US2408055A - Ultra high frequency coupling device and system - Google Patents

Ultra high frequency coupling device and system Download PDF

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US2408055A
US2408055A US545314A US54531444A US2408055A US 2408055 A US2408055 A US 2408055A US 545314 A US545314 A US 545314A US 54531444 A US54531444 A US 54531444A US 2408055 A US2408055 A US 2408055A
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guide
waves
wave
frequency
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US545314A
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Milan D Fiske
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General Electric Co
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General Electric Co
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01SRADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
    • G01S7/00Details of systems according to groups G01S13/00, G01S15/00, G01S17/00
    • G01S7/02Details of systems according to groups G01S13/00, G01S15/00, G01S17/00 of systems according to group G01S13/00
    • G01S7/03Details of HF subsystems specially adapted therefor, e.g. common to transmitter and receiver
    • G01S7/034Duplexers

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  • My invention relates to apparatus and methods for coupling ultra high frequency systems and it has for its object to provide a new and improved broad band coupling device for ultra high frequency circuits of the type employing dielectric wave guides of the hollow pipe type, concentric or coaxial transmission lines, or interconnecting wave guides and coaxial transmission lines.
  • the antenna radiating high intensity signals from the transmitter and receiving relatively weak signals reflected from an object upon which the radiated signals impinge, it has long been a problem to decouple the high frequency signal nerating apparatus from the interconnecting circuits to prevent dissipation of the relatively weak incoming signals in the circuits of such apparatus or reflection of the signals to the antenna to be reradiated thereby, Accordingly, it is another object of my invention to provide a new and improved device for decoupling ultra high frequency generating equipment in such a system from receiving circuits during periods when incoming signals are being received by the antenna.
  • I provide new and improved apparatus and methods for coupling elements or parts of high frequency systems, such as systems designed for the utilization of ultra high frequency electromagnetic waves or microwaves.
  • An anti-resonant element which isconnected across a wave guide used for transmitting ultra high frequency waves, breaks down under relatively high energy waves transmitted from the system, but is not broken down for received waves of considerably lower energy level.
  • the element is so constructed that it effectively shortcircuits the wave guide and it is so located with respect to the circuits of the receiving equipment that it assures efiicient transmission of all incoming power into these receiving circuits.
  • the anti-resonant element employs a gas-filled section of dielectric wave guide connected to a principal wave guide system through a resonant slot sealed by a glazed window, the slot breaking down in the presence of Waves of high energy level.
  • the invention includes the use of additional anti-resonant elements serially connected between the generating equipment of the system and the ultra high frequency circuits of the receiving equipment to insert a resistance in series with the circuits of the generating equipment to prevent dissipation of the energy of received signals.
  • the serially connected element may comprise a breakdown element which eiiectively short-circuits the anti-resonant element in the presence of high energy signals and provides high reflection of low level signals.
  • FIG. 1 illustrates an ultra high frequency system embodying the coupling device of my invention
  • Fig. 2 is an enlarged sectional view of the coupling device employed in the system of Fig. 1
  • Fig. 3 diagrammatically illustrates a modification of the invention as embodied in an ultra high frequency signalling system
  • Figs. 4 and 5 illustrate alternative forms of resistance elements which may be employed in the system of Fig. 3
  • Fig. 6 illustrates a broad band coupling device particularly adapted for high frequency signalling systems operating at low power levels
  • Figs. '7 and 8 illustrate different forms of breakdown elements which may be employed in the system of Fig. 6.
  • Fig. 1 illustrates an ultra high frequency system which may be used, for example, for radio detection and direction purposes.
  • the transmitter l which includes an ultra high frequency generator 2 which may be for example a magnetron, is connected to a dielectric Wave guide 3 which is terminated at its other end in a flared horn or radiative element l.
  • a receiver 5 is likewise connected to wave guide 3 through a coupling unit which comprises a plurality of transverse metallic walls 68 connected across a branch wave guide 9.
  • the transverse walls 6-8 are provided with resonant or tuned.
  • apertures H such as slots which may be of rectanguopposite end of the branch wave guide 9 is like-' wise closed by a transverse wall 53 having a resonant or tuned aperture therein sealed by a glass window it.
  • guide t is filled with gas and the resonant slot structures Ill of transverse walls 6 and'l may,
  • the rectangular guides 3 and 9 may comprise metallic enclosing walls constructed of a conductive material, such as copper or brass.
  • the depth and height of the guide, the dielectric constant of the medium within the guide, and the wave pattern determine principally the critical or cut-oi? frequency of the guide.
  • the dielectric medium through which the electromagnetic. energy istransmitted may be considered as being. air or gas.
  • the waves may also besatisfactorily transmitted through an evacuated space.
  • the gaseous medium within the se'aled'guide 9 maybe, for example, hydrogen under a pressure of about ten millimeters.
  • the transverse walls H and [3.preferably are formed of an iron-nickel-cobalt alloy sealed to the walls of. theguide 9 and the windows l2, is sealed across the resonant apertures in these transverse walls preferably are formed of a boro silicate glass.
  • the transmitter I propagates a high intensity electromagnetic wave along the wave guide 3. to be radiated by antenna 4.
  • Lower intensity signals received from space after reflection from an object upon which the signals impinge, are transmitted by the radiating element or horn 4 to the receiver ii over the wave guides 3 and-9.
  • the slots l6 affect a concentration of the 'field intensity or potential incident to the electromagnetic field across the horizontal edges of the slot.
  • antenna 4 provide substantially reflectionless transmission over a relatively broad band of frequencies.
  • a unidirectional potential from any suitable source (not shown) and connected between electrodes l5 and the walls 6, "l maintains a discharge across the resonant gaps in transverse walls 6 and 'l to cause the gaps to break down more readily.
  • the resonant gaps in walls II and 8 break down because the magnitude of the high intensity waves is sufficient to cause ionization of the gas on the interior surface ofthe window 12 and across the gap is in transverse wall 8. An electric discharge, therefore, takes place across all of the resonant slots. which prevents transmission of high intensity signals to the sensitive apparatus of the receiver 5.
  • anti-resonant element It, that is, an'element which hinders dissipation of the incoming energy in the high Q circuits of the transmitter, is connected across the wave guide 3 between the-point of connection of branch guide 9 and transmitter l at a point spaced fromwave guide 9 by a distance d equal to a quarter wave length at the mid-band frequency of the system.
  • the wave guide I7 is short-circuited at its end remote from Wave guide 3 by a transverse metallic wall !8.
  • transverse metallic wall 19 having a resonant slottherein across which is sealeda glass window 253.
  • the transverse metallic wall It is constituted preferably of an iron-nickel-cobalt alloy and is provided with a recessed shoulder 2! across which is hermetically sealed the window 20 formed of boro silicate glass.
  • the wave guide section ll is closed, exhaunted, and filled with gas to the proper pressure through a tubulation 23.
  • the wall It and the glass window 23 are made sufhcicntly thin that they have very small phase extension along the guide and, hence, can be made reflectionless and of very low Q, the Q being determined by the.
  • the dielectric window 20 breaks down when the magnitude of these waves reaches a predeteraeoaoss mined value, the voltage difference being suincient to cause ionization of the gas on the interior surface of the window 20, and an electric discharge takes place across this window.
  • the decoupling element 46 itself causes virtually no dissipation of energy at the lower level of incoming signals, the dissipation in the element [6 being less than one-tenth of one per cent of the total received energy.
  • FIG. 3 there is shown an ultra high frequency circuit which employs a second anti-resonant element or decoupling device 24 connected across the wave guide 3 between the first anti-resonant element l6 and the transmitter I and spaced from the element [6 by a distance equal to a quarter wave length at the mid band frequency of the system.
  • the second antiresonant element 24 separated from the element l6 by a distance equal to a multiple of a quarter wave length at the mid band frequency not only substantially doubles the band width obtainable with asingle anti-resonant element, but reduces the possibility of great loss of low level signals at frequencies near the edges of the pass band, especially if the element 24 is made to be moderately dissipative to low level signals.
  • the magnetron 2 of the transmitter I is not only substantially doubles the band width obtainable with asingle anti-resonant element, but reduces the possibility of great loss of low level signals at frequencies near the edges of the pass band, especially if the element 24 is made to be moderately dissipative to low level signals.
  • Figs. 4 and 5 Two arrangements which may be used for presenting apredetermined resistance to low level signals, but which have substantiallylittle effect upon high level transmitter power, are shown in Figs. 4 and 5.
  • a resistance paint 25 which may be, for example, a graphite-impregnated silicone varnish .or a tin oxide deposit.
  • This paint is placed on the outside of the window 20, i. e., on the side facing the wave guide 3, away from the electric discharge which occurs across the inner surface of the window when high intensity waves in the wave guide 3 cause a breakdown of the resonant gap in the transverse Wall l9.
  • the resistive paint 25 is applied to the surface of a transverse wall 21, which may comprise a pane of glass and which is spaced from the short-circuited end wall 23 of the wave guide section by a distance equal to a quarter wave length at the mid band frequency. While the spacing of the glass plate 21 from the transverse wall [9 preferably is of the order of one-half wave length, it has been found that this spacing is not critical. If the resistance of element 25 is made equal to the characteristic resistance of the guide section, the spacing of wall 21 with respect to wall 19 may have any value. For higher resistance values of element 25, the spacing ofwall 21 with respect to wall I9 approaches a half wave length. Wall 28 is spaced from wall 21 by a distance equal to a quarter wave length, regardless of the resistance of element 25. Hence, for high resistance values of the element 25,'wall 28 is spaced from wall l9 by approximately threequarters of a wave length.
  • the arrangement illustrated in Fig. 5 has the advantage that its frequency sensitivity is very low and it affords the desired protection against resonance conditions over the entire band of operation of the high frequency system.
  • a gain in band width over the arrangement of Fig. 1 of approximately fifty per cent is obtained.
  • the dissipative paint element 25 is of much higher resistance than the discharge across the window 20 in the tuned aperture, the operation of the system for transmission of high energy waves from the transmitter l to the antenna 4 is unaffected by the addition of the'dissipative paint element.
  • a coupling device particularly adapted for high frequency signals operating at low power levels.
  • the energy of the high frequency waves propagated along the wave guide 3 from the transmitter connected therewith is insufficient to cause breakdown of window 20 across the resonant gap of transversemetallic wall l9.
  • by a distance equal to a quarter wave length at the mid band frequency has therein a cen-" trally positioned resonant gap I 321 constructed 1 to break down. and initiate an. electric discharge thereacross at any power leveldesired. When suchan electric discharge.
  • Thedecoupling device constituted by the stub waveguide- 30. is. sealed by the transparent window ZU-"and filled witha desired. gaseous medium .inthe manner pointed out; in connection with the description of the structure of Fig. 2.
  • the decoupling device of Fig. 6 is connected acrossthewave. guide 3 ata point spaced a quarter wave length from thepoint of connection ofthe receiver circuit therewith and is located between the point. of connection of. the receiver circuit and a source of ultra high frequency waves in the samemanner as.
  • Figs. 7 and 8 Twoforms of the resonant gap structure which may. be employed in. the coupling device of'Fig. 6 are illustrated in Figs. 7 and 8.
  • the metallic member 29 which. is placed across a wave guide as a transverse wall contains two symmetrically: placed circular apertures 33, 34.
  • the metallic wall 29 forms a pair of opposed points 35, 36 which define the gap 32 connecting the openings;33, 34.
  • the dimensions of the gap 32 are correlated with the total area of the wall 29 .to form an aperture which is resonant at the mid bandfrequency of the electromagnetic waves propagated along the wave guide 3.
  • the points 35, 36 form a gap which, when sealed in a gaseous medium as described previously, functions as means for effecting a conversion of the potential of the electromagnetic wave propagated therethrough and breaks down upon the incidence of electromagneticwaves of the relatively low energy level to produce current flow across the resonant aperture and. the metallic wal129.
  • the openings 31, 38 are rectangular in form and a central portion of the wall 29- forms .a pair of opposed points 39,.40 which define the gap 32 connecting, the openings 31, 38.
  • the structure of. Fig. 8 operates similar to that explainedin connection. with the description of Fig. 7.
  • my invention provides a. new and improvedapparatus and method for coupling elements or parts of high: frequency systems in Which transmission of low level signals to receiver circuits .of the system is assured by decoupling high reactance circuits of the transmitting equipment connected therewith d uring periods when such low level signals are being received. Furthermore, during transmitting periods, not only is the effect of the decoupling means employed removed from the system, but adequate protectionfor the receiver circuits is provided to prevent injury thereto.
  • means for transmitting high intensity waves over said guide andfor refiecting low intensity waves comprising astub section'of wave guide connected to said principal I. guide through an aperture tuned to the frequency' of said waves, said stub section having alength equal approximately to an odd multiple of i a quarter wavelength atsaid frequency, and said stubsection being short circuited-at itsendre motefrom said aperture.
  • means for transmitting high intensity waves over said guide and for reflecting low intensity waves comprising, a stub section of wave guide connected to said principal guide through an aperture tuned to the frequency of said waves, said stub section having a length equal approximately to an odd multiple of a quarter wave length at said frequency and being short circuited at its end remote from said aperture, and dielectric means sealed acrosssaid aperture,-said section being gas-filled to facilitate establishment of an electric discharge across'said aperture in the presence of said high intensity waves.
  • a first hollow pipe type wave guide for transmitting electromagnetic waves'di electrically, a transmitter connected .to said wave guide, a receiver connected to said wave guide through a branch transmission path, and means to decouple said transmitter from said guide to prevent dissipation therein-of low intensity signals.
  • a stub wave guide connected to saidfirst guide at-a point be tween sa-id transmitter and said path and spaced fromsaidpath by a distance equal .toa quarter wave lengthof. saidwave, saidastub guidev being connected to: said first guide through.
  • a first hollow pipe type-wave guide fortransmitting electromagnetic waves di electrically, a transmitter connected to said "wave guide: areceivenconnected'to said wave guide through a branch' transmission path, and means to decouple saidtransmitterfrom said guide to prevent dissipation therein-of lowintensity sig'- nals.
  • said transmitter and said path and spaced fronrsaid path-shy a distance equal to a quarter wave length of said waves
  • said stub guide being connectedttoasaid first guide through an aperture tunedntdthe frequency of said waves and being shortcircuit'ed at its end remote from said aperture and. having a length approximately equal to a quarter wavelength at said frequency, and dielectric'means. sealed-across said aperture, said sectionbeinggasefilledto facilitate establishment of; an. electric. discharge across: said aperture in the: presence of. said high intensity waves.
  • a system for transmitting and receiving ultra high frequency electromagnetic waves comprising a transmitter and a receiver connected by a common wave guide system of the hollow pipe type, a pair of stub wave guides connected across said common guide between the points of connection of said transmitter and receiver therewith, each of said stub guides being connected to said common guide through an aperture tuned to the frequency of said waves and being short circuited at a point spaced from said common guide by a distance approximately equal Ito a quarter wave length at said frequency, dielectric means sealed across said apertures, said stub guides being gas-filled to facilitate establishment of an electric discharge across the apertures thereof in the presence of high intensity waves in said common guide.
  • a coupling device for selectively controlling the transmission of electromagnetic waves over a first wave guide of the hollow pipe type in accordance with the energy of said waves comprising, a stub wave guide connected across said first guide and having a length approximately equal to a quarter wave length at the frequency of said waves, said stub guide being short-circuited at its end remote from said first guide, and a. transverse metallic wall connected across said stub guide at its point of connection with said first guide having an aperture therein tuned to the frequency of said wave.
  • a coupling device for selectively controlling the transmission of electromagnetic waves over a first wave guide of the hollow pipe type in accordance with the energy of said waves comprising, a stub wave guide connected across said first guide and having a length approximately equal to a, quarter wave length at the frequency of said waves, said stub guide being short-circuited at its end remote from said first guide, a transverse metallic wall connected across said stub guide at its point of connection with said first guide having an aperture therein tuned to the frequency of said wave, and dielectric means sealed across said aperture, said stub guide being gas-filled to establish an electric discharge across said aperture in the presence of high energy waves in said first guide.
  • a coupling device for selectively controlling the transmission of electromagnetic waves over a first wave guide of the hollow pipe type in accordance with the energy of said waves comprising, a stub wave guide connected across said first guide and having a length approximately equal to a quarter wave length at the frequency of said waves, said stub guide being short-circuited at its end remote from said first guide, a transverse metallic wall connected across said stub guide prising a transmitter and a receiver connected by a common wave guide system of the hollow pipe type, a pair of stub wave guides connected across said common guide between the points of connection of said transmitter and receiver therewith, each of said stub guides being connected to said common guide through an aperture tuned to the frequency of said waves and being short-circuited at a point spaced from said common guide by a distance approximately equal to a multiple of said quarter wave length at said frequency, one of said stub guides being connected to said common guide at a point spaced from the point of connection of said receiver therewith by a distance equal to a quarter wave length at said frequency,
  • a stub wave guide connected across said first wave guide and having a length approximately equal to an odd multiple of the quarter wave length at the frequency of said waves, said stub wave guide being shortcircuited at its end remote from said main guide and having a transverse metallic wall connected thereacross at its point of connection with said first guide, said metallic wall having an aperture therein tuned to the frequency of said waves, a dielectric window sealed across said aperture, and a resistance element attached to said window on its side facing said first guide.
  • a stub wave guide connected across said first wave guid and having a length approximately equal to an odd multiple of the quarter wave length at the frequency of said waves, said stub wave guide being short-circuited at its end remote from said main guide and having a transverse metallic wall connected thereacross at its point of connection with said first guide, said metallic wall having an aperture therein tuned to the frequency of said waves, a dielectric window sealed across said aperture, and a resistance element attached to said window on its side facing said first guide, said. stub guide being gas-filled to facilitate establishment of an electric discharge across said aperture in the presence of high intensity waves in aid first uide.
  • means for permitting transmission of waves above a predetermined energy level through said guide and resisting transmission of waves below said energy level therethrough comprising, a tub wave guide connected across said first wave guide and having a length approximately equal'to an odd multiple of the quarter wave length at the frequency of said Waves, said stub wave guide being shortcircuitedat its e d remote from said main guide and ,havinga transverse metallic wall connected therea ross ataits point of connection with-said firstsuidasaidmetallic wall having an aperturc thereintuned to.

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Description

Sept. 24, 1946. FlsKE I r 2,408,055
ULTRA HIGH FREQUENCY COUPLING DEVICE AND SYSTEM Filed July 1'7, 1944 IIIII'IIII.
Inventor: Milan D. Fiske,
His Attorney.
Patented Sept. 24, 1946 ULTRA HIGH FREQUENCY COUPLING DEVICE AND SYSTEM Milan D. Fiske, Schenectady, N. Y., assignor to General Electric Company, a corporation of New York Application July 17, 1944, Serial No. 545,314
14 Claims. 1
My invention relates to apparatus and methods for coupling ultra high frequency systems and it has for its object to provide a new and improved broad band coupling device for ultra high frequency circuits of the type employing dielectric wave guides of the hollow pipe type, concentric or coaxial transmission lines, or interconnecting wave guides and coaxial transmission lines.
In ultra high frequency systems which employ transmitting apparatus and receiving apparatus connected to the same antenna system, the antenna radiating high intensity signals from the transmitter and receiving relatively weak signals reflected from an object upon which the radiated signals impinge, it has long been a problem to decouple the high frequency signal nerating apparatus from the interconnecting circuits to prevent dissipation of the relatively weak incoming signals in the circuits of such apparatus or reflection of the signals to the antenna to be reradiated thereby, Accordingly, it is another object of my invention to provide a new and improved device for decoupling ultra high frequency generating equipment in such a system from receiving circuits during periods when incoming signals are being received by the antenna.
It is another object of my invention to provide new and improved devices for isolating undesired parts from a desired transmission path for low level signals substantially without attenuation.
It is a further object of my invention to provide new and improved coupling devices for ultra high frequency apparatus having an impedance characteristic responsive to the energy of the signals incident thereon.
It is a still further object of my invention to provide a new and improved coupling device for ultra high frequency systems which is operative over a broad frequency range.
Briefly stated, in accordance with a general aspect of my invention, I provide new and improved apparatus and methods for coupling elements or parts of high frequency systems, such as systems designed for the utilization of ultra high frequency electromagnetic waves or microwaves. An anti-resonant element, which isconnected across a wave guide used for transmitting ultra high frequency waves, breaks down under relatively high energy waves transmitted from the system, but is not broken down for received waves of considerably lower energy level. The element is so constructed that it effectively shortcircuits the wave guide and it is so located with respect to the circuits of the receiving equipment that it assures efiicient transmission of all incoming power into these receiving circuits.
The anti-resonant element employs a gas-filled section of dielectric wave guide connected to a principal wave guide system through a resonant slot sealed by a glazed window, the slot breaking down in the presence of Waves of high energy level.
In another aspect, the invention includes the use of additional anti-resonant elements serially connected between the generating equipment of the system and the ultra high frequency circuits of the receiving equipment to insert a resistance in series with the circuits of the generating equipment to prevent dissipation of the energy of received signals.
In still another aspect of this system, the serially connected element may comprise a breakdown element which eiiectively short-circuits the anti-resonant element in the presence of high energy signals and provides high reflection of low level signals.
For a better understanding of my invention, reference may be had to the following description taken in connection with the accompanying drawing and its scope will be pointed out in the appended claims. Fig. 1 illustrates an ultra high frequency system embodying the coupling device of my invention; Fig. 2 is an enlarged sectional view of the coupling device employed in the system of Fig. 1; Fig. 3 diagrammatically illustrates a modification of the invention as embodied in an ultra high frequency signalling system; Figs. 4 and 5 illustrate alternative forms of resistance elements which may be employed in the system of Fig. 3; Fig. 6 illustrates a broad band coupling device particularly adapted for high frequency signalling systems operating at low power levels; and Figs. '7 and 8 illustrate different forms of breakdown elements which may be employed in the system of Fig. 6.
Referring now to the accompanying drawing, Fig. 1 illustrates an ultra high frequency system which may be used, for example, for radio detection and direction purposes. In this figure, the transmitter l, which includes an ultra high frequency generator 2 which may be for example a magnetron, is connected to a dielectric Wave guide 3 which is terminated at its other end in a flared horn or radiative element l. A receiver 5 is likewise connected to wave guide 3 through a coupling unit which comprises a plurality of transverse metallic walls 68 connected across a branch wave guide 9. The transverse walls 6-8 are provided with resonant or tuned. apertures H], such as slots which may be of rectanguopposite end of the branch wave guide 9 is like-' wise closed by a transverse wall 53 having a resonant or tuned aperture therein sealed by a glass window it. guide t is filled with gas and the resonant slot structures Ill of transverse walls 6 and'l may,
employ electrodes ill for maintaining a discharge across the associated slots Ill. The discharge.
Across The region within the wave maintained across the slots it! by the electrodes. 5
is sufiiciently small that it does not interfere with the transmission of low level signals through the slots. Because of its presence, however, the slot breaks down more readily when high level signals reach the slot. Each of the electrodes it lies in a plane parallel with the slot lil and its associated wall and is spaced from the slot by a distance great enough that the tuning of the slot is not disturbed. The inner edges of the electrodes l5 are bent inwardly toward the slot to-localize the discharge in the center of the slots ill. Certain features of the system shown in Fig. l aredisclosed and claimed in my copending application, Serial No. 538,483, filed June 2, 1944, and assigned tothe assignee of the present invention; while the construction and operation of the glass window 52 is disclosed and'clairned in my copending application, Serial No. 519,267, filed January 22, 19.44.
The rectangular guides 3 and 9 may comprise metallic enclosing walls constructed of a conductive material, such as copper or brass. The depth and height of the guide, the dielectric constant of the medium within the guide, and the wave pattern determine principally the critical or cut-oi? frequency of the guide. The dielectric medium through which the electromagnetic. energy istransmitted may be considered as being. air or gas. Of course, the waves may also besatisfactorily transmitted through an evacuated space. The gaseous medium within the se'aled'guide 9 maybe, for example, hydrogen under a pressure of about ten millimeters. The transverse walls H and [3.preferably are formed of an iron-nickel-cobalt alloy sealed to the walls of. theguide 9 and the windows l2, is sealed across the resonant apertures in these transverse walls preferably are formed of a boro silicate glass.
In the operation of the portion of the ultra high frequency signalling system of Fig. 1 thus far described, the transmitter I propagates a high intensity electromagnetic wave along the wave guide 3. to be radiated by antenna 4. Lower intensity signals, received from space after reflection from an object upon which the signals impinge, are transmitted by the radiating element or horn 4 to the receiver ii over the wave guides 3 and-9. The slots l6 affect a concentration of the 'field intensity or potential incident to the electromagnetic field across the horizontal edges of the slot. The'slots it of the transverse walls 6-81 and the slots of the transverse walls I l and I,3Iare tuned to the frequency of the electromagneticwaves propagated along the wave guide so that they cause. little reflection of the electromagnetic waves transmitted along the guide. Because of the resonant character of the slots in the transverse walls 6B, H and I3, the low intensity signalssuch as those received by the 2,408,055 i I ,l .f
antenna 4 provide substantially reflectionless transmission over a relatively broad band of frequencies. During periods when high intensity signals are being transmitted from the transmitter I, a unidirectional potential from any suitable source (not shown) and connected between electrodes l5 and the walls 6, "l maintains a discharge across the resonant gaps in transverse walls 6 and 'l to cause the gaps to break down more readily. At the same time, the resonant gaps in walls II and 8 break down because the magnitude of the high intensity waves is sufficient to cause ionization of the gas on the interior surface ofthe window 12 and across the gap is in transverse wall 8. An electric discharge, therefore, takes place across all of the resonant slots. which prevents transmission of high intensity signals to the sensitive apparatus of the receiver 5.
It has been observed that, in a system of the type illustrated in Fig, 1, a considerable portion of the signals received by antenna 4 and trans-' lated to the receiver 5 is dissipated. in the. high Q circuits of the magnetron 2 used in the transmitter I. In order to prevent such dissipation of relatively low intensity incoming signals, an.
anti-resonant element It, that is, an'element which hinders dissipation of the incoming energy in the high Q circuits of the transmitter, is connected across the wave guide 3 between the-point of connection of branch guide 9 and transmitter l at a point spaced fromwave guide 9 by a distance d equal to a quarter wave length at the mid-band frequency of the system. The construction of the element I6, which is shown in mid frequency of the band of frequencies of oper- /ation of the signalling system, connected to wave guide 3. The wave guide I7 is short-circuited at its end remote from Wave guide 3 by a transverse metallic wall !8. and is sealed at its'p-oint of connection to waveguide 3 by means of a transverse metallic wall 19 having a resonant slottherein across which is sealeda glass window 253.. The transverse metallic wall It is constituted preferably of an iron-nickel-cobalt alloy and is provided with a recessed shoulder 2! across which is hermetically sealed the window 20 formed of boro silicate glass. A glaze or thin layer of glass 22, connected to the glass window 20 and extending over a portion of the metal wall 19 adjacent the resonant slot therein, is provided to reduce or eliminate sputtering onto the glass, Eliproduced by an electrodeless discharge which occurs across the window 20 on its side of lower pressure. The wave guide section ll is closed, exhaunted, and filled with gas to the proper pressure through a tubulation 23. The wall It and the glass window 23 are made sufhcicntly thin that they have very small phase extension along the guide and, hence, can be made reflectionless and of very low Q, the Q being determined by the.
the upper and lower edges of this opening is;
affected by the resonant character of the slot and the magnitude of this voltage difference increases as the magnitude of the electromagnetic waves passing along the wave guide 3 increases. The dielectric window 20 breaks down when the magnitude of these waves reaches a predeteraeoaoss mined value, the voltage difference being suincient to cause ionization of the gas on the interior surface of the window 20, and an electric discharge takes place across this window. As a result, when high intensity waves from the trans mitter I are being transmited over the wave guide 3, very small reflection of the electromagnetic waves is caused by theelement it. However, when low intensity waves are being transmitted over the wave guide 3, such as incoming signals, there is no discharge across the resonant slot and the short-circuit across the wave guide 1! constituted by the transverse wall l8, since it is cateda half wave length away from the point of connection of wave guidefi across wave guide 3, appears as an electricalshort circuit across the wave guide 3 at this point anddirects substantially all of the incoming power into the receiver 5 over the wave guide 9. It has been found that, at the mid band frequency of the system, the frequency to which the slot in wall [9 is tuned, substantially less than 10 per cent of incident power is transmitted past the element I6 when the ,energy of the electromagnetic waves in the guide 3 is insufficient to cause a breakdown in the resonant slot {6. Moreover, over a frequency interval of from five to ten per cent of the desired frequency, the energy transmitted past the element ii in wave guide 3 remains less than thirty per cent of the total energy. It has been found that the decoupling element 46 itself causes virtually no dissipation of energy at the lower level of incoming signals, the dissipation in the element [6 being less than one-tenth of one per cent of the total received energy.
In the modification of the invention illustrated in Fig. 3, there is shown an ultra high frequency circuit which employs a second anti-resonant element or decoupling device 24 connected across the wave guide 3 between the first anti-resonant element l6 and the transmitter I and spaced from the element [6 by a distance equal to a quarter wave length at the mid band frequency of the system. It has been noted that, if the spacing between the element I6 and the highly reactive magnetron circuit of the transmitter l bears a certain relationship with the frequency of the wave transmitted over the wave guide 3, a resonance is built up between these units such that a large portion of incoming signals received by antenna 4 is lost because of the resonant circuit thus established and is not transmitted to receiver 5 but may be reradiated by antenna 4 and absorbed in the circuit element. This loss is of very mall value for frequencies near that to which the resonant gap in the element It is tuned, but may be of considerable value at frequencies removed from the mid band frequency of the system. The addition of the second antiresonant element 24 separated from the element l6 by a distance equal to a multiple of a quarter wave length at the mid band frequency not only substantially doubles the band width obtainable with asingle anti-resonant element, but reduces the possibility of great loss of low level signals at frequencies near the edges of the pass band, especially if the element 24 is made to be moderately dissipative to low level signals. With such addition, the magnetron 2 of the transmitter I,
no matter how reactive its circuits may be, always has connected in series with it a resistance which precludes the building up of resonance of significant value.
Two arrangements which may be used for presenting apredetermined resistance to low level signals, but which have substantiallylittle effect upon high level transmitter power, are shown in Figs. 4 and 5. In the arrangement of Fig. 4, the window 20 across the resonant gap in the transverse metallic wall I9 is covered with a dissipative element in theform of a resistance paint 25 which may be, for example, a graphite-impregnated silicone varnish .or a tin oxide deposit. This paint is placed on the outside of the window 20, i. e., on the side facing the wave guide 3, away from the electric discharge which occurs across the inner surface of the window when high intensity waves in the wave guide 3 cause a breakdown of the resonant gap in the transverse Wall l9. In the alternative anti-resonant element 26 illustrated in Fig. 5, the resistive paint 25 is applied to the surface of a transverse wall 21, which may comprise a pane of glass and which is spaced from the short-circuited end wall 23 of the wave guide section by a distance equal to a quarter wave length at the mid band frequency. While the spacing of the glass plate 21 from the transverse wall [9 preferably is of the order of one-half wave length, it has been found that this spacing is not critical. If the resistance of element 25 is made equal to the characteristic resistance of the guide section, the spacing of wall 21 with respect to wall 19 may have any value. For higher resistance values of element 25, the spacing ofwall 21 with respect to wall I9 approaches a half wave length. Wall 28 is spaced from wall 21 by a distance equal to a quarter wave length, regardless of the resistance of element 25. Hence, for high resistance values of the element 25,'wall 28 is spaced from wall l9 by approximately threequarters of a wave length.
The arrangement illustrated in Fig. 5 has the advantage that its frequency sensitivity is very low and it affords the desired protection against resonance conditions over the entire band of operation of the high frequency system. For the arrangement shown in Fig. 3, when using either of the dissipative arrangements illustrated in Figs. 4 and 5, a gain in band width over the arrangement of Fig. 1 of approximately fifty per cent is obtained. At the same time, since the dissipative paint element 25 is of much higher resistance than the discharge across the window 20 in the tuned aperture, the operation of the system for transmission of high energy waves from the transmitter l to the antenna 4 is unaffected by the addition of the'dissipative paint element.
In the modification of the invention illustrated in Fig. 6, there is shown a coupling device particularly adapted for high frequency signals operating at low power levels. At such low power levels, of the order of a few hundred watts peak, the energy of the high frequency waves propagated along the wave guide 3 from the transmitter connected therewith is insufficient to cause breakdown of window 20 across the resonant gap of transversemetallic wall l9. In such installa-- the mid band frequency and from the end wall 3| by a distance equal to a quarter wave length at the mid band frequency, has therein a cen-" trally positioned resonant gap I 321 constructed 1 to break down. and initiate an. electric discharge thereacross at any power leveldesired. When suchan electric discharge. occurs,.it functionsas a;short-circuit acrossthe wave guider33,.which short-circuit is reproduced atthe-window 20 and the power'in the main guideBxpassesthe coupling device without reflection. Thedecoupling device constituted by the stub waveguide- 30. is. sealed by the transparent window ZU-"and filled witha desired. gaseous medium .inthe manner pointed out; in connection with the description of the structure of Fig. 2. The decoupling device of Fig. 6 is connected acrossthewave. guide 3 ata point spaced a quarter wave length from thepoint of connection ofthe receiver circuit therewith and is located between the point. of connection of. the receiver circuit and a source of ultra high frequency waves in the samemanner as. is shown in :the systems of Figs. 1 and 2. In the presence ofsignals of an energy level lower than that at which breakdownof the resonant gap. 32 occurs, thershort-circuit.constituted by the end wall 3| andiwhichislocated an integral number of half wave lengths'away from the point of connection of the receiver to the wave guide 3 is reproduced atithis; point of connection to provide required high reflection of signals of low energy level and assure their transmission. to the receiver circuits.
Twoforms of the resonant gap structure which may. be employed in. the coupling device of'Fig. 6 are illustrated in Figs. 7 and 8. In Fig. 7, the metallic member 29 which. is placed across a wave guide as a transverse wall contains two symmetrically: placed circular apertures 33, 34. The metallic wall 29 forms a pair of opposed points 35, 36 which define the gap 32 connecting the openings;33, 34. The dimensions of the gap 32 are correlated with the total area of the wall 29 .to form an aperture which is resonant at the mid bandfrequency of the electromagnetic waves propagated along the wave guide 3. In operation, the points 35, 36 form a gap which, when sealed in a gaseous medium as described previously, functions as means for effecting a conversion of the potential of the electromagnetic wave propagated therethrough and breaks down upon the incidence of electromagneticwaves of the relatively low energy level to produce current flow across the resonant aperture and. the metallic wal129.
In the modification of the, transversewall 29 shown inFig. 8, the openings 31, 38 are rectangular in form and a central portion of the wall 29- forms .a pair of opposed points 39,.40 which define the gap 32 connecting, the openings 31, 38. In other respectsthe structure of. Fig. 8 operates similar to that explainedin connection. with the description of Fig. 7.
From the foregoing, it is seen that my invention provides a. new and improvedapparatus and method for coupling elements or parts of high: frequency systems in Which transmission of low level signals to receiver circuits .of the system is assured by decoupling high reactance circuits of the transmitting equipment connected therewith d uring periods when such low level signals are being received. Furthermore, during transmitting periods, not only is the effect of the decoupling means employed removed from the system, but adequate protectionfor the receiver circuits is provided to prevent injury thereto.
While I have shown particular embodiments of my, invention, it will of coursebe understood that I'donot wish to be limited thereto since various;
modifications may bemadaand-I contemplatelby the appended claims to cover any such modifications. as fall. within the. true spiritandscopemf my invention.
'WhatI claim as... new and desirellto. secure by Letters Patent of the United States, is:
1. In combination with a principalholldw-pipe type wave guide for transmitting electromagnetic wavesdielectrically, means for transmitting high intensity waves over said guide andfor refiecting low intensity waves comprising astub section'of wave guide connected to said principal I. guide through an aperture tuned to the frequency' of said waves, said stub section having alength equal approximately to an odd multiple of i a quarter wavelength atsaid frequency, and said stubsection being short circuited-at itsendre motefrom said aperture.
2. In combination with aprincipal hollow-'pi-pe type wave guide for transmitting electromagnetic Waves dielectrically, means for transmitting high intensity waves over said guide and for reflecting low intensity waves comprising, a stub section of wave guide connected to said principal guide through an aperture tuned to the frequency of said waves, said stub section having a length equal approximately to an odd multiple of a quarter wave length at said frequency and being short circuited at its end remote from said aperture, and dielectric means sealed acrosssaid aperture,-said section being gas-filled to facilitate establishment of an electric discharge across'said aperture in the presence of said high intensity waves.
3. In combination, afirst hollow pipe type wave guide for transmitting electromagnetic waves'di electrically, a transmitter connected .to said wave guide, a receiver connected to said wave guide through a branch transmission path, and means to decouple said transmitter from said guide to prevent dissipation therein-of low intensity signals. for said receiver comprising, a stub wave guide connected to saidfirst guide at-a point be tween sa-id transmitter and said path and spaced fromsaidpath by a distance equal .toa quarter wave lengthof. saidwave, saidastub guidev being connected to: said first guide through. an aperture tunedto' the frequency; of saidwavessaid stub guide being short circuited a-t'itsendremote from said: aperture and having a length equal approxi- 50 mately .t'da. quarter wavelength at said frequency.
4; .In combination a first hollow pipe type-wave guide: fortransmitting electromagnetic waves di electrically, a transmitter connected to said "wave guide: areceivenconnected'to said wave guide through a branch' transmission path, and means to decouple saidtransmitterfrom said guide to prevent dissipation therein-of lowintensity sig'- nals. for1-sald receivercomprising, a stub wave guide connectedtosaid first" guide at a point between. said transmitter and said path and spaced fronrsaid path-shy a distance equal to a quarter wave length of said waves, said stub guide being connectedttoasaid first guide through an aperture tunedntdthe frequency of said waves and being shortcircuit'ed at its end remote from said aperture and. having a length approximately equal to a quarter wavelength at said frequency, and dielectric'means. sealed-across said aperture, said sectionbeinggasefilledto facilitate establishment of; an. electric. discharge across: said aperture in the: presence of. said high intensity waves.
5; In a system for transmitting and receiving.
ultra high frequency electromagnetic waves com-- prising a transmitter and a receiver connected by 75 a; common wave guide system of the hollo wpip e type, apair of stub wave guides connected across said common guide between the points of connectionof said transmitter and receiver therewith, each of said stub guides being connected to said common guide through an aperture tuned to the frequency of said waves and being short circuited at a point spaced from said common guide by a distance approximately equal to a quarter wave length at said frequency, one of said stub guides being connected to said common guide at a point spaced from the point of connection of said receiver therewith by a distance equal to a quarter wave length at said frequency, the other of said stub guides being connected to said common guide between the points of connection of said one guide and said transmitter therewith, said other stub guide including a resistance element.
' 6. In a system for transmitting and receiving ultra high frequency electromagnetic waves comprising a transmitter and a receiver connected by a common wave guide system of the hollow pipe type, a pair of stub wave guides connected across said common guide between the points of connection of said transmitter and receiver therewith, each of said stub guides being connected to said common guide through an aperture tuned to the frequency of said waves and being short circuited at a point spaced from said common guide by a distance approximately equal Ito a quarter wave length at said frequency, dielectric means sealed across said apertures, said stub guides being gas-filled to facilitate establishment of an electric discharge across the apertures thereof in the presence of high intensity waves in said common guide.
'7. A coupling device for selectively controlling the transmission of electromagnetic waves over a first wave guide of the hollow pipe type in accordance with the energy of said waves comprising, a stub wave guide connected across said first guide and having a length approximately equal to a quarter wave length at the frequency of said waves, said stub guide being short-circuited at its end remote from said first guide, and a. transverse metallic wall connected across said stub guide at its point of connection with said first guide having an aperture therein tuned to the frequency of said wave.
8. A coupling device for selectively controlling the transmission of electromagnetic waves over a first wave guide of the hollow pipe type in accordance with the energy of said waves comprising, a stub wave guide connected across said first guide and having a length approximately equal to a, quarter wave length at the frequency of said waves, said stub guide being short-circuited at its end remote from said first guide, a transverse metallic wall connected across said stub guide at its point of connection with said first guide having an aperture therein tuned to the frequency of said wave, and dielectric means sealed across said aperture, said stub guide being gas-filled to establish an electric discharge across said aperture in the presence of high energy waves in said first guide.
9. A coupling device for selectively controlling the transmission of electromagnetic waves over a first wave guide of the hollow pipe type in accordance with the energy of said waves comprising, a stub wave guide connected across said first guide and having a length approximately equal to a quarter wave length at the frequency of said waves, said stub guide being short-circuited at its end remote from said first guide, a transverse metallic wall connected across said stub guide prising a transmitter and a receiver connected by a common wave guide system of the hollow pipe type, a pair of stub wave guides connected across said common guide between the points of connection of said transmitter and receiver therewith, each of said stub guides being connected to said common guide through an aperture tuned to the frequency of said waves and being short-circuited at a point spaced from said common guide by a distance approximately equal to a multiple of said quarter wave length at said frequency, one of said stub guides being connected to said common guide at a point spaced from the point of connection of said receiver therewith by a distance equal to a quarter wave length at said frequency, the other of said stub guides being connected to said common guide between the points of connection of said one guide and said transmitter therewith, said other stub guide having a transverse wall therein, and a dissipative element supported on said transverse wall to prevent establishment of resonance in said transmitter and said common wave guide in the presence of low energy Waves in said common guide.
11. In combination with a first wave guide of the hollow pipe type for transmitting electromagnetic waves dielectrically, means for permitting transmission of waves above a predetermined energy level through said guide and resisting transmission of waves below said energy level thereth'rough comprising, a stub wave guide connected across said first wave guide and having a length approximately equal to an odd multiple of the quarter wave length at the frequency of said waves, said stub wave guide being shortcircuited at its end remote from said main guide and having a transverse metallic wall connected thereacross at its point of connection with said first guide, said metallic wall having an aperture therein tuned to the frequency of said waves, a dielectric window sealed across said aperture, and a resistance element attached to said window on its side facing said first guide.
12. In combination with a first wave guide of the hollow pipe type for transmitting electromagnetic waves dielectrically, means for permitting transmission of waves above a predetermined energy level through said guide and resisting transmission of waves below said energy level therethrough comprising, a stub wave guide connected across said first wave guid and having a length approximately equal to an odd multiple of the quarter wave length at the frequency of said waves, said stub wave guide being short-circuited at its end remote from said main guide and having a transverse metallic wall connected thereacross at its point of connection with said first guide, said metallic wall having an aperture therein tuned to the frequency of said waves, a dielectric window sealed across said aperture, and a resistance element attached to said window on its side facing said first guide, said. stub guide being gas-filled to facilitate establishment of an electric discharge across said aperture in the presence of high intensity waves in aid first uide.
13. In combination with a first wave guide of the hollow pipe type vfor transmitting electromagnetic waves dielectrically, means for permitting transmission of waves above a predetermined energy level through said guide and resisting transmission of waves below said energy level therethrough comprising, a tub wave guide connected across said first wave guide and having a length approximately equal'to an odd multiple of the quarter wave length at the frequency of said Waves, said stub wave guide being shortcircuitedat its e d remote from said main guide and ,havinga transverse metallic wall connected therea ross ataits point of connection with-said firstsuidasaidmetallic wall having an aperturc thereintuned to. the irequency of aid waves, 'dielectric, window sealed across aid apert r a secondtrausverse wallconnected across said stub uide at a point spaced he w ensaidends, and a. resistance element s pported on said lastmentioned transversewall.
l4. Ilrcolnbinationzwith a first wave guide of the hollow pipe typ fortransmitting electromagnetic waves dielectrically, :means for permitting transmission of waves above a predetermined energy level through said guide and resisting transmission of waves .below said energy level thereth'rough comprising, a' tub wave guide connected acros said first wave guide and having a length approximately equal to an odd multiple of the quarter wave length at the frequency of said waves, said stub wave guide: being'shortcircuited at its end remote from saidrmain= guide and having a transverse metallic wall connected thereacross'at its point of connectionwithsaid first. guide, said metallic wall havinganaperture therein tuned to the frequency. of c said Waves,a-a dielectric window :sealed acros said aperture, and a second transverse. metallic-wall connected across said stub guide, said second transverse wall having airesonantcaperture therein tuned. to
said frequency.
US545314A 1944-07-17 1944-07-17 Ultra high frequency coupling device and system Expired - Lifetime US2408055A (en)

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Cited By (27)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2491971A (en) * 1945-07-13 1949-12-20 Raytheon Mfg Co Switch tube device for wave guides
US2501052A (en) * 1945-09-14 1950-03-21 Us Sec War High-frequency transmission system
US2523841A (en) * 1946-06-21 1950-09-26 Bell Telephone Labor Inc Wave guide coupler
US2524268A (en) * 1946-01-11 1950-10-03 Sylvania Electric Prod Ultra high frequency resonator
US2540148A (en) * 1945-03-22 1951-02-06 Sperry Corp Ultra high frequency powerselective protective device
US2541375A (en) * 1948-06-04 1951-02-13 Bell Telephone Labor Inc Wave filter
US2548816A (en) * 1945-09-19 1951-04-10 William M Preston Frequency stabilization of magnetrons
US2603744A (en) * 1945-09-14 1952-07-15 Roland W Larson Tuning mechanism
US2623207A (en) * 1945-02-07 1952-12-23 Csf Radio obstacle detector
US2627020A (en) * 1949-05-28 1953-01-27 William S Parnell Two-feed "x" band antenna
US2627573A (en) * 1948-04-28 1953-02-03 Raytheon Mfg Co Wave guide duplexer
US2632854A (en) * 1947-12-18 1953-03-24 Westinghouse Electric Corp Resonant cavity drive
US2644926A (en) * 1948-01-09 1953-07-07 Arthur A Varela Electronic switch for highfrequency power
US2646550A (en) * 1948-01-09 1953-07-21 Arthur A Varela Controlled impedance gas discharge device for mechanical transmission mediums
US2681987A (en) * 1946-06-05 1954-06-22 Us Navy Transmission system for radio echo detection systems
US2683212A (en) * 1945-12-27 1954-07-06 Us Navy Radar-beacon mixer
US2688120A (en) * 1945-07-09 1954-08-31 Us Sec War Antitransmit-receive switch
US2691761A (en) * 1948-02-03 1954-10-12 Jr Nicholas M Smith Microwave measuring of projectile speed
US2735092A (en) * 1955-04-04 1956-02-14 Guide space
DE1002474B (en) * 1953-01-22 1957-02-14 Ferranti Ltd Gas discharge tubes with a waveguide section
US2816271A (en) * 1950-11-22 1957-12-10 Gen Electric Microwave mode converter
US3076157A (en) * 1959-06-29 1963-01-29 Gen Electric High powered duplexing arrangement
US3337819A (en) * 1965-04-23 1967-08-22 Stafford D Schreyer Transmit-receive switch wherein branch line gas cell has resonant iris at its low power port, whereby iris is protected from peak power
US4613989A (en) * 1984-09-28 1986-09-23 Cincinnati Microwave, Inc. Police radar warning receiver
US4686499A (en) * 1984-09-28 1987-08-11 Cincinnati Microwave, Inc. Police radar warning receiver with cantilevered PC board structure
US6259207B1 (en) * 1998-07-27 2001-07-10 Litton Systems, Inc. Waveguide series resonant cavity for enhancing efficiency and bandwidth in a klystron
US20100066594A1 (en) * 2008-09-15 2010-03-18 Klaus Kienzle Modular design for a fill-level-radar antenna system

Cited By (29)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2623207A (en) * 1945-02-07 1952-12-23 Csf Radio obstacle detector
US2540148A (en) * 1945-03-22 1951-02-06 Sperry Corp Ultra high frequency powerselective protective device
US2688120A (en) * 1945-07-09 1954-08-31 Us Sec War Antitransmit-receive switch
US2491971A (en) * 1945-07-13 1949-12-20 Raytheon Mfg Co Switch tube device for wave guides
US2501052A (en) * 1945-09-14 1950-03-21 Us Sec War High-frequency transmission system
US2603744A (en) * 1945-09-14 1952-07-15 Roland W Larson Tuning mechanism
US2548816A (en) * 1945-09-19 1951-04-10 William M Preston Frequency stabilization of magnetrons
US2683212A (en) * 1945-12-27 1954-07-06 Us Navy Radar-beacon mixer
US2524268A (en) * 1946-01-11 1950-10-03 Sylvania Electric Prod Ultra high frequency resonator
US2681987A (en) * 1946-06-05 1954-06-22 Us Navy Transmission system for radio echo detection systems
US2523841A (en) * 1946-06-21 1950-09-26 Bell Telephone Labor Inc Wave guide coupler
US2632854A (en) * 1947-12-18 1953-03-24 Westinghouse Electric Corp Resonant cavity drive
US2644926A (en) * 1948-01-09 1953-07-07 Arthur A Varela Electronic switch for highfrequency power
US2646550A (en) * 1948-01-09 1953-07-21 Arthur A Varela Controlled impedance gas discharge device for mechanical transmission mediums
US2691761A (en) * 1948-02-03 1954-10-12 Jr Nicholas M Smith Microwave measuring of projectile speed
US2627573A (en) * 1948-04-28 1953-02-03 Raytheon Mfg Co Wave guide duplexer
US2541375A (en) * 1948-06-04 1951-02-13 Bell Telephone Labor Inc Wave filter
US2627020A (en) * 1949-05-28 1953-01-27 William S Parnell Two-feed "x" band antenna
US2816271A (en) * 1950-11-22 1957-12-10 Gen Electric Microwave mode converter
DE1002474B (en) * 1953-01-22 1957-02-14 Ferranti Ltd Gas discharge tubes with a waveguide section
US2735092A (en) * 1955-04-04 1956-02-14 Guide space
US3076157A (en) * 1959-06-29 1963-01-29 Gen Electric High powered duplexing arrangement
US3337819A (en) * 1965-04-23 1967-08-22 Stafford D Schreyer Transmit-receive switch wherein branch line gas cell has resonant iris at its low power port, whereby iris is protected from peak power
US4613989A (en) * 1984-09-28 1986-09-23 Cincinnati Microwave, Inc. Police radar warning receiver
US4686499A (en) * 1984-09-28 1987-08-11 Cincinnati Microwave, Inc. Police radar warning receiver with cantilevered PC board structure
US6259207B1 (en) * 1998-07-27 2001-07-10 Litton Systems, Inc. Waveguide series resonant cavity for enhancing efficiency and bandwidth in a klystron
US20100066594A1 (en) * 2008-09-15 2010-03-18 Klaus Kienzle Modular design for a fill-level-radar antenna system
US7940207B1 (en) * 2008-09-15 2011-05-10 Vega Grieshaber Kg Modular design for a fill-level-radar antenna system
US20110109499A9 (en) * 2008-09-15 2011-05-12 Klaus Kienzle Modular design for a fill-level-radar antenna system

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GB597662A (en) 1948-01-30

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