KR830000627B1 - Color TV receiver - Google Patents

Abstract

No content.

Description

Color TV receiver

1 is a schematic diagram of an example of a receiver of the present invention.

2 through 6 are provided for illustration.

The present invention relates to a color television receiver using a color picture tube of a beam index type. The color index tube of the beam index method scans the fluorescent surface of red, green, and blue color phosphor bands in which a single beam is sequentially arranged in the horizontal scanning direction, and the index phosphor band arranged in the horizontal scanning direction on the inner surface of the fluorescent surface. When the electron beam scans the red color phosphor band according to the index signal obtained by scanning, the primary color signal of the blue color is density-modulated.

In this case, in order to ensure that the fluorescent screen is always at the correct timing, and that the color reproduction is always accurate, the index signal must always be obtained despite the content of the video signal. Therefore, even in the black level of the video signal, It is necessary to allow some beam current to flow without blocking current in the receiver. Furthermore, in this case, it is necessary to ensure that the index signal of a certain size is surely obtained at the black level of the video signal in consideration of the disturbance of the characteristics such as the blocking level of the water pipe and the secular variation of these characteristics.

The present invention makes it possible to realize such a demand by simple means.

According to the present invention, a potential is applied to the receiving tube so that a predetermined period of time between the syringes, for example, the horizontal scanning initiation portion, can flow a relatively large beam current in the period, and at the same time, The potential is controlled so that the magnitude of the signal is constant, and a color signal is applied to the receiving tube based on the potential changed by a constant potential in a direction in which the beam current decreases with respect to the controlled potential.

According to the present invention, a beam index type color television may be configured to apply a potential to a receiver to supply a beam current for a predetermined period of time between a beam index color cathode ray tube having a screen and a syringe, that is, a region in which the beam is scanned. A device, a device responsive to an index signal to generate a chair signal of a level based on the beam current, a device that controls the potential to maintain a constant level of the chair signal, a shift from the control potential in a direction to reduce the beam current A device for generating a reduced reference potential, and a device for applying a color signal to a cathode ray tube as a reference level of an applied color signal during scanning of an image area by an electron beam.

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

FIG. 1 is a specific example of a color television receiver according to the present invention, wherein 11 is a color index tube of a beam index type, and is configured as shown in FIG. 4 as an example.

That is, red, green, and blue color phosphor strips R, G, and B are sequentially arranged in the horizontal scanning direction on the inner surface of the panel to form an effective screen portion 12, and in this case, between the color phosphor strips R, G, and B; In the periphery of the effective screen portion 12, a layer 14 of black material is formed and a metal pack 15 is formed over its entire surface. The index phosphor band I on the metal pack 15 is arranged in the horizontal scanning direction across the effective screen portion 12 and one horizontal scanning and presentation portion 14 thereof, so that the red, green, and blue color phosphor bands R, G, and B A pair of pitches is formed, for example 2/3 pitches. The index phosphor band I is provided at positions between the color phosphor bands R, G and B of red, green and blue.

Figure 1. For reference, in the outer example of the panel portion of the color receiver 11, a photodetector 19 for detecting the light 20 emitted when the electron beam 13 scans the index phosphor band I is disposed.

The horizontal synchronizing pulse P _H (FIG. 2) is supplied to the set side of the flip flop circuit 21 and the output of the flip flop circuit 21 at the rear edge of the pulse P _H as shown in FIG. 2. The signal F _X wins. As will be described later, the flip-flop circuit 21 is reset when the electron beam scans the boundary positions of the horizontal scanning start section 17 and the effective screen section 15 so that the output signal F _X is reset. It is received. When the output signal F _X of the flip-flop circuit 21 is supplied to the switch circuit 22 to be at the logic "1" level, the switch circuit 22 is turned on, and during this period, The resulting potential V _H is supplied to the first grid 24 of the receiving tube 11 so that the beam current flows, so that the electron beam 13 scans the index phosphor band I of the horizontal scanning initiation section 17. This results in an output signal from the photodetector 19.

Is the output signal of the photodetector 19 is supplied to a band-pass filter 25 is a frequency index signal (S _I) determined by the pitch of the index I between the phosphor strip is supplied. FIG. 2 shows only a part of the horizontal scanning time section 3 in the period.

The index signal S _I is supplied to the amplitude detection circuit 26 to amplitude detection to obtain a detection voltage V _D. 2 shows only a portion of the horizontal scanning start section 17 in the period. It is supplied to the sampling and holding circuit 27 of the detection voltage V _D of the amplitude detection circuit 26 and sampled and held by the output signal F _X of the flip-flop circuit 21. Therefore, as the output voltage V _H of the sampling and holding circuit 27, the held value of the value at the end of the period of the horizontal scanning start section 17 of the detection voltage V _D of the amplitude detection circuit 23 is obtained. The output voltage V _H of the sampling and hold circuit 27 is supplied to the comparator 23 and compared with a preset reference voltage by the variable resistor 28.

Therefore, during the period of the horizontal scan start unit 17 in the period, the output voltage is such that the comparator 23 takes a constant beam current flows index signal (S _I) of a predetermined size that is initiating the horizontal scanning part 17 of the correlation The feedback of the voltage V _M given to the first grid 24 of (11) is controlled. In this case, the variable resistor 28 is selected in the period of the horizontal scan initiation unit 17, so that a relatively large beam current flows so that a relatively large index signal responsive to the column image for the index band I of the scan initiation unit 17 ( S _I ) is obtained.

On the other hand, the demodulated red, green, and blue primary color signals E _R , E _G , and E _B are supplied to the black level compensation circuit 26, which is, for example, a clip circuit or a clamp circuit, and output voltage V of the comparator 23. _M ) is supplied to the level shift circuit 30 to obtain a voltage V _B which is lowered by a constant potential than the voltage V _M , and this voltage V _B is supplied to the black level compensation circuit 29 to supply each primary color signal. is not to be less than the voltage (V _B) that is controlled so that the voltage V _B of the black level.

When this voltage V _B is given to the eleventh grid 24 of the water pipe 1 as described later, the electron beam 13 modulates a current so that a sufficient beam current flows at the black level of the image signal so that The index band I of the effective screen unit 15 is sufficiently excited. During the period in which the controlled primary color signals are supplied to the switch circuits 31R, 31G and 31B and pass through the effective display section 15, the switch circuits 31R, 31G and 31B are index signals S _1. In response to), the color signals are turned on at the positions of the color strips R, G, and B in turn, and the color signals are synchronized to the first grade 24 of the water pipe 11.

If the blocking level of the receiving pipe is disturbed or if it changes over time, the characteristic between the driving voltage and the level of the index signal S ₁ does not change the value of the so-called V of the receiving pipe depending on the characteristic between the driving voltage and the cathode current. 3, it changes to move in parallel as shown by curves 31 and 33. As shown in FIG. Even if the characteristic is changed in this way, the output of the comparator 23 is maintained such that the level of the index signal S ₁ is constant as shown by (V _M ) during the runner period of the horizontal scan initiation unit 17. Since the voltage V _M is controlled, even if the output voltage V _M of the comparator 23 is changed to be (V _M1 ) or (V _M2 ) by the change of this characteristic, the level shift circuit 30 is used therefrom. The voltage V _B lowered by the constant voltage changes as (V _B1 ) or (V _B2 ). Therefore, even if the characteristic changes, the level of the index signal S ₁ obtained at the black level is represented by (VB). It becomes constant.

As described above, according to the present invention, it is possible to ensure the minimum beam current stably and reliably and always obtain the minimum necessary index signal despite the content of the video signal.

Referring to FIG. 5, in the beam index type color television receiver 10 described with reference to FIG. ₁ , the detector 26 which detects the amplitude of the index signal S ₁ is bandpassed with the capacitor 26a. The resistor 26 connected between the output of the filter 25 and the ground is connected in series, and the resistor 26d connected between the junction of the capacitor 26a having the diode 26c and the resistor 26b and the ground is connected in series. will be.

The output voltage V _D from the detector 26 is generated at the junction of the diode 26c with the resistor 26d and is connected between the switch 27a and the ground and charged in response to the closing of the switch 27a. It is sampled because the switch 27a of the sampling and holding circuit 27 constituted by the above is closed. Comparator 23 is shown as an operational amplifier 23a, the pressure of one side of which is connected to the junction of a switch 27a with a capacitor 27b, while the other input of the operational amplifier 23a is a variable resistor 28. ) The level shift circuit 30 is composed of a zener diode 30a to obtain the teh output voltage V _M from the operational amplifier 28a and to supply the individual reference potential V _B to the black level compensation circuit 29.

As shown in FIG. 5, the black level compensation circuit 29 is composed of the clamping capacitors 34R, 34G, and 34B and the primary color signals E _R , E _G , and E passed through them. _B ) is separately applied to the switching circuits 31R, 31G and 31B. The reference potential V _B from the zener diode 30a is filtered or stabilized by the filter circuit composed of the resistor 35 and the capacitor 36 so that the predetermined stable reference condition V _B ′ has a predetermined amplitude and is clamped at the same time. The line connecting the capacitor 34R and the switch 31R via the diodes 37R, 37G and 37B, the line connecting the capacitor 34G and the switch 31G, the capacitor 34B and the switch 31B. To be supplied separately to the connecting line.

As in the prior art, the primary colors signals E _R , E _G and E _B supplied to the compensation circuit 29 already have a synchronization or blanking portion from which the video signal has been removed therefrom so that the lowermost part is not the synchronization tip part. Make a postmarked part. However, diodes 37R, 36G and 37B and capacitors 34R, 34G and 34B cause the portion of the highest black level of the primary color signal to be clamped to a stable reference potential (V _B '). Then, the minimum voltage value of the signal supplied via the switch circuits 31R, 31G and 31B is brought to the previous position V _B '.

Referring to FIG. 1, in order to control the operation of the switching circuits 31R, 31G, and 31B in the non-impression type color television receiver 10 for the purpose of color switching, the bandpass filter 25 is used. The index signal S ₁ (FIG. 4) from is supplied to the PLL circuit 38 to obtain a frequency signal SL twice the frequency of the signal S _{1 in} synchronization with the index signal S ₁ .

As shown in FIG. 6, the PLL circuit 38 has a center frequency, but has a frequency approximately twice that of the index signal S ₁ , and a frequency divided by one half of the frequency divider 40. It consists of a voltage controlled generator 39 for generating a. The phase adjusted pulse from the phase shifter 41 is supplied to the phase comparator 41 and phase compared with the index signal S ₁ from the band pass filter 25. The final comparison error voltage by the phase comparator 42 is equal to the low bandpass filter 43, so that the control voltage for the voltage controlled generator 39 causes the frequency of the index signal S ₁ to be phase locked up to twice. Generate a pulse S _I. Pulse (SL) is a ring that generates a pulse _{(F R), (F G} ) and (F _B) in a third frequency band of the third frequency, i.e., frequency index signal (S _I) of his frequency-counter (ring and the pulses F _R , F _B and F _B are phase shifted by 120 ° as shown in FIG. 4.

On the other hand, the index signal S _I from the bandpass filter 12 is supplied to the pulsed circuit 45 so that the index pulse S _P that stands at the intersection of zero when the index signal S _I moves from the positive to the negative. Is obtained and the index pulse S _P is supplied to the counter 46 so that the index pulse _SP is counted in the period of " 1 " of the output signal F _X of the flip-flop circuit 21.

Therefore, the index pulse S _P in the horizontal scan initiation unit 17 is counted as shown by 1, 2, 3 in the figure, and the preset value, i.e., the horizontal scanning initiation unit of the index phosphor band I in the drawing. When counted to 8 corresponding to the last one at (17), negative pulse S _C is obtained at counter 46. Then, when the pulse (S _C) is supplied to the monostable multivibrator 47, the pulse (S _C) is a far-vibrator 47 is triggered at the time of the particulate having a pulse width required for the timing control pulses (S _M) is Obtained.

The flip-flop circuit 21 is reset at the rear edge of the pulse S _M , and the output signal F _X is received as "0" as described above.

The pulse S _M is supplied to the ring counter 44, and the output signal S _L of the PLL circuit 38 is divided into 1/3 each other in a state regulated by the pulse S _M. The red, green, and blue division pulses F _R , F _G , and F _B are obtained by 120 °.

The division pulses F _R , F _G , and F _B are supplied to the gate circuit 48, while the output signal F _X of the flip-flop circuit 21 described above is supplied to the gate circuit 48. Supplied to the gate circuit 48 during the period of " 0 " of the signal F _X , i.e., during the effective display unit 17, the division pulses F _R , F _G and F _B are applied to the gate signal ( G _R ), (G _G ) and (G _B ).

The switch circuits 28R, 28G, and 28B are turned on as described above in the section "1" of the gate signals G _R , G _G , and G _B.

Therefore, when the electron beam 13 scans the red phosphor strip (R) with the primary color signal (E _R ) of the red, the green color phosphor band (G) is used to scan the green phosphor strip ( _G ), and the blue phosphor strip ( When scanning B), the primary color signal (E _B ) of blue is respectively modulated.

In the photodetector 19 instead of the index signal (S _I) from the bandpass filter 25. The output signal itself is the full width detection circuit 26. The amplitude can be detected. In addition the output signal of the band index signal from the pass filter (25) (S _I) or optical detector 19 is compared with a dust reference voltage of the comparison output voltage may be detected.

In the present invention, when the pitch of the index phosphor band (I) different from the example in the figure is generally an integer multiple, such as a pair of pitches of the red, green and blue color phosphor bands (R), (G) and (B) Can also be applied to

As described above, according to the present invention, by using a predetermined period between syringes, it is possible to ensure the minimum beam current stably and reliably, and the index signal is always turned on despite the contents of the video signal.

Moreover, when using the period of the horizontal scanning time unit as in the example of the figure, there is an advantage that the color switching is surely controlled since the index signal in this period is controlled to be obtained with certainty and with sufficient magnitude.

Claims (1)

1. A color television receiver having a beam-indexed color receiver, comprising: an apparatus for applying a potential to the receiver so that the beam current can be supplied for a predetermined period between syringes; and an index signal for generating a level control signal in accordance with the beam current. A device responsive to the device; a device for controlling said potential to maintain a constant level of said control signal; a device for providing a reference potential shifted from a potential controlled in a direction of decreasing beam current; And a device for applying a color signal to the receiver as a reference.

Images