DE874030C - Modulation circuit - Google Patents

Description

The invention relates to a modulation circuit and is particularly suitable for use in radio frequency transmission circuits such as she z. B. in radio transmission and «empire facilities be used.

Modulation or frequency transposing has so far generally been effected in that two alternating voltages of generally different frequencies, one or two different discharge tubes in symmetry circuit due to the non-linear mode of operation of the tubes, oscillation components arise whose frequency is equal to the Is the sum or the difference of the original frequencies. It is known that. the emission current of a Hot cathode tube essentially proportional to the 3/2-th power of the effective control voltage is when this voltage acts positively on the cathode and is zero when it is in the opposite direction Control voltage. This non-linear way of working causes distortions of the output vibrations, which is often annoying.

In practice, two main means have been resorted to in order to avoid these distortions to avoid. The first is applicable- when the tensions to be processed are only idein are; it consists in limiting the modulation to such a small range of the tube characteristics, that the part of this curve used can practically be regarded as parabolic, whereby the mathematical expression -for the emission current no essential terms of higher Contains order as a quadratic. This quadratic expression has three parts, one each

to the. Square - each individual voltage 'proportional and a part proportional to the ¹ product of the two voltages; the latter contains the components of the sum freedom and the difference frequency. In this way the distortion "can be substantially avoided, provided that the" components containing "the square of each" voltage can be filtered out, which is not always possible. The second means is suitable if the The voltages to be processed are high, and consists in firstly switching on a resistance in the anode circuit of the modulation tube, which is high in comparison with the internal anode resistance of the tube above. so that the working characteristic of the tube with the external resistance consists of a part in which the current is zero and another part, the course of which is mainly determined by the external resistance and which is consequently approximately linear.

Certain distortion components can also can be eliminated by using two tubes in a balun. It is suggested Instead of two tubes, a single tube with two anodes, two control electrodes and a common cathode was used. Tubes of this design are, however not particularly in use for modulation attitudes because (among other reasons) they have a relatively large control alternating voltage needed to distribute the en, tladuttigsstrom.es between the two anodes so that -a single tube of this type in was inferior to the mode of action of two separate thin-electrode tubes. In addition, this was Tubes do not completely eliminate distortion, because the control of the current distribution between the anodes that between the control electrodes effective tension was not proportional.

In another invention by the same inventor is an improved discharge tube having two Anodes described in which the current distribution · between the two anodes by relatively small voltages can be controlled and essentially proportional to the control voltage is. This tube contains a cathode, two anodes, placed close together and means for controlling power distribution; the electrodes are arranged so that the one running from the cathode to the anodes; Discharge broken down into several parallel partial discharges which! according to the. Course of the control voltage alternately from an anode - the other to be directed. With this arrangement of the tubular elements, one is relatively sufficient small change of the safety voltage to the Divert discharge from one anode to the other. Because of the small distance between the Anodes, the change in direction of the electron paths necessary for this is so small that the division of the The charge on the two anodes is essentially proportional to the controlling voltage; to the point where the discharge is completely diverted from one anode to the other. There are various arrangements of the tube elements are useful to achieve this effect. One Embodiment includes, for example, two control electrodes, which are like a two-thread Screw intermeshed and arranged coaxially to the cathode, either being the same or can have unequal distances from the cathode; furthermore there are two very similar ones Anodes are present, which are also two intertwined or shot through Form screw grids and surround the control electrodes; they have the same pitch like the control grid electrodes. If with this arrangement the corresponding turns of the anodes and the control electrodes are opposite one another, i.e. if they lie within a common helical surface developed around the cathode, the discharge can be seen Think of divided into several parallel currents, which correspond to the changes in the electrostatic Field between the control electrodes. deflected from one anode to the other and vice versa will. In addition, the total emission can be controlled by a second voltage that between the cathode and both control electrodes is applied in the same direction.

In another embodiment of the tube, the total emission is controlled by an additional electrode, and the control electrodes wound with one another only effect the deflection of the discharge currents from one anode to the other. In a further embodiment of the tube, only one control electrode is provided for controlling the emission; the deflection control _loo is effected by an electromagnetic field which is generated by a control coil which is attached outside the tube and coaxial with the tube electrodes.

The subject of the invention is a modulation circuit, in which a tube with the features just described is used and which the modulation, 'one frequency with another frequency with extremely low distortion enables.

This is achieved in the invention by that two electrical oscillations of the same or different frequency on the control means of the So act on the tube that an oscillation reduces the total electron emission of the cathode and the another oscillation deflecting the discharge now onto one anode, now onto the other controls. In this way one voltage of one frequency can be replaced by the voltage of another Frequency to be modulated; the resulting voltage of the sum or difference frequency can be filtered out. The relationship between the deflection voltage and the resulting current distribution between the two anodes is within a favorable,. fairly wide amplitude ranges the deflection voltage essentially

linear, as long as there is not a complete deflection of the discharge on one of the two anodes is. The total emission should not be influenced by the distraction control, because this would create distortions.

For the modulation circuit according to the invention many different embodiments are possible. When using the tube with the two shot through helical control electrodes can direct one of the alternating voltages are switched on between the two control electrodes, so that the deflection according to the Frequency of this voltage is controlled, and the other alternating voltage can be between the two Control electrodes on the one hand and the cathode on the other hand are switched on, so that thereby the total emission is varied with the frequency of the second voltage. Steer this way Both voltages the current in the circuit between the two anodes, and there is a modulation one voltage through the other, so that components of the superposition frequencies arise, which can be screened out through a filter. When a tube with unbalanced Control electrodes or anodes are used is, the circuit elements can be dimensioned so that a symmetry of the Deflection control is ensured so that the deflection voltage does not affect the overall emission; the general circuit remains the same. In the embodiment with magnetic deflection control one of the control voltages is used to generate the change in this field.

In Figs. 1, 2 and 3 is an embodiment of the discharge tube according to the mentioned invention. It contains several electrodes, ■ which by a pinch foot or in any other way can be kept. The vacuum vessel is not shown in the figures.

The electrodes consist of a cathode 2 (indirectly or directly heated), two control electrodes (Grid) 3 and 4, which surround the cathode, and two anodes 5 and 6, which are the control electrodes surround, and a screen 7 which surrounds the anodes 5 and 6. In the illustrated embodiment the control electrodes 3 and 4 are in the form of interleaved or intermingled Bolts built which are coaxial to and equidistant from the cylindrical Cathode 2 are arranged. The anodes 5 and 6 are constructed in a similar manner; they form shot through Screws which have the same pitch and the same winding direction as the control electrodes; they are arranged coaxially with respect to the cathode 2 and surround the control electrodes 3 and 4.

Any holder means can be used for the electrode assembly, if they only have the necessary rigidity to keep the electrodes immovable in their mutual position to hold on. In the present case, four metallic rods S, 9, 10 and 11 are used as holders for the anodes 5 'and 6 are provided and also j insulating supports 12, which at their edges with

[Depressions are provided in which the turns of the anodes and the control electrodes engage, so that they are kept at the correct distance from each other will.

The metal rods 8 and 9 can with the turns of the anode 5 on opposite sides Points of each turn to be welded; they are opposite the turns of the anode 6 with Cutouts 13 are provided so that there is no electrical connection between the two anodes. The metallic rods 10 and 11 be welded to the anode 6 and have cutouts 13 to prevent electrical Connection between the two anodes. The shield 7 can be provided with recesses 14 be to adapt their shape to the four supports 8 to 11 and an even spacing of the Ensure shielding from the anodes. The position of the electrodes to each other is on can best be seen from the longitudinal sectional view according to FIG. You can see that the turns of the one control electrode and the turns of one anode lie in the same right-hand helical surface

! and therefore all face each other. Accordingly, the cut surfaces of the control electrode lie 3 and the anode 5 on a common Senki-real to the cathode 2. The Cut surfaces of the electrode 4 and the anode 6 on a common perpendicular to the cathode 2. With this electrode arrangement, the two control electrodes cause the discharge to be divided into several parallel partial flows. This notion is made easier if you look at every turn the anodes and control electrodes on their own as part of the corresponding whole electrode considered, whereby the individual parts or turns are connected at their ends. The discharge takes place within two intertwined Very screw bodies, two of which are essentially perpendicular to the cathode Helical surfaces are included and between each two adjacent control grid turns pass through the two-start winding. The strength of the emission leann through the simultaneous action of both control electrodes can be controlled.-When the ■ instantaneous potentials the electrodes 3 and 4 are the same with respect to the cathode 2 and are changed to the same extent, for example by applying the same periodic alternating voltage to both electrodes, see above the emission and thus the size of the current flowing through the anodes 5 and 6 accordingly the course of the alternating voltage changed. Furthermore, the direction of the discharges can be controlled by changing the electrostatic field between electrodes 3 and 4. When the electrode 3 is made alternately more negative and more positive with respect to the cathode 2 is called the electrode 4, so that the electrostatic field between the two electrodes changed, the electrons are alternately on one and then on the other

Directed anode. If an alternating voltage is applied between the control electrodes 3 and 4, the electron flow is alternately directed from one anode to the other. It 'should not be overlooked werdien of course, that the division' of the discharge on the anodes to a certain extent also be influenced ¹ -through the potentials at the anodes. If the anode 5 is more positive with respect to the cathode 2 than the anode 6, more electrons are drawn to the anode 5 than to the anode 6 and vice versa. Such differences in the anode potentials, however, have less of an influence; on the current distribution as differences of the control grid potentials because the anodes a greater Absitand _of: the cathode have emerged as the Steuierelektroden.

It can be understood that the electrons passing between the anodes 5 and 6 withdrawn at least in part to the anodes will; However, some can also use the shield-7 reach when the potential of the shield is not negative enough to generate the Bit rate of the electrons up to Brake zero. Therefore, the shield 7 can conveniently be placed on one opposite to the other Cathode 2 can be kept slightly negative potential, in order 'thereby the electrons to the anodes to drive back. If .the exit velocity of the electrons is sufficiently small, the negative bias voltage can also be omitted and the Shield 7 'can be connected directly to cathode 2.

The shield 7 surrounding the anodes 5 and 6 served a threefold purpose. Firstly, it prevents the electrons passing between the anodes from collecting on the inner surface of the vacuum vessel and thereby forming an undesirable electrostatic charge. Second, it reduces the secondary emission from the currently less positive anode to the more positive anode, and thirdly, it acts as an electrostatic screen ¹ to reduce the capacitive coupling between the input circuit and the output circuit. It is particularly effective in reducing the capacitive coupling between the two control electrodes on the one hand and the two anodes on the other. In order to further reduce the secondary emission from one anode to the other and the capacitance between the electrodes, the. Shield 7 may be provided with inwardly directed helical fins which engage between the two anodes. When the shield is connected to the cathode, these fins essentially have the effect of a trap, as is the case in common pentode tubes; is used.

4 shows an embodiment of the modulation circuit according to the invention which contains a tube with the construction features described. The input electrodes 3 and 4 are connected to the secondary coil 17 of a transformer 18, to whose primary coil 19 an alternating voltage of the frequency f _{t is} fed. The center point 20 of the secondary winding 17 _: is connected to the cathode via a shunt capacitor 21 and the secondary coil 22 of a transformer 23. The primary coil 24 of the transformer 23 is supplied with an alternating voltage of the frequency / ₂ . To the control electrode !! 3 and 4 to a suitable negative bias with respect to the cathode 2; a bias voltage source can be switched on between terminals 25 and 26; the negative pole of this voltage source is to be connected to terminal 2 5. The anodes 5 and 6 are connected to the input terminals of a filter 28. The circles between the anodes 5 and 6 and the cathode 2 contain an anode voltage source -j- B, which is bridged by a shunt capacitor 27.

It can be seen that the voltage of frequency / _{2 is} simultaneously applied to both control electrodes 3 and 4, so that the mean value of the instantaneous potentials of both electrodes with respect to cathode 2 is changed as a result. Therefore, the size of the emission is controlled in accordance with the profile of the alternating voltage applied to the terminals of the primary coil 20. As already explained above, the control electrodes split the total discharge into several parallel partial discharges, which pass to the anodes under the influence of the positive anode potential. These deep discharge currents are now directed alternately to one and the other anode by the influence of the electrostatic field between the control electrodes 3 and 4 according to the course of the alternating voltage supplied to the primary winding ro. If, for example, during one half cycle of the voltage of the transformer 18 the polarity of the electrostatic field between the control electrodes 3 and 4 causes the discharge to be deflected onto the anode S, the discharge will be deflected onto the anode 6 during the other half cycle. In this way, the current emitted by the cathode 2 flows alternately through one and the other anode with a periodicity that varies through! the frequency of the voltage supplied to the transformer 18 is determined. At the same time, the size of this anode current is controlled by changing the emission intensity in accordance with the voltage supplied to the input terminals of the transformer 23. At the input impedance of the filter 28, the anode currents form between the anodes 5 and 6 a little boitentialdiffierenz, which contains a frequency f _t modulated with a frequency / ₂ . The result is the generation of two potential differences whose frequencies are equal to J ₁ - \ ~ / ₂ and f _t - / ₂ . The filter 28 can be dimensioned in such a way that it only transmits a voltage of one frequency component. As a result of the symmetry of the arrangement, no voltage dej frequency / _{2 is} generated between the anodes.

It is known that the self-capacitance between the anode and the control electrode of a tube is a Coupling · between the input circuit and the output circuit, which is often very annoying and which usually by the use of a screen grid between the control electrode and the anode can be made negligibly small. In the embodiment described above the invention, this is unnecessary insofar as couplings between the input and output circuit be considered because the circuit almost completely neutralizes itself. this is because, to a certain extent, each control electrode is the other control electrode and each anode is the shields other anodes and that the anodes have almost the same capacities (with opposite Effects) compared to the control electrodes and the control electrodes almost the same capacities opposite to the anodes.

In Fig. 5, an embodiment of the invention is shown, which depending on the setting of the Circuit elements both as an oscillator modulator for a superheterodyne receiver as well as Oscillator detector can be used in a homodyne receiver. The circuit is different 4 in that the second alternating voltage by feedback in a tunable resonance circuit is generated in the circuit itself. The circuit contains a transformer 29, on whose primary coil 30 the modulated carrier frequency oscillations from a previous one Part of the receiver are fed; by the secondary coil31 these Vibrations the control electrodes 3 and 4 are pressed in phase opposition. The anode circle contains the Primary coil 33 of a transformer 32, which is connected between the two anodes 5 and 6; the primary coil 33 is bridged by two shunt capacitors 34 and 35 connected in series.

The total emission of the cathode 2 is controlled by the voltage of a resonance circuit 36, which contains an inductor 37 and a tuning capacitor 38. The circle is between the two Control electrodes 3 and 4 on the one hand and the cathode 2 on the other hand via the capacitor 39 and the two parts of the secondary coil 31 switched on. In order to generate a continuous oscillation of its resonance frequency in the resonance circuit 36, a feedback is provided, which is formed by a coil 40 connected to the inductance 37 of the oscillation circuit is coupled.

If the oscillator modulator circuit of FIG. 5 is used as a transpose stage in a superheterodyne receiver is to be used, the primary coil 30 can be connected to the output circuit of the preceding High frequency amplifier stage connected so that between the control electrodes 3 and 4 the received modulated high-frequency carrier voltage is impressed. This tension causes the deflection of the discharge currents alternately on the two anodes 5 and 6 and thereby generated a change in the anode current distribution according to the frequency of the incoming carrier. The anode circuit is symmetrical with respect to the cathode 2 so that the carrier frequency components compensate each other in their effect in the turn 33 and not a component of the Carrier frequency voltage occurs between the center point 41 and the cathode 2. The sum of the Both anode currents flows through the coil 40 and induces a voltage in the resonance circuit 36. This circuit can by means of the variable capacitor 38 to a resonance frequency above or below the received carrier frequency. The one generated at the circle 36 AC voltage is fed to the control electrodes 3 and 4 in phase, so that in the already described Way the total emission is controlled. These changes in total emission modulate that produced by the deflection control Alternating current, so that superimposed frequencies arise in the anode current which are the same the sum and the difference of the original frequencies. One recognizes that the alternating component of the current in the coil 40 contains only the oscillator frequency, which is generated by the resonance circuit 36 is determined. By matching the circles coupled to the coil 33 to the desired one Beat frequency, which at a superimposition temp is more than the intermediate frequency modulated with the low frequency oscillations, is only this selected beat frequency passed to the subsequent parts of the receiver.

By means of the capacitor 38 in FIG. 5, the circuit 36 can also be tuned to the carrier frequency of the received oscillations, so that the mode of operation of a homodyne receiver is achieved.

In Fig. 6 an oscillator modulator is shown which allows a high frequency voltage to be modulated with a low frequency and is particularly useful for laboratory purposes. The circuit has a tunable high-frequency resonance circuit 45 which, in parallel, contains an inductance 46 and a variable capacitor 47 and a tunable low-frequency resonance circuit 48 with an inductance 49 and a variable capacitor 50. The resonance circuit 45 is connected between the control electrodes 3 and 4 and with one between the anodes 5 and 6 lying inductance 51 coupled. The circuit 48 is switched on between the two control electrodes on the one hand and the cathode 2 on the other hand and is coupled to the coil 52, which is connected to the center point 53 of the coil 51; it lies in the common part of the two anode circles. The anode circuit also includes an anode voltage source - \ - B connected to one end of the coil 52 and bridged by a capacitor 54. The two control electrodes can be provided with a suitable bias voltage with respect to the cathode by applying a voltage between the terminals 55 and 56, which are bridged by a shunt capacitor 57.

. Using the circuit shown in FIG becomes; the two frequency-determining circles 45 and 48 vibrational energy through the couplings : fed back between the "coils 46 and 51 as well as 49 'and 52, so that the two resonance circles in. continuous vibration can be obtained. In this way, .high-frequency alternating voltage, corresponding to the resonance frequency of the circuit 45 between the two control electrodes 3 and 4 generated, whereby- the distraction, the .: discharge alternately to one and then to the other

- ■■ anode is initiated. At the same time: between both. .Control electrodes 3 and 4 / on the one hand, and the Cathode 2, on the other hand, a low-frequency voltage effective at the resonance circuit 48, which increases the overall emission to the Arioderi. controls. Accordingly, the current in coil 51 contains one High frequency component that has a low frequency is modulated. '. : ■

Instead of two symmetrical with respect to the cathode 2 arranged anodes can also be used for the shielding, which the other elements surrounding the tube can be used as an anode. Such. Tube is shown in Figure 7; ; the metal cylinder 7 5 can be connected as an anode will. Otherwise it is. Construction of the tube shown in this figure identical to that in Fig. -1, ,. The use of the shield in place of the one-screw-shaped anode changes the mode of operation . of the tube., not essential; due to the deflection control, the electrons hit alternately the surface / of one and then the other anode (5 and 75) in the same way as it has been described so far. One ... can therefore do this Tube in each of the described modulation circuits use without major changes. However, under certain circumstances it can be advantageous to use the Circuit according to FIG. 8 - to be used; it corresponds to that according to FIG. 4 with the difference that only the Anode 75 is connected directly to the output circuit ;: the anode 5 is on a fixed positive potential, which, over the. Terminal76 is created. Here, the anode 5 acts as a screen grid between the control electrodes 3 and 4 on the one hand and the single anode 75 on the other hand. The positive potential applied to the electrode 5 is im generally lower than that of the anode 7 5.

• In Fig. 9 there is a further modification of the one to be used Tube shown, with weigher the windings the helical. Control electrodes to each other stand on gap "; the turns of the one. control electrode. are in fact in a larger one. Distance from ·., The cathode arranged than that of the others. Control electrode. Accordingly is. the control electrode 4 is a larger diameter solenoid ials the solenoid of electrode 3.

- ■ - -,. The asymmetry of the tube structure changes the fundamental effect of the deflection control not; it. but is 'advantageous' an asymmetrical one. Input circle between these two Sieuerelectroden • to use .. Such an unbalanced switch-

· -.- tujig, is. in..Fig-10. shown; it is the circuit, similar to FIG. 4, but with the; Difference is that the secondary ptue of the transformer 18 is divided into two parts J ¹ J and 78 with an unequal number of turns. The coil 77 having a larger number of turns is connected to the control electrode 4 further away from the cathode 2, and the part 78 having a smaller number of turns is connected to the control electrode 3 which is closer to the cathode 2. The operation of this circuit is essentially the same as that of the circuit of FIG. 4; the ratio of the number of turns of 77 and 78 is to be selected so that the changes in the control grid potentials, which are fed via the Transferma tor 18; do not have any effect on the overall emission. Furthermore, the ratios of the number of turns in the Kopp-! By means of transformers 18 and 23 it is dimensioned so that the voltage used to control the total emission does not cause any deflection of the discharge currents. For reasons of simplicity, only the control electrode 3, which is closest to the cathode, is used for emission control; The secondary part 22 of the transfermator 23 lies in its circle.

In the tube according to FIG. 11, the anode 6 is omitted; the cylindrical electrode 75 acts as a second anode, as it is in connection with FIG. 7 has been described; the arrangement of the control electrodes is asymmetrical as in FIG. 9. A tube _{: of} this type can be used in an asymmetrical modulation circuit as _: it is shown in FIG. A voltage of frequency J ₁ is supplied by means of a transformer 81 in order to control the deflection of the discharge currents onto the two anodes 5 and 75. The Tnansformatoa: 81 contains two secondary coils 82 and 83 which are connected in series between the control electrodes 3 and 4 via the coupling capacitor 84. A voltage of frequency / ₂ is applied to electrodes 3 and 4 in phase, thereby controlling the total emission. The supply of / ₂ takes place via the transformer 85, which has a primary coil 86 and two secondary coils 87 and 88. The output circuit between the anodes 5 and 75 and the cathode 2 contains the primary coil of a transformer 89, to which the positive terminal of an anode voltage source -j- B is connected via a tap 90.

The. Operation of the circuit according to FIG. 12 is similar to that of FIG. 4; the proportions of the number of turns are chosen so that the asymmetry due to the asymmetrical arrangement of the control electrodes ^ and 4 and the anodes 5 and 75 is compensated. In both cases the number of turns of the transformers is determined in such a way that the voltage of the frequency Z ₁ does not influence the electron emission and the voltage of the frequency / ₂ does not appear between the anodes S and 75. . 13 shows a further modification of the tube used, in which two further electrodes, namely a helical screen grid 91 and a helical catch grid 92, are provided in addition to the elements a described in FIG. -are. A modulation circuit

with such a tube is shown in FIG. File is the capture grid 92 inside the tube with the cathode 2 and the screen grid with the positive terminal of a voltage source connected, so that the latter grid on a slightly lower positive potential is held than the anodes 5 and 75. The operation of this circuit is essentially the same as with the circuits already described. One into the individual a detailed description therefore appears unnecessary.

In the tube according to Fig. 15 the metal cylinder / S acts as an anode, and the helical electrode 93 acts as a screen grid. It is also a helical catch grid 94 is provided, which between the electrode 93 and the anode 75 lies. The use of this tube in a modulation circuit is shown in Fig. 16, which differs from the circuit shown in FIG only differs in that a single anode is used; the screen grid is through the electrode 93 is formed, and the electrode 94 is connected to the cathode 2 as a catching grid.

In the tube shown in Fig. 17 there is an additional Control electrode 95 between the cathode 2 and the intermingled helical Control electrodes 3 and 4 are provided. With this electrode, one of the control electrodes 3 ■ and 4 Independent control of the emission effected and the control electrodes 3 and 4 act solely to deflect the discharge currents. One Circuit with the tube according to FIG. 17 is in FIG. 18 shown; it can be seen that in this figure one terminal of the coil 17 with the additional electrode 95 is connected to electrodes 3 and 4 instead.

In the embodiments of the modulation circuit described so far, the deflection voltage and the emission control voltage is impressed on the control electrodes separately from the anodes.

One or both of these voltages can now be applied to the anodes. As an example, a tube is shown in FIG. 19 which contains the anodes 5 and 6, the cathode 2 and a targeting electrode 96 for controlling the electron emission on the emission control like a normal thin-electrode tube, while with respect to the deflection control it acts in the manner of a rectifier; the deflection voltage is impressed between the anodes. A corresponding modulation circuit is shown in Fig. 20; the anodes 5 and 6 are via the block capacitors the fed on its primary coil, a current of the frequency ^ connected 97 and 98 to the secondary part of a transformer 99. the resulting deflection of the Entladunigsströme from an anode to the other of generating a stream of the frequency Z ₁ is equivalent to that between the anodes and flows via the secondary part of the transformer 99. A transformer 100 can now lead to an S Voltage of the frequency / ₂ are fed to the Elektrodego, so that the emission is _{controlled with the frequency / 2} , whereby the resistance between the anodes 5 and 6 is changed with this frequency / ₂ . It follows that between the anodes 5 and 6, potential differences of such frequencies arise which are equal to _{the sum and the difference of the original frequencies Z 1} and / _2.

In the arrangement shown in FIG. 20 it is assumed that only the difference frequency is to be used and that this frequency is considerably lower than Z ₁ , so that it can be kept away from the input circuit by the capacitors 97 and 98.

FIG. 21 shows a circuit in which the emission control voltage "is applied to the two anodes 5 and 6 and the deflection control voltage is applied to the two control electrodes 3 and 4. The circuit differs from that of FIG. 4 only in that the emission control voltage of the Frequency / _{2 is} pressed onto the anodes instead of the control electrodes. For this purpose, a transformer 102 with a secondary coil 103 is provided, which lies between the anodes 5 and 6 on the one hand and the cathode 2 on the other hand. In this circuit, the modulation in the anode circuit is carried out in the manner of Heising modulation causes.

In the circuit of Fig. 22, the control electrodes 3 and 4 are omitted; Both control voltages are fed to the anodes 5 and 6. The circuit is similar to that of FIG. 20, but the transformer 100 is omitted and replaced by a transformer 104, by means of which the voltage of frequency / _{2 is applied} between the anodes 5 and 6 on the one hand and the cathode 2 on the other hand. The transformer 104 has a primary coil 105, _{through which the current of frequency / 2} flows, and a secondary coil 106, which is connected between the center point 107 of the secondary coil of the transformer 99 and the cathode 2 via the capacitor 108. The anodes can be symmetrically arranged as shown, or the outer shield can be used as an anode, eliminating one of the intermingled anodes. As in FIG. 20, the deflection of the discharge from one anode to the other is _{controlled by the voltage of frequency / x} impressed by the transformer 99 between the anodes. In addition, the emission is controlled by the voltage of the frequency / ₂ , which is applied between the two anodes on the one hand and the cathode on the other hand via the transformer 104. As in the circuit of FIG. 20, the input and output circuits are connected in parallel.

The circuit shown in Fig. 23 operates in a similar manner like that of Fig. 22, but the input and output circuits are connected in series instead of in parallel. This arrangement can sometimes be more advantageous. Another difference is that the Tube is unbalanced; one anode 5 is in the form of a grid, and the other anode 75 is in the form of a shield or plate outside the grid similar to the anodes of FIG and 11. The. The tube is therefore essentially an ordinary triode, but the circuit is very vet * - differentiated from the usual modulation

in which common triodes are used. The input circuit corresponds to that of FIGS. 12, and. identical reference symbols are used for elements that correspond to one another. The deflection voltage of frequency f _x is impressed between the anodes 5 and 7 5 by the secondary coils 82 and 83 of the transformer 81; these coils have no such. Ratio of the number of turns so that the deflection voltage does not affect the emission. The emission voltage of frequency / ₂ is between the anodes 5 and 75 on the one hand and the cathode 2 on the other hand via the secondary coils 87 and 8.8. of the transformer 8 5 pressed. . So far, the effect of deflection control using control electrodes has been described, the deflection being caused by the effect of the electrostatic field between the control electrodes; the desired deflection of the discharge currents can also be produced by the action of a variable magnetic field. In Fig. 24 is a tube with a. Cathode. 109 shown, which are a number of axially directed. Contains rods 110 which are connected to one another within the tube and in this way form a control electrode which is concentric to the cathode. There are also a number of axially directed anode rods 111: of which, if they are numbered consecutively, those with even ordinal numbers and those with odd ordinal numbers are joined together so that they form two interlocking or interleaved anodes. The number of control grid bars is half the number of anode bars; each control grid bar faces the passage between two anode bars. A shield 112 surrounds the electrodes, which are all accommodated by an evacuated vessel 1.13. In order to avoid eddy currents in the shield as much as possible, a gap 112 'is provided therein the envelope is arranged and is excited by a suitable control current.

: A modulation circuit including the tube shown in FIG. 24 is shown in FIG. An alternating voltage of frequency / _x is supplied to coil 114, and a second alternating voltage of frequency / ₂ is applied to emission control electrode 115 via transformer 116. The two anodes 119 and 120 are connected to an output circuit which contains the input tube of the filter 121 and an anode distribution source. During operation, the emission from the cathode 109 to the anodes is controlled in accordance with the frequency / _{2 by the} spajinung on the control electrode 115. In addition, the discharge is alternately directed to one and then to the other anode by the alternating magnetic field. The modulation circuits described are particularly useful for three scenarios, namely for modulation. a transmitter, for modulation in order to generate the intermediate frequency in a superhetenodyne receiver and for demodulation in a receiver. In these applications, a voltage of a single monochromatic frequency is to be combined with a frequency band. The benefit of lower distortion is generally better achieved when the signal voltage is used for deflection control and the mionochromatic frequency is used for emission control. If a symmetrical tube as in FIG. 4 is used as a modulator device in a transmitter and the signal voltage (low frequency) is used for deflection control, the carrier in the output circuit is canceled out. If, however, an unbalanced tube is used in a circuit according to Fig. 8: and the signal voltage is again used for deflection control _: normal amplitude modulation is obtained, the output current containing the carrier modulated by both sidebands.

In a superhierodyne receiver for amplitude-modulated carrier oscillations, the received oscillations can be used for deflection control and the local auxiliary oscillation can be used for emission control; The voltage of the receiving vibrations between the deflection electrodes should be sufficiently small to give ¹ is a linear modulation of the modulated carrier at all amplitudes. In a superheterodyne receiver for frequency-modulated characters, however, the receiving voltage used for deflection control can be so great that the discharge is completely deflected from one anode to the other, so that a limiting effect is created in this way.

In a demodulation circuit without local Homodyne vibration generation can use the complete receiving hand for deflection control and the Carrier voltage screened out via a sharply coordinated selection circuit for emission control be used.

In a homodyne demodulation circuit with local oscillation generation, the complete Receiving band serve to control the deflection, while the local oscillation the Emission controls.

The circuits described in the last two paragraphs result in linear D-emodulation and thus avoid those in non-linear detectors occurring distortions, including those of the square type. They are special to demodulation useful for single sideband reception, since even the common linear detectors are in this Distort the case if not the support component excessively with respect to the side hand components is great.

The modulation circuits described have a particular application in circuits for automatic tuning in superheterodyne receivers. The circuits are similar to the circuits described for reception demodulation, except that the voltage for emission control not in phase with the carrier component of the intermediate frequency voltage, 12g but is in quadrature with it. The grain

Ö74Ö3Ö

The combination of these voltages results in a direct voltage, which is normally zero, but which moves from zero in one direction or the other removed as the phase difference between the voltages moves away from the quadrature. A distinction must be made whether 'the Emission control voltage by sharp screening of the carrier or by a local homodyne oscillator is produced. Changed in the former case

ίο the phase difference just mentioned quickly, if the intermediate frequency moves away from the resonance frequency of the sharply tuned circle, and the The resulting DC voltage is used to control the frequency of the superheterodyne oscillator applicable in such a way that the intermediate frequency essentially coincides with the resonance frequency Coincidence is brought. In the latter case, the DC voltage obtained is applicable to the phase to control the heterodyne oscillator in such a way that the mentioned phase difference im is essentially squared.

Albeit in the various embodiments of the tube used described here If helical steward electrodes and anodes were assumed, it is clear that other shapes can be used as well. The electrodes can e.g. B. from shot through, coaxial rings, each ring lying in a plane and all rings

.30 of an electrode have the same diameter. Of course, each electrode must have the individual rings in this case be electrically connected to each other. In general, the form of the Rings or the cross section of the helical electrodes of any shape, such as. B. flattened or elliptical. The pairs of penetrated electrodes can also be coplanar Parts be built up, alternating a part of an electrode on the corresponding Part of the other electrode follows.

It should be noted that the terms interlocking and interleaving which appear in appear many times in the description to identify the relative position of the electrodes in are to be understood in their broadest sense, regardless of whether the individual electrode parts actually are at the same distance from the cathode. All that matters is that of the cathode Seen from the surfaces of the parts appear as if the parts of the two are interlocking Alternating electrodes next to each other. For example, the control electrodes even in the example of the game, they are seen as shot through, where they are different Have a diameter, but their turns are spaced apart from one another.

Even in the embodiment with only one helical anode, the surrounding The cylinder serves as a second anode, the effective surfaces of the cathode facing both anodes as being shot through or grasping mineandier be viewed as seen from the cathode in the spaces of the helical Anode visible TeBe of the cylindrical anode can be viewed exactly as lying a second helical anode formed from them in the interstices of the first helical Anode.

It is therefore clear that many modifications of the tube according to the invention are possible which all make use of the idea of the invention. The invention is therefore by no means based on the exemplary embodiments described are limited.

Claims (1)

Patent claims: 1. Using modulation circuit a tube with a cathode and at least two at positive voltage with respect to the cathode held electrodes, in which a Control of the current distribution to the two positively biased electrodes and as a function a second control variable, preferably control voltage, controls the strength of the two positive electrodes Total discharge takes place, characterized in that means, for example a the cathode surface partially covering (shadowing) grid, are provided to the discharge emanating from the cathode into several separate discharge bundles in this way to divide - that each bundle is a surface element an anode and at the same time one that is closely adjacent to it as seen from the cathode Surface element of the! Other anode can meet, whereby by changing the Discharge directions (deflection) the discharge beam according to the course of the first control units alternately mainly on the parts of the one and then on the parts the other anode fall and also a control of the passing to both anodes Total discharge takes place according to the course of the second control variable. 2. modulator circuit according to claim 1, characterized characterized in that one for dividing the discharge into several discharge bundles serving (shadowing) grid electrode and at least 'one of the anodes in relation to each other on 'the cathode as a source of radiation are similar, so that in one phase of the deflection control those through the gaps The discharge beam passing through the dividing electrode also essentially can pass through the interstices of this anode while in the other Phase this anode is hit by the discharge bundles. 3. Modulation circuit according to claim 2, characterized in that the other of the two Anodes is arranged in such a position to the other electrodes that they are on the Gaps of the silhouette-like anode falling discharge beam detected. 4. Mpdulation circuit according to claim 1 to 3, characterized in that the other than the anode similar to silhouette -. "existing anode is designed as a flat electrode and, viewed from the cathode, is arranged behind the anode similar to silhouette,
.5. Modulation circuit according to Claims 1 to 3, • characterized in that: both anodes are designed as grids, the rods or windings of which are staggered as seen from the cathode. 6. modulation circuit according to claim .1 to 3 and 5, characterized in that both ' Anodes are equidistant from the cathode, so that they interlock with their grid parts, i.e. that the rods or coils. of one electrode in the spaces between the : other lie. 7. modulation circuit according to claim 5 and 6, characterized in that the two interlocking anodes, as screw-type. grids are formed. ' : 8. Modulation circuit according to claim 5 to 7, ^ characterized in that the two interlocking- Anodes are twisted into one another in the manner of ζ reversible screws, whereby also At least one shadow-forming grid electrode as a screw grid, however, of your diameter - Is designed with the same slope. 9 .: modulation circuit according to claim 5 and 6, characterized in that the two interlocking anodes are made as a bar grid Rods or strips parallel to each other and to the cathode axis are constructed, with also at least one shadow-forming grid electrode as a similar bar grid at a smaller distance provided by the cathode. 10. modulation circuit according to claim 9,: 'characterized in that the rods of the interlocking Anodes are arranged on a cylinder lying coaxially to the cathode. 11. Modulation circuit according to claim 1 : and / or one of the subsequent ones, in particular according to claim 8, characterized in that: the - shadow-forming grid arrangement is divided into two grid electrodes.
12. modulation circuit according to claim 11, characterized in that: the two shadow. forming grid electrodes arranged in such a way are that their rods or turns are seen from the cathode on a gap.
13. Modulation circuit according to claim 11 and 12, characterized in that the two shadow-forming grid electrodes have the same distances from the cathode, so that they interlock, d. H. that the bars or, windings of one electrode in the intermediate.-'-: spaces of the other, lie. 14. Modulation circuit according to claim 11 and 12, characterized in that the shadow-forming Grid electrodes are designed as a screw grid. . - · 15 .: modulation circuit according to claim 1 . . -until. 14, - characterized by '^ - that the used Tube two gap-forming or interlocking shadow-forming grid electrodes and two from the cathode. see - behind, silhouetted similar, also contains gaps or interlocking grid-shaped anodes (Fig. 3). - 16. modulation circuit according to claim 15, 'characterized in that both the shadow-forming grid electrodes and them lattice-shaped anodes similar to shadow images with the same slope and in pairs according to Art two-start screws are formed * (Fig. 1). 17. Modulation circuit according to one of the speeches ι to 16, in particular claim 11, characterized characterized in that means are provided to provide a control alternating voltage of a frequency 'the two shadow-forming grid electrodes in phase opposition and a control alternating voltage of a second frequency at least one ^ but preferably both shadow-forming To feed grid electrodes in phase, and that the output circuit to one or both anodes is connected. ' 18. Modulation circuit according to one of claims ι to 16, in particular claim 9 and 1 o, characterized in that a control variable of a frequency of a coil is supplied, the magnetic ^ field lines penetrate the discharge space, and that a control voltage of a second frequency between the cable ^; Thode and the _Emission intensity controlling electrode preferably a shadow-forming mesh electrode is fed while the output circuit to one or both anodes is connected. 19. Modulation circuit according to claim 17 and 18, characterized in that the output circuit connected between the two anodes in a push-pull arrangement and to the desired Beat frequency is matched. 20. Modulation circuit according to one of claims ι to 19, characterized in that an expensive voltage to a control organ of the tube, preferably the organ for emission control, supplied via 'an' oscillating circuit is, and that from the circuit of an anode a feedback to this oscillating circuit is provided so that the control voltage of a frequency in the circuit itself is excited .. 21. Modulation circuit according to claim 1 to '20, characterized in that the asymmetrical position of the grid electrodes for the Deflection control the. voltage amplitudes supplied to them in phase opposition through corresponding Appropriate dimensioning of the "coupling means be chosen so different that due to the deflection voltages Influencing the emission control 'takes place. .22. Modulation circuit according to claim! to 21, characterized in that in the; used pipes besides the. to the. Abfenksteeu- ■ tion certain grid electrodes a special Electrode for. Emissions firing planned is, the AC voltage serving for emission control between the cathode and of these additional electrodes is applied while the deflection voltage · between the applied to both deflection electrodes. 23. Modulation circuit according to claim 1 to 22, characterized in that the deflection voltage is applied between the two anodes. 24. Modulation circuit according to claim 1 to 23, characterized in that the emission control voltage is applied between the cathode and at least one anode, but preferably both anodes in phase. For this purpose 2 sheets of drawings © 5860 4.5)