NO137472B - COLOR SYNCHRONIZATION DEVICE IN A TELEVISION RECEIVER - Google Patents

Description

The present invention relates to a color synchronization device

for television receivers adapted to PAL (phase alternation for each line) or similar signal transmission systems, in which a pair. of color signals causes simultaneous quadrature-balanced modulation of a color carrier wave with respect to a first and a second mutually perpendicular modulation axis, the second axis of which is subjected to a 180° phase shift for each of the subsequent horizontal line sweeps.

In a color television receiver built for such a signal transmission system, for the demodulation of color components along said first and second modulation axes from a color or chrominance signal, a pair of reference carrier waves is required, each of which maintains a fixed phase relationship with said chrominance signal. One of these reference carrier waves preferably has a fixed phase of 0° which thus coincides with said first axis j. while. the ■ other nerve preferably has a phase shift of 90° in relation to the first axis as well as a

phase change of 180° for each new horizontal line sweep,

in that this phase change must correspond to the periodic phase switching for said second axis. A method of automatically achieving phase control by means of these reference carrier waves is described in German Patent Document No. 1,260,520, which proposes to use a color sync signal which is included in the color television signal and comprises a first and a second component which can act simultaneously or in sequence in the opening paragraph of each horizontal

sweep line, whereby these components have a mutual phase shift of 90°. Below, the first component has a fixed phase, while the second component has a phase that periodically alternates 180° for each successive horizontal line, corresponding to the periodic phase switching for said second modulation axis.

In the PAL system that is in common use today, said first and second color sync signal components appear simultaneously as a synthesized signal, which alternately has a phase of +45 or -45° for successive horizontal line sweeps. This synthesized color sync signal is resolved in the receiver into two components, the first component being used for synchronizing the reference carrier waves while the second component is used for controlling the periodic switching of the phase for it. one. of said reference carrier waves. In a conventional color television receiver operating in accordance with the PAL system, the reference carrier wave used for demodulating a

■ color difference signal along the R-Y axis, which corresponds to the above-mentioned second modulation axis, from a chrominance signal, usually by means of a technique which will be discussed in the following..

A color sync signal is initially derived from a color television signal and phase demodulated to form a so-called "discriminating control voltage" with a frequency equal to half the horizontal sweep frequency. The control frequency thus formed synchronizes a square wave <- generator, which produces square waves with the same duration as a horizontal line sweep, this duration being hereinafter referred to as "1 inje period". This square wave is supplied as a voltage input to a switch

which is arranged to cause switching between two output signals from a local oscillator, and which have a mutual phase difference of 180°. relative to. each other, as this oscillator synchronizes with the base frequency of the received color sync signal.

The demodulation of the color signal along the modulation axis with

fixed phase, on the other hand, is caused by a reference carrier wave with the same frequency as the color carrier wave, and which is synchronized with the fundamental frequency of the received color sync signal.

On the other hand, an improved color synchronization system for a television receiver is proposed in the applicant's previously filed Norwegian patent application no. 197/72, which eliminates the need for the above-mentioned switch to control the phase change by 180° for one of the reference carrier waves used in the demodulation of the chrominance signal.

Briefly, in the proposed color synchronization system, the aforementioned demodulation of the color signal is achieved along the modulation axis which is subjected to 180° phase change, by producing a shifted carrier wave with a frequency equal to fsc + <2>n ^ fH, where fsc denotes the frequency of the color carrier wave, fH the line sweep frequency and n is a positive integer. The shifted carrier wave is phase modulated with a sawtooth wave at the frequency of the line sweep to provide a reference carrier frequency whose phase is kept constant during each line sweep period. The synchronization of the carrier wave with frequency fsc + ^n ^ ^ fH is achieved by using one of the sideband frequencies contained in the color sync signal for this purpose.

It is an object of the present invention to provide a color synchronization system for demodulation along the modulation axis with fixed phase, and which can be used in connection with said color synchronization system for demodulation along the modulation axis with phase change, as indicated in the aforementioned previously filed patent application, in order thereby to enable the construction of an improved color television receiver.

The invention thus relates to a device for color synchronization of a color television receiver arranged for receiving color television signals of the type that comprises a pair of color signals which are quadrature balanced modulated on a color carrier wave along the respective a first and a second modulation axis, which are mutually perpendicular, and of which the second axis is subject to 180° phase change for each successive horizontal line sweep, as in the known PAL color television system, while the television signals further comprise a color sync signal with the same frequency as said color carrier wave and which makes it possible to identify said first and second modulation axis in the receiver, and the device includes devices for producing a shifted carrier wave with a frequency equal to fsc + ^—— fH, where fsc is the frequency of the color carrier wave, fH is that of the line sweep frequency and n is a positive whole number, as well as means for generating a reference carrier wave for use in demodulation along said first modulation axis. Against this background, the special feature of the device according to the invention is that said means comprise shaping circuits to derive from said shifted carrier wave an auxiliary carrier wave with frequency equal to twice the f of the color carrier wave frequency, a dividing circuit for frequency halving of said auxiliary carrier wave

thereby producing a carrier frequency equal to the frequency of the color carrier wave and with one or the other of two alternative polarities, as well as control circuits for selecting any of the two polarities as suitable for said reference carrier wave.

The shifted carrier wave, whose frequency corresponds to one of the sideband frequencies in the color sync signal, can be derived from this sideband frequency by means of a sideband amplifier or a ringing oscillator with a crystal filter.

To perform synchronous detection in the normal way, the shifted carrier is modified into an auxiliary carrier with a frequency equal to twice the frequency of the color carrier, and this auxiliary carrier is applied to a frequency divider, the output frequency of which is controlled with respect to its polarity by a pulse derived by phase detection of the shifted carrier wave and the color sync signal, whereby a reference carrier wave with the same frequency as the color carrier wave and a fixed phase that coincides with the phase of the color carrier wave is obtained. The reference carrier wave can be used when demodulating a chrominance signal to produce a desired color signal. In this case, the demodulation along the second modulation axis can be produced by means of an output signal from a phase modulator which phase modulates the shifted carrier wave with a sawtooth wave of line-swept frequency, whereby the resulting output signal can be used as a reference carrier wave at any time during the sweep time for each horizontal line .

For a better understanding of the invention, various examples of this invention will now be described with reference to the attached drawings, in which: Fig. 1 is a block diagram for an embodiment of the invention,

fig. 2 is a vector diagram for the color sync signal,

fig. 3 is a frequency spectrum for the color sync signal shown in fig. 2,

■ fig. 4 shows waveforms appearing in the diagram in fig. 1,.

fig. 5 is a vector diagram indicating the phase relationship between the color sync signal and the output signal from the sideband amplifier, as detected by the phase detector in the diagram in fig. 1,

fig. 6 shows the curve shape for the output signal from the phase detector for the phase relationship indicated in fig. 5,

fig. 7 shows the waveform of the output signal from a ringing oscillator synchronized with the pulses shown in fig. 6,

fig. 8 is a block diagram of another embodiment according to the invention and equipped with two sideband amplifiers,

fig. 9 is a block diagram of a portion of a further embodiment

of the invention, and which includes an automatic phase control circuit,

fig. 10 is a vector diagram of the same type as fig. 5, but which indicates a different phase relationship, and

fig. 11 shows the curve shape for the output signal from the phase detector for the phase relationship indicated in fig. 10.

Reference must now be made to fig. 1, in which a gate circuit is shown

1 for the color sync signal* As is known, a chrominance signal is supplied to the gate circuit for the color sync signal together with a gate pulse, which can be the horizontal return pulse bg which keeps the gate open for the duration of the pulse, thereby separating the color sync signal from the chrominance signal when it passes the output of the gate circuit. In the commonly used PAL system, the color sync signal comprises a pair of signal components that act simultaneously, so that the resulting color sync signal has an alternating phase of +45° or -45° for successive horizontal line sweeps, as indicated in fig. 2. The frequency spectrum for the color sync signal is shown in fig. 3, whereby it will be clear that said signal comprises sidebands with frequencies fsc <2>n — ^ fH, i.e. frequencies higher or lower than the color carrier frequency, fscy with values n ~ times 1 the injection frequency fH. Thus, when the output signal from the gate circuit 1 is supplied to a sideband amplifier 2 with a crystal filter to extract and amplify one of the mentioned sidebands which can be used as the previously mentioned shifted carrier wave. The sideband preamplifier 2 can be replaced by a local oscillator with automatic phase control (APC) and a

2n — 1

oscillator frequency of fsc + —■'—^— fH, the output signal from gate circuit 1 being used for synchronizing the oscillator's output frequency. It will further be understood that the same result can also be achieved by using a ringing oscillator instead of the sideband amplifier.

The shifted carrier wave obtained at the output side of the sideband amplifier 2 is supplied to a phase modulator 3 in which it is phase modulated by a modulation wave with period H. (the reciprocal value of the 1 inje frequency) and which is supplied from a shaping circuit 4 for a sawtooth wave. As a result of this phase modulation, an output signal is obtained from the modulator 3 which can be used as a reference carrier wave in a demodulator 5 for demodulating the chrominance signal along the phase-changing modulation axis,

which is to say the R-Y axis. This part of the demodulation forms no part of the present invention and will therefore not be further explained or described here.

According to the invention, however, the output signal is carried

from the phase modulator 3' also to a frequency multiplier 9 comprising a double rectifier with a pair of diodes and an output circuit tuned to twice the frequency of the color carrier wave.

Fig. 4 (a) shows the output signal from the phase modulator, and it will be noted in this figure that this signal is reversed in phase for each horizontal line sweep. Fig. 4 (b) shows the curve shape for output signals according to the direction in the double rectifier, and fig. 4 (c) shows the output signal from the frequency multiplier 9 and with a frequency equal to twice the frequency of the color carrier wave. As will be clear from fig. 4 (c), the output signal from the frequency multiplier 9 has a constant amplitude and a fixed phase which remains unchanged during successive horizontal line sweeps. This output signal is supplied to a counter circuit 10 which comprises a resonant circuit tuned to the frequency of the color carrier wave,

so that a frequency-divided auxiliary carrier wave with a frequency equal to the frequency of the color carrier wave and with constant amplitude is obtained

and fixed phase, which remains unchanged for subsequent horizontal line sweeps. The output signal from the counting circuit 10 proceeds synchronously with the color carrier wave and is achieved by synchronization with the sideband for the color sync signal or another component thereof.

As shown by respectively solid drawn and dashed lines in fig. 4 (d), the output signal from the counter circuit 10 can have one or the other polarity, but for its use as a reference carrier wave must

this polarity must be unambiguously established. For this purpose, an identification pulse with the same period as twice the line sweep is derived from a phase detector 6, which is applied to the color sync signal

and the shifted carrier wave from the respective the color sync gate 1 and the sideband amplifier 2. A ring oscillator 7 is preferably connected and synchronized with the output signal from the phase detector 6. The identification pulse is applied to a gate circuit 8 as a controlling

gate pulse for this, and the shifted carrier wave which is supplied as another input signal to said gate circuit 8, is thus allowed to pass this as a polarity identifying sync signal, which includes oscillations of short duration for each period equal to twice the line sweep period. Such sync signals are used in the counting circuit 10 to control the polarity selection for the output signal from it. The output signal from the counting circuit 10 can therefore be directly used as a reference carrier wave with

fixed phase for synchronous detection of the chrominance signal in a demodulator ll._

The operation of the phase detector 6 will now be described in more detail. This phase detector 6 is supplied with the color sync signal and the shifted carrier wave under a suitable mutual phase relationship. If this phase relationship is as shown in fig. 5, where the color sync signal is indicated by an arrow or phase vector m and the shifted carrier wave during the same line period is indicated in a phase position shown by an arrow or phase vector n, the closest following color sync signal will have an inverted position, as indicated by the arrow s is drawn dashed, and the corresponding shifted carrier wave will have a phase position. which is shown by the arrow t.i. dotted line. For such a phase relationship, the phase detector 9 will produce identification pulses as shown in fig. 6, and with reversed polarity for each line period. The identification pulses thus have a period equal to twice the line period H. Such identification pulses can be generated by the phase detector 6 for a phase relationship different from that shown in Fig. 5, even such that the phase vectors m and n are in phase, which corresponds to the use of a color sync signal with a first and second component appearing in sequence, as opposed to the most commonly-occurring relationship in the PAL system. These identification pulses are used in the gate circuit 8 to generate short-term sync oscillations for each pulse period, as mentioned above. In order to ensure stable operation of the gate circuit 8, the output signal from the phase detector 6 is preferably supplied through a ring oscillator 7 instead of directly, the oscillator 7 being able to oscillate at a frequency equal to half the line sweep frequency, and is synchronized with said pulses. 7 can either be a multivibrator or a blocking oscillator, which will then supply the gate circuit 8 with pulses of the form shown in Fig. 7.

Reference must now be made to fig. 8 which shows another embodiment

of the invention, and in which corresponding parts are designated with the same reference number as above. The frequency multiplier 9

in the above-mentioned embodiment is omitted and instead an additional sideband amplifier 14 and a detector 15 are arranged to carry out "hover detection" of two shifted carrier waves in an additive manner, thereby deriving an auxiliary carrier wave with a frequency equal to double the frequency of color carrier waves from sidebands in the color sync signal or from shifted carrier waves synchronized with such sidebands.

The further sideband amplifier 14 extracts a shifted carrier wave with a frequency fsc + <-> fH from the sideband of the color Syn]c_ signal, such as the sideband2 amplifier 2, the selected frequencies for these sideband amplifiers being such that one of them extracts a sideband with a frequency higher than the color carrier frequency with a value equal to —n ^ . times the line sweep frequency, while the other extracts another sideband with a frequency lower than the color carrier frequency with the same value given above. The mentioned sideband amplifiers 2 and 14 thus amplify sideband frequencies above and below the center frequency, fsc and shifted from this by a value equal to 2 n ^— 1 times the line sweep frequency. The sideband amplifier can also be replaced by a ringing oscillator or a local oscillator with APC and synchronized with the selected sideband. By supplying these two shifted carrier waves to the detector 15 to produce drift detection in an additive manner, an auxiliary carrier wave is obtained with a frequency equal to twice the frequency of the color carrier wave, as indicated by the following equation:

The detector 15 comprises a resonant circuit tuned car 2 fsc,

so that an output signal with the same waveform as shown in fig. 4 (c), and corresponding output signal from the frequency multiplier 9 in the previous embodiment. The output signal from the detector 15 is supplied to the counting circuit 10

and is treated in a similar way as before, to produce a reference carrier wave with a color carrier wave.' frequency and with fixed phase.

Although the frequency of the shifted carrier remains

constant at a predetermined value, its phase may be subject to deviation from a given phase relationship relative to the color sync signal, due to variations in the circuit's temperature coefficients, aging or fluctuations in the voltage supply. In order to avoid such deviations, according to the invention it is prescribed to use an automatic phase control circuit to maintain a fixed phase relationship between the color sync signal and the shifted carrier wave.

Another embodiment of the invention comprises an automatic phase control as shown in fig. 9, in which corresponding parts are designated with the same reference number as in fig. 1. Additional reference numbers 16 and 17 denote respectively a .buffer amplifier

and a detector for detecting faults. When the output signal from the phase detector 6 consists of pulses with alternating polarity as indicated in fig. 6, this indicates that the shifted carrier wave supplied to the phase detector 6 from the sideband amplifier 2 has the correct phase between the alternating phases of the color sync signal, as indicated in fig. 5. When a deviation occurs in the phase of the shifted carrier wave, as indicated by the vector n' in fig. '10, however, the resulting output signal from the phase detector 6 from positive and negative pulses will .(Fig. 11). of different size. Under these circumstances, the buffer amplifier 16 amplifies the output signal from the phase detector 6 to a suitable level, and the error detector 17 is operative to derive a control voltage on the basis of these different levels of the alternating pulses, the control voltage being used for corresponding correction of the phase of the local oscillator 2.

The above description of the invention deals with the derivation of a reference carrier wave with a fixed phase and a frequency equal to the frequency of the color carrier wave, on the basis of a shifted carrier wave, and it also specifies the derivation of another reference carrier wave with alternating phase, on the basis of a shifted carrier wave . There is also mention of a color synchronization system in which both of these reference carrier waves depend directly only on one of the two components of the color sync signal.

Claims (6)

1. Device for color synchronization of a color television receiver arranged for the reception of color television signals of the kind comprising a pair of color signals which are quadrature-balanced modulated on a color carrier wave. along respectively a first and a second modulation axis, which are mutually perpendicular, and of which the other axis is subject to a 180° phase shift for each successive horizontal line sweep, as in the known PAL color television system, while the televis ion signals further comprise a color sync signal with the same frequency as said color carrier wave and which makes it possible to identify said first and second modulation axis in the receiver, and the device comprises devices (1, 2) for producing a shifted carrier wave with a frequency equal to fsc + ^ fH, where fsc is the frequency of the color carrier wave, fH is the frequency of the line sweep and n is a positive integer , as well as means (3, 4, 9, 10, 6, 7, 8) for generating a reference carrier wave for use in demodulation along said first modulation axis, characterized in that said organs comprise shaping circuits (3, 4, 9) for deriving from said shifted carrier wave an auxiliary carrier wave with a frequency equal to twice the frequency of the color carrier wave, a dividing circuit (10) for frequency halving of said auxiliary carrier wave to thereby produce a carrier frequency equal to that of the color carrier wave frequency and with one or the other of two alternative polarities, as well as control circuits (6, 7, 8) for selecting any of the two polarities as suitable for said reference carrier wave. 2. Device as stated in claim 1, characterized by. that said shaping circuits (3, 4, 9) for deriving the auxiliary carrier wave with a frequency equal to twice the frequency of the color carrier wave comprises modulator circuits (3, 4) for phase modulation of the shifted carrier wave with a sawtooth wave whose frequency is equal to the line sweep frequency, as well as a multiplier circuit (9) for frequency doubling of the modulated, shifted carrier wave. 3. Device as stated in krtav 1, characterized in that said shaping circuits (3, 4, 9) for deriving the auxiliary carrier wave with a frequency equal to twice the frequency of the color carrier wave comprise devices (1, 14) for producing a further shifted carrier wave with a frequency equal to fsc'+ n fH, since the frequencies for the former and the further shifted carrier wave are equidistant from the frequency of the color carrier wave and on opposite sides of this, as well as a drift detector (15) for drift addition of the two shifted carrier waves.. 4. Device as stated in claim 1, characterized in that said control circuits (6, 7, 8) for selecting polarity are arranged for phase detection of the color sync signal and the shifted carrier wave for producing a pulse with a period equal to twice that of the line sweep period. 5. Device as stated in claim 4, characterized in that said control circuits (6, 7, 8) for selecting polarity comprise a gate circuit. (8) arranged to supply the shifted carrier wave on the input side, as well as equipment (7) for transmitting said pulse as a control pulse to the gate circuit (8). 6. Device as stated in claim 5, characterized in that said equipment (7) comprises a ringing oscillator (7) with an oscillation frequency equal to half the line frequency and synchronized with said pulse"