DE2130310B2 - Control circuit for the color lock of a color television receiver - Google Patents

Description

synchronize voltage signals with the reference signal; is «Which is not as well as one controlled by the control signal Circuit for adjusting the phase of the switching signal and a color lock controlled by the control signal. The color switch-off is therefore through the same signal controlled, which also the identification or switching in the receiver in the richt.ge Phaleniagc brings. With the PAL. And SEC'AM systems, this suppresses the color reproduction in the event of incorrect identification.

The object of the invention is to provide a control attitude, which is particularly in circuitry easy way to control the color lock and the correct setting of the phase position of the switching signal due to only a single control signal and is very reliable. also in that the three signal states of the control signal can be distinguished safely and without problems and the controls mentioned can be carried out without the risk of undesired influences.

This object is achieved by the features of claim 1.

A circuit with two transistors of opposite Lciiungtyps is known from DT-PS 10 39 570, whose emitters and their bases are connected to one another and between their collectors a Voltage source is connected, while the emitter is connected to a potential between the two via a load End potentials of the voltage source is performed. | e after that supplied to the interconnected bases Input signal conducts one or the other transistor, and the current flowing through the load hai accordingly one or the other direction, so with the help of the at the bases of the transistors lying control signal can be reversed in its direction.

In the circuit according to the invention, the transistor combination via their base electrodes also controlled so that either one or the other transistor conducts, but no current reversal is used here, but rather it is used different output signals are passed by the two collectors, in such a way that in the case of white of the three different signal states, namely the first and the third signal state, one of the two transistors supplies the same output signal, while two other of the three signal states, namely the second and third signal state, the other transistor delivers the same output signal both times. In this way, the extremely simple and absolutely safe control of the color lock is implemented at the same time as controlling the phase position of the 'clock for the PAL switch (or the corresponding Parts in the SECAM system) possible. There are thus different output signals at different Taps of the transistor combination generated, with for two of the three states of the control signal each one of the two transistors generates the same output signal.

Developments of the invention are identified in the unclaims.

The following are exemplary embodiments of the invention explained in more detail with reference to the drawing. It shows

F i g. 1 is a block diagram of part of a color television receiver according to the invention and

F i g. FIG. 2 shows a circuit diagram of a preferred embodiment of part of FIG. 1.

The in F i g. I illustrated part of a PAL color television receiver a color television signal / is fed to a terminal I, which is not represented by Filter, delay and amplitude sifter circuits divided into three parts. The first part will be one

PA L delay line signal processing device 2 supplied, in which the color information in a known manner in carried BY and R- V 'signals

ίο lines 3 and 4 for phase demodulation in denioclulator circuits 5 and 6, respectively. The d ·. ¹ -nodulated signals are fed to a consumer 7, the z. B. may contain a matrix circuit and a picture tube. The deniodulators 5 and 6 are also supplied with a reference carrier wave from the output of a local color reference carrier oscillator 8. The reference carrier oscillation for the demodulator 6 is practically in all PAL receivers, especially those that work with a delay line, switched by 180 in phase after each line by a PAL switch 9,! • "Another possibility, however is less common is to switch the PAL switch 9 on the line 4.

F.s no problem, switch 9 as required, to switch with half the line frequency 0.5 fii and to synchronize the oscillator 8 by the received signal with the color subcarrier frequency. aside from that however, the switching of the switch 9 must be done with the correct of the two possible phases, which in is effected in a known way as follows:

The second part of the input signal becomes an isolation circuit 10 supplied, each of which supplies a color synchronizing signal (burst) between the image lines.

which comes from the transmitted signal and is used to control the reference carrier oscillator 8 by means of a phase and Frequcnzregclschaluing 11, which forms part of a phase locked loop 12, with the correct To synchronize the color carrier frequency. The color carrier frequency The color sync signal from the separation circuit 10 also contains half-line frequency phase information, since the phase of the successive color sync signals changes by ± 45 ", which however, the phase of the oscillator 8 does not switch because it has too high a quality for this Has color subcarrier frequency. The phase of the output signal of the reference carrier oscillator 8 is therefore constant. The half-line rate information, however, can be obtained in various ways from the color synchronizing signal can be obtained, e.g. B. provides the phase comparison circuit of many automatic phase locked circuits a square wave output signal. This half-line frequency information is unambiguous, it contains however, often such a high proportion of noise that it is not suitable for controlling the PAL switch 9. The very low-noise line-frequency pulses from the line deflection circuit are therefore used. the however, half-line rate information obtained from the available line rate signals is alone ambiguous about the phase.

The third part of the input signal contains line frequencies Zeilensynchronisierimpul.se from the received signal, the amplitude of which corresponds to the blacker-than-black area correspond and via a line synchronizing pulse separation stage 14 of a key signal qtiellc 13 are supplied. The output signal of the key signal source 13 is scanned by a bistable circuit 15, see above that these cycles with half the line frequency fn

as it is e.g. in the I IS A-Caten tschrift 1 35 53 357 is described. 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 it must be interrupted and by the uninterrupted Key pulses from the key signal source 13 are started. After two or three false starts it is generally the correct phase and the now unambiguous low-interference output signal is used to to control the PAL switch 9 via a line 17. The fact that it is now wrong and does not have the wrong phase (and also, as will be explained later, that color synchronization 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 delivers a half-line-frequency square wave of a clear phase (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 via a line 18 to a synchronous demodulator 19, which also has antiphase versions of the output signal from the bistable circuit (flip-flop) 15 via a 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 if the color synchronization signal or the output signal of the bistable circuit fail. 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 wave cn stop even if this circuit is keyed by the key signal source 13. When the vibration the bistable circuit 15 stops, the synchronous demodulator 19 on the line 21 supplies the voltage 0 volts, i.e. that is, that of the bistable circuit over the line 21, the identification control 22 and the line 23 applied reverse voltage disappears and the bistable circuit begins to work again, which eventually after one or more repetitions of switching off and resumption of oscillation happens with the correct phase position. 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 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 in the case of a black-and-white broadcast fails or is missing. A delay can be provided which causes the color to switch off only then is, if several successive color synchronization signals are missing, so that a short-term Shrinkage remains ineffective in a known manner.

The output signal used to control the identification on line 21 is also used here for color switch-off, which was previously demodulation a color subcarrier frequency signal level and the use of this level to control the color reproduction required. The present sound arrangement thus becomes active to a considerable extent and other circuit elements saved.

With reference to FIG. 2 will now be an optional detail of the recipient according to FIG. I explained. For the synchronous demodulator 19 is typical that it receives the disturbance-prone but in-phase rectangular oscillation 25 from the phase locked loop 12 in FIG. 1 at the connection of two with the same polarity series-connected diodes 26 and 27 is supplied. Between the other terminals of 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 resp.

20 of the bistable circuit 15 (F i g. 1) coupled, on which the anti-phase 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 the Oscillations 30 and 31 are not present, the bistable circuit 15 either does not work at all or with the opposite phase, in which case the two oscillations are then simultaneously with oscillation 25 32 and 33 occur. In this case then appears on the 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 sensed square waves are perceived as correct, d. h "that the vibrations 32, 33 last for. The transistor in the identification control 22 is also blocked when the voltage is on the line 21 has the value 0. what is the case if oscillation 25 is missing (failure of the color synchronizing signal) or the bistable circuit does not work, which is usually due to the fact that the The phase position was incorrect, i.e. oscillations 30 and 31 were present.

According to the idea of the invention, the direct voltage on line 21 also controls the color shading. The negative voltage that occurs when the oscillation 25, and the in-phase oscillations 32, there are 33 biases a PNP transistor in the color killer 24 in the flow direction in front, which then removes the color shutdown, since the at-conducting transistor is less negative collector voltage allows that a

Transistor stage 34 conducts normally in the color channel If the phase-reversed oscillations 30 and 31 are present, The positive bias blocks the transistor in the color switch 24, so that the color reproduction through Blocking of the transistor stage 34 is prevented. This also occurs when there is voltage on the line

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

⁶ S and the bistable circuit emits an output oscillation with the correct phase position.

The present color switch has the advantage of extreme simplicity (the well-known circuit

Orders for identification and dismantling needed up to five transistors and two diodes) too nor inherently advantageous property that he closely related to the DC control voltage for the identification circuit and even the same Spaniningsquclle used. If any kind of Threshold curl 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, a suitable DC voltage is fed in at 36 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 for proper synchronization of the phase-locked loop 12 for the reference / carrier oscillator to synchronize. In this case, the output signal of the synchronous demodulator serving as the phase η comparison circuit 19 on the line 21 do not assume a sufficiently negative value to switch the transistor in the color switch-off 24 to bias in the flow direction, so that the color rendering is then suppressed. The paint stripper thus only allows color reproduction if the conditions allow perfect image reproduction enable.

Hin Another important feature of the described circuit is that the DC voltage is generated on line 21 by Synchrondemodulalion, which naturally has the advantage of exceptional Störuncmpfindliehkeit, since the interference component acts symmetrically and therefore weitestgehcnd compensated for, which is not the case. when the voltage for color shut-off is generated as usual by a simple amplitude demodulation.

The idea of noise control is illustrated above with reference to FIG. 1 and 2 have been explained in connection with a PA L receiver, it is of course in a corresponding manner

ίο way applicable to the SF.CAM-Syslem, the only one The difference is in the extraction of the square wave 25, the connection of the diodes 26 and 27 is fed. With the SECAM system, the color subcarrier frequency is switched from line to line and you can z. B. use a discriminator that during the occurrence of the back porch is sampled and its output signal after a certain integration an approximately rectangular shape Vibration results, which are fed to the connection of the two diodes 26 and 27 via the line 18 can be. With this method there is no need to use a special SECAM identification signal.

which is only present during the vertical interval.

Many features of the identification circuit are similar to the known circuits shown in FIGS above-mentioned patent specification are described for the inventive control of the color shutdown canr however, one can also work with any other suitable phase correlation.

For this purpose 2 sheets of drawings

$ 09 546 /;

Claims (6)

Patent claims: 1. Control circuit for the color lock of a color television receiver with a switching signal generator controlling the phase change of the color carrier, the switching signal of which can assume two Phasenzuständc with respect to a reference signal, and with a control signal generator which supplies a control signal to the switching signal generator for controlling the phase position of the sound signal and to the color lock , which has a first state when the switching signal and the reference signal match, a second state when there is no phase match and a second state when the B; Zugssigna! assumes a third state, the color block only being opened in the first control signal state, characterized in that the control signal (on line 21) is fed to the bases of two transistors (SC 107, ßC177) of opposite conduction types, one of which (ß (T177) only when the control signal is in the first state, it supplies an enable signal to the color blocker (24), while the other (ßClO7) supplies an enable signal to the switching signal generator (15), and the other (ßC107) only sends a phase correction signal to the switching signal generator when the control signal is in the second state ( 15) delivers. 2. Control circuit according to claim 1, characterized in that the phase correction signal is a Blocking signal for the keyed switching signal generator which delivers two square waves in antiphase (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 phases ;; mseha! Device takes place at half the line frequency. 4. Control circuit according to claim 2 or 3, characterized in that the switching signal generator (15) controlled by a key signal source (13) with the main nominal frequency of the phase switching is. 5. Control circuit according to claim 4, characterized by a color subcarrier oscillator (8), the color subcarrier frequency output oscillation by a color subcarrier frequency color sync signal, the phase of which is switched from line to line by 90 ", by means of a control loop (12) which is unable to follow the phase change τ , is synchronized to the color carrier frequency, further by an arrangement (phase control circuit 11) for obtaining a half-line frequency square wave from the control loop (12), by a circuit arrangement (19, 22, 15) for synchronizing the keyed phase switch signal with the half-line frequency square wave, and by a switch (9) controlled by the synchronized phase switching signal for changing the phase of the oscillator (8) or the color carrier oscillation in half-cycle intervals under control by the color sync signal. 6. Control circuit according to claim 5, characterized by a synchronous demodulator (19), the one with antiphase. Oscillations of the sampled 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 1 presupposes. Egg is known to be a so-called in a color television Provide color switch that prevents color reproduction when the received signals are too weak, distorted or faded for proper playback. Let / was such signals often a reasonably acceptable monochrome image reproduction, but when received in color they give Color images that are perceived to be far more unsatisfactory than corresponding black and white images colourless. There are color television receivers known, which automatically alternate between two with normal reception Operational states can be switched. Typical examples are recipients following work with the SECAM or PAL system. The switching of the receiver is controlled by a feature in the received signal in order to ensure perfect color reproduction. This feature is a frequency change in the SECAM system and a phase change in the PAL system, from which an identification signal is generated. The color reproduction is grossly distorted if the Umschalu-i: at shifted by 180 degrees phase. In the known color television receivers, the color switch 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 operating mode is switched of the recipient is in phase or not. In the case of color television receivers of the type specified above, it can therefore occur, even if usually 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. In this case, however, the colors are reproduced completely incorrectly. With a phase difference of 180 ° between the reference signal and the switching of the receiver z. B. in a PAL receiver a pure red corresponding signal is reproduced in green, while in a SECAM receiver such a signal is reproduced in a greenish blue. It is evident that the color distortions which occur when the phase position of the half-line frequency switching of the receiver is incorrect, especially when reproducing flesh tones, are much more disturbing than an achromatic reproduction. According to DT-AS 12 36 820, this disadvantage is eliminated in that the color switch is not only then comes into action when a signal component characterizing a color transmission, in particular in the received signal the color sync signal (as in the NTSC system) is missing, but also when the switchover odei Identification are wrong. Color reproduction is only possible if the color sync signal is available and the switchover is working properly. The color television receiver described there is synchror alternately switchable between two operating states with a reference signal and has a switch processing arrangement for generating an alternating switchover signal for the purpose of securing the switchover; Receiver between the two operating states and a circuit for generating a Steui gnals, which depends on whether the switching signal is ord