US2692336A - Aperture antenna - Google Patents

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US2692336A
US2692336A US129552A US12955249A US2692336A US 2692336 A US2692336 A US 2692336A US 129552 A US129552 A US 129552A US 12955249 A US12955249 A US 12955249A US 2692336 A US2692336 A US 2692336A
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aperture
horn
cells
antenna
wavelength
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Winston E Kock
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AT&T Corp
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Bell Telephone Laboratories Inc
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q19/00Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic
    • H01Q19/06Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using refracting or diffracting devices, e.g. lens
    • H01Q19/08Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using refracting or diffracting devices, e.g. lens for modifying the radiation pattern of a radiating horn in which it is located

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  • This invention relates to directive antennas and more particularly to methods and means for improving the directive action of microwave antennas of the aperture type.
  • horns, wave guides, lens, reflectors and difiractors each having a so-called antenna aperture
  • the directivity or more specifically the half power width of the major directive lobe, in any given plane is inversely proportional to the linear dimension of the aperture in the said given plane, and directly proportional to the wavelength.
  • the sharpest beam, or stated dilferently, the minimum half power Width for the major lobe is obtainable only when the components of the Wave in the aperture are cophasal and the amplitudes of the foresaid components are equal.
  • the mouth aperture of a microwave horn designed for a mean wavelength is divided by a pair of fiat conductive members or partitions into three small cells each having a dimension or span in a given plane or radio action which is small, for example a quarter wavelength, relative to one-half of said wavelength.
  • the spacing, in the horn mouth aperture, betweenthe front edges of the flat partitions is such as to render the cell areas or more specifically the aforesaid cell dimensions equal.
  • the partitions extend toward the horn throat aperture and the spacing between the back edges of the partitions is such as to secure a predetermined non-uniform amplitude distribution for the waves propagated through the three cells.
  • a dielectric phase reverser is positioned between the two partitions, that is, in the central channel or cell so that the waves in the adjacent cells are oppositely phased. More specifically, the relative amplitude distribution is 4, 3, 4 and the phase distribution.
  • Fig. 1 is a perspective view and Fig. 2 is a sectional partial plan view of one embodiment of the invention
  • Fig. 3 is a diagram used for explaining the invention.
  • Fig. 4 is a sectional partial plan view of a slightly different embodiment of the invention.
  • Fig. 5 is a perspective view of still another embodiment of the invention.
  • Fig. 6 is a diagram used in explaining the embodiment of Fig. 5.
  • a microwave system I which comprises a sectoral horn 2 connected to a translation device 3 by means of a rectangular guide 4.
  • the sectoral horn comprises the parallel wall members 5 and 6, the flared wall members 1 and 8.
  • Numerals 9 and lil denote respectively the mouth or main antenna aperture and the throat a erture.
  • a pair of diverting conductive members or partitions H and !2 of negligible thickness are positioned perpendicular to the parallel walls 5 and 6 and form therewith thethree passages or channels I3, is and i5.
  • Numerals l6 and Il denote respectively the front and back edges of partitions H and 12.
  • the front edges it of members H and 52 are spaced equal distances h from each other and from the flared horn walls .5 and 6, and form with the front .elges IQ of the horn Walls 5 and 6 the three antenna cells 2%, 2
  • the back edges ll of the partitions H and !2 are spaced apart a distance a; and each partition is spaced a distance I) from the adjacent horn wall.
  • the Width or span h of each cell is small relative to one-half the operating wavelength as, for example, a quarter wavelength; and the spacings a and b are also each small relative to one-half the minimum operating wavelength.
  • the spacing a determines the amplitude of the wave in the middle channel It relative to the equal amplitudes .of the waves in the side channels l3 and i5 and, in the three-channel system of Figs. '1 and 2, the spacing at is smaller than the distance D and i selected so that the amplitude distribution in channels i3, I s and l5 and, more particularly, in cells 20, 24 and .22 is .respectively 4, 3, 4. If the electric polarization of the waves is perpendicular to the partitions H and 12 the dimensional ratio (1/1) is directly proportional tc the amplitude ratio 3/4 for the adjacent cells 2 I, 20 or 2
  • Numeral 23 denotes a dielectric phase reverser positioned in channel l4 between and contacting the partitions I l and l2.
  • a dielectric phase reverser suitable for use in this system is disclosed in Patent 2,405,992 granted to E. Bruce.
  • the reverser 23 has-a critical length L such that the wave component, propagated through the middle channel 1 t and having the mean or given operating wavelength, isdelayed 180 degrees relative tothe component propagated through either of the side channels I3 and 55, as indicated by the signs associated respectively with channels I3,
  • the waves emitted by cells 21,122 and 23 have a non-uniform amplitude distribution, namely, 4, 3, 4 and the Wave components emitted by cell 2
  • each cell is small compared to one-half of the given or mean wavelength, an optimum directive pattern in the plane i8 is obtained. More specifically, as compared to the directive pattern of the horn 2 obtained when the partitions H and !2 and the phase reverser .23 are omitted and the amplitude distribution across the horn mouth aperture is uniform, the pattern of the structure shown in Figs. 1 and .2 is more satisfactory in that it contains an exceedingly narrow major lobeandlow minor lobesthe minor lobe level being one ninth of the major lobe. Stated differently, the beam or major lobe obtained for the sectionalized horn of Figs.
  • the effect of inserting the partition Ii and I2 and the phase reverser 23 in the horn 2, and judiciously selecting the amplitude distribution is to increase the horn aperture span, in the plane l8, from the relatively small actual dimension of 3. h, neglecting the thickness of the partitions H and I2, to the relatively lar e dimension H, for the hypothetical horn comprising the walls 24 and 25.
  • sectional-ized horn 2 comprises a one-dimension linear array of only three cells spaced alon a direction in the plane .18, any practical number of cells as, for example, several :hundredrmay be utilized in the one-dimension array.
  • phase and amplitude distributions should be +0.43, .057, +1.0, -5
  • the amplitude distribution obtained from the above expression namely 5.5, 1.0 and 5.5 is comparable to the 4, 3, 4 distribution employed in the horn of Figs. ,1 and 2.
  • the cell spacing h in the horn 2 is an eighth of a wavelength
  • the distribution, as determined experimentally, should be 0.63, 1.0, and 0.63, and this distribution is substantially the same as the distribution 0.68, 1.0, 0.68 obtained from the above-mentioned expression for an array using one-eighth wavelength spacing. It may be noted that both of the amplitude distributions given above, for the eighth wavelength spacing array,
  • Fig. 4 The embodiment illustrated by Fig. 4 is similar to that illustrated by Figs. 1 and 2, the main difference being that the metallic partition members in Fig. 4 are parallel instead of diverging.
  • Numerals 26 and 2'! denote copper foil members corresponding to the rigid metallic partitions II and I2 and attached to the parallel fiat surfaces of the dielectric phase reverser 23.
  • the thickness of the assembly comprising the dielectric reverser and copper foil members is chosen so as to obtain the correct dimensions a and b and for securing the desired amplitude distribution 4, 3, 4.
  • and 22 are equal, as is the case in the horn of Figs. 1 and 2.
  • the sectionalized horn of Fig. 4 emits or receives waves in substantially the same optimum manner as the sectionalized horn of Figs. 1 and 2.
  • a microwave system 29 comprising a pyramidal horn 30 having a pair of walls 3
  • the horn is sectionalized to form a two-dimension array of cells.
  • the metallic members 35 divide the horn into nine shielded channels 36 and the horn mouth aperture 9 into nine square cells 3?, 38, 39, 40, 4
  • a phase reverser 23 is included in only one of the two adjacent channels.
  • the metallic partition members 35 diverge from back to front in both planes, the front edges of these members being spaced equally in both planes and the back edges being spaced so as to produce the two-dimensional amplitude distribution shown in Fig. 6.
  • has a relative amplitude of 3 and a positive phase
  • the corner cells 31, 39, 43 and 45 each have a relative amplitude of 16/3 and a positive phase
  • the remaining intermediate side cells 38, 40, 42 and 44 each have a relative amplitude of 4 and a negative phase.
  • the effective amplitude distribution is 20/3, 15/3, 20/3, that is 4, 3, 4 which is the algebraic addition of the amplitudes in each horizontal tier.
  • the effective amplitude distribution is 20/3, 15/3, 20/3, that is, 4, 3, 4 obtained by the algebraic addition of the amplitudes in each ver tical stack.
  • the invention has been specifically de- 6: scribed in connection with aperture antennas of the horn type it may be utilized in connection with other types of aperture antennas such as lenses, reflectors and diffractors.
  • the four horn walls may be omitted and a cellular structure comprising open channels or cells and phase shifting channels or cells may be positioned at an appreciable distance in front of the actual horn aperture.
  • a cellular structure corresponding to the cells 31-45 and comprising antiphased adjacent cells may be spaced from the opening of the reflector or the face of the lens or diffractor.
  • An aperture antenna having a given linear aperture dimension, and means for increasing for a given wavelength the effective value of said given dimension, comprising a pair of conductive members positioned in said aperture and forming with the aperture boundary at least three parallelcells having collinear dimensions, each of said collinear dimensions being small relative to one-half of said wavelength, said pair of conductive members being at one end contiguous to and extending inwardly from the energy delivering aperture of said antenna, said conductive members being positioned with respect to said aperture to direct more energy to each of the outer cells than to the central cell. and a phase reverser positioned in the central cell, only.
  • a sectionalized aperture antenna for waves having a given wavelength comprising a plurality of conductive members positioned in the aperture of said antenna and forming a plurality of antenna cells, including a central cell and a plurality of outer cells, the dimensions of each cell in a given plane being small relative to one-half of said wavelength, and a phase changer posi tioned in one only of each pair of adjacent cells said antenna cells being formed contiguous to and extending inwardly from the energy delivering aperture of said antenna, said conductive elements being positioned within said aperture to direct more energy to each of the outer cells than to the central cell.
  • a pyramidal horn for a wave of a given wavelength having four similarly flared Walls and a square mouth aperture, a first set of flat metallic members positioned perpendicularly to one pair of opposite horn walls and a second set of fiat metallic members positioned perpendicularly to the other set of opposite horn walls, each of said flat members having front and back edges, said four horn walls and the front edgesof all of said members forming a square array of square antenna cells, including a central cell and a plurality of outer cells, the side dimension of each cell being small relative to one-half of said wavelength, a plurality of phasing reversers, one of said reversers 7 being positioned in one-only :01 each pair of adjacent cells said partitions being positioned with respect to the mouth :aperture of said horn Lto direct more energy to :each of said outer cells than to the 'centrai cell of said array.

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Description

Oct. 19, '1954 w, E, OCK 2,692,336
APERTURE ANTENNA Filed Nov. 26, 1949 45 INVENTOR gi M E. K OCK A 7' TORNE V Patented Oct. 19, 1954 UNITED STATES PATENT OFFICE APERTURE ANTENNA Winston E. Kock, Basking Ridge, N. J., assignor to Bell Telephone Laboratories, Incorporated, New York, N. Y., a corporation of New York Application November 26, 1949, Serial No. 129,552
3 Claims. 1
This invention relates to directive antennas and more particularly to methods and means for improving the directive action of microwave antennas of the aperture type.
As is known, horns, wave guides, lens, reflectors and difiractors, each having a so-called antenna aperture, have been widely used in the microwave art. In general, in this type of antenna the directivity or more specifically the half power width of the major directive lobe, in any given plane, is inversely proportional to the linear dimension of the aperture in the said given plane, and directly proportional to the wavelength. Also, considering for example, a horn having a single aperture of given area, it has heretofore been assumed that the sharpest beam, or stated dilferently, the minimum half power Width for the major lobe, is obtainable only when the components of the Wave in the aperture are cophasal and the amplitudes of the foresaid components are equal. Consequently, in the past, in order to secure an extremely narrow main beam, it has been found necessary in actual practice to utilize a large cumbersome antenna having an extreme ly large aperture, or at least an exceedingly large dimension or span in the selected plane of radio action, and in some systems, to employ structural means for securing the desired in-phase' uniform energization of the aperture. Accordingly, it now appears desirable to secure, in anaperture type antenna, the exceedingly narrow main beam mentioned above, and in general an optimum directive pattern including a very narrow major lobe and negligible minor lobes, without utilizing a large antenna aperture. Conversely considered, it appears desirable to improve greatly the directive action of an antenna having a given small aperture. In particular, considering an antenna having an aperture of given area or linear span, it appears advantageous to obtain a beam which is considerably sharper, that is, a major lobe which is considerably more narrow, than the beam or lobe obtained when the aforesaid aperture is excited with cophasal wave components of uniform amplitude. In short, whereas in the prior art aperture antennas, the effective antenna area is always smaller than the actual or physical aperture area, it now appears advantageous to secure an effectiv aperture area which is larger than the actual aperture area.
It is one object ofthis invention to increase the directivity of an aperture type antenna.
It is another object of the invention to produce a radio beam having an exceedingly narrow width,
utilizing an antenna having an aperture which is small as compared to that of the prior art antenna heretofore employed to produce a beam having the aforesaid width.
It is another object of this invention to render, in an aperture type antenna, the effective aperture dimension in the given plane, or the effective aperture area, relatively large compared respectively to the actual aperture dimension in said plane or the actual aperture area.
It is still another object of this invention to obtain, in one or more planes of action, a sharper or more narrow major directive lobe, lower minor lobes and more satisfactorily positioned null points, for an aperture type antenna having an aperture of given area, than heretofore secured in aperture type antennas having said given aperture area and, in particular, in aperture antennas having said given aperture area and in which the so-called cophasal uniform type of energization is utilized in said aperture.
In accordance with one embodiment of the invention the mouth aperture of a microwave horn designed for a mean wavelength is divided by a pair of fiat conductive members or partitions into three small cells each having a dimension or span in a given plane or radio action which is small, for example a quarter wavelength, relative to one-half of said wavelength. Preferably, but not necessarily, the spacing, in the horn mouth aperture, betweenthe front edges of the flat partitions is such as to render the cell areas or more specifically the aforesaid cell dimensions equal. The partitions extend toward the horn throat aperture and the spacing between the back edges of the partitions is such as to secure a predetermined non-uniform amplitude distribution for the waves propagated through the three cells. Also, a dielectric phase reverser is positioned between the two partitions, that is, in the central channel or cell so that the waves in the adjacent cells are oppositely phased. More specifically, the relative amplitude distribution is 4, 3, 4 and the phase distribution By reason of the subdivision of the main horn aperture into three small cells, and the use of the above-described amplitude and phase distributions, the beam width produced is exceedingly narrow, as compared with that produced by the aforesaid horn, with the conductive members and the phase reverser omitted. Since the aperture antennas of the prior art are classified as highly directive devices, the aperture antenna of the invention may, for convenience, be classified as super-directive.
The invention will be more fully understood from the following specification taken in conjunction with the drawing on which like characters denote elements of similar function and on which:
Fig. 1 is a perspective view and Fig. 2 is a sectional partial plan view of one embodiment of the invention;
Fig. 3 is a diagram used for explaining the invention;
Fig. 4 is a sectional partial plan view of a slightly different embodiment of the invention;
Fig. 5 is a perspective view of still another embodiment of the invention, and
Fig. 6 is a diagram used in explaining the embodiment of Fig. 5.
Referring to Figs. 1 and ,2, there is shown a microwave system I which comprises a sectoral horn 2 connected to a translation device 3 by means of a rectangular guide 4. The sectoral horn comprises the parallel wall members 5 and 6, the flared wall members 1 and 8. Numerals 9 and lil denote respectively the mouth or main antenna aperture and the throat a erture. A pair of diverting conductive members or partitions H and !2 of negligible thickness are positioned perpendicular to the parallel walls 5 and 6 and form therewith thethree passages or channels I3, is and i5. Numerals l6 and Il denote respectively the front and back edges of partitions H and 12. In the plane l8 of radio action perpendicular to the fiared horn Walls 5 and 6, the front edges it of members H and 52 are spaced equal distances h from each other and from the flared horn walls .5 and 6, and form with the front .elges IQ of the horn Walls 5 and 6 the three antenna cells 2%, 2| and 2 2 having equal areas. The back edges ll of the partitions H and !2 are spaced apart a distance a; and each partition is spaced a distance I) from the adjacent horn wall. The Width or span h of each cell is small relative to one-half the operating wavelength as, for example, a quarter wavelength; and the spacings a and b are also each small relative to one-half the minimum operating wavelength. The spacing a determines the amplitude of the wave in the middle channel It relative to the equal amplitudes .of the waves in the side channels l3 and i5 and, in the three-channel system of Figs. '1 and 2, the spacing at is smaller than the distance D and i selected so that the amplitude distribution in channels i3, I s and l5 and, more particularly, in cells 20, 24 and .22 is .respectively 4, 3, 4. If the electric polarization of the waves is perpendicular to the partitions H and 12 the dimensional ratio (1/1) is directly proportional tc the amplitude ratio 3/4 for the adjacent cells 2 I, 20 or 2|, 22,.inasmuch as the amplitude distribution in the throat aperture it? in the plane of the electric polarization is uniform. 0n the other hand if the electric polarization is parallel to partitions H and I2 the ratio a/b is not directly proportional to the aforesaid amplitude ratio 3/4, since in a plane perpendicular to the electric polarization the amplitude distribution in the throat aperture i0 is sinusoidal. Numeral 23 denotes a dielectric phase reverser positioned in channel l4 between and contacting the partitions I l and l2. A dielectric phase reverser suitable for use in this system is disclosed in Patent 2,405,992 granted to E. Bruce. The reverser 23 has-a critical length L such that the wave component, propagated through the middle channel 1 t and having the mean or given operating wavelength, isdelayed 180 degrees relative tothe component propagated through either of the side channels I3 and 55, as indicated by the signs associated respectively with channels I3,
is and [5.
In operation, assuming device 3 is a transmitter, waves are supplied by device 3 over guide 4 to the throat aperture Id of the horn and thence through the distinct channels l3, M and IE to t e radiating cells 2%, 2A :and 22. .As explained above, the waves emitted by cells 21,122 and 23 have a non-uniform amplitude distribution, namely, 4, 3, 4 and the Wave components emitted by cell 2| are phased opposite to the waves emitted by cells 253 and 22. By reason of the aforesaid amplitude and phase distributions, and especially by reason of the fact that the dimension '71. :of each cell is small compared to one-half of the given or mean wavelength, an optimum directive pattern in the plane i8 is obtained. More specifically, as compared to the directive pattern of the horn 2 obtained when the partitions H and !2 and the phase reverser .23 are omitted and the amplitude distribution across the horn mouth aperture is uniform, the pattern of the structure shown in Figs. 1 and .2 is more satisfactory in that it contains an exceedingly narrow major lobeandlow minor lobesthe minor lobe level being one ninth of the major lobe. Stated differently, the beam or major lobe obtained for the sectionalized horn of Figs. 1 and 2 corresponds to that secured for a non-sectionaliZed horn having a mouth aperture area much greater than the area of the actual mouth aperture 9 of horn 2. Thus, as illustrated schematically in Fig. 3, the effect of inserting the partition Ii and I2 and the phase reverser 23 in the horn 2, and judiciously selecting the amplitude distribution, is to increase the horn aperture span, in the plane l8, from the relatively small actual dimension of 3. h, neglecting the thickness of the partitions H and I2, to the relatively lar e dimension H, for the hypothetical horn comprising the walls 24 and 25.
In reception, the converseoperation is obtained by reason of the theorem of reciprocity. While the sectional-ized horn 2 comprises a one-dimension linear array of only three cells spaced alon a direction in the plane .18, any practical number of cells as, for example, several :hundredrmay be utilized in the one-dimension array. for a fivecell linear array the phase and amplitude distributions should be +0.43, .057, +1.0, -5
+0.43, the amplitude distribution being symmetgiven by H. J. Riblet on page 491 ina discussion of the article A Current Distribution for Broad Side Arrays Which Optimizes the Relationship Between Beam Widths and Side Lobe Level by C. L. Dolph, Proceedings I. R. E., May 1947, page 489, for the righthandhalf of a hypothetical linear array of spaced elements, the term at representin the center antenna .element. Thus, .for a three-element linear array having elements spaced a quarter wavelength apart corresponding to the cell spacing in the born 2 of Figs. 1 and 2, the amplitude distribution obtained from the above expression, namely 5.5, 1.0 and 5.5 is comparable to the 4, 3, 4 distribution employed in the horn of Figs. ,1 and 2. Assuming now that 5. the cell spacing h in the horn 2 is an eighth of a wavelength, the distribution, as determined experimentally, should be 0.63, 1.0, and 0.63, and this distribution is substantially the same as the distribution 0.68, 1.0, 0.68 obtained from the above-mentioned expression for an array using one-eighth wavelength spacing. It may be noted that both of the amplitude distributions given above, for the eighth wavelength spacing array,
are substantially the same a the distribution 0.645, 1, 0.645 corresponding to the distribution 1, 1.55, 1 given in Fig. 1 of Patent 2,066,874 to O. Bohm et al.
The embodiment illustrated by Fig. 4 is similar to that illustrated by Figs. 1 and 2, the main difference being that the metallic partition members in Fig. 4 are parallel instead of diverging. Numerals 26 and 2'! denote copper foil members corresponding to the rigid metallic partitions II and I2 and attached to the parallel fiat surfaces of the dielectric phase reverser 23. The thickness of the assembly comprising the dielectric reverser and copper foil members is chosen so as to obtain the correct dimensions a and b and for securing the desired amplitude distribution 4, 3, 4. As shown on the drawing the spacings between the centers 28 of the cells 20, 2| and 22 are equal, as is the case in the horn of Figs. 1 and 2. In operation, the sectionalized horn of Fig. 4 emits or receives waves in substantially the same optimum manner as the sectionalized horn of Figs. 1 and 2.
Referring to Fig. 5, there is shown a microwave system 29 comprising a pyramidal horn 30 having a pair of walls 3| and 32 flared in the vertical plane and the pair of walls 33 and 34 flared in a plane perpendicular to the first-mentioned plane. As shown on the drawing, the horn is sectionalized to form a two-dimension array of cells. Thus, the metallic members 35 divide the horn into nine shielded channels 36 and the horn mouth aperture 9 into nine square cells 3?, 38, 39, 40, 4|, 42, 43, 44 and 45 arranged in three horizontal tiers 46, 4'1 and 48 and in three vertical stacks 49, 50 and The horizontal dimension 7!. and the vertical dimension 2; of each cell are small compared to a half wavelength. Considering any pair of channels in each horizontal tier, or in each vertical stack, a phase reverser 23 is included in only one of the two adjacent channels. The metallic partition members 35 diverge from back to front in both planes, the front edges of these members being spaced equally in both planes and the back edges being spaced so as to produce the two-dimensional amplitude distribution shown in Fig. 6. Thus, the center cell 4| has a relative amplitude of 3 and a positive phase, the corner cells 31, 39, 43 and 45 each have a relative amplitude of 16/3 and a positive phase, and the remaining intermediate side cells 38, 40, 42 and 44 each have a relative amplitude of 4 and a negative phase. With this distribution, in the horizontal plane, the effective amplitude distribution is 20/3, 15/3, 20/3, that is 4, 3, 4 which is the algebraic addition of the amplitudes in each horizontal tier. Similarly in the vertical plane, the effective amplitude distribution is 20/3, 15/3, 20/3, that is, 4, 3, 4 obtained by the algebraic addition of the amplitudes in each ver tical stack. Hence the amplitude and phase dis tributions are optimum for both planes and the resulting directive patterns in the two planes, and in general the directive characteristic considered in the solid, are the optimum.
While the invention has been specifically de- 6: scribed in connection with aperture antennas of the horn type it may be utilized in connection with other types of aperture antennas such as lenses, reflectors and diffractors. Also, if desired, in horn systems utilizing a relatively large :humber of cells compared to the number employed in the embodiments described herein, the four horn walls may be omitted and a cellular structure comprising open channels or cells and phase shifting channels or cells may be positioned at an appreciable distance in front of the actual horn aperture. similarly, in the other types of aperture antennas mentioned above, a cellular structure corresponding to the cells 31-45 and comprising antiphased adjacent cells may be spaced from the opening of the reflector or the face of the lens or diffractor.
Although the invention has been explained in connection with certain embodiments, it is to be understood that it is not to be limited to the embodiments described inasmuch as other apparatus may be successfully employed in practicing the invention. In particular, in place of the dielectric phase changer, other types of phase changers, such as metallic delay or metallic advance shifters may be employed in practicing applicants invention.
What is claimed is:
1. An aperture antenna having a given linear aperture dimension, and means for increasing for a given wavelength the effective value of said given dimension, comprising a pair of conductive members positioned in said aperture and forming with the aperture boundary at least three parallelcells having collinear dimensions, each of said collinear dimensions being small relative to one-half of said wavelength, said pair of conductive members being at one end contiguous to and extending inwardly from the energy delivering aperture of said antenna, said conductive members being positioned with respect to said aperture to direct more energy to each of the outer cells than to the central cell. and a phase reverser positioned in the central cell, only.
2. A sectionalized aperture antenna for waves having a given wavelength comprising a plurality of conductive members positioned in the aperture of said antenna and forming a plurality of antenna cells, including a central cell and a plurality of outer cells, the dimensions of each cell in a given plane being small relative to one-half of said wavelength, and a phase changer posi tioned in one only of each pair of adjacent cells said antenna cells being formed contiguous to and extending inwardly from the energy delivering aperture of said antenna, said conductive elements being positioned within said aperture to direct more energy to each of the outer cells than to the central cell.
3. In combination, a pyramidal horn for a wave of a given wavelength having four similarly flared Walls and a square mouth aperture, a first set of flat metallic members positioned perpendicularly to one pair of opposite horn walls and a second set of fiat metallic members positioned perpendicularly to the other set of opposite horn walls, each of said flat members having front and back edges, said four horn walls and the front edgesof all of said members forming a square array of square antenna cells, including a central cell and a plurality of outer cells, the side dimension of each cell being small relative to one-half of said wavelength, a plurality of phasing reversers, one of said reversers 7 being positioned in one-only :01 each pair of adjacent cells said partitions being positioned with respect to the mouth :aperture of said horn Lto direct more energy to :each of said outer cells than to the 'centrai cell of said array.
References Cited in the file of this patent UNITED STATES PATENTS Number Name Date 2,129,669 Bowen Sept. 13, 1938 2,206,683 Wolfi July 2, 1940 2,415,807 Barrow Feb. 18, 1947 Number Number 1 Name Date Whinnery June 110, I947 Tawney Mar. 9, I948 Devore V v Aug. 23, 1949 Alvarez Aug. 130, 1949 Lawson July 2'4, "1950* Afiel Aug. '12, 1952 FOREIGN PATENTS Country Date Great Britain Mar. 16, 1-948
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Cited By (16)

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US2946999A (en) * 1957-12-16 1960-07-26 Melpar Inc Constant beamwidth horn antenna
US3045156A (en) * 1958-07-03 1962-07-17 Itt Servosystem including quadrature signal gate
US3046550A (en) * 1959-04-17 1962-07-24 Telefunken Gmbh Internal dielectric means for equalization of patterns due to perpendicular components of circularly polarized waves
US3146453A (en) * 1959-08-24 1964-08-25 Deco Electronics Inc Shortened horn antenna with multiple phased feed
US3205501A (en) * 1959-10-01 1965-09-07 Gen Electric Closely spaced stocked waveguide antenna array employing reciprocal ridged wageguide phase shifters
US3218580A (en) * 1963-09-12 1965-11-16 Zanichkowsky Martin Waveguide power dividing elements
US3500422A (en) * 1966-11-03 1970-03-10 Us Navy Sub-array horn assembly for phased array application
US4667205A (en) * 1983-02-22 1987-05-19 Thomson-Csf Wideband microwave antenna with two coupled sectoral horns and power dividers
US4689630A (en) * 1983-06-23 1987-08-25 Contraves Italiana S.P.A. Multi-shaped-beam reflector antenna
US4965869A (en) * 1987-06-23 1990-10-23 Brunswick Corporation Aperture antenna having nonuniform resistivity
EP1993166A1 (en) * 2007-05-14 2008-11-19 Saab AB Antenna device
US20150022399A1 (en) * 2002-08-20 2015-01-22 Astronics Aerosat Corporation Communication system with broadband antenna
US20170288291A1 (en) * 2015-06-03 2017-10-05 Mitsubishi Electric Corporation Horn antenna
US10297924B2 (en) * 2015-08-27 2019-05-21 Nidec Corporation Radar antenna unit and radar device
US10992052B2 (en) 2017-08-28 2021-04-27 Astronics Aerosat Corporation Dielectric lens for antenna system
US11929552B2 (en) 2016-07-21 2024-03-12 Astronics Aerosat Corporation Multi-channel communications antenna

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US2946999A (en) * 1957-12-16 1960-07-26 Melpar Inc Constant beamwidth horn antenna
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US3046550A (en) * 1959-04-17 1962-07-24 Telefunken Gmbh Internal dielectric means for equalization of patterns due to perpendicular components of circularly polarized waves
US3146453A (en) * 1959-08-24 1964-08-25 Deco Electronics Inc Shortened horn antenna with multiple phased feed
US3205501A (en) * 1959-10-01 1965-09-07 Gen Electric Closely spaced stocked waveguide antenna array employing reciprocal ridged wageguide phase shifters
US3218580A (en) * 1963-09-12 1965-11-16 Zanichkowsky Martin Waveguide power dividing elements
US3500422A (en) * 1966-11-03 1970-03-10 Us Navy Sub-array horn assembly for phased array application
US4667205A (en) * 1983-02-22 1987-05-19 Thomson-Csf Wideband microwave antenna with two coupled sectoral horns and power dividers
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US20150022399A1 (en) * 2002-08-20 2015-01-22 Astronics Aerosat Corporation Communication system with broadband antenna
US9293835B2 (en) * 2002-08-20 2016-03-22 Astronics Aerosat Corporation Communication system with broadband antenna
EP1993166A1 (en) * 2007-05-14 2008-11-19 Saab AB Antenna device
US7710339B2 (en) 2007-05-14 2010-05-04 Saab Ab Antenna device
US20090021440A1 (en) * 2007-05-14 2009-01-22 Saab Ab Antenna device
US20170288291A1 (en) * 2015-06-03 2017-10-05 Mitsubishi Electric Corporation Horn antenna
US10027031B2 (en) * 2015-06-03 2018-07-17 Mitsubishi Electric Corporation Horn antenna device
US10297924B2 (en) * 2015-08-27 2019-05-21 Nidec Corporation Radar antenna unit and radar device
US11929552B2 (en) 2016-07-21 2024-03-12 Astronics Aerosat Corporation Multi-channel communications antenna
US10992052B2 (en) 2017-08-28 2021-04-27 Astronics Aerosat Corporation Dielectric lens for antenna system

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