DE1050805B - Pulse separation circuit for television receivers - Google Patents

Description

GERMAN

The invention relates to a pulse separator circuit for television receivers for separating the Vertical sync pulses from the sync signal. Circuits of this type are known per se, but so far essentially in the form that a tube, which can also be a multigrid tube, provides the synchronizing signal separates from the image signal. For the subsequent separation of the vertical sync pulses from the horizontal sync pulses hitherto, tubeless circuits have generally been used which only Differentiating members or integrating members contained. To filter out the vertical synchronization pulses is generally an integration; of the sync signal made, which is too proportionate leads to fuzzy pulse edges. Accordingly, television receivers equipped with such circuits have the disadvantage that the picture change does not take place precisely enough in terms of time. The so generated As a result, images have defects.

A well-known Impuilistrennschadtung with upstream The amplitude sieve is shown in FIG. It is set up for one in today's television operation applied synchronous signal, which in temporal succession periodic time pulses for the Contains horizontal synchronization and longer periods in between in consistently larger periods of time Vertical sync pulses for vertical synchronization. Between the horizontal synonial impulses and the longer vertical sync pulse are auxiliary pulses, so-called satellites, inserted, which facilitate the exact work of the receiver circuits should.

The known circuit according to FIG. 1 contains a pentode Rö 1 (ECL 80), which has the task of separating the synchronous signal from the image signal. The pentode is followed by a triode Rö 2, the two tube systems generally being combined in a composite tube. The television signal mixture, which consists of the image signal and the synchronous signal, is fed to the first control grid of the pentode via a coupling capacitor C1 with positive polarity of the synchronous signal. The pentode is controlled into the grid current area, so that the grid-side end of the coupling capacitor C 1 is negatively charged by the current flowing through the grid bleeder resistor R 1 so that the image signal is suppressed and only the negative synchronous signal is generated at the anode.

The anode voltage for the tube Rö 1 is applied to a voltage divider R 4 / i? 5 attacked while the screen grid is connected to a voltage divider R2 / R3 and grounded through a capacitor C 2 in terms of high frequency. The negative synchronous pulse separation circuit for television receivers that occurs at the anode resistor i? 4 of the pentode

Applicant: Siemens-Electrogeräte Aktiengesellschaft, Berlin and Munich, Munich 2, Oskar-von-Miller-Ring 18

Dipl.-Ing. Eduard Lüdicke, Renfrew, Ontario (Canada), has been named as the inventor

signal is sent via a coupling capacitor C 3 to the control grid of the downstream triode Rö 2 and cut to constant voltage values by driving the triode into the blocking range. For this purpose, the control grid of the tube Rö 2 is connected to the anode feed line + A via a resistor R 6, so that negative charging of the grid-side assignment of the coupling capacitor C 3 and thus a shift in the operating point is avoided. The positive synchronous signal with constant amplitude then appears at the anode resistor R 7 of the triode. This positive synchronous signal is fed via a further coupling capacitor C 4 to a roarless isolating circuit, which consists of a differentiating chain for the horizontal pulses and an integrating chain for the vertical pulses.

The horizontal pulses are differentiated at the differentiating element consisting of the capacitor C 5 and the resistor i -8 and fed via the coupling capacitor C 6 to the subsequent horizontal deflection circuit in a manner known per se. the

4-0 in comparison with the horizontal pulses substantially longer vertical pulses are integrated in the group consisting of the resistors R9 and RIO and capacitors C 7 and C 8 existing Integrierkette and the vertical oscillator optionally fed from there with the interposition of a per se known Frequenzna, chstell ^J circuit.

In Fig. 1 are the differentiated horizontal pulses and the integrated vertical pulses at the output of the associated differentiating element or integrating element drawn. The differentiated horizontal pulses have sharp edges, while the integrated vertical sync pulses have gradually rising edges as a result of the integration. Accordingly, it is the point in time when the image change occurs

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not defined exactly enough, which expresses itself to the effect that the interline is not always exactly in the middle lies. This leads to uneven tendering of the grid. It's possible, even for that Vertical synchronizing pulses "differentiating elements to-" turn, but then an additional tube is usually required. In addition, interference impulses then have a stronger effect, which is why such circuits often only on the transmitter side for 'studio equipment. The pulse integration in vertical deflection shows less susceptibility to short-term disturbance impulses. But their disadvantage is the one mentioned above slow rise and thus the temporally imprecise determination of the time of synchronization ^ Another disadvantage of the known circuit is that, despite the integration Remnants of the synchronous mixture are present in the vertical synchronization circle, as are the intermediate lines affect unfavorably. For this purpose, it is known per se, after the pulse separation circuit, further To provide tube systems that ensure that exact vertical sync pulses are generated, which have no disturbing remnants of the rest of the sync signals. The effort of such a circuit is however considerable, so that it could not prevail in practice.

Circuits are also known which are used to separate the horizontal pulses and the vertical pulses use a multigrid tube. These circuits based on the principle of the transiton show however, the disadvantage on / that of the Synrihirongemisch separate vertical pulses still have remnants of the horizontal pulses. The ones used for this Electron tubes have three grids. The composite television signal is generated with the positive polarity of the Synchronous signal fed to the first grid, which · as a result of the charging of the coupling capacitor by means of Grid current is negatively biased to such an extent that only the sync pulses can open the tube. the the other two grids are attached to one between the anode feed line and. Cathode potential switched on Voltage divider, which consists of the series connection of two resistors with an interposed There is a capacitor, connected in such a way that the second grid (screen grid) on the one hand via the a resistor to the anode supply source and on the other hand is connected via the capacitor to the third grid, while the third grid is simultaneously is connected to the cathode potential via the other resistor. Meet on the first Grid the positive synchronizing impulses, so · thereby the path of the electron stream is both to the second grid (screen grid) as well as to the anode Approved. Only through the voltage drop caused by the screen grid current at the screen grid resistor and the resultant, over the one between the screen grid and the third grid When the capacitor is switched on, the negative voltage surge reaching the third grid becomes this third The grid is negatively biased to such an extent that the path to the anode is blocked for the flow of electrons. These Blocking of the discharge path to the anode continues until the mentioned capacitor is over the has discharged it to the resistor connecting the cathode potential so far that the voltage on third grid opens the way to the anode - again. When horizontal impulses arrive, will the capacitor up to such a voltage value only after the disappearance of the horizontal pulse have discharged so that ■ from the horizontal pulses only that part of the anode resistor that reaches the anode in the first moment as a pulse-shaped voltage appears. When vertical pulses arrive, however, the capacitor discharges during the Duration of the vertical pulse, so that the distance to the The anode is released and the vertical pulse appears at the anode resistor. However, it is with this Circuit not possible to generate free vertical pulses from residual horizontal pulses ίο.

The purpose of the invention is to simplify the circuit according to FIG. 1, known per se, so that without additional effort in spite of the use of integration, precisely timed and residual horizontal impulses Free vertical sync pulses are generated with the help of a multi-grating tube, which is connected to a Electrode emits the vertical impulses and another electrode emits the synchronous signal. ...

According to the invention, this is achieved by ao that the negative synchronous signal separated from the image signal a positively biased first control grid of a Hexöde is fed that a further electrode or first and second screen grids of the tube via a resistor with a positive anode feed line are connected that the positive synchronous signal generated at this electrode or at the resistor fed to the horizontal deflection generator in a manner known per se for synchronization is that, furthermore, from the synchronous signal arising at the said electrode or at the resistor a positive control voltage corresponding to the vertical sync pulses is derived by integration and fed back to the second control grid of the multigrid tube and there a negative bias this grid counteracts so that the current to the anode of the tube only for the duration of the Vertical pulses is released, so that a vertical sync pulse arises at the anode, which by Cutting off its lower part is exactly limited and then in a known manner for synchronization of the vertical deflection generator is used. In a particularly expedient embodiment of the invention, this becomes the positive synchronous signal supplying electrode, preferably the first and / or second screen grid of the multi-grid tube, by one of a series resistance and one; Transverse condenser formed integrating member and one Coupling capacitor connected to the second control grid of the tube. Furthermore, the second is expedient Control grid of the multi-grid tube with positively biased cathode via its lead resistance Earth or ground potential laid. The grid resistance of the first grid of the multigrid tube is preferably at its other end on a positive anode feed line. ' ,

According to a particularly expedient embodiment of the invention, the multigrid tube is preceded by an amplitude separator tube known per se, which is expediently controlled into the grid current area, so that only the synchronous signal opens it. If the negative signal mixture is fed to its control grid, the negative synchronous mixture can be taken from its anode. The amplitude separation tube and the multigrid _tube: s (Hexöde) expediently form two systems of a composite tube (eg ECH 81), ie they have; a common tubular envelope and a common cathode. The effort is therefore not greater than with the known circuit according to = Fig. .1, which .also

works with a composite tube (e.g. ECL 80), whereas the mode of operation is also very important compared to the transitronech circuit described above is improved.

The invention and associated details are explained with reference to FIGS. 2 to 4, for example.

The circuit according to FIG. 2 consists of the triode Rö 11 and the hexode Rö 12. Both tubes are located in a common glass bulb and have a common cathode. It is also within the scope of the invention that separate tubes are used. For this case, a separate cathode is also shown in the hexode Rö 12, although this is common to both systems in a composite tube. ^{The negative signal mixture 5 1} , which consists of the image signal and the synchronous signal, reaches the grid of the triode Rö 11 via the coupling capacitor CI1 Capacitor C15 blocked cathode resistor R17 switched on. The anode resistance is designated R12, the cathode of which is connected through resistor R 16 to the anode. As a result, an additional current flows through the cathode resistor R 17. The triode Rö 11 shifts its operating point so far into the negative by grid current that only the pulses of the synchronous signal open it. For this purpose the grid bleeder resistor has 7? 11 has a relatively large value, e.g. B. 5 MOhm. At the anode or at the anode resistor i? 12 then only negative synchronous pulses occur, which reach the first control grid of the hexode i? Oil2 via the coupling capacitor C 12. The other end of the grid resistor i? 13 of the hexode is connected to a positive anode feed line; this prevents a shift in the operating point. Two electrodes of the hexode Rö 12, preferably the first and second screen grid, are connected to one another in the tube and are connected to the positive anode feed line - \ - A via the resistor R 14. The positive synchronous signal is now generated at these electrodes or at the resistor R 14. This is firstly fed to the horizontal deflection oscillator in a manner known per se via a differentiating element matched to the horizontal pulses for synchronization, if necessary via a retuning circuit. Secondly, a pulse voltage corresponding to the vertical pulses is derived from the positive synchronous signal by integration, which is fed to the second control grid of the hexode Rö 12. The integrating element consisting of the series resistor R 15 and the shunt capacitor C 13 and the coupling capacitor C 14 are provided for this purpose. The grid resistance of the second control grid is denoted by R18 and its other end is at ground or ground potential. A positive pulse of the form shown in FIG. 3 is thus present at the second control grid of the hexode. In contrast to the pulse obtained on the integrating chain according to FIG. 1, this pulse has a flat course of the roof, since the grid current which sets in when the voltage continues to rise at the second control grid causes the pulse to be limited, so that the course itself is flat of the pulse roof are only superimposed by the fluctuations resulting from the pulse gaps contained in the vertical pulse for maintaining the horizontal synchronization.

The cathode is so positively biased by the cross-current passed through the resistor R 16 through the cathode resistor R 17 that only the upper part of the pulse shown in FIG. 3 on the second grid of the hexode is released. By cutting off the lower, shallow pulse parts, the pulse edges are taxed and the residues and disturbances resulting from the Hörizöntal pulses are suppressed. Then appear at the anode of the hexode or at the anode resistor i? 19

ίο exact vertical sync pulses with negative sign, as shown in FIG.

The vertical pulses at the anode resistor R19 are then used in a manner known per se to synchronize the vertical deflection oscillator. Since the vertical pulse in this circuit is very precise and defined and also completely cleaned of pulse residues of the synchronous signal, the vertical synchronization works very precisely and the bad interline cannot occur in the circuit according to the invention. The rise of the vertical pulse delivered in this way has been taxed and all remnants of the remaining sync signal have been removed. This mode of operation is achieved without increasing the cost of tubes and other components compared to the known circuits.

It is as a result of sufficiently large ^amplitude: the vertical synchronization signal obtained in this way certainly technically possible to send this through further integration chain and only then to use the existing signal at its output to synchronize the vertical oscillator.

- Through this double integration, once in front of the grid 3 of the hexode, the other time at its exit due to the integration chain mentioned above, is a particularly good suppression of interference pulses, which benefits the synchronization stability of the vertical oscillator is guaranteed.

Claims (8)

Patent claims: 1. Pulse separation circuit for television receivers to separate the vertical sync pulses from the sync signal with the help of a multi-grating tube that emits the vertical pulses at one electrode and the sync signal at another electrode, characterized in that the negative sync signal, separated from the image signal, is a positively biased first control grid of a hexode ( Rö 12) is supplied that a further electrode or first and second screen grids of the tube are connected via a resistor (i? 14) to a positive anode feed line so that the positive synchronous signal generated at this electrode or at the resistor (i? 14) the horizontal deflection generator is fed in a known manner for synchronization, that a positive control voltage corresponding to the vertical sync pulses is derived by integration from the sync signal generated at the said electrode or at the resistor (i? 14) and transferred to the second control grid of the multigrid öhre is fed back and there counteracts a negative bias of this grid in such a way that the current to the anode of the tube is only released for the duration of the vertical pulses, so that a vertical sync pulse is generated at the anode, which is precisely limited by cutting off its lower part, and then is used in a manner known per se for synchronizing the vertical deflection generator. 2. Pulse separation circuit according to claim 1, characterized in that the electrode supplying the positive synchronous signal, preferably the first and / or second screen grid, and the second control grid of the multi-grid tube by an integrating element formed from a series resistor (RiS) and a transverse capacitor (C 13) and a coupling capacitor (C14) are connected to one another. 3. Pulse separating circuit according to claim 1 or 2, characterized in that when the cathode is positively biased, the second control grid of the multi-grid tube is connected to earth or ground potential via a bleeder resistor (R 18). 4. Pulse separation circuit according to claim 1 or the following, characterized in that the grid resistor (R13) of the first control grid of the multi-grid tube is at its other end on a positive anode feed line. 5. Pulse separation circuit according to claim 1 or the following, characterized in that the multigrid tube is preceded by a known amplitude separation tube (Rö 11) for the separation of the synchronous signal from the image signal, which is expediently designed as a triode and works in the grid current area, so that only the synchronous pulses they open when the negative signal mixture is fed to their control grid and the negative synchronous mixture is removed from their anode. 6. Pulse separating circuit according to claim 1 or the following, characterized in that the grid resistor (i? Ll) of the amplitude separating tube ( Rö 11) is connected to the cathode and a blocked cathode resistor (R 17) is switched on between the two and the earth point The end is connected to the anode of the tube via a resistor (R 16). 7. Pulse separation circuit according to claim 1 or the following, characterized in that the amplitude separation tube (triode Rö 11) and the multi-grid tube (hexode RölZ) form two systems of a composite tube, ie are arranged in the common tube piston, and that both have a common cathode. 8. Pulse separation circuit according to claim 1 or the following, characterized in that the output the multigrid tube is further integrated. Considered publications: German Patent No. 813 163; French Patent No. 974,732; Swiss Patent No. 214 515; Kerkhof and Werner, "Fernsehen", edition of the N. V. Philips' Gloeilampenfabrieken, 1951, p. 123 up to 125; ■ - Wireless World, July 1949, pp. 249/250, article "Transitron Syne Separator" by H. V. Versey. 1 sheet of drawings © 809 750/210 2.59