DE2438477A1 - DECODING DEVICE FOR A COLOR TELEVISION SYSTEM - Google Patents

Description

It 29 86

SONY CORPORATION Tokyo / Japan

Decoding device for a color television system

The invention relates to a decoding device for a Color television system.

If from a known color television receiver a black vsiss television signal is received, a disturbance occurs in the reproduced picture as a result of the switch-on pulse on / which is generated in a circuit used in the television receiver.

The invention is based on the object / the formation of such to avoid a disturbance.

The invention provides a decoding device for a color television receiver for decoding a chrominance signal proposed that generated by quadratic amplitude modulation of a carrier wave by two color signal components being one of the modulation axes for alternating Line periods of the video signal is phase inverted. the Apparatus has a delay device which delays the chrominance signal for one line period, a Device for generating by subtraction and addition of combinations of delayed and non-delayed chromos

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minance signals a first and second combined signal, each of which represents color signal components, a selector, which is connected to receive the first combined signal and which is a phase inverter for inverting the phase of the first combined signal and a switch for alternately selecting sections a line period of inverted and non-inverted first combined signals and to the successive one Delivery of alternately selected sections, an actuating device for actuating the switch to this to actuate a shift phase controller at each line blanking interval for generating a control signal that is normally synchronous with a burst signal that occurs in the line blanking interval, and for applying the control signal to the actuator in order to do so to control so that it gives the switch a certain switching phase, and an additional control device, which is connected to the switching phase control device in order to prevent it from receiving an undesired control signal, which is generated abnormally asynchronously with the burst signal is applied to the actuating device, thereby turning the switch to prevent switching during the line blanking interval.

The invention is explained below with reference to FIGS. 1 to 7, for example. It shows:

Figure IA, IB, 2 and 5 vector diagrams to explain the Invention,

Figure 3 is a block diagram of an example of a color demodulation circuit,

FIGS. 4A to 4E are signal diagrams for explaining the operation of the circuit in FIGS. 3 and

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Figures 6 and 7 circuit diagrams of embodiments of the Invention.

Before describing the invention, the PAL color television system will be discussed first explained.

In a chrominance signal of the PAL'-r color television system Carrier components F and F, for color difference signals R-Y and B-Y, a signal F + with a phase relationship like them is shown in Fig. 1A, during each particular interval T +, and a signal F- with a phase relationship, as shown in Fig. 1B, while each remaining Time interval T-. The carrier component F for the color difference signal R-Y is increased during each line interval inverted. As FIG. 2 shows, a burst signal B + is transmitted during the line interval T +, whereas during of the line interval T- a burst signal B- is transmitted.

A so-called standard PAL system color demodulation circuit, v.'ie it is shown in Fig. 3, is called a color demodulation circuit proposed for the chrominance signal described above. In the circle shown in Fig. 3, a PAL system color video or television signal given via an input terminal 11 to a bandpass amplifier 12, the separates the chrominance signal from it. The chrominance signal separated in this way is transmitted via a setting resistor 13 given to a second bandpass amplifier 14 for color adjustment. The chrominance signal of the bandpass amplifier 14 is to an adding circuit 15 or ", a subtracting circuit 16 and also to a delay circuit 17 for delay given by a line interval ". The thus delayed chrominance signal is applied to the adding or subtracting circuit 15 and 16.

During the line interval T + during which the chrominance signal F + is derived from the bandpass amplifier 14, on the other hand, the chrominance signal F- is taken from the delay

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Circuit 17 derived, whereas during the line interval T-, in which the chrominance signal F- is derived from the amplifier 14, the chrominance signal F + from the delay circuit 17 is obtained. Since the chrominance signals of the amplifier 14 and the delay circuit 17 are added in the adding circuit 15, the carrier component F. is obtained from the adding circuit 15 alternately. The carrier component Fj_ of the adder circuit 15 is supplied to a demodulator circuit 21 and then demodulated by the same together with a reference signal in phase with the BY axis (as will be described later). The color difference signal BY is thus obtained from the demodulator circuit 21 and then applied to a terminal 22.

The chrominance signals of the amplifier 14 and the delay circuit 17 are subtracted in the subtracting circuit 16 so that the carrier components F and -F are obtained from the subtracting circuit 16 alternately at every line interval. A line sequence signal of the carrier components F and -F is applied directly to one contact of a circuit 23 and also to the other contact of the circuit 23 via an inverter 24 which inverts the line sequence signal. A horizontal pulse P. from a flyback transformer (not shown) is given via a connection 25 to a flip-flop circuit 26, which then generates a pulse P ₀ ,

'a

which is inverted at every line interval IH, as shown in Fig. 4A shows. The pulse P "is sent as a control signal to the switching

et

circle 2 3 given. The circuit 23 leaves the carrier component, for example F through. This carrier component F is given to a demodulator circuit 26a, which they together demodulated with a reference signal in phase with the R-Y axis to produce the color difference signal R-Y. This Color difference signal R-Y is applied to a terminal 27.

If the reversal phase of the flip-flop circuit 26 is reversed and thus the phase of the pulse P ₌ inverted w

Cl

the switching phase of the circuit 23 is inverted and

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generates the carrier component ~ F. In such a case it can the demodulator circuit 26a does not have a proper color demodulation achieve. It is therefore necessary to provide a circuit that controls the operation of the flip-flop circuit 26. For this the chrominance signal of the first bandpass amplifier 12 is applied to a burst gate circuit 31, from which burst signals B + and B- present in a line blanking interval can be derived as shown in Fig. 4B. The burst signals B + and B- become a synchronous detector circuit 32 and also an oscillator circuit 33 for its control fed. The oscillator circuit 33 generates an oscillation signal S with a phase between the burst signals B + and B- as Fig. 5 shows. The oscillation signal S is applied to the synchronous detection circuit 32 as a reference signal. The synchronous detector circuit 32 therefore generates a pulse P which is switched over so that it occurs at every line interval is positive and negative depending on the burst signals B + and B, as shown in FIG. 4C. The momentum P is applied to a resonance circuit 34 which is in resonance at half the line frequency f i. The resonance circuit 34

η /

generates an alternating signal S, with a frequency 1/2 h synchronous with the pulse P, as Fig. 4D shows. The signal S i is given to a shape circle 35 to be used as a Pulse P to be formed in synchronism with the burst signal B + as shown by a solid line in Fig. 4E. Of the Pulse P is given to the flip-flop circuit 26 as a control signal. Hence the operation of the 'flip-flop circuit

from the pulses P, and P from the terminal 25 and the ^r he

Form circuit 35 controlled and generates the pulse P with the desired phase as previously described.

The oscillation _{signal S Q of} the oscillator circuit 33 is applied to phase shifters 37 and 38, which generate signals in phase with the axes BY and RY, respectively. The signals of the phase shifters 37 and 38 are applied to the demodulator circuits 21 and 26a, respectively, as their reference signals to the above

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to achieve mentioned color demodulation. Referred to in Fig. 3 39 a color blocking circuit 39 which distinguishes whether the burst signals B + and B- of the burst gate circuit 31 are present or not, and then its distinguishing signal (a color blocking signal) to the second, bandpass amplifier 14 as a control signal for the color blocking signal there to interrupt the operation of the bandpass amplifier 14 and a so-called Achieve color lockout when receiving a black and white broadcast television signal.

In the above-mentioned color demodulating circuit, the following effect can be obtained. As the carrier components F and -F are obtained from the subtracting circuit 16 alternately every line interval, becomes the line sequence signal of the carrier components F and -F as it is, given to the demodulator circuit 26a. Therefore, even if the reference signal for color demodulation from the phase shifter 38 at each line interval from one inverter and one Circuit is alternately inverted, the demodulator circuit 26a can the color difference signal in the same way Demodulate R-Y. Since, however, the »level of the reference signal for the color demodulation, which is sent to the demodulator circuit 26a is high, it is necessary to have a diode and a transistor along with a large capacitor to be provided in the inverter and the circuit, and thus the circuit becomes expensive. As the inverter supplies a reference signal in phase reversed to the reference signal of the phase shifting circuit 38 is generated and its level is made high so that it is easily mixed with other signals, interference between the reference signal having the reversed phase and the original reference signal becomes a problem.

In the color demodulator circuit of FIG. 3, however, the level of the carrier components F and -F, which are fed to the inverter 24 and the circuit 23 will be given low, and most importantly its level will be given by the delay circuit 17 reduced, so that a small capacitance of a diode

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- 7 ".. 2438A77

and one transistor are sufficient for use in the inverter and the switching circuit 23, hence reducing its cost will. Since the level of the carrier components F and -F is low as described above, a Interference between them is difficult to occur.

As mentioned above, the color demodulation circuit shown in Fig. 3 has various advantages that it can however, interference may occur in the reproduced picture when a black and white television signal is received from a color television receiver is received with the color demodulation circuit in FIG. The reason is as follows: When the black and white television signal is received, no burst signals B + and B- are generated. There is thus no pulse P from the synchronous detector circuit 32 received. As a result of the interference signal that is given to the resonance circuit 34 at this point in time, however, the resonance circuit 34 generates a signal S i with an incorrect phase. Hence the shape circle is given 35 the signal S, and generates a pulse P with incorrect phase, as shown in Fig. 4E by a dashed line. If the pulse P during of the line interval is generated, the flip-flop circuit 26 is reset within the line interval. In order to the circuit 23 is switched in the line interval. As a result, a switch-on pulse occurs in the circuit 23 is generated when it is switched over, appears in the reproduced picture as a disturbance and deteriorates the picture.

The aim of the invention is to avoid the generation of such a disturbance in the reproduced image when the Black and white television signal is received by a color television receiver. For this purpose, in the invention, the circuit 23 not switched during the line interval.

An embodiment of the invention is illustrated below with reference to of Fig. 6, in which the elements that make the-

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correspond to those in Fig. 3, are provided with the same reference numerals. In the embodiment of Fig. 6, the resonance circuit 34 comprises a transistor 52 with a grounded emitter, the collector of which is connected to a resonance circuit consisting of a coil 42 and a capacitor 43 to generate the signal S ^ on the basis of the pulse P des Synchronous detector circuit 32 to generate. The signal S ^ is given to a transistor. 44 of the circuit 35. The transistor 44 thus receives no bias voltage and the signal S i is applied to the base of the transistor 44. The collector of the transistor 44 is connected to a -Vcc voltage source 46 through a resistor 45, and its emitter is grounded through a resistor 47 and also connected to the voltage source 46 through a resistor 48. The horizontal pulse P ^ from the terminal 25 is applied via a resistor 51 and a capacitor 52 to the emitter of the transistor 44, which generates the pulse P at its collector. The pulse P _e is applied to the flip-flop circuit 26, which consists of transistors 54 and 55, via a diode 53. The horizontal pulse P_ of the terminal 25 is applied to the bases of the transistors 54 and 55, and the pulse P _{e of} the diode 53 is applied to the base of the transistor 54. The pulse P of the flip-flop 26 is applied to the circuit 23.

With the above construction of the invention, the transistor operates 44 as a shape circuit 35, and also as an AND gate, so that only when the pulse P. on the emitter of the transistor and the positive part of the signal S ^ to the base of the transistor 44 is given, the transistor 44 is turned on to generate the pulse P_ at its collector. The case, that the horizontal pulse P ^ and the positive part of the signal S, are simultaneously applied to transistor 44, occurs only when a color television signal is being received. If a black and white television signal is received, that has

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Signal S, not the correct phase as previously described. In this case, therefore, it does not occur that the Horizontal pulse P, and the positive part of the signal S, are applied to transistor 44 at the same time. Therefore no pulse P is generated and the flip-flop circuit 26 is not reset during the line interval. Therefore, the switching circuit 23 is not switched over during the line interval, the switch-on interference signal that occurs when switching of the circuit 23 is generated, as previously mentioned, is not generated, and thus none occurs Disturbance in the displayed picture.

As described above, according to the invention, an image can be formed without disturbance when the black and white television signal Will be received. It is sufficient to apply the horizontal pulse P, from terminal 25 to the emitter of transistor 44 so that the ** circle according to the Invention is simple in construction and inexpensive.

Fig. 7 shows a further embodiment of the invention, ' in which the same reference numerals as those in Fig. 6 denote the same elements. In the embodiment of 7, transistor 44 is not biased to form shape circuit 35. The emitter of transistor 41 is grounded via the collector-emitter path of the transistor, the base of which is the color blocking signal of the color blocking circuit 39 receives.

In the embodiment of FIG. 7, when the color television signal is received, the transtor 56 is disturbed by the color lock signal of the color blocking circuit 39 switched on. The transistor 41 therefore generates the signal S i on the basis of of the pulse P of the synchronous detector circuit 32 to

perform the above-mentioned color demodulation. if the black-and-white television signal is received, the Transistor 56 from the color lock signal of the color lock circuit

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turned off and thus the transistor 41 is turned off. The signal S 'is therefore not generated, so that the circuit 23 does not switch over during the line interval will. Therefore, no disturbance occurs in the reproduced picture.

When a black ¥ ice television signal is received, interference signals are therefore prevented according to the invention from being in appear on the reproduced image without deteriorating the advantage of the color demodulator circuit in FIG. The circuit for this purpose is also simple in construction and inexpensive.

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Claims (5)

Expectations 1. Decoding device for a color television receiver for decoding a chrominance signal by quadratic Amplitude modulation of a carrier wave is formed by two color signal components, one of the Modulation axes for alternating line periods of the Video signal is phase inverted, consisting of a delay device for delaying the chrominance signal by a line period, a combination circle to generate by subtracting and adding combinations delayed and non-delayed chrominance signals of a first and second combined signal, each of which represents color signal components, a selector circuit connected to combine the first Receives signal, and the one phase inverter for phase inversion of the first combined signal and a switch for alternately selecting portions of a line period of the inverted and non-inverted ones Signals and for the successive output of alternately selected sections, an actuation circuit for actuation the switch to cause the switching operation at every line blanking interval, and a switching phase control circuit for generating a control signal normally in synchronism with a burst signal contained in the Line blanking interval occurs, and for applying the control signal to the switch operating circuit to this to control so that it gives the switch a certain switching phase, characterized in that an additional Control circuit (51, 52; 39, 56) with the switching phase control circuit (31, 32 ^ 34, 35) is connected to this to prevent an undesirable control signal generated abnormally asynchronously with the burst signal to enter the switch actuation circuit (26), thereby preventing the switch from operating during the line blanking terval Is to switch. 509808/0908 -AX- 2. Decoding device according to claim 1, characterized in that the additional control circuit (51, 52) has a horizontal pulse, which occurs during the line interval on the switching phase control circuit (31, 32, 34, 35), so that it generates the control signal that is only synchronized with the first on the switch actuation circuit (26) Signal is given. 3. Decoding device according to claim 2, characterized in that the additional control circuit (51, 52) with a pulse shaping active device (44) for generating the control signal in the switching phase control circuit (31, 32, 34, 35) is connected to apply the horizontal pulse to this so that the active device only during the Line blanking interval is working. 4. Decoding device according to claim 1, characterized in that the additional control circuit (39, 56) is designed in such a way is that he at least a part (34) of the switching phase control circuit (31, 32, 34, 35) out of order so that no control signal is generated when the burst signal is not present. 5. Decoding device according to claim 4, characterized in that the additional control circuit öinen additional Has switch (56) which is connected to the part (34) of the switching phase control circuit (31, 32, 34, 35) to its operating status to control, as well as a circuit (39) to a switching signal that is used for color blocking is to give on the additional switch (56) to control its switching operation. 509808/0908 Blank page