KR830002192B1 - TV receiver - Google Patents

Abstract

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Description

TV receiver

1 is a schematic diagram of an example of a beam index type color television receiver according to the present invention.

2 is a schematic diagram of main parts of another example.

3 to 8 are diagrams for explaining the operation.

A beam index type color television receiver has a single electron beam as a receiving tube, and has a fluorescent surface in which red, green, and blue phosphor stripes are arranged in a horizontal direction, and an index phosphor strip is arranged in a horizontal direction on an inner surface of the fluorescent surface. it is used, the electron beam is, the index signal obtained by the Sikkim scanning the index phosphor stripes, for example, supplied to the P _LL, and the color changer by the output signal of the P _LL, the electron beam is scanning a red phosphor stripe In this case, the red primary color signal is used to scan the green phosphor stripe and the green primary color signal is used to scan the blue phosphor stripe.

The frequency of the index signal is inversely proportional to the pitch of the index phosphor stripe and is proportional to the scanning speed of the electron beam. To this end, there is the left and right pin cushion distortion, the scanning speed of the electron beam is, each line, that is, the change in the vertical direction, and the frequency of the index signal is changed in each line, that is, vertical direction, and the incoming range of the above-described P _LL There is a fear that color reproduction will not occur at all. In particular, when the index signal is weak as a dark screen, the incoming range of the P _LL is narrowed, and such a concern is further increased.

Conventionally, even in a general television receiver, in order to correct left and right pincushion distortion, the power supply of the horizontal deflection circuit is modulated into a parabolic waveform in a vertical period, and a saturable reactor is connected in series to the horizontal deflection coil, and this is parabolic in a vertical period. The method of controlling by waveform was adopted. However, either of them is not sufficiently corrected, and the change in the horizontal amplitude due to the variation of the heavy industry does not need to be compensated very much, and there is inconvenience such as requiring adjustment.

In particular, in the beam index type color television receiver, the left and right pincushion distortions can be almost completely corrected with a simple configuration, and at the same time, the horizontal amplitude changes due to variations in the labor industry can be corrected.

FIG. 1 is an example of a beam index type color television receiver according to the present invention, and 10 is a beam index type color picture tube, for example, red, green and blue phosphor stripes R, G as shown in FIG. And an index phosphor stripe I is formed as a pitch of 2/3 of a pair of pitches of the color phosphor stripes R, G, and B over the effective screen portion 11 on which B is formed and the horizontal scanning start portion 12 on the left side thereof. The photodetector 21 is provided outside the panel portion.

Horizontal and vertical blanking pulses P _B are supplied to the switch 28 so that the switching 28 is turned off during the period of " 0 " of the pulse P _B , i.e., the horizontal and vertical return periods, so that the water pipe 10 is cut. The switch 28 is turned on as a period of " 1 " of the pulse P _B , that is, as a horizontal scan period within the vertical scan period. As a trailing edge of the blanking pulse P _B , an R _S flip-flop 41 is set so that its output signal P _W becomes " 1 " so that its output signal P _W is supplied to the switch 26, and in the period of " 1 " The switch 26 is switched to the terminal W side so that the direct current electric power supply from the electric power source 27 is supplied to the first grid 13 of the water pipe 10 so that the electron beam is relatively large, and the horizontal scanning start portion ( 12), and the light from the index phosphor stripe I of the horizontal scanning initiation portion 12 is detected by the photodetector 21.

The output signal of the photodetector 21 passes through the band pass filter 22, and passes through the phase adjuster 23, thereby indexing the frequency f _I determined as the pitch of the index phosphor stripe I and the scanning speed of the electron beam. Signal S _I is obtained which is fed to P _LL 30.

As the P _LL 30, the index signal S _I is supplied to the phase comparator 31, and the output signal S _O of the full-time control oscillator 32 is supplied to the divider 33, so as to be 1 / N. Is divided into 1/2, and the divided signal P _N is supplied to the phase comparator 31, and the output full-phase of the phase comparator 31 is supplied to the oscillator 32 through the low pass filter 34.

On the other hand, as the trailing edge of the blanking pulse P _B , the R _S flip-flop 42 of the sickness is set so that the output signal P _S becomes "1", the index signal S _I is obtained, and is supplied to the Schmitt trigger circuit 43. The index pulse P _I is obtained, and the flip-flop 42 is reset by the first granularity of the index pulse P _I , and this output signal P _S becomes "0".

The output signal P _S of the flip-flop 42 is supplied to the oscillator 32 of the 30 to restrict the oscillation phase of the oscillator 32. That is, as shown in FIG. 3, the oscillator 32 stops oscillation and the output signal thereof as the period of "1" of the signal P _S from the trailing edge of the blank pulse P _B to the first granularity of the index pulse P _I. S is such that _O is repeated the state of "0" and "1" alternately, so that the phase of the output signal S _O with respect to the index pulse _I P is determined as shown in the drawing.

Furthermore, the output signal P _S of the flip-flop 42 is also supplied to the divider 33 of the P _LL 30 and the state of the divider 33 is regulated. That is, when the receiver 10 is configured as shown in FIG. 3 and the divider 33 is a half divider, the divider 33 is configured as one flip-flop, but in this case, the oscillator 32 This flip-flop is triggered at the granularity of the output signal S _O of the same), and this flip-flop is cleared as a period of " 1 " of the signal P _S , and the output signal P _N becomes " 0 ".

As described above, the phase of the index signal S _I of the output signal S _O of the oscillator 32 is determined by the output signal P _S of the flip-flop 42, and the state of the divider 33 is regulated to thereby regulate the index pulse P. As the start point of _I , the divided signal P _N from the frequency divider 33 is delayed by 90 degrees out of phase with respect to the index signal S _I as shown in the drawing, so that the P _LL 30 is locked immediately. .

When P _LL 30 is locked, the output signal S _O of the oscillator 32 is twice the index signal S _I as shown in the figure, that is, the pitch of the pair of color phosphor stripes R, G and B and the scanning speed of the electron beam. It is a frequency of 3ft, which is three times the triple rate frequency, which is determined as a spectral phosphor stripe R, G, and B in the granular phase (though not in the horizontal scanning start section 12, but is thought to extend from the effective screen section 11). It's in the phase that comes to just the middle position of.

The output signal S _O of this P _LL 30 is supplied to the gate signal generator 24 to obtain three-phase gate signals S _R , S _G and S _B to gate the red, green and blue primary color signals, in which case flip The output signal P _S of the flop 42 is supplied to this gate signal generator 24 as a further mode set pulse, so that the phase matching of the gate signals S _R , S _G and S _B is performed by the signal P _S.

That is, the gate signal generator 24 is configured as a ring counter having, for example, three stages of _JK flip-flops, and the Q outputs of the flip-flops of the first stage, the second stage, and the third stage are the gate signals S _R. , S _G and S _B , but the flip-flop of the first stage is preset as a period of "1 " of the output signal P _S of the flip-flop 42 so that the gate signal S _R becomes " 1 " the two each output each time the flip-flop of the third stage keulriyi gate signal S _G and S _B are set to "0" particulate signal S _O when the signal P _S is set to "0" in the first figurine of the index pulse P _I The gate signals S _R , S _R, and S _B are shifted so that the red, green, and blue color phosphor stripes R, G, and B, respectively, are not formed in the horizontal scanning initiation unit 12 but extend from the effective screen unit 11. Conceived) as the position of "1".

On the other hand, if the counter 44 is cleared in the period of " 1 " of the output signal P _S of the flip-flop 42, if the signal P _S is at " 0 " at the initial granularity of the index pulse P _I, the P _LL 30 When the input of the divided signal P _N from the frequency divider 33 is counted by the counter 44, and the predetermined arrival shown as an arrow of the divided signal P _N is counted at the end of the horizontal scanning start section 12, The flip-flop 41 is reset so that its output signal P _W is at " 0 " and the switch 26 is switched to the terminal V side.

When the switch 26 is switched to the terminal V side and thus becomes the effective display portion 11, the gate signals S _R , S _G and S _B from the gate signal generator 24 become " 1 " The switches 25R, 25G, and 25B are heated to the positions of the phosphor stripes R, G, and B, and red, green, and blue primary color signals E _R , E _G, and E _B are taken out, and the primary color signals are switched. Is supplied to the first grid 13 of the receiver 10.

In the present invention, the horizontal amplitude is controlled as the time from the horizontal retrace period until the first index phosphor stripe is detected is constant. That is, the block raengkil, for example, the pulse P _B, monostable multivibrator 50 as a trailing edge is triggered and its output signal P _M the block raengkil pulse time to a predetermined time from the trailing edge of P _B T _M between the "1" This output signal P _M is supplied to the sampling and holding circuit 60 as a phase comparator.

On the other hand, when the output signal P _S of the flip-flop 42 and the output signal P _W of the flip-flop 41 are supplied to the logic circuit 70 _and the signal P _W is received from the time t ^I when the signal P _S is received. A signal P _D is obtained which becomes “1” up to t ₂ . For example, when the inverter 71 is defined as the AND gate 72 and the signal P _S is inverted by the inverter 71, the inversion signal P _S and the signal P _W become the AND gate 72. ), A signal P _D is obtained from the AND gate 72.

When the signal P _D is supplied to the switch 61 of the sampling and holding circuit 60 as a sampling pulse and the switch 61 is turned on in the period of " 1 " of the signal P _D, the monostable multivibrator 50 When the output signal P _M is sampled and a sampling hold power-up E _SH is obtained from the capacitor 62 through the resistor 63, this sampling hold voltage E _SH is supplied to the horizontal amplitude modulator circuit 80.

The left and right pincushion distortion correction circuit 80 is configured as a power supply voltage modulation circuit of the horizontal deflection circuit 90, that is, the power supply voltage of the horizontal deflection circuit 90 is varied by the sampling and hold voltage E _SH . In this case, the larger the voltage E _SH is, the larger the power supply voltage is.

The time from the time point t ₀ to the time point t ₁ , that is, the period of "1" of the output signal P _S of the flip-flop 42 is long, and as shown in FIG. 4, the output signal P _M of the monostable multivibrator 50 is shown. As can be seen from the figure, only the period of "0" of the signal P _M is sampled and the sampling hold voltage E _SH becomes the minimum value. Conversely, the time from the time point t ₀ to the time point t ₁ , that is, the period of "1" of the signal P _S is short, and as shown in FIG. 5, the "1" of the pull force signal P _W of the flip-flop 41 is short. When the period coincides with the period of " 1 & quot _; of the signal P _M , the sampling hold circuit 60 is sampled at the end of the period of " 1 " of the signal P _M , so that the sampling hold voltage E _SH becomes the maximum value.

That is, in the sampling and holding circuit 60, the output signal P _M of the monostable multivibrator 50 and the signal P ₀ obtained from the logic circuit 70 are phase compared, i.e., to the time point t ₀ at the end of the horizontal retrace period. From the time point t ₁ to the _first time of winning the index pulse P _I is detected, and the sampling hold voltage E _SH varies greatly in response to the length of time from this time point t ₀ to the time point t ₁ .

6 is a state in which left and right pincushion dents appear in the raster 1, (2) is an effective screen, and therefore (3) is the upper side and the over scam portion 4, and the lower side and the scanning portion 6 The right side and the scanning part. As can clearly know from which, in the time from the point in time t ₀ the end of a horizontal return period to the first index phosphor (stripe) I ₁ is the index pulse time t that it is detected that the first figurine of the P _{I 1} is a screen up and down Long, short in the middle Therefore, the sampling hold voltage E _SH is small at the top and the bottom of the screen, and is enlarged at the center, and thus becomes the parabolic waveform of the vertical period T _V as shown in FIG. Therefore, the power supply voltage of the horizontal deflection circuit 90 is reduced at the top and bottom of the screen, the horizontal deflection current is made smaller, and the horizontal amplitude is reduced, and the power supply voltage of the horizontal deflection circuit 90 is increased at the center, so that the horizontal deflection current is increased. The horizontal amplitude is elongated, i.e., the time from time t ₀ to time t ₁ is always constant as in FIG. 3 and the amplitude of the horizontal is controlled, as in FIG. The left and right pincushion distortion of the stur 1 is corrected, the horizontal amplitude is controlled, and as in FIG. 8, the left and right pincushion distortion of the raster 1 is corrected, and the horizontal amplitude is constant.

2 is another example, when the main deflection coil for the water pipe is provided with another horizontal deflection coil 100 for correction, the voltage E _SH obtained from the sampling and holding circuit 60 described above is supplied to the amplitude modulator 110. The horizontal pulse P _H is amplitude modulated by this voltage E _S , and the amplitude modulated pulse is supplied to the correction horizontal deflection coil 100.

The horizontal pulse P _H is integrated in the coil 100 so that the horizontal deflection current of the sawtooth shaped waveform flows and the horizontal deflection current is amplitude modulated as the voltage E _SH of the parabolic waveform of the vertical period T _V , The same horizontal amplitude as the example of FIG. 1 becomes constant.

As described above, according to the present invention, the left and right pincushion distortion can be almost completely corrected, and at the same time, the horizontal amplitude change due to the fluctuation of the high pressure can be constant. As a result, the horizontal amplitude becomes constant, and the frequency of the index signal is the same in each line, so that the P _LL is surely locked even when the index signal is weak in a dark screen, and stable color reproduction is possible. Therefore, even if any beam current always flows so that the index signal can be obtained despite the contents of the video signal, the beam current can be reduced, and the contrast can be improved. Moreover, no adjustment is required at all.

Also, as shown in FIG. 7, when the left end of the raster ₁ is eaten inward from the _first index phosphor stripe I ₁ at the center of the screen, the first granularity of the index pulse P _I is the first index phosphor stripe I _1. However, according to the present invention, as shown in FIG. 8, the left end of the raster 1 always comes outward from the _first index phosphor stripe I ₁ , as shown in FIG. 8. There is no work.

The present invention is also limited to beam index color television receivers, but can also be applied to general television receivers. For example, a red, green, and blue phosphor stripe has a fluorescent surface arranged in a horizontal direction, the electron beams of red, green, and blue are arranged in an inline shape, and the arrival position of each electron beam to the fluorescent surface is regulated inside the fluorescent surface. When a large number of grid wires are collapsing and the electron beam impacts it, the horizontal amplitude is obtained by the capacitive coupling from the panel and the time taken until the signal is obtained from the horizontal retrace period by the capacitive coupling. This is controlled.

Claims (1)

In the beam index type color television receiver, the pulse generator 23 causes the reference pulse signal corresponding to the signal generated by the photo detector 21 to be generated, and the phase comparator 31 is horizontal to the reference pulse signal. To provide an output of magnitude due to a phase difference between control pulse signals, and to configure the horizontal deflection circuit 90 to receive the output of the phase comparator 31 to control scanning of the cathode beam to compensate for peripheral pincushion distortion. One TV receiver.

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