US2981951A - Broadband antenna - Google Patents
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- US2981951A US2981951A US839504A US83950459A US2981951A US 2981951 A US2981951 A US 2981951A US 839504 A US839504 A US 839504A US 83950459 A US83950459 A US 83950459A US 2981951 A US2981951 A US 2981951A
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q11/00—Electrically-long antennas having dimensions more than twice the shortest operating wavelength and consisting of conductive active radiating elements
- H01Q11/02—Non-resonant antennas, e.g. travelling-wave antenna
- H01Q11/10—Logperiodic antennas
Definitions
- the zig-zag antenna of Cummings comprises a'wire bent into a saw-tooth configuration lying in a plane and extending outwardly from a'ground plane or counterpoise. The shape results from the projection of a straight helix on a plane.
- the zig-zag antenna is compactand simple, and produces an end-fire beam which is fairly stable over a bandwidth of approximately 1-5 "of the center frequency of the antenna.
- the present invention is concerned with improvement in the bandwidth of the zig-zag antenna.
- the area under each tooth or element of the zig-zag antenna is filled with conducting material, and a twin wire transmission line, located close to the plane of the antenna, extends over its full length.
- the structure then, consists of two sets of triangular radiator plates on opposite sides of. the an-- Jr., Santa Clara, Calif and Jimmy' Y of a predetermined tenna axis, each plate being ofif-set from the axially adjacent plate.
- the consequence of filling the teeth of the antenna is to increase the couplingwith the transmission line and to lowerthe Q of each element.
- the ground plane or counterpoise is no longer necessary.
- the antenna is then tapered, that is, the physical dimensions and spacing of the plates and of the transmission line are uniformly decreased in accordance with a predetermined ratio.
- the transmission line is located asymmetrically on the antenna. :This latter an- 7 where m designates any radiating element,
- a principal object of this invention is the provision of a broadband unidirectional end-fire antenna.
- Another object is the provision of a compact antenna having a geometrically simple configuration and which, therefore, is relatively inexpensive to manufacture.
- a more specific object is the provisionof an antenna of the foregoing type which is conveniently and eflicient- 1y matched to theinput feed line over a broad range of frequencies.
- a further object is the provision of a feed system for a zig-zag antenna which permits the antenna to be used without a ground plane, artificial ground, or counter-- polse.
- Figure 1 is a side elevation of tenna with a twin wire feed system illustrated schematically;
- Figure 2 is a vertical section taken on line 2 2 of Figure 1;
- Figure 3 is a view similar to Figure 1 showing a twin 3 a taperedzig-zag an- 4.
- wire feed line comprising a coaxial cable and a coextensive conductor connected to the center conductor of the cable;
- Figure 4 is an enlarged view of a part of Figure 3';
- Figure 5 is a section taken on line 5-5 of Figure 4;
- Figure 6 is a side elevation of a tapered zig-zag anice tenna with the twin wire feed line disposed asymmetri- 14 are in a plane containing the antenna axis and all are conductors Whereas the central member 12, which functions as a supporting boom,".
- member 12 and all 'of ele- 14 comprise a unitary structure, preferably cut single sheet of conducting material.
- Each element 14 is triangular in shape, is axially spaced from the adjacent element, whether on the same or opposite side of the antenna axis, and has physical dimen-' sions that dilfer from those of the other elements. More particularly, the physical dimensions and spacings of the elements decrease from one end of the antenna, the left end as viewed, to the other in progressive increments ratio.
- rn+1 fi i n-i Lm Ln constant and m+1" is the adjacent larger element.
- the decrease in size, called tapering, permits operation of the antenna over an indfinitely broad frequency range.
- the array has a-taper angle designated as a.
- the Q of the indivdual elements which is a measure of the sharpness of resonance of the elements, must be a value such that the overlap of excitation gives a smooth transition as the wavelength changes.
- a low value of Q, which provides the desired smoothness of transition, is attained, in accordance with the invention, by coupling the transmission lines to the relatively broad conducting area of each radiating element.
- the tapered antenna is energized by a twin wire trans- I mission line comprising conductor-s16 and 18 which ex:
- these conductors are symmetrically arranged about the axis A of the antenna, as shown in Figures 1 and 3.
- the conductors are slanted to form acute angles with the antenna axis and converge toward each other from the left end of the antenna, as viewed, for connection to input leads 20 from an excitation source 21, such as a transmitter.
- an excitation source 21 such as a transmitter.
- the angle 20 of convergence of the conductors 16 and 18 is selected so as to optimize the endfire patterns over the operating frequency range.
- an angle 20 was used which resulted in a spacing between the conductors of approximately onefifth the length of an element 14 at the point of crossover of the conductors with that element.
- Such an antenna produced unidirectional end-fire patterns that were uniform over a bandwidth of approximately to l, the average E-plane beamwidth being approximately 53.
- the symmetrically fed antenna is sensitive to the spacing of the twin lines which makes diflicult the repeatability of performance of the antenna.
- the twin wire feed line conveniently takes the form of a coaxial cable generally indicated at 25 and a solid conductor 26, both converging toward each other and arranged symmetrically about the axis A of antenna in close proximity to the radiating elements 14'.
- the antenna 10' is substantially identical to the antenna 10 of Figure 1.
- the inner conductor 27 of cable is connected by jumper lead 28 to conductor 26, see Figure 4, so that the latter conductor becomes essentially an extension of the inner conductor.
- the outer conductor 29 of the coaxial cable constitutes one of the twin wire feed lines while the conductor 26 constitutes the other of such lines.
- This form of transmission line is not only eifective in energizing the radiating elements of the antenna, but also affords a convenient means of matching the impedance of the antenna over a wide range of frequencies to an input coaxial cable, not shown, which is connected to cable 25 at the large end of the antenna.
- the feed lines are coupled to the radiating elements electromagnetically but are physically insulated from the elements by suitable means.
- the cable 25 and conductor 26 are secured to the antenna body by brackets 30 made of dielectric material and secured in place by screws 31, see Figures 4 and 5.
- twin wire feed lines consisting of the outer conductor of coaxial cable 36, and conductor 37, are offset vertically from the axis A, as shown. Cable 35 and conductor 37 converge toward each other in the direction toward the smaller end of the antenna where jumper 39 connects inner conductor 38 of the cable to conductor 37.
- Each of these tapered twin lines traverses the radiating elements 14" which are located on one side only of the axis A.
- a pair of insulator plates 40 and 41 are secured to each radiating elements and on opposite sides of the feed lines. Screws 42 hold the plates to the antenna.
- the feed lines therefore are physically insulated from each other and from the antenna proper but are electromagnetically coupled to the several radiating elements.
- a broadband end-fire antenna having an axis and comprising a plurality of triangularly shaped conducting elements arranged in a common plane with the apex of each element remote from the axis, said elements being axially spaced apart with successive elements extending on opposite sides of said axis, the physical dimensions of successive elements decreasing toward one end of the antenna in' accordance with a predetermined ratio, and means for feeding electromagnetic wave energy to said conducting elements comprising a pair of conducting lines disposed adjacent to said elements for the full length of the antenna and converging toward each other in a direction toward said one end of the antenna, said lines being electromagnetically coupled to said elements, and input means connected to said lines for energizing said elements.
- a broadband end-fire antenna having an axis and comprising a plurality of conducting elements arranged in a single plane, said elements being arranged in succession along the axis with successive elements extending on opposite sides only of said axis, the physical dimensions of successive elements decreasing toward one end of the antenna in accordance with a predetermined ratio, and means for feeding electromagnetic wave energy to said conducting elements comprising a coaxial cable and a conducting member disposed adjacent to said elements for the full length of the antenna and converging toward 'each other in a direction toward said one end of the antenna, said cable having an outer conductor and an inner conductor, said inner conductor being electrically connected to said conducting member at said one end of the antenna, and input means connected to said coaxial cable for energizing said elements.
- means for feeding electromagnetic wave energy to said conducting elements comprising a pair of axially extending conducting lines disposed symmetrically about said axis and lying adjacent to and spaced from said elements for the full length of the antenna and converging toward each other in a direction toward said one end of the antenna, said lines being electromagnetically coupled to said elements, and input means connected to said lines for energizing said elements.
- An antenna having an axis and comprising a series of triangularly shaped conducting elements lying in a common plane and arranged successively along said axis with axially adjacent elements extending in opposite directions from said axis,the dimensions of the series of elements tapering from a maximum at one end of the antenna to a minimum at the other end, and means for feeding electromagnetic wave energy to said conducting elements com-prising a pair of laterally spaced conducting lines disposed adjacent to said series of elements whereby to be electromagnetically coupled thereto, said lines converging toward each other in a direction toward said one end of the antenna with both lines being located on the same side of said axis, and input means connected to said lines for energizing said elements.
- An antenna having an axis and comprising a series of triangularly shaped conducting elements lying in a single plane and arranged successively along said axis with axially adjacent elements extending in opposite directions from said axis, the dimensions of the series of elements tapering from a maximum at one end of the antenna to a minimum at the other end, and means for feeding electromagnetic wave energy to said conducting elements comprising a coaxial cable and a coextensive conducting member laterally spaced from the cable, said 1 cable and said member being disposed adjacent to said series of elements and converging toward each other in a direction toward said other end of the antenna, said cable having an outer conductor and an inner conductor, said inner conductor being directly electrically connected to said conducting member at said other end of the antenna, and input means connected to said cable at saidv one end of the antenna for energizing said elements.
- a broadband antenna having an axis and comprising a series of triangularly shaped conducting elements lying in a common plane and arranged successively along said axis with axially adjacent elements extending in opposite directions from said axis, the dimensions of the series of elements tapering from a maximum-at one end of the antenna to a minimum at the other end, and means for feeding electromagnetic wave energy to said conducting elements comprising a coaxial cable and a coextensive conducting member, said cable and said member being closely spaced from said elements on the same side of said axis, said cable having an outer conductor and an inner conductor, said inner conductor being directly electrically connected to said member at said other end of the antenna whereby said outer conductor and said conducting member constitute twin wire feed lines, and input means connected to said cable at said one end of the antenna for energizing said elements.
- a broadband unidirectional tapered end-fire array having an axis and a plurality of radiating elements disposed in a single plane containing said axis, said elements comprising a series of conducting plates having a profile defined by the projection of a tapered helix on a plane whereby the plates are triangularly shaped and with successive plates projecting alternately from opposite sides of the axis, and spaced twin conducting lines traversing the series of plates and located adjacent to and spaced from the plane of the plates, the physical dimensions and spacing of said elements and the spacing of said lines decreasing from one end of the array to the other in progressive increments of a predetermined ratio.
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Description
April 1961 A. F. WICKERSHAM, JR, ETAL 2,981,951
BROADBAND ANTENNA Filed Sept. 11, 1959 2 Sheets-Sheet 1 INVENTORS ARTHUR F. WICKERSHAM JR. JIMMY E. M DOWELL m j ATTORNEY April 1961 A. F. WICKERSHAM, JR,, EIAL 2,981,951
BROADBAND ANTENNA 2 Sheets-Sheet 2 Filed Sept. 11, 1959 L! V EN TORS ARTHUR E WICKERSHAM JR.
JIMMY E. M DOWELL United States Patent BROADBAND ANTENNA Arthur F. Wickersham,
E. McDowell, Bessemer, Ala., assignors to Sylvama Electric Products Inc.,. a corporation of Delaware Filed Sept. 11, '1959, Ser. No. 839,504
. 9 Claims. (Cl. 343-807) The zig-zag antenna of Cummings comprises a'wire bent into a saw-tooth configuration lying in a plane and extending outwardly from a'ground plane or counterpoise. The shape results from the projection of a straight helix on a plane. The zig-zag antenna is compactand simple, and produces an end-fire beam which is fairly stable over a bandwidth of approximately 1-5 "of the center frequency of the antenna. The present invention is concerned with improvement in the bandwidth of the zig-zag antenna.
In accordance with this invention, the area under each tooth or element of the zig-zag antenna is filled with conducting material, and a twin wire transmission line, located close to the plane of the antenna, extends over its full length. The structure, then, consists of two sets of triangular radiator plates on opposite sides of. the an-- Jr., Santa Clara, Calif and Jimmy' Y of a predetermined tenna axis, each plate being ofif-set from the axially adjacent plate. The consequence of filling the teeth of the antenna is to increase the couplingwith the transmission line and to lowerthe Q of each element. The ground plane or counterpoise is no longer necessary. The antenna is then tapered, that is, the physical dimensions and spacing of the plates and of the transmission line are uniformly decreased in accordance with a predetermined ratio. In one form, the transmission line is located asymmetrically on the antenna. :This latter an- 7 where m designates any radiating element,
tenna. produced satisfactory results over a 7 to 1 bandwidth, which range readily can be extended simply by increasing the length of the antenna. t r
A principal object of this invention is the provision of a broadband unidirectional end-fire antenna.
Another object is the provision of a compact antenna having a geometrically simple configuration and which, therefore, is relatively inexpensive to manufacture.
A more specific object is the provisionof an antenna of the foregoing type which is conveniently and eflicient- 1y matched to theinput feed line over a broad range of frequencies. g
A further object is the provision of a feed system for a zig-zag antenna which permits the antenna to be used without a ground plane, artificial ground, or counter-- polse.
These and other objects of my invention will become apparent from the following description of preferred embodiments thereof, reference being had to the accompanying drawings in which:
Figure 1 is a side elevation of tenna with a twin wire feed system illustrated schematically;
Figure 2 is a vertical section taken on line 2 2 of Figure 1;
, Figure 3 is a view similar to Figure 1 showing a twin 3 a taperedzig-zag an- 4.
and economy of construction,
2,981,951 Patented Apr. 25, 1.961
wire feed line comprising a coaxial cable and a coextensive conductor connected to the center conductor of the cable; 7
Figure 4 is an enlarged view of a part of Figure 3'; Figure 5 is a section taken on line 5-5 of Figure 4; Figure 6 is a side elevation of a tapered zig-zag anice tenna with the twin wire feed line disposed asymmetri- 14 are in a plane containing the antenna axis and all are conductors Whereas the central member 12, which functions as a supporting boom,".
maybe a conductor or a non-conductor. For simplicity member 12 and all 'of ele- 14 comprise a unitary structure, preferably cut single sheet of conducting material.
ments from a Each element 14 is triangular in shape, is axially spaced from the adjacent element, whether on the same or opposite side of the antenna axis, and has physical dimen-' sions that dilfer from those of the other elements. More particularly, the physical dimensions and spacings of the elements decrease from one end of the antenna, the left end as viewed, to the other in progressive increments ratio. Thus the lengths L L L .L of the elements, the spacing S S S S n between elements, and the mean width W W W W of the elements, wherein n is the total 11 ber of elements, uniformly decrease in magnitude in accordance with the predetermined ratio. Stated different 1y, rn+1 fi i n-i Lm Ln constant and m+1"is the adjacent larger element. The decrease in size, called tapering, permits operation of the antenna over an indfinitely broad frequency range. The array has a-taper angle designated as a.
' This broadband operation will be better understood by a brief explanation of the theory of operation of the tapered antenna. Assume that the lentgh L, of the largest radiating element 14 is equal to ).,/2, where A approximately corresponds to the largest operating Wavelength in the band, and L approximately is equal to [2 where A corresponds to the smallest operating wave-' length. The bandwidth of the antenna then is indicated by the ratio' A i/A It is clear that for an intermediate wavelength A, less than a some radiating element in the structure will have the same lentgh to wavelength ratio as the active element at any other frequency within the bandwidth. At half-wavelengths which fall between two adjacent elements, the total radiation must be a sum of the excitation of elements operating at a frequency displaced from their resonant lengths. This suggests, then,'that the Q of the indivdual elements,which is a measure of the sharpness of resonance of the elements, must be a value such that the overlap of excitation gives a smooth transition as the wavelength changes. A low value of Q, which provides the desired smoothness of transition, is attained, in accordance with the invention, by coupling the transmission lines to the relatively broad conducting area of each radiating element.
The tapered antenna is energized by a twin wire trans- I mission line comprising conductor-s16 and 18 which ex:
a vertical section taken on line 88 of 14 over the length of the antenna.
tend the full length of the antenna close to but spaced from the radiating elements 14. In one form of the invention, these conductors are symmetrically arranged about the axis A of the antenna, as shown in Figures 1 and 3. The conductors are slanted to form acute angles with the antenna axis and converge toward each other from the left end of the antenna, as viewed, for connection to input leads 20 from an excitation source 21, such as a transmitter. It will be understood, of course, that the antenna may be used for receiving purposes as well as transmitting purposes, the latter being described simply for convenience as illustrative of one application of the antenna. The angle 20 of convergence of the conductors 16 and 18 is selected so as to optimize the endfire patterns over the operating frequency range. By way of example, in one model that was built and successfully operated, an angle 20 was used which resulted in a spacing between the conductors of approximately onefifth the length of an element 14 at the point of crossover of the conductors with that element. Such an antenna produced unidirectional end-fire patterns that were uniform over a bandwidth of approximately to l, the average E-plane beamwidth being approximately 53. The symmetrically fed antenna, however, is sensitive to the spacing of the twin lines which makes diflicult the repeatability of performance of the antenna.
In the form of the invention shown in Figures 3 to 5, the twin wire feed line conveniently takes the form of a coaxial cable generally indicated at 25 and a solid conductor 26, both converging toward each other and arranged symmetrically about the axis A of antenna in close proximity to the radiating elements 14'. With the exception of these feed lines, the antenna 10' is substantially identical to the antenna 10 of Figure 1. At the small end of the antenna, to the right as viewed in Figure 3, the inner conductor 27 of cable is connected by jumper lead 28 to conductor 26, see Figure 4, so that the latter conductor becomes essentially an extension of the inner conductor. The outer conductor 29 of the coaxial cable constitutes one of the twin wire feed lines while the conductor 26 constitutes the other of such lines. This form of transmission line is not only eifective in energizing the radiating elements of the antenna, but also affords a convenient means of matching the impedance of the antenna over a wide range of frequencies to an input coaxial cable, not shown, which is connected to cable 25 at the large end of the antenna.
The feed lines are coupled to the radiating elements electromagnetically but are physically insulated from the elements by suitable means. As shown in Figures 3 to 5, the cable 25 and conductor 26 are secured to the antenna body by brackets 30 made of dielectric material and secured in place by screws 31, see Figures 4 and 5.
In order to overcome the aforementioned sensitivity of the antenna to the location and the spacing of the twin wire feed lines, the latter are located in a laterally ofiset relation with respect to the axis of the antenna, as shown in Figures 6 to 8. Antenna 10", with radiating elements 14" projecting from opposite sides of antenna axis A and tapering in one direction, is substantially the same .as antenna 10 described above. However, the twin feed lines consisting of the outer conductor of coaxial cable 36, and conductor 37, are offset vertically from the axis A, as shown. Cable 35 and conductor 37 converge toward each other in the direction toward the smaller end of the antenna where jumper 39 connects inner conductor 38 of the cable to conductor 37. Each of these tapered twin lines traverses the radiating elements 14" which are located on one side only of the axis A. In order mechanically to hold cable 36 and conductor 37 in position on the antenna, a pair of insulator plates 40 and 41 are secured to each radiating elements and on opposite sides of the feed lines. Screws 42 hold the plates to the antenna. The feed lines therefore are physically insulated from each other and from the antenna proper but are electromagnetically coupled to the several radiating elements. By simply loosening screws 42, adjustment of the spacings of the feed lines from each other and from the axis A of the antenna to optimize performance and improve impedance matching is readily accomplished.
By way of example, an antenna of the type shown in Figure 6 having the following dimensions and characteristics, has been built and successfully tested:
Changes, modifications and improvements to the abovedescribcd embodiments of our invention may be made by those skilled in the art without departing from the precepts of the invention. The scope of the invention is defined in the appended claims.
We claim:
1. A broadband end-fire antenna having an axis and comprising a plurality of triangularly shaped conducting elements arranged in a common plane with the apex of each element remote from the axis, said elements being axially spaced apart with successive elements extending on opposite sides of said axis, the physical dimensions of successive elements decreasing toward one end of the antenna in' accordance with a predetermined ratio, and means for feeding electromagnetic wave energy to said conducting elements comprising a pair of conducting lines disposed adjacent to said elements for the full length of the antenna and converging toward each other in a direction toward said one end of the antenna, said lines being electromagnetically coupled to said elements, and input means connected to said lines for energizing said elements.
2. A broadband end-fire antenna having an axis and comprising a plurality of conducting elements arranged in a single plane, said elements being arranged in succession along the axis with successive elements extending on opposite sides only of said axis, the physical dimensions of successive elements decreasing toward one end of the antenna in accordance with a predetermined ratio, and means for feeding electromagnetic wave energy to said conducting elements comprising a coaxial cable and a conducting member disposed adjacent to said elements for the full length of the antenna and converging toward 'each other in a direction toward said one end of the antenna, said cable having an outer conductor and an inner conductor, said inner conductor being electrically connected to said conducting member at said one end of the antenna, and input means connected to said coaxial cable for energizing said elements.
3. A broadband end-fire antenna'ha'ving an axis and comprising a plurality of triangularly shaped conducting elements arranged in a common plane with the apex of each' element remote from the axis, said elements being arranged in succession along said axis with successive elements extending on opposite sides of said axis, the
physical dimensions of successive elements decreasing toward one end of the antenna in accordance with a predetermined ratio, and means for feeding electromagnetic wave energy to said conducting elements comprising a pair of axially extending conducting lines disposed symmetrically about said axis and lying adjacent to and spaced from said elements for the full length of the antenna and converging toward each other in a direction toward said one end of the antenna, said lines being electromagnetically coupled to said elements, and input means connected to said lines for energizing said elements.
4. An antenna having an axis and comprising a series of triangularly shaped conducting elements lying in a common plane and arranged successively along said axis with axially adjacent elements extending in opposite directions from said axis,the dimensions of the series of elements tapering from a maximum at one end of the antenna to a minimum at the other end, and means for feeding electromagnetic wave energy to said conducting elements com-prising a pair of laterally spaced conducting lines disposed adjacent to said series of elements whereby to be electromagnetically coupled thereto, said lines converging toward each other in a direction toward said one end of the antenna with both lines being located on the same side of said axis, and input means connected to said lines for energizing said elements.
5. An antenna having an axis and comprising a series of triangularly shaped conducting elements lying in a single plane and arranged successively along said axis with axially adjacent elements extending in opposite directions from said axis, the dimensions of the series of elements tapering from a maximum at one end of the antenna to a minimum at the other end, and means for feeding electromagnetic wave energy to said conducting elements comprising a coaxial cable and a coextensive conducting member laterally spaced from the cable, said 1 cable and said member being disposed adjacent to said series of elements and converging toward each other in a direction toward said other end of the antenna, said cable having an outer conductor and an inner conductor, said inner conductor being directly electrically connected to said conducting member at said other end of the antenna, and input means connected to said cable at saidv one end of the antenna for energizing said elements.
6. The antenna according to claim 5 in which said cable and said conducting member are located on the same side of the antenna axis.
7. The antenna according to claim 5 with means for insulating said cable and said conducting member from said elements.
8. A broadband antenna having an axis and comprising a series of triangularly shaped conducting elements lying in a common plane and arranged successively along said axis with axially adjacent elements extending in opposite directions from said axis, the dimensions of the series of elements tapering from a maximum-at one end of the antenna to a minimum at the other end, and means for feeding electromagnetic wave energy to said conducting elements comprising a coaxial cable and a coextensive conducting member, said cable and said member being closely spaced from said elements on the same side of said axis, said cable having an outer conductor and an inner conductor, said inner conductor being directly electrically connected to said member at said other end of the antenna whereby said outer conductor and said conducting member constitute twin wire feed lines, and input means connected to said cable at said one end of the antenna for energizing said elements.
9. A broadband unidirectional tapered end-fire array having an axis and a plurality of radiating elements disposed in a single plane containing said axis, said elements comprising a series of conducting plates having a profile defined by the projection of a tapered helix on a plane whereby the plates are triangularly shaped and with successive plates projecting alternately from opposite sides of the axis, and spaced twin conducting lines traversing the series of plates and located adjacent to and spaced from the plane of the plates, the physical dimensions and spacing of said elements and the spacing of said lines decreasing from one end of the array to the other in progressive increments of a predetermined ratio.
References Cited in the file of this patent UNITED STATES PATENTS Wolfi Dec. 30, 1947 OTHER REFERENCES
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US839504A US2981951A (en) | 1959-09-11 | 1959-09-11 | Broadband antenna |
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US839504A US2981951A (en) | 1959-09-11 | 1959-09-11 | Broadband antenna |
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US2981951A true US2981951A (en) | 1961-04-25 |
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Cited By (13)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3056960A (en) * | 1959-08-31 | 1962-10-02 | Sylvania Electric Prod | Broadband tapered-ladder type antenna |
US3101474A (en) * | 1960-11-25 | 1963-08-20 | Sylvania Electric Prod | Log periodic type antenna mounted on ground plane and fed by tapered feed |
US3134979A (en) * | 1961-01-27 | 1964-05-26 | Granger Associates | Tapered ladder log periodic antenna |
US3181161A (en) * | 1961-06-09 | 1965-04-27 | Collins Radio Co | Horizontally polarized log periodic antenna over ground |
US3271775A (en) * | 1963-07-25 | 1966-09-06 | Andrew Corp | Vertically polarized log-periodic antenna |
US3308470A (en) * | 1961-01-27 | 1967-03-07 | Granger Associates | Tapered ladder log periodic antenna |
US3344431A (en) * | 1963-08-14 | 1967-09-26 | Channel Master Corp | Ultra-high-frequency antenna assembly and parasitic array therefor |
DE1275636B (en) * | 1963-02-13 | 1968-08-22 | Rohde & Schwarz | Cable for connecting the dipoles of a logarithmically periodic dipole antenna |
US4220956A (en) * | 1978-11-06 | 1980-09-02 | Ball Corporation | Collinear series-fed radio frequency antenna array |
US4907011A (en) * | 1987-12-14 | 1990-03-06 | Gte Government Systems Corporation | Foreshortened dipole antenna with triangular radiating elements and tapered coaxial feedline |
US5790082A (en) * | 1996-03-27 | 1998-08-04 | Podger; James Stanley | Double-delta log-periodic antenna |
JP2015076759A (en) * | 2013-10-09 | 2015-04-20 | 株式会社日立国際八木ソリューションズ | Logarithmic period type antenna, and processing method of logarithmic period type antenna |
WO2017142966A1 (en) * | 2016-02-16 | 2017-08-24 | Te Connectivity Corporation | Antenna system having a set of inverted-f antenna elements |
Citations (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2433804A (en) * | 1943-04-23 | 1947-12-30 | Rca Corp | Frequency-modulated pulse radio locating system |
-
1959
- 1959-09-11 US US839504A patent/US2981951A/en not_active Expired - Lifetime
Patent Citations (1)
Publication number | Priority date | Publication date | Assignee | Title |
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US2433804A (en) * | 1943-04-23 | 1947-12-30 | Rca Corp | Frequency-modulated pulse radio locating system |
Cited By (13)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3056960A (en) * | 1959-08-31 | 1962-10-02 | Sylvania Electric Prod | Broadband tapered-ladder type antenna |
US3101474A (en) * | 1960-11-25 | 1963-08-20 | Sylvania Electric Prod | Log periodic type antenna mounted on ground plane and fed by tapered feed |
US3134979A (en) * | 1961-01-27 | 1964-05-26 | Granger Associates | Tapered ladder log periodic antenna |
US3308470A (en) * | 1961-01-27 | 1967-03-07 | Granger Associates | Tapered ladder log periodic antenna |
US3181161A (en) * | 1961-06-09 | 1965-04-27 | Collins Radio Co | Horizontally polarized log periodic antenna over ground |
DE1275636B (en) * | 1963-02-13 | 1968-08-22 | Rohde & Schwarz | Cable for connecting the dipoles of a logarithmically periodic dipole antenna |
US3271775A (en) * | 1963-07-25 | 1966-09-06 | Andrew Corp | Vertically polarized log-periodic antenna |
US3344431A (en) * | 1963-08-14 | 1967-09-26 | Channel Master Corp | Ultra-high-frequency antenna assembly and parasitic array therefor |
US4220956A (en) * | 1978-11-06 | 1980-09-02 | Ball Corporation | Collinear series-fed radio frequency antenna array |
US4907011A (en) * | 1987-12-14 | 1990-03-06 | Gte Government Systems Corporation | Foreshortened dipole antenna with triangular radiating elements and tapered coaxial feedline |
US5790082A (en) * | 1996-03-27 | 1998-08-04 | Podger; James Stanley | Double-delta log-periodic antenna |
JP2015076759A (en) * | 2013-10-09 | 2015-04-20 | 株式会社日立国際八木ソリューションズ | Logarithmic period type antenna, and processing method of logarithmic period type antenna |
WO2017142966A1 (en) * | 2016-02-16 | 2017-08-24 | Te Connectivity Corporation | Antenna system having a set of inverted-f antenna elements |
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