US2197239A - Stabilized tuned system - Google Patents

Stabilized tuned system Download PDF

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US2197239A
US2197239A US254013A US25401339A US2197239A US 2197239 A US2197239 A US 2197239A US 254013 A US254013 A US 254013A US 25401339 A US25401339 A US 25401339A US 2197239 A US2197239 A US 2197239A
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tube
circuit
tuned circuit
tuned
resistance
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US254013A
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John F Farrington
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BAE Systems Aerospace Inc
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Hazeltine Corp
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Priority to GB879/40A priority patent/GB534988A/en
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    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03FAMPLIFIERS
    • H03F1/00Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements
    • H03F1/38Positive-feedback circuit arrangements without negative feedback
    • H03F1/40Positive-feedback circuit arrangements without negative feedback in discharge-tube amplifiers
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B1/00Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
    • H04B1/06Receivers
    • H04B1/16Circuits
    • H04B1/163Special arrangements for the reduction of the damping of resonant circuits of receivers

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  • Regeneration has heretofore been utilized to provide a circuit which is more sharply selective than a simple tuned circuit.
  • the efiect of regeneration is effectively to introduce into the tuned circuit a negative resistance.
  • the effective resistance is reduced to a very low value and the tuned circuit becomes very sharply selective.
  • Such regenerative circuits commonly utilize vacuum tubes to provide regeneration.
  • the amount of negative resistance so introduced into a tuned circuit varies rapidly with variations in transconductance of the regenerating tube. If the total effective resistance of such a system becomes negative, regenerative oscillation will result.
  • a stabilized tuned system comprises a tuned circuit having a given eflective positive resistance together with a vacuum tube coupled to the tuned circuit.
  • means for providing regeneration in the tuned circuit preferably comprising means for impressing on an input electrode of the tube a voltage derived from, and varying in phase and magnitude in accordance with, the voltage across the tuned circuit of the system to provide regeneration in the tuned circuit, and means for impressing on an input electrode of the vacuum tube also a degenerative voltage derived from, and varying in phase and magnitude in accordance with, the output current of the tube.
  • the feed-back voltages are so proportioned that their joint efiect on the tuned circuit is that of an added negative resistance in the tuned circuit which approaches asymptotically a value not substantially greater than the value of the actual effective positive resistance included in the tuned.circuit as the transconductance of the tube is increased; speciiically, the circuit is so proportioned that the negative resistance is not greater than the posi tive resistance for any value of transconductance within the range of operation of the tube and so that for the higher values of transconductanceutilized the negative resistance increases gradually with variations of transconductance oi the tube.
  • the circuit When the circuit is proportioned in this manner, a very sharply selective resonance characteristic may be obtained with a single-tuned circuit for relatively high transconductance. of the regenerating tube while, at the same time, the system is stabilized against regenerative oscillations due to variations in the transconductance ofthe tube.
  • the stabilized regenerative system When coupled tuned circuits are used, as in an adjustable band-pass selector, the stabilized regenerative system may be used to control selectivity without danger of producing oscillations.
  • the added negative resistance is made to approach asymptotically the approximate value of the actual, resistance of the tuned circuit.
  • Fig. 1 of the drawing is a circuit diagram of a stabilized tuned system in accordance with the invention, utilized as a tuned circuit in the output circuit of a vacuum-tube amplifier;
  • Fig. 2 illustrates the negative resistance-grid bias characteristic of analogous prior art regenerative circuit arrangements; while Fig. 3 illustrates the negative resistance-grid bias characteristic of the arrangementof Flg. 1.
  • a vacuum-tube amplifier I II coupled between input terminals II, I I and output terminals I2, I2.
  • the output circuit of vacuum tube I comprises a load circuit including a stabilized tuned system having an inductance l3 inductively coupled to an inductance I4 comprising with a condenser I5 a parallel-tuned circuit.
  • Output terminals I2 are coupled to tuned circuit I 4, I5 by means of an inductance I6 inductively coupled to inductance I4.
  • a regenerating vacuum tube 20 the output electrodes of the tube being coupled across tuned circuit I4, I5 through a resistor 2
  • is indicated by dotted-line condenser 22 and there is also connected across resistor 2I an inductance 23 effective to resonate with capacitance 22 at the frequency of tuned circuit I4, I5, thereby to neutralize the effect of the inherent capacitance 22.
  • the circuit 22, 23 is heavily loaded by resistor 2I so that its impedance is substantially resistive and constant over a reasonable frequency range in the vicinity of its resonant frequency.
  • the control-grid circuit including inductance 24 includes also the output circuit resistor 2I.
  • Suitable blocking condensers 25, 26, and 21 are also provided for the circuit of Fig. 1, while suitable operating potentials are applied to the electrodes of the tubes I0 and 20 from sources indicated at +80 and +3.
  • the bias potential of the input electrode of tube 20 may be adjusted by means of potentials applied to the control-bias terminal through a resistor 28 of high impedance as compared to resistor 2
  • the regenerative feedback circuit to the control grid of tube 20 including inductance 24 is efiective to provide regeneration in a manner well understood in the art, and that this feed-back voltage varies in phase and magnitude in accordance with the voltage across tuned circuit I4, 15.
  • resistor 2I provides a means for impressing on an input electrode of tube 20 a degenerative voltage derived from, and varying in phase and magnitude in. accordance with, the output current of the tube.
  • the joint eflfect of the two feed-back means of Fig. 1 is to introduce a negative resistance into tuned circuit I4, IS.
  • I5 of the invention has an actual resistance of a magnitude indicated by the dotted line A of Fig. 2, it is apparent that any value of negative resistance of a greater magnitude introduced into the tuned circuit causes oscillation. Furthermore, it is seen that the grid voltage-negative resistance characteristic of such prior art systems is very steep in the region of its intersection with the positive resistance curve of the circuit, thus causing such a system'to be very unstable for any appreciable variation in transconductance of the feed-back tube in such region.
  • Fig. 3 The negative resistance characteristic of the circuit of Fig. 1, proportioned in a manner to be hereinafter described, is illustrated in Fig. 3.
  • the dotted horizontal line B of Fig. 3 represents the magnitude of the eifective positive resistance of tuned circuit I4, I5, it will be seen that, for any value of negative grid voltage or transconductance of tube 20, the magnitude of the negative resistance introduced by regeneration cannot exceed that of the actual resistance of the circuit.
  • the system is, therefore, stable against changes in grid voltage or variations in transconductance of vacuum tube 20.
  • the total effective resistance of tuned circuit ll it approaches which is a constant, that is, independent of the transconductance of tube 20. Therefore, by properly proportioning the circuit impedances r, m, 1!, and B so that is positive, the total eflective resistance of tuned circuit l4, l5 remains positive and oscillation is avoided.
  • tuned circuit I4, l5 has a very sharply selective resonance characteristic for relatively high values of transconductance of the tube It and the system is stabilized against regenerative oscillation. It will be seen that the value of negative resistance in- 'serted in the tuned circuit may be varied by a variation of the transconductance a of tube 20 and it will be understood that the circuit constants may be so proportioned that the added negative resistance in the tuned circuit is approximately equal to, but not greater than, the
  • a stabilized tuned system comprising, at least one tuned circuit having a given resistance, a vacuum tube having input and output sets of trodes to said tuned circuit to provide regeneration in said tuned circuit, means for impressing on an input electrode oi said tube a negative feed-- back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said degeneration being so proportioned with respect to said regeneration that their Joint eflect on said tuned circuit is that of an added negative resistance in said tunedcircuit which approaches a value not greater than the value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply selective resonant characteristic for relatively high values of transconductance of said tube and the system is stabilized against regenerative oscillation.
  • a stabilized tuned system comprising, at least one tuned circuit having a given resistance, a vacuum tube having input and output sets of electrodes, one of said sets of electrodes being coupled to said tuned circuit, means for impressing on an input electrode of said tube a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuitto provide regeneration in said tuned circuit, means for impressing on an input electrode of said tube a negative feed-back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so proportioned that their joint efiect on said tuned circuit is that of an added negative resistance in said tuned circuit which approaches a value not greater than the value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply selective resonant characteristic for relatively high values of transconductance of said tube and the system is stabilized against regenerative oscillation.
  • a stabilized tuned system comprising, a tuned circuit having a given resistance, a vacuum tube having input and outputsets of electrodes, one of said sets of electrodes being coupled to said tuned circuit, means for impressing on an electrodes, means for coupling said sets of elec voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, means for impressing on an input electrode of said tube a negative feed-back .voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so proportioned that their joint effect on said tuned circuit is that of an added negative resistance in said tuned circuit which approaches the approximate value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply peaked resonant characteristic for relatively high values of transconductance of said tube and the system is stabilized against'regenerative oscillation.
  • a stabilized tuned system comprising, a tuned circuit having a given resistance, a vacuum tube having input and output sets of electrodes,
  • said tuned circuit has a very sharply peaked resonant characteristic for relatively high values of transconductance of said tube-and. the system is stabilized against regenerative oscillation.
  • a stabilized tuned system comprising, at least one tuned circuit having a given resistance, a vacuum tube having input and output sets of electrodes, said output electrodes being coupled to said tuned circuit, means for impressing on an input electrode of said tube a positive feedback voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, means for impressing on an input electrode of said tube a negative feed-back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so proportioned that their joint efiect on said tuned circuit is that of an added negative resistance in said circuit which approaches the approximate value of said given resistance with increasing transconductance oi said tube, whereby said tuned circuit has a very sharply peaked response characteristic for relatively high values of transconductance of said tube and the system is stabilized against regenerative oscillation.
  • a stabilized tuned system comprising, at least one tuned circuit having a given resistance, a vacuum tube having input and output sets of electrodes, said output electrodes being coupled to said tuned circuit, means for impressing on one of said input electrodes a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, means for impressing on said one of said input electrodes of said tube a negative feedback voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so proportioned that their joint effect on said tuned circuit is that of an added negative resistance in said circuit which approaches the approximate value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply selective response characteristic for relatively high values of transconductance of said tube and said system is stabilized against regenerative oscillation.
  • a stabilized tuned system comprising, at least one tuned circuit having a. given resistance, a vacuum tube having input and output sets of electrodes, a circuit common to an input set of electrodes and said output electrodes and including a resistor to provide a negative feed-back voltage, one of said sets of electrodes being coupled to said tuned circuit, means for impressing on an input electrode of said tube a positive feedback voltage derived from and varying in accordance with the voltage across said tuned air-- cuit to provide regeneration, the feed-back voltages being so proportioned that their joint effect on said tuned circuit is that of an added negative resistance in said tuned circuit which approaches the approximate value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply selective response characteristic for relatively high values of transconductance of said tube and the system is stabilized against regenerative oscillation.
  • a stabilized tuned system comprising, at least one tuned circuit having a given resistance, a vacuum tube having input and output sets of electrodes, one of said setsof electrodes being coupled to said tuned circuit, means comprising an inductance inductively coupled to said tuned circuit for impressing on an input electrode of said tube a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in-said tuned circuit, means for impressing on an input electrode of said tube a neg-,
  • a load circuit for said tube including a stabilized tuned system comprising, a tuned circuit having a given resistance, a second vacuum tube having input and output sets of electrodes, one of said sets of electrodes being coupled to said tuned circuit, means for impressing on an input electrode of said second tube a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, means for impressing on an output electrode of said second tube a negative feed-back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so proportioned that their joint effect on their tuned circuit is that of an added negative resistance in said tuned circuit which approaches a value substantially equal to the value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply peaked resonance characteristic for relatively high values of transconductance of said tube and the system is
  • a stabilized tuned system comprising, a tuned circuit including a parallel-connected inductance and capacitance and having a given resistance, a vacuum tube having input and output sets of electrodes, a circuit common to an input set of electrodes and said output electrodes and including a resistor, said output electrodes being coupled to said tuned circuit through said resistor, means comprising an inductance inductively coupled to said inductance of said tuned circuit for impressing on an input electrode of said tube a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, said resistor comprising means for impressing on an input electrode of said tube a positive feed-back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so proportioned that their joint effect on said tuned circuit is that of an added negative resistance in said tuned circuit which approaches the approximate value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply peaked
  • a stabilized tuned system comprising, at least one tuned circuit having a given resistance, a vacuum tube having input and output sets of electrodes, one of said sets of electrodes being coupled to said tuned circuit, means for impressing on an input electrode of said tube a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, means for impressing on an input electrode of said tube a negative feed-back voltage derived from and varying in accordance with the output current of said tube to provide degeneration, said circuit being so proportioned that 1 +129 is positive for relatively high values of transconductance of said tube, where the various parameters have the significance defined in the specification, whereby said tuned circuit has a very sharply selective resonant characteristic for relatively high values of transconductance of said tube' and the system is stabilized against regenerative oscillation.
  • a stabilized tuned system comprising, a tuned circuit having a given resistance, a vacuum tube having a predetermined maximum value of transconductance and input and output sets of electrodes, a circuit common to an input set of electrodes and said output set of electrodes and including a resistor, one of said sets of electrodes being coupled to said tuned circuit, means for impressing on an input electrode of said tube a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, means including said resistor for impressing on an input electrode of said tube a negative feed-back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said circuit being so proportioned that the product of the value of said maximum transconductance and the value of said resistor is much greater than unity and the negative resistance introduced into said tuned circuit is approximately equal to said given resistance for relatively high values of transconductance of said tube, whereby said tuned circuit has a very sharply peaked resonant characteristic for values

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Description

Negative Grid Volts O 2 2 .2 3 I! 2 E R6. 2. g 4 Z Negative Grid Vol'ls INVENTOR J0 F. FARRINGTON BY v \ ATTORNEY Patented Apr. 16, 1940 UNITED STATES PATENT OFFICE STABILIZED TUNED SYSTEM John F. Fanington, Flushing, N. Y., assignor to llalcltine o 'lm'atlon, a corporation of Dcla-' Application February 1, 1939, Serial No. 254,013
steeply sloping sides, in either case sharply selective against undesired signals, but which are stabilized against regenerative oscillations.
In many high-frequency signal-translating systems it is necessary to provide a very sharply selective circuit. may be desired in order to select signals of a particular frequency or of a given band of frequencies from a source comprising signals of a wider range of frequencies. Such a circuit is of particular utility as a load circuit of a vacuum tube which is to be utilized as an amplifier for such selected frequencies. Simple tuned circuits have commonly been utilized in the manner described above. However, since it is not possible to construct reactive elements, together with conductors connecting the same, which have zero resistance, conventional prior art tuned circuits have not been as selective as is sometimes desired.
Regeneration has heretofore been utilized to provide a circuit which is more sharply selective than a simple tuned circuit. The efiect of regeneration is effectively to introduce into the tuned circuit a negative resistance. Thus, as the magnitude of the negative resistance so introduced into the tuned circuit becomes comparable in magnitude to the inherent or actual resistance of the tuned circuit, the effective resistance is reduced to a very low value and the tuned circuit becomes very sharply selective. Such regenerative circuits commonly utilize vacuum tubes to provide regeneration. However, in such prior art circuits the amount of negative resistance so introduced into a tuned circuit varies rapidly with variations in transconductance of the regenerating tube. If the total effective resistance of such a system becomes negative, regenerative oscillation will result. Therefore, inasmuch as for a highly selective circuit it is necessary to reduce the effective resistance of the tuned circuit to a very low positive value while any resultant efiective negative resistance causes the system to oscillate, such prior .art systems may tend to be unstable and unsuitable for use in a system where it is desired to adjust the transconductance 'of the tube to adjust the gain of the system.
It is, therefore, an object of the invention to provide a stabilized tuned system in which the above-mentioned disadvantages of the arrangements of the prior art are eliminated.
It is another object of the invention to provide Thus, such a selective circuit a stabilized tuned system comprising a tuned circult and a regenerating vacuum tube, the system being stabilized against regenerative oscillation due to changes in the transconductance of the tube. It is a further object of the invention to .pro-' vide a tuned system in which the selectivity can be adjusted between broad and very sharp characteristics by regeneration without becoming u'nstable when a high degree of regeneration is.
utilized.
In accordance with the invention, a stabilized tuned system comprises a tuned circuit having a given eflective positive resistance together with a vacuum tube coupled to the tuned circuit. There are included in the system means for providing regeneration in the tuned circuit, preferably comprising means for impressing on an input electrode of the tube a voltage derived from, and varying in phase and magnitude in accordance with, the voltage across the tuned circuit of the system to provide regeneration in the tuned circuit, and means for impressing on an input electrode of the vacuum tube also a degenerative voltage derived from, and varying in phase and magnitude in accordance with, the output current of the tube. The feed-back voltages, provided by the above-mentioned means, are so proportioned that their joint efiect on the tuned circuit is that of an added negative resistance in the tuned circuit which approaches asymptotically a value not substantially greater than the value of the actual effective positive resistance included in the tuned.circuit as the transconductance of the tube is increased; speciiically, the circuit is so proportioned that the negative resistance is not greater than the posi tive resistance for any value of transconductance within the range of operation of the tube and so that for the higher values of transconductanceutilized the negative resistance increases gradually with variations of transconductance oi the tube.
When the circuit is proportioned in this manner, a very sharply selective resonance characteristic may be obtained with a single-tuned circuit for relatively high transconductance. of the regenerating tube while, at the same time, the system is stabilized against regenerative oscillations due to variations in the transconductance ofthe tube. When coupled tuned circuits are used, as in an adjustable band-pass selector, the stabilized regenerative system may be used to control selectivity without danger of producing oscillations. In a preferred embodiment of the invention, the added negative resistance is made to approach asymptotically the approximate value of the actual, resistance of the tuned circuit.
For a better understanding of the invention,
together with other and further objects thereof, reference is had to the following description taken in' connection with the accompanying drawing and its scope will be pointed out in the appended claims.
Fig. 1 of the drawing is a circuit diagram of a stabilized tuned system in accordance with the invention, utilized as a tuned circuit in the output circuit of a vacuum-tube amplifier; Fig. 2 illustrates the negative resistance-grid bias characteristic of analogous prior art regenerative circuit arrangements; while Fig. 3 illustrates the negative resistance-grid bias characteristic of the arrangementof Flg. 1.
Referring now more particularly to Fig. 1, there is shown a vacuum-tube amplifier I II coupled between input terminals II, I I and output terminals I2, I2. The output circuit of vacuum tube I comprises a load circuit including a stabilized tuned system having an inductance l3 inductively coupled to an inductance I4 comprising with a condenser I5 a parallel-tuned circuit. Output terminals I2 are coupled to tuned circuit I 4, I5 by means of an inductance I6 inductively coupled to inductance I4.
There is also provided a regenerating vacuum tube 20, the output electrodes of the tube being coupled across tuned circuit I4, I5 through a resistor 2|. The inherent capacitance across resistor 2| is indicated by dotted-line condenser 22 and there is also connected across resistor 2I an inductance 23 effective to resonate with capacitance 22 at the frequency of tuned circuit I4, I5, thereby to neutralize the effect of the inherent capacitance 22. The circuit 22, 23 is heavily loaded by resistor 2I so that its impedance is substantially resistive and constant over a reasonable frequency range in the vicinity of its resonant frequency. In order to provide a positive feedback voltage to an input electrode of tube 20 for regeneration of circuit I4, I5 which variesin phase and magnitude in accordance with the voltage acro ss circuit I4, I5, there is provided an inductance 24 inductively coupled to inductance I4 and included in the control or input-grid cir= cuit of tube 20. In order to provide a negative or degenerative feed-back voltage to an input electrode of tube 20, the control-grid circuit including inductance 24 includes also the output circuit resistor 2I. Suitable blocking condensers 25, 26, and 21 are also provided for the circuit of Fig. 1, while suitable operating potentials are applied to the electrodes of the tubes I0 and 20 from sources indicated at +80 and +3. The bias potential of the input electrode of tube 20 may be adjusted by means of potentials applied to the control-bias terminal through a resistor 28 of high impedance as compared to resistor 2|, and this tube may be adapted to operate over a predetermined-bias range including a bias corresponding to a relatively high value of transconductance of the tube.
In considering the operation of the system of Fig. 1, it will be seen that the regenerative feedback circuit to the control grid of tube 20 including inductance 24 is efiective to provide regeneration in a manner well understood in the art, and that this feed-back voltage varies in phase and magnitude in accordance with the voltage across tuned circuit I4, 15. It wil also be seen that resistor 2I provides a means for impressing on an input electrode of tube 20 a degenerative voltage derived from, and varying in phase and magnitude in. accordance with, the output current of the tube. The joint eflfect of the two feed-back means of Fig. 1 is to introduce a negative resistance into tuned circuit I4, IS.
The negative resistance characteristic of comparable circuits of the prior art is shown by Fig. 2. If it is assumed that the tuned circuit of prior art arrangements, corresponding to tuned circuit I4,
I5 of the invention, has an actual resistance of a magnitude indicated by the dotted line A of Fig. 2, it is apparent that any value of negative resistance of a greater magnitude introduced into the tuned circuit causes oscillation. Furthermore, it is seen that the grid voltage-negative resistance characteristic of such prior art systems is very steep in the region of its intersection with the positive resistance curve of the circuit, thus causing such a system'to be very unstable for any appreciable variation in transconductance of the feed-back tube in such region.
The negative resistance characteristic of the circuit of Fig. 1, proportioned in a manner to be hereinafter described, is illustrated in Fig. 3. Thus, if the dotted horizontal line B of Fig. 3 represents the magnitude of the eifective positive resistance of tuned circuit I4, I5, it will be seen that, for any value of negative grid voltage or transconductance of tube 20, the magnitude of the negative resistance introduced by regeneration cannot exceed that of the actual resistance of the circuit. The system is, therefore, stable against changes in grid voltage or variations in transconductance of vacuum tube 20.
The following equations are applicable to the system of Fig. 1 and are utilized in proportioning the constants of the system to secure the characteristic illustrated in Fig. 3:
myg 1+Rg) (3) Frorn (3) the efiective resistance of tuned circuit 1. y= the reactance of capacitor 15,
When Rg 1, the negative resistance approaches and is substantially independent of g, the trans conductance oi tube 20;
Therefore, the total effective resistance of tuned circuit ll, it approaches which is a constant, that is, independent of the transconductance of tube 20. Therefore, by properly proportioning the circuit impedances r, m, 1!, and B so that is positive, the total eflective resistance of tuned circuit l4, l5 remains positive and oscillation is avoided.
It is, therefore, seen that, by means of the relationship described above, it is possible to proportion the constants of the circuit of Fig. 1 so that the joint efiect'of the two feed-back means in the feed-back circuit is an added negative resistance in the tuned circuit which approaches asymptotically a value not substantially greater than the value of the resistance r of tuned circuit l4, l5; actually, the circuit is so proportioned that within the range of variation of. transconductance of tube 20 the negative resistance is less than 1', the actual resistance of tuned circuit I, I5. The value of negative resistance so introduced may be made to approach very nearly the value of resistance 1 without impairing the stability of the system. In this manner, tuned circuit I4, l5 has a very sharply selective resonance characteristic for relatively high values of transconductance of the tube It and the system is stabilized against regenerative oscillation. It will be seen that the value of negative resistance in- 'serted in the tuned circuit may be varied by a variation of the transconductance a of tube 20 and it will be understood that the circuit constants may be so proportioned that the added negative resistance in the tuned circuit is approximately equal to, but not greater than, the
value of the given resistance over a substantial portion of the transconductance range. While the resonant circuit ll, l5 has been shown in the embodiment of Fig. 1 in the output circuit of tube 20, it will be apparent to those skilled in the art that tuned circuit I, I5 may be coupled in the input circuit of tube It. While the invention has been illustrated with reference to a single sharply tuned circuit, it will be understood that the invention is equally applicable to systems compris ing a plurality of coupled tuned circuits. Thus, the invention is particularly useful in that type of variable band-pass selector circuit comprising a plurality of coupled tuned circuits and having a vacuum tube coupling the circuits to provide regeneration to narrow the pass band with increasing values of transconductance of the coupling tube.
While there has been described what is at present considered to be the preferred embodiment of this invention, it will be obvious to those skilled in the art that various changes and modifications may be made therein without departing from the invention, and it is, therefore, aimed in the appended claims to cover all such changes and modifications as fall within the true spirit and scope of the invention.
What is claimed is:
1. A stabilized tuned system comprising, at least one tuned circuit having a given resistance, a vacuum tube having input and output sets of trodes to said tuned circuit to provide regeneration in said tuned circuit, means for impressing on an input electrode oi said tube a negative feed-- back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said degeneration being so proportioned with respect to said regeneration that their Joint eflect on said tuned circuit is that of an added negative resistance in said tunedcircuit which approaches a value not greater than the value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply selective resonant characteristic for relatively high values of transconductance of said tube and the system is stabilized against regenerative oscillation.
2. A stabilized tuned system comprising, at least one tuned circuit having a given resistance, a vacuum tube having input and output sets of electrodes, one of said sets of electrodes being coupled to said tuned circuit, means for impressing on an input electrode of said tube a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuitto provide regeneration in said tuned circuit, means for impressing on an input electrode of said tube a negative feed-back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so proportioned that their joint efiect on said tuned circuit is that of an added negative resistance in said tuned circuit which approaches a value not greater than the value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply selective resonant characteristic for relatively high values of transconductance of said tube and the system is stabilized against regenerative oscillation.
3; A stabilized tuned system comprising, a tuned circuit having a given resistance, a vacuum tube having input and outputsets of electrodes, one of said sets of electrodes being coupled to said tuned circuit, means for impressing on an electrodes, means for coupling said sets of elec voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, means for impressing on an input electrode of said tube a negative feed-back .voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so proportioned that their joint effect on said tuned circuit is that of an added negative resistance in said tuned circuit which approaches the approximate value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply peaked resonant characteristic for relatively high values of transconductance of said tube and the system is stabilized against'regenerative oscillation.
4. A stabilized tuned system comprising, a tuned circuit having a given resistance, a vacuum tube having input and output sets of electrodes,
than the value of said given resistance over a substantial portion of said bias range, whereby said tuned circuit has a very sharply peaked resonant characteristic for relatively high values of transconductance of said tube-and. the system is stabilized against regenerative oscillation.
5. A stabilized tuned system comprising, at least one tuned circuit having a given resistance, a vacuum tube having input and output sets of electrodes, said output electrodes being coupled to said tuned circuit, means for impressing on an input electrode of said tube a positive feedback voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, means for impressing on an input electrode of said tube a negative feed-back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so proportioned that their joint efiect on said tuned circuit is that of an added negative resistance in said circuit which approaches the approximate value of said given resistance with increasing transconductance oi said tube, whereby said tuned circuit has a very sharply peaked response characteristic for relatively high values of transconductance of said tube and the system is stabilized against regenerative oscillation.
6. A stabilized tuned system comprising, at least one tuned circuit having a given resistance, a vacuum tube having input and output sets of electrodes, said output electrodes being coupled to said tuned circuit, means for impressing on one of said input electrodes a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, means for impressing on said one of said input electrodes of said tube a negative feedback voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so proportioned that their joint effect on said tuned circuit is that of an added negative resistance in said circuit which approaches the approximate value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply selective response characteristic for relatively high values of transconductance of said tube and said system is stabilized against regenerative oscillation.
'2. A stabilized tuned system comprising, at least one tuned circuit having a. given resistance, a vacuum tube having input and output sets of electrodes, a circuit common to an input set of electrodes and said output electrodes and including a resistor to provide a negative feed-back voltage, one of said sets of electrodes being coupled to said tuned circuit, means for impressing on an input electrode of said tube a positive feedback voltage derived from and varying in accordance with the voltage across said tuned air-- cuit to provide regeneration, the feed-back voltages being so proportioned that their joint effect on said tuned circuit is that of an added negative resistance in said tuned circuit which approaches the approximate value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply selective response characteristic for relatively high values of transconductance of said tube and the system is stabilized against regenerative oscillation.
8. A stabilized tuned system comprising, at least one tuned circuit having a given resistance, a vacuum tube having input and output sets of electrodes, one of said setsof electrodes being coupled to said tuned circuit, means comprising an inductance inductively coupled to said tuned circuit for impressing on an input electrode of said tube a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in-said tuned circuit, means for impressing on an input electrode of said tube a neg-,
ative feed-back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so propor'tioned that their joint effect on said tuned circuit is that of an added negative resistance in said tuned circuit which approaches the approximate value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply selective response characteristic for relatively high values of transconductance of said tube and the system is stabilized against regenerative oscillation.
9. In a high-frequency amplifier for amplifying signals with sharp selectivity against undesired signals including a vacuum tube, a load circuit for said tube including a stabilized tuned system comprising, a tuned circuit having a given resistance, a second vacuum tube having input and output sets of electrodes, one of said sets of electrodes being coupled to said tuned circuit, means for impressing on an input electrode of said second tube a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, means for impressing on an output electrode of said second tube a negative feed-back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so proportioned that their joint effect on their tuned circuit is that of an added negative resistance in said tuned circuit which approaches a value substantially equal to the value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply peaked resonance characteristic for relatively high values of transconductance of said tube and the system is stabilized against regenerative oscillation.
10. A stabilized tuned system comprising, a tuned circuit including a parallel-connected inductance and capacitance and having a given resistance, a vacuum tube having input and output sets of electrodes, a circuit common to an input set of electrodes and said output electrodes and including a resistor, said output electrodes being coupled to said tuned circuit through said resistor, means comprising an inductance inductively coupled to said inductance of said tuned circuit for impressing on an input electrode of said tube a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, said resistor comprising means for impressing on an input electrode of said tube a positive feed-back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said voltages being so proportioned that their joint effect on said tuned circuit is that of an added negative resistance in said tuned circuit which approaches the approximate value of said given resistance with increasing transconductance of said tube, whereby said tuned circuit has a very sharply peaked resonant characteristic for relatively high values of transconductance of said tube and the 1 system is stabilized against regenerative oscilla- 11. A stabilized tuned system comprising, at least one tuned circuit having a given resistance, a vacuum tube having input and output sets of electrodes, one of said sets of electrodes being coupled to said tuned circuit, means for impressing on an input electrode of said tube a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, means for impressing on an input electrode of said tube a negative feed-back voltage derived from and varying in accordance with the output current of said tube to provide degeneration, said circuit being so proportioned that 1 +129 is positive for relatively high values of transconductance of said tube, where the various parameters have the significance defined in the specification, whereby said tuned circuit has a very sharply selective resonant characteristic for relatively high values of transconductance of said tube' and the system is stabilized against regenerative oscillation.
12. A stabilized tuned system comprising, a tuned circuit having a given resistance, a vacuum tube having a predetermined maximum value of transconductance and input and output sets of electrodes, a circuit common to an input set of electrodes and said output set of electrodes and including a resistor, one of said sets of electrodes being coupled to said tuned circuit, means for impressing on an input electrode of said tube a positive feed-back voltage derived from and varying in accordance with the voltage across said tuned circuit to provide regeneration in said tuned circuit, means including said resistor for impressing on an input electrode of said tube a negative feed-back voltage derived from and varying in phase and magnitude primarily in accordance with the output current of said tube to provide degeneration, said circuit being so proportioned that the product of the value of said maximum transconductance and the value of said resistor is much greater than unity and the negative resistance introduced into said tuned circuit is approximately equal to said given resistance for relatively high values of transconductance of said tube, whereby said tuned circuit has a very sharply peaked resonant characteristic for values of transconductance of said tube approaching said maximum value and the system is stabilized against regenerative oscillation.
JOHN F. FARRINGTON.
US254013A 1939-02-01 1939-02-01 Stabilized tuned system Expired - Lifetime US2197239A (en)

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US254013A US2197239A (en) 1939-02-01 1939-02-01 Stabilized tuned system
GB879/40A GB534988A (en) 1939-02-01 1940-01-15 Stabilised tuned system for high-frequency oscillations
DEH161368D DE758656C (en) 1939-02-01 1940-01-18 Feedback circuit for bandwidth control

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2557154A (en) * 1949-03-24 1951-06-19 Halvor T Strandrud Stabilized negative impedance circuit
US2586365A (en) * 1947-03-20 1952-02-19 Westinghouse Electric Corp Means for eliminating spurious frequencies
US2594485A (en) * 1948-04-15 1952-04-29 Nowak Karl Circuit organization adapted to receive or amplify electric oscillations
US2650760A (en) * 1950-02-01 1953-09-01 Glenn W Bills Network calculating board
US2659776A (en) * 1949-05-13 1953-11-17 Nowak Karl Selective receiving and amplifying circuit
US2662939A (en) * 1949-04-02 1953-12-15 Nowak Karl High selectivity amplifier

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2586365A (en) * 1947-03-20 1952-02-19 Westinghouse Electric Corp Means for eliminating spurious frequencies
US2594485A (en) * 1948-04-15 1952-04-29 Nowak Karl Circuit organization adapted to receive or amplify electric oscillations
US2557154A (en) * 1949-03-24 1951-06-19 Halvor T Strandrud Stabilized negative impedance circuit
US2662939A (en) * 1949-04-02 1953-12-15 Nowak Karl High selectivity amplifier
US2659776A (en) * 1949-05-13 1953-11-17 Nowak Karl Selective receiving and amplifying circuit
US2650760A (en) * 1950-02-01 1953-09-01 Glenn W Bills Network calculating board

Also Published As

Publication number Publication date
GB534988A (en) 1941-03-25
DE758656C (en) 1953-05-18

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