DE2130310C3 - Control circuit for the color lock of a color television receiver - Google Patents

Description

It is synchronized with the reference signal. _{through (las s} , _{CIR; rHl} g | _Ut | (TusteucTic

! ^oi fuz Sr setting Phi.se of llrmchalisig See """" * _{color blocking} c that uireh ti "· control signal." as wm - ■ · _The p _ar b _a ij _SC | _ia | tung is therefore by diis ^"cthey , "<_; Anally controlled, that also the identification ^gl f .imSaltung in the splitter in dip correct Pha ^Φ ΐ1 bring'Sim PAL and SKCAM syitem thereby the color display in case of incorrect identification

15th

25th

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rw- Aulsaoe ucr invention is to provide • 1 control circuit forth, the control of color killer and TIEE adjustment of the phase position of the Umschaltsif reason, only a single control signal durchn permitted in schaltungsmößig particular ^el 'and thereby is very safe in operation. in that the three signal _{destinations of the} '": Bna | ₅ can be differentiated safely and without problems and the mentioned controls m ⁴ IL reduce the risk of undesired influences.

B ^{| e} ! 5This task is made possible by the characteristics of the An

* ^P 7war isfais ^St of DT PS 10 39 570 a circuit with each, transistors of opposite conduction type be-ίηηΐ whose emitters and their bases are connected to each other and between their collectors a cnnnSauclle is connected. while the emitter £ Lastarfein potential between the two Endpo the voltage source entialen Led, .st Depending on the interconnected bases zugefuhr- Z input signal passes one or the other transformants "or" nd of the load current flowing through accordingly has the one or the other Direction. Γ η, so with the help of the control signal sending to the bases of the transistors in its direction reversed

"In the circuit according to the invention, the transistor combination is also controlled via its base electrodes in such a way that either one or the other transistor conducts, but here no use is made of a reversal, but different fan-out signals are derived from the two collectors, in this way that with two of the three finite signal states, namely, bc * .first and with the third signal state, one of the two tranches delivers the same output signal, while with other of the three signal states, namely the third and third signal state, the other delivers the same output signal both times In this way, the extremely simple and absolutely safe control of the barrier lock is possible at the same time as the control of the phase position of the TaSeber for the PAL switch (or the corresponding parts in the SECAM system) er χ where ffr two of the three The states of the control are the same in each case for one of the two transistors

Invention are in the sub

^ ÄrwiSiAusierungsbe-sp ^ e of the invention referring to the drawing closer he

^ Äckscha..bi.d one, part of a color fern «• hmnnfän«! «Ecmess of the invention and,.

"Tig ^r 2" is a circuit diagram of a preferred embodiment of a part of the Y ι g. 1

The Icil of a PAL color television receiver shown in FIG becomes at a. · Clamps · J a color television signal supplied, which by mchtdargesiell te I ilier ·. Delay and amplitude screen formwork divided into three parts. The first part will be one

PAL Vcr / ogciungsleitiings-Signalvfrarbeilungsein · device 2 supplied, in which the color information is separated in a known manner into amounts BY- 'and Ii-Y signals: ηιΓ lines 1 or 4 for phase demodulation in demodula'orschaliungen 5 or f> . The demodulated signals are fed to a consumer 7 which, for. Ii. may contain a matrix sound system and a picture tube. The demodulators 5 and 6 are also supplied with a reference frame oscillation from the output of a local color reference carrier croscillaior 8. The reference carrier oscillation for the demodulator 6 is switched in phase by 180 ° after each line by a PAL switch 9 in practically all PAL receivers, especially those that work with a delay line. Another option, but less common, is to put the PAL switch 9 on the line

4 to be switched on.

There is no problem, the switch 9 as required fii toggle at half the Zei'enfrequenz 0.5 and synchronize the oscillator 8 ^p arbträgerfrequenz by the received signal with the. In addition, however, the switch 9 must be switched over with the correct of the two possible phases, which is effected in a known manner as follows:

The second part of the input signal is fed to a separation circuit 10 which supplies a color synchronization signal (burst) between the image lines. which comes from the transmitted signal and serves to synchronize the reference carrier oscillator 8 with the correct color carrier frequency by means of a phase and frequency control circuit 11, which forms part of a phase locked loop 12. The color-slow 40-frequency color synchronization signal from the separating circuit 10 also contains half-line frequency phase information, since the phase of the successive color synchronization signals changes by ± 45 ", which, however, does not cause the phase of the oscillator 8 to be switched because the quality of the oscillator is too high for this The phase of the output signal of the reference carrier oscillator 8 is therefore constant. The half-line frequency information can, however, be obtained in various ways from the color synchronization signal 50, e.g. the phase comparison circuit of many automatic phase control circuits provides a square wave output signal is unambiguous, but it often contains such a high level of interference that it is not suitable for controlling the PAL switch 9. The very low-interference, line-frequency pulses from the line deflection circuit are therefore used requenten signals of half the information obtained is, however, only ⁶⁰ ambiguous with respect to the phase.

The third part of the input signal contains line-rate line synchronization pulses from the received Signal whose amplitude corresponds to the black-than-black area and via a line sync pulse separator 14 are supplied to a Tastsignaiquolle 13. The output signal of the Key signal source 13 samples a bistable circuit {5, see above that these cycles have half the line frequency fH

r.

leads like it ζ. B. in US Pat. No. 3,553,357. The square wave signal from the output 16 of the bistable circuit 13 can be in phase or out of phase, in the latter case Case it must be interrupted and by the uninterrupted Tastimpulsc from the key signal source 13 again to be started. After two or three false starts, it is generally in the right phase and the now clear one The low-interference output signal is used to control the PAL switch 9 via a line 17 steer. The fact that it is now in phase and not in the wrong phase (and besides, as before will be explained that color sync signals arrive) is determined in the following way:

It has already been mentioned that the phase comparison circuit in the phase and frequency control circuit 11 a half-line-frequency square wave of a clear phase would lead (if this is not the case such an oscillation can be obtained from the color synchronizing signal in other ways) and this oscillation is fed to a synchronous demodulator 19 via a line! antiphase versions of the output signal from the bistable circuit (Flipfiop) 15 via a 1-line 16 and 0-line 20 (or in any other way) is fed. The synchronous demodulator 19 supplies a positive voltage on an output line 21 if the phase position of the output signal is the bistable Circuit is wrong, a negative voltage of the same magnitude if the phase position is correct and the Voltage zero when the color sync signal or the output signal of the bistable circuit are refined. The positive voltage, when it occurs, e.g. B. via an identification control 22 that a reverse voltage is fed via a line 23 of the bistable circuit 15, so that its square waves stop, even if this sounding is keyed by the Tastsignaiqueile 13. When the vibration the bistable circuit 15 stops, the synchronous demodulator 19 on the line 21 supplies the voltage 0 Vo it. d. That is, that of the bistable circuit via the line 21, the identification control 22 and the The reverse voltage supplied to line 23 disappears and the bistable circuit begins to work again, what finally after one or more repetitions of switching off and resuming with the correct phasing happens. The identification control 22 expediently contains a transistor, which only conducts when the input voltage is positive and then one of the inputs of the bistable circuit 15 shorts.

The output signal of the synchronous demodulator 19 is also used by means of a color switch 24 a color signal stage, e.g. B. in the processing line circuit 2 to put out of operation when the voltage of line 21 is zero or positive. The color channel is therefore not only blocked when the identification square wave has the wrong phase position, but also if the color synchronization signal is due to fading or a black and white signal fails or is missing. A delay can be provided which causes the color to switch off only then is, if several successive color sync signals are missing, so that a short-term Shrinkage remains ineffective in a known manner.

The w for controlling the serving fdentifiknlion output signal on the line 21. H · therefore also be used to Fiirliiibschallunfj what bislu · demodulating an farblrägcrfrequenten signal level and use this level required to control the color reproduction. The present circuit arrangement therefore saves a great deal of active and other circuit elements.

An optional detail will now be made with reference to FIG of the receiver according to FIG. 1 explained. It is typical of the synchronous demodulator 19 that the Disturbance-prone but in-phase square wave 25 from the phase locked loop 12 in FIG. 1 at the connection of two with the same polarity in series schalletei diodes 2g and 27 is supplied. Between the other terminals of the diodes 26 and 27 are two series-connected resistors 28 and 29, the connection of which serves as an output terminal and is connected to the line 21 (see also FIG. 1). the Terminals of the diodes connected to the resistors are also connected to the output lines 16 or

20 of the bistable circuit 15 (F i g. 1) coupled, on which the antiphase output signals of this Circuit, the course of which is shown at 30 to 31 in the case of an incorrect phase position with regard to oscillation 25 is. If these oscillations 30, 31 are fed to the synchronous demodulator 19 with the wrong phase position.

occurs on the line 21 a positive DC voltage of z. B. + 0.7 volts, through which a normally

. blocked npn transistor in the identification control 22 is biased in the flow direction. If vibrations 30 and 31 are absent, work the bistable circuit 15 either not at all or with the opposite phase, in which case At the same time as the oscillation 25, the two oscillations 32 and 33 occur. In that case appear! then on line 21 a negative voltage of

z. B. - 0.7 volts, which blocks the npn transistor 22. No reverse voltage then occurs on line 23 and the sampled square waves are perceived as correct, d. that is, the vibrations 32, 33 last for. The transistor in the identification control 22 is also blocked when the voltage surf of line 2i has the value 0, which is the case when the oscillation 25 is missing (failure of the color synchronization signal) or the bistable circuit does not work. What usually has its reason for the fact that the The phase position was incorrect, i.e. oscillations 30 and 31 were present.

In accordance with the concept of the invention, the direct voltage controls on line 21 also the color switch-off. The negative voltage that occurs when the

Oscillation 25 and the in-phase oscillations 32, 33 are present, tensioning a pnp transistor in the color switch 24 in the flow direction, which then cancels the color switch-off, since the less when the transistor is conductive negative collector voltage allows a

Transistorstufc 34 conducts normally in the color channel. When the phase-related oscillations 30 and 31 are present, The positive bias blocks the transistor in the color switch-off 24, so that the color reproduction goes through Blocking of the traiisislorsstufc 34 is prevented. this occurs even when the voltage is on the line

21 has the value 0, so that the color reproduction is only possible when the phase-locked loop has reverse oscillations supplies (i.e. the color synchronizing signal is always or at least mostly available)

f'5 and the bistable circuit an output oscillation correct phase position.

The present color switch-off also has the advantage extreme failure (the well-known

Regulations for identification and color switch-off required up to five transistors and two diodes) also still inherently advantageous property that it is closely related to the DC control voltage for the identification circuit related and even uses the same voltage source. If any kind of Threshold control or delay is desired, can therefore be on the ground side of a resistor, which couples the connection of the diodes 26 and 27 to ground, at 36 a suitable DC voltage cingc- ίο are fed, and there is then an automatic synchronization of the identification and color switch-off function guaranteed. In the circuit shown, the identification can only fail again if the signal is too weak or too disturbed to receive a to synchronize perfect synchronization of the phase locked loop 12 for the reference carrier oscillator. In this case, the output of the can be used as a phase comparison circuit Serving synchronous demodulator 19 on line 21 is not sufficiently negative Assume value to bias the transistor in the color switch 24 in the forward direction, so that then so the color reproduction is suppressed. The color switch only allows color reproduction if the conditions allow perfect image reproduction.

Another important feature of the circuit described is that the DC voltage on the line 21 is generated by synchronous demodulation ■, which inherently has the advantage of an exceptional Insensitivity to interference, as the interference component acts symmetrically and is therefore largely compensates what is not the case. when the voltage for color shutdown as usual by a simple Amplitude demodulation is generated.

The idea of the invention is shown above with reference to FIG. I and 2 explained in connection with a PAL receiver It can of course be applied in a corresponding manner to the SECAM system, the only one The difference lies in the Gcwinp'iwg of the square wave 25 fed to the junction of diodes 26 and 27. With the SECAM system, the Color subcarrier frequency switched from line to line and you can z. B. use a discriminator, which is felt during the occurrence of the back porch and its output signal a certain integration an approximately rectangular shapec Vibration results, which are fed to the connection of the two diodes 26 and 27 via the line 18 can be. You don't need one with this procedure to use a special SECAM identification signal, that is only present during the vertical interval.

Many features of the identification circuit are similar to the known circuits described in the aforementioned patent, for the However, control of the color switch-off according to the invention can also be used with any other suitable control Work phase correlation.

In addition 2 sheets of drawings £ 09 025 /! 55

Claims (6)

Patent claims: 2i 30310 ι · I. Steiierscli! i! '. (ing for clic color lock of a color television receiver with a control signal generator controlling the phase control of the color trigger, the switching signal of which can assume two phase states with respect to a reference signal, and with a control signal generator which sends a control signal to the switching signal generator the control of the phase position of the switching signal and supplies to the color lock, which assumes a first state when the switching signal and reference signal phase match, a second state when there is no phase matching, and a third state when the reference signal is absent, with the color barrier only being open in the first control signal state, characterized in that that the control signal (on line 21) is fed to the bases of two transistors (BC 107, BC177) of opposite splitting types, one of which (13C177) only supplies an enable signal to the color blocker (24) when the control signal is in the first state, while the other ( ÖC107) e in Frcigabesignal supplies to the switching signal generator (15), and the other (BC 107) supplies a phase correction signal to the switching signal generator (15) only in the case of the second state of the control signal. 2. Control circuit according to claim 1, characterized in that «a phase correction signal Blocking signal for the keyed switching signal generator, which produces two antiphase square waves (15) is that when the switching signal generator is blocked, it disappears again when it starts up again. 3. Control circuit according to claim 1 or 2, characterized in that the phase switching takes place at half the line frequency. 4. Control circuit according to claim 2 or 3, characterized in that the switching signal generator (15) by a key signal source (13) with the haiben Nominal frequency of the phase switching is controlled. 5. Control circuit according to claim 4, characterized by a color subcarrier oscillator (8) whose Color carrier-frequency output oscillation through a color-carrier frequency color sync signal, whose phase is switched from line to line by 90 ° by means of a control loop (12) that controls the Phase changes cannot follow the Color carrier frequency is synchronized, further by an arrangement (phase control circuit 11) to obtain a half-line frequency square wave from the control loop (12) a circuit arrangement (19, 22, 15) for synchronizing the keyed phase switching signal with the half-line frequency square wave, and by one by the synchronized phase switching signal controlled switch (9) for changing the phase of the oscillator (8) or the color carrier oscillation in half-line intervals under control of the color sync signal. 6. Control circuit according to claim 5, characterized by a synchronous demodulator (19), the one with anti-phase oscillations of the loaded signal (30 to 33) and the square wave (25) is fed by the control loop (12) and supplies the control signal (on line 21). The invention relates to a control circuit such as the claim I presupposes. It is known to provide a so-called color monitor in a color television, which prevents color reproduction when the received signals are weak, distorted or faint for proper reproduction. Such signals often allow a reasonably acceptable monochrome image reproduction, but when color is received, they result in color images which are perceived to be far more unsatisfactory than corresponding black-and-white images without color. F.s color television receivers are known to work with normal Reception can be switched automatically between two alternating operating states. Typical examples of this are receivers that work according to the SECAM or PAL system. The switching of the receiver is controlled by a feature in the received signal to ensure perfect color reproduction. This feature is a frequency change in the SECAM system and in the PAL system, a phase change from which an identification signal is generated. The color rendering is grossly falsified if the switchover takes place with a phase shifted by 180 ". In the known color television receivers, the color monitor is controlled by the identification signal, which is generated in the receiver when a color signal is received. The receiver's color channel is enabled when a color signal is received, regardless of whether the FJe operating state of the receiver takes place in phase or not. In the case of color television receivers of the type specified above, it can therefore occur, even if mostly only for a short time, that the color channel is released before the operating status of the receiver is switched over, so z. B. in a PAL receiver, the PAL switch is synchronized. Here, however, the colors completely wrongly reproduced. With a phase difference of 180 "between the Reference signal and the switching of the receiver is z. B. in a PAL receiver a pure red corresponding signal is shown in green, while in a SECAM receiver such a signal is shown in is rendered a greenish blue. It is evident that the color falsification that occurs with the wrong Phase position of the half-line frequency switching of the receiver occur, especially during playback of flesh tones are much more disturbing than an achromatic rendering. According to DT-AS 12 36 820, this disadvantage is eliminated by the fact that the color monitor is not only activated when a signal component characterizing a color transmission, in particular the color sync signal (as in the NTSC system), is missing in the received signal, but also if the switchover or identification is wrong. Color reproduction is only possible if the color sync signal is available and the switching is working properly. The color television receiver described there can be switched alternately between two operating states synchronously with a reference signal and has a circuit arrangement for generating an alternating switching signal for controlling the switching of the receiver between the two operating states and a sound system for generating a control signal that depends on whether the switching signal is normal.