DE2329818B2 - CIRCUIT ARRANGEMENT FOR GENERATING A PAL COLOR CARRIER SIGNAL COUPLED WITH THE HORIZONTAL FREQUENCY OF A COLOR TELEVISION SIGNAL - Google Patents

Description

60

multiplied is coupled to an input of a mixer stage (81), which further r. it the second The oscillator (45) is coupled and its output via a frequency divider (83) to an input of the Phase detector (49) is coupled (F i g. 3.4).

The invention relates to a circuit arrangement for generating a with the horizontal frequency a color television signal coupled PAL reference color carrier signal having a first and a second Oscillator, a phase detector coupled to the oscillators, the signals with an opposite of the Frequency deviation significantly higher frequency are fed from which a control DC voltage output is coupled to a control signal input of one of the oscillators, the coupling of one of the Oscillators with the phase detector contains a digital mixer circuit, with the help of which a frequency deviation (Offset) corresponding to a small multiple of the frame rate is obtained from a simple ratio of the reference color subcarrier frequency to a quarter of the horizontal frequency.

From »News from Technology« June 15, 1971 No. 3, page 1 a circuit arrangement of the above type is known, wherein in a digital mixer circuit from Output signal of a first oscillator with the reference color carrier frequency subtracts the image frequency will. The output signal of this mixer circuit is divided in its frequency and a phase detector supplied, which is further supplied with an output signal of a second oscillator. The output signal of the Phase detector regulates the frequency of the second oscillator, specifically to maintain the desired Coupling between the oscillators.

It turns out that there is in the output signal of the phase detector with such a circuit arrangement there is a ripple voltage of the frame rate that is difficult to smooth

The invention now aims to avoid this disadvantage.

A circuit arrangement of the type mentioned at the outset therefore has the identifier according to the invention on that to suppress ripple voltages tier digital mixer a signal with a Frequency is supplied corresponding to a much higher multiple of the image frequency.

The inventor (s) has (have) found that said ripple voltage is the result of use a digital mixer in which the correction of the frequency deviation between the reference color subcarrier frequency and an odd multiple of a quarter of the horizontal frequency with the Frame rate is performed.

In the case of a digital mixer circuit, a number of pulses are suppressed at the rate of the frame rate or added.

This disturbance of the regularity in the signal remains even if the output signal is processed further the mixer stage available. The invention is based on the knowledge that the frequency of this Disturbance must be as high as possible in order to keep the hum frequency at the output of the phase detector as high as possible to make and thereby to simplify the smoothing of the output signal of the same. By increasing the Disturbance frequency is then at the same time the disturbance itself lower, so that this has a further favorable influence on the smoothing of the ripple voltage at the output of the phase detector.

Embodiments of the invention are shown in the drawings and are described below described in more detail. It shows

Fig. 1 is a simplified block diagram of a possible Embodiment of a circuit arrangement according to the invention,

2 shows a block diagram of the Principle on which the circuit arrangement narh F i -. I. founds,

Figure 3 is a simplified block diagram of another Possible implementation of a circuit arrangement according to the invention,

4 shows a simplified block diagram of a modification the implementation option according to FIG. 3.

Corresponding parts are indicated by the same reference symbols in the figures.

In Fig. 1, a first oscillator 1 has an output 3, which is connected to an input 5 of a synchronizing signal generator 7 and is connected to an input 9 of a frequency divider 11

The first oscillator 1 generates a signal with a _s $ frequency corresponding to 160 times the 1 horizontal frequency. The frequency divider 11 halves up to 80 times the horizontal frequency. If desired, the input signal of the synchronizing signal generator 7 could also be taken from an output of this frequency divider 11, so that a halver is saved therein.

An output 13 of the frequency divider is directly connected to an input 15 of a mixer circuit 17 and via a frequency divider 19, which divides by four, to an input 21 of the mixer circuit 17. The mixing circuit 17 is a subtracting circuit and in this way multiplies the output frequency of the frequency divider 11 by a factor of ³ A to da. 60 times the horizontal frequency. An output 22 of the mixer circuit 17 is connected to an input 23 of a digital mixer circuit 27, which thereby receives the signal at this input 23 with a frequency corresponding to 60 times the horizontal frequency. Another input 29 of the mixer circuit is connected to an output 31 of the synchronous signal generator 7, which supplies a signal corresponding to the multiple of the frame rate. The digital mixer circuit 27 supplies an output 33 with a series of pulses at a frequency of 60.0256 times the horizontal frequency. This frequency has arisen from the fact that in a pulse pattern with a frequency of 60 / «, ie 60 times the horizontal frequency fed to input 23, every 2 ms, i.e. with a frequency of 400 Hz = 16 h (corresponding to sixteen times the Frame rate) = 0.0256 / »a pulse is added. This creates an irregularity in the pulse pattern that is retained during further processing of the signal. The frequency with which this irregularity occurs is 400 H z.

The output 33 of the digital mixing circuit 27 is connected to an input 37 of a mixing circuit 39 via a frequency divider 35 which divides by sixteen. The input 33 is thus supplied with a signal with a frequency equal to 3.75! 6 / Ή, in which a disturbance occurs with a frequency of 400 Hz. Another input 41 of the mixer circuit 39 is connected to an output 43 of a second oscillator 45 which supplies a signal with a reference color carrier frequency / sub equal to 283.7516 fn , that is to say around the '·'; Frame rate (f _B = 0.00 \ hf _fl ) of 1135ma! deviates by a quarter of the horizontal frequency.

In the mixer circuit 39, a signal is formed with the difference frequency between the two input signals, which is 280 fn and which signal appears at an output 43. This signal is frequency divided by seven up to 40 / "via a frequency divider 45 and fed to an input 47 of a phase detector 49, which receives a signal imi with a frequency equal to 40 Λ / at an input 51 via a frequency divider 53 from the output 13 of the halver 11. The phase detector 49 emits a control DC voltage at an output 55, which contains a ripple voltage with the above-mentioned interference frequency of 400 Hz, which can be flattened much more easily than a ripple voltage with a frequency of 25 Hz, as in the previous The control voltage is fed via a smoothing circuit 56 to a control signal input 57 of the first oscillator 1, as a result of which this oscillator is doubled in frequency and phase with the second oscillator 45. The synchronizing signal generator 7 then emits synchronizing signals coupled to the reference color carrier signal.

The digital mixer circuit 27 is specified as an adder circuit in the example described above; if the use of a subtracting circuit is desired, it can be subtracted twice to obtain a sign inversion. In this case, for example, the frequency 16 / β can first be subtracted from 20 f _H , and the frequency obtained in this way (20 l'n- 16 // 3) can again be subtracted from 80 fn to (50 / «+ 16 / ß to get which frequency at the input of the divider 35 is desired.

In Fig.2, the principle of is in a calculation model Frequency division and the signal mixing, as this takes place in front of the input 47 of the phase detector 49, specified. For the sake of clarity, a number of assumptions that simplify the calculation have been assumed.

It is assumed that the first oscillator 1 outputs a signal with a frequency equal to 80 fn at its output 3. This frequency is a customary minimum frequency so that the standard signals can be contained in a color television signal with the aid of a division of pulse edges at time intervals that correspond to the period time of this frequency.

It is assumed that a frequency multiplier 59 with a multiplication factor ρ feeds a signal from the output 3 with a frequency of 80 pin to the input 23 of the digital mixer circuit 27. The input 29 of the digital mixer circuit 27 is supplied with a signal which is assumed to originate via a frequency multiplier 61 with a multiplication factor χ from a generator 63 which supplies a signal with the image frequency / β.

The digital mixing circuit now mixes a frequency ρ 80 fa with a frequency χ ■ fj to a frequency (p SOfH + xfe) which is brought by the frequency divider 35 to a frequency which, like the reference color carrier, has a favorably selected value around the image frequency deviates. A frequency division by χ must therefore take place in the divider 35. The frequency of the output signal of the Freq jenzteilers 35 is then

[ 80 / ,, + ■ / ".

The frequency of the reference color carrier is 280 / "/, + 3.75 fn + fn. It's cheap, well

to choose so that

- ■ = 3.75 / _Jf

3 64

Then it will be

for χ = 6 ρ -

χ = 8 p =

χ = 12 ρ =

x = 15 p =

x = 16 η =

3
"8th"

9
16

45
64

Depending on a desired multiple of the image frequency because of the desired reduction in ripple voltage amplitude, an associated easily realizable value of ρ can be selected.

It should be evident that - 80 to someone else too

Value can be made accordingly if it turns out that this value is more favorable because of the comparison in the phase detector, with ρ preferably not being allowed to assume a value that is too large.

If the mixer 39 is designed as a frequency adding stage, the digital mixer 27 can be used as a Frequency subtraction circuit can be switched, ^ 80

can then be chosen as 4.25, for example. Some favorable values for ρ are then exemplified

way:

Rir x = 10 P - 4.25 1/ X = 20 P - 8th 32 X = 40 P = 4.25 17th 4th 16 4.25
1 17th

= ^ = ¹ Wed

16 ·;

Tt To) '

The output frequency of the mixer 39 is then 288 / η, which is for example 16 // ybzw. 144 /// can be brought back by a subsequent division or multiplication and then with one of the output of the first oscillator ί by division by 10 or

Multiplication compared with r ^ obtained frequency

can be.

Another way of making a fix for the 160

160
5

160

709 379

fi,

80000

720000-10621

800 (X)

/ "

'.' · 159
XOOOO

), "

= 160

= 160

G-G-

19th
500

19th
500

559
800

159 + 400 \.
■ "■ ~ 8ÖÖ ) '"

The Member

160

19th
20th

25 "

(I.

¹⁵⁹
16Ö

is halved with the help of the divider 111, a divider 65, which divides by five, a divider 67 which divides by sixteen, the digital mixer circuit 27 which divides the difference between

160 /., And 160 · -, --- / "= / ,, = 625 f _a

forms, a divider 71. which divides by five, a mixing circuit 73 which the sum of

40

= 283.7516 / _H

1135.
4th

709 379
2500

625 " ^{/ h}

159 160 .

5- / 7 / ^and -j-.fη

forms, a divider 75 dividing by twenty, one Mixing circuit 77, which for a factor of 1? cares and

a frequency divider 79 that divides by twenty-five has been implemented.
It follows from equation (1)

5 ° 1 19

25 '20

/ 1 15 «
"\ 5 '1"

159
160

= 288 / -

Deviation (offset) by 25 Hz from the ratio ^l ~ ge

compared to the horizontal frequency is in the F i g. 3 and 4 indicated.

This manner is based on the following knowledge.

60

65 In a mixer 31, this signal formed by a frequency divider 83 is divided in frequency by 18, up to 16 / h. and compared in the phase detector 49 with a signal of 16 / Ή resulting from the divider 65.

The circuit arrangement according to FIG. 4 differs from that according to FIG. 3 only in a divider 83 located downstream of the mixer circuit 81, which halves by 144 f _H , and in a mixer circuit 85 located in front of the input 51 of the phase detector 49, which forms a frequency equal to 144 f _H from signals originating from the first oscillator.

The circuit arrangements according to FIG. 3 and 4 offer the advantage that no herrührendes from the synchronizing signal generator 7 signal needs to be vtrwendet This generator is usually from the remaining part of the

Circuit arrangement far away and is often designed as an independent unit.

With the circuit arrangements according to FIG. 3 and 4 , the offset is sensed at a frequency of 625 / β = / Ή , which leads to a very low ripple voltage at the output of the smoothing filter 56.

It should be evident that all mixer circuits used work digitally do not need filters, so that the circuit is almost completely integrated circuit technology can be.

For this purpose 3 sheets of drawings

Claims (3)

Patent claims: 1. Circuit arrangement for generating a PAL reference color carrier signal coupled to the horizontal frequency of a color television signal 5 with a first and a second oscillator, a phase detector coupled to the oscillators, to which signals with a frequency that is significantly higher than the frequency deviation are fed, from which a The DC control voltage output is coupled to a control signal input of one of the oscillators, the coupling of one of the oscillators to the phase detector containing a digital mixing circuit, with the aid of which a frequency deviation (offset) corresponding to a small multiple of the image frequency from a simple ratio of the reference color carrier frequency to a quarter of the horizon Frequency is obtained, characterized in that, in order to suppress ripple voltages, the digital mixer circuit (27) is supplied with a signal with a frequency corresponding to a significantly higher multiple of the image frequency. 2. Circuit arrangement according to claim 1, characterized in that the first oscillator (1) on the Hundred and sixty times the horizontal frequency and the second oscillator (45) on 283.75 times the horizontal frequency operates, while the digital mixer (27) signals accordingly sixty times the horizontal frequency and sixteen times the frame rate and wherein an output (33) of the digital mixer circuit (27) has one through sixteen dividing frequency divider circuit (35) is connected to a mixer circuit (39), which further with an output of the second oscillator (45) is connected, which latter mixer circuit (39) is coupled to the phase detector (49) via a frequency divider (45) dividing by seven, while the phase detector (49) continues via a frequency divider (11, 53) that divides by four with the first oscillator (1) is coupled (F i g. 1). 3. Circuit arrangement according to claim 1, characterized in that the first oscillator (1) on eggs One hundred and sixty times and the second (45) works at 283.7516 times the horizontal frequency, during the digital mixing circuit (27) signals corresponding to the horizontal frequency and the Hundreds of sixty times the horizontal frequency are fed while an output is the digital Mixing circuit (27) via a frequency divider (71) dividing by five with a mixing circuit (73) is connected, which further feeds a signal corresponding to eighty times the horizontal frequency an output of the latter mixer circuit (73) via a divider circuit (77, 79) that with a factor