DE1029887B - High frequency amplifier with a neutralization circuit - Google Patents

Description

The invention relates to a high-frequency amplifier with an electron tube, in particular one Triode, an output coil connected on one side to the anode and a neutralization circuit.

In the case of high-frequency amplifiers for the range from 50 to 250MHz (hereinafter referred to as VHF range), in particular with tuning devices after the turret type for television sets, were previously Pentode or cascade amplifier stages used. Such stages are more expensive and contain more Individual parts as a triode amplifier stage for the same amplifier. Triode amplifiers were used in However, these frequency ranges have not yet been used because the feedback signals lead to negative amplification lead and because it has not yet succeeded in such a To neutralize high frequency feedback within the whole VHF range. Through the invention the applicability of the neutralization is expanded, so that in the VHF or meter wave range from 50 or less to 250 or more MHz triodes can be practically used for amplification. Their use in VHF television multichannel tuners, Particularly in the case of moving species with a revolver or coil, simple triode stages have a remarkable neutralizing effect.

According to the invention, a high-frequency amplifier of the type mentioned is designed in such a way that a conductive main part and a counter electrode with two connections having a capacitor with negligible inductance is provided, one connection with the anode-remote but HF-carrying end of the output coil, its main part is connected to the amplifier chassis , and its second connection, at which signals occur which are 180 ° out of phase with those occurring at the anode, is connected to a neutralizing capacitor, which feeds a counter signal stabilizing the amplifier to the grid of the triode.

In this way, the effective capacitances and the entire frequency range of the signal will be the Otherwise existing inductance in the supply lines is reduced to a very small value, so that it has a negligible influence on the phase of the feedback neutralization signal.

In the commercial application of the invention, the circuit complexity is significantly reduced Achieved gains that are the same as those of the pentode or cascode amplifiers, with the noise factor and other parameters are comparable to those of the latter amplifiers.

According to a preferred embodiment of the invention, the capacitor is a bushing

High frequency amplifier
with a neutralization circle

Applicant:

Standard Coil Products Co.,
Inc., Los Angeles, Calif. (V.StA.)

Representative: Dipl.-Ing. C. Wallach, patent attorney,
Munich 2, Kaufingerstr. 8th

Claimed priority:
V. St. v. America April 5, 1955

Robert CA Eland, Arcadia, Calif. (V. St. Α.),
has been named as the inventor

capacitor, which expediently has an outer conductive main part and an inner electrode has two terminals protruding from opposite sides of the capacitor. Farther can conveniently the conductive main part of the capacitor on the metallic amplifier chassis be attached, while said connectors are on opposite sides of the chassis and are shielded from each other by this.

Further details and advantages of the invention emerge from the description of preferred ones Embodiments on the basis of a single circuit shown in the drawing. The invention however, it can be applied to any type of television voting or voting system or for the transmission of messages, High frequency amplification or the like. Serve. In the drawing shows

Fig. 1 is a circuit diagram of a radio frequency amplifier and mixer that is part of a television tuner is equivalent to,

Fig. 2 shows a circuit of the neutralization circuit according to the invention,

3 shows a modified circle according to FIG. 2,
4 shows, in section, a capacitor of low inductance and preferably used in the neutralization circuit

FIG. 5 shows a modification of the circle corresponding to FIG. 4.

Fig. 1 shows a circuit diagram of a television tuner. An antenna transformer 10 has a

809 510/351

3 4

symmetrical primary winding-11 ■ on ,, those with a or pentode amplifier. The preselector 20, 21

Dipole receiving antenna 15 is connected. The upper 22 is assigned to a specific channel, as well

The end 18 of the secondary winding 16 is by means of a like the circles, which the high-frequency transforma-

Coupling capacitor 20, a high-frequency inductor 33 and the oscillator 21 belonging to the coil 50 and a coupling capacitor 22 with 5 circuit included. These circuit parts are for

a preselection or frequency determination stage, each channel on a special switchboard or

bound. The sizes of the capacitors 20, 22 and the strips of a turret-type tuner

Inductance or coil 21 determine the frequency arrangement. The neutralization according to the invention

The band, to which the stage is matched or the parts serving in advance, are firmly arranged and remain

is true. 'io effective for all selected channels.

The output signal of the preselection stage is fed to a feed-through or disk capacitor control grid 25 of an amplifier triode 30. serves to couple the output circuit of the triode. The sieve grid has two independent ones with the neutralization capacitor 65 and via leads 68 and 69: -The anode 31 of the triode 30 this with the control grid. In Fig. 1, such is shown with the primary winding 32 of an output transformer 15 feedthrough capacitor at 60 and connected to the transformer 33 ·. The anode voltage source connects point B at the lower end of the primary BV is connected to the anode 31 via a high frequency winding 32 of the transformer 33 through a plate choke 36. A bridging capacitor 61 with a neutralizing capacitor 37 is connected to earth in the usual way. 65. The plate 61 can be a coil board, a secondary winding 35 of the output transformer shielding or a part of the chassis of the tuning gate 33 is connected to the control grid 41 of a mixer. In this way, a capacitor 60 is either directly selected or through the members 20, 21 and 22-Vof and in the tri- the conductive plate 61 is connected to earth, or 30 amplified high-frequency band via the trans- The lower or inner terminal C des Feedthrough transformer 33 with the control grid 41 of the mixing tube 25 condenser 60 is coupled to the neutralization 40. "" condenser 65. To reduce external

An oscillator, not shown, is the inductance between point B and the Gkter-

Mixing tube 40 over a winding 50 and the secondary connection 26, the triode must be close to the transformer

Därwick 35 supplied the oscillator frequency. Be located at 33 so that the distance between the

a tuning device for abrupt adjustment 30 points B, C and 26 is as small as possible. then

the windings 32, 35 and 50 are grouped together for a

the various frequency channels switched on. A capacitor 65 is formed between points C and 26

Point 56 in the anode circle of the mixer tube has only a small influence on the inductance achieved

"is neutralizing with the intermediate frequency part of the television receiver, gers connected in the usual way. 35 For a better understanding, FIG. 2

The \ ^r Before Using the triode Stärkers construction, the effect of the feedthrough capacitor 60 in

frequency gain- depends on a perfect of the described circuit explained. A condensate

Neutralizing the voltage feedback from gate C ₀ provides that between anode 31, grid 25

Anode circle to the circle of the control grid 25. Interelectrode or internal ones present to and earth

Achievement of a neutralization must be a capacity of the triode 30 to the grid 40 and an additional one

The voltage is essentially the external capacitance of the circuit parts in the output

180 ° out of phase with the voltage circle of the tube 30, regardless of the tuned

be attached to the grid through the anode 31 via the coil32. In other words: C ₀ represents the capacitance

between them existing intermediate electrode capacitors of the triode 30 between point A and earth,

that is added to it. 'To; The returned signal should be 45 L ₀ the inductance of coil 32 and C ₁ the capacitance

that through the intermediate electrode capacitance of the feed-through capacitor 60, which is between

led signal same ^; which is of course switched on with points B and C (Fig. 1). These

_{the capacitance C 1} present in the anode circuit "of the triode" is that between the bushing part

strengthened signal identical; is. "'tung BC and earth occurring capacity.

Because the control grid 25 has a counter voltage 50 As can be seen, the circle which is _{supplied to C 0} , L ₀ and 'voltage,' which contains about the same size and C ₁ , is a π-term Voltage at point A waveform as that of the control grid through the return represents the output high frequency signal of the triode 30 coupling via the intermediate electrode capacitance, which has voltage introduced via the coil 32 into the mixing tube 40, but is fed opposite this. The potential at point B is 180 °. is out of phase. If the effect of 55 has the same waveform as that at the point of feedback, or if the triode is neutralized, it is reversed compared to this. In this way, Mrd in the frequency ranges, about 180 ° out of phase. The amplitude am at which the neutralization is effective, the full point B can be approximately the same as that at point A or e> t gain of the triode ^; he * aims. The invention aims to be less if the inductance L _{0 is} based on this neutralization over a wide 60 ohmic resistance. The whole inductive high frequency range, especially at higher highs L _0, can be effective than between points A and B. Which are viewed as an example centered, the potential at the serving execution farm for a television channel point £ compared to the selector at the point by about 180 ° in the VHF range ¹ being in the range from 54 to is phase-shifted.

216MHz for the twelve VHF-65 common in the USA. The feed-through capacitor 60 has the task of

Channels neutralized. . . the potential B with the neutralization capacitor

The effective neutralization 65 to be described with the correct phase shift of 180 °

works satisfactorily, and yields for anyone to relate to. This is achieved by using ν.

twelve x-channels a full gain of the triode, which means that the feed-through capacitor 60, considered ¹ '

It is comparable to the amplification of a cascode 70 from point C, compared to point B practically! ·

has no inductance, but in this sense is a pure capacitance, while any small inductance that may be present lies _{in L 0.} Should an effective inductance occur between points B and C, the phase shift of 180 ° for the purpose of neutralizing the triode 30 would be disturbed. At the maximum frequencies at which the exemplary embodiment operates, even a small inductance at BC completely perturbs neutralization. In this case the signal 1> once it arrives at the grid 25 would not have sufficient effect to neutralize the signal supplied by the anode 31 to the grid. The triode 30 could therefore not be able to effectively amplify as required.

The outer sleeve 62 of the feed-through capacitor is connected to ground via the capacitance C ₁ . In this way, the capacitance C ₀ at the input of L ₀ is neutralized by the π-element shown. According to the invention, the phase shift of 180 ° of the required signal is caused with certainty by a .τ element at point C. Furthermore, the capacitance of the feed-through capacitor C _{1 should be} in the order of magnitude of ten times the effective capacitance C ₀ . In the exemplary embodiment, feedthrough capacitor 60 can have a capacitance C _{1 on} the order of 10 to 50 pF , depending on the value of C _0. In the following, C _n denotes the effective neutralization capacitance of the capacitor 65 and C _ga denotes the capacitance between the grid 25 and the anode 31. The inventor has found that the broadband neutralization mentioned here occurs when the relationship

C _n

35

C _a

is satisfied. It is essential that no effective inductance is added at point B due to the connection to the neutralizing _{capacitor 65 and that the inductances are concentrated in L 0 of} the ^ element. A different value of the capacitance C ₁ only results in a different amplitude of the signal occurring at point C. This can be taken into account by the size of the neutralization capacitor 65 when the signal is linked with the feedback signal required at the grid 25.

The neutralizing capacitor 65 may be adjustable to allow complete neutralization of any particular triode 30 within the high frequency range. In the embodiment serving as an example, the C ₀ corresponding inter-electrode capacitance of the tube 30 had a value of 1 pF and the effective capacitance of the neutralization capacitor 65 was approximately 1.8 pF. The inductance of the leads of the neutralizing capacitor 65 between the points C and 26 is not very important here in view of the small value of the capacitance of the capacitor 65. Even so, it is desirable and important that the overall lengths of the leads from condenser 65 to points 26 and C be as short as possible,

Fig. 3 shows an effective τι-member C ₀ , L ₀ , C ₂ , L ₂ . The portion between the points A and B and C ₀ is similar to those of FIG. 2. In place of a grounded feedthrough capacitor 60, however, the member is a common line between the point B of the coil 32 and the junction point C at which point C of Figure 2 corresponds to. Such a common line has an effective inductance L ₂ , which disturbs the phase shift required at point C by 180 ° with respect to the signal occurring at point A. The π-term is disturbed and ^p the neutralization normally achieved by the above means according to FIG. 1 cannot occur.

4 shows a cross section through an embodiment of the feedthrough capacitor 60. The feedthrough conductor 63 connects the points B and C located on both sides of the plate 61. A dielectric tube 64, e.g. Of ceramic material, surrounds the conductor 63. A conductive layer 62, e.g. B. silver, surrounds the dielectric 64 or is electroplated onto it. The feed-through capacitor 60 is arranged in an opening in the plate 61 which, if it is metallic, itself forms a ground for the outer layer 62 of the feed-through capacitor 60. Other known constructions for the feedthrough capacitor can of course also be used.

5 shows an alternative to the feed-through capacitor 60 in the form of a disc capacitor 66. A disc capacitor likewise has a very low or negligible inductance for the high frequencies which are considered here. The bottom surface 67 of the disc capacitor 66 is attached to the plate 61 ', which can be a shield or a chassis part, or is soldered to it. The disc capacitor 66 is switched on instead of the feed-through capacitor 60. The connection B ″ is directly connected to the lower side B of the coil 32 and the connection C ″ is connected directly to one side of the neutralizing capacitor 65. The inventor has found that neutralizing a triode with a disc capacitor produces just as good results as with a feed-through capacitor.

The inventor has found that even in an embodiment with only one grid feed one effective neutralization according to the invention can be achieved when used as a tuned high frequency input circuit the stage 30 uses a series resonant circuit instead of a parallel resonant circuit will.

The price of a triode is less than that of a hull or a pentode, so a substantial one Savings are achieved, especially when one considers that fewer circuit parts are used for the triode circuit required are. The triode 30 of FIG. 1 can be one half of a double tube, so that further savings occur when the second half is used for another part of the circuit, e.g. B. for the Oscillator or mixer stage is used. Should a neutralization of a second triode in the High frequency amplifiers are required, the invention can also be applied to them independently will.

Claims (6)

Patent claims: 1. High-frequency amplifier with an electron tube, in particular a triode, an output coil connected on one side to the anode and a neutralization circuit, characterized in that a conductive main part (62 in Fig. 1 and 4; 67 in Fig. 5) and a counter electrode with two Terminals (B, C; B ", C") having capacitor (60, 66) with negligible inductance is provided, one terminal (B, B ") of which with the end of the output coil remote from the anode but carrying HF voltage (32), the main part (62, 67) of which is connected to the amplifier chassis (61, 61 '), and its second connection (C, C "), at which signals occur which are 180 ° with respect to those at the anode (31 ) occurring are phase-shifted, is connected to a neutralizing capacitor (65), which supplies the grid (25) of the triode (30) with a counter-signal that stabilizes the amplifier. 2. Amplifier according to claim 1, characterized in that that the output spuk (32) is one of several for operating the receiver within of a certain VHF band, optionally in series with the anode (31) switchable output coils is. 3. Amplifier according to claim 1 or 2, characterized in that the capacitor is a feed-through capacitor (60) is. 4. Amplifier according to claim 3, characterized in that the feed-through capacitor (60) an outer conductive main part (62) and an inner electrode with two terminals (B, C) protruding from opposite sides of the capacitor. 5. Amplifier according to claim 4, characterized in that the conductive main part (62) of the capacitor is attached to the metallic amplifier chassis (61) and that the connections (B, C) are located on opposite sides of the chassis and are shielded from one another by this . 6. Amplifier according to claim 1 or 2, characterized in that the capacitor is button-like is trained. Considered publications:
German patent specifications No. 658 450, 829 908,
732, 869 224; British Patent No. 436,419;
U.S. Patent No. 2,128,661. 1 sheet of drawings © 809 510/351 5. 58