US2476034A - Conformal grating resonant cavity - Google Patents

Conformal grating resonant cavity Download PDF

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US2476034A
US2476034A US605408A US60540845A US2476034A US 2476034 A US2476034 A US 2476034A US 605408 A US605408 A US 605408A US 60540845 A US60540845 A US 60540845A US 2476034 A US2476034 A US 2476034A
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grating
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Fox Arthur Gardner
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AT&T Corp
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P1/00Auxiliary devices
    • H01P1/16Auxiliary devices for mode selection, e.g. mode suppression or mode promotion; for mode conversion
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P7/00Resonators of the waveguide type
    • H01P7/06Cavity resonators

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  • a principal object of the invention is to suppress predetermined higher order waves in wave guides and cavity resonators.
  • a further object of the invention is to increase the effective Q of a resonant cavity, by accentuating waves of a predetermined low order and suppressing waves of higher order.
  • Another object of the invention is to provide reactances with high Q, which will not generate higher order waves up to a predetermined order, particularly in wave guides of a size, capable of supporting such higher order waves.
  • Fi 1 shows a wave guide containing a high Q resonant cavity in accordance with the invention.
  • Fig. 1A represents a sectional view of the grating shown in Fig. 1.
  • Fig. 1B represents a modified grating in section.
  • Fig. 2 represents a rectangular wave guide modification of Fig. 1.
  • Fig. 2A is a cross-section of Fig. 2.
  • Fig 2B shows an explanatory diagram.
  • Fig. 3 is a cut-away View of Fig. 1 showing the details of the resonant cavity.
  • Fig 4 shows a modification thereof.
  • Fig. 5 shows a coaxial transmission line with a high Q coaxial resonator contained therein.
  • a feature of the invention is the provision of a conformal grating in a wave guide, characterized by a definite relationship between the number of higher order waves which must be suppressed and the number of wires or corresponding elements of the grating.
  • a further feature of the invention is to provide a resonant cavity having high Q by terminating it with a conformal grating, designed to suppress higher order Waves and spurious resonances.
  • a wave guide is capable of transmitting electromagnetic energy in one or more of an infinite number of ways or wave modes, distinguishable from each other by characteristic field patterns formed within the guide. In some instances, only one or a limited number of Wave modes may be excited depending upon the frequency employed, the geometry of the device for applying the energy to the guide and the geometry of the guide itself.
  • All wave modes which can exist within a tubular conductor may be classified either as transverse electric I'E or transverse magnetic TM.
  • TEmn For rectangular wave guides, a specific mode is designated as TEmn or 'IMmn, the indicia m and n representing the number of half-wave variations in field intensity developed in traversing the cross-section of the guide along the principal, orthogonal axes.
  • the term dominant wave refers to the dominant mode, characterized by the lowest possible frequency which the wave guide will support. In the case of a rectangular guide, TE'm is the dominant mode.
  • All other modes may be designated as higher order waves, their indicia m, n being higher than those of the dominant mode.
  • conformal grating refers to a grating of wires or the like, configurated to conform or be parallel to the electric lines of force of the desired wave mode at the location of the grating.
  • effective Q refers to the percentage selectivity of a resonant cavity, namely where A is the width of the selectivity curve between points 3 decibels down and f is the midband frequency.
  • Irises and conformal gratings in wave guides have heretofore been known and disclosed in the United States patents of G. C. Southworth 2,129,- 712 patented September 13, 1938, 2,129,713 patented September 13, 1938, and in the United States Patent 2,151,157 of S. A. Schelkunoif, patented March 21, 1939.
  • Resonant cavities or chambers (for use with ultra-high frequencies and microwaves) terminated by an apertured iris member or the like, have heretofore been disclosed in the United States patents of G. C. Southworth 2,106,768 patented February 1, 1938, and W. L. Barrow 2,281,- 550 patented May 5, 1942.
  • an iris plate with a circular or'recta'ngular' opening in the center, placed acrossa recta'ngular" guide is particularly suitable for use infilterl con struction, because inherently it will not generate higher order waves up to the third order.
  • the first higher order wave which such a centrally apertured iris generates, is the TEs, 0, and assuming that the wave guide is beyond cut-off for this wave,;no power will be abstracted from the .domin'antz'mode, so that the iris will act as a pure shunt" reactance.
  • the iris should-be replaced by some other form of structure, which does not generatei-TEan or other higher order waves, capable of propagation in said guide.
  • a conformal grating capable of suppressing higher order waves can be used to construct more efficient wave guide structuresingeneral andiparti'cularly when applied as a closure to a resonant cavity, than a corresponding apertu'redliri's plate. With the conformal-grating, less power'is lost as dissipation for any given value of reactanc'epro 1 vided by the grating, i.
  • aconformal grating adapted'for the suppression of higher order waves may be effected in the following manner: First. the direction of the lines of force at everyp'oint in the cross-section of the wave guidewillbe' de'* termined by calculation or by experiment. Thus. in the case of a rectangular wave guide" excited by the dominant transverse electric wave, theeleci tric' lines of force are known from" theory to. be everywhere parallel to-the shortsidesoff'thewave guide.
  • the direction of the wire at any point along its length will then be perpendicular to the lines of electric force. This procedure may be repeated as many times as necessary for different positions of the wire in the cross-section of thewaveguidaso that; finally a' map may be drawnof contours, orthogonal to the electric field.
  • the actual conformal grating will then consist of conducting wires more or less equally spaced andso shaped-that. they are everywhere perpendicular to the orthogonal contours aforemen- The susceptance of the grating will be essentially' dependent on two principal factors, (1) the number of:wires, (2) the diameter of the wires:
  • the grating will thenrbe'provided with" the appropriate number of wires.
  • the distribution of the'electric field set up by a dominant wave across the. grating wouldbe-approximatelyas illustratedzin Fig. 232.
  • 'Iihe distribution of electric field may in: accordance with Fourier series analysis, be: considered to consist of the fundamental component (the half. sinewave of the dominantmode) and an: infinite number of harmonically related, sinusoidal components corresponding tothe-higher order waves. In general, .all higher order waves will be present in some amount.
  • the amplitude of the lower harmonic components will. be'decreased.
  • the first harmonic'or higher order wavegenerated with any appreciable amplitude will be that one having a periodicity corresponding. to the spacing between wires.
  • all higher order modes below the TEzm-+1; 0 mode will be substantially eliminated. Consequently, by the use of a large um-- benofrwires-in-thagrating, a corresponding number of higher order waves will beredu'c'ed toprac tically zero amplitude;
  • the inductance of the grating then may be adjusted by varying the diameter of the wires.
  • the use of larger diameter wires will result in' a lower inductance-and conversely, finewires will produce high inductance.
  • the exact determinations are preferably made experimentally. In order" that theQ of the-grating may be as high as possible, the wiresvsh'ould possessgood conductivity.
  • the source 2 maybe any suitable type of osciltlator known to' theart, such as the'Barkhausen Kurasparkgap, the" magnetron, the: velocity variation' tube; etc.
  • the oscillator 2 is connected to the wave guide by diam'etral. wires 3; whereby a substantially linearly polarized" field vector E0: is produced at the center: ofa dominantwave TEE, nrpa'tterne developed across the corresponding section of the guide.
  • the conformal grating 4 whose wires 6 (Fig. 1A) conform at every point thereof, to the field pattern of the dominant wave, constitutes a shunt reactance across the guide, and to the extent that it discriminates against the generation and propagation of higher order waves, it is more effective and suitable as an element of an impedance network or filter.
  • bands or strips of metal 6' of good conductance may be used in the grating, as shown in Fig. 13.
  • Fig. 2 shows a rectangular wave guide I, excited by an oscillator 2', to establish a dominant wave therein.
  • the rectangular grating 4' is placed across the guide, transverse to its principal axis, to constitute an effective reactance, with the disturbing effects of higher order waves substantially eliminated to a predetermined high order (m, n).
  • Fig. 2A shows the rectangular grating i with an efiective number and spacing of Wires thereof, and Fig. 23 illustrates the field pattern developed by the grating.
  • a dominant TE, wave enters and excites a resonant chamber 4.
  • the chamber or cavity 4 is approximately in length (where A is the wavelength for which the chamber will show sharp resonance effects either in voltage or current), and is bounded at one end by a reflecting piston 5 and at the other end by a conformal grating 6.
  • Variable tuning of the cavity is effected by moving piston 5 along its length.
  • Fig. i shows a resonant chamber or cavity bounded by a pair of conformal gratings l, spaced a distance apart.
  • the resonant frequency, set up in the cavity may be transmitted to load 8, all other frequencies being efiectively discriminated against by virtue of the high Q.
  • the conformal grating distributes the wave energy uniformly over the guide cross-section, thereby tending to foster the development of a wave front of the dominant mode in the resonant chamber.
  • a source 9 of oscillations is applied to a coaxial line III, to excite the dominant coaxial mode therein, the corresponding lines of force being radial and extending between the inner and outer conductors.
  • the conformal grating II consisting of radial wires I2, conformal to the dominant mode field pattern, is placed in the coaxial line as a shunt reactance thereto. The elimination of higher order waves,
  • the coaxial grating particularly suitable as a reactance element per se, or as a closure for the coaxial tuned section I3.
  • the Q of the coaxial resonant section is materially increased and certain higher order waves are appreciably reduced.
  • Tuning of resonant section I3 to may be effected by the reflecting piston I-i operated by handles I5.
  • a Wave guide means for exciting in said guide electromagnetic waves of predetermined frequency and of a predetermined mode, said guide having a cross section large enough to permit propagation of higher order waves at said predetermined frequency, a conductively bounded cavity resonator comprising a section of said guide and a pair of conductive gratings disposed transversely of said guide and spaced apart therein, each of said gratings comprising a multiplicity of wires spaced apart and conforming in direction with the transverse electric field of the said waves of predetermined mode, said resonator being proportioned to resonate at the frequency of the said waves of predetermined mode, and a load coupled to said guide at a point separated from said exciting means by at least one of said gratings for utilizing the energy of the waves of said predetermined mode.
  • a main wave guide means for exciting in said guide waves of the dominant mode at a predetermined operating frequency, said guide having a cross section dimensioned to support and propagate other modes at said predetermined operating frequency, a cavity resonator of high Q comprising a section of said guide and a conductive grating at each end of said section, said gratings being spaced apart a distance substantially equal to a half wavelength, and each of said gratings comprising uniform conductors conformal to the said dominant mode and equally spaced apart to inhibit the generation of modes below TE2m+1, o where m represents the number of wires in the grating, and a load in said main guide external to said resonator for utilizing the energy of said dominant mode.

Description

July 12, 1949. A. G. FOX 2,476,034
CONFORMAL GRA'IING RESONANT CAVITY Filed July 16, 1945 2 Sheets-Sheet l FIG. 2
INVENTOR A 6. FOX
4 TTORNE V July 12, 1949. A. G. FOX
CONFORMAL GRATING RESONANT CAVITY 2 Sheets-Sheet 2 Filed July is, 1945 FIG. 3
IIIIIIIIII;I"IIA RESONANT CA WT Y WITH HIGH 0 RESONANT CAVITY WITH HIGH 0 FIG. .5
INVENTOR A. 6. FOX
ATT'ORN Y Patented July 12, 1949 UNITED STATES PATENT OFFICE CONFORMAL GRATIN G RESONAN T CAVITY Arthur Gardner Fox, Red Bank, N. .L, assignor to Bell Telephone Laboratories, Incorporated, New York, N. Y., a corporation of New York Application July 16, 1945, Serial No. 605,408
2 Claims.
sion.
A principal object of the invention is to suppress predetermined higher order waves in wave guides and cavity resonators.
A further object of the invention is to increase the effective Q of a resonant cavity, by accentuating waves of a predetermined low order and suppressing waves of higher order.
Another object of the invention is to provide reactances with high Q, which will not generate higher order waves up to a predetermined order, particularly in wave guides of a size, capable of supporting such higher order waves.
Further objects will become apparent from a consideration of the specification, and the detailed drawings wherein:
Fi 1 shows a wave guide containing a high Q resonant cavity in accordance With the invention.
Fig. 1A represents a sectional view of the grating shown in Fig. 1.
Fig. 1B represents a modified grating in section.
Fig. 2 represents a rectangular wave guide modification of Fig. 1.
Fig. 2A is a cross-section of Fig. 2.
Fig 2B shows an explanatory diagram.
Fig. 3 is a cut-away View of Fig. 1 showing the details of the resonant cavity.
Fig 4 shows a modification thereof.
Fig. 5 shows a coaxial transmission line with a high Q coaxial resonator contained therein.
A feature of the invention is the provision of a conformal grating in a wave guide, characterized by a definite relationship between the number of higher order waves which must be suppressed and the number of wires or corresponding elements of the grating.
A further feature of the invention is to provide a resonant cavity having high Q by terminating it with a conformal grating, designed to suppress higher order Waves and spurious resonances.
A wave guide is capable of transmitting electromagnetic energy in one or more of an infinite number of ways or wave modes, distinguishable from each other by characteristic field patterns formed within the guide. In some instances, only one or a limited number of Wave modes may be excited depending upon the frequency employed, the geometry of the device for applying the energy to the guide and the geometry of the guide itself.
All wave modes which can exist within a tubular conductor may be classified either as transverse electric I'E or transverse magnetic TM. In
2 the former case (TE), the electric field is at all points directed transverse to the axis of the wave guide and there are no components parallel to the axis, While in the latter case (TM) the same applies to the magnetic field.
For rectangular wave guides, a specific mode is designated as TEmn or 'IMmn, the indicia m and n representing the number of half-wave variations in field intensity developed in traversing the cross-section of the guide along the principal, orthogonal axes.
The term dominant wave refers to the dominant mode, characterized by the lowest possible frequency which the wave guide will support. In the case of a rectangular guide, TE'm is the dominant mode.
All other modes may be designated as higher order waves, their indicia m, n being higher than those of the dominant mode.
The term conformal grating as used in this specification refers to a grating of wires or the like, configurated to conform or be parallel to the electric lines of force of the desired wave mode at the location of the grating.
The term effective Q, as used in this specification, refers to the percentage selectivity of a resonant cavity, namely where A is the width of the selectivity curve between points 3 decibels down and f is the midband frequency.
Irises and conformal gratings in wave guides have heretofore been known and disclosed in the United States patents of G. C. Southworth 2,129,- 712 patented September 13, 1938, 2,129,713 patented September 13, 1938, and in the United States Patent 2,151,157 of S. A. Schelkunoif, patented March 21, 1939.
Resonant cavities or chambers (for use with ultra-high frequencies and microwaves) terminated by an apertured iris member or the like, have heretofore been disclosed in the United States patents of G. C. Southworth 2,106,768 patented February 1, 1938, and W. L. Barrow 2,281,- 550 patented May 5, 1942.
It is well known that iris plates or corresponding structures placed in a wave guide for the purpose of introducing the effect of a reactance have concomitantly acted as generators of waves of higher order than the one for which the reactive effect was desired. One way of suppressing such higher order waves in common practice has been by the employment of wave guides so dimenthe dominant mode, resulting in inefficiency and spurious resonance effects."
Thus, an iris plate with a circular or'recta'ngular' opening in the center, placed acrossa recta'ngular" guide is particularly suitable for use infilterl con struction, because inherently it will not generate higher order waves up to the third order. Thus,
it does not give rise to the following waves: TEz, o, 'I'E'1,1, TM1,1, TE2, 1, TMz, 1. The first higher order wave, which such a centrally apertured iris generates, is the TEs, 0, and assuming that the wave guide is beyond cut-off for this wave,;no power will be abstracted from the .domin'antz'mode, so that the iris will act as a pure shunt" reactance.
However, in the case of a wave guide of still larger dimensions such that TEa, o canbe' propagated, the iris should-be replaced by some other form of structure, which does not generatei-TEan or other higher order waves, capable of propagation in said guide.
In accordance with the invention, it has been found that higher order modes of oscillation within a wave guidemay be eliminated or sub- Suc'i'r higher order waves tend to abstract power from stantially reduced by introducing a conformal grating comprising a grid-oft wires, paralleling at all points thereof the lines of ele'ctric'force' ofithe desired or dominant wave mode associated with the wave guide or cavity. Equivalently, the'number of wires employed in thegratin'g, orI thespacing between adjacent wires, may bepre'determined to insure the'virt'ual absence of'any number of higher order wave modes. Besides retaining available power in the desired mode, the conformal grating makes available a? shunt reactance element of higher Q than the apertured iris. Thus, it has been found experimentally, that a conformal grating capable of suppressing higher order waves can be used to construct more efficient wave guide structuresingeneral andiparti'cularly when applied as a closure to a resonant cavity, than a corresponding apertu'redliri's plate. With the conformal-grating, less power'is lost as dissipation for any given value of reactanc'epro 1 vided by the grating, i. e., the Q of theconformal grating is higher than the Q of the apertured iris, where Q represents the ratio' of the series reactance to the series resistance of the iris'orgrating The construction of aconformal grating adapted'for the suppression of higher order waves may be effected in the following manner: First. the direction of the lines of force at everyp'oint in the cross-section of the wave guidewillbe' de'* termined by calculation or by experiment. Thus. in the case of a rectangular wave guide" excited by the dominant transverse electric wave, theeleci tric' lines of force are known from" theory to. be everywhere parallel to-the shortsidesoff'thewave guide. In the case of a waveguide of'any' other cross-section, for example, circular; it may be simpler to determine the direction of the lines'of electric force experimentally by placing a fine wire across the guide in a direction more or less perpendicular to the electric field, and then bend:-
ing and positioning the wire in such a way that it produces no reflection of power flowing through the wave guide. The direction of the wire at any point along its length will then be perpendicular to the lines of electric force. This procedure may be repeated as many times as necessary for different positions of the wire in the cross-section of thewaveguidaso that; finally a' map may be drawnof contours, orthogonal to the electric field. The actual conformal grating will then consist of conducting wires more or less equally spaced andso shaped-that. they are everywhere perpendicular to the orthogonal contours aforemen- The susceptance of the grating will be essentially' dependent on two principal factors, (1) the number of:wires, (2) the diameter of the wires:
Having determined the number of higher order waves that the guide is capable of propagating and which must not be generated, the grating will thenrbe'provided with" the appropriate number of wires. In general, if many uniformly spaced wires-are used, for'example, 20 or 30, the distribution of the'electric field set up by a dominant wave across the. grating wouldbe-approximatelyas illustratedzin Fig. 232. 'Iihe distribution of electric field may in: accordance with Fourier series analysis, be: considered to consist of the fundamental component (the half. sinewave of the dominantmode) and an: infinite number of harmonically related, sinusoidal components corresponding tothe-higher order waves. In general, .all higher order waves will be present in some amount. However, asthe number of wires (m)- is increased, the amplitude of the lower harmonic components will. be'decreased. As (m) becomes large, for example greater thanlO, the first harmonic'or higher order wavegenerated with any appreciable amplitude will be that one having a periodicity corresponding. to the spacing between wires. Specifically, all higher order modes below the TEzm-+1; 0 mode will be substantially eliminated. Consequently, by the use of a large um-- benofrwires-in-thagrating, a corresponding number of higher order waves will beredu'c'ed toprac tically zero amplitude;
Normally, it will .notbe' necessary toruse such a closely spaced grating... A relatively few wires will suflice to suppress undesired higher order waves'in such guides? as are likely to be usedv in practice:
Having arranged the grating with a predetermined number of wires in accordance with the number of higherorder waves-to be suppressed, the inductance of the grating then may be adjusted by varying the diameter of the wires. The use of larger diameter wires will result in' a lower inductance-and conversely, finewires will produce high inductance. The exact determinations are preferably made experimentally. In order" that theQ of the-grating may be as high as possible, the wiresvsh'ould possessgood conductivity.
Referring; to Fig. I, a waveguide of the metal sheath type'disclosed in" the United States patent toG'. C. Southworth 2,129,712 patentedseptember 13,1938; is shown a'nd asource 2 of microwaves is shown connectedithereto for producing adominant transverse electric wave.
The source 2 maybeany suitable type of osciltlator known to' theart, such as the'Barkhausen Kurasparkgap, the" magnetron, the: velocity variation' tube; etc.
The oscillator 2 is connected to the wave guide by diam'etral. wires 3; whereby a substantially linearly polarized" field vector E0: is produced at the center: ofa dominantwave TEE, nrpa'tterne developed across the corresponding section of the guide.
The conformal grating 4, whose wires 6 (Fig. 1A) conform at every point thereof, to the field pattern of the dominant wave, constitutes a shunt reactance across the guide, and to the extent that it discriminates against the generation and propagation of higher order waves, it is more effective and suitable as an element of an impedance network or filter. In lieu of conducting wires, bands or strips of metal 6' of good conductance may be used in the grating, as shown in Fig. 13.
Fig. 2 shows a rectangular wave guide I, excited by an oscillator 2', to establish a dominant wave therein. The rectangular grating 4' is placed across the guide, transverse to its principal axis, to constitute an effective reactance, with the disturbing effects of higher order waves substantially eliminated to a predetermined high order (m, n).
Fig. 2A shows the rectangular grating i with an efiective number and spacing of Wires thereof, and Fig. 23 illustrates the field pattern developed by the grating.
In Fig. 3, a dominant TE, wave enters and excites a resonant chamber 4. The chamber or cavity 4 is approximately in length (where A is the wavelength for which the chamber will show sharp resonance effects either in voltage or current), and is bounded at one end by a reflecting piston 5 and at the other end by a conformal grating 6. Variable tuning of the cavity is effected by moving piston 5 along its length. Through the reduction or practical absence of higher order waves up to a predetermined high order mode, the Q of the cavity is considerably enhanced.
The modification illustrated in Fig. i shows a resonant chamber or cavity bounded by a pair of conformal gratings l, spaced a distance apart. The resonant frequency, set up in the cavity may be transmitted to load 8, all other frequencies being efiectively discriminated against by virtue of the high Q. The conformal grating distributes the wave energy uniformly over the guide cross-section, thereby tending to foster the development of a wave front of the dominant mode in the resonant chamber.
Referring to Fig. 5, a source 9 of oscillations is applied to a coaxial line III, to excite the dominant coaxial mode therein, the corresponding lines of force being radial and extending between the inner and outer conductors. The conformal grating II, consisting of radial wires I2, conformal to the dominant mode field pattern, is placed in the coaxial line as a shunt reactance thereto. The elimination of higher order waves,
consequent upon its use, renders the coaxial grating particularly suitable as a reactance element per se, or as a closure for the coaxial tuned section I3. In the latter application, the Q of the coaxial resonant section is materially increased and certain higher order waves are appreciably reduced. Tuning of resonant section I3 to may be effected by the reflecting piston I-i operated by handles I5.
What is claimed is:
1. In combination, a Wave guide, means for exciting in said guide electromagnetic waves of predetermined frequency and of a predetermined mode, said guide having a cross section large enough to permit propagation of higher order waves at said predetermined frequency, a conductively bounded cavity resonator comprising a section of said guide and a pair of conductive gratings disposed transversely of said guide and spaced apart therein, each of said gratings comprising a multiplicity of wires spaced apart and conforming in direction with the transverse electric field of the said waves of predetermined mode, said resonator being proportioned to resonate at the frequency of the said waves of predetermined mode, and a load coupled to said guide at a point separated from said exciting means by at least one of said gratings for utilizing the energy of the waves of said predetermined mode.
2. In combination, a main wave guide, means for exciting in said guide waves of the dominant mode at a predetermined operating frequency, said guide having a cross section dimensioned to support and propagate other modes at said predetermined operating frequency, a cavity resonator of high Q comprising a section of said guide and a conductive grating at each end of said section, said gratings being spaced apart a distance substantially equal to a half wavelength, and each of said gratings comprising uniform conductors conformal to the said dominant mode and equally spaced apart to inhibit the generation of modes below TE2m+1, o where m represents the number of wires in the grating, and a load in said main guide external to said resonator for utilizing the energy of said dominant mode.
ARTHUR GARDNER FOX.
REFERENCES CITED The following referenlces are of record in the file of this patent:
UNITED STATES PATENTS Number Name Date 2,088,749 King Aug. 3, 1937 2,129,714 Southworth Sept. 13, 1938 2,267,289 Roosenstein Dec. 23, 1941 2,364,371 Katzin Dec. 5, 1944
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US2589248A (en) * 1946-01-11 1952-03-18 Andrew V Haeff Signal generator
US2593155A (en) * 1947-03-07 1952-04-15 Bell Telephone Labor Inc Cavity resonator
US2830289A (en) * 1953-04-02 1958-04-08 Gen Precision Lab Inc Broad band echo box
DE1081086B (en) * 1956-01-04 1960-05-05 Gen Electric Co Ltd Waveguide device
US2951998A (en) * 1956-04-19 1960-09-06 Philips Corp Waveguide variable impedance apparatus
US3218586A (en) * 1960-04-22 1965-11-16 Decca Ltd Transmission of dominant transverse electric mode in large rectangular waveguide, with polarization parallel to width, by use of mode absorber
US3242439A (en) * 1962-06-21 1966-03-22 Bell Telephone Labor Inc Visible output gaseous optical maser with mode pattern selector
US3479622A (en) * 1966-04-11 1969-11-18 Gen Instrument Corp Multi-compartment tuner constructtion facilitating electromagnetic high-frequency coupling and minimizing electrostatic low-frequency coupling
US3614518A (en) * 1970-03-16 1971-10-19 Varian Associates Microwave tuner having sliding contactors
US3657670A (en) * 1969-02-14 1972-04-18 Nippon Electric Co Microwave bandpass filter with higher harmonics rejection function
US3697898A (en) * 1970-05-08 1972-10-10 Communications Satellite Corp Plural cavity bandpass waveguide filter
US4598262A (en) * 1983-06-08 1986-07-01 Trw Inc. Quasi-optical waveguide filter

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US2088749A (en) * 1935-10-30 1937-08-03 Bell Telephone Labor Inc Reception of guided waves
US2129714A (en) * 1935-10-05 1938-09-13 American Telephone & Telegraph Wave type converter for use with dielectric guides
US2267289A (en) * 1938-03-26 1941-12-23 Telefunken Gmbh Transmission system
US2364371A (en) * 1940-08-31 1944-12-05 Rca Corp Double polarization feed for horn antennas

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US2129714A (en) * 1935-10-05 1938-09-13 American Telephone & Telegraph Wave type converter for use with dielectric guides
US2088749A (en) * 1935-10-30 1937-08-03 Bell Telephone Labor Inc Reception of guided waves
US2267289A (en) * 1938-03-26 1941-12-23 Telefunken Gmbh Transmission system
US2364371A (en) * 1940-08-31 1944-12-05 Rca Corp Double polarization feed for horn antennas

Cited By (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2589248A (en) * 1946-01-11 1952-03-18 Andrew V Haeff Signal generator
US2593155A (en) * 1947-03-07 1952-04-15 Bell Telephone Labor Inc Cavity resonator
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