NL192177C - Signal processing circuit for processing the chrominance signal component independently of an applied standard signal transmission mode. - Google Patents

Description

1 192177

Signal processing switching for editing the chrominance signal component independently of an applied standard signal transfer mode

The invention relates to a signal processing circuit for independently processing the chrominance signal component associated with the color video signals used for signal transmission of composite color video signals, comprising: a common, first processing circuit operating independently of the standard video transmission signals for the color video signals. selecting at least the chrominance signal component and a color burst signal; 10 a second processing circuit connected to the first processing circuit with, for each standard signal transmission mode, a separate operating mode selectable by means of first switching means for processing and demodulating the chrominance signal component generated by the first processing circuit; a color carrier generator with, per standard signal transmission mode, an operating mode selectable by means of second switching means for generating a color carrier signal specific for the selected operating mode; detection and switching control means connected to the first processing circuit for providing an indication signal relating to the transmission mode of the color burst signal relating to the supply of the color burst signal selected in the first processing circuit and generating a switching control signal on the basis of this indication signal for the purpose of the first and second switching means, the switching control means activating the switching means with a periodicity of predetermined period duration; and holding means for keeping the switching means in a switching state corresponding to the output signal of the detection means.

Such a signal processing circuit is known from German patent application No. DE-A.2.943.271. The signal processing circuit according to this patent application is suitable for determining which of the possible modulation methods has been used to obtain a signal applied to the input of the signal processing circuit, and demodulating this signal accordingly.

A drawback of the known signal processing circuit is that the indication signal forms an identification signal of the relevant modulation method and serves directly as a switching control signal. The identification signal is generated as a result of the comparison of the properties of the received signal with properties known from the modulation modes, in particular the frequency of the color synchronization signal. There is a danger here that a comparison will not lead to a result if a received signal deviates slightly from the standard or as a result of the expiry of the settings of the detection and switching control means.

The object of the invention is to eliminate the above-mentioned drawbacks and to this end provide a signal processing circuit which is distinguished in that the detection and switching control means comprise: a phase comparison circuit for generating the color carrier signal produced by the color carrier generator on the color carrier generator at basis of 40 the phase difference signal to be formed; and a switching signal generator connected to the phase comparison circuit for generating the switching control signal, depending on the status of the indication signal at a state of the indication signal unchanged for a predetermined period of time.

With a signal processing circuit according to the invention, identification takes place on the basis of the coherence present in the received signal, which differs for each of the modulation modes.

The invention will be elucidated in the following description with reference to the drawing of some embodiments, to which, however, the invention is not limited. In the drawing: Figure 1 shows a block diagram of a chrominance component processing circuit according to an embodiment of the invention, and Figure 2 shows a block diagram of a part of a chrominance component processing circuit according to another embodiment of the invention.

Figure 1 relates to the use of the invention in a color television receiver capable of receiving both NTSC type composite color video signals and such PAL type signals.

In the block diagram of Figure 1, a composite 192177 2 color video signal of the NTSC or PAL type received through an input terminal 1 is supplied to a band filter 2; the central frequency value of the transmission frequency band of the band filter 2 can be switched between 3.58 MHz for an NTSC type signal and 4.43 MHz for a PAL type signal; this switching is effected by means of a control signal to be supplied to the control signal input connection 3 of the band filter 2. The band filter 2 separates from the NTSC or PAL type composite video video signal the eligible chrominance component, which is modulated on a carrier signal, and delivers it to a chrominance component processing circuit 4 according to the invention, which will subsequently be described in detail. .

The carrier wave modulated chrominance component separated by the bandpass filter 2 is supplied to an amplifier 5 for automatic chrominance control, the output of which is fed to a color burst gate circuit 7 for separation of the color burst signal. This color burst signal alternates between + 135 ° and -135 ° phases with a PAL video color video signal at each image line scan period. The color burst gate circuit 7 is supplied via a input terminal 8 with a color burst gate signal and supplies the separated color burst signal to a chrominance detection circuit 9, of which the detection output signal appearing across the capacitance 6 is applied as a chrominance control signal. The carrier-modulated chrominance component output from this amplifier 5 is then supplied to a control amplifier 10, to which a color control signal is also supplied via an input connection 11, an image control signal via an input connection 12 and furthermore a deaf voltage originating from a detection circuit 45 to be described further. .

In the block diagram of Figure 1, reference details 16 and 17 refer to respective selector switches, which are switched depending on whether a received color. video signal is of the NTSC or PAL type. When a NTSC type color video signal is received, the carrier modulated chrominance component output from the control amplifier 10 is supplied via the selector switches 16 and 17 to respective color difference signal demodulators 18 and 19 for the colors blue and red, the respective output terminals of which are 20 and 21 respectively provide the color difference signal for the color blue and dét for the color red.

On the other hand, when a PAL video color video signal is received, the carrier-modulated chrominance component output from the control amplifier 10 is applied to a delay line 13 13 with a delay duration 1Η (H = the picture line scan period duration) and further to an adder 14 and a subtractor 15. The output signal of the delay line 13 is also applied to the addition unit 14 and the subtraction unit 15. The blue color difference signal output from the adder 14 is supplied to the blue color difference signal demodulator 18 by the selector 16, while the red color difference signal output from the subtractor 15, 35 of which reverses the phase at each image control scan period, is selected via the selector switch. 17 is applied to the color difference signal demodulator 19 for the color red.

Next, an auxiliary carrier signal generating circuit 22 will be described. This circuit 22 comprises an oscillation circuit 23 with a voltage-controlled oscillator 24, two oscillation crystals 25 and 26 added thereto for NTSC and PAL, respectively, and a selector switch 27 for selection 40 of the oscillation crystals 25 and 26. The color burst signal supplied by the color burst gate 7 is in the case of an NTSC type color video signal through a hue control phase shifter 30 applied to a phase comparator 28 to which the oscillation output of the voltage controlled oscillator 24 is also supplied. The phase comparison output of the circuit 28 is applied as a phase control signal to the oscillation circuit 23 via a low-pass filter 29.

The sub-carrier signal formed by the sub-carrier signal generating circuit 22, which has a frequency of 3.58 for NTSC and a frequency of 4.43 MHz for PAL, is supplied via a phase shifter 36 with a phase shift angle of 90 ° to the color difference signal demodulator 18 for the color blue.

When a received color video signal is of the NTSC type, the subcarrier signal formed by the circuit 22 is supplied to the color difference signal demodulator 19 for the color red via a selector switch 32 in the position shown. On the other hand, when a received color video signal is of the PAL type, the color subcarrier signal formed is inverted by the selector switch and with the aid of a reversing circuit 31 at each phase control scan period of phase and added in 55 the corresponding shape to the color difference signal demodulator 19 for the color red.

The selector switch 32 just mentioned is controlled by a flip-flop 33, to which a selector switch 35 is supplied via an input terminal 34 in the case of a color video signal of the PAL type, the horizontal synchronizing pulse. The respective selector switch 35 is closed upon receipt of a color video signal of the PAL type, but upon receipt of a color video signal of the NTSC type.

Next, the detection circuit 45 which supplies the aforementioned extinguishing voltage 5 to the control scaffold 10 will be described. This detection circuit 45 comprises a phase comparison circuit 37, to which the color burst signal from the color burst gate circuit 7 and the color auxiliary carrier signal appearing at the output contact of the selector switch 32 are applied for phase comparison. The resulting comparison output signal is applied to a low-pass filter 38, consisting of a resistor 39 and a capacitance 40. The extinguishing voltage output from the layer-defrost filter 38 is selected such that when a received video signal is either a monochromatic video signal or a color video signal of aberrant type, the extinguishing voltage has a high level, while when the received video signal is a color video signal of the corresponding type, the extinguishing voltage has a low level. This extinguishing voltage is applied to the control amplifier 10, so that the amplification factor thereof is also controlled by the extinguishing voltage. The output of the control amplifier 10 takes the form of a low DC voltage on which an AC voltage is superimposed when the video signal is a color video signal of the correct type, but the shape of a high DC voltage when a received video signal is a monochromatic signal or a color video signal of a different type. The said quenching voltage is also applied to the flip-flop 33, so that the switching of the selector switch 32 upon receipt of the PAL type video signal is controlled synchronously with the polarity changes of the color burst signal.

In the block diagram of Figure 1, reference numeral 41 refers to a switching control circuit, which changes the central frequency value of the pass-frequency band of the band filter 2 and the switching of switches 16, 17, 27 and 35 with a periodicity. of predetermined period duration. The switchover control circuit 41 is designed such that a vertical synchronization pulse received via an input terminal 42 is applied to the clock pulse input terminal CK of 16-counter 43, the output of which is applied to the erase terminal CL of the counter 43 and further to a flip-flop 44. The latter gives a rectangular wave-shaped signal, which has a duty cycle of 50% and whose 30 period duration corresponds to 32 vertical period durations. This rectangular waveform signal from the flip-flop 44 controls the center frequency values of the forward frequency band of the band filter 2 and the switchover of the switches 16, 17, 27 and 35 after every 16th vertical period.

In the block diagram of Figure 1, reference numeral 46 refers to a sustain control circuit which examines the carrier modulated chrominance component based on the quenching voltage supplied by the detection circuit 45 and the central frequency value of the forward frequency band of the band filter 2 and the switching states of keep the different selector switches 16,17,27,35 in accordance with the standard type of the received color video signal found in the examination. This holding control circuit 46 will now be described in more detail.

Of a pnp type transistor 47, the collector is grounded through a resistor 49, the base is connected 40 to the output terminal of the low-pass filter 38, and the emitter is coupled through a reverse current blocking diode 48 to a voltage source 55 of previously certain voltage value. The voltage source 55 is adjustable, and is adjusted such that when a received video signal turns out to be a monochromatic video signal or a color video signal of a different standard type, the transistor 47 is turned to its non-conducting state; on the other hand, when a received video signal turns out to be a suitable standard color video signal, the transistor 47 is turned on. In a particular embodiment, an adjustment of the voltage source 55 is chosen such that the base voltage of transistor 47 is 8V when a received video signal appears to be a monochromatic video signal or a color video signal of a different standard type, but a base voltage of about 6V 50 when a received video signal is a color video signal of the correct standard type. The collector of transistor 47 is coupled through a resistor 56 to the base of a transistor 57, the emitter of which is grounded and the collector is connected to input terminal 42.

Next, the operation of the circuit shown in Figure 1 will be described.

When the color television receiver not shown in the drawing, to which the chrominance component processing circuit according to the invention belongs, is turned on, the central frequency value of the forward frequency band of the band filter 2 and the respective switching states of the selector switches 16, 17, 27 and 35 become periodically, that is to say, with the changeover control

Claims (3)

192177 4 circuit 41 certain period duration changed. If a subsequently received color video signal is of the NTSC type, the transistor 47 of the hold control circuit 46, when switched to the switching state added to NTSC, will enter its conducting state, the collector voltage of the transistor 47 being high, so that the transistor 57 comes into its conductive state. As a result, the vertical synchronization pulse supplied through input terminal 42 is derived from transistor 57, or is not supplied to counter 43. Flip-flop 44 then remains in its previously occupied stable switching state. As a result, NTSC signal processing of the received color video signal is effected by the chrominance component processing circuit 4. When a PAL video color video signal is received, a similar operation is obtained. In the above-described embodiment, the supply of vertical synchronizing pulses to the counter 43 is controlled by the extinguishing voltage from the detection circuit 45. Since the DC voltage level of the output voltage of the control amplifier 10 is proportional to this extinguishing voltage, it is also possible that the supply of the vertical synchronizing pulse to the counter 43 is controlled based on the output voltage of the control amplifier 10. When the chrominance component processing circuit according to the invention to be used for color video signal of the pure NTSC type, the PAL type and the quasi-NTSC type, in which the latter case the color subcarrier frequency is 4.43 MHz as with the PAL type, it is sufficient, that the shift control circuit 41 is performed in the manner of Figure 2, wherein the control signal output from this circuit 41 is used for the respective switches in Figure 20. In the switchover control circuit 41 of FIG. 2, instead of the flip-flop 44 of FIG. 1, a 3-counter 50 is used, whose output terminals 51, 52 and 53 display the signal level "1" when PAL, pure NTSC and quasi-NTSC are involved is. The signals appearing at these output terminals 51, 52 and 53 are then used for controlling the said switches. In the case of a color television signal of the quasi-NTSC type, it is sufficient that for the subcarrier frequency of the subcarrier signal generating circuit 22 of Figure 1, a value of 4.43 MHz is selected, as with a color video signal of the PAL type; the selector switches 16, 17, 27 and 35 are subjected to the same switching control as in the case of a color video signal of the pure NTSC type. The present invention is particularly suitable for use in such cases, such as for example in Central and South America, where chrominance components of color video signals of the type PAL-N (subcarrier frequency 3.58 MHz), the type PAL-M (subcarrier frequency 3, 57 MHz), and NTSC (subcarrier frequency 3.58 MHz) must be processed by a common chrominance component processing circuit. As described above, according to the invention, switching takes place between certain circuit parts, such that the carrier-modulated chrominance components of color video signals according to mutually different standard types are processed by a common circuit, whereby automatic switching of the different parts is obtained. A signal processing circuit for processing the chrominance signal component associated with the color video signals independently of a standard signal transfer mode used in signal transmission of composite color video signals, comprising: a common, first processing circuit operating independently of the standard signal transfer mode used for selecting from the color video signals at least the 50 chrominance signal component and a color burst signal; a second processing circuit connected to the first processing circuit with, for each standard signal transmission mode, a separate operating mode selectable by means of first switching means for processing and demodulating the chrominance signal component produced by the first processing circuit; 55 a color carrier generator with, for each standard signal transmission mode, an operating mode selectable by means of second switching means for generating a color carrier signal specific for the selected operating mode; 192177 detection and switching control means connected to the first processing circuit for supplying an indication signal relating to the transmission mode of the color burst signal, when supplying the color burst signal selected in the first processing circuit, and generating a switching control signal on the basis of this indication signal for the purpose of the first and the second switching means, wherein the switching control means activates the switching means with a periodicity of predetermined period duration; and holding means for maintaining the switching means in a switching state corresponding to the output signal of the detection means, characterized in that the detection and the switching control means comprise: a phase comparison circuit for supplying the color burst signal and the signal carrier generated by the color carrier generator. generating a carrier color signal from the indication signal based on the phase difference signal to be formed; and a switching signal generator connected to the phase comparison circuit for generating the switching control signal, depending on the status of the indication signal at a state of the indication signal unchanged for a predetermined period of time. Signal processing circuit according to claim 1, characterized in that the detection means comprise a low-pass filter, the time constant of which represents a shorter duration than the predetermined period duration. Signal processing circuit according to claim 1 or 2, characterized in that the switching control means comprises a counter, the clock pulse input terminal of which receives the vertical synchronization pulses of a composite video signal and the counting result of which is a measure of the predetermined period duration. Hereby 1 sheet drawing