as control data for future pincushion correction.

According to the present invention made as described above, the pincushion correction based on the difference by comparing the ABL voltage with the reference pulse signal in the television, the pincushion correction can be made automatically, This has the advantage of convenience, speed and accuracy.

Claims (3)

The flyback transformer 24 generates the ABL voltage for automatic luminance restriction by the driving operation of the horizontal deflection driving unit 22, and the horizontal deflection driving signal generated for the horizontal deflection operation from the horizontal deflection driving unit 22 is applied. In a television equipped with a pincushion correction unit (40) for receiving a pincushion correction signal, An ABL comparison means 26 for receiving an ABL voltage from the flyback transformer 24 and generating an ABL level detection signal compared to a reference voltage Vref; Clock generating means (28) for receiving a horizontal synchronization signal separated from the video signal to perform phase detection and clock oscillation operations; Reference pulse generating means (30) for receiving the horizontal synchronization signal and generating a reference pulse signal as a reference for detecting a pincushion distortion state based on the clock signal (CK) generated from the clock generating means (28); Pulse difference detection means for generating a pincushion distortion detection signal according to the pincushion distortion detection of the ABL level detection signal based on the clock pulse of the clock signal CK based on the reference pulse signal from the reference pulse generation means 30 ( 32), A counter cushion 34 for counting the horizontal synchronizing signal N times to generate a counting output, and a pincushion from the pulse difference detecting means 32 for every Nth horizontal scanning period by the counting output of the counter means 34. Recognizing the distortion degree of the pincushion by receiving the distortion detection signal and outputting a correction control signal for correcting the distortion degree to the pincushion correction unit 40. The method of claim 1, wherein the reference pulse signal generated by the reference pulse generating means 30 is generated in the form of a short pulse having the same pulse interval as the interval between syringes according to the effective video region of the video signal. Pin cushion automatic adjustment device. The data storage device according to claim 1, further comprising a data memory (36) for storing said correction control signal generated so that the pincushion distortion degree with respect to the pincushion distortion detection signal from said pulse difference detecting means (32) is minimized, The control means 38 gradually performs pincushion correction control for the pincushion correction unit 40 in the Nth horizontal scanning period, and thus the degree of pulse difference of the pincushion distortion detection signal from the pulse difference detection means 32 is obtained. The apparatus for automatically adjusting the pincushion of a television, characterized in that it is configured to store a correction control signal which is minimized in the data memory (36).

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