US2957173A

US2957173A - Variable conductance trough waveguide antennas

Info

Publication number: US2957173A
Application number: US647453A
Authority: US
Inventors: Rotman Walter
Original assignee: Individual
Current assignee: Individual
Priority date: 1957-03-20
Filing date: 1957-03-20
Publication date: 1960-10-18
Anticipated expiration: 1977-10-18

Description

w. Ro'rMAN 2,957,173

VARIABLE coNDucTANcE TRouGHmvEGUIDE ANTENNAS Oct. 18, 1960 2 Sheets-Sheet 1 Filed March 20, 1957 1N VENTOR. A/AL fav Rar/VAN -q @ff Mm @imm Oct. 18, 1960 w. ROTMAN 2,957,173

VARIABLE CONDUCTANCE TROUGH WAVEGUIDE ANTENNAS Filed March 20, 1957 2 Sheets-Sheet 2 Patented Oct; 18; 1.960.`

VARIABLE coNnUcrANcE rRoUGH WAVE- GUmE ANrENNAs s Walter Rotman, Brighton, Mass. Filed Mar. zo, 1957, ser. No. 647,453

4 claims. (Cl. 343-772) (Granted under Title 3'5, U.S. VCode (1952), sec. 266) The invention described herein may be manufactured and used by or for the United States Government for governmental purposes without payment to me of any royalty thereon.

This invention relates generally to antennas and more particularly to apparatus for the transmission of highfrequency electrical energy. The invention is characterized by the utilization of a special waveguide structure as a means for radiating energy to the surrounding space and involves the use of elements within the waveguide structure for controlling the conductance and radiation intensity or attenuation rate in the waveguide. Control of these parameters enables the obtaining of various desired controlled radiation characteristics which include a lobing pattern. l A

A trough waveguide of either rectangular channel shape, U-shape, V-shape or variations thereof having a symmetrically disposed n therein comprises the transmission line which is modiiied to produce the controlled radiation. The basic concept on which this invention relies is that anti-symmetrical obstacles in a trough waveguide couple energy from the bound symmetrical trough guide mode, a transverse electric (TE) mode, into energy in a transverse electromagnetic (TEM) eld which radiates into free space from the open side of the waveguide. Symmetrical obstacles, on the other hand, react as tuning elements. In accordance with above principles, a variety of radiating devices may be constructed.

The trough waveguides, together with their radiating elements, have utility alone or as primary line source arrays for use with secondary reflectors, horns, or lenses in radar and communication `antenna systems. In this respect, they are superior to slots or dipole equivalent arrays on rectangular or circular waveguides.

Because of the superior electrical and mechanical properties of the antennas of this invention, many new advantages are realized. l

It is contemplated that the subject invention will open new vistas in the iields of radio astronomy, radar, and communications.

It is an object of this invention to produce an antenna comprising a trough waveguide with means for controlling radiation therefrom. n.

It is another object of the invention to produce an antenna composed of discreet resonant radiating elements..

Still another object of the invention involves the production of novel radiating, non-susceptive elements whose conductances are variable.

It is a further object of the invention to produce an antenna which is easily and economically produced by conventional, commercial manufacturing techniques.

It is a still further object of this invention to produce a novel antenna for broadband radiation.

Another object of the invention is to produce a novel resonant radiating element for use in a trough waveguide.

Still another object of the invention involves the production of a novel traveling wave antenna array of resonant radiating elements.

y I Y, 2 y j. K A further object of the invention involves the production of a novel antenna suitable for producing a sequential lobing radiation pattern. Y A still further object of the invention involves the production of an antenna array where a phase reversal is achieved between successive radiating elements.

These and other advantages, features and objects ofthe invention will become more apparent from the following description taken in connection with the villustrative embodiments in the accompanying drawings, wherein:

'Figure l is a cross-sectionalview of a trough waveguide with a representation of the electric eld -of the transverse electric (TE) mode therein; y

Figure 2 is a cross-section of a trough waveguide with a representation of the electric componentsf ofthe transverse electromagnetic (TEM)-eld; p 1

Figure'3 is a cross-section of a trough waveguide with a TE mode to TEM` field coupler; d

Figure 4 s a cross-sectional View of a trough Waveguide with a tuning element for ,the TE mode;

Figure 5 is a pictorial view of the tri-rod coupling element; Y j f l Figure 6 is a pictorial view of a rotatable. tri-rod coupler in a trough waveguide; and n f Figure 7 is a schematic representationof Va part of a trough waveguide with variable coupling elements for lobe switching. v j l, Y Thev invention utilizes a symmetrical non-radiating trough waveguide which acts as a transmission line. vThis type of waveguide in` its mechanical construction is left open on one side; however, it still acts as a transmission line. Its characteristics, frequency-wise follow those-ot a waveguide while it retains simplicity of a strip trans-. mission line. The general conguration of the waveguide has ltwo side walls and a bottom, thus forming a trough, and a substantially centrally disposed lin member of less height than the ,side walls.l The embodiment of Figure 1 is a channel or rectangular form of trough waveguide but various alternative formsv can be achieved by deformation of the sidewalls, for example, the troughV v may be of U or V shapeas long as symmetry about the centraln is maintained in order to avoid spurious modes. Like numerals will designate like parts ofthe wave-l guide throughout the specification. t p. Figure 1, for illustration purposes, shows a rectangular Y trough waveguide having side Wallsy 20 and 21, a bottom wall 22 and a substantially centrally disposed iin member 23.l When the

side walls

20 and 21 are lessV than one-half wavelength apart, a TE (transverse electric) mode may be propagated along the axis of the guide. This mode is bound Vto the center lin and has an electric iield with a general coniguration as shown in FigureV 1.,A The intensity of the eld lines of the electric vector increases from the bottom 22 of the waveguide to the top of the central vane or Viin 23. The transverse currents on the sides of n 23 vary from a minimum at the free edge to a maximum at its base. v

The electric components of the TEM (transverse electroma'gnetic) field is depicted in Figure 2 and-can bel propagated wherever side walls exist asis shown by -the verted into a TEM field which is not bound to the ,centery fin. The'TEM eld is capable of being propagated in`v all directions at right angles to the TE vectors. which allows a release of energyfrom the open side of the wave-- guide.`

Although the trough waveguide is shown as ,a` unitary.A

structure of highly conductive material,y each of portions' designated' as20, 21, 22`and'23 couldbemade of separate ieces of stock of any material secured together by con- 'entional means as long as the interior of the trough is lated or otherwise lined with a highly conductive maerial.

The* characteristics of a trough waveguide ar-e such hat the cut-off wavelength depends upon the electrical leight of the center n 23, e.g., the cut-olf wavelength s approximately that at which the center tin is a quar er wavelength. The side wall (20, 21) height abovev he center fin 23 and the spacing between side walls act4 o prevent unwanted, uncontrolledy radiation. Less than ralf wavelength spacing between the side walls allows :'or operation of the line over a range of frequencies'. lhe spacing of the side walls, at any rate, should not :Xceed a half wavelength of the highest frequency in he range. The TE mode is critically dependent upon he dimensions ofthe center iin while the TEM or radiatng mode is independent of the n 23.

Figure 3 represents a basic principle or concept upon which this invention is based. An anti-symmetrical ob- ;tacle, such as a horizontal rod 24, has the ability in a rough waveguide to convert some of the energy from he bound TE mode into the TEM field which is then radiated into free space. Utilization of this principle allows for the production of controlled radiation along :he length of the waveguide. The rod 24, perpendicular :o center iin 23, creates an asymmetry such that when rod 24 is excited, it reradiates the incident energy in both the TEM fiel-d and the TE mode thereby causing a portion of the incident energy from the TE mode to be converted into the TEM eld while another portion is reflected back in the TE mode towards the source. The shunt admittance of the rod as measured in the trough guide appears to have two components: a reactive suscept-ance determined by the amount of reflected energy and a conductance governed by the amount of energy coupled between the TE mode and the TEM field and subsequently radiated. The rod 24 will appear as a resonant element if the capacitive susceptance is cancelled by an additional reilection, equal in magnitude but opposite in phase. Changing the length of the rod increases both the susceptive and conductive component.

Symmetrical obstacles do not couple the TE mode and TEM field; therefore, they may be used as tuning elements. The vertical post 25 placed above fin 23 (Figure 4) is greater than a quarter wavelength and by virtue of its symmetry does not couple energy, but causes a reflection which appears as an inductive shunt susceptance.

The tri-rod coupler 26 (Figure 5) may be applied to a waveguide as illustrated in Figure 6. The coupling of tri-rod 26 may be varied continuously from zero to some maximum value while its susceptance remains substantially zero. Rotation ot the coupler allows for the production of various` desired, radiation amplitudes and for modification of the radiation pattern.

Coupler 26 comprises an inductive tuning post 27, symmetrical

capacitive tuning rods

28 and 29, and an asymmetrical coupling rod 30. By combining elements 24 and 25 of Figures 3 and 4 the structure of Figure 5 results without

elements

28 and 29. Rotation of the two element

structures comprising elements

27 and 30 mounted on the fin 23 of a waveguide will be considered. Capacitive asymme-tric rod 30, when at a position at right angles to `the lin 23, may be resonated by adjusting the length of vertical post 27. When element 30 lies on top of and in line with the .fin 23, a lack of asymmetry occurs yand the conductance drops to zero with only a residual susceptance, due to the vertical post 27 remain-

Identical elements

28 and 29, at right angles to the inductive post 27 and on either side thereof, compensate for the residual susceptance, effectively reducing it to substantially zero.

Asshown in Figure;6,.thetri.1:o,d coupler 26. is mounted on a shaft 31 housed by a tubular por-tion 32 forming a part of the center iin 23 4in* the trough waveguide; By passing the shaft 31 through` center fin 23, the rotation of the shaft does not disturb the field within the guide. Rotation of shaft 31 produces a rotation of coupler 26, which, because of its symmetry, remains approximately in resonance in all of its orientations and the conductance varies smoothly and cyclically from zero -to a maximum value.

By placing a number of tri-rod couplers 26, properly oriented, along the tin, the variations in phase and conductance produced by the diierent orientations of the A coupler may be utilized to produce various radiation characteristics. For example, a broadside radiating antenna may be constructed by utilizing the 180 phase reversal obtained by having rod 30 project on opposite sides of lin 23 at half wavelength intervals.

A holding means may be provided for the shaft 32 (e.g., a set screw in the projecting portion of tubular portion 32 below wall 22) where movement of the cou-` pler will not be affected at too frequent intervals. For relatively long periods of fixed positions of -the coupler, post 27 of the tri-rod coupler could house a 'screw means therein which would engage fin 23 thus securing the. coupler to the lin without the need of a shaft or housing.`

By utilizing the rotating means displayed in Figure 6, the tri-rod coupler may be used for several diierent types of sequential lobing antenna systems.

Referring to the schematic representation of Figure 7" which shows only the center fin of a trough waveguide, couplers 26 `are placed an integral number m of half" wavelengths apart with a shorting termination 33 placedl an odd number n of quarter wavelengths on the n 231 beyond the second coupler. A signal source 34 feeds the waveguide. The shafts of the two couplers are gearedJ together as shown by

gears

35, 3o and 37 and oriented so that one coupler is mechanically out of phase with the other. Thus, when attached -to a driving means; 38 and the tirst coupler is at its maximum conductance, the second element is completely decoupled, and vicel versa. Since the elements are spaced a half Wavelength apart, the input admittance to the trough waveguide is,A the sum of the admittances of the two couplers, It can be seen that as the couplers are rotated in synchronism, the input conductance remains approximately constant while the susceptance is always signioant. Thus, this" antenna system always presents a good match to the transmitter. However, the apparent point off radiation moves from the first coupler to the second and back' again as the elements yare rotated, completing two cycles for one rotation of the couplers. If this device is used as the primary feed for sa microwave lens or reflector, sequential lobing of the radiation pattern may be obtained.

Although the invention has been described with reference to particular embodiments, it will be understood to those skilled in the art that the invention is capableof a variety of alternative embodiments within the spirit and scope of the appended claims.

I claim:

1. A waveguide adapted for the controlled interchange of energy between itself and surrounding space comprising a transmission line of generally trough-shaped cross section which is substantially constant throughout its length, a center fm symmetrically disposed within said' generally trough-shaped structure and a tri-rod coupling element mounted on said center tin, said tri-rod coupler comprising a horizontal radiating or coupling element, a tuning element` at right angles to said radiating element and a pair of capacitive tuning elements each of which is mutually perpendicular to both said radiating element' and said tuning element.

2. A waveguide as defined in claim -1 wherein a number of said tri-rod couplers are oriented on said' center n.

3. A waveguide as defined in claim 2 including means for adjusting the orientation of said tri-rod couplers.

4. A sequential lobing antenna comprising a generally trough-shaped waveguide having a centrally disposed n member extending longitudinally thereof, at least one pair of tri-rod couplers mounted on said n an integral number of half wavelengths apart, and means -for rotating said tri-rod couplers simultaneously in a 90 mechanically out of phase relation, said tri-rod coupler comprising a horizontal radiating or coupling element, a vertical tuning element attached to one end of said radiating element and a pair of capacitive tuning elements each of which is perpendicular to said radiating element and said vertical tuning element.

References Cited in the le of this patent UNITED STATES VPATENTS OTHER REFERENCES Pub. I. Some New Microwave Antenna Designs Based on the Trough Wave Guide, Rotman and Karas, 1956 IRE Convention Record, vol. 4, Part l, copyright l1956,

5 pp. 23o-235.

Pub. II. The Bell System Technical Journal, vol. 34, No. 1 January 1955, pp. 71, 72.