NL8005457A - DEMODULATION CIRCUIT FOR OBTAINING A LINE SEQUENTIAL SIGNAL FROM A FREQUENCY MODULATED COLOR INFORMATION SIGNAL. - Google Patents

Description

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EHN 9856 1 N.V. Philips' Incandescent lamp factories in Eindhoven.

Demculation circuit for obtaining a line sequential signal from a frequency modulated color information signal.

The invention relates to a demodulation circuit for obtaining a line sequential signal from a frequency modulated color information signal of a Secam color television signal in which two color difference signals are modulated from line to line in frequency each on a carrier of a different frequency, which demodulation circuit single demodulator for demodulating the frequency modulated color information signal and a level correction circuit for decreasing a half line frequency component 10 caused by the different carrier frequencies in the output of the demodulation circuit.

German Auslegeschrift 2221888 discloses such a demodulation circuit which is used in a Secam-Pal transcoder. The semi-line frequency component is thereby reduced by line-to-line tuning of a circuit in the demodulator. In practice, the remaining half-line frequency component generally proves to be unacceptably large or to become so after some time due to changes in the thinning of the circuit.

The object of the invention is to eliminate this drawback.

According to the invention, a demodulation circuit of the type mentioned in the preamble, is therefore characterized in that the level correction circuit comprises two parallel signal paths coupled to an output of the demodulator, each with a clamping circuit and a half-line frequency switching network, which leads from line to line. one of the two clamp circuits is switched on.

The measure according to the invention practically completely suppresses the disturbing semi-line-regulating component. Any change in the tuning of a tuned circuit in the demodulator has no effect on the size of the staring half-line frequency component.

The invention will now be elucidated with reference to the drawing.

80 05 45 7 I - = «EHN 9856 2 __________ The drawing contains only one figure with a block diagram.

illustrates a possible embodiment of a demodulation circuit according to the invention.

In the figure, a Secam color information signal to be demodulated is applied to an input 1 of a frequency-5 demodulator 3, in which a first color difference signal in frequency qp is a carrier of a first frequency during a first line time and a second color difference signal in a second line time. frequency is modulated onto a carrier of a second frequency.

10 The carrier frequencies change from line to line as well as the color difference signals modulated thereon.

A demodulated signal is generated at an output 5 of the frequency demodulator 3, which alternately contains the first and the second color difference signal line-to-line and a half-line frequency component caused by the carrier frequencies which differ from line to line.

This signal at the output 5 of the frequency demodulator 3 is applied via a level correction circuit 7 to an output 9 of the demodulation circuit, which is also the output of the level correction circuit 7.

The output 5 of the frequency demodulator 3 is connected to an input 11 of a change-over switch 13, an output 15 of which can be connected alternately via an half-line frequency switch 17 to an input 19 of a first signal path and an input 21 of a second signal path. An output 23 of the first signal path and an output 25 of the second signal path form the inputs of an adder circuit 27 whose output is at the output 9 of the demodulation circuit. The first and second signal paths are called parallel signal paths. The switch 13 is usually in the drawn position. Its function will be discussed later.

. In the first and second signal path, respectively, the output 19 and 21 of the cm switch 17 are respectively connected to an input 29 and 31 respectively of an amplifier 33 and 35, of which an output 37 and 39 respectively is connected to the input 23 and the adder circuit 27, respectively. The output 37 and 39 respectively of the amplifier 33 /. 3b furthermore lies via a switch 41 and 43 respectively on a capacitor 45 and 47 and on a further input 49 and 51 respectively of the amplifier 33 and 80 05 45 7 ► t - S ~ ... * HIN 9856 3 .33 __________ 35. The vector and 35 respectively form a clamping circuit with the switches 41 and 43, respectively, and the capacitor 45 and 47 respectively.

Switch 41 and 43, respectively, are actuated by a signal applied to an input 55 and 57, respectively, which comes from an output 59 and 61, respectively, from a change-over switch 63, an input 65 of which, via a waveform correction circuit 67, is connected to an input 69 of the circuit. A pulse signal of the line frequency is applied to this input 69.

The switch 41 and 43, respectively, are closed by the signal at the input 55 and 57 thereof when the change-over switch 17 is in the position shown and not shown, respectively, and when a reference signal is present at the input 19 and 21 of the first and second signal path, respectively. are created by the demodulation of a signal of the first and second carrier frequency, respectively. As a result, in one line time the reference level of the first color difference signal at the output 23 of the first signal path and in the other line time the reference level of the second color difference signal at the output 25 of the second signal path cp are clamped a certain value which is signal paths are selected immediately. Furthermore, in the drawn position of the change-over switch 17, the output 25 of the second signal path assumes a certain level which is equal to the level which occurs in the unsigned position of the change-over switch 17 at the output 23 of the first signal path. If a semi-line frequency signal component now occurs because the level at the output of the first and second signal paths is different in the drawn position of the switch 17 than in the not shown, these components are in opposite phases in the two signal paths and cancel each other out. pptel circuit 30 27 qp. In the above it was assumed that the change-over switch 13 is constantly in the drawn position.

In order to be able to compensate the half-line frequency components in the two signal paths in the Secam signal in the line flyback times, a half-line frequency reference voltage is applied to a further input 73 of the switcher 13 via a change-over switch 71. This arises from one line time a DC voltage from a source 75 and the other line time from another DC voltage from a source.

80 0545 7 EHN 9856 4 _________77 at that entrance 73. With this reference voltage, a reference level is filled in in the two color difference signals at the output 15 of the switch 13, each of the influence of a signal of the line frequency originating from the waveform supplied via a switch 78 closed in this case to the switch 13. correction circuit 67 so that the clamping circuits can then color that reference signal.

The half-line frequency switches 17, 71 and 63 were operated by a half-line frequency switching signal from an output 79 of a bistable multivibrator 81 which is controlled by the pulse signal of the line frequency at input 69 and by a signal at an input 83 in the correct switching state. is being held. This signal at the input 83 of the multivibrator 81 comes from an identification circuit 85 which processes an identification signal at the output 5 of the demodulator that occurs as a result of certain auxiliary signals present in a second signal.

It is also possible to connect the inputs 19 and 31 of the two signal carriages to each other and, instead of adding the addition circuit 27, to install the change-over switch 17 which alternately connects the 20 outputs 23 and 25 of the two signal paths with the output 9 of the circuit connects.

In this case, control circuits are used as clamping circuits, so that no capacitors have to be used to suppress a DC component. If desired, however, other clamping circuits, such as, for example, a capacitor followed by a short-circuit switch, can also be used.

The switches 13 and 76 and the switch 78 can be omitted if desired if the demodulation circuit need only be suitable for second signals in which a reference signal occurs in the line retrace times.

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Claims (1)

Demodulation circuit according to claim 1, characterized in that the inputs of the parallel signal paths are coupled to the output of the demodulator via a semi-line frequency switch and the outputs to the output of the demodulation circuit via an adder. 25 30 80 05 45 7 35