US3054017A - Electron discharge devices - Google Patents

Electron discharge devices Download PDF

Info

Publication number
US3054017A
US3054017A US657367A US65736757A US3054017A US 3054017 A US3054017 A US 3054017A US 657367 A US657367 A US 657367A US 65736757 A US65736757 A US 65736757A US 3054017 A US3054017 A US 3054017A
Authority
US
United States
Prior art keywords
wave
conductors
members
helical
electron
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US657367A
Other languages
English (en)
Inventor
John L Putz
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
General Electric Co
Original Assignee
General Electric Co
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by General Electric Co filed Critical General Electric Co
Priority to US657367A priority Critical patent/US3054017A/en
Priority to GB13203/58A priority patent/GB841791A/en
Priority to FR1209100D priority patent/FR1209100A/fr
Priority to DEG24470A priority patent/DE1282797B/de
Application granted granted Critical
Publication of US3054017A publication Critical patent/US3054017A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J23/00Details of transit-time tubes of the types covered by group H01J25/00
    • H01J23/16Circuit elements, having distributed capacitance and inductance, structurally associated with the tube and interacting with the discharge
    • H01J23/24Slow-wave structures, e.g. delay systems
    • H01J23/26Helical slow-wave structures; Adjustment therefor
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J23/00Details of transit-time tubes of the types covered by group H01J25/00
    • H01J23/16Circuit elements, having distributed capacitance and inductance, structurally associated with the tube and interacting with the discharge
    • H01J23/24Slow-wave structures, e.g. delay systems
    • H01J23/26Helical slow-wave structures; Adjustment therefor
    • H01J23/27Helix-derived slow-wave structures

Definitions

  • FIG.6 is a diagrammatic representation of FIG.6.
  • This invention relates generally to electron discharge devices, and more particularly to improvements in electron discharge devices of the kind involving interaction of an electron beam with an electromagnetic wave propagated on a waveguide structure disposed adjacent to the path of the electron beam.
  • traveling-wave tubes Such devices are generally referred to in the art as traveling-wave tubes.
  • One type of traveling-wave tube comprises a waveguiding conductor of generally helical configuraion several wavelengths long measured along the axis thereof at the frequency of operation of the tube.
  • the helical conductor is proportioned and arranged to produce an electric field directed along the axis of helical conductor and moving at a velocity substantially less than the velocity of the wave along the conductor itself and within the range of practically obtainable electron beam velocities when an electromagnetic wave is applied to one end of the conductive structure.
  • Such waveguiding structures which have the effect of producing a component of electric field of an electromagnetic wave which moves at a lower velocity than the wave itself on the structure are commonly referred to as slow-wave structures.
  • a variety of conductive structures have such properties and are suitable for use in traveling-wave devices.
  • the tube When the tube is energized to produce an electron beam therein and an electromagnetic wave is applied to the beam entrance end of the helical conductor, the wave travels along the helical conductor producing an axially-directed component of electric field traveling at a velocity less than the velocity of the wave along the helical conductor.
  • the average velocity of the electron cam is arranged with respect to the velocity of the axially-directed component of electric field of the applied wave to effect a conversion of energy associated with the electron beam into electromagnetic wave energy. Accordingly, as the applied electromagnetic wave moves along the helical conductor, it is augmented in amplitude. The wave augmented in amplitude is removed at the beam exit end of the helical conductor.
  • traveling-wave devices of the kind described above are useful as amplifiers, oscillators and the like at radio frequencies and are capable of delivering appreciable amounts of power at these frequencies.
  • the power output of a traveling-wave tube depends on the conversion of beam power into radio frequency power
  • to obtain higher power outputs from traveling-wave tubes of the kind having a single slow-wave structure it is necessary to increase either the current of the electron beam, the voltage applied between the ends of the electron beam, or increase both, that is, it is necessary to suply more power to the electron beam which can then be converted into radio frequency power.
  • juxtaposition of two slowwave structures electrically connected only at the input and output thereof permits modes of propagation of electromagnetic waves on the structures other than the desired mode, particularly when the structures are not appreciably separated or shielded from one another.
  • an object of the present invention to provide electron beam-eletromagnetic wave interaction type tubes capable of developing high power output.
  • Helical conductors are commonly used in tubes of the kind described above.
  • One of the problems generally encountered in constructing helical conductors for use at high frequencies and for high power outputs is that of providing helical conductors with sufficiently small helix diameters yet mechanically strong and electrically effective.
  • Another object of the present invention to provide simple, yet mechanically rugged and electrically effective, slow-wave structures of helical configuration for traveling-Wave tubes for high frequency operation.
  • each of a plurality of electron beams interacts with respective ones of a plurality of moving electromagnetic waves, each of said waves being associated with a respective waveguiding structure of the slow wave type to effect a conversion of beam energy into electromagnetic energy
  • each one of said slow-wave structures to be conductively connected to at least one other of said slow-wave structures at points spaced along said structures.
  • the points of connection of the conductors are arranged to be at substantially electrically equivalent intervals from the input ends of said conductors.
  • the intervals between successive points of connection are arranged to be sufficiently small to maintain the axial components of the traveling electromagnetic waves associated with said conductors in phase during their propagation from the input end of the conductors to the output ends thereof.
  • FIGURE 1 shows a cross-sectional view of a traveling wave tube embodying the present invention and shows the tube connected in an operative circuit;
  • FIGURE 2 shows an enlarged cross-sectional view of the tube of FIGURE 1 taken along section 22 of FIG- URE l;
  • FIGURES 3 and 4 show end views of slow-wave structures embodying the present invention and consisting of four helical conductors;
  • FIGURES 5 and 6 show side and end views, respectively, of a slow-wave structure embodying the present invention and consisting of two helical conductors spaced apart;
  • FIGURE 7 shows an end view of a composite slowwave structure embodying the present invention and consisting of five helical conductors
  • FIGURE 8 shows an isometric view partly broken away of a composite slow-Wave structure embodying the present invention and consisting of a pair of slotted contra-wound helix structures;
  • FIGURE 9 shows an isometric view partly broken away of a composite slow-wave structure consisting of four bi-filar, slotted contra-wound, helix conductors;
  • FIGURES l and 11 show plan and side views, respectively, of a composite slow-wave structure utilizing a plurality of linear conductors.
  • traveling wave tube 1 functioningas an amplifier.
  • Traveling wave tube 1 comprises an evacuated elongated dielectric envelope 2 mounted at one end of which are a pair of electron guns or sources 3 and 4 for producing beams of electrons in the evacuated space of the envelope, and mounted at the opposite end of which is a collector structure for intercepting the electrons ejected from the electron gun.
  • An elongated coil 7 of generally cylindrical configuration for developing a umdirectional magnetic field directed along the axis of the envelope for focusing the electron beams is located substantially concentric with respect to the envelope 2 and substantially surrounds the envelope 2 along its length.
  • the electron gun structure 3 comprises a cathode 8, a heater 9 therefor mounted in insulating relationship therewith, and an accelerating or beam-forming electrode 10 spaced and insulated from the cathode S.
  • Accelerating electrode 19 has an aperture therein in axial registration with cathode 8.
  • External connections are made to the cathode 8 by means of conductor 11, to the heater 9 by means of conductors 11 and 12, and to the accelerating electrode 10 by means of conductor 13.
  • the electron gun structure 4 comprises a cathode 14 and a heater 15 therefor mounted in insulating relationship therewith, and an accelerating or beam-forming electrode 16 spaced and insulated from the cathode 14.
  • Accelerating electrode 16 has an aperture therein in axial registration with cathode 14.
  • External connections are made to the cathode by means of conductor 17, to the heater 15' by means of conductors 17 and 18, and to the accelerating electrode 16 by means of conductor 19.
  • the collector structure 5 comprises a conductive plate mounted on conductor 2% by means of which suitable external connections may be made to the plate.
  • beams 24 and 25 are formed and extend into the clongated region of the envelope from the gun structure to the collector 5.
  • Electrode 27 having apertures in registration with beams 24 and 25 is provided adjacent gun structures 3 and 4 and serves both to shape the electron beams and to terminate or match the radio frequency field on the waveguiding structure 6 to an external circuit.
  • Electrode 28 having apertures in registration with electron beams 24 and 25 is provided adjacent to collector 5 and functions principally to match the output of the waveguiding structure 6 to an external circuit.
  • Waveguiding structure 6 comprises a pair of conductors 29 and 30 of helical configuration, each having the same helix diameter, pitch and axial length.
  • the considerations entering into the design and construction of the individual helical conductors are very similar to the considerations used for traveling-wave tubes employing a single helical conductor.
  • Each of the helical conductors has a helix diameter relatively small compared to the wave length of an applied electromagnetic wave or electrical signal in free space.
  • the diameter for maximum gain per unit axial length of structure and maximum efficiency is arranged so that the ratio of the helix diameter to free space wave length of the applied wave is about 0.4 times the ratio of velocity of an electromagnetic wave along the axis of the helix to its free space velocity or the velocity of light.
  • each of the helical conductors is arranged to provide a predetermined velocity of propagation for the applied electromagnetic wave through the structure substantially less than the free space velocity of the electromagnetic wave and in the range of conveniently obtainable electron beam velocities, i.e. from about live to fifty percent of the velocity of light, and is additionally arranged to optimize interaction of the electron beam with the axially-directed component of the electric field of the electromagnetic wave.
  • Each of the helical conductors is made of such a length as to produce the desired gain in the tube.
  • the increment of length over an optimum length becomes increasingly less effective in the conversion of beam energy into electromagnetic energy.
  • the length of the helical conductor is made too small, insufficient amplification is obtained.
  • practical difficulties arise with respect to maintaining an electron beam in association therewith in proper focus.
  • the axial length of helical conductors commonly used in traveling-wave tubes is usually many wavelengths long, in the range from about twenty to fifty wavelengths long.
  • the helical conductors are arranged so that their axes form the opposite sides of a rectangle, the other sides of each of which are equal to the diameter of the helix formed by each of said conductors. With such an arrangement, the helical conductors are in conductive contact along the entire length thereof at points one turn apart as measured along the helical conductors. Conductive engagement of the conductors may be assured by soldering or brazing the conductors at the points of contact.
  • the helical conductors 29 and 30 are mounted in the envelope so that helical conductor 29 is concentric with respect to beam 24 and helical conductor 30 is concentric with respect to beam 25.
  • Suitable elongated insulating members 31 may be used to hold or wedge the helical conductors in the envelope 2 in proper alignment with the electron beams as more clearly shown in FIGURE 2.
  • the ends of the helical conductors 29 and 30 are spaced from the input matching electrode 27 and output matching electrode 28, but sufliciently closely spaced thereto so that waves may be applied between the beam entrance end of the helix and the input matching electrode 27 and may be removed between the beam exit end of the helical conductors and output matching electrode 28.
  • External conductive connections are made to the input matching electrode, the input end of the helical conductors, the output end of the helical conductors and the output maching electrode by means of conductors 32, 33, 34 and 35, respectively.
  • the input electrodes 32 and 33 are connected to the outer and inner conductor of a transmission line 36, respectively, to the other end of which is connected a source 37 of high frequency waves to be amplified.
  • Outer conductor of transmission line 36 is grounded at 38.
  • a high frequency choke 39 is provided in the transmission line 36. This choke takes the form of a quarter-wave length transmission line having one end short-circuited and having the other end connected in shunt across the transmission line 36. Of course, other kinds of chokes having the desired frequency versus impedance characteristics may be used.
  • Output conductors 34 and are connected to the inner and outer conductor, respectively, of a transmission line 40, to the other end of which is connected a utilization device or load 41.
  • Power supply 43 provides unidirectionally operating potentials to various electrodes of the device.
  • Power supply 43 includes a grounded point 44, a point 45 positive with respect to the ground and points 46, 47, 48 and 49 of variable potential arranged in order of increasingly negative potential with respect to the ground point.
  • Cathode 8, cathode 14, accelerating electrode 10, and accelerating electrode 16 are connected respectively to points 49, 48, 47 and 46, respectively, over conductors 11, 17, 13 and 19, respectively.
  • Collector electrode 5 is connected over conductor 23 to point 45.
  • Source of power 50 having one terminal connected to conductor 11 and the other terminal thereof connected to conductor 12, supplies power for the heater 8.
  • Source 51 having one terminal connected to conductor 17 and the other terminal connected to conductor 18, supplies power to heater 15.
  • Source 52 having one terminal thereof connected to one terminal of the focus coil '7 and having the other terminal thereof connected to the other terminal of the coil through a variable focusing resistance 53, provides current to the coil for focusing the electron beams.
  • a high frequency signal from the source 37 is applied between the beam entrance end of the helical conductors 29 and 3t) and electrode 27 to initiate a wave on each of the helical conductors.
  • each of the helical conductors is arranged such that the application of signals thereto produces a Wave having a component of electric field which is directed along the axis of the helical conductor and which travels at a velocity substantially less than the free space velocity of the electromagnetic wave.
  • This velocity of the electromagnetic Wave along the axis of the helical slow-Wave structure is commonly referred to as the phase velocity of the wave on the structure.
  • each of the beams is adjusted to be slightly greater, i.e. about ten to fifteen percent, than the velocity of the aforementioned axially-directed component of electric field.
  • the electromagnetic wave on each of the helical conductors interacts with a respective electron beam and a net interchange of energy from the beam to the electromagnetic wave is effected.
  • each of the Waves travels on the respective helical conductor from the entrance to the exit end thereof, it is continuously augmented in amplitude. Waves of augmented amplitudes appear at the exit ends of the helical conductors and are applied over conductors 34 and 35 and transmission line 40 to the utilization circuit or load 41.
  • the helical conductors are conductively connected at points spaced at turn apart. As the intervals of coupling are increased, less satisfactory operation results. Also it has been found that with conductive coupling once every turn, a few poor connections randomly distributed on the structure are not detrimental to the operation of the tube.
  • FIGURE 2 shows a sectional view of the tube of FIG- URE 1 and in particular shows the positioning of the insulating rods 31.
  • the helical conductors of the device of FIGURES l and 2 are wound in the same sense, that is, as shown they are both right-hand helices. Of course, they both may be left-hand helices or one may be a right-hand helix and the other a left-hand helix.
  • a right-hand helical conductor is a conductor the direction of advance of which in an axial direction as one proceeds along the conductor is the same as the direction of advance of the thread of a righthand screw.
  • a left-hand helical conductor is a conductor the direction of advance of which in an axial direction as one proceeds along the conductor is the same as the direction of advance of the thread of a left-hand screw.
  • traveling-wave structures will support a number of traveling waves including a forward traveling wave and a reflected traveling wave.
  • traveling-wave tube devices When traveling-wave tube devices are suitably energized, both the forward traveling wave and the reflected traveling wave may appear on the structure.
  • the velocity of the electron beam in devices used as a forward traveling-wave amplifier is adjusted to be slightly greater than the axially-directed velocity of the applied wave and to effect an interchange of energy between the beam and the electromagnetic wave.
  • Attenuators are placed along the helical conductors to attenuate the reflected traveling waves;
  • the attenuator may take the form of conductive strips 54 distributed along the length of insulators 31, for example.
  • Aquadag an aqueous suspension of graphite commonly used in the electron tube art because of its good heat absorption properties, is suitable for this purpose.
  • backward waves may appear on the structure.
  • the term backward wave has been applied to any space-harmonic component of a propagated wave which has phase and group velocities in opposite directions.
  • the most important of such spaceharmonic components as far as traveling-wave tubes are concerned is the so-called 1 component, since the tube will tend to oscillate at a frequency for which the phase velocity of this 1 component is nearly equal to the velocity of the beam.
  • the frequency of oscillation is considerably higher (two to three times) the normal operating frequency of the tube but, nevertheless, it interferes with normal operation.
  • the presence of the attenuator does not appreciably affect this backward-wave interaction, except to determine the length of the tube over which the interaction can take place.
  • Unequal velocities and also unequal currents in the beams can be used to increase the bandwidth of the tube or permit simultaneous operation in two separate frequency ranges.
  • FIGURES 3, 4, 5, 6 and 7 show various composite helical conductive structures which may be associated with beam-producing structures to form traveling-wave devices of the kind shown in FIGURE 1.
  • FIGURE 3 there is shown a composite slow-wave structure 59 consisting of four helical conductors 60, 61, 62 and 63, each having the same diameter, pitch and axial length.
  • the conductors are arranged so that their axes form the parallel sides of a rectangular parallelepiped, the other sides of which are equal to the diameter of the helical condutcor.
  • Each of the helical conductors of FIGURE 3 are wound in the same sense, that is, they are right-handed as indicated by arrows adjacent each of the helical conductors. But, of course, they all maybe left-hand helices, if desired.
  • each helical conductor contacts two other adjacent helical conductors along their lengths at points that are spaced a turn apart.
  • the resultant composite structure 59 may be associated with beam-producing structures forming a single or a plurality of beams axially directed through one or more of the helical conductors and function as a traveling-wave tube in the manner described in connection with FIGURE 1.
  • Input connection may be made to the structure 59 by means of conductor 58 corresponding to conductor 33 of FIGURE 1 connected to a point of contact between helices 61 and 62 at the entrance end thereof. Similar provisions may be made at the output end of the helical conductors.
  • FIGURE 3 A particularly useful mode of operation of the slowwave structure FIGURE 3 is in conjunction with beamproducing means forming a single beam axially directed through axial opening 64 of the composite helical structure.
  • the structure of FIGURE 3 has the advantage that though the electrically effective dimensions of the composite structure are small and hence suitable for operation at very high frequencies, the structure is formed, not from elements which are delicate and difiicult to produce, but
  • the structure of FI URE 3 provides an eflicient slow-wave structure for use at high frequencies, having excellent heat dissipation qualities.
  • FIGURE 4 shows a composite slow-wave structure 65 consisting of helical conductors 66, 67, 68 and 69, identical in all respects to the structure 59 of FIGURE 3 except that helical conductors 66 and 68 are in the form of righthand helices and conductors 67 and 69 are in the form of left-hand helices.
  • the composite structure 65 of FIGURE 4 may be used in association with beam-producing means in the manner explained in connection with FIGURES l, 2 and 3.
  • Conductor 56 connected between the junction of conductors 66, 67 and conductors 68, 69 and energizable at a mid-point 57 thereof provides a means for applying energization thereof. Similar means may be provided at the output end of the composite structure.
  • a particular advantage of the structure of FIGURE 4 is that better performance is obtained over a wider frequency range.
  • FIGURES 5 and 6 there are shown side and end views, respectively, of another composite structure 70 comprising helical conductors 71 and 72 suitable for use in traveling-wave tubes.
  • the composite structure is similar to the slow-wave structure of the embodiment of FIGURE 1, except that the axes of the helical conductors 71 and 72 are separated by a distance greater than the helix diameter of the conductors.
  • the conductors are joined at adjacent points along their lengths by straps 73.
  • Conductors 98 and 55 connected to one of the straps 73 at the entrance and exit end of the composite structure provide means for coupling energy into and out of the composite structure.
  • Successive points of connection on a conductor are arranged to be a turn apart and preferably the straps should not be more than a small fraction of a wavelength long at the frequency of operation of the structure. If desired, small conductive rings having a diameter small in comparison to a wavelength at the frequency of operation may be used in place of the straps.
  • This structure is advantageously used where the beams formed by a cathode gun structure are separated by radial distances greater than the diameter of the helical conductors.
  • FIGURE 7 is shown a further composite structure 74, suitable for use in traveling-wave tubes consisting of five helical conductors 75, 76, 77, 78 and 79, each having the same diameter, pitch and length, in which the axes of four of the conductors form the parallel sides of a rectangular parallelepiped, and in which the axis of the fifth helical conductor extends through the center of the para]- lelepiped parallel to the other axes and separated therefrom by the helix diameter of a helical conductor.
  • Such an arrangement produces a structure in which the center helical conductor contacts each of the other helical conductors.
  • the fifth or center helical conductor may also be replaced by a series of discrete rings.
  • Waves to be amplified may be applied to the structure and removed therefrom by input and output conductors similar to those shown and described in connection with FIGURES 3, 4 and 5, or by waveguide coupling means which convey electromagnetic Wave energy to and from appropriate portions of the composite structure in a manner well known in the art.
  • FIGURES 8, 9, l0 and 11 show various composite helix-derived structures which may be associated with beam-producing structures to form traveling-wave devices of the kind shown in FIGURE 1.
  • Helix-derived structures are those structures wherein there is provided a conductive path or plurality of conductive paths on a structure which extends about and along an axis of the structure.
  • Electromagnetic waves or signals may be coupled to and from the structures of FIGURES 8, 9, and 11 by conductive or waveguiding means described in connection with FIG- URES 2, 3, 4, 5, 6 and 7.
  • a composite slow-wave structure 80 suitable for use in traveling-wave tubes comprising individual helix derived members 81 and 82 of circular cross section.
  • Each of the members comprises a plurality of annular conductors 83, each axially aligned and displaced from an annular conductor.
  • Each of the annular conductors is joined to adjacent annular conductors by a pair of conductive straps 84, 85, one conductive strap joining one annular conductor with an adjacent annular conductor on one side thereof, and the other conductive strap diametrically opposite the one conductive strap and joining the annular conductor with the adjacent annular conductor on the other side thereof.
  • the members 81 and 82 are arranged in tangential relationship with their axes aligned in parallel and with the adjacent conductive straps of one member in conductive contact with the adjacent conductive straps of the other member.
  • the diameter of the annular conductors are chosen with respect to the frequency of operation to obtain the desired operation and the members may be many wavelengths long as explained in connection with FIGURE 1.
  • a pair of contra-wound helical paths may be traced. Accordingly, it is referred to as a contra-wound helix-derived structure.
  • FIGURE 9 there is shown another composite slow-wave structure 85 made up of four complex helix-derived members 87, 88, 89 and 00.
  • the four members are identical to one another in all respects.
  • Each of the members is comprised of a plurality of annular conductors 91, each lying on the same axis and each being displaced by a predetermined distance from adjacent annular conductors on each side thereof.
  • Each annular conductor is connected to an adjacent annular conductor on one side thereof by a pair of conductive straps 92 and 93 diametrically opposite one another and is connected to an adjacent annular member on the other side thereof by a pair of conductive straps 94 and 95 diametrically opposite one another and generally displaced in a plane perpendicular to the plane of the first-mentioned straps.
  • the members 87, 88, S9 and 90 are arranged in contactive relationship with their axes forming the parallel sides of a parallelepiped, the other sides of which are equal to the diameter of the annular conductors 91.
  • the members are further arranged so that the composite structure of the annular conductors are aligned in planes perpendicular to the axes of the individual members.
  • the members are still further arranged so that the conductive straps of a pair of vertically disposed members, one with respect to the other, are in conductive contact and so that the conductive straps of a pair of horizontally disposed members, one with respect to the other, are in conductive contact.
  • two pairs of contra-wound helical paths may be traced. Accordingly, it is referred to as a bi-filar contra-wound helixderived structure.
  • FIGURE 10 shows a plan view and FIGURE 11 shows a side view of a portion of a composite helix-derived structure 100 which is rugged and is economical to construct.
  • the composite structure comprises two groups of rodlike linear conductors, one group comprising elements 101-106, the other group comprising elements 107112.
  • the conductors in each group are parallel to one another and the conductors of one group are in space quadrature relationship to the conductors of the other group.
  • the conductors of each of the groups are arranged into a plurality of sets. In the one group conductors 101 and 102 comprise one set, conductors 103 and 104 comprise a second set, and conductors 105 and 106 comprise a third set.
  • conductors 107 and 108 comprise a first set
  • conductors 109 and 110 comprise a second set
  • conductors 111 and 112 comprise a third set.
  • the conductors in each set lie in a plane and successive conductors in a set are laterally displaced from one another by a predetermined distance 113.
  • the conductors of each set of one group are conductively stacked or interleaved between the conductors of successive sets of conductors of the other group.
  • Conductors 101 and 102 of an odd-numbered set of the one group are first laid down.
  • Conductors 107 and 108 of the odd-numbered set of the other group are then laid down.
  • conductors 103 and 104 of the even set of the one group are laid over conductors 107 and 108.
  • conductors 109 and 110 of the next even set of conductors of the other group are laid over conductors 103 and 104 to complete a repeating pattern of the composite structure which may include many sets of conductors.
  • the conductors of the odd-positioned sets of each group lie in a respective set of planes perpendicular to the planes of said sets.
  • the conductors of the even-positioned sets of each group also lie in a respective set of planes perpendicular to the planes of said sets.
  • the number of planes in a set of planes is equal to the number of conductors in a set of conductors.
  • Adjacent planes of the even and odd position sets of planes of one group of conductors are spaced apart by a predetermined distance 114 equal to one-half the firstmentioned predetermined distance.
  • a plurality of generally helical conductive configurations made up of rectilinearly oriented elements, instead of the usual curvilinear elements, joined together along their length are formed.
  • a turn and a half for each of nine such conductive configurations are formed, designated a through i.
  • Configurations a, b, c, d and i are lefthand helical configurations as viewed looking into the plane of the figure and as indicated by arrows adjacent each of the configurations.
  • Configurations e, f, g and h are right-hand helical configurations as indicated by arrows adjacent each of the configurations.
  • Helices a, b, c and d each have two sides in common with other helices of the combination.
  • Helices e, f, g and h have three sides in common with the other helices.
  • the helix i not only has four sides in common with other helices e, f, g and h, but also has a point in common with each of the helices a, b, c and d.
  • a single or plurality of beams may be utilized.
  • the number of helixderived configurations formed can be increased, if desired, by simply increasing the number of linear conductors in each set.
  • Such a composite structure may be used in conjunction with beam-producing means forming a single or a plurality of beams coupling with one or a plurality of helical conductors in the manner described in connection with FIGURE 3.
  • An electron discharge device of the type wherein an electron beam interacts with a traveling wave comprising a plurality of individual waveguiding members of circular cross section each adapted to develop a velocity of travel for an applied electromagnetic wave along an axis thereof substantially less than the free-space velocity of said wave, each of said Waveguiding members being several wavelengths long at the frequency of said applied electromagnetic wave and having an input and an output, a plurality of electrically corresponding parts of said waveguiding member being joined to one another along the lengths thereof at intervals less than a wave-length apart, and means for producing an electron flow in an axial di- 1 1 rection in the path of travel of said applied wave in energy interchanging relationship withsaid traveling wave in each of said Waveguiding members.
  • An electron discharge device of the type wherein an electron beam interacts with a traveling wave comprising an electron source, a collector electrode spaced apart from said source for defining therebetween a path of electron flow, a wave transmission circuit positioned along the path of electron flow for propagating an electromagnetic wave in energy coupling relation with electron flow in said path including a plurality of individual electromagnetic wave propagation members of circular cross section, each of said members comprising a continuous conductive member constructed to produce from an applied electromagnetic wave a component of electric field in the direction of electron fiow having a velocity substantially lower than the free-space velocity of said wave, each of said members having a length in the direction of flow several wavelengths long at the frequency of said wave and positioned so that electrons from said electron source traverse the length thereof, each of said members being conductively joined to at least one other member at a plurality of points spaced at electrically equivalent intervals less than a wavelength apart along the length thereof, and means for coupling electromagnetic wave energy to said wave transmission circuit at one point thereof and for removing electromagnetic wave energy from said circuit at another point
  • An electron discharge device of the type wherein an electron beam interacts with a traveling wave comprising a plurality of sources of electrons, a collector electrode means spaced apart from said sources for defining therebetween a plurality of distinct paths of electron flow, a wave transmission circuit positioned along said paths of electron fiow for propagating a traveling wave in energy coupling relation with electron flow in said paths including a plurality of individual electromagnetic wave propagation members of circular cross section, each of said members comprising a continuous conductive member constructed to produce from an applied electromagnetic wave a component of electric field in the direction of electron flow having a velocity along the axis of said member substantially lower than the free-space velocity of said applied wave, each of said members having a length in the direction of electron flow several wavelengths long at the frequency of said wave, each of said members being conductively joined to at least one other member at points spaced at electrically equivalent intervals less than a wavelength apart along the length thereof, and means for cou pling electromagnetic wave energy to said wave transmission circuit at one point thereof and for removing electromagnetic wave energy from said circuit
  • An electron discharge device which utilizes the interaction between an electromagnetic wave and an electron beam to augment the amplitude of said wave comprising an electron source, a collector electrode spaced apart from said source for defining therebetween a path of electron flow, a wave transmission circuit positioned along the path of electron flow for propagating an electromagnetic wave in energy coupling relation with electron flow in said path including a plurality of individual electromagnetic wave-propagation members of circular cross section, each of said members producing from an applied electromagnetic wave a component of electric field in the direction of electron flow having a velocity substantially lower than the free-space velocity of said wave, each of said members having a length in the direction of electron flow several wavelengths long at the frequency of said wave, each of said members being conductively joined to at least one other member at points spaced at electrically equivalent intervals less than a wave-length apart along the length thereof, means for applying an electromagnetic wave to said wave transmission circuit at one point thereof, means for establishing an electron flow between said l2. electron source within each of said members and said collector electrode of an average velocity to augment the amplitude of
  • An electron discharge device which utilizes the interaction between an electromagnetic wave and an electron beam to augment the amplitude of said wave, comprising a plurality of sources of electrons, a collector electrode means spaced apart from said source for defining therebetween a plurality of distinct paths of electron flow, a wave transmission circuit positioned along said-paths of electron flow for propagating a traveling Wave in energy coupling relation with electron fiow in said paths including a plurality of individual electromagnetic wave-propagation members of circular cross section, each of said members comprising a continuous conductive member constructed to produce from an applied electromagnetic wave a component of electric field in the direction of electron flow having a velocity substantially lower than the free-space velocity of said applied Wave, each of said members having a length in the direction of electron flow several wavelengths long at the frequency of said wave, each of said members being conductively joined to at least one other member at points spaced at electrically equivalent intervals less than a wave-length apart along the length thereof, means for applying an electromagnetic wave to said wave transmission circuit at one point thereof, means for establishing an electron flow
  • An electron discharge device which utilizes the interaction between an electromagnetic wave and an electron beam to augment the amplitude of said wave, comprising a pair of electron sources, a collector electrode means spaced apart from said sources for defining therewith a pair of distinct paths of electron fiow, a wave transmission circuit positioned along said paths of electron flow for propagating a traveling wave in energy coupling relation with electron flow in said paths including a pair of individual electromagnetic wave-propagation members of circular cross section, each of said members comprising a continuous conductive member constructed to produce from an applied electromagnetic wave a component of electric field in the direction of electron flow having a velocity substantially lower than the free-space velocity of said applied wave, each of said members having a length in the direction of electron flow several wavelengths long at the frequency of said wave, one of said members being conductively joined to the other of said members at points spaced at electrically equivalent intervals less than a wave-length apart along the lengths thereof, and means for coupling electromagnetic wave energy to said wave transmission circuit at one point thereof and for removing electromagnetic wave energy from said circuit at another
  • An electron discharge device which utilizes the interaction between an electron beam and an electromagnetic wave traveling in the direction of flow of electrons of said beam to augment the amplitude of said wave, comprising a pair of electron sources, a collector electrode means spaced apart from said source for defining therewith a pair of distinct paths of electron flow, a wave transmission circuit positioned along said paths of electron flow for propagating a traveling wave in energy coupling relation with electron flow in said paths including a pair of individual electromagnetic wave-propagation members of circular cross section, each of said members constructed of a continuous conductive member having a configuration to produce from an applied electromagnetic wave a component of electric field in the direction of electron flow having a phase velocity substantially lower than the free-space velocity of said applied wave,
  • each of said members having a length in the direction of electron flow several wavelengths long at the frequency of said wave, one of said members being conductively joined to the other of said members at points spaced at electrically equivalent intervals less than a wave-length apart along the lengths thereof, means for applying an electromagnetic wave to said wave transmission circuit at one point thereof, means for establishing an electron flow in each of said paths between said electron sources and said collector electrode, means of adjusting the electron velocity to augment the amplitude of said applied wave, the average velocity of electron flow in one of said paths being different from the average velocity of electron flow of the other of said paths to suppress amplification of backward waves without appreciably affecting forward traveling waves, and means for removing electromagnetic Wave energy augmented in amplitude from said circuit at another point thereof.
  • An electron discharge device which utilizes the interaction between an electromagnetic wave and an electron beam to augment the amplitude of said wave, comprising a plurality of sources of electrons, a collector electrode means spaced apart from said source for defining therebetween a plurality of distinct paths of electron flow, a wave transmission circuit positioned along said paths of electron flow for propagating a traveling wave in energy coupling relation with electron flow in said paths including a plurality of individual electromagnetic wave-propagation members of circular cross section, each of said members having a length in the direction of electron flow several wavelengths long at the frequency of said wave, each of said members constructed of a continuous conductive member having configuration to produce from an applied electromagnetic wave an electric field component having a velocity substantially lower than the free-space velocity of said electromagnetic wave and being aligned with a respective one of said paths to permit interaction with electron flow therewith, each of said members being conductively joined to at least one other member at points spaced at electrically equivalent intervals less than a wave-length apart along the length thereof, and means for coupling electromagnetic wave energy to said wave transmission
  • An electron discharge device which utilizes the interaction between an electromagnetic wave and an electron beam to augment amplitude of said wave comprising a structure including a plurality of individual electromagnetic wave-propagating substantially continuous conductors, each of said conductors extending about and along an axis thereof to provide a member of circular cross section whereby an electromagnetic wave applied thereto has a component of electric field along said axis having a velocity along said axis less than the velocity of said wave along said conductor, each of said conductors having an axial length of several wavelengths at the frequency of said applied wave, one of said conductors being connected to at least one other of said conductors at points spaced along the conductors, said points for each of said conductors being at substantially electrically equivalent intervals from the ends of said conductors, said intervals being sufficiently small to maintain the axial component of the wave associated with each of said conductors in phase during propagation of the wave from one end of each of the conductors to the other end thereof, and means for producing a flow of electrons along an axis
  • An electron discharge device of the kind depending for operation on the interaction of an electron beam with a traveling electromagnetic wave comprising a plurality of individual electromagnetic wave-propagating conductors, each of said conductors having an input and an output, each of said conductors including an individual continuous conductive member extending about and alongthe axis thereof to provide a member of circular cross section whereby the velocity of an electromagnetic wave on said conductor in the direction of said axis is less than the velocity of said wave along said conductor, and means for producing a plurality of electron beams, each of said beams being axially directed with respect to a respective conductor and in energy exchanging relationship therewith, each of said conductors having a length of several wavelengths long at the frequency of said wave, each one of said conductors and another of said conductors conductively connected at points spaced along said conductors, said points for each of said conductors being at substantially electrically equivalent intervals from the input end of said conductors, said intervals being sufficiently small tomaintain the axial component of the wave
  • a slow-wave structure for use in connection with devices for propagating electromagnetic waves comprising a plurality of individual identical helix-derived conductive members of circular cross section for guiding said electromagnetic wave, a means to introduce and extract electromagnetic waves from each of said members, each of said members comprising a continuous conductor having an input and an output, each of said individual members being capable of propagating an electromagnetic wave and proportioned to produce a component of electric field having a phase velocity substantially lower than thefreespace velocity of an applied electromagnetic wave, each of said members having an axial length of many wavelengths at the frequency of said waves, each one of Said members conductively connected to at least one other of said conductors at points spaced along said members, said points for each of said members being at substantially electrically equivalent intervals from the input end of said members, said intervals being sufficiently small to maintain the axial component of waves associated with each of said members in phase during the propagation thereof from the input end of said members to the output ends thereof.
  • a slow-wave structure for use in connection with devices for translating electromagnetic waves comprising a pair of identical helix-derived conductive members of circular cross section for guiding said electromagnetic wave, each of said members having an input and an output, each of said members being composed of a continuous conductor and proportioned to produce a compo nent of electric field having a phase velocity substantially lower than the free-space velocity of an applied electromagnetic wave, said members being of equal axial lengths many wavelengths long at the frequency of said wave, each of said members including a plurality of annular conductive elements, the conductive elements of each member being spaced apart on a common axis, one of said conductive elements being conductively joined on one side to an adjacent conductive element by a conducting strap and being joined with an annular element on the other side thereof by another conductive strap diametrically opposite said first strap, the axes of said member being arranged in parallel and said members being in tangential contact at said straps.
  • a slow-wave structure for use in connection with devices for translating electromagnetic waves comprising a pair of identical helix-derived conductive members for guiding said electromagnetic wave, each of said members having an input and an output, each of said members being proportioned to produce a component of electric field having a phase velocity substantially lower than the free-space velocity of an applied electromagnetic Wave, said members being of equal axial length many wavelengths long at the frequency of said wave, each of said conductive members including a plurality of annular conductive elements, the conductive elements of each memher being uniformly spaced apart on a common axis, one of said conductive elements being conductively joined on one side to an adjacent conductive element by a pair of diametrically opposite conductive straps and being joined with an annular element on the other side thereof by another pair of diametrically opposite conductive straps in quadrature space relationship to said one pair of straps, the axes of said members being in parallel and said members being in tangential contact with said straps.
  • a slow-wave structure for use in connection With devices for translating electromagnetic waves comprising a plurality of individual helical conductive members for guiding said electromagnetic wave, a means for introducing and extracting electromagnetic Waves from each of said members, each of said members having an input and an output, each of said members being proportioned to produce a component of electric field having a phase velocity substantially lower than the free-space velocity of an applied electromagnetic wave, each of said members having the same helix diameter, pitch and length, the axial length of each of said elements being many Wavelengths at the fre quency of said Wave, the axes of said members being aligned in parallel, each one of said members being conductively connected to at least one other of said members at points spaced along said members a turn apart, the conductive connection from a point of one conductor to a corresponding point on the other member being a small fraction of a wavelength of the applied wave in length.
  • a slow-wave structure for use in connection with devices for translating electromagnetic waves comprising a group of tour helical conductive members for guiding said electromagnetic wave, each of said members having an input and an output,'each of said members being proportioned to produce a component of electric field having a phase velocity along the axis thereof lower than the free-space velocity of an applied electromagnetic wave, each of said members having the same helix diameter, pitch and length, the axial length of each of said members being many wavelengths at the frequency of said Wave, the axes of said members being aligned in parallel and forming the sides of a parallelepiped the other sides of which are equal to said helix diameter, each helical member being in conductive contact with two other helical members once every turn thereof, one pair of diagonally opposite helical conductive members being wound in one sense and the other pair of diagonally opposite helical conductive members being wound in the opposite sense.

Landscapes

  • Microwave Tubes (AREA)
US657367A 1957-05-06 1957-05-06 Electron discharge devices Expired - Lifetime US3054017A (en)

Priority Applications (4)

Application Number Priority Date Filing Date Title
US657367A US3054017A (en) 1957-05-06 1957-05-06 Electron discharge devices
GB13203/58A GB841791A (en) 1957-05-06 1958-04-25 Improvements in or relating to travelling-wave electron discharge devices
FR1209100D FR1209100A (fr) 1957-05-06 1958-05-06 Dispositifs à décharge électronique
DEG24470A DE1282797B (de) 1957-05-06 1958-05-06 Wanderfeldroehre mit mehreren, parallelen Verzoegerungsleitungen

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US657367A US3054017A (en) 1957-05-06 1957-05-06 Electron discharge devices

Publications (1)

Publication Number Publication Date
US3054017A true US3054017A (en) 1962-09-11

Family

ID=24636862

Family Applications (1)

Application Number Title Priority Date Filing Date
US657367A Expired - Lifetime US3054017A (en) 1957-05-06 1957-05-06 Electron discharge devices

Country Status (4)

Country Link
US (1) US3054017A (de)
DE (1) DE1282797B (de)
FR (1) FR1209100A (de)
GB (1) GB841791A (de)

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3167727A (en) * 1961-03-09 1965-01-26 Boeing Co Microwave zig-zag line couplers
US3253230A (en) * 1963-01-30 1966-05-24 Raytheon Co Cascaded traveling wave tubes for producing a multiplicity of frequency signals
US3293563A (en) * 1964-03-16 1966-12-20 Hughes Aircraft Co Microwave power source including plural wave-beam interaction circuits with a plurality of feedback circuit means including a common resonant cavity
US3427495A (en) * 1965-12-15 1969-02-11 Sfd Lab Inc Dual helix coupled periodic circuits and tubes using same
US3484649A (en) * 1967-08-14 1969-12-16 Varian Associates Helix coupled vane circuit with the helix connected centrally of the vanes
US3666984A (en) * 1969-12-16 1972-05-30 Thomson Csf Wide-band high-power delay line

Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB668017A (en) * 1949-06-08 1952-03-12 Vickers Electrical Co Ltd Improvements relating to electromagnetic waveguides
US2735033A (en) * 1956-02-14 Traveling wave tube
FR1119661A (fr) * 1952-11-27 1956-06-22 Siemens Ag Tube électronique pour ondes très courtes avec deux courants électroniques ou plusde deux
US2789247A (en) * 1948-07-23 1957-04-16 Philips Corp Traveling wave tube
US2821652A (en) * 1952-10-06 1958-01-28 Bell Telephone Labor Inc Multihelix traveling wave tubes
US2853644A (en) * 1956-07-30 1958-09-23 California Inst Res Found Traveling-wave tube

Family Cites Families (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2679019A (en) * 1947-12-02 1954-05-18 Rca Corp High-frequency electron discharge device
US2708236A (en) * 1950-03-18 1955-05-10 Bell Telephone Labor Inc Microwave amplifiers
NL165263B (nl) * 1950-12-29 Skf Ind Trading & Dev Luchtgekoelde remschijf voor de schijfrem van een motorvoertuig.

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2735033A (en) * 1956-02-14 Traveling wave tube
US2789247A (en) * 1948-07-23 1957-04-16 Philips Corp Traveling wave tube
GB668017A (en) * 1949-06-08 1952-03-12 Vickers Electrical Co Ltd Improvements relating to electromagnetic waveguides
US2821652A (en) * 1952-10-06 1958-01-28 Bell Telephone Labor Inc Multihelix traveling wave tubes
FR1119661A (fr) * 1952-11-27 1956-06-22 Siemens Ag Tube électronique pour ondes très courtes avec deux courants électroniques ou plusde deux
US2853644A (en) * 1956-07-30 1958-09-23 California Inst Res Found Traveling-wave tube

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3167727A (en) * 1961-03-09 1965-01-26 Boeing Co Microwave zig-zag line couplers
US3253230A (en) * 1963-01-30 1966-05-24 Raytheon Co Cascaded traveling wave tubes for producing a multiplicity of frequency signals
US3293563A (en) * 1964-03-16 1966-12-20 Hughes Aircraft Co Microwave power source including plural wave-beam interaction circuits with a plurality of feedback circuit means including a common resonant cavity
US3427495A (en) * 1965-12-15 1969-02-11 Sfd Lab Inc Dual helix coupled periodic circuits and tubes using same
US3484649A (en) * 1967-08-14 1969-12-16 Varian Associates Helix coupled vane circuit with the helix connected centrally of the vanes
US3666984A (en) * 1969-12-16 1972-05-30 Thomson Csf Wide-band high-power delay line

Also Published As

Publication number Publication date
GB841791A (en) 1960-07-20
FR1209100A (fr) 1960-02-29
DE1282797B (de) 1968-11-14

Similar Documents

Publication Publication Date Title
US2602148A (en) High-frequency amplifier
Kompfner The traveling-wave tube as amplifier at microwaves
US2708236A (en) Microwave amplifiers
US3221205A (en) Traveling-wave tube with trap means for preventing oscillation at unwanted frequencies
US2827589A (en) Electron discharge device
Boyd et al. The multiple-beam klystron
US3622834A (en) High-efficiency velocity modulation tube employing harmonic prebunching
US3054017A (en) Electron discharge devices
US2802135A (en) Traveling wave electron tube
US3005126A (en) Traveling-wave tubes
US2952795A (en) Electron discharge device
US2712614A (en) Travelling wave tubes
US2966610A (en) Electron beam tube
US2967968A (en) Electron discharge device
US3571651A (en) Log periodic electron discharge device
US2843797A (en) Slow-wave structures
US2824257A (en) Traveling wave tube
US3104340A (en) Broadband klystron
US2823333A (en) Traveling wave tube
US2843790A (en) Traveling wave amplifier
US3209272A (en) Wide band traveling wave tube amplifier apparatus
US3532926A (en) Broadband waveguide transition for a centipede type traveling wave tube
US3573540A (en) Microwave traveling wave device with electronically switched interaction characteristics
US4370596A (en) Slow-wave filter for electron discharge device
US2758244A (en) Electron beam tubes