US2121877A - Ultrahigh frequency electron discharge modulator - Google Patents

Ultrahigh frequency electron discharge modulator Download PDF

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US2121877A
US2121877A US53522A US5352235A US2121877A US 2121877 A US2121877 A US 2121877A US 53522 A US53522 A US 53522A US 5352235 A US5352235 A US 5352235A US 2121877 A US2121877 A US 2121877A
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grid
oscillator
radiator
ultrahigh frequency
electron
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US53522A
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Linsell Alfred Aubyn
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RCA Corp
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RCA Corp
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J25/00Transit-time tubes, e.g. klystrons, travelling-wave tubes, magnetrons
    • H01J25/68Tubes specially designed to act as oscillator with positive grid and retarding field, e.g. for Barkhausen-Kurz oscillators

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  • the electrons may oscillate backwards'and forwards between the neighborhood ofthe filament and the neighborhood of the anode and experiments indicate that such oscillation has a natural time period which depends sub- 35 stantially solely upon the tube dimensions and upon the voltage applied to the grid.
  • This type of oscillator is now well known as the Barkhausen Kurz or Gill Morell type.
  • the presentinvention utilizes the same general principles as were utilized in the invention contained in the British Pat. #404,708 andconsists in employing :what may be termed anfelectron oscillator to effect modulation.
  • modulating potentials are applied to vary the periodicity of the electron oscillation and the resultant varying frequency output is utilized to effect an ultrahigh frequency oscillatorto cause modulation.
  • an'ultrahigh frequency oscillator I consisting, for example, of a magnetron tube oscillator as shown in Fig. 1a or as shown in Fig. 1, of a dynatron tube oscillator, has a frequency determining tuned circuit 5 the inductance of which is coupled to an inductance 6 in an aerial or other utilization circuit. Also arranged in accordance with the principles above outlined to produce electron oscillation about the grid I l.
  • the grid of this tube is positively biased relative to the cathode by means of a suitable source of potential l8 connected in the cathode grid circuit, there being in series with this source, the secondary of a transformer to whose primary modulating potentials are applied, e, g. from a microphone 3 so that the total potential on the grid will vary with the modulating potentials.
  • the fixed grid biasing source is shunted by a suitable blocking condenser 9 and a negative point on this source relative to the point at which the cathode is connected, is connected to the plate l2 which is connected to the grid through the blocking condenser 8.
  • the invention may also be used in conjunction with the invention contained in the specification of Br. Pat. #413,646, accepted July 17, 1934, or in the specification accompanying my copending U. S. appln. Ser. No. 15,384, filed April 9, 1935, patented December 7, 1937, No. 2,101,440.
  • the output from the ultrahigh frequency oscillator l providing the carrier energy which is to be modulated may be fed to a radiator and the output from what may be termed the modulator oscillator 2 may be fed to an auxiliary conductor associated with said radiator modulation resulting in the final outgoing radiation by reason of the relationship between the radiator and auxiliary conductor or reflector and in accordance with the principles set forth in the specification of said British Pat.
  • the output from the ultrahigh frequency oscillator may be fed to a radio beam generating arrangement 6 and it as shown in Figures 2 and 2a and a plurality of reflectors or conductors 1,1, and l" which may be graded in effectiveness, are
  • the outputs from a plurality of modulator oscillators comprising elements 2, 3, d, 8, 9, etc., as herein described being coupled to the reflectors or conductors l, 'l, and I.
  • the ultrahigh frequency oscillator I is coupled at 5, 6 to a radiator as described in the embodiment of Fig. 1, the radiator with the beam reflector l6 forming part of an installation for radiating an ultrashort wave beam.
  • the radiator with the beam reflector l6 forming part of an installation for radiating an ultrashort wave beam.
  • In the path of this beam is interposed a plurality of conductors or reflectors, there being two such conductors l, 1 shown in Fig.
  • Conductors l, T, etc. are connected as shown with interposed inductances l l l i ,.etc., respectively, there being coupled to each of said inductances an aperiodic loop 4 of a modulator oscillator 2 as hereinbefore described and illustrated.
  • the oscillators 2 are modulated by po-- electron oscillator is employed to mean oscillators (of which the Barkhausen-Kurz and Gill- Morell and the magnetron types are examples) wherein the oscillations generated are due to electron oscillations, as distinct from what may be termed feed back oscillators wherein the oscillations are due to energy feed back from an output circuit to an input circuit.
  • the energy feed back type of oscillator of course, depends for its action upon controlling potentials fed to a controlling electrode, usually a grid.
  • An electron oscillator does not depend for its action upon this but, as stated, directly upon oscillations of electrons.
  • a very high frequency oscillator a radiator coupled thereto, and modulating means therefor, a conductor in the path of radiation from said radiator, said modulating means comprising an electron oscillator having an output circuit, means for applying modulating potentials to vary the periodicity of said electron oscillator, and means for coupling the output circuit of said electron oscillator to said conductor in the path of radiation from the radiator coupled with the very high frequency oscillator whereby modulation of the final outgoing radiation from the combination of radiator and reflector is obtained.
  • an ultrahigh frequency 05- cillator a beam radiator coupled to said oscillator, a conductive member in the pathof radiation of said beam radiator and modulating means comprising an electron oscillator including a tube having its electrodes coupled in high frequency oscillatory circuits including an output circuit, means for coupling said output circuit to said conductive member in the path of said beam from said beam radiator and means for modulating the potential on an electrode in said electron oscillator to thereby modulate the periodicity of oscillation thereof and the radiation from said beam radiator.
  • a high frequency radiator and means for energizing the same by high frequency oscillations a conductive member in the path of radiation of said radiator, an eleccuits, a coupling between said circuitsand con ductive member, and means for modulating the potential on the control electrode of said device in accordance with signals.
  • a beam radiator and means for setting up high frequency oscillations therein a plurality of conducting members in the path of radiation from said beam radiator and a controlled oscillator coupled to each conducting member, each controlled oscillator comprising an electron discharge device having an anode, a cathode, and a control electrode, means for applying positive potential to said control electrodes with respect to said cathodes, and a potential of lesser value tosaid anodes with respect to said cathodes whereby the electrons-emitted by said cathode oscillate between said anodes and cathodes, and means for applying modulating potentials to said control electrodes.
  • an ultrahigh frequency radiator an ultrahigh frequency oscillator coupled to said radiator to produce radiation of ultrahigh frequency energy therefrom and means for modulating said ultrahigh irequenoy oscillations
  • means for modulating said ultrahigh irequenoy oscillations comprising an electron discharge device having an anode, a cathode and a blocking condenser in series between said control grid and cathode, means for applying a positive potential to said control electrode and a lesser potential to said anode, means for applying modulating potentials between said control grid and said cathode, and a coupling between one of said loop circuits and said radiator.

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Description

June.28, 193s A. A. LINSELL ULTRAHIGH FREQUENCY ELECTRON DISCHARGE MODULATOR Filed Dec. 9. 1935 ATTORNEY Patented June 28, 1938 UNITED STATES PATENT OFFICE QULTRAHIGVH FREQUENCY ELECTRON Dis- CHARGE MODULATOR Alfred Aubyn 'Linsell, London, England, assignor to Radio Corporation of America, a corporation of Delaware Application December 9, 1935, Serial No. 53,522
In Great Britain January 25, 1935 otherwise of the theoretical explanation now to be advanced. 'p I 7 ,Consider the case of a thermionic tube having a line filament, a cylindrical grid concentrically surrounding said filament and a cylindrical anode concentricallysurroundingsaid grid and suppose the grid to be maintained at a positive voltage with 29 respect to the filament and theanode at a slightly'negative voltage with respect thereto, for example-2 volts. Electrons leaving the filament of this tube and moving towards thegrid may over-shoot the, grid before they areslowed down 25 and reversed in direction and. may again overshoot the grid in the other direction, and in this manner may oscillate backwards and forwards past the grid a number of times-before they are final1y caught thereon, To put thematter in so another way, the electrons may oscillate backwards'and forwards between the neighborhood ofthe filament and the neighborhood of the anode and experiments indicate that such oscillation has a natural time period which depends sub- 35 stantially solely upon the tube dimensions and upon the voltage applied to the grid. This type of oscillator is now well known as the Barkhausen Kurz or Gill Morell type. Now,.if there be applied between the filament and the anode moan alternating electro-motive force of small amplitude and of periodicity corresponding to the periodicityat which the electrons oscillate in the previously described action, the said oscillations will (for those electrons for which the phase of 4g the applied electro-inotive force is correct) become larger and larger in amplitude until some of the electrons reach the anode.
The above phenomena will be found described 'in detail in the specification of British Pat."
50;, #404,708, accepted Jan. 22, 1934, which specifica- H tion describes an invention accordingto which detection is obtained by applying the wave to be detected between the anode and cathode of a thermionic tube andiapplying to the grid of said 5 5, tube a critically selected positive potential'of such magnitude that a correspondence exists between the periodicity of theenergy to be detected and the natural periodicity of the electron oscillation about said grid.
'In one circuit arrangement describedin the 3 specification of'said British Pat. #404,708, the anode of a'tube is connected through anaperiodic loop in series with a large blocking condenserto the! grid which is in turn connected through a large blocking condenser to the; cathode. Positive potential is appliedto the grid relativeto the cathode and a source of ultrashort wave energy is loosely coupled to the aperiodic loop, an indicating galvanometer being connected between the cathode'and the side ofthe first mentioned blocking condenser-remote from thegrid. With 7 this arrangement, the anode'current (as measured by the galvanometer) varies substantially with variation of grid voltage. the characteristic curveconnecting these variables being asharply peaked curveT-Jike that of a tuned circuit-thus indicating that the periodicity of electron oscillation about-the'grid varies with applied grid potential; v i
The presentinvention utilizes the same general principles as were utilized in the invention contained in the British Pat. #404,708 andconsists in employing :what may be termed anfelectron oscillator to effect modulation. Incarrying out this invention, modulating potentials are applied to vary the periodicity of the electron oscillation and the resultant varying frequency output is utilized to effect an ultrahigh frequency oscillatorto cause modulation. 7
The invention is illustrated in the accompanying diagrammatic drawing, wherein Figs. 1, 1a, 2a and 2 illustrate diagrammatically two modifications of my invention, each of which include electron typeroscillators and means for modulating the very high frequencies produced in a novel manner. I I
Referring to Figs; 1 and 1a, which show one way of carrying out this invention, an'ultrahigh frequency oscillator I consisting, for example, of a magnetron tube oscillator as shown in Fig. 1a or as shown in Fig. 1, of a dynatron tube oscillator, has a frequency determining tuned circuit 5 the inductance of which is coupled to an inductance 6 in an aerial or other utilization circuit. Also arranged in accordance with the principles above outlined to produce electron oscillation about the grid I l. The grid of this tube is positively biased relative to the cathode by means of a suitable source of potential l8 connected in the cathode grid circuit, there being in series with this source, the secondary of a transformer to whose primary modulating potentials are applied, e, g. from a microphone 3 so that the total potential on the grid will vary with the modulating potentials. The fixed grid biasing source is shunted by a suitable blocking condenser 9 and a negative point on this source relative to the point at which the cathode is connected, is connected to the plate l2 which is connected to the grid through the blocking condenser 8. It will be seen accordingly that the natural periodicity of the electron oscillation about the grid of the modulator tube 2 will vary with the applied modulating potentials and by reason of the coupling of the aperiodic loop 4 there will be a consequent reaction upon the oscillatory circuit of the electron or other ultrahigh frequency oscillator l with consequent modulation of the energy radiated.
The invention may also be used in conjunction with the invention contained in the specification of Br. Pat. #413,646, accepted July 17, 1934, or in the specification accompanying my copending U. S. appln. Ser. No. 15,384, filed April 9, 1935, patented December 7, 1937, No. 2,101,440. In other words, in the former case the output from the ultrahigh frequency oscillator l providing the carrier energy which is to be modulated may be fed to a radiator and the output from what may be termed the modulator oscillator 2 may be fed to an auxiliary conductor associated with said radiator modulation resulting in the final outgoing radiation by reason of the relationship between the radiator and auxiliary conductor or reflector and in accordance with the principles set forth in the specification of said British Pat.
Where the invention is used in conjunction with the invention contained in the specification accompanying my above mentioned patent, the output from the ultrahigh frequency oscillator may be fed to a radio beam generating arrangement 6 and it as shown in Figures 2 and 2a and a plurality of reflectors or conductors 1,1, and l" which may be graded in effectiveness, are
positioned in the path of said beam so as to alter.
the convergence or divergence of the said beam in accordance with the principles set forth in the copending specification in question, the outputs from a plurality of modulator oscillators comprising elements 2, 3, d, 8, 9, etc., as herein described being coupled to the reflectors or conductors l, 'l, and I. In the installation of this nature illustrated in Figs. 2 and 2a, the ultrahigh frequency oscillator I is coupled at 5, 6 to a radiator as described in the embodiment of Fig. 1, the radiator with the beam reflector l6 forming part of an installation for radiating an ultrashort wave beam. In the path of this beam is interposed a plurality of conductors or reflectors, there being two such conductors l, 1 shown in Fig. 2 and three such conductors l, 1', and 1" shown in Fig. 2a. Conductors l, T, etc., are connected as shown with interposed inductances l l l i ,.etc., respectively, there being coupled to each of said inductances an aperiodic loop 4 of a modulator oscillator 2 as hereinbefore described and illustrated. The oscillators 2 are modulated by po-- electron oscillator is employed to mean oscillators (of which the Barkhausen-Kurz and Gill- Morell and the magnetron types are examples) wherein the oscillations generated are due to electron oscillations, as distinct from what may be termed feed back oscillators wherein the oscillations are due to energy feed back from an output circuit to an input circuit. The energy feed back type of oscillator, of course, depends for its action upon controlling potentials fed to a controlling electrode, usually a grid. An electron oscillator, however, does not depend for its action upon this but, as stated, directly upon oscillations of electrons.
What is claimed is:
1. In combination a very high frequency oscillator, a radiator coupled thereto, and modulating means therefor, a conductor in the path of radiation from said radiator, said modulating means comprising an electron oscillator having an output circuit, means for applying modulating potentials to vary the periodicity of said electron oscillator, and means for coupling the output circuit of said electron oscillator to said conductor in the path of radiation from the radiator coupled with the very high frequency oscillator whereby modulation of the final outgoing radiation from the combination of radiator and reflector is obtained. 1
2. In combination, an ultrahigh frequency 05- cillator, a beam radiator coupled to said oscillator, a conductive member in the pathof radiation of said beam radiator and modulating means comprising an electron oscillator including a tube having its electrodes coupled in high frequency oscillatory circuits including an output circuit, means for coupling said output circuit to said conductive member in the path of said beam from said beam radiator and means for modulating the potential on an electrode in said electron oscillator to thereby modulate the periodicity of oscillation thereof and the radiation from said beam radiator.
3. In a signalling system, a high frequency radiator and means for energizing the same by high frequency oscillations, a conductive member in the path of radiation of said radiator, an eleccuits, a coupling between said circuitsand con ductive member, and means for modulating the potential on the control electrode of said device in accordance with signals.
4. In a signalling system, a beam radiator and means for setting up high frequency oscillations therein, a plurality of conducting members in the path of radiation from said beam radiator and a controlled oscillator coupled to each conducting member, each controlled oscillator comprising an electron discharge device having an anode, a cathode, and a control electrode, means for applying positive potential to said control electrodes with respect to said cathodes, and a potential of lesser value tosaid anodes with respect to said cathodes whereby the electrons-emitted by said cathode oscillate between said anodes and cathodes, and means for applying modulating potentials to said control electrodes.
5. In a signalling system, an ultrahigh frequency radiator, an ultrahigh frequency oscillator coupled to said radiator to produce radiation of ultrahigh frequency energy therefrom and means for modulating said ultrahigh irequenoy oscillations comprising an electron discharge device having an anode, a cathode and a blocking condenser in series between said control grid and cathode, means for applying a positive potential to said control electrode and a lesser potential to said anode, means for applying modulating potentials between said control grid and said cathode, and a coupling between one of said loop circuits and said radiator.
ALFRED AUBYN LINSELL.
US53522A 1935-01-25 1935-12-09 Ultrahigh frequency electron discharge modulator Expired - Lifetime US2121877A (en)

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2515663A (en) * 1945-09-13 1950-07-18 Gen Railway Signal Co Negative resistance coupling device
US2607004A (en) * 1947-09-12 1952-08-12 Donald B Harris Radio transmission system

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2515663A (en) * 1945-09-13 1950-07-18 Gen Railway Signal Co Negative resistance coupling device
US2607004A (en) * 1947-09-12 1952-08-12 Donald B Harris Radio transmission system

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