US1943302A - Oscillator system - Google Patents

Description

. Jan. 16, 1934. J 5 ow OSCILLATOR SYSTEM Filed April 22; 1931 I INVENTOR. 30W 8.). $0M,

ATTORNEY Patented Jan. 16, 1934 TES PATENT OFFICE 1,943,302 osonm'ron SYSTEM Jennings B. Dow, Alexandria, Va. Application April 22,1931. Serial No. 532,056

16 Claims.

(Granted under the act of March a, 1883, as

amended April 30, 1928; 370 0. G. 757) 'My invention relates broadly to electron tube oscillator circuits..

One of the objects of my invention is to provide means for controlling the frequency of oscillation 5 of oscillating electron tube circuits.

Another object of my invention is to provide means for eliminating, for all practical purposes, the effect of variations in the anode voltage supply to oscillating electron tube circuits upon the frequency of oscillation.

Still another object of my invention is to provide means for automatically compensatingfor the effect upon frequency caused by variations in the anode voltage supply to oscillating electron tube circuits.

Other and further objects of my invention reside in the arrangement of circuit for constant frequency oscillation generators as set forth more fully in the specification hereinafter following by reference to the accompanying drawing,

which: Figure 1 shows one form of circuit incorporating the features of my invention; Fig. 2 illustrates the principles employed in obtaining automatic compensation for variations in frequency caused by changes in the anode voltage supply of oscillating electron tube circuits; and Fig. 3 shows the results of actual measurements of the automatic compensating effect obtained by the method illustrated in Fig. 2 upon the circuit of Fig. 1.

Fig. 1 illustrates my invention embodied in a circuit arranged for the generation of high frequency oscillations.

The circuit shows an electron tube including a cathode l, a control grid 2,

an inner anode 3, and an outer anode 4. The

resonant circuit 5 which substantially fixes the frequency of oscillation includes the split-stator variable capacity 6 and the inductance '7. The

split-stator condenser 6 has two sets of plates'Ga.

and 6b capacitatively related to a third or intermediate set of plates 60.

A blocking capacity 8 and the leak resistance 9 are connected as shown. A neutralizing capacity is shown at 10. Battery 11 supplies the necessary cathode heating energy, whereas battery 12 supplies the inner and outer anode potentials which are adjustable through the medium of taps 18 and 19 on the potentiometer 13.

Battery 12 is fixedly connected to potentiometer 13.

Obviously, the power supply may be taken from direct or alternating current generators.

14 and 15 are impedances that may take many forms although I prefer to employ resistances or inductances.

By-pass capacities are shown at 16 connected across the power supply circuits tothe inner anode 3 and the outer anode 4. The output energy from the circuit, as shown in Fig. 1, may be delivered to a work circuit by connecting or coupling such work circuit to tuned circuit 5, or to impedance'l4 or 15.

By associating with the electron stream of any conventional oscillating tube circuit, an auxiliary element, such as the outer anode element 4, and connecting it with a source of potential preferably through an impedance 15, the frequency of oscillation may be varied over quite a wide range by varying the potential applied to this auxiliary element. I have found that the magnitude of change in frequency for a given change in potential of the auxiliary element as well as the direction of change of frequency, i. e., whether the fre quency increases or decreases with an increase in the potential of the auxiliary element, is a function of the-potentials applied to the other elements of the tube, the potential of the auxiliary element, and the position of the auxiliary element with respect to the other elements. I have found that this effect may be utilized to great practical advantage in oscillating electron tube circuits.

Fig. 2 illustrates one manner in which the change in frequency caused by varying the po- 'tential of an auxiliary element associated with the electron stream of an oscillating electron tube circuit may be utilized. The ordinates represent changes in frequency in cycles above or below a given frequency to which such a circuit as that shown in Fig. 1 may be initially adjusted. The changes in frequency involved in the curves plotted in Fig.2 are those which result from varying taps 18, 19 and 20 on potentiometer 13 shown in Fig. 1. These changes in frequency are therefore the direct result of varying the inner and outer anode voltages from the initially adjusted values represented by points 18a, 19a and 20a, in Fi 2.

By making a suitable choice of initially adjusted voltages for the inner and outer anodes, I have found that when tap '18 is varied, meanwhile keeping the position of taps 19 and 20 fixed, the frequency at which the circuit of Fig. l oscillates varies in accordance with curve 181), and that when tap 19 is varied, meanwhile keeping the pozition of taps 18 and 20 fixed, the frequency varies in accordance with curve 19b. It will be noted that the slopes of curves 18b and 19b are opposite in sense. I have found that the slopes of these curves at the points of crossing the axis' corresponding to zero change in frequency, may

be varied over wide limits by a suitable choice of the initially adjusted voltages corresponding to points 18a and 19a. Obviously then, if such a choice of initially adjusted voltages is made as will make the slopes at points 18a and 19a exactly equal and opposite in sense, no appreciable change in frequency would be expected to take place when varying tap 20 of Fig. 1 over quite a wide range. It is therefore axiomatic that in or der to avoid changes in frequency due to momentary variations in the anode voltage supply for vacuum tube oscillators of the two anode type, such a choice of anode voltages should be made as will make the tangents 18c and 19c of equal and opposite slope.

Fig. 3 shows the observed results of an actual application of the principles disclosed in the preceding paragraph. Curves 18d, 19d and 20d of Fig. 3 show respectively the actual changes in the frequency of oscillation of the circuit of Fig. 1 when varying taps 18, 19 and 20. The overall compensating effect is shown by curve 20d.

The resonant circuit 5 is adjusted to a selected frequency by varying the spacial relation of the intermediate set of plates 60 withrespect to the sets of plates 6a and 6b. When the selected frequency is obtained, the position of the variable capacity 6 is set and thereafter the circuits continue to generate-oscillations at the selected fre-. quency substantially independent of changes or variations in the potential supplied to the inner and outer anodes.

I have made measurements upon the circuit of Fig. 1 which show a change in frequency of only 4 cycles in 4,500,000 for a 25 per cent change in the voltage of battery 12. This change in frequency is less than 0.0001 per cent for a 25 per cent change in the anode voltage supply and indicates the great advantage to be gained in the use of my invention wherever a high degree of precision as to frequency maintenance in vacuum tube oscillators is required.

As variations in the frequency of oscillation of electron tube circuits caused by variations in the anode voltage supply are a frequent source of trouble, particularly in circuits of the self-oscillating types, and especially when the precision maintenance of frequency is essential, the principles of my invention have many important applications.

The circuit of Fig. 1 is only one of many forms of oscillating electron tube circuits to which the present invention is applicable. I have employed my invention with all conventional oscillating electron tube circuits including those of the piezo electric crystal controlled type as well as the selfoscillating type.

While I have described my invention in certain of its preferred embodiments, I desire that it be understood that modifications may be made and that no limitations upon my invention are intended other than are imposed by the scope of the appended claims.

The invention herein disclosed may be manufactured and used by or for the Government of the United States for governmental purposes without the payment of any royalties thereon.

What I claim as new and desire to secure by Letters Patent of the United States is as follows:

1. In an oscillating electron tube circuit including an electron tube having a cathode element, a control grid element, an anode element and an auxiliary element associated with the electron stream of said tube, means including said auxiliary element and the main source of electric energy for said oscillating electron tube circuit for compensating for changes in the frequency of oscillation arising from variations in the voltage of the said main source of electric energy, through the application of such increments of potential to said auxiliary element as substantially neutralize the tendency to frequency change caused by simultaneous increments in potential applied to said anode element.

2. In an oscillating electron tube circuit including an electron tube with at least two anode elements associated with a commonsource of electric energy, the method of minimizing changes in the frequency of oscillation arising from variations in the voltage of said common source of electric energy which consists in the selection of such operating potentials for said anodes as to cause the change in frequency due to a change in the voltage applied to one of said anodes to be substantially compensated for by'the oppositeeffect upon frequency of a change in voltage applied to the second of said anodes.

3. In an oscillating electron tube circuit including an electron tube having a cathode element a control element and anode element associated in circuit for the generation of oscillations, an auxiliary element associated with the electron stream of said tube and having a connection to an impedance to one extremity of which a variable voltage is applied, and means including a device for applying to said anode element certain selected voltages, the values of which are a function of said variable voltage whereby the frequency of oscillation of said electron tube circuit is maintained substantially constant.

4. In an oscillating electron tube circuit including an electron tube containing a cathode, a control grid, and two additional elements, a source of potential and connections between said 115 source of potential and said two additional elements, the potentials for the said two additional elements being selected for causing the frequency of oscillation to remain substantially constant for changes in the potential of said potential 120 source due to the compensating effect of the said two additional elements.

5. In an oscillating electron tube circuit including an electron tube containing a cathode, a control grid, an inner anode and an'outer anode, 125 a circuit between said inner and outer anodes, a common potential source connected in said circuit, said source delivering such operating potentials to said anodes for causing the frequency of oscillation to remain substantially constant for changes in the potential of said common potential source due to the compensating effect of the said anodes.

6. In an oscillation generator, an electron tube including a cathode, a control grid and at least two additional elements, a resonant circuit included between said cathode and one of said additional elements, a source of electric energy included in circuit between said cathode and one of said additional elements, and means including one other of said additional elements and a connection to said source of electric energy for selectively applying such potentials to saidlast mentioned element as cause the frequency of oscillation to be substantially constant for varl- 145 ations in the voltage of said source oi. electric energy.

'7. In an oscillation generator, an electron tube including a cathode element, a control grid element and at least two additional elements, a 15 resonant circuit included between two of said elements for determining the frequency of oscillation, a source of electric energy included in circuit between said cathode and one of said additional elements and means including one other of said additional elements and a connection to said source of electric energy for applying such variations of potential to said last mentioned additional element as will substantially counteract the frequency change tendency due to variations in the voltage of said source of electric energy.

8. In an oscillation generator comprising an electron tube having a cathode, a control grid, an anode and an additional element, the method of compensating for changes in the frequency of oscillation resulting from variations in potential of the source of anode potential which consists in so choosing the potentials of the anode and additional element that the net eifect upon frequency caused by a change in the potential of said anode potential source is substantially zero.

9. In an oscillating electron tube system comprising an electron tube having a cathode, a control grid, an inner anode and a main outer anode, the method of compensating for changes in the frequency of oscillation resulting from variations in potential of the source of anode potential, which comprises applying to the inner anode a potential proportional at all times to the potential applied to the man anode and of such value that the change in frequency due to a change in the outer anode potential will be substantially compensated by the efiect of a proportional change in the inner anode potential.

10. In an oscillation generator compris'ng an electron tube having at least four separate elements, the method of compensating for changes in the frequency of oscillation which comprises applying to one of said elements a positive potential, and applying to another one of said elements a diiferent positive potential proportional at all times to the first-mentioned applied potential and of such value that the change in frequency due to a change in the first mentioned positive potential is substantially compensated by an opposite effect upon frequency caused by the proportional change in the second mentioned positive potential.

11. In an oscillating electron tube system comprising an electron tube having a cathode, a control grid, an anode and an additional element, a resonant circuit connected between said cathode and said control grid, an output circuit and a source of anode potential, the method of compensating for changes in the frequency of oscillation resulting from variations in potential of the source of anode potential which comprises applying to said additional element a potential proportional to the potential appl'ed to the anode and of such a value that the frequency change tendency caused by a variation of the anode potentialis substantially offset by an opposite frequency change tendency caused by a proportional variation of the potential of the additional element.

12. In an oscillating electron tube circuit having an electron tube containing a cathode and two electrodes electro-positive with respect to said cathode,the method of stabilizing the frequency of oscillation which consists in applying to the said two electrodes such electro-positive potentials as to cause an increase in frequency due to an increase in potential applied to one of said electrodes to be substantially compensated by a decrease in frequency resulting from a change in potential applied to the other of said electrodes.

13. In an oscillation generator including an electron tube containing a cathode and two electrodes associated with a common potential source, the method of minimizing changes in the frequency of oscillation arising from changes in the potential of said common source which consists in the selection of such operating potentials for said two electrodes as to cause the change in frequency due to a change in the potential applied to one of said electrodes to be substantially offset by the opposite effect upon frequency caused by a change in potential applied to the other of said electrodes.

14. In an oscillation generator having an electron tube including a cathode element, a control element and two anode elements, the method of avoiding frequency modulation resulting from changes in a common anode potential source which consists in so choosing the ratio of the potentials applied to the two anodes that the frequency remains substantially constant due to the compensating eilect of the two anodes.

15. In an oscillation generator having an electron tube containing a cathode and at least two elements electro-positlve with respect to said cathode, the method of compensating for a change in frequency due to a change in the electro-positive potential of one of said elements which consists in applying such change in the electro-positive potential of the other of said elements as to cause an opposite frequency change tendency from that caused by the change in electro-positive potential of the first mentioned element.

16. In an oscillating electron tube circuit including an electron tube having a cathode and at least two elements electro-positive with respect to said'cathode by virtue'of their association with a common power source, the method of minimizing changes in the frequency of oscillation arising from variations in the voltage of said common power source which consists in the selection of such electro-positive potentials for said elements as to cause the change in frequency due to a change in the electro-positive potential of one of said elements to be opposite

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