NL8005532A - TRANSCODE SWITCH. - Google Patents

Description

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Jr 'ί SPHN 9854 1 N.V. Philips' Light bulb factories in Eindhoven.

Transcode switching.

The invention relates to a transcode circuit for converting a SECM color information signal in which another color difference signal is alternately modulated in frequency on a carrier wave of a different frequency from a line to line in a signal combination demodulated by a demodulation circuit for quadrature demodulation. is which transcoder circuit contains a modulator for modulating a demodulated SECAM clay information signal qp a carrier signal derived from an oscillator signal to be supplied to an oscillator signal input and a system switch which can be operated by a system switch signal for switching the processing from a frequency demodulated to a quadrature-modulated color information signal.

Such a transcode circuit is known from European patent application 0003169. The carrier wave signal has the same frequency as the oscillator signal.

The object of the invention is to make such a transcode circuit suitable for using an oscillator signal having the double frequency of the carrier signal.

A transcode circuit of the type 20 mentioned in the preamble according to the invention is characterized in that the oscillator signal input is coupled to the modulator via a divider circuit, the divider circuit having a stop signal input which is coupled to an output of a differential determining circuit in the collector circuit. of two transistors, the bases of which are supplied with a voltage determined by a system switching signal and the emitters of which are each connected to a different phase control signal terminal of the transcode circuit, while at the output for a first quadrature component of a constant phase no color synchronizing signal is generated and a color synchronization signal of a phase corresponding to that second quadrature component is generated at an output for a second quadrature constant having a line-to-line alternating phase only for the other line retrace time.

The invention will now be elucidated on the basis of the drawing, which contains only 8005532 PHN 9854 2 I * r * _____________ one figure. ____________

The figure illustrates with a simplified block diagram a transcode circuit according to the invention in cooperation with a known demodulation circuit.

For the sake of clarity, details have been omitted from the figure which are not important for the understanding of the invention.

A color information signal may be applied to an input 1 of a transcode circuit 3, which may be of the SECM type, in which one of two color difference signals 10 is alternately frequency-modulated on a carrier of one of two frequencies from line to line, or of the PAL type in which a color difference signal has been modulated on each of two quadrature components of a carrier wave and anchors the phase of one of the two quadrature components from line to line.

This color information signal is applied on the one hand to an input 5 of a frequency demodulator 7 and to an input 9 of a system switch 11.

Connected to an output 13 of the frequency demodulator 7 is an input 15 of a system identification circuit 17 which supplies to an output 19 a system switching signal which in this case has a low value for 20 PAL and a high value for SECAM and which is, for example, known in a known manner. generated with the aid of certain characteristics of the output signal of the frequency demodulator 7.

The system switch signal is applied to a system 25 cm switch signal input 21 of the system switch 11. This is in the drawn position when processing an SBCAM color information signal and in the position not shown when processing a PAL color information signal.

The signal at the output 13 of the frequency demodulator 7 30 is further applied to an input 21 of a modulator 23 and to an input 25 of an identification circuit 27. From an output 29 of the identification circuit 27, in the case of a SECAM signal, processing obtained an identification signal which is applied to an input 31 of a bistable multivibrator 33 in order to connect the phase of a half-line 35 frequency signal to an output 35 thereof to that of a switch in a color television transmitter which determines the order in which the color differences signal on the carrier are modulated.

The position of the multivibrator 33 is changed from line to line 8005532 PHN 9854 3 *, 4 # t ---- by a pulse signal of the line frequency which is applied to an input 37 thereof and which comes from an input 39 of the transcode circuit 3.

The modulator 23 receives at its input 41 a carrier wave signal from an output 43 of a half line frequency arrt switch 45 which is operated by a half line frequency signal applied to an input 47 thereof and from the output 35 of the multivibrator 33.

Under the influence of the signal at the input 47 of the inverter 45, its output 43 is alternately connected to an output 49 and 51 of a divider circuit 53, which is supplied with an oscillator signal from an input 55 of an input 57 of the transcode circuit 3. The oscillator signal has the double frequency of the carrier wave which is applied to the input 41 of the modulator 23 and the divider circuit 53 divides the frequency by two and gives a signal at its output 49 with a phase of 0 ° and at its output 51 a signal with a phase of 90 ° when the divider circuit 53 is in the correct partial state.

In order to obtain this correct partial state, a stop signal input 57 thereof is supplied, in the case of an incorrect dividing state, a stop signal from an output 59 of a difference-determining circuit 61 which is included in the collector circuit of two transistors 63, 65 whose bases are connected. the output 19 of the system identification circuit 17 by which the transistors are blocked during the processing of a PAL signal and conduct during the processing of a SEC&M signal.

The emitters of transistors 63, 65 are connected to terminals 67 and 69, respectively, for a phase control signal. This phase control signal is produced at a terminal 71 and 73 of a demo circuit 75, to which the terminals 67 and 69 of the transcode circuit 3 are connected, respectively, and which are grounded via a capacitor 75 and 77, respectively.

In case a SECAM signal is processed, the emitters of both transistors apply the same voltage due to the system switching signal at their bases. The streets through these transistors are then determined by the currents through the terminals 71, 73 of the danodulation circuit 75. This will be reflected later on.

...... In case of PAL reception, transistors 63 and 65 are blocked and 8005532 PHN 9854 4 s f * I * __ do not affect the voltage at terminals 71 and 73 of demodulation circuit 75.

In the demodulation circuit 75, the terminal 71 and 73, respectively, are connected to a phase control signal output 79 and 81, respectively, of a phase detector 83 and to a phase control signal input 85, and 87, respectively, of an oscillator 89. An output 91 of the oscillator 89 is connected to an output 93 of the demodulation circuit 75, which output 93 is connected to the oscillator signal input 57 of the transcode circuit 3, and to an input 97 of a divider circuit 99. The output 93 of the demodulation circuit 75 is connected via a crystal 101 to an input 103 thereof which in turn is connected to an input 105 of the oscillator 89.

The oscillator 89 operates on the double carrier frequency of the PAL color information signal and a signal of the carrier frequency and with a phase of 0 °, -90 ° and 0 and -90 °, respectively, is produced at an output 107 and 109 and 111 of the divider circuit 99, respectively. + 90 °.

The 0 ° signal at the output 107 of the divider circuit 99 is applied to a reference signal input 113 of a synchronous demodulator 115, an input 117 of which is connected to an input 119 of the demodulation circuit 75 which in turn is connected to an output 121 of the transcoding circuit 20. 3 is bandaging.

In a synchronized state of the circuit, the input 119 is supplied with a carrier of 0 ° modulated blue color difference (BY) modulated by the demodulator 115 and processed to a SECAM as well as a PAL color information signal. output 123 issued for further processing. .

The signal at the input 119 of the demodulation circuit 75 does show for both systems a difference in a color synchronization signal transmitted in the line flyback times. A color synchronization signal with a phase of 180 ° qp is applied to this input 30 119 when processing a PAL signal and no color synchronizing signal is processed when processing a SECftM signal.

At the input 127 of the demodulation circuit 73 connected to an output 125 of the transcode circuit 3, in the synchronized state of the circuit, an information signal is generated in the synchronized state of the circuit both when processing a SECAM and a PAL-1 door. -90 ° and + 90 ° modulated red color difference signal + _ (RY) which becomes at an input 129 of a synchronous demodulator 131 8005532. * PHN 9854 5 which is demodulated under the influence of a reference signal applied to an input 133 thereof alternately from -90 ° and + 90 ° and output it to an output 135 thereof for further processing.

The signal at the input 127 of the demodulation circuit 57 has, in the case of the processing of a PAL signal in the line flyback times, a color synchronization signal having a phase of -90 ° and + 90 ° alternately. In the case of processing a SECAM signal, this color synchronization signal is present only every other line and then has a phase of + 90 °.

The reference signal at the input 133 of the demodulator 131 is obtained via a half-line frequency switch 137 from the outputs 109 and 111 of the divider circuit 99. The half-line frequency switch 137 is operated by a half-line frequency switching signal applied to an input 139 thereof, which comes from a output 141 of a bistable multivibrator 143.

This multivibrator 143 changes position from line to line under the influence of the line frequency pulse signal applied to an input 145 thereof which is obtained from an input 147 of the demodulation circuit 75.

The multivibrator 143 has a further input 149 to which a half-line frequency identification signal is supplied which comes from an output 151 of the phase detector 83. To this end, an input 153 of the phase detector 83 is connected via a switch 155, which is fed by the line frequency pulse signal to the input. 147 of the demodulation circuit 75 is operated, and an adder circuit 155, the inputs of which are connected to the inputs 119 and 127 of the demodulation circuit 75, supplies a color synchronizing signal which alternates a phase of -135 when processing a PAL signal ° and + 135 ° and when processing a SECAM signal in the synchronized state of 30, the circuit is alternately zero and has a phase of + 90 °. In the unsynchronized state, the color synchronization signal remains constant zero. Under the influence of a reference signal of + 90 ° which is applied to a further input 159 of the phase detector 83, it gives a SECAM signal at its output 151 both when processing a PAL signal and when processing a PAL signal. half-line frequency signal which keeps the multivibrator 143 in the correct switching state and which can also be used for a color deaf circuit and color signal amplitude control circuit not shown 8005532 * PEN 9854 6 * ________ When processing a PAL signal, the DC signal supplies the outputs 79 and 81 of the phase detector 83 show the phase control of the oscillator 89 in a known manner. When a SECM signal is processed, outputs 79 and 81 in the synchronized. In the case of the circuit, a similar power component which, as a result of the transistor then acting as an emitter follower, cannot generate a DC voltage and thus does not cause a phase control of the oscillator 89.

An unsynchronized state occurs in the processing of a PAL signal only if the switching state of the multivibrator 143 is incorrect. It is then corrected by the identification signal at its input 149.

When processing a SECAM signal, an unsynchronized state may arise from a difference in switching state of the multivibrator 143 in the demodulation circuit 75 from that of the multivibrator 33 in the transcode circuit 3 or due to an incorrect divider state of the divider circuit 53 in the transcode circuit 3.

In order to be able to understand the consequences of the incorrect switching state of the multivibrator 143 or of the incorrect dividing state of the divider circuit 53, the operation of the transcode circuit will now be further investigated.

When a PAL signal is processed, the system switch 11 of the transcode circuit is in the position not shown. The color information signal at the input 1 is then fed via the input 9 of the system switch 11 to an output 161 thereof which is connected to an input 163 of a delay line 165 which has a delay of substantially one line time.

An output 167 of the delay line 165 is connected to an input 169 of a balancing circuit 171, a 0 ° output 173 of which is connected to an input 175 of the system switch 11 which is then connected to the output 121 of the transcode circuit 3. A 180 ° output 179 of the balancing circuit is connected to an input 179 of the system switch 11, which is then connected to the output 125 of the transducer circuit 3. A resistor 181 is provided between the outputs 173 and 177 of the balancing circuit 171, a center tap of which is connected to an output of the system switch 11 is located which is then connected to an input 185 thereof which is connected to the input 163 of the delay line 8005532

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PHN 9854 7 ________165. __________

In a known manner the quadrature components (BY) and + (RY) are now separated from each other by means of the delay line 165 / the balancing circuit 171 and the resistor 181 and are applied to the output 121 and 125 of the transcode circuit and to a known manner by the derivation circuit 75.

In the case of processing a SECAM signal, the system switch 11 is in the designated position. From an output 187 of a carrier 10 modulated signal applied to the input> input 41 thereof is obtained which modulates line to line alternately with another of the two quadrature components of a PAL signal apart from the sign change in a of these quadrature components.

This signal is applied to an input 193 of the system switch 11 via a line frequency changeover 189 / which is in the line 15 stroke times under the influence of an operating signal at an input 191 connected to the input 39 of the transcode circuit 3, in the drawn position. and then through its output 161 to input 163 of delay line 163.

20 m the line flyback times, the switch 189 provides a color synchronization signal from an output 195 of the switch 45 to the input 193 of the system switch 11. This color synchronization signal originates from the output 51 of the divider circuit 45 and, due to the switch 45, is only present every other line retrace time. It has a phase of + 90 ° in the correct divider state of divider circuit 53 and a phase of -90 ° in the incorrect divider state.

The output 121 of the transcode circuit is now connected via the system switch 11 to an input 197 thereof which, via a half-line 30 frequent switch 199, of which an operating signal input 201 is at the output 35 of the multivibrator 33, alternately connects this output 121 to the input 163 and the output 167 of the delay line. As a result of the operation of the changeover switch 45, the changeover switch 189 does not output a color synchronization signal when the changeover switch 199 is in the drawn position and thus no color synchronization signal is produced at the output 121 of the transcode circuit. In the position of the changeover switch 199 not shown, the delayed signal also combs ..... none. color synchronization signal included at output 121.

8 0 0 5 5 3 2 PHN 9854 8 * V-

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The output 125 of the transcode circuit 3 is connected via an input 203 of the system switch 11, a switch 205 and the switch 199 during alternating line times to the 180 ° output 177 of the balancing circuit 171 and to the input 163 of the delay line 165 so that output 125 alternately produces a red color difference signal modulated on a -90 ° or + 90 ° carrier.

The switch 205 is actuated by a signal supplied to an input 207 thereof from an EN port 209. Of the AND gate 209, an input is connected to the output 35 of the multivibrator 33 and an input to the input 39 for the line frequency pulse signal of the transcode circuit 3. Under the influence of this operating signal, the switch 205 blocks during line retrace times that the switch 199 is turned on. the position not shown represents the color sync signal and allows it to pass through the line flyback times that the switch 199 is in the position shown.

At the output 125 of the transcode circuit 3, the other line fly-back time now produces a color synchronizing signal which has a phase of 20 + 90 ° in the correct divider state of the divider circuit 53 and a phase of -90 ° in the incorrect divider state.

As explained above, no color synchronizing signal occurs at the output 121 of the transcode circuit 3.

In the incorrect divider state of the divider circuit 53 of the transcode circuit 3, the phase detector 83 will therefore receive at its input 159 a reference signal of 90 ° and at its input 153 a color synchronizing signal that the other line fly-back time is present and that a phase of -90 °. At the outputs 79 and 81 thereof and at the inputs 67, 69 of the transcode circuit 3, a direct current is then generated which, through the transistors 63 and 65, via the difference-determining circuit 61 and the stop signal input 57 of the divider circuit 53, steps the divider circuit 53 so that it no longer gives an output signal and the color synchronization signal is lost and thus the output signal of the phase detector 83, so that the divider circuit 53 starts operating again. This process continues until the color synchronization signal occurring at the other line flyback time at the input 153 of the phase detector 83 has the correct phase of 90 °.

The divider circuit 53 of the transcode circuit 3 is then synchronized with the divider circuit 99 of the demodulation circuit 8005532

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EHN 9854 9 __________75 after which the multivibrator 143 of the demodulation circuit 75 synchronizes with the multivibrator 33 of the transcode circuit 3 due to the signal, at the output 151 of the phase detector 83.

The transistors 63 and 65 can of course be replaced by transistor combinations with the same properties as for example a Darlington pair. These are therefore deemed to fall under the scope of protection of the application.

The bases of the transistors 63, 65 are operated directly by the system circuit signal in the exemplary embodiment. It will be clear that this may also be the case via some transfer circuit. In the case of manual operation of the system switch 11, the voltage at the bases of the transistors must of course also be influenced appropriately by this manual operation.

It will furthermore be clear that the color synchronization-15 signal which is output via the amps switches 45, 189 and 199 during a SECAM signal processing at the output 125 of the transcode circuit ing 3 every other line retrace time may, if desired, also be the -90 ° phase. if the phase detector 83 or the synchronization of the multivibrator 143 are adapted thereto.

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Claims (1)

V ^ C. PHN 9854 10 Transcode circuit for converting a SECftM color information signal in which, alternating line to line, another color difference signal in frequency is modulated on a carrier of a different frequency in a signal combination generated by a demodulation circuit it is demodulable for quadrature demodulation which transcode circuit comprises a modulator for modulating a demodulated SECM color information signal on a carrier signal derived from an oscillator signal to be supplied to an oscillator signal input and a system switch 10 operable by a system switching signal. processing a frequency demodulated to a quadrature modulated color information Ignal, characterized in that the oscillator signal input (57) is coupled via a divider circuit (53) to the modulator (23), which divider circuit (53) has a stop signal input (57) is with an output (59) of one difference-determining circuit (61) in the collector circuit of two transistors (63, 65) whose base is supplied with a voltage determined by a system switching signal (from output 19) and whose emitters are each connected to a different phase control signal terminal ( 67, 69) of the transcode circuit, while no color synchronization signal is generated at an output (121) for a first quadrature component of a constant phase and at an output (125) for a second quadrature component with a phase-to-line alternating phase only At the other line fly-back time, a color synchronization signal is generated from a phase corresponding to that second quadrature signal. 25 30 35 800 5532