US2265016A - Electrical oscillation generator - Google Patents
Electrical oscillation generator Download PDFInfo
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- US2265016A US2265016A US321380A US32138040A US2265016A US 2265016 A US2265016 A US 2265016A US 321380 A US321380 A US 321380A US 32138040 A US32138040 A US 32138040A US 2265016 A US2265016 A US 2265016A
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03C—MODULATION
- H03C3/00—Angle modulation
- H03C3/10—Angle modulation by means of variable impedance
- H03C3/12—Angle modulation by means of variable impedance by means of a variable reactive element
- H03C3/14—Angle modulation by means of variable impedance by means of a variable reactive element simulated by circuit comprising active element with at least three electrodes, e.g. reactance-tube circuit
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- a further object of the invention is to provide means whereby the control of the frequency of the oscillations is effected without correspondingly great changes in their amplitude.
- the action of the control tube is made to simulate a pure reactance' which imparts neither positive nor negative resistance of any considerable amount into the oscillator circuit.
- this object is secured by providing a tuned tank, or frequency determining circuit in the'plate circuit of the oscillator tube and means whereby energy may be fed from the plate circuit of the controltube into the frequency'determining circuit which is 90 degrees out of phase with the energy in such circuit.
- grid voltage of the proper phase to sustain the oscillations may be generated by means of a tickler circuit. It is a further object of the invention to utilize the phase shift produced by the leakage inductance of the grid tickler coil in association with another phase shift. to produce a voltage on the grid of the control tube which may be 90 out of phase with the energy in thetuned plate circuit. When this voltage is amplified in the control tube, it willappearin the plate circuit as a simulation of a pure reactance.
- Another object of the invention is to provide means for securing the desired phase shift in the energy supp-lied to the frequency determining circuit by the control tube, in the form of a plurality of phase shifting elements connected in V series in the grid circuit of the control tube, one
- phase'shift secured by the resistor is thus additive to' that secured in the tickler coil and a total phase shift of or more may thus be readily secured.
- this auxiliary phase shifting'means comprises a resistor having one end connected to the tuned oscillator circuit and its other end connected to the plate of the control tube. It will also be understood that the phase shifting means described may be used in any desired combinations, the total phase shift being secured in the grid circuit of the control tube or a portion only being secured in the grid circuit andthe balance secured in its plate circuit.
- Fig. 1 is a schematic circuit diagram of an electron discharge tube oscillator arrangement embodying the invention
- Fig. 2 is a schematic circuit diagram of a modified form of oscillatorarrangement embodying the invention
- r Fig. 3 shows schematically a modified form of input circuit for the control tube shown in Fig. 1.
- the invention is shown as comprising a generator I of electrical oscillations of ultra-high-frequencies, a control unit 2 for controlling the frequency of the oscillations, and a source of control voltage 3 for varying the effect of the control unit 2. It has been found that when arranged for the generation of frequencies of the order of megacycles, especial attention must be given to the design of the oscillator and its associated circuits.
- the resonant plate circuit may have lumped constants comprising the coil LI and the fixed condenser Cl, as shown, a variable condenser being unsuitable for tuning clue to the varying L-C ratio, which gives much more stability at one end of the tuning range than at the other, thereby providing greatly exaggerated variations over the range of tuning control of the control tube.
- condenser CI of a fixed value and varying the inductance of coil Ll so as to change its permeability, as by means of a powdered ferro magnetic core, as indicated at 4, substantially equal percentage effects of the oscillator tuning ar secured throughout the range of tuning.
- An additional advantage of efiecting the tuning of the oscillator by change of permeability lies in a more simplified switching procedure where different coils are used for tuning over difierent frequency ranges. Each such coil may have attached to it permanently its own tuning condenser, thus forming a circulating path of low resistance and when the oscillator is used in a superheterodyne receiver, the only switching connections required are those at the grids and plates of the tubes.
- ferromagnetic cores known under the trade name Aladdinite are very satisfactory. These cores are made from a synthetically produced ferromagnetic mass powder consisting substantially wholly of "magnetic oxide of iron in the form of minute particles, substantially all of which, as they appear under a microscope, are of generally rounded form. These particles are preferably molded into cores by mixing with several per cent of Bakelite as a binder.
- the grid of the oscillator VTI is, shown as being energized through condenser C2 and coils L2 and L3 connected in series.
- ,Stable oscillators which may be calibrated to oscillate at definite frequencies are highly desirable.
- the mutual inductance of the tickler coil with coil L] of the tank circuit is designated as L2 and its leakage inductance by the reference character L3.
- the ,ratio between these two inductances L2-L3, as well as their .actual values may vary between wide limits.
- a desirable oscillator for use with a control tube in a system of this type would be one without phase angle, that is, one in which the plate energy exactly reinforces the grid energy with no reactive component, This ideal condition would require .a vacuum tube which is a simple genera-toner negative resistance, an arrangement which may be closely approximated in practice. If the oscillator is well designed with respect to this feature, its plate supply voltage may vary within rather wide limits without substantially affecting the frequency of the oscillations generated, although their amplitude will be affected to some extent.
- control tube which modifies the frequency of the oscillations, these are exactly the opposite. It is desired that this generate pure reactance only and neither negative nor positive resistance. It is necessary, therefore, that the control tube be coupled into the tube circuit to be controlled in such manner that phase shifts of considerable value are secured either in the energy feed to the grid or the energy of the plate circuit, or both.
- a standard means of shifting phase is to place a reactance in series with a resistance and take the voltage drop across the reactance. In practice, only a limited phase shift can occur, since a 90 shift would require an infinite resis- In practice, approximations of 90 can be reached as a limit, but since at radio frequencies only relatively small resistances can be employed, it is only practical to secure a or phase shift instead of the desirable
- a further phase shift may be secured by connecting another phase shifting network in series with the first, the second network being capable of producing an additional phase shift that can approximate 90. Since the two phase shifting means in cascade have the possibility of approximating a phase shift, it is possible to utilize a portion of each in any desired combination to produce a resultant phase shift of 90 which, of course, simulates a pure reactance.
- the grid receives charging current through Ll.
- the grid current at the end of L2 is thus exactly 180 out of phase with the circulating current in Ll.
- the current Before reaching the grid of tube VTI, the current must pass through some series leakage inductance, represented by L3, which produces a reactance of rather small amount, but which is quite effective due to the very heavy current flowing through it.
- energy is supplied which is so phased in relation to that of the plate tank circuit as to cause the tube to oscillate.
- the amount of phasing due to L3 may be varied as desired by making it of the proper value, even, if necessary, by winding an additional uncoupled coil in series with the grid, or, by more loosely coupling L2, and by making this coll larger we can increase the leakage inductance to any desired amount without having any physical coil, as represented by L3.
- the grid energy of tube 'VT2 may now be further phased in the same direction by means of the circuit comprising resistor R2 and the grid-cathode capacity of the control tube VTZ.
- condensers C2 and C3 are merely for the purpose of blocking the direct current and are so large that their phasing eifect is negligible.
- phase relations may be established so that the control tube VT2 acts substantially as a pure reactance in controlling the frequency of the oscillations generated by tube VTI. Under these conditions the energy fed into the frequency determining circuit LlCl by the control tube is 90 out of phase with the circulating current in this circuit.
- phase angle may be overcontrolled past 90 and we can observe the resultant resistive component as being either positive or negative by noting the change in the oscillator grid current.
- resistor R4 in series with the plate of tube VT2 and the tank circuit comprising coil LI, in which the preliminary phasing is secured by resistor R2 alone at the input of the tube and additional phasing secured in an additive sense by R4.
- a suitable short circuiting switch may be provided therefor, as indicated at 5.
- the control tube VT2 is provided with the usual supply voltage, its inner grid being given a normal bias of approximately -6 volts by connecting its cathode to the bleeder resistor R5 at a point approximately this number of volts above ground.
- This permits the operation of the tube at the mid-point of its control range, as determined by plotting a curve of grid bias against oscillator frequency, which results in an S-shaped curve, so that we secure operation about the mid.- point thereof.
- This mid-point usually occurs at about 6 volts and if this value is changed to -3 volts, the tube becomes much more effective and if changed to -9 volts, the control tube becomes practically ineffective.
- the source of control voltage 3 comprises a resistor R6 connected across the terminals of a battery B, and a contact 6 adjustable along R5 and connected to the inner grid of VTZ through a circuit comprising resistor R3.
- adjustable contact 6 is adjusted until the grid bias of the inner grid of control tube V'I'2 has a normal value of approximately 6 volts.
- the oscillator frequency is then adjusted to approximately the correct value by adjustment of the permeability tuning control 4. Adjustment of the oscillator frequency to a higher or lower value through the action of the control tube may then be readily effected by adjustment of the contact 6 along resistor R6.
- the output of the oscillator may be utilized in any desired manner where radio frequenc carrier currents are required as, for example, in connection with the mixing device of a superheterodyne receiver, or by impressing audio modulations on the grid of the control tube, a frequency modulated transmitter is provided.
- Fig. 2 shows a modified form of the invention in which an alternative arrangement for securing the desired 90 phase shift is provided.
- a phase shift of for example, may be secured in the circuit comprising the series connection of resistor R1 and condenser C5 and a further phase shift of the order of 70 in the same direction secured in the circuit comprising the series connection of resistor R8 and condenser C6. It is thus possible to pick out a resistance value of resistor R8 by means of the adjustable contact 1 which gives the desired phase shift and the control tube VT3 will then act as a pure reactance connected across the frequency determining circuit comprising LI and Cl.
- Fig. 1 shows a modified form of the invention in which an alternative arrangement for securing the desired 90 phase shift.
- the degree of control of the frequency generated is regulated by varying the grid voltage of the control tube by means of the adjustable contact 6. Since the resistors R1 and R8 must be given very large values in order to produce the required phase shifts, the voltage available for operating the grid of the control tube is reduced to such a low value that only a small control of the plate current is secured and hence only a very limited degree of frequency control is possible.
- Fig. 3 shows a modified form of input circuit for the control tube VT2 of Fig. 1 to provide for frequency modulation of the oscillator output.
- This circuit comprises a microphone M connected to the inner grid of the control tube through the choke coil CH.
- the output of the oscillator tube is frequency modulated in accordance with the voice modulations impressed on the microphone.
- the tank circuit of the oscillator may be coupled to a transmitting antenna (not shown) by any known type of transmission line.
- Means for generating electrical oscillations including, in combination, an electron discharge tube oscillator having a frequency determining circuit, an electron discharge control tube having its plate connected to said circuit, and means coupling the control tube and the frequency determining circuit including a plurality of phase shifting elements so arranged as to be capable of feeding energy from the control tube into the frequency determining circuit which is 90 out of phase with the energy in said circuit, one of said phase shifting elements consisting of an impedance connected in series between the plate of the control tube and the high potential side of the frequency determining circuit.
- Means for generating electrical oscillations including, in combination, an electron discharge tube oscillator having a frequency determining circuit, a circuit connected to the grid of the oscillator tube including a feed-back coil coupled to said frequency determining circuit, an electron discharge control tube having its Plate connected to the frequency determining circuit, and
- said coupling means comprising a coil connected in series witlrthe feed-back coil.
- Means for generating electrical oscillations including, in combination, an electron discharge tube oscillator having a frequency determining circuit, a circuit connected to the grid of the oscillator tube including a feed-back coil coupled to said frequency determining circuit, an electron discharge control tube having its plate connected to the frequency determining circuit, and means coupling the control tube and the frequency determining circuit so arranged as to be capable of feeding energy from the control tube into the frequency determining circuit which is 90 out of phase with the energy in said circuit, said coupling means comprising a coil and resistor connected in series with the feed-back coil.
- Means for generating electrical oscillations including, in combination, an electron discharge tube oscillator having a frequency determining circuit, a circuit connected to the grid of the oscillator tube including a feed-back coil coupled to said frequency determining circuit, an electron discharge control tube, a circuit comprising a resistor connecting the plate of the control tube to the frequency determining circuit, and additional means coupling the control tube and the frequency determining circuit so arranged as to be capable of feeding energy from the control tube into the frequency determining circuit which is 90 out of phase with the energy in said circuit, said additional coupling mean comprising a coil connected in series with the feed-back coil.
- Means for generating electrical oscillations including, in combination, an electron discharge tube oscillator having a frequency determining circuit, a circuit connected to the grid of the oscillator tube including a feed-back coil coupled to said frequency determining circuit, an electron discharge control tube, a circuit comprising a resistor connecting the plate of the control tube to the frequency determining circuit, and additional means coupling the control tube and the frequency determining circuit so arranged as to be capable of feeding energy from the control tube into the frequency determining circuit which is 90 out of phase with the energy in said circuit, said additional coupling means comprising a resistor connected in series with the feed-back coil.
- Means for generating electrical oscillations including, in combination, an electron discharge tube. oscillator having a frequency determining circuit, a circuit connected to the grid of the oscillator tube including a feed-back coil coupled to said frequency determining circuit, an electron discharge control tube, a circuit comprising a resistor connecting the plate of the control tube to the frequency determining circuit, and additional means coupling the control tube and the frequency determining circuitso arranged as to be capable of feeding energy from the control tube into the frequency determining circuit which is 90 out of phase with the energy in said circuit, said additional coupling means comprising a coil and resistor connected in series with the feedback coil.
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Description
Dec. 2,- 1941.
S. Y. WHITE ELECTRICAL OSCILLATION GENERATOR Filed F eb 29, 1940 e w w on E TW N ,N R w m ma m Patented Dec. 2, 1941 UNITED ST PATENT OFFlCE 6 Claims.
pending application Serial No. 321,377, filed February'29', 1940, of which the present application is a continuation in part. 1
A further object of the invention is to provide means whereby the control of the frequency of the oscillations is effected without correspondingly great changes in their amplitude. For this purpose the action of the control tube is made to simulate a pure reactance' which imparts neither positive nor negative resistance of any considerable amount into the oscillator circuit. In the illustrated embodiment of the'invention, this object is secured by providing a tuned tank, or frequency determining circuit in the'plate circuit of the oscillator tube and means whereby energy may be fed from the plate circuit of the controltube into the frequency'determining circuit which is 90 degrees out of phase with the energy in such circuit. Where the oscillations are generated by means of a vacuum tube whose plate circuit is tuned, grid voltage of the proper phase to sustain the oscillations may be generated by means of a tickler circuit. It is a further object of the invention to utilize the phase shift produced by the leakage inductance of the grid tickler coil in association with another phase shift. to produce a voltage on the grid of the control tube which may be 90 out of phase with the energy in thetuned plate circuit. When this voltage is amplified in the control tube, it willappearin the plate circuit as a simulation of a pure reactance.
Another object of the invention is to provide means for securing the desired phase shift in the energy supp-lied to the frequency determining circuit by the control tube, in the form of a plurality of phase shifting elements connected in V series in the grid circuit of the control tube, one
of said elements constituting a resistor. The phase'shift secured by the resistor is thus additive to' that secured in the tickler coil and a total phase shift of or more may thus be readily secured.
' In any case where it may for any reason be undesirable to secure the total desired phase shift in the grid circuit of the control tube, it is a still further object of the invention to provide means in the plate circuit of the control tube for securing a portion of the total phase shift. In one illustrated embodiment of the invention, this auxiliary phase shifting'means comprises a resistor having one end connected to the tuned oscillator circuit and its other end connected to the plate of the control tube. It will also be understood that the phase shifting means described may be used in any desired combinations, the total phase shift being secured in the grid circuit of the control tube or a portion only being secured in the grid circuit andthe balance secured in its plate circuit. Other objects of the invention will become apparent to those skilled in the art as the description thereof proceeds. For the better understanding of the invention, however, reference is made to the accompanying drawing in which:
Fig. 1 is a schematic circuit diagram of an electron discharge tube oscillator arrangement embodying the invention;
Fig. 2 is a schematic circuit diagram of a modified form of oscillatorarrangement embodying the invention; and r Fig. 3 shows schematically a modified form of input circuit for the control tube shown in Fig. 1.
Referring to Fig. l, the invention is shown as comprising a generator I of electrical oscillations of ultra-high-frequencies, a control unit 2 for controlling the frequency of the oscillations, and a source of control voltage 3 for varying the effect of the control unit 2. It has been found that when arranged for the generation of frequencies of the order of megacycles, especial attention must be given to the design of the oscillator and its associated circuits.
Experience has shown that the cathode of the are made to tunethe grid circuit, conditions almost invariably occur where the system will commence oscillating at a parasitic frequency determined by the constants of the plate circuit.
It is,'therefore, preferred to use an oscillator whose plate circuit is tuned, and a tickler circuit provides a grid voltage of the proper phase to generate the oscillations. The resonant plate circuit may have lumped constants comprising the coil LI and the fixed condenser Cl, as shown, a variable condenser being unsuitable for tuning clue to the varying L-C ratio, which gives much more stability at one end of the tuning range than at the other, thereby providing greatly exaggerated variations over the range of tuning control of the control tube. By making condenser CI of a fixed value and varying the inductance of coil Ll so as to change its permeability, as by means of a powdered ferro magnetic core, as indicated at 4, substantially equal percentage effects of the oscillator tuning ar secured throughout the range of tuning. An additional advantage of efiecting the tuning of the oscillator by change of permeability lies in a more simplified switching procedure where different coils are used for tuning over difierent frequency ranges. Each such coil may have attached to it permanently its own tuning condenser, thus forming a circulating path of low resistance and when the oscillator is used in a superheterodyne receiver, the only switching connections required are those at the grids and plates of the tubes. It is found that the ordinary hydrogen reduced iron cores are not at all suitable for permeability tuning at frequencies of the order of 100 megacycles. However, it has been found that ferromagnetic cores known under the trade name Aladdinite are very satisfactory. These cores are made from a synthetically produced ferromagnetic mass powder consisting substantially wholly of "magnetic oxide of iron in the form of minute particles, substantially all of which, as they appear under a microscope, are of generally rounded form. These particles are preferably molded into cores by mixing with several per cent of Bakelite as a binder.
The grid of the oscillator VTI is, shown as being energized through condenser C2 and coils L2 and L3 connected in series. ,Stable oscillators which may be calibrated to oscillate at definite frequencies are highly desirable. There is a 180 phase difference between the plate and grid voltages of the tube, and. where a, tickler coil is used to provide the feed-back, this is always given a polarity such as to reverse the phase of the grid relative to that of the plate. The mutual inductance of the tickler coil with coil L] of the tank circuit is designated as L2 and its leakage inductance by the reference character L3. Depending upon the physical placement of the component parts, the length of leads employed and numerous other factors, the ,ratio between these two inductances L2-L3, as well as their .actual values, may vary between wide limits.
A desirable oscillator for use with a control tube in a system of this type would be one without phase angle, that is, one in which the plate energy exactly reinforces the grid energy with no reactive component, This ideal condition would require .a vacuum tube which is a simple genera-toner negative resistance, an arrangement which may be closely approximated in practice. If the oscillator is well designed with respect to this feature, its plate supply voltage may vary within rather wide limits without substantially affecting the frequency of the oscillations generated, although their amplitude will be affected to some extent.
With respect to the requiretance and a perfect reactance.
merits of the control tube which modifies the frequency of the oscillations, these are exactly the opposite. It is desired that this generate pure reactance only and neither negative nor positive resistance. It is necessary, therefore, that the control tube be coupled into the tube circuit to be controlled in such manner that phase shifts of considerable value are secured either in the energy feed to the grid or the energy of the plate circuit, or both.
A standard means of shifting phase is to place a reactance in series with a resistance and take the voltage drop across the reactance. In practice, only a limited phase shift can occur, since a 90 shift would require an infinite resis- In practice, approximations of 90 can be reached as a limit, but since at radio frequencies only relatively small resistances can be employed, it is only practical to secure a or phase shift instead of the desirable A further phase shift, however, may be secured by connecting another phase shifting network in series with the first, the second network being capable of producing an additional phase shift that can approximate 90. Since the two phase shifting means in cascade have the possibility of approximating a phase shift, it is possible to utilize a portion of each in any desired combination to produce a resultant phase shift of 90 which, of course, simulates a pure reactance.
Referring to Fig. 1 and considering the frequency determining circuit which is grounded at the lower end of coil LI, the grid receives charging current through Ll. The grid current at the end of L2 is thus exactly 180 out of phase with the circulating current in Ll. Before reaching the grid of tube VTI, the current must pass through some series leakage inductance, represented by L3, which produces a reactance of rather small amount, but which is quite effective due to the very heavy current flowing through it. At the grid of VTI, energy is supplied which is so phased in relation to that of the plate tank circuit as to cause the tube to oscillate. The amount of phasing due to L3 may be varied as desired by making it of the proper value, even, if necessary, by winding an additional uncoupled coil in series with the grid, or, by more loosely coupling L2, and by making this coll larger we can increase the leakage inductance to any desired amount without having any physical coil, as represented by L3. With this energy, preliminarily phased, as described, the grid energy of tube 'VT2 may now be further phased in the same direction by means of the circuit comprising resistor R2 and the grid-cathode capacity of the control tube VTZ. It will be understood that condensers C2 and C3 are merely for the purpose of blocking the direct current and are so large that their phasing eifect is negligible.
By a suitable choice of the values of L3 and R2 it is possible to produce the desired degree of reactance with a maximum stability of the oscillator and a minimum loading effect due to the connection of the control tube VTZ with the oscillator. Considerable difliculty is met with in networks of this type where the oscillator is one used in a superheterodyne receiver and is re-- quired to supply voltage to the mixer device as well as having a control tube, such as VT2, connected across it. The system is prone to be so heavily overloaded as to cease oscillation entirely, or if excessive amounts of negative resistance are generated in the control tube, parasitic oscillations are likely to occur at a'frequency determined by some tuned loop, which may be almost anywhere in the system, or even coupled rather loosely to the circuit system. With the circuit arrangement described, phase relations may be established so that the control tube VT2 acts substantially as a pure reactance in controlling the frequency of the oscillations generated by tube VTI. Under these conditions the energy fed into the frequency determining circuit LlCl by the control tube is 90 out of phase with the circulating current in this circuit. It can be determined when this phase relationsh'ip exists by energizing the control tube and noting that the frequency changes but the strength of oscillation as evidenced by the grid current of the oscillator does not change. The phase angle may be overcontrolled past 90 and we can observe the resultant resistive component as being either positive or negative by noting the change in the oscillator grid current.
Instead of securingthe double phasing effect by the arrangement previously described, it may be secured in a somewhat satisfactory manner by the inclusion of a resistor R4 in series with the plate of tube VT2 and the tank circuit comprising coil LI, in which the preliminary phasing is secured by resistor R2 alone at the input of the tube and additional phasing secured in an additive sense by R4. In cases where it may be desired to eliminate the eifect of resistor R4, a suitable short circuiting switch may be provided therefor, as indicated at 5.
The control tube VT2 is provided with the usual supply voltage, its inner grid being given a normal bias of approximately -6 volts by connecting its cathode to the bleeder resistor R5 at a point approximately this number of volts above ground. This permits the operation of the tube at the mid-point of its control range, as determined by plotting a curve of grid bias against oscillator frequency, which results in an S-shaped curve, so that we secure operation about the mid.- point thereof. This mid-point usually occurs at about 6 volts and if this value is changed to -3 volts, the tube becomes much more effective and if changed to -9 volts, the control tube becomes practically ineffective.
The source of control voltage 3 comprises a resistor R6 connected across the terminals of a battery B, and a contact 6 adjustable along R5 and connected to the inner grid of VTZ through a circuit comprising resistor R3. By providing a voltage control on the inner grid of the control tube over a range of :3 volts by the adjustment of contact S, the oscillator frequency may be varied over the desired range of frequencies.
In the operation of the oscillator device, the
Fig. 2 shows a modified form of the invention in which an alternative arrangement for securing the desired 90 phase shift is provided. In this arrangement a phase shift of, for example, may be secured in the circuit comprising the series connection of resistor R1 and condenser C5 and a further phase shift of the order of 70 in the same direction secured in the circuit comprising the series connection of resistor R8 and condenser C6. It is thus possible to pick out a resistance value of resistor R8 by means of the adjustable contact 1 which gives the desired phase shift and the control tube VT3 will then act as a pure reactance connected across the frequency determining circuit comprising LI and Cl. As in the case of Fig. 1, the degree of control of the frequency generated is regulated by varying the grid voltage of the control tube by means of the adjustable contact 6. Since the resistors R1 and R8 must be given very large values in order to produce the required phase shifts, the voltage available for operating the grid of the control tube is reduced to such a low value that only a small control of the plate current is secured and hence only a very limited degree of frequency control is possible.
Several oscillator-control tube combinations are well known in the art, and all the suitable ones were carefully investigated at 150,000 kilocycles. It was found that ranges of control did not exceed 0.4 per cent and the action of the control tubes quenched the oscillator. With the arrangement herein shown in Fig. 1, control ranges of 2 per cent were obtainable without quenching the oscillator or generating parasitics.
Fig. 3 shows a modified form of input circuit for the control tube VT2 of Fig. 1 to provide for frequency modulation of the oscillator output. This circuit comprises a microphone M connected to the inner grid of the control tube through the choke coil CH. In the operation of this form of the invention, the output of the oscillator tube is frequency modulated in accordance with the voice modulations impressed on the microphone. The tank circuit of the oscillator may be coupled to a transmitting antenna (not shown) by any known type of transmission line.
I have described what I believe to be the best embodiments of my invention. I do not wish, however, to be confined to the embodiments shown, but what I desire to cover by Letters Patent is set forth in the appended claims,
I claim:
1. Means for generating electrical oscillations including, in combination, an electron discharge tube oscillator having a frequency determining circuit, an electron discharge control tube having its plate connected to said circuit, and means coupling the control tube and the frequency determining circuit including a plurality of phase shifting elements so arranged as to be capable of feeding energy from the control tube into the frequency determining circuit which is 90 out of phase with the energy in said circuit, one of said phase shifting elements consisting of an impedance connected in series between the plate of the control tube and the high potential side of the frequency determining circuit.
Means for generating electrical oscillations including, in combination, an electron discharge tube oscillator having a frequency determining circuit, a circuit connected to the grid of the oscillator tube including a feed-back coil coupled to said frequency determining circuit, an electron discharge control tube having its Plate connected to the frequency determining circuit, and
means coupling the control tube and the frequency determining circuit so arranged as to be capable f feeding n rgy from the control tube into the frequency determining circuit which is,
90 outof phase with the energy in said circuit, said coupling means comprising a coil connected in series witlrthe feed-back coil.
3, Means for generating electrical oscillations including, in combination, an electron discharge tube oscillator having a frequency determining circuit, a circuit connected to the grid of the oscillator tube including a feed-back coil coupled to said frequency determining circuit, an electron discharge control tube having its plate connected to the frequency determining circuit, and means coupling the control tube and the frequency determining circuit so arranged as to be capable of feeding energy from the control tube into the frequency determining circuit which is 90 out of phase with the energy in said circuit, said coupling means comprising a coil and resistor connected in series with the feed-back coil.
4, Means for generating electrical oscillations including, in combination, an electron discharge tube oscillator having a frequency determining circuit, a circuit connected to the grid of the oscillator tube including a feed-back coil coupled to said frequency determining circuit, an electron discharge control tube, a circuit comprising a resistor connecting the plate of the control tube to the frequency determining circuit, and additional means coupling the control tube and the frequency determining circuit so arranged as to be capable of feeding energy from the control tube into the frequency determining circuit which is 90 out of phase with the energy in said circuit, said additional coupling mean comprising a coil connected in series with the feed-back coil.
5. Means for generating electrical oscillations including, in combination, an electron discharge tube oscillator having a frequency determining circuit, a circuit connected to the grid of the oscillator tube including a feed-back coil coupled to said frequency determining circuit, an electron discharge control tube, a circuit comprising a resistor connecting the plate of the control tube to the frequency determining circuit, and additional means coupling the control tube and the frequency determining circuit so arranged as to be capable of feeding energy from the control tube into the frequency determining circuit which is 90 out of phase with the energy in said circuit, said additional coupling means comprising a resistor connected in series with the feed-back coil.
6. Means for generating electrical oscillations including, in combination, an electron discharge tube. oscillator having a frequency determining circuit, a circuit connected to the grid of the oscillator tube including a feed-back coil coupled to said frequency determining circuit, an electron discharge control tube, a circuit comprising a resistor connecting the plate of the control tube to the frequency determining circuit, and additional means coupling the control tube and the frequency determining circuitso arranged as to be capable of feeding energy from the control tube into the frequency determining circuit which is 90 out of phase with the energy in said circuit, said additional coupling means comprising a coil and resistor connected in series with the feedback coil.
SIDNEY Y. WHITE.
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US321380A US2265016A (en) | 1940-02-29 | 1940-02-29 | Electrical oscillation generator |
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Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2419869A (en) * | 1944-04-08 | 1947-04-29 | Gen Electric | Oscillation generator |
US2427231A (en) * | 1943-11-10 | 1947-09-09 | Gen Electric | Compensation of frequency variation of oscillator caused by change in voltage source |
US2498932A (en) * | 1944-08-18 | 1950-02-28 | Panoramic Radio Corp | High-frequency tuning circuit |
US2531301A (en) * | 1945-02-08 | 1950-11-21 | Hartford Nat Bank & Trust Co | Circuit arrangement for frequency controls |
US2555711A (en) * | 1946-07-18 | 1951-06-05 | Us Television Mfg Corp | Signal generator |
US2587493A (en) * | 1947-08-06 | 1952-02-26 | Boonton Radio Corp | Modulated signal generator |
US2782375A (en) * | 1951-11-05 | 1957-02-19 | Bendix Aviat Corp | Wide deviation reactance tube modulator circuit |
-
1940
- 1940-02-29 US US321380A patent/US2265016A/en not_active Expired - Lifetime
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2427231A (en) * | 1943-11-10 | 1947-09-09 | Gen Electric | Compensation of frequency variation of oscillator caused by change in voltage source |
US2419869A (en) * | 1944-04-08 | 1947-04-29 | Gen Electric | Oscillation generator |
US2498932A (en) * | 1944-08-18 | 1950-02-28 | Panoramic Radio Corp | High-frequency tuning circuit |
US2531301A (en) * | 1945-02-08 | 1950-11-21 | Hartford Nat Bank & Trust Co | Circuit arrangement for frequency controls |
US2555711A (en) * | 1946-07-18 | 1951-06-05 | Us Television Mfg Corp | Signal generator |
US2587493A (en) * | 1947-08-06 | 1952-02-26 | Boonton Radio Corp | Modulated signal generator |
US2782375A (en) * | 1951-11-05 | 1957-02-19 | Bendix Aviat Corp | Wide deviation reactance tube modulator circuit |
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