NO135049B - - Google Patents

Abstract

Decoding device for a color television receiver.

Description

The invention generally relates to color television receivers which are adapted to receive signals transmitted in accordance with the phase shift system, usually referred to as the PAL system, and in particular to a decoding device for color television receivers which are adapted to receive and reproduce the signals transmitted in accordance with the PAL system.

In the PAL system, as is known, a composite color television signal comprises two color signal components, usually in the form of color difference signals containing chrominance information,

which by means of quadrature amplitude modulation with a suppressed carrier is simultaneously modulated on a color auxiliary carrier within the video frequency band, the phase of a modulation axis for one of the chrominance signal components being reversed by 180° for each line period.

Certain systems have so far been proposed for decoding such a composite color television signal, e.g. the so-called simple PAL system and the normal PAL system. With these conventional systems, however, the PAL signal is decoded at the expense of reduced quality of the reproduced image or at the expense of greatly increased complexity in the system.

In the Norwegian patent application 1000/71, a system for decoding the PAL signals is described in such a way that certain of

the limitations that naturally form part of the existing PAL decoding systems are avoided. This system is also theoretically capable of

to receive signals transmitted either in accordance with the PAL system or in accordance with the so-called NTSC system, even if the actual color auxiliary carrier frequencies used

in these two color television systems, it makes it difficult to exploit the latter property.

The decoding system according to the aforementioned Norwegian patent application comprises an arrangement of a switching circuit and a delay circuit which are connected to receive the incoming chrominance signal. This chrominance signal is first transmitted directly to demodulators in the course of a line time interval, and then the same information, which is delayed by a line time interval, is transmitted again by the delay circuit via the switching circuit to the demodulators in the course of the next line interval. The chrominance information sent from the television station during the course of. the second line interval is not used by the receiver. The signal transmitted during the third line interval is passed through to the demodulators without delay and is repeated in delayed form during the fourth line interval. The chrominance signal in which both modulation axes of two color signal components are kept in fixed phases during the entire line interval is obtained as a result and fed to the demodulators. In this case, for correct demodulation, it is necessary that the two modulation axes for the chrominance signal that is fed to the demodulators have the same phases as the corresponding reference auxiliary carrier wave signals emitted by a local oscillator that is phase-controlled in relation to a color sync pulse signal that is included in the composite color television signal and is used for demodulation of the two chrominance signal components. One way of achieving this is that the phases for the chrominance signal's modulation axes are detected, and that the switching circuit which is connected to receive the incoming chrominance signal is controlled to transfer the chrominance signal with correct modulation axes to the demodulator, or that the phase of the reference auxiliary carrier wave signals from the local oscillator is controlled.

In a chrominance signal transposed in accordance with the PAL system, a sync pulse signal has two phase positions that alternate for each line period. These two sync pulse phases are taken alternately in accordance with a modulation axis's phase which is shifted by 180° for each line period.

It is an object of the invention to provide an improvement of the decoding device according to the aforementioned Norwegian patent application no. 1000/71. More specifically, the purpose of the invention is to provide a decoding device where the reference auxiliary carrier wave signals used for demodulation of the chrominance signal are automatically transmitted to the demodulators with the correct phase relationship to the chrominance signal to be demodulated, and where the phases of the aforementioned reference auxiliary carrier wave signals . at the same time is varied in a predetermined ratio to achieve hue regulation.

For the achievement of the above purpose it is provided

a decoding device for a color television receiver for decoding a PAL color television signal, comprising a switching device which switches through a time-selected part of the received original chrominance signal components in an intermittent rhythm during such time periods in which the two chrominance signal components with respect to their modulation axis have the same relative phase position, a delay circuit for delaying at least the selected chrominance signal components by a time which is an equal or an odd multiple of the duration of the said time sections, only the original chrominance signal components and their delayed repetitions being used alternately for demodulation, two demodulators, a first addition circuit for addition of a first and a second reference signal with phases that are in a certain ratio to the chrominance signal's sync pulse signal to provide a signal which is applied to one of the two demodulators as a reference auxiliary carrier signal, and a second addition circuit for addition of the first reference signal and the phase-inverted second reference signal for providing a signal which is fed to the second of the two demodulators as a reference auxiliary carrier signal, and the decoding device is, according to the invention, characterized in that it comprises level control devices for simultaneously changing the level of minimum the first or the second reference signal in such a way that an increase of the amplitude of the level-changed reference signal added to the first addition circuit corresponds to a decrease of the amplitude of this reference signal added to the second addition circuit.

With this decoding device, as an intermediate step, first and second signals are formed which have the same frequency, but different phase in accordance with the sync pulse phases of the incoming chrominance signal, e.g. using local oscillators locked to the sync pulse phases, and these two signals are added to each other directly and after being suitably phase-shifted to provide two vector sums. As a result, two reference auxiliary carrier signals with the correct phases are automatically formed for correct demodulation of the chrominance signal in the demodulators. In this case, the level ratio between the two signals which are added to provide the vector sum is simultaneously varied in both pairs in a predetermined ratio to simultaneously shift the phases of the vector sum, i.e. the phases of the reference auxiliary carrier wave signals. This makes it possible to provide tonal adjustment as required. The reference auxiliary carrier signals which for the hue control are appropriately phase controlled are supplied to the demodulators for demodulation of the chrominance signal obtained from the arrangement of a switching device and a delay device. Both demodulators' output signals are fed to a matrix circuit to

. for example produce three primary color signals.

The invention will be described in more detail below with reference to the drawings, where fig. 1 and 2 are vector diagrams for explaining a color television signal in the PAL system, Figs. 3 is a block diagram showing an embodiment of a decoding device according to the invention, fig. k - 16 are vector diagrams for explaining the device in fig. 3, and fig. 17 - 19 are block diagrams showing modified embodiments of the invention.

The core of the PAL color television system lies in the phase relationship between the two color difference signals which are modulated on a common auxiliary carrier wave to form a chrominance signal. This phase relationship is shown in fig. 1. One of the chrominance components, namely Eg-Ey, contains information regarding blue components in the television picture. The second chrominance component, namely ER-Ey contains information regarding red components. Both of these chrominance components are modulated on the same carrier wave or rather auxiliary carrier wave, but the modulation is carried out separately in such a way that for a given time interval corresponding to a line n in the color television signal, the chrominance component E^-Ey is modulated on the auxiliary carrier wave with a modulation axis having the phase ØQ. In the course of the same time interval, the second chrominance component E--Ey is modulated on the carrier wave with a modulation axis having the phase øQ-<y>/2. For this reason, the chrominance component (Eg-<E>y)n representing blue information during the given line interval n is shown as a horizontal arrow in fig. 1, and the red chrominance component (Ep-Ey)n during the same line interval n is shown as a vertical arrow. Vector addition of these two chrominance components gives rise to a resulting signal F n which is a complex voltage that can be defined by the expression (E-g-Ey)n +

<j>(<E>R-<E>Y)n.

The phase relationship for the following line n+1 is also shown

on fig. 1. In this case, the chrominance component Eg-Ey is modulated on the carrier as the modulation axis likewise has the phase (zSq-tt/2, so that the chrominance component (Eg-Ey)n+-^ for the line n+1 is shown in the same direction as the component (Eg -Ey) . In accordance with the PAL system, however, the chrominance component E^-Ey is modulated on the carrier with a modulation axis having a phase

ØQ-fl" (-0 ), i.e. reversed phase in relation to the phase that characterizes the preceding line n, so that the chrominance component (E^-Ey)n+-^ for line n+1 is shown in the opposite direction of the component (E^-Ey)n. The signal Fn+-]_ can thus be defined by the expression (Wn+l <-> ^%-Vn+l-

The chrominance signal contains a sync pulse signal or color synchronization signal. The sync pulse signal has different phases for the two signals Fn and Fn+-^. As shown in fig. 2,

thus the phase of the sync pulse signal in the signal Fn is phase-shifted +5° in the anti-clockwise direction in relation to the phase øQ and is represented as B+. Likewise, the phase of the sync pulse signal in the signal F is shifted <>>+5° in the clockwise direction in relation to the phase ø^- TT (-øq) and or shown as

Fig. 3 shows an embodiment of the decoding device according to the invention. The reference number 1 denotes a band pass amplifier by means of which the aforementioned chrominance signal ad is separated from the composite color television signal. The chrominance signal is fed directly to an input terminal 3 in a switching device or switching circuit 2, usually designated as a two-pole two-way switch, and at the same time to the switching circuit 2's second input terminal h via a delay circuit 5 by means of which the signal is delayed by a line interval. A horizontal pulse formed by a horizontal deflection circuit (not shown) is fed to a flip-flop circuit 6 for its operation. By means of a switching signal produced by the flip-flop circuit 6, the switch circuit 2 changes in such a way with each horizontal scan that diodes 10 and

•11 is made conductive at the beginning of a line (hereafter called plus line), at which the demodulation axis for, for example, the red color difference signal has a phase øQ, and so that

diodes 12 and 13 are made conductive at the beginning of a line (hereinafter called minus line), at which the modulation axis of the red color difference signal has a phase -J3q. When the switch circuit 2 is switched in the above manner, only positive line signals are obtained and each such signal is obtained twice from the output terminal 7 of the switch circuit 2 in the sequence: Fn, Fn, Fn+2, Fn+2, <F>n+1+, ,

and no minus line signals are obtained from this output terminal. Only minus line signals are received simultaneously in sequence and twice each from the second output terminal lh in sequence: Fn_-^, F ^, Fn+-^, Fn+3' Fn+3' •••'■ > °S no plus line signals are received from this output terminal. The signals from, for example, the output terminal 7 are then fed to the demodulators 8 and 9.

If, on the other hand, the switch circuit 2 is changed to the opposite state in relation to that stated above, only minus line signals are obtained from one output terminal 7 in the sequence: Fn-1,<F>n<+>1, Lo, Lii 1 °g no plus line signals are obtained from

n+ x7 n+ j5' n+ j

this output terminal. Only plus line signals are emitted simultaneously from the second output terminal l^ in • the sequence: Fn,. Fn, F 2?- Fn+2, Fn+!+, and-no minus line signals are obtained from this output terminal. In this case, the minus line signals are consequently fed to the demodulators 8 and 9. In this case, the signals that are fed to the demodulator 9, of the signals for lines located

next to the respective lines whose signals are fed to the demodulator 8.

The signal obtained from one output terminal 7 of the switching circuit 2 is fed to a sync pulse gate circuit 15 in order to obtain a sync pulse signal from this circuit by means of a gate signal supplied from a gate signal generator circuit 16. The thus obtained sync pulse signal is fed to a generator circuit 17 which consists of a quartz crystal oscillator for generating a continuous wave signal that drives a local oscillator 18. In a similar way, the signal obtained from the switch circuit 2's second output terminal 1k is fed to a sync pulse gate circuit 19 in order to obtain from this circuit a sync pulse signal which is fed to a generator circuit 20 for generation ay' a continuous wave signal that drives a local oscillator 21. A signal obtained from the local oscillator 18 is fed via a level control device 22 to an addition circuit 23

for generating a vector sum. A signal obtained from the local oscillator 21 is fed to a phase inversion circuit 2h whose output signal is fed to the addition circuit 23 via a level control device 25, and the output signal of the addition circuit 23 is fed to the first demodulator 8. At the same time, the signals from the local oscillators 18 and 21 are fed to an addition circuit 28 via level control devices 26 respectively 27, and the output signal of the addition circuit 28 is supplied to the second demodulator 9 via a phase inversion circuit 29.

The level control devices 22, 25, 26 and 27 are set simultaneously by the action of a common hue control button. When the hue adjustment knob is turned to its middle position, the signals from the local oscillator 18 and the phase inversion circuit 2h are added to each other with the same level in the addition circuit 23, and the signals from the local oscillators 18 and 21 are added to each other with the same level in the addition circuit. 28..When the hue adjustment knob is turned in a first direction from the middle position, the level of the signal obtained from the local oscillator 18 is increased by means of the level control device 22, the level of the signal obtained from the phase inversion circuit 2^ is decreased by means of the level control device 25, the level of the signal obtained from the local oscillator 18, is decreased by means of the level control device 26, and the level of the signal obtained from the local oscillator 21 is increased by means of the level control device 27. When the hue control knob is turned in the other direction in relation to the center position, the level of the signals fed to the addition circuits 23 and 28, in opposite directions in relation to the above ang not.

When the plus line signal is fed to the demodulators 8 and 9 from the switch circuit's. 2 one output terminal 7 on the one described above

manner, and assuming that the color tone adjustment knob is turned to its middle position, the sync pulse signal contained in the plus line signal from the gate circuit 15 and a continuous wave signal with the same phase as the sync pulse signal from the generator circuit 17 are consequently obtained, so that a first reference signal S-j_ with the same phase

as the sync pulse signal is obtained from the local oscillator 18, like this. as shown in fig. h and 6. In this case the minus line signal is obtained

.from the switch circuit 2's second output terminal 1<*>+, so that the sync pulse signal in the minus signal is obtained from the gate circuit 19 to form a continuous wave signal with the same phase as the sync pulse signal with the help of the generator circuit 20. As shown in fig. h and 6, the local oscillator 21 consequently forms a second reference signal S2 with the same phase as the sync pulse signal so that a signal S- is obtained from the phase inversion circuit 2h. which is phase-shifted by 180 in relation to the signal S2'. In the addition circuit 23, the reference signals and from the oscillator 18 and the phase inversion circuit 2h are added to each other with the same level, so that as a vector sum of these signals a signal S^ is provided as shown in fig. <*>+, which signal's phase is exactly in the middle

between the phase of the signals S-^ and Sy The signal S^ is supplied as a first reference auxiliary carrier wave signal to the first demodulator 8. At the same time the reference signals S-L and S2 from the oscillators

18 and 21 in the adding circuit 28 are added in a similar way to each other with the same level, so that a signal S^ as shown in fig. 6, the phase of which signal lies in the middle between the phases of the signals S-^ and S2, so that the phase inversion circuit 29 produces a signal S,- which is phase-shifted by 180° in relation to the signal ■S^,•i.e. phase shifted by 90° relative to the first reference auxiliary carrier wave signal S^. The thus produced signal S^ is supplied as a second reference auxiliary carrier wave signal to the second demodulator 9. The plus line signal fed to the demodulators 8 and 9 is consequently demodulated with the same axes as the corresponding modulation axes, which is evident from fig. 1. When, on the other hand, the flip-flop circuit 6 changes state in the opposite way to supply the minus line signal to the demodulators 8 and 9 from the output terminal 7 of the switch circuit 2, as described above, the gate circuit 15 takes out the sync pulse signal in the minus line signal, so that from local oscillator 18, a reference signal S2 with the same phase as the sync pulse signal is produced. as shown in fig. 5 and 6. Since the plus line signal in this case is obtained from the switch circuit 2's second output terminal X^t-, the gate circuit 19 produces the sync pulse signal in the plus line signal, and the local oscillator 21 emits a reference signal .S-^ with the same phase as the sync pulse signal, as shown in fig . 5 and 6. Consequently, the phase inversion circuit 2h produces a signal S,-, which is 180° phase-shifted in relation to the signal S-^ The signals S2 and S^ which are obtained from the local oscillator 18 respectively. the phase inversion circuit 2^, are then added to each other with the same level in the addition circuit 23 to provide a signal Sg as shown in fig. 5, which signal's phase - ØQ lies midway between the phases of the signals S2 and S^, and which

signal Sg is supplied as a first reference auxiliary carrier wave signal to the first demodulator 8. At the same time, the signals S2 and S-^ supplied from the local oscillators 18 and 21 are added to each other with the same level in the addition circuit 28, to provide a signal S^- which is uniform with those mentioned above. The phase inversion circuit 29 consequently also produces a signal Sg which is uniform, with those mentioned above and which is supplied as a second reference auxiliary carrier signal to the second demodulator 9. The minus line signal fed to the demodulators 8 and 9 is consequently demodulated with the same axes as the corresponding modulation axes,

which appears from fig. 1. At this stage, the demodulators 8 and 9 thus produce predetermined, demodulated chrominance signals which are always demodulated with the same axes as the modulation axes.

• When the color tone adjustment knob is turned in a first direction', for example to the right, in relation to its middle position, an increased level is obtained for the signal from the level control device 22, decreased level

for the signal from the level control device 25, reduced level for the signal from the level control device 26 and increased level for the signal from the level control device 27, compared with the signal levels from the hue control knob is in its middle position. When the plus line signal under these conditions is supplied to the demodulators 8 and 9 from the switching circuit 2 output terminal 7, the oscillators 18 and 21 produce the signals Sj_ respectively. S2, and the phase inversion circuit 2<*>+ produces the signal Sy A signal S-q which is obtained from the level control device 22 and which has the same phase as the signal S-[_, but a higher level than this, and a signal S-^ which is obtained from the level control device 25 and which have the same phase as the signal S-^, but a lower level than this, are easily added to each other to produce a signal S-^, as shown in fig. 7. The phase of this signal is a ahead of the phase of the signal S^_ and this signal is fed as a first reference auxiliary carrier wave signal to the first demodulator 8. A signal S21 which is obtained from the level control device 26 and which has the same phase as, but lower level than the signal S-p and a signal S22 which is obtained from the level control device 27 and which also has the same phase as, but a higher level than, this signal,

are further added to each other in the addition circuit 28, as shown in fig. 8. In this case, the level ratio between the signals S2^ and S22 is the opposite of the ratio between the signals S^_j_ and S-j^, so that the addition circuit 28 produces a signal S2^ as shown in fig. 8, which signal has a phase that lies a° - ahead of the signal S^. As a result of this, the phase inversion circuit 29 produces a signal S2g which in phase is a° ahead of the signal S^, i.e. is 90° out of phase with respect to the first reference auxiliary carrier wave signal of the second demodulator 9. The demodulation axis is shifted in this case as indicated by a dashed line in fig. 9, and the plus side signal F+ fed to the demodulators in 8 and 9 is demodulated with an axis which is in phase a° in front of the modulation axis. In the event that the flip-flop circuit 6 changes state in the opposite way to supply the minus line signal to the demodulators 8 and 9 from the terminal 7 of the switch circuit 2, the local oscillators 18 and 21, however, produce the signals S2 and S^, respectively, and the phase inversion circuit 2h produces the signal Sy. As shown in fig. 10, added,-fbl-

eg a signal S^2 which is obtained from the level control device 22 and which has the same phase but a lower level than the signal S^, and a signal S^,- which is obtained from the level control device 26 and which has the same phase as but a lower level than the signal S^, to each other in the addition circuit 23, so that from this circuit a signal S^g is obtained which is phase-delayed a° in relation to the signal Sg, and this signal added

res as a first reference auxiliary carrier wave signal to the first demodulator 8. As shown in fig. 11, a signal S^2 is added which is obtained from the level control device 26 and has the same phase as, but a lower level than, the signal S2, and a signal S^ which is obtained from the level control device 27 and which also has the same phase as, but a higher level than the signal S-p to each other in the addition circuit 28. Since the level ratio between the signals S^ and S^ is in this case the inverse of the ratio between the signals S^2 and S^y, the addition circuit 28 produces a signal S^ which is phased or lowered a° in relation to to the signal S^, and the phase inversion circuit 29 consequently produces a signal S^g which is phase-delayed a° in relation to the signal Sg, i.e. is 90° ahead in phase in relation to the first reference auxiliary carrier wave signal S^g, and the signal S^g is supplied as a second reference auxiliary carrier wave signal to the second demodulator 9. As a result, the demodulation axis is shifted as indicated by a dotted line in fig. 9,

and the minus line signal F fed to the demodulators 8 and 9 is demodulated with an axis which is phase shifted by a° in relation to the modulation axis. When the color tone adjustment button as shown in fig. 9, is turned e.g. contrary to opinion, the color tone is regulated in such a way that, for example, blue color is emphasized regardless of the flipping state of the flipper circuit 6, i.e. whether the plus or minus line signal is supplied to the demodulators 8 and 9. Depending on how the hue adjustment knob in this case is turned further away from its center position, the level difference increases between the two signals which are added to each other in the addition circuits 23 and 28, and the signal fed to the demodulators is demodulated with an axis which is further separated from the modulation axis,

to further emphasize the blue color.

When the hue control knob is turned in the other direction, e.g. towards the left, in relation to its central position, a reduced level is obtained for the signal from the level control device 22, an increased level for the signal from the level control device 25, an increased level for the signal from the level control device 26 and a reduced level for the signal from the level control device 27, compared to the levels of these signals the hue adjustment knob is in its center position. When the plus line signal under these conditions is fed to the demodulators 8 and 9 from the output terminal 7 of the switching circuit 2, the local oscillators 18 and 21 produce the signals S-^ respectively. S2, and the phase inversion circuit 2h produces the signal Sy As shown in fig. 12, a signal S^ which is obtained from the level control device 22 and which has the same phase as, but a lower level than the signal S-p and a signal S^ which is obtained from the level control device 25 and which has the same phase as, but a higher level than the signal S^ is added , to each other in the addition circuit 23, so that a signal S^ is obtained from this circuit which is phase-shifted B° in relation to. the signal S^, and this signal is fed as a first reference auxiliary carrier wave signal to the first demodulator 8. As shown in fig. 13, further becomes a signal Sg-^ which is obtained from the level control device 26 and which has the same phase as, but a higher level than, the signal Sp and a signal Sg2 which is obtained from the level control device 27 and which also has the same phase as, but a lower level than the signal S2, added to each other in the addition circuit 28, so that a signal Sg^ is obtained from this circuit which is phase shifted B° in relation to the signal S^. . second demodulator 9. In this case, the demodulation axis is shifted in the manner indicated by means of a dashed line in fig. 1<*>+, and the plus line signal F+ added to the demodulators 8 and 9 is demodulated with an axis which is

phase for s.inked B° in relation to the modulas ion axis. For that case

that the flip-flop circuit 6 changes state in the opposite way so that the minus line signal is fed to the demodulators 8 and 9 from the output terminal 7 of the switch circuit 2, the local oscillators 18 and 21 produce the signals S2 respectively. S-^ and the phase inversion circuit 2h produces the signal S^. As indicated in fig. 15, becomes in this case

a signal Sy2 which is obtained from the level control device 22 and which has the same phase, but a lower level than the signal S2, and a signal Syy which is obtained from the level control device 25 and which also. have the same phase as, but a higher level than, the signal Sy, added to each other in the addition circuit 23, so that from this circuit a signal Syg is obtained which is in phase B° ahead of the signal Sg, and the signal Syg is supplied as a first reference auxiliary carrier wave signal to the first demodulator .8. As indicated in fig. 16, further becomes a signal Sg2 which is obtained from the level control device 26 and which has the same phase as, but a higher level than, the signal S2, and a signal Sg-^ which is obtained from the level control device 27 and which has the same phase

as the signal S-^, but lower level than this, added to each other in the addition circuit 28, so that from this circuit a sig-

nal Sg^ which is in phase B° ahead of the signal S^. The phase inversion circuit 29 therefore produces a signal Sgg which is in phase B° ahead of the signal Sg, i.e. 90° ahead of the first reference auxiliary carrier signal Syg, and the signal Sgg is supplied as a second reference auxiliary carrier signal to the second demodulator 9. In this case, the demodulation axis is thus shifted in the manner indicated by means of a dash-dotted line in fig. I1*-, and the minus line signal F- fed to the demodulators 8 and 9 is demodulated with an axis which is in phase B° in front of the modulation axis. When the hue adjustment knob, as shown in the figure, is turned in the other direction in relation to its middle position, the hue is thus adjusted in a direction to emphasize the red color regardless of the flipping state of the flipper circuit 6, i.e. whether the plus or minus line signal is fed to the demodulators 8 and 9 As the hue control knob is turned further away from the center position, In this case, of course, the signal fed to the demodulators is also demodulated with an axis that is more separated from the modulation axis, in order to further emphasize the red color.

By turning the hue control knob for parallel adjustment of the level control devices 22, 25, 26 and 27, and at the same time changing the level ratios between the two signals added to each other in the addition circuits 23 and 28 in the manner described, the phases of the first and second reference auxiliary carrier signals supplied to the first and second demodulators 8 and 9 are continuously changed while the mutual difference is kept constant, in order to achieve hue regulation in this way.

In fig. 17 shows a modified embodiment of the invention, and this embodiment is exactly identical to the embodiment in fig. 3, with the exception ay that the signal obtained from the switch circuit 2's one output terminal 7 is fed to. the first demodulator 8, and the signal from the second output terminal 1*+ is fed to the second demodulator 9. One of the demodulators 8 and 9 is therefore fed with the plus line signal, and the other is fed with the nearby minus line signal. Thus, when the neighboring plus and minus line signals have the same level and are symmetrical with regard to phase in relation to the axis B-Y, the demodulators 8 and 9 produce demodulated chrominance signals which are similar to those mentioned above which are obtained in the embodiment according to fig. 3, and by adjusting the level control devices 26 and 27 in the opposite direction in relation to the above example, it is possible to achieve color tone regulation of the same type as that indicated above.

In fig. 18 another modification of the present invention is shown. When the chrominance signal in the present example is supplied to the demodulators 8 and 9 in the same way as described in connection with fig. 3, the sync pulse signal obtained from the sync pulse gate circuit 15 is fed through the level control device 22 to the addition circuit 23, and the sync pulse signal from the sync pulse gate circuit 19 is fed to the addition circuit 23 through the phase inversion circuit '<2>^ and the level control device 25. The output signal from the addition circuit 23 is fed to a generator circuit 30 f° r production of a continuous wave signal which is supplied to an oscillator 31 for operation of this. The oscillator's output signal is fed as a first reference auxiliary carrier wave signal to the first demodulator 8. The sync pulse signals from the sync pulse gate circuits 15 and 19 are simultaneously fed to the addition circuit 28 through the level control devices 26 or 27, and the output signal of the addition circuit 28 is fed through the phase inversion circuit 29 to a generator circuit 32 for producing a continuous wave signal which is fed to an oscillator 33 for operation thereof. The oscillator's output signal is fed as a second reference auxiliary carrier wave signal to the second demodulator 9. The addition operation is thus achieved in the sync pulse signal stage. Also in this case, the same demodulation is carried out as was the case in fig. 3, °g color tone regulation is achieved in the same way as discussed in connection with fig. 3.

Also in the case when the auxiliary carrier wave signal is fed to the demodulators 8 and 9 in the same way as in the example according to fig. 17, the addition operation can be performed in the sync pulse signal stage.

In fig. 19 shows a further modified embodiment of the invention, and this embodiment uses a switch circuit 3 with only one output terminal instead of the switch circuit 2, which is usually referred to as a two-pole two-way switch. The chrominance signal separated by the band-pass amplifier 1 is fed directly to an input terminal in the switching circuit 3'+, and simultaneously to the other input terminal via the delay circuit 5, by means of which the signal is delayed by a horizontal line period. The state of the switch circuit 31+ is changed by means of the switching signal supplied from the flip-flop circuit 6 for each horizontal scan, and the output signal of the switching circuit is fed to the demodulators 8 and 9. The signal from the bandpass amplifier 1 is simultaneously fed to switch circuits 35 and 36 whose switching state is changed by switching .ssignal from the flip-flop circuit 6 for each horizontal sweep, at the same time as they are maintained in a certain relationship to the switch circuit 3^ to produce a signal for each horizontal sweep, and the signals thus produced are fed to the sync pulse gate circuits 15 or

19. When the switch circuit 3<*>+ in this case changes to the on

state shown in the figure, the switch circuits 35 and 36 also change to the states shown in the figure.

If the switch circuits 3<*>+ °g 36 are switched to the shown states upon the arrival of the plus line signal, and to the opposite states upon the arrival of the minus line signal, consequently the plus line signal is produced continuously from the switch circuit 3^ °g this signal is supplied to the demodulators 8 and 9. From the switch circuit 35 is produced the plus line signal for providing the sync pulse signal in the plus line signal by means of the gate circuit 15, and from the switch circuit 36 the minus line signal is produced for providing the sync pulse signal in the minus line signal by means of the gate circuit 19. If the flip-flop circuit 6 changes state • in the opposite way to switch the switch circuits 3+ - 36 to the opposite of the states shown upon the arrival of the plus line signal, and to the states shown upon the arrival of the minus line signal, instead the minus line signal is produced continuously from the switch circuit 3+ and this signal is fed to the demodulators 8 and 9. From the switch circuit 35 the minus line signal is produced for further introducing the sync pulse signal into this signal by means of the gate circuit 15, and from the switch circuit 36 the plus line signal is produced for providing the sync pulse signal into this signal by means of the gate circuit 19. Also in this case, therefore, precisely the same demodulation is achieved as was the case with the device in fig. 3, and the color tone regulation is carried out in the same way as with the device in fig. 3.

In this case, the signal from the switch circuit 3<!>+ can be supplied to the sync pulse port circuit 15. Also in this case, when the switch circuit or the so-called two-pole two-way switch 2 in fig. 3 °g 17 is used, the oscillator can further be driven with the sync pulse signal which is contained in the signal obtained from the bandpass amplifier 1 for each horizontal sweep.

In each of the above examples, for each horizontal scan the non-too-synched, original chrominance signal and the signal delayed by one horizontal line period with respect to the former signal are picked up alternately and then fed to the demodulators, but it is also possible that for each horizontal scan alternately picks up the non-delayed original chrominance signal and a signal delayed by a different number of times a horizontal line period.

With the previously described circuit according to the invention, two signals with different phases are added to each other

for generating a vector sum of these signals, by means of which a predetermined reference subcarrier signal for demodulation can be easily obtained to ensure a predetermined demodulation, and further, hue control can be achieved efficiently and directly by means of a simple construction for changing the level ratio between the two signals added to each other.

In the above examples, the phase difference between the first and second reference auxiliary carrier signals, i.e. the difference between the demodulation axes in the first and second demodulators, is 90° when the hue control knob is held in its center position, but it will be appreciated that the phase difference can be selected with a value other than 90° using of a suitable treatment in a matrix circuit. The present invention can further be adapted to the case when the two chrominance signals are I and Q signals or similar."

Claims (1)

Decoding device-for a color television receiver for decoding a PAL color television signal, comprising a switching device (2) which switches through a time-selected part of the received original chrominance signal components in an intermittent rhythm during such time periods in which the two chrominance signal components with respect to their modulation axis have same relative phase position, a delay circuit (5) for delaying at least the selected chrominance signal components by a time which is an equal or an odd multiple of the duration of the mentioned time sections, only the original chrominance signal components and their delayed repetitions being utilized alternately for demodulation, two demodulators (8, 9), a first addition circuit (28) for the addition of a first and a second reference signal (S-j_, S2) with phases that are in a specific relationship to the chrominance signal's sync pulse signal (B+, B-) to provide a signal (Sg) which is supplied to one (e.g. e.g. 9) of the two demodulators (8,9) as reference auxiliary carrier wave signal, and a second addition circuit (23) for addition of the first reference signal (S-^) and the phase-inverted second reference signal to provide a signal (Si) which is supplied to the second (e.g. 8) of the two de- • .« - ■ - •-,« modulators (8, 9) as a reference auxiliary carrier wave signal, characterized in that it comprises level control devices (22, 25, 26, 27) for simultaneously changing the level of at least the first or the second reference signal (S-|_ or S2) in such a way that an increase of it to the first addition circuit (28) adds to the amplitude of the level-changed reference signal (f . eg S-^) corresponds to a reduction of the amplitude added to the second addition circuit (23) by this reference esignal.