KR800000782B1 - Color television receiver - Google Patents

Abstract

A color TV having automatic and manual tint adjustor is composed of a CRT having screen for radiating a plurality of color lights, a cct. device connected to the CRT and for responding to received TV signals, a first generator conneted to the cct. device to luminesce by selected tint and a second generator connected to the cct. device to luminesce the other selected area of the screen, which has second tint controller for changing the tint of the light provided by the other area. A gain is responded to the change of the first tint controler and controled complementarily from the second tint controler.

Description

Color television receiver

1 is a schematic diagram of an embodiment of a color television receiver according to the present invention.

2 to 6 are views for explaining the first FIG.

7 is a schematic diagram of another embodiment of a color television receiver according to the present invention.

In the present invention, the color of the screen is simple and easily adjusted in the color television receiver, or the color is automatically brought into a suitable state.

Hereinafter, the color television receiver according to the present invention will be described with reference to the drawings.

FIG. 1 is an embodiment thereof, in which the luminance signal is extracted by passing the output of the image detection circuit 1 through the first image amplifier 2 and the second image amplifier 3, and this is converted into a switch circuit 4Y. Supply to one input terminal of. The output of the first image amplifier 2 passes through the first band amplifier 5 and the second band amplifier 6 to extract a carrier color signal, which is then demodulated through an ideal phase 7 for color adjustment. While supplying to (8) and (9), the output of the first band amplifier 5 is supplied to the burst circuit 10, and the burst signal is taken out, and this is supplied to the oscillator 11 to supply the continuous wave signal of the same phase. Is supplied to the phase shifter (12) and the phase shifter (13) and the signal for demodulation of the phases of the RY axis and the BY axis, and is supplied to the demodulators (8) and (9) to the demodulator (8). The color difference signal of the blue is used as the demodulator 9 to respectively demodulate the blue color difference signal.

Then, the red color difference signal is supplied to one input terminal of the switch circuit 4R, and the blue color difference signal is supplied to one input terminal of the switch circuit 4B, respectively, and the red and blue color generator signals are supplied to the matrix circuit 14. A color difference signal is obtained and supplied to the input terminal of one of the switch circuits 4G. In addition, the burst signal from the burst gate circuit 10 is supplied to the color killer circuit 15 so that, when the monochrome television signal is received, the color killer signal is obtained therefrom so that the second band amplifier 6 is cut off. .

Then, the output of the first image amplifier 2 is supplied to the horizontal synchronizing signal separation circuit 16 and the vertical synchronizing signal separation circuit 17 to obtain the horizontal synchronizing signal P _H and the vertical synchronizing signal P _V , and the switching signal forming circuit ( 18), and as shown in FIG. 2 from this point, the beam becomes “1” in the section scanning the area A ₀ of the upper half of the screen, for example, and has a band shape extending in the horizontal direction below it. In the section in which the area A _P is scanned, the switching signal S ₁ which becomes "0" is obtained. Then, the horizontal synchronizing signal P _H and the switching signal S ₁ are supplied to the color bar signal generator 19 to obtain three E _Y , E _R -E _Y and E _B -E _Y signals therefrom. These signals E _Y , E _R -E _Y and E _B -E _Y are obtained in the section in which the switching signal S ₁ becomes "0", that is, in the section in which the beam scans the area A _P of the screen. In periods T ₁ to T ₇ in which the machine horizontal scanning periods are divided into _seven , the voltage value changes as shown in FIG. The signal F _R -E _Y is supplied via the switch circuit 20 and supplied separately to the input terminals of one and the other of the switch circuit 23 via the amplifiers 21 and 22 separately, and at the same time the signal E _B- E _Y is supplied via the switch circuit 24 to the input terminals of one and the other of the switch circuit 27 via the amplifiers 25 and 26 separately, while the horizontal synchronization signal P _H and the switching signal are supplied. S ₁ is supplied to the other switching signal forming circuit 28 so that the beam becomes " 1 " in the section where the beam is scanned, for example, the region A _F of the upper half, among the above-described regions A ₀ and A _P. period of a _P the period for scanning the area a _V of the lower half of the "0" to "1" in these signal s ₂ to obtain the switching signal s _2, and supplies this data to the switch circuits 23 and 27 are Is switched to the state of the drawing, and in the section of “0” of the signal S ₂ , the state is reversed from the state of the drawing. To be switched. The signal E _Y is supplied to the other input terminal of the switch circuit 4Y through the amplifier 29, and the output of the switch circuit 23 is supplied to the other input terminal of the switch circuit 4R, and the switch circuit 27 is supplied. The output of the switch circuit 4B is supplied to the other input terminal of the switch circuit 4B, and the output of the switch circuit 23 and the output of the switch circuit 27 are supplied to the matrix circuit 30, and the former is applied to the red color difference. When the signal is used and the latter is used as the blue color difference signal, a signal corresponding to the color difference signal is obtained, and the signal is supplied to the other input terminal of the switch circuit 4G, and the switching signal S ₁ is supplied to the switch circuit 31. ) the switch circuit (4Y) through, (4R), (4G), and (supplied to 4B), they are in the range of "1" of the signal S ₁ is switched to the state of the figure, the signal S _1, "0" In the interval of to switch to the opposite state from the state of the drawing. The output of the switch circuits 4Y is used as the luminance signal, and the outputs of the switch circuits 4R, 4G, and 4B are used as the color difference signals of red, green, and blue, respectively, and are supplied to the matrix circuit 32. From this, red, green, and blue are obtained as primary color signals, which are then supplied to respective cathodes of the color cathode ray tube.

In this case, the amplification gains of the amplifiers 29, 21, and 25 are fixed at the same constant value, and the amplifiers 29, 21, and 25 scan the region A _P in the figure. In the interval, the signals E _Y , E _R -E _Y and E _B -E _{Y shown} in FIG. 3 are obtained in the same level relationship. On the other hand, the switching switch 33 is switched to the contact M side as shown in the drawing, and the voltage from the power supply 34 for color adjustment is supplied to the phase shifter 7 and the amplifiers 22 and 26 for color adjustment. In the ideal phase 7 so that the abnormality in 7) and the amplification gain of the amplifiers 22 and 26 can be related and changed, and the color is in an appropriate state as indicated by F ₀ in FIG. 4A. When the ideal amount of A becomes a predetermined value, the amplification gains of the amplifiers 22 and 26 are equal to the amplification gains of the amplifiers 29, 21 and 25, and are indicated by B and C. Likewise, signals E _R ′ -E _Y ′ and E _B ′ -E _Y ′ from amplifiers 22 and 26 are equal to signals E _R −E _Y and E _B − from amplifiers 21 and 25. are each equal to E and _Y, such that the color red is strong state, as indicated by the degrees F _R 4a, when moving amount than in the phase shifter (7), increasing Amplifying gain of the group 22 is larger than the amplification gain of the amplifier 21, and the signal E _R '-E _Y' from the amplifier 22 becomes larger than the signal E _R -E _Y from the amplifier 21 At the same time, the amplification gain of the amplifier 26 is smaller than the amplification gain of the amplifier 25 so that the signals E _B ′ -E _Y ′ from the amplifier 26 are greater than the signals E _B ˜E _Y from the amplifier 25. smaller and, conversely, such that one color state in which blue is strong, as indicated by a fourth-degree F _0, when the movement amount is more than in the phase shifter (7), whereas the amplification gain of the amplifier 22 is that of the amplifier 21 Signals on region A _F since the circuits 4Y, 4R, 4G, and 4B of amplifier 25 of amplifier 26 are switched to the opposite state of the manufacturer's drawing. By E _Y , E _R -E _Y and E _B -E _Y , parallel to white, sulfur, cyan, green, magenta, red, blue are sequentially parallel as indicated in FIG. Color bars of fixed color are drawn. And the period for scanning the area A _V of the lower half of the area A _P switch circuits (23), (27), (4Y), (4R), (4G) and (4B) are opposite to the state of the maker drawings since switching to the status area a formed on the signal _{V E Y, E R '-E Y} ' and E _B is youngchul color bar according to the '-E _Y', the area a is _V color bar on the voltage of the power source 34 When changing color by changing, the color of each part divided in the horizontal direction changes in conjunction with this.

And signals E _R ′ -E _Y ′ and E _B ′ -E _Y ′ are equal to signals E _R -E _Y and E _B -E _Y , respectively, so that the color of the color bar on area A _{V is} on the area A _F. Since the color of the broadcast image is in the proper state when it is the same as that of the color bar, look at the screen and turn the power supply 34 so that the color of the color bar on the area A _V is the same as that of the color bar on the area A _F. Adjust to get the right color.

Upon reception of the black and white television signal, the switch circuits 20 and 24 are turned off by the color killer signal from the color killer circuit 15 so that only the signal A _F on the area A _{V is} shown in FIG. The gray scale is drawn out or the switch signal forming circuit 18 is controlled by the color killer signal so that the switch signal S ₁ is always “1” and the switch circuits 4Y, 4R, 4G and As shown in FIG. 6, 4B is always switched to the state of the drawing, and as shown in FIG. 6, a broadcast image may be output on the entire screen.

When the above-described color adjustment is made, for example, the switching circuit 35 is switched off from the contact C side to the contact F side to turn off the switch circuit 31 to switch circuits 4Y, 4R, 4G, and the like. It is sufficient that 4B is always switched to the state shown in the drawing so that a broadcast picture is produced on the full screen.

By switching the switch 33 to the contact M side, the color can be adjusted manually as described above, and at the same time, when the switch 33 is switched to the contact A side, the color can be automatically adjusted to be appropriate.

In this case, after comparing the magnitudes of the signals E _B ′ -E _Y ′ from the level comparator 25, the comparison output is transmitted through the amplifier 37 and for the color adjustment through the contact A side of the switch 33. Amplifiers 22 and 26 so that the amplification gains of the amplifiers 22 and 26 are equal to the amplification gains of the amplifiers 21 and 25. 22 and 26, signals E _R '-E _Y' and E _B '-E _Y' are the signals from amplifiers 21 and _{(25) E R '-E Y} ' and E _B from the By making it equal to ′ -E _Y ′, the abnormality amount in the abnormal phase 17 is such that the color is in a proper state.

In this case, when the switch circuit 31 is turned on by switching the switch 35 to the contact C side, color bars of the same color are generated in the areas A _F and A _V , and the switch 35 is connected to the contact F. When the switch circuit 31 is turned off by switching to the side, color adjustment is automatically performed, but color bars are not drawn out.

FIG. 7 provides a transmission signal for demodulating the color bar signal once and demodulating the modulated signal like a demodulator for demodulating a carrier color signal to one input terminal of the switch circuit 4C, while supplying a continuous wave signal from the oscillator 11. FIG. It is supplied to one input terminal of the switch circuit 38 as it is, and is also supplied to the other input terminal of the switch circuit 38 through the abnormality adjusting device 7 for color adjustment, and the beam from the switching signal forming circuit 28 is displayed on the screen. A switching signal of "0" is supplied to this switch circuit 4C via the switch circuit 31 in the section in which the area A _P is scanned, and this is switched to the state of the drawing in the section of "1" of the signal S ₁ . In the section of “0” of the signal S ₁ , it is switched to the opposite state of the drawing.

Then, the signal from this switch circuit 4C is supplied to the demodulators 8 and 9, while the continuous wave signal through the phase shifter 7 is passed through the phase shifters 12 and 13 on the RY and BY axes. Signals from the color bar signal generator 19 from the demodulators 8 and 9 are supplied to the demodulators 8 and 9 as demodulator signals of the phase shifter E _R -E _Y and E _B. By allowing -E _Y to be obtained as it is, a color bar of a fixed color is generated on the region A _F region as described above by signals E _Y , E _R -E _Y and E _B -E _Y. In the section for scanning the area A _V of the lower half of the area A _P , the switch circuits 4Y, 4C, and 38 are respectively switched to states opposite to those in the drawing, so that the color bar signal generator 19 From the modulators 39 and 40 for the signals E _R -E _Y and E _B -E _Y from the demodulator axes in the demodulators 8 and 9, Since it changes according to the abnormality in the color bar, a color bar is drawn out on the area A _V , but the color of each part divided in the horizontal direction changes in conjunction with the color adjustment by the power supply 30.

And when the ideal amount in the ideal phase 7 is zero, the modulation side in the modulators 39 and 40 and the demodulation axis in the demodulators 8 and 9 respectively match, i.e. Since the region is the time of an image of a broadcast color is as the color of the a _V the color bar on the color of the color bar area, a _F to the time the proper state, the power source such that as the color of the color bar on the reporting area a _V the screen By adjusting (34), an appropriate color can be achieved.

Also in this embodiment, when the monochrome television signal is received, the switch circuit 45 is turned off by the color killer signal from the color bar circuit 15, and the gray scale is _changed only by the signal E _Y on the area A _P. The switching signal forming circuit 18 is controlled so that the switching signal S ₁ is always “1”, and the switch circuits 4Y and 4C are always switched to the state of the drawing so that the broadcast signal is displayed in full screen. It is good to make an image appear.

As described above, the present invention is characterized in that the color of the screen is simply and easily adjusted or the color is automatically brought into an appropriate state.

The comparison is not a color bar signal but may be a specific standard color. In this case, the display may be displayed in a corner of the screen.

Claims (1)

As described herein and shown in the figures, a cathode ray tube comprising a screen that emits multiple colors, and a circuit connected to the tube to provide color television images on the screen, the circuit being responsive to received color television signals A device, a first hue control device connected to the circuit device to change the hue of the image, and the circuit device for generating reference signals of a predetermined relationship and for causing the selected area of the screen to emit light of a predetermined hue. A first generating device coupled to the circuit arrangement for generating signals of varying relationship and for causing the screen to emit a different predetermined area of light, the light provided in the other area having hue control of the image. A second generating device including a second tone control device to change the color tone, said second color And a jaw control device comprising first and second gain control amplifiers whose gains are compensated controlled relative to each other in response to a change in the first color control device.

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