US2626355A - Variable frequency oscillator - Google Patents

Variable frequency oscillator Download PDF

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US2626355A
US2626355A US608550A US60855045A US2626355A US 2626355 A US2626355 A US 2626355A US 608550 A US608550 A US 608550A US 60855045 A US60855045 A US 60855045A US 2626355 A US2626355 A US 2626355A
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grid
cylinder
anode
cathode
section
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Philip A Hoffman
Garold K Jensen
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    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03BGENERATION OF OSCILLATIONS, DIRECTLY OR BY FREQUENCY-CHANGING, BY CIRCUITS EMPLOYING ACTIVE ELEMENTS WHICH OPERATE IN A NON-SWITCHING MANNER; GENERATION OF NOISE BY SUCH CIRCUITS
    • H03B5/00Generation of oscillations using amplifier with regenerative feedback from output to input
    • H03B5/18Generation of oscillations using amplifier with regenerative feedback from output to input with frequency-determining element comprising distributed inductance and capacitance
    • H03B5/1817Generation of oscillations using amplifier with regenerative feedback from output to input with frequency-determining element comprising distributed inductance and capacitance the frequency-determining element being a cavity resonator
    • H03B5/1835Generation of oscillations using amplifier with regenerative feedback from output to input with frequency-determining element comprising distributed inductance and capacitance the frequency-determining element being a cavity resonator the active element in the amplifier being a vacuum tube

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  • This invention relates in general to a generator of high frequency oscillations and in p-articular to a line controlled type of oscillator which may be tuned over an extended frequency range by way of a single tuning means.
  • An object of this invention is to provide a line controlled type of oscillator having two resonant line sections adjustment of only one of which is necessary to tune the oscillator.
  • Another object of this invention is to provide a line controlled type of oscillator having two resonant line sections one of which is of low Q and the other of which is of high Q.
  • triode vacuum tubes especially adapted for concentric line type of operation have been provided by the prior art.
  • One of such vacuum tubes is provided with annular anode, grid, and cathode ring terminals projecting from the tube envelope in parallel planes normal to the longitudinal axis of the tube.
  • These rings are each of a diferent diameter and are arranged in a step-wise manner so that the cathode has the largest ring, the anode the smallest ring and the grid the intermediate ring. Because of its functional design the tube has inherited the appellation lighthouse tube.
  • one such vacuum tube designated in general at I having a cathode ring H, a grid ring I2 and an anode ring and cap I3 is shown as applied to the present invention.
  • the tube itself hasrin addition to the annular ring terminals a number of base pin connections which are seated in a conventional type tube socket 9 which is carried by a metallic cup member 8.
  • the latter is adapted to engage the outermost cylinder I4 of the oscillator assembly shown in general to the right of the tube.
  • the cup member 8 may be held to the outer cylinder I4 of the oscillator assembly by means of a simple clamping ring (not shown) or by a number of longitudinal slots cut in the end of the cup member so as to form a fingered engagement to the outer cylinder I4.
  • the oscillator assembly comprises an outer cylinder I4, an intermediate cylinder I concentrically disposed within the outer cylinder and nally an inner rod-like member 4 concentrically disposed in the inner cylinder I5.
  • the outer cylinder I4 is provided at its left hand end with an annular shoulder member I6 to which is secured, for example, by means of machine screws or welding (not shown) a suitable fingered ring contacting member 20.
  • the ring contacting member 20 may be made of phosphor bronze and is adapted to provide a good high frequency contact to the cathode ring I I of the lighthouse tube IU. 'I'he corresponding or left hand end of the second cylinder I5 is similarly provided with a fingered annular contacting ring 2I which is adapted to electrically contact the grid ring I2 of the tube I0. At the opposite or right hand end of the inner cylinder I5 is an integral annular element 25 which is suitably fastened, by means of screws, for example, to the outer ⁇ cylinder I4 to thereby provide good coaxial alignment between the cylinders I4 and I5.
  • the space between the cylinders I4 and I5 forms a grid-cathode resonant line section of the oscillator.
  • a slidable dual cylinder 26 is inserted in the space between the outer cylinder I4 and the intermediate cylinder I5 and may be variably positioned to change the electrical length of this line section as desired.
  • a rod like member 4 Concentrically disposed within the inner cylinder I5 is a rod like member 4 the left hand end of which is provided with a recess 21 which is suitably adapted to seat the anode cap I3 of the tube I0.
  • the right hand end of rod 4 is securely fastened, brazed for example, to an end plate 28 which in turn may contain a soldered connection to the plate supply for the tube.
  • a dielectric washer 29 Interposed between the end plate 28 and the annular terminating lug 23 of the outer cylinder is a dielectric washer 29. The function of this dielectric washer is to isolate the high plate voltage from the outer cylinder I4.
  • Threadably engaging bar 4 is an internally threaded sleeve 30 which is machined to a diameter slightly less than the inner diameter of the intermediate cylinder I5.
  • the annular space existing between the sleeve 30 and the internal periphery of cylinder I5 functions as a capacitative short circuit at the high frequency of operation of the oscillator.
  • and the grid ring terminal I2 at the left end and by the sleeve 30 at the right hand end forms the grid-anode resonant line section of the oscillator.
  • a fiber gear I9 is securely fixed to the right hand end of the sleeve 30. This gear meshes with a second gear 38 which is suitably journalled to the outer cylinder I4 as shown at 34 and 35.
  • Gear 38 is driven by means of shaft 39 and thumb wheel 40. Rotation 3 of thumb wheel 4l) is translated into longitudinal movement of the sleeve 30 to thus provide a means for varying ejjelectrical length of the grid-anode line section.
  • Typical operation of the oscillator shown' was with the quarter Wavelength mode in both resonant sections.
  • Output energy may be coupled, for example, from the grid-cathode circuit by means of a suitable magnetic pick up loop 4
  • the ratio of the internal diameter of the grid cylinder l5 to the external diameter of the anode bar 4 is made larger than the ratio of the internal diameter of the cathode cylinder I4 to the external diameter of the grid cylinder I5. It is thus apparent that the volume to surface ratio of the grid-anode line section is greater than the corresponding ratio in the grid cathode line section which consequently provides the former line section with a higher Q than that of the latter line section. Furthermore the insertion of the energy output coupling loop 4
  • the ratio of diameters in the grid-cathode section was set at 3-2 while that of the grid-anode section was set at 3-l.3 which permitted easy tuning (solely -by means of the sleeve 30) over a frequency range having a ratio of 5 4, without serious loss in power at either end of the operating range.
  • An oscillator assembly comprising a pair of cylindrical elements of different diameters, the smaller of which is concentrically disposed within the other, a rod-like member concentrically disposed within the inner of said pair of cylinders, a sleeve member of a diameter slightly less than said inner cylinder, spaced therefrom to ,Y form a capacitance short therebetween and mounted on said rod-like member and movable therealong, a triode vacuum tube connected to said rod and cylinder assembly so as to form both a low Q grid-cathode and a high Q grid-anode resonant line section, means feeding back energy from said grid-anode section to said grid-cathode section so as to cause and sustain oscillations, and means for coupling energy from the line section between the cylinders to an external load, whereby the selectivity of the low Q resonant line section is broadened to permit tuning of the assembly over a wide frequency range by a variation of the high Q resonant line section alone.
  • An oscillator assembly comprising a pair of cylindrical elements of different diameters the smaller of which is concentrically disposed Within the other, an annular shorting element movably positioned in the space between the two cylinders, a rod-like member concentrically disposed within the inner of said pair of cylinders, a sleeve member of a diameter slightly less than said inner cylinder, spaced therefrom to form a capacitance short therebetween and mounted on said rod-like member and movable therealong, a triode vacuum tube connected to said rod and assembly so as to form both a low Q grid-cathode and a high Q grid-anode resonant line section, means feeding back energy from said grid-anode section to said grid-cathode section so as to cause and sustain oscillations, and means for coupling energy from the line section between the cylinders to an external load, whereby the selectivity of the low Q resonant line section is broadened to permit tuning of the assembly over a wide frequency range by a Variation
  • An oscillator assembly comprising a pair of cylindrical elements of different diameters the smaller of which is concentrically disposed within the other, an annular snorting element movably positioned in the space between the two cylinders, a rod-like member concentrically disposed within the inner of said pair of cylinders, a sleeve member of a diameter slightly less than said inner cylinder, spaced therefrom to for-m a capacitance short therebetween and mounted 0n said rod-like member and movable therealong, the ratio of the internal diameter of the outer cylinder to the outer diameter of the inner cylinder being smaller than the ratio of the internal diameter of the inner cylinder to the diameter of the rod-like member, a triode vacuum tube connected to said rod and cylinder assembly so as to form both a grid-anode and a grid-cathode line section, means feeding back energy from said grid-anode section to said grid-cathode section so as to cause and sustain oscillations, and means for coupling energy from the outer line
  • An oscillator assembly comprising a pair of cylindrical elements of different diameters the -smaller of which is concentrically disposed within the other, an annular snorting element movably positioned in the yspace between said pair of cylinders, a rod-like member concentrically disposed within the inner of said pair of cylinders, a sleeve member threaded on said rod-like member, said sleeve member being of a slightly smaller diameter than said inner cylinder so as to form a capacitance short therebetween, a triode vacuum tube of the species described having annular anode, grid and cathode terminals projecting from the tube envelope in parallel planes normal to the longitudinal axis of the tube, said tube adapted to be tted into said rod and cylinder assembly in such manner that said cathode, grid and anode terminals electrically contact the outer cylinder, the inner cylinder and the rod-like member respectively, whereby grid-anode and grid-cathode resonant line sections are formed

Description

ummm uw Filed Aug, 2, 1945 mm mm m O Jan. 20, 1953 P A HOFFMAN Er AL VARIABLE FREQUENCY oscILLAToE Patented Jan. 20, A1953 UNITED STATES PATENT OFFICE VARIABLE FREQUENCY OS'CILLATOR Philip A. Hoffman and Garold K. Jensen, United States Navy (Granted under Title 35, U. S. Code (1952),
sec. 266) This invention relates in general to a generator of high frequency oscillations and in p-articular to a line controlled type of oscillator which may be tuned over an extended frequency range by way of a single tuning means.
An object of this invention is to provide a line controlled type of oscillator having two resonant line sections adjustment of only one of which is necessary to tune the oscillator.
Another object of this invention is to provide a line controlled type of oscillator having two resonant line sections one of which is of low Q and the other of which is of high Q.
Other objects and features of the present invention will become apparent from a careful consideration of the following detailed description taken together with the accompanying drawing, the single figure of which is an elevational View of a typical embodiment of the invention.
A number of triode vacuum tubes especially adapted for concentric line type of operation have been provided by the prior art. One of such vacuum tubes is provided with annular anode, grid, and cathode ring terminals projecting from the tube envelope in parallel planes normal to the longitudinal axis of the tube. These rings are each of a diferent diameter and are arranged in a step-wise manner so that the cathode has the largest ring, the anode the smallest ring and the grid the intermediate ring. Because of its functional design the tube has inherited the appellation lighthouse tube.
With particular reference to the single gure, one such vacuum tube designated in general at I having a cathode ring H, a grid ring I2 and an anode ring and cap I3 is shown as applied to the present invention. The tube itself hasrin addition to the annular ring terminals a number of base pin connections which are seated in a conventional type tube socket 9 which is carried by a metallic cup member 8. The latter is adapted to engage the outermost cylinder I4 of the oscillator assembly shown in general to the right of the tube. The cup member 8 may be held to the outer cylinder I4 of the oscillator assembly by means of a simple clamping ring (not shown) or by a number of longitudinal slots cut in the end of the cup member so as to form a fingered engagement to the outer cylinder I4. The oscillator assembly comprises an outer cylinder I4, an intermediate cylinder I concentrically disposed within the outer cylinder and nally an inner rod-like member 4 concentrically disposed in the inner cylinder I5. The outer cylinder I4 is provided at its left hand end with an annular shoulder member I6 to which is secured, for example, by means of machine screws or welding (not shown) a suitable fingered ring contacting member 20. The ring contacting member 20 may be made of phosphor bronze and is adapted to provide a good high frequency contact to the cathode ring I I of the lighthouse tube IU. 'I'he corresponding or left hand end of the second cylinder I5 is similarly provided with a fingered annular contacting ring 2I which is adapted to electrically contact the grid ring I2 of the tube I0. At the opposite or right hand end of the inner cylinder I5 is an integral annular element 25 which is suitably fastened, by means of screws, for example, to the outer` cylinder I4 to thereby provide good coaxial alignment between the cylinders I4 and I5. It may thus be seen that the space between the cylinders I4 and I5 forms a grid-cathode resonant line section of the oscillator. To tune this section a slidable dual cylinder 26 is inserted in the space between the outer cylinder I4 and the intermediate cylinder I5 and may be variably positioned to change the electrical length of this line section as desired.
Concentrically disposed within the inner cylinder I5 is a rod like member 4 the left hand end of which is provided with a recess 21 which is suitably adapted to seat the anode cap I3 of the tube I0. The right hand end of rod 4 is securely fastened, brazed for example, to an end plate 28 which in turn may contain a soldered connection to the plate supply for the tube. Interposed between the end plate 28 and the annular terminating lug 23 of the outer cylinder is a dielectric washer 29. The function of this dielectric washer is to isolate the high plate voltage from the outer cylinder I4. Threadably engaging bar 4 is an internally threaded sleeve 30 which is machined to a diameter slightly less than the inner diameter of the intermediate cylinder I5. The annular space existing between the sleeve 30 and the internal periphery of cylinder I5 functions as a capacitative short circuit at the high frequency of operation of the oscillator. The space between the intermediate cylinder I5 and the anode bar 4 which is bounded by the grid contacting member 2| and the grid ring terminal I2 at the left end and by the sleeve 30 at the right hand end forms the grid-anode resonant line section of the oscillator. To tune this line section a fiber gear I9 is securely fixed to the right hand end of the sleeve 30. This gear meshes with a second gear 38 which is suitably journalled to the outer cylinder I4 as shown at 34 and 35. Gear 38 is driven by means of shaft 39 and thumb wheel 40. Rotation 3 of thumb wheel 4l) is translated into longitudinal movement of the sleeve 30 to thus provide a means for varying ejjelectrical length of the grid-anode line section. Typical operation of the oscillator shown'was with the quarter Wavelength mode in both resonant sections.
To complete the oscillatory circuit energy must be fed back from the grid-anode line section to the grid-cathode line section. This effect is accomplished by means of, for example, a suitable screw member 32 which threadably engages the boss member 33 and extends into the grid-anode section through an aperture Il cut in the grid cylinder l5. Screw 32 is positioned at a point of maximum electrostatic field in the grid-anode cylinder and thus provides a capacity type coupling between the grid-anode section and the grid-cathode section of the oscillator. The amount of feedback is made controllable by adjustment of the penetration depth of the screw member 32. Output energy may be coupled, for example, from the grid-cathode circuit by means of a suitable magnetic pick up loop 4| positioned at a point of maximum electromagnetic eld intensity and brought out of the cylinder through a suitable coaxial connector 42 which is threaded to boss member 43.
In the physical construction of the oscillator assembly the ratio of the internal diameter of the grid cylinder l5 to the external diameter of the anode bar 4 is made larger than the ratio of the internal diameter of the cathode cylinder I4 to the external diameter of the grid cylinder I5. It is thus apparent that the volume to surface ratio of the grid-anode line section is greater than the corresponding ratio in the grid cathode line section which consequently provides the former line section with a higher Q than that of the latter line section. Furthermore the insertion of the energy output coupling loop 4| in the grid-cathode line section operates to further reduce the Q of this section. With this arrangement it becomes only necessary to adjust the electrical length of the higher Q circuit in order to tune the oscillator over a considerable frequency range. For example, in a typical case the ratio of diameters in the grid-cathode section was set at 3-2 while that of the grid-anode section was set at 3-l.3 which permitted easy tuning (solely -by means of the sleeve 30) over a frequency range having a ratio of 5 4, without serious loss in power at either end of the operating range.
Although only one specic and preferred embodiment of the invention has been shown it is to be understood that many modifications of the invention are possible without departing from the spirit of the invention. Therefore, this invention is not to 'be limited except insofar as is necessitated by the spirit of the prior art and the scope of the appended claims.
The invention described herein may be manufactured and used by or for the Government of the United States of America for governmental purposes without the payment of any royalties thereon or therefor.
What is claimed is:
l. An oscillator assembly comprising a pair of cylindrical elements of different diameters, the smaller of which is concentrically disposed within the other, a rod-like member concentrically disposed within the inner of said pair of cylinders, a sleeve member of a diameter slightly less than said inner cylinder, spaced therefrom to ,Y form a capacitance short therebetween and mounted on said rod-like member and movable therealong, a triode vacuum tube connected to said rod and cylinder assembly so as to form both a low Q grid-cathode and a high Q grid-anode resonant line section, means feeding back energy from said grid-anode section to said grid-cathode section so as to cause and sustain oscillations, and means for coupling energy from the line section between the cylinders to an external load, whereby the selectivity of the low Q resonant line section is broadened to permit tuning of the assembly over a wide frequency range by a variation of the high Q resonant line section alone.
2. An oscillator assembly comprising a pair of cylindrical elements of different diameters the smaller of which is concentrically disposed Within the other, an annular shorting element movably positioned in the space between the two cylinders, a rod-like member concentrically disposed within the inner of said pair of cylinders, a sleeve member of a diameter slightly less than said inner cylinder, spaced therefrom to form a capacitance short therebetween and mounted on said rod-like member and movable therealong, a triode vacuum tube connected to said rod and assembly so as to form both a low Q grid-cathode and a high Q grid-anode resonant line section, means feeding back energy from said grid-anode section to said grid-cathode section so as to cause and sustain oscillations, and means for coupling energy from the line section between the cylinders to an external load, whereby the selectivity of the low Q resonant line section is broadened to permit tuning of the assembly over a wide frequency range by a Variation of the high Q resonant line section alone.
3. An oscillator assembly comprising a pair of cylindrical elements of different diameters the smaller of which is concentrically disposed within the other, an annular snorting element movably positioned in the space between the two cylinders, a rod-like member concentrically disposed within the inner of said pair of cylinders, a sleeve member of a diameter slightly less than said inner cylinder, spaced therefrom to for-m a capacitance short therebetween and mounted 0n said rod-like member and movable therealong, the ratio of the internal diameter of the outer cylinder to the outer diameter of the inner cylinder being smaller than the ratio of the internal diameter of the inner cylinder to the diameter of the rod-like member, a triode vacuum tube connected to said rod and cylinder assembly so as to form both a grid-anode and a grid-cathode line section, means feeding back energy from said grid-anode section to said grid-cathode section so as to cause and sustain oscillations, and means for coupling energy from the outer line sections to an external load, whereby the selectivity of the grid-cathode line section is broadened to permit tuning of said assembly over a Wide frequency range by a variation of the grid-anode line section alone.
4. An oscillator assembly comprising a pair of cylindrical elements of different diameters the -smaller of which is concentrically disposed within the other, an annular snorting element movably positioned in the yspace between said pair of cylinders, a rod-like member concentrically disposed within the inner of said pair of cylinders, a sleeve member threaded on said rod-like member, said sleeve member being of a slightly smaller diameter than said inner cylinder so as to form a capacitance short therebetween, a triode vacuum tube of the species described having annular anode, grid and cathode terminals projecting from the tube envelope in parallel planes normal to the longitudinal axis of the tube, said tube adapted to be tted into said rod and cylinder assembly in such manner that said cathode, grid and anode terminals electrically contact the outer cylinder, the inner cylinder and the rod-like member respectively, whereby grid-anode and grid-cathode resonant line sections are formed, means feeding back energy from said grid-anode section to said grid-cathode section, gear means for adjusting the position of said sleeve member on said rod-like member to effect a tuning of the oscillator, and means for coupling energy from the line section formed between the cylinders t0 an external load.
PHILIP A. HOFFMAN.
GAROLD K. JENSEN.
REFERENCES CITED The following references are of record in the file of this patent:
UNITED STATES PATENTS Number Name Date 2,132,208 Dunmore Oct. 4, 1938 2,253,503 Bowen Aug. 26, 1941 2,404,261 Whinnery July 16, 1946 2,404,279 Dow July 16, 1946 2,408,355 Turner Sept. 24, 1946 2,412,805 Ford Dec. 17, 1946 2,416,565 Beggs Feb. 25, 1947 2,428,622 Gurewitsch Oct. 7, 1947 2,477,232 Branson July 26, 1949
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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2750504A (en) * 1951-06-21 1956-06-12 C G S Laborastories Inc Signal generator
US2805335A (en) * 1953-08-19 1957-09-03 Gen Railway Signal Co Resonant cavity resonator
US3631363A (en) * 1969-11-14 1971-12-28 Gen Electric High-frequency cavity oscillator having improved tuning means
US5345203A (en) * 1991-08-02 1994-09-06 Bruker Analytische Messtechnik Gmbh Resonator arrangement for electron spin resonance spectroscopy

Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2132208A (en) * 1935-12-27 1938-10-04 Francis W Dunmore Ultrahigh frequency radio amplifier
US2253503A (en) * 1938-08-06 1941-08-26 Bell Telephone Labor Inc Generation and transmission of high frequency oscillations
US2404279A (en) * 1941-08-07 1946-07-16 Rca Corp Ultra short wave system
US2404261A (en) * 1942-10-31 1946-07-16 Gen Electric Ultra high frequency system
US2408355A (en) * 1942-01-29 1946-09-24 Rca Corp Concentric line oscillator
US2412805A (en) * 1944-02-05 1946-12-17 Rca Corp Ultra high frequency oscillation generator
US2416565A (en) * 1942-03-28 1947-02-25 Gen Electric High-frequency electronic device
US2428622A (en) * 1942-11-12 1947-10-07 Gen Electric Tuning and coupling means for highfrequency systems
US2477232A (en) * 1945-03-28 1949-07-26 Bell Telephone Labor Inc Cavity resonator

Patent Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2132208A (en) * 1935-12-27 1938-10-04 Francis W Dunmore Ultrahigh frequency radio amplifier
US2253503A (en) * 1938-08-06 1941-08-26 Bell Telephone Labor Inc Generation and transmission of high frequency oscillations
US2404279A (en) * 1941-08-07 1946-07-16 Rca Corp Ultra short wave system
US2408355A (en) * 1942-01-29 1946-09-24 Rca Corp Concentric line oscillator
US2416565A (en) * 1942-03-28 1947-02-25 Gen Electric High-frequency electronic device
US2404261A (en) * 1942-10-31 1946-07-16 Gen Electric Ultra high frequency system
US2428622A (en) * 1942-11-12 1947-10-07 Gen Electric Tuning and coupling means for highfrequency systems
US2412805A (en) * 1944-02-05 1946-12-17 Rca Corp Ultra high frequency oscillation generator
US2477232A (en) * 1945-03-28 1949-07-26 Bell Telephone Labor Inc Cavity resonator

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2750504A (en) * 1951-06-21 1956-06-12 C G S Laborastories Inc Signal generator
US2805335A (en) * 1953-08-19 1957-09-03 Gen Railway Signal Co Resonant cavity resonator
US3631363A (en) * 1969-11-14 1971-12-28 Gen Electric High-frequency cavity oscillator having improved tuning means
US5345203A (en) * 1991-08-02 1994-09-06 Bruker Analytische Messtechnik Gmbh Resonator arrangement for electron spin resonance spectroscopy

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