DE895776C - Circuit for separating current or voltage pulses - Google Patents

Description

Circuit for separating current or voltage pulses For various technical purposes, e.g. B. for television reception, the task is currents or Tensions resulting from pulses of different sizes or different levels of amplitude Modulation degrees are composed to be separated from each other (amplitude filtering). For example, it is common in television to send the image and synchronization pulses on the transmission side (see the diagram in Fig. z) so that, starting from a z. B. a5o / oigen modulation of the carrier wave, the image pulses b according to higher degrees of modulation to, the synchronization pulses s, z. B. the line pulses, after the modulation value To run zero. Fig. R shows the course of these television reception currents after rectification (i.e. without carrier or intermediate frequency wave). The task here is to separate the two pulses b and s from each other in such a way that that the first means the image stream control means, e.g. B. the modulation electrode of a television tube, the second to the synchronization part, e.g. B. the tilting vibration device of the television receiver, can be fed.

With the invention, the object is first of all to one another combined pulses of different amplitudes or different degrees of modulation to separate from each other by a very simple, tube-saving and yet completely Reliable working circuit solved.

The circuit according to the invention includes an amplifier tube, e.g. B. a simple control grid tube that controls the amplitude mixture to be separated first is supplied in such a way that it is rectified in its output circuit, i. H. after Elimination of any pre-existing carrier wave occurs. These can Impulses have already been rectified before entering the amplifier tube, or the rectification only takes place in the tube itself, e.g. B. by working ' on the lower bend of the curve. Especially in the case of working with television reception streams so the current flowing in the output circuit of the amplifier tube has the same course as in Fig. i. Part of this rectified voltage is now taken from the output circuit of the amplifier tube described to the input circuit of a second amplifier tube fed, which is biased so that the below or above a certain amplitude or a certain degree of modulation lying pulses cut off will. The output circuit of this second tube now works together with that of the first tube on a common circuit in such a way that the current or voltage pulses of the same size and in opposite directions, d. H. around i so 'different in phase are. The impulses of the same kind cancel each other out and stay that way only the pulses suppressed by the second amplifier tube remain. These are taken from the circuit and fed to the breakover voltage device.

- Usually, as can be seen from the diagram in Fig. 2, give the second amplifier tube such a bias of its grid circle that the maximum value of the smaller amplitude of the voltage mixture or the limit value the modulation degrees to be separated from each other lie in the lower bend of the characteristic curve. In this case, the pulses below this limit are suppressed, while the impulses lying above this limit are amplified. One can but the bias, if necessary, also dimensioned so that the amplitude or. Modulation Degree Limit of the voltage mixture is in the upper bend of the characteristic curve, so that it is in the Hand has to suppress the impulses lying above this limit and only those to reinforce lying below the same.

The drawing shows the basic principle in Fig.3, in-Fig. 4 shows a particularly advantageous embodiment of the invention. In Fig. 3, which like Fig. 4 only schematically reproduces the switching parts of a television receiver necessary to understand the invention, e means the receiver part of a television receiver, in particular a superimposed receiver. Its output leads to the grid circuit of an amplifier tube v:, in the anode circuit of which there is a resistor w:. An appropriately adjustable tap leads from this resistor via a capacitor c to the grid circuit of a second amplifier tube v2. At the anode circuit of the latter there is again a resistor w2. The cathodes of the two amplifier tubes are connected to one another and suitably earthed. A line 1 2 leads from them to the synchronization part of the oscillating vibration generator. Furthermore, the anodes of the two tubes viundv2 are each connected to a line L1 via a capacitor k1 or k2, which also leads to the synchronization device. Both tubes have a common anode current source a, furthermore the tube v2 has a grid bias voltage source g, which is negative, for example for the separation of pulse mixtures according to FIG. I.

The mode of operation of the circuit is as follows: That either already rectified emerging from the receiver e or, at the latest, rectified in the amplifier tube v1 Pulse mixture, which initially corresponds to the diagram in Fig. I, for example, is fed to the grid circle of the tube v2. Where is the negative grid bias dimensioned so that the boundary between the two degrees of modulation of the to be separated Amplitude mixture, i.e. the dashed line according to Fig. I (25 ° air modulation), is just in the lower bend of the tube characteristic, so that only part b of the amplitude mixture, d. H. the image currents, transmitted through the tube v2, while the sync pulses s are suppressed. The one in the tube v1 and the other in the tube v2 amplified pulses now have a phase shift of i, So ° to each other, so that, as soon as they are also the same size, in the common circuit formed by 1i and 12, on which both tubes through the capacitors k1 and k2 work at the same time, cancel each other out. It just remains the synchronization pulse left, which although amplified by the first tube, by the second but had been suppressed. These pulses are then s through the line pair L1, 12 fed to the synchronization part of the receiver. By means of regulation known per se, z. B. by choosing the position of the tap of the input line of v2 on the external resistance w1, you have it in your hand, the one in the outer circles of the two amplifier tubes acting amplified voltage pulses to make the same size, so that in the line pair h, 12 completely cancel the image streams b (see Fig. i).

The circuit according to Fig. 4 has the further advantage over the circuit according to Fig. 3 that it only works with a single tube. A double tube is used for this, the anode circuits of which form a kind of push-pull circuit. In principle, the circuit is the same as in Fig. 2, ie the first amplifier system of the tube v amplifies the amplitude mixture that has already been rectified or the amplitude mixture that has not yet been rectified. From the external resistance w. Of the first amplifier system, a coupling line leads, expediently tapped again, via the capacitor c to the grid of the second amplifier system, which is again negatively biased by the voltage source g. The anode voltage source a is connected on the one hand to the appropriately grounded cathode line and on the other hand to the two external resistors w1, w2 of the two amplifier systems connected in push-pull to one another. The line 11 is again connected to the two anodes of the amplifier systems via a capacitor k1 or k2. In this case, too, the voltage pulses acting in w1 and w2 are directed in opposite directions, so that they cancel each other out in the line circuit 11, 12 with the same dimensioning.

The new circuit has compared to the known amplitude filter circuits the advantage that it does not need a voltage reversing tube. While at one of the amplitude sieves that have been customary up to now at least three tubes are necessary, comes the new circuit with two or, as in Fig. q. shows even with just one tube out. In addition, synchronization pulses arise in the new circuit in the acceptance circuit of relatively large amplitude, so that an effortless synchronization is guaranteed.

Claims (5)

PATENT CLAIMS: r. Circuit for separating (filtering out) current or voltage pulses which differ in amplitudes of different sizes or which are above and below a certain degree of modulation acting as a limit, characterized in that the output circuit of an amplifier tube, which carries the rectified voltage mixture, with the input circuit a second amplifier tube is coupled, the control grid such, for. B. negative, is biased that the pulses of one amplitude or one degree of modulation, z. B. the synchronizing pulses are cut off, and that the output voltages of the two amplifier tubes are connected in opposite directions and with the same amplitude to a common circuit from which the pulses of the amplitude group suppressed by the second amplifier tube are taken. 2nd circuit after Claim i, characterized in that d @ aß the decrease circle for the impulses screened out with a line via a capacitor each to the anodes of the two amplifier tubes, with the other is connected to its common cathode. 3rd circuit after Claim r or 2, characterized in that the first amplifier tube is used as a rectifier is switched. q .. Circuit according to Claim z, 2 or 3, characterized in that that the amplitude of the voltage pulses taken from the output circuit of the first amplifier tube, expediently variable by means of an adjustable tap in the external resistance of this tube is. 5. A circuit according to claim r or the following, characterized in that the two amplifier tubes to form a double tube with a common cathode in push-pull circuit are united.