DE1067473B - Key circuit arrangement for reintroducing the direct current component in pulse mixtures - Google Patents

Description

GERMAN

The invention relates to a circuit for reintroducing the direct current component and / or lower frequency components in electrical signals and uses an already proposed in current-permeable switch in both directions. The invention is particularly suitable for reintroduction the mean brightness in a television signal.

There are already various circuits for the reintroduction of the medium brightness that are used at television transmission, in transformers or in AC amplifiers are proposed been. These circuits require the appearance of periodically recurring pulses in the signal to be transmitted remotely, namely from pulses up to a certain signal value in the picture, e.g. B. up to the black level or up to a few volts beyond the black level Signal value must run before the DC component was suppressed. Watching television these repeating pulses usually consist of the base pulses and the synchronization pulses. A detailed discussion of the problem of reintroducing the direct current component with a comparative consideration of the various circuits proposed for this purpose in the work of Wen dt: "Television DC Component" in the magazine "RCA Review", March 1948, P. 85 ff.

Among the various known circuits are the so-called keyed circuits, from an example of which is described in U.S. Patent 2,299,945. Have such keyed circuits compared to other possible circuits the advantage that they the direct current component very quickly can reintroduce with low distortion and with high insensitivity to noise and that they can still operate at a much smaller signal level than other circuits.

When working with two diodes key circuit according to the said USA.-patent, the charge of a capacitor in the grid circuit of a tube, whose anode current should contain the direct current component, is influenced by means of two diodes, which are periodically repeated by pulses, e.g. B. by synchronizing pulses are sampled. When a synchronization pulse or key pulse occurs, one of these two diodes is keyed in and the capacitor partially discharges through this diode. This applies in the event that the capacitor charge has to be reduced in order to set the correct value of the direct current component. When the other diode is keyed in, the capacitor charges by a certain amount in order to make the key circuit arrangement
to reintroduce the direct current component in pulse mixtures

Applicant:

Radio Corporation of America,
New York, NY (V. St. A.)

Representative: Dr.-Ing. E. Sommerfeld, patent attorney,
Munich 23, Dunantstr. 6th

Claimed priority:
V. St. v. America October 1, 1952

George Clifford Sziklai, Princeton, NJ,
and Alfred Christian Schroeder, Huntingdon Valley, Pa.

(V. StA.),
have been named as inventors

then adjust the prevailing value of the direct current component. Between the tactile impulses, both Diodes locked by means of a bias.

Another circuit, which is also referred to as a bidirectional current-permeable circuit can be, d. H. as a circuit in which the coupling capacitor is charged or can be discharged, uses two keyed triodes instead of two keyed diodes. Such a one Triode circuit is in the book "Principles of Radar", 1946, McGraw-Hill Book Company, described on p. 2 to 35. Another simpler form of key circuit works with a single one keyed diode and is described in U.S. Patent 2,299,944. Their mode of action is up to a certain extent comparable to that of the circuit with two keyed diodes, but is only a single keyed diode is available, and the grid cathode path of the associated tube is used as an additional diode.

These three known circuits have the advantages of key circuits in that they are can be set quickly, show low distortion and low sensitivity to noise and only one require low signal levels, but they have other properties as well in terms of their

909 639/219

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Suitability and usability in detail Fig. 3 shows an embodiment with an n-p-n-

differentiate. The circuit with two keyed transistors, which also relate to a television

Diodes can be made symmetrical, so that the receiver according to Fig. 2 can be used,

the key pulses do not appear in the signal. Also in Fig. 1 is a source 11 of video signals

the level value can be easily adjusted and the 5 a capacitor 13 to the input terminal or

Circuit evenly good for establishing positive the electrode 17 in a subsequent tube stage

or negative signal peaks on a particular one of a circuit for transmitting video signals

Level can be used. However, it poses a downside to being docked. The source 11 can have a certain level

This circuit represents that synchronous strobe pulses ent- in a television transmitter or a television receiver

opposite polarity to the push-pull keying of the io, whereby in the video signals the direct current com-

both diodes must be present, and also contain no more components or incorrectly

the probe pulses must have a greater amplitude. The step with the input electrode 17

sit as the signal so that with a bias can any consumer for the video signals

be both diodes in the pause between the key pulses, z. B. the modulation amplifier of a transmitter

need to be locked. 15 or an image display device of a receiver

The keyed circuit with two triodes requires gers to which the direct current component again only Impulses of one polarity, and these impulses should be guided. The input electrode 17 can also do not need to be as large as the signal, or the control grid of an electron tube 15 if negative signal peaks at a certain level, for example, also the input electrode of a Tran level should be set. However, since these 20 sistors.

The video signal 12 at the output side is the white portion of the key pulses in the signal, and the source 11 contains periodically recurring inter-desired level value cannot be very easily one-valle x, z. B. the basic pulse intervals in a remote setting, visual signal, in which periodically recurring control

The circuit with only one keyed diode is 25 signals, e.g. B. base pulses and synchronizing pulses the simplest of the three circuits described can be given. As with other types of keyed gen, however, can only be used to establish positive reintroduction circuits providing a pulse spike of the signal. The level value is source 41 strobe pulses 42 for the purpose while not adjustable but coincides with the cathode of a certain part of the. Control intervals one potential of the associated tube. Key in the 30 circuit. The The circuit is also asymmetrical in its nature, the charge of the capacitor 13 is readjusted so that the so that impulse residues also appear in the signal here. Grid 17 of tube 15 during each control interval

The invention provides a circuit for the potential fixed to the same, namely the correction of signals in the manner of a key circuit desired signal level can be brought. the suggested which the advantages of the known 35 strobe pulses42 can be in the source41 from synchronous types be made by reintroduction circuits in itself pulse, which unites from the video, without the above-mentioned disadvantages to be signal 12 have been separated, or can also from sit. The circuit according to the invention uses return pulses obtained from the deflection generators a transistor as one in both directions will be current, which through such separated synchronism permeable Switches in the lattice circle that are controlled for re-setting pulses. Let the tactile impulses introductory tube. The base electrode of this is also made up of other devices within each Transistors are supplied with strobe pulses, which system used for the transmission of video signals the current path between the emitter electrode and the win. Regardless of the type of extraction Close the collector electrode for the duty cycle. Since the strobe pulses 42, however, it is important that this through this current path in both directions current 45 pulses synchronous to a horizontally running, can flow through, this current path is used alternately for the periodically recurring part of the video signal to charge or discharge the step, z. B. to the top of the synchronization pulses Coupling capacitor in the lattice circle to the re-stage or to the so-called reverse stage, d. H. the part of Introduction of the direct current component used base pulses, which are connected to the synchromesh pulse on-tube. 50 closes.

It can thus be seen that the invention is a circuit The circuit for adjusting the charge according to the reintroduction of the direct current component of the invention is characterized in that it represents a fast, distortion-free electrical current path both for charging free and noise-free within a large one Signal as used to discharge the capacitor 13. This is level range and yet a very simple structure 55 is made possible by the fact that one transistor is used in both. The circuit according to the invention requires directions to be able to carry current,
only strobe pulses of one polarity, and the ampli A transistor 20 of the pnp type is shown in Fig. 1 dartude of these pulses can be compared to the whole. It consists of a semiconductor body, e.g. B. amplitude range of the signal can be quite small. Made of germanium or silicon, with two p-regions21 The circuit can also have the advantages of 60 and 23, which have circuits that are symmetrical with one another via an n-region 23, as the tactile links are. As in U.S. Patent 2,569,347, pulses do not appear in the corrected signal. explained, occur at the contact surfaces 27 and 29 The specified signal level can be within an electrical barrier. Easily set the electrodes 31, 33 in a wide range, and the circuitry 35 and 35 at the end points of connection lines can be used to establish both positive and 65 form an ohmic contact without rectifier-negative signal peaks. effect with the areas concerned. A theoretical

Fig. 1 is the circuit diagram of an embodiment table explanation of the junction transistors is found

using a p-n-p transistor; in the last mentioned USA patent and in

Fig. 2 shows the application of the circuit according to the work of Shockley, "The Theory of ρ-η-

Fig. 1 in a television receiver; 70 Junctions in Semiconductors and p-n- Junction Tran-

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sistors «, in the journal» Bell System Technical vails y occur with the same level value. Wenn Journal «, vol. 28, p.435ff .; the book by Shockley, but the direct current component is lost "Electrons and Holes in Semiconductors", Verlag van ist, the signal level fluctuates at the grid 17 according to Nostrand Co., 1950; the work of Shockley, according to the signal swing between the intervals y. Je-Spanks and Teal "Physical Review", from July 1, 1951, p but one can readjust the charge of p. 151 ff .; the work of Wallace and Pietenpol capacitor 13 bring the grid 17 always to the desired signal level, and when this charge of the TuIi 1951, p. 753 ff. capacitor 13 to the next interval y er -According to the usual designation at Tran-, the anode current of the tube sistors contains the electrodes 31, 33 and 35 as io 15 the correct direct current component.
Emitter electrode, base electrode and collector electrode, so when the signal level at the grid 17 at the beginning denotes trode. However, it should be noted that because of an interval y is greater than the voltage applied to the voltage of the two possible current directions between the divider 47, the emitter electrode and the collector electrode discharge the loading capacitor 13 via the collector electrode and drawing the electrode 31 as emitter electrode and 15 transmitting electrode of transistor 20 until the potential of electrode 35 as a collector electrode is arbitrary. The collector electrode 47 has reached the voltage value at the voltage in the circuit according to FIG. 1 at the grid 17. But if the signal level trode 35 connected directly to the grid 17 of the tube 15 on the grid 17 at the beginning of an interval y lower, the cathode 19 of which is grounded. This is as the voltage at the voltage divider, the emitter electrode 31 of the transistor 20 flows is adjustable 20 via the transistor a charging current, ie a current connected to a reference voltage, z. B. by means of in the opposite direction, until the voltage of a voltage divider 47 which is reached between earth and that is equal again. When the key pulse is terminated, a negative point returns. The base electrode 33 on the transistor, which is again in the reverse direction, is connected to ground via a resistor 45. Between the bias voltage lying back and the current path electrodes 33 and 31 there is thus a bias voltage 25 between its transmitting electrode and its collector in the so-called reverse direction, which the electrode is thus interrupted again, so that the current path between the emitter electrode and the charge on the capacitor 13 temporarily cannot change the collector electrode of transistor 20 normally. Because the waveform locks between the intervals y. changes, the capacitor 13 is therefore continuously on, but if a probe pulse 42 of negative 30 is charged or discharged, so that the grid 17 always reaches polarity from the source 41 via the capacitor 43 to the fixed level set on the voltage divider 47 to the base electrode 33 , is this preload remains.

It can be desirable, but is not created in the inward direction between 33 and 31 , which requires that transistor 20 be symmetrical in that current path between the emitter electrode and the 33 sense that its current voltage Collector electrode of transistor 20 for the duration characteristics for both current directions exactly the same as the pulse 42 opens. Run between the emitter electrode. This condition is not met for all surfaces 31 and earth a shunt capacitor 46 to the transistors, but many transistors represent the left part of the voltage divider 47 for a current direction a noticeably greater resistance than for a negative feedback between the circuits 40 to avoid the reverse current direction, 33-31 and the circles 35-31 and that for given bias voltages.
Reintroduction process for the direct current component Although many factors for the lack of a component independent of amplitude fluctuations can determine such characteristic symmetry, but to make the probe pulses. As noted above, if the two outer p-regions are the same, the probe pulses 42 should occur synchronously with a horizontally displaced 45 and if the two barrier layers are of the same size, running part of the signal curve 12, e.g. B. to the synchronization pulses present a sufficient symmetry of the characteristic curves or to which this Im- be in order to be able to consider the transistor as a symmetrical tranpulse subsequent part of the base pulses during sistor. It is true that with one of the interval x. In television, it is indeed an unsymmetrical circuit according to the invention to make the keying during the last-mentioned part 50 Irish transistor, the direct current component below the base pulses, but for the purpose of re-introducing circumstances correctly, the explanation in the following is assumed that The advantage of the circuit and the greatest accuracy. Since it is also useful, the approximately symmetrical transistor is fully achieved.
Not to allow keying pulses extend beyond the intended interval of 55 One application of the invention in a television signal receiver to erroneous settings is shown in Fig. 2 of the drawing, to avoid Assume also that the this includes a conventional receiver section 51, in Probe pulses only extend over the part y within which a received television carrier wave amplified interval χ should extend. and is demodulated. This so-called receive-During each interval y the current path is part of 60 can contain a carrier frequency amplifier, a Freder emitter electrode to the collector electrode by means of a quenzwandler and a signal detector, so a pulse 42 is opened and is then opened by one of the video signals and synchronizing and base currents flow through a certain direction, where pulses are obtained from the carrier wave. If this direction of current depends on the polarity, the chip-dwelling video amplifier 53 amplifies the difference in frequency between the signal level at the grating 17 65 frequency composite signal,
and between the reference potential or the einzu- The video amplifier 53 is dependent on a picture display drying divider 47 via the capacitor alternate the voltage level at the tapping point of the chip 13 to the input electrode 57th If the DC component 55 were connected, which would have a Braun component at the output of the source 11 , tube with a deflection yoke 69 and a cathode 59, the signal 12 would be at the grid 17 during each inter 70. Further, to the amplifier 53 a Im-

Claims (7)

7 8 Pulse separator 61 connected, with which in the usual device can be used for signals of any polarity Mode the sync pulses from the video signal and are, i. H. also in stages in which the synchronicity of each other be separated. The separated synchronization pulses will run in the negative direction as in FIG. 2. Further Line deflection generator 63 and the vertical deflection 5 can especially when using a symmetrical generator 67 supplied. These also work in the corrected transistor in the sense explained above The usual way and provide saw teeth for the deflection signal of tactile pulses are kept completely free. yoke 69 of the tube 55. Fig. 3 shows that also transistors of the η-μ-η-Likewise As in Fig. 1, a transistor 20 of one type is used for the purposes of the invention Emitter electrode 31, a base electrode 33 and an io can. 3 includes a transistor 70 having two Collector electrode 35 present. The emitter electrode zones 71 and 75, between which a p zone 73 trode is again at negative voltage, for example, the barrier layers with 77 and 79 denoting at the tap of a voltage divider 47, which are net. The emitter electrode 81, the base electrode on the one hand to earth and on the other hand to a fixed negative 83 and the collector electrode 85 form with the positive Potential is connected. A shunted area with ohmic contacts without a DC capacitor 46 can again be between the emitter func- tion. electrode 31 and earth are switched on. If one uses the npn transistor instead of the pnp collector electrode 35 on the grid 57, ie on the transistor in FIG. 2, the collector 85 becomes the brightness control electrode of the tube 55. The 59 is grounded. The base electrode 33 is again over 20, the emitter electrode 81 is at a point of an adjusting resistor 45 to earth, barem negative potential, for example at the tap point the emitter-fixed negative voltage is switched on. As with electrode 31, FIGS. 1 and 2 lying in the reverse direction, a shunt capacitor 46 can normally be switched between bias voltage, which see the current path between emitter electrode 81 and ground electrode and collector electrode. A bolt effective in the reverse direction. However, if a negative pulse 62 at the bias voltage between the base electrode 83 and the terminal H of the line deflection generator 63 via the emitter electrode 81 is reached by connecting the base capacitor 43 to the base electrode, this electrode is canceled through the resistor 45 to the negative reverse voltage and for the duration of this 30 end of the voltage divider 47 is established. In order to overcome this bias voltage lying in the forward direction and the reverse direction between these two electrodes hergeodically and the current path over the, so that the transistor 20 for the duration of this emitter electrode and collector electrode temporarily to pulse between the transmitter electrode and Collector close, the tactile impulses 62.4, which can carry current from the electrode in both directions. 35 Terminal H ' via the capacitor 43 to the base-in of the circuit according to FIG. z. B. the line deflection generator 63 obtained pulses. The pulse pulses 62.4 can also be from the. Delay circuits and retrace pulses of the line deflection generator 63 may be required in order to set the im- 40 and put them at a desired point of the pulse 62 at exactly the right point within the signal 54. To allow interval λγ to occur. Thus, for example, the mode of operation of the npn transistor in a key pulse 62 at a certain point of the black circuit according to FIG. If wise of the pnp transistor described above. Thus, one decides to this mode of operation, occurs on 45, when the base pulse 54 c occurs at the grid 57, grid 57 of the tube 55 the key pulse always synchronously through a key pulse 62 A of the transistor 70 in a to this level 54 c on and makes brought the transistor 20 J _n both current directions conductive state, current-permeable. If there is a potential difference between If the signal level on grid 57 differs from the reference signal level on grid 57 and the voltage on emitter electrode 81, voltage flows at the sliding contact of resistor 47, 50 via the emitter electrode and the collector electrode becomes capacitor 13 either further charged the transistor 70 a current in the correct direction or further discharged, so that the grid 57 comes to the device, which the charge on the capacitor 13 ver reference voltage level. So it will then change and bring the grating 57 to the reference level. Brightness of the picture elements on the screen of the tube When the key pulse 62 ^ 4 is over, between 55 including its direct current component is correctly 55 of the base electrode and the emitter electrode of the Tran, since the charge of the capacitor 70 is again a reverse direction during the transmission of the next following kende bias, and the current path between the line is maintained. The emitter electrode and the collector electrode is interrupted again, so that the capacitor 13 retains its reintroduction of the direct current component, the 60 charge until the next key pulse. z. B. lost in an AC amplifier- may have gone are obvious. Claims are made: namely, an almost distortion-free and noise-free 1. sensing circuit arrangement for re-insertion insensitivity Reintroduction with a very strong reduction in the direct current component in the case of pulse multiples Circuit achieved that mix only one transistor 65 by means of a flat transistor, there- and only requires strobe pulses of one polarity, characterized in that the transistor is used as a and the pulse amplitude can be compared to the bidirectional current-permeable switch Maximum amplitude of the corrected signal must be small. in the grid circle of the intended for reintroduction Reference voltage can be arranged by changing the th tube stage so that through Easily adjust the potential at the emitter 31. The switching pulses of the 70 the base electrode Current path between emitter and collector is closed only for the duty cycle, and that the current path is used to charge or discharge a capacitor in the grid circuit, such that the grid potential is brought to the reference voltage level during the duty cycle. 2. Circuit arrangement according to claim 1, characterized in that the direct current component at the control grid a vacuum tube is reintroduced, which is capacitive to the output terminal a previous stage is coupled. 3. Circuit arrangement according to claim 1, characterized in that the DC compo- 10 component is reintroduced at the control grid of the cathode ray tube of a television receiver, to which the video signal is supplied, and that the reference voltage corresponds to the black level of the transmitted Corresponds to the image. 4. Circuit arrangement according to claim 3, characterized in that the video signal is periodic Contains interruptions and that the periodic key pulse only part of this interruption interval occupies. 5. Circuit arrangement according to one of the preceding claims, characterized by a Bridging capacitor for the reference voltage source. Hi> r to 1 sheet of drawings © 909 639/219 10.59