FR2649849A1 - Device for regulating the amplitude of the chrominance signal corresponding to a colour television signal - Google Patents

Abstract

The invention relates to a device for regulating the amplitude of the chrominance signal corresponding to a colour television signal, comprising: means for extracting a value of the amplitude of the chrominance signal; means for comparing this value with a reference value and for producing a control signal; and means for modifying the amplitude of the chrominance signal which comprise a resonant circuit L1, C1 mounted in series between an input and an output of the said device and a variable resistor cooperating with the said resonant circuit in order to modify a transfer function of the latter as a function of the said control signal. According to the invention, the said variable resistor R3 and a band-pass filter L2, C2 centred on the frequency of the chrominance signal are mounted in parallel in the device. Application to semi-still and moving video transmissions.

Description

 The invention relates to a device for regulating the amplitude of the chrominance signal relating to a color television signal, comprising: sampling means for taking a value from the amplitude of the chrominance signal; comparison means for comparing this value with a reference value and producing a corresponding control signal; and means for modifying the amplitude of the chrominance signal which comprise a resonant circuit connected in series between an input and an output of said device and a variable resistor cooperating with said resonant circuit to modify a transfer function thereof as a function of said control signal.

 A device of this kind is known from patent FR 2 170 950. In this device, the variable resistor is connected in series so that the variation thereof affects the television signal as a whole, namely not only the signal of chrominance but also the luminance signal, especially since the resistance variation which must be produced in this case is particularly large.

 In practice, such a device does not appear to be able to give any satisfaction, since the luminance signal would be too disturbed. Furthermore, the variable resistor is controlled by a voltage signal, which does not provide very satisfactory stability.

 The object of the invention is to propose a device of the kind mentioned at the beginning of the presentation, in which the transfer function of the resonant circuit can be modified without appreciably disturbing the luminance signal.

 To this end, said variable resistor and a bandpass filter centered on the frequency of the chrominance signal are mounted in parallel in the device.

 Another object of the invention is to be able to easily set the minimum and maximum values of the overvoltage factor of the -resonant circuit. For this purpose, two resistors - preferably potentiometers - are mounted respectively on the resonant circuit and on the bandpass filter.

 Another object of the invention is to vary the overvoltage coefficient of the resonant circuit only in the vicinity of the frequency of the chrominance signal, in order to disturb even less the luminance signal, the spectrum of which is essentially offset from this frequency. To this end, the variable resistor is arranged so as to vary essentially only beyond a certain frequency, close to that of the chrominance signal.

 Another object of the invention is to control the variable resistance stably. For this purpose, the variable resistor is arranged to be controlled by a current signal.

Other details and advantages of the invention will appear during the following description of a preferred but non-limiting embodiment with reference to the appended drawings, in which
Figure 1 is a block diagram of the chrominance regulator as a whole
Figure 2 is an electrical diagram of the control block of Figure 1;
Figure 3 is an electrical diagram of a preferred embodiment of the control block of Figure 2; and
FIG. 4 represents curves defining the variation of certain parameters as a function of the frequency.

 The chrominance regulator shown in FIG. 1 has an input 1 receiving the color television signal, including the video signal and the synchronization signal, and an output 2 delivering the regulated video signal.

 At the input is provided an extraction device 3 known in itself and arranged to extract the synchronization signal, followed by a regulation block 4 which is very particularly the subject of the present invention, and a amplifier 5 whose output corresponds to output 2 of the chrominance regulator. The eXtraction device 3 has a very low output impedance.

 A feedback loop 6 comprises, in series from the output 2, a filter 7, a diode 8, a sample-and-hold circuit 9, and a comparator 10 from which an output drives a control input of this regulation block 4.

 Filter 7 is a bandpass filter centered on the frequency of the chrominance subcarriers, that is to say on a frequency band between 4.2 and 4.43 MHz. The sampler-blocker 9 is arranged to take the instantaneous value of the amplitude of the chrominance signal.

 As regards the comparator 10, it receives on a first input said instantaneous value of the amplitude of the chrominance signal, and on a second input a predetermined reference value which can be chosen, by means of an electrical switch 11, between - a first fixed reference value for the case where the television signal is coded according to the PAL system; - another fixed reference value for the case where the television signal is coded according to the SECAM system; and - a manually adjustable reference value for the case where the user wishes to impose this value himself.

 Depending on the result of the comparison, the comparator 10 sends to the regulation block 4 a control signal with a view to decreasing or increasing the amplitude of the chrominance signal.

 According to the invention, the regulation block (FIG. 2) comprises a series resonant filter or circuit constituted by an inductor of adjustable value L1 connected in series between the input 21 and the output 22 of the regulation block and a capacitor C1 mounted. in parallel between output 22 and earth. A potentiometer R1 is mounted in parallel with the capacitor Cl.

 Furthermore, between output 22 and earth is still mounted a variable resistor R3, controlled by the control signal from comparator 10, in series with a filter or plug circuit. This plug circuit includes a choke L2, a capacitor C2 and a potentiometer R2 connected in parallel.

Preferably, the variable resistance R3 is such that it can vary from 100 μl to 10 KΩ. I1 is a microwave component consisting in particular of a diode
PIN, a field effect transistor or a VCR (Variable Controler Resistor) resistor.

 The filter L2, C2 is a bandpass filter centered on the same frequency band as the filter 7, namely on a band between 4.25 and 4.43 MHZ.

In operation, the transfer function of the filter L1, C1 is modified only by the variation of the variable resistance R3. Furthermore, only the chrominance signal actually crosses the variable resistance
R3 due to the presence of the plug circuit L2, C2.

 Advantageously, the minimum and maximum values of the overvoltage factor of the resonant circuit L1, C1 are respectively adjusted to the average of the two potentiometers R2 and R1; moreover, these values are independent of variations in the variable resistance R3.

 Thus, mounting the variable resistor R3 egt parallel rather than in series with the choke L1 has in particular the following two-advantages: on the one hand the luminance signal, which does not pass through the variable resistor R3, is not not disturbed during variations thereof; on the other hand, the range of variation of the variable resistance R3 is more reduced.

According to a preferred embodiment (Figure 3), the variable resistor R3 is constituted by a diode
PIN 30 whose resistance is a function of the current flowing through it. Also, a current source is connected in series with the PIN diode 30 and the plug circuit L2, C2, R2, which is formed by an NPN transistor 31. The collector of transistor 31 is connected to the plug circuit L2, C2, R2 while that its transmitter is connected, via a Zener diode 32 and a resistor R4 connected in series, to a negative voltage source. Furthermore, the control signal from the comparator 10 is applied to the base of the transistor 31. Finally, a capacitor C3 is mounted between the collector of the transistor 31 and the ground.

In Figure 4 is shown a curve I defining the variations of the equivalent resistance
Re, resulting from the association of PIN 30 and potentiometer R2, as a function of frequency. Note that the equivalent resistance Re is substantially constant from frequency zero to a frequency close to the frequency fO of the chrominance subcarriers. In the vicinity of the frequency fO, the equivalent resistance Re can either increase according to a curve 1a 'or decrease according to a curve Ib. This shape results from the fact that the resistance of the PIN diode is variable only beyond a certain frequency, close to fO.

At low frequency, the PIN 30 diode behaves like an ordinary diode: once the capacitor
C3 has been charged, the diode is blocked.

 Because the equivalent resistance Re, and therefore the overvoltage coefficient of the filter L1, C1 which is proportional to it, are substantially constant over a wide band between the frequencies zero and fO, the luminance signal - whose spectrum corresponds to the essential to this band - is not disturbed.

 Thanks to this device, the amplitude of the chrominance signal can be reduced by a value up to 10 dB, or increased by a value up to 20 dB.

Curve II (FIG. 4) corresponds to the less advantageous case where the variable resistance R3 is constituted by a component whose resistance is substantially constant whatever the frequency, for example a transistor.
The hatched area III shows the difference in selectivity between curves I and II.

Claims (9)

 1.- Device for regulating the amplitude of the chrominance signal relating to a color television signal, comprising  - sampling means (7, 8, 9) for sampling a value of the amplitude of the chrominance signal;  - comparison means (10, 11) for comparing this value with a reference value and producing a corresponding control signal;  means for modifying the amplitude of the chrominance signal which include a resonant circuit (L1, C1) connected in series between an input (1) and an output (2) of said device and a variable resistor cooperating with said resonant circuit to modify a transfer function thereof as a function of said control signal, characterized in that said variable resistance (R3) and a bandpass filter (L2, C2) centered on the frequency of the chrominance signal are connected in parallel in the device.  2.- Device according to claim 1, wherein said bandpass filter is a plug circuit comprising a choke (L2) and a capacitor (C2).  3.- Device according to claim 2, wherein the plug circuit (L2, C2) is mounted in series with said variable resistor (R3).  4.- Device according to any one of the preceding claims, which comprises two resistors (R1, R2) mounted respectively on said resonant circuit (L1, Cl) and on said bandpass filter (L2, C2).  5.- Device according to any one of the preceding claims, wherein the variable resistor is arranged to vary essentially only beyond a certain frequency, close to that of the chrominance signal.  6.- Device according to any one of the preceding claims, wherein the variable resistor is arranged to be controlled by a current signal.  7.- Device according to claim 5 or claim 6, wherein the variable resistor comprises a PIN diode (30) connected in series with a current source (31).  8.- Device according to claim 7, wherein said current source is a transistor (31).  9.- Device according to any one of the preceding claims, in which said sampling means comprise a bandpass filter (7) centered on the frequency of the chrominance signal, associated in series with a diode (8) and with a sampler. - blocker (9)