US2893004A - Dual band antenna array - Google Patents
Dual band antenna array Download PDFInfo
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- US2893004A US2893004A US555097A US55509755A US2893004A US 2893004 A US2893004 A US 2893004A US 555097 A US555097 A US 555097A US 55509755 A US55509755 A US 55509755A US 2893004 A US2893004 A US 2893004A
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
- H05B3/00—Ohmic-resistance heating
- H05B3/62—Heating elements specially adapted for furnaces
- H05B3/64—Heating elements specially adapted for furnaces using ribbon, rod, or wire heater
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q5/00—Arrangements for simultaneous operation of antennas on two or more different wavebands, e.g. dual-band or multi-band arrangements
- H01Q5/40—Imbricated or interleaved structures; Combined or electromagnetically coupled arrangements, e.g. comprising two or more non-connected fed radiating elements
- H01Q5/48—Combinations of two or more dipole type antennas
- H01Q5/49—Combinations of two or more dipole type antennas with parasitic elements used for purposes other than for dual-band or multi-band, e.g. imbricated Yagi antennas
Definitions
- Thisv invention relates to linear antenna arrays, and more particularly to a single linear antenna array of the yagi type for operation at its fundamentalhalf wave length resonant dimension and at its corresponding three; half wavelength resonant dimension with substantial identity of its directional characteristicslf I e e
- a Present day television broadcasting in the United Statesand nanyipar'ts of the world is accomplished on two bands, 54-88 mo. and 174-216 mc.
- a half-wave dipole antenna for television reception designed to be resonant in the low VHF band and centered at 66 Inc.
- an antenna such as the half wave dipole has the familiar dipole radiation pattern in; volving a single forward lobe and substantially no backwardlobe, i f
- the urrent distribution curve of the same antenna at the threehalf-wave length resonant frequency has three half-wave current loops.
- the center half-wave current loop has an oppositerphase directionto the outer halfwave current, loops.
- the phase reversal of the current loop of the center halfwave section of the antennaat its three-half wave frequency results in a butterfly-shaped radiation pattern.
- the butterflyEshaped radiation patter-nt' is very undesirable for television reception because the forward lobe is almost cancelled and the maximum sensitivity is' lin't wo direetions'each at an angle of approximately 43 on either side of "the forward direction.
- the radiation pattern of the antenna may becorrected inthis way, to make itjuseful for unidirectional television reception on the high VHF band a'sfwell fasbnthe low VHF band.
- Theg ainffof'the antenna on th'e high'band is increased the forward lobe of the'hi'gh band radiation'pattern sharpened as ifjthree' separate' half-wave antennas are lined upin collinear "array; 1 I
- This antenna structure includes a complex of three driven elements to effect dual band operation.
- the system necessitates quarter-wave impedance matching stubs in each driven element termination to maintain a satisfactory impedance match on both high and low bands.
- the required interconnecting harness is cumbersome and critical as to adjustment and positioning with respect to the remainder of the antenna array.
- Another solution to the problem of reversing the phase of the center half-wave current loop at the third harmonic operation of a low-band TV (tele ison) receiving dipole involves the insertion of a quarter-wave stub element shaped like a folded dipole in each half of the driven element of the low-band antenna.
- the folded dipole shaped stub elements connecting the main elements of the dipole have alower Q than similarly used purely reactive stub elements. Thisnecessitates multiplication of driven elements to increase the antenna sensitivity.
- novel phase reversing means in association with a driven dipole to render'it effective for both low and high-band TV reception.
- the novel phase reversing means of the Weiss Patent is a parasitic (i.e., non-driven) dipole disposed in closely spaced parallel relationship with the driven dipole and being coextentive with approximately the central one- The effect of this parasitic element is to reverse the phase of the current in the central portion of the driven dipole when it is operating at or near its three half-wave resonant frequency.
- the principal object of the present invention is to pro vide a driven dipole having phase reversing means to render it responsive with similar directional character, istics in both the low and high television bands, and also having a parasitic array associated therewith which will enhance the gain of the driven dipole at low-band frefrequency.
- This means so associated with the'driven dipole may be a parasitic (non-driven) dipole that is closely spaced in front of the driven dipole, as disclosed and claimed by Weiss.
- the present invention involves an appropriate other parasitic element, for example, a low-band director, and a parasitic phase reversing element associated therewith to render it eifective at both the low and high-band frequencies to which the driven dipole with its phase reverser ,is responsive.
- an appropriate other parasitic element for example, a low-band director, and a parasitic phase reversing element associated therewith to render it eifective at both the low and high-band frequencies to which the driven dipole with its phase reverser ,is responsive.
- a low-band director for example, may be cut to its. optimum length for enhancing the forward gain of the. driven dipole in its low-band range of operation ⁇ and, byeinploying the phase reversing element associated with 1 the director, the" director is apparently caused tofunction' at high-band frequencies essentially as a three-element high-band director so as to enhance the forward gain of the antenna array in its high-band range of operation, without impairing the normal operation of the array as a whole orof the, director in the low-band range;
- Figure l is a drawing of the basic half-wave dipole antenna to show characteristics thereof
- Figure Z-i's a' diagram of an antenna array showing characteristics the correction of which is accomplished by this invention.
- F,igure 3 is adiagrammatic representation of an antenna embodying the invention.
- FIG. 1 there is shown an elemntary half-wave folded dipole 101 and a reflector parasitic element 102.
- an antenna structure operating at its half-Wave resonant frequency, has an instantaneous current distribution such as represented by the dotted half sine wave curve 103.
- Theinstantaneous phase direction of this current may be represented by arrows 104.
- the arrow 105 shows the direction in which this antenna has a maximum sensitivity when used as a receiving antenna.
- this antenna may be considered to be resonant at 66 mc., but not limited to operation at this frequency.
- antenna 101 shown in Figure 2 embodies a folded dipole 101 that is identical with that shown in Figure l, which bears the same reference character.
- antenna 101 is a three half-wave dipole.
- the current distribution curve for a three halfwa've dipole is shown at 201, 202, and 203.
- the three parasitic reflector elements shown at 204 are each one half-wave length long at the three half-wave operating frequency or the exemplary 198 me.
- the maximum directions of sensitivity of an antenna such as shown in Figure 2 are in the directions of arrows 205, each of which is at an angle of 43 01f center.
- the directivity is in two directions.
- the dual direotivity is the result of the fact that the central current loop 202 is out of phase with the outer loops 201 and 203, as shown by arrows 206, 207, and 208.
- the phase reversing elements 301a and 3011 of the invention are broad, generally rectangular, metal pieces dimensioned for one half-wave resonance at the three half-wave frequency of the same driven folded dipole 101 shown in Figuresl and 2.
- the phase reversing elements 301a and 30111 may be mounted directly on conventional antenna supporting structure (not shown) or maybe insulated from it.
- the shape of the pieces 301a and 3011) may be varied for mechanical strength or wind conditions, and for optimum radiation properties.
- the phase reversing element 301a may be positioned in close proximity to the driven dipole 101.
- the phase reversing element 301 may be positioned in close proximity to a low-band parasitic element such as a low-band director 401. Both of the elements 301a and 301b are centrally aligned with the driven dipole 101 and the director 401, as shown.
- phase reversing element 301a on the current distribution in the driven dipole 101 is that the central current loop 202 of Figure 2 is inverted as shown at 202a in Figure 3.
- all three current loops 201, 202a, and 203 in the driven element 101 are in phase and have a common phase direction as indicated by arrows 309.
- the antenna of Figure 3 may include a conventional reflector 102 identical with the reflector of Figure 1.
- an antenna array such as shown in Figure 3 has a directivity pattern as at 310 at its three half-wave frequency.
- the low-band director 401 were to be included in the antenna of Figure 3 to enhance the low-band gain, without including the phase re erser 301b, -it would generally seriously impair the operation of the antenna on high band.
- the phase reverser 301b may be included in the antenna of Figure 3 to enhance the low-band gain, without including the phase re erser 301b, without in any respect impairing the normal action of the director 401 on low band.
- inclusion of the phase reverser 301b gives it the characteristics of a three-element, collinear, high band director, and generally enhances the high-band gain compared to what would be obtained without either the director 401 or phase reverser 301b.
- An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a. non-driven conductor dimensioned and spaced from said driven dipole for operation as a half-wave parasitic element for the driven dipole at said first frequency, said driven dipole and said parasitic conductor being disposed one in front of the other withrespect to a direction of maximum sensitivity of the antenna, and a parasitic phase reversing element dimensioned for halfwave resonance at approximately said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said nondriven conductor.
- An antenna comprising a driven folded dipole dimensioned for operation as a half-wave radiating element at a first selected frequency, means associated therewith for giving said folded dipole essentially a twolobe radiation pattern at a second frequency approximately three times said first frequency, a non-driven conductor dimensioned and spaced from said folded dipole for operation as a half-wave parasitic element for the folded dipole at said first frequency,,said folded dipole and said parasitic conductor being disposed one in front of the other with respect to a direction of maximum sensitivity of the antenna, and a parasitic phase reversing element dimensioned for half-wave resonance at approximately said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said non-driven conductor.
- An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a non-driven conductor dimensioned and spaced from said driven dipole for operation as a half-wave parasitic element for the driven dipole at said first frequency, said driven dipole and said parasitic element being disposed one in front of the other with respect to a direction of maximum sensitivity of the antenna, and a parasitic phase reversing element dimensioned for halfwave resonance at approximately said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said parasitic element on the opposite side thereof from the driven dipole.
- An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, phase reversing means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a first non-driven conductor dimensioned and spaced from said driven dipole for halfwave resonance as a parasitic element for the driven dipole at approximately said first frequency, said driven dipole and said non-driven conductor being disposed one in front of the other with respect to a direction of maximum sensitivity of the antenna, and additional phase reversing means for said non-driven conductor, said additional phase reversing means comprising a second nondriven conductor dimensioned for half-wave resonance at approximately said second frequency and disposed in closely spaced parallel relationship with the center portion of said first non-driven conductor.
- An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, first parasitic phase reversing means associated therewith for giving said dipole essentially a twolobe radiation pattern at a second frequency approximately three times said first frequency and comprising a non-driven conductor dimensioned for half-wave resonance at said second frequency, a second non-driven conductor dimensioned and spaced from said driven dipole for operation as a half-wave parasitic element at said first frequency, said driven dipole and said second non-driven conductor being disposed one in front of the other with respect to a direction of maximum sensitivity of the antenna, and second parasitic phase reversing means for said second non-driven conductor, said second phase reversing means comprising a third nondriven conductor dimensioned for half-wave resonance at approximately said second frequency, said third nondriven conductor being disposed in closely spaced parallel relationship with the center portion of said second non-driven conductor.
- An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a parasitic director dimensioned as a half-wave director at said first frequency and disposed in directive relationship in front of said driven dipole, and a parasitic phase reversing element dimensioned for half-wave resonance at said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said director.
- An antenna comprising a driven folded dipole dimensioned for operation as a half-wave radiating element at a first selected frequency, means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a parasitic director dimensioned as a half-wave director at said first frequency and disposed in directive relationship in front of said driven dipole, and a parasitic phase reversing element dimensioned for half-wave resonance at said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said director.
- An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a parasitic conductor dimensioned as a half-wave parasitic element at said first frequency and disposed in spaced directive relationship with said driven dipole, and a parasitic phase reversing element dimensioned for halfwave resonance at said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said director on the opposite side thereof from the driven dipole.
- An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, phase reversing means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a parasitic director dimensioned as a half-wave director at said first frequency and disposed in directive relationship in front of said driven dipole, and a parasitic phase reversing dipole element dimensioned for half-wave resonance at said second frequency, said parasitic phase reverser being disposed in closely spaced parallel relationship with the center portion of said director.
- An antenna comprising a driven folded dipole dimensioned for operation as a half-wave dipole at a first selected frequency, a parasitic phase reversing dipole element associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a parasitic director dimensioned as a half-wave director at said first frequency and disposed in directive relationship in front of said driven dipole, and a second parasitic phase reversing dipole element dimensioned for half-wave resonance at said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said director on the opposite side thereof from said driven dipole.
Description
June 30, 1959 J, K, KQBLER 2,893,004
DUAL BAND ANTENNA ARRAY Filed Dec. 23, 1955 JAN K KOBLER,
INVEN TOR.
HUEBNER, BEE'HLE'R, WORREL 8 HERZ/G,
A T TORNEKS.
nirsds P m assignments, to Finney Manufacturing Company,
Cleveland, Ohio, a corporation of Ohio Application'December 23, 1955, Serial No. 555,097 Claims. 01. 343-818) "Thisv invention relates to linear antenna arrays, and more particularly to a single linear antenna array of the yagi type for operation at its fundamentalhalf wave length resonant dimension and at its corresponding three; half wavelength resonant dimension with substantial identity of its directional characteristicslf I e e A Present day television broadcasting in the United Statesand nanyipar'ts of the world is accomplished on two bands, 54-88 mo. and 174-216 mc. A half-wave dipole antenna for television reception, designed to be resonant in the low VHF band and centered at 66 Inc. is resonant also at its three half-wave dimension in the high VHF band centered at] 1:98 mc. The current distribution curve of a dipole at its half-wave low VHF band resonant frequency is ,a single loop with maximum current at thecenter and zero at either end of the dipole. With a parasitioreflector an antenna such as the half wave dipole has the familiar dipole radiation pattern in; volving a single forward lobe and substantially no backwardlobe, i f
The urrent distribution curve of the same antenna at the threehalf-wave length resonant frequency has three half-wave current loops. The center half-wave current loop has an oppositerphase directionto the outer halfwave current, loops. The phase reversal of the current loop of the center halfwave section of the antennaat its three-half wave frequency results in a butterfly-shaped radiation pattern. The butterflyEshaped radiation patter-nt'is very undesirable for television reception because the forward lobe is almost cancelled and the maximum sensitivity is' lin't wo direetions'each at an angle of approximately 43 on either side of "the forward direction. wane 'thedip'ole is'fthu'sjsatisfactory for the low VHF band, such an antenna arrangement is not satisfactory for dual band operation for television reception on both the low an dthe high vnFbands, t 'j If thephase of th half-wave current distribntionloop of, the' center half-wave section ofithe' three half-wave- 1eng aan ennae reame to be in phase with the current loop, of the outer half-Wave sections, the result-- ing"current distribution curve will'then have three halfwave current loops'in' the same phase. The radiation pattern of the antenna may becorrected inthis way, to make itjuseful for unidirectional television reception on the high VHF band a'sfwell fasbnthe low VHF band. Theg ainffof'the antenna on th'e high'band is increased the forward lobe of the'hi'gh band radiation'pattern sharpened as ifjthree' separate' half-wave antennas are lined upin collinear "array; 1 I
ni ber "f'solutionsjto the phase reversal problem have been reported in the' literature, "and some are 'in' actual use. These' solutionshave'included the connec tion of certain complex"additional high-band resonant antennalstructures to the low-band antenna. Oneof these involves a'pairof'high-jband dipoles connected in parallel with each 'other' and out of phase with the lowhand dipole.l""The high-band dipoles are a half-wavelength long at'three times theresonant frequencyof the" third of the driven dipole.
r 2,893,004 Patented June 30, 1959 low-band antenna. This antenna structure includes a complex of three driven elements to effect dual band operation. The system necessitates quarter-wave impedance matching stubs in each driven element termination to maintain a satisfactory impedance match on both high and low bands. The required interconnecting harness is cumbersome and critical as to adjustment and positioning with respect to the remainder of the antenna array.
' Another solution to the problem of reversing the phase of the center half-wave current loop at the third harmonic operation of a low-band TV (tele ison) receiving dipole involves the insertion of a quarter-wave stub element shaped like a folded dipole in each half of the driven element of the low-band antenna. The folded dipole shaped stub elements connecting the main elements of the dipole have alower Q than similarly used purely reactive stub elements. Thisnecessitates multiplication of driven elements to increase the antenna sensitivity.
. Other solutions proposed have also required additional elements connected to the driven element or have required a plurality of driven elements to obtain satisfactory results on both low-band and high-band TV frequencies.
' More recently, as disclosed and claimed in US. patent to Weiss, Re. 24,413, it has been proposed to use a novel phase reversing means in association with a driven dipole to render'it effective for both low and high-band TV reception. The novel phase reversing means of the Weiss Patent is a parasitic (i.e., non-driven) dipole disposed in closely spaced parallel relationship with the driven dipole and being coextentive with approximately the central one- The effect of this parasitic element is to reverse the phase of the current in the central portion of the driven dipole when it is operating at or near its three half-wave resonant frequency. This gives the driven dipole essentially a two-lobe radiation pattern at such frequencies (as Well as at or near the onehalf-wave resonant frequency of the driven dipole). As disclosed by Weiss, conventional directors and/or reflectors may be used in combination with such an array, with the usual effects. a
'The principal object of the present invention is to pro vide a driven dipole having phase reversing means to render it responsive with similar directional character, istics in both the low and high television bands, and also having a parasitic array associated therewith which will enhance the gain of the driven dipole at low-band frefrequency. This means so associated with the'driven dipole, for example, may be a parasitic (non-driven) dipole that is closely spaced in front of the driven dipole, as disclosed and claimed by Weiss. In addition, the present invention involves an appropriate other parasitic element, for example, a low-band director, anda parasitic phase reversing element associated therewith to render it eifective at both the low and high-band frequencies to which the driven dipole with its phase reverser ,is responsive.
The principal advantages of this arrangement arethat a low-band director, for example, may be cut to its. optimum length for enhancing the forward gain of the. driven dipole in its low-band range of operation} and, byeinploying the phase reversing element associated with 1 the director, the" director is apparently caused tofunction' at high-band frequencies essentially as a three-element high-band director so as to enhance the forward gain of the antenna array in its high-band range of operation, without impairing the normal operation of the array as a whole orof the, director in the low-band range;
These and other objects, features, and advantages of this invention will become apparent from the following specification and claims taken together with the accompanying drawings, in which two illustrative prior art antennas and an illustrative embodiment of the invention are shown.
In the drawings:
Figure lis a drawing of the basic half-wave dipole antenna to show characteristics thereof;
. Figure Z-i's a' diagram of an antenna array showing characteristics the correction of which is accomplished by this invention; and
. F,igure 3 is adiagrammatic representation of an antenna embodying the invention.
Referring now to Figure 1, there is shown an elemntary half-wave folded dipole 101 and a reflector parasitic element 102. It is well known that such an antenna structure, operating at its half-Wave resonant frequency, has an instantaneous current distribution such as represented by the dotted half sine wave curve 103. Theinstantaneous phase direction of this current may be represented by arrows 104. The arrow 105 shows the direction in which this antenna has a maximum sensitivity when used as a receiving antenna. For illustrative purposes, this antenna may be considered to be resonant at 66 mc., but not limited to operation at this frequency.
The antenna 101 shown in Figure 2, to which referonce is now made, embodies a folded dipole 101 that is identical with that shown in Figure l, which bears the same reference character. As represented in Figure 2, at a frequency three times that at which the antenna of Figure l is operated, antenna 101 is a three half-wave dipole. The current distribution curve for a three halfwa've dipole is shown at 201, 202, and 203. The three parasitic reflector elements shown at 204 are each one half-wave length long at the three half-wave operating frequency or the exemplary 198 me. The maximum directions of sensitivity of an antenna such as shown in Figure 2 are in the directions of arrows 205, each of which is at an angle of 43 01f center. Thus, for the three half-wave operation of the half-wave dipole 101, the directivity is in two directions. The dual direotivity is the result of the fact that the central current loop 202 is out of phase with the outer loops 201 and 203, as shown by arrows 206, 207, and 208.
In order to make this antenna more useful for television reception at, say, 198 mc., it should be made sensitive only in a single direction, as shown by arrow 105 for the 198 mc. operation of the antenna array, as well as for operation at 66 mc. To accomplish this it is necessary to provide means for inverting the phase of central current loop 202 so that it is in the same phase as loops 201 and 203.
One example of how this may be done in accordance with the present invention is shown in Figure 3. The phase reversing elements 301a and 3011: of the invention are broad, generally rectangular, metal pieces dimensioned for one half-wave resonance at the three half-wave frequency of the same driven folded dipole 101 shown in Figuresl and 2. The phase reversing elements 301a and 30111 may be mounted directly on conventional antenna supporting structure (not shown) or maybe insulated from it. The shape of the pieces 301a and 3011) may be varied for mechanical strength or wind conditions, and for optimum radiation properties. The phase reversing element 301a may be positioned in close proximity to the driven dipole 101. The phase reversing element 301!) may be positioned in close proximity to a low-band parasitic element such as a low-band director 401. Both of the elements 301a and 301b are centrally aligned with the driven dipole 101 and the director 401, as shown.
The resultant effect of the phase reversing element 301a on the current distribution in the driven dipole 101 is that the central current loop 202 of Figure 2 is inverted as shown at 202a in Figure 3. Thus, all three current loops 201, 202a, and 203 in the driven element 101 are in phase and have a common phase direction as indicated by arrows 309.
In addition to the foregoing elements, the antenna of Figure 3 may include a conventional reflector 102 identical with the reflector of Figure 1.
As a result of this phase reversal of the central current loop, an antenna array such as shown in Figure 3 has a directivity pattern as at 310 at its three half-wave frequency.
If the low-band director 401 were to be included in the antenna of Figure 3 to enhance the low-band gain, without including the phase re erser 301b, -it would generally seriously impair the operation of the antenna on high band. However, in accordance with this invention, I have found that this effect may be avoided by also including the phase reverser 301b, without in any respect impairing the normal action of the director 401 on low band. At the same time, inclusion of the phase reverser 301b gives it the characteristics of a three-element, collinear, high band director, and generally enhances the high-band gain compared to what would be obtained without either the director 401 or phase reverser 301b.
The result is that the inclusion in the antenna of Figure 3 of both the high-band director 401 and its associated phase reverser 30112 enhances the gain of the antenna on low-band without any adverse effect on the high-band operation achieved by associating the phase reverser 30142 with the driven dipole 101, and generally will also enhance the high-band gain.
While I have herein shown and described my invention in what I have conceived to be the most practical and preferred embodiments, it is recognized that departures may be made therefrom within the scope of my invention, which is not to be limited to the details disclosed herein, but is to be accorded the full scope of the claims so as to embrace any and all equivalent structures.
What is claimed is:
1. An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a. non-driven conductor dimensioned and spaced from said driven dipole for operation as a half-wave parasitic element for the driven dipole at said first frequency, said driven dipole and said parasitic conductor being disposed one in front of the other withrespect to a direction of maximum sensitivity of the antenna, and a parasitic phase reversing element dimensioned for halfwave resonance at approximately said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said nondriven conductor.
2. An antenna comprising a driven folded dipole dimensioned for operation as a half-wave radiating element at a first selected frequency, means associated therewith for giving said folded dipole essentially a twolobe radiation pattern at a second frequency approximately three times said first frequency, a non-driven conductor dimensioned and spaced from said folded dipole for operation as a half-wave parasitic element for the folded dipole at said first frequency,,said folded dipole and said parasitic conductor being disposed one in front of the other with respect to a direction of maximum sensitivity of the antenna, and a parasitic phase reversing element dimensioned for half-wave resonance at approximately said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said non-driven conductor.
3. An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a non-driven conductor dimensioned and spaced from said driven dipole for operation as a half-wave parasitic element for the driven dipole at said first frequency, said driven dipole and said parasitic element being disposed one in front of the other with respect to a direction of maximum sensitivity of the antenna, and a parasitic phase reversing element dimensioned for halfwave resonance at approximately said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said parasitic element on the opposite side thereof from the driven dipole.
4. An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, phase reversing means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a first non-driven conductor dimensioned and spaced from said driven dipole for halfwave resonance as a parasitic element for the driven dipole at approximately said first frequency, said driven dipole and said non-driven conductor being disposed one in front of the other with respect to a direction of maximum sensitivity of the antenna, and additional phase reversing means for said non-driven conductor, said additional phase reversing means comprising a second nondriven conductor dimensioned for half-wave resonance at approximately said second frequency and disposed in closely spaced parallel relationship with the center portion of said first non-driven conductor.
5. An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, first parasitic phase reversing means associated therewith for giving said dipole essentially a twolobe radiation pattern at a second frequency approximately three times said first frequency and comprising a non-driven conductor dimensioned for half-wave resonance at said second frequency, a second non-driven conductor dimensioned and spaced from said driven dipole for operation as a half-wave parasitic element at said first frequency, said driven dipole and said second non-driven conductor being disposed one in front of the other with respect to a direction of maximum sensitivity of the antenna, and second parasitic phase reversing means for said second non-driven conductor, said second phase reversing means comprising a third nondriven conductor dimensioned for half-wave resonance at approximately said second frequency, said third nondriven conductor being disposed in closely spaced parallel relationship with the center portion of said second non-driven conductor.
6. An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a parasitic director dimensioned as a half-wave director at said first frequency and disposed in directive relationship in front of said driven dipole, and a parasitic phase reversing element dimensioned for half-wave resonance at said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said director.
7. An antenna comprising a driven folded dipole dimensioned for operation as a half-wave radiating element at a first selected frequency, means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a parasitic director dimensioned as a half-wave director at said first frequency and disposed in directive relationship in front of said driven dipole, and a parasitic phase reversing element dimensioned for half-wave resonance at said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said director.
8. An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a parasitic conductor dimensioned as a half-wave parasitic element at said first frequency and disposed in spaced directive relationship with said driven dipole, and a parasitic phase reversing element dimensioned for halfwave resonance at said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said director on the opposite side thereof from the driven dipole.
9. An antenna comprising a driven dipole dimensioned for operation as a half-wave dipole at a first selected frequency, phase reversing means associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a parasitic director dimensioned as a half-wave director at said first frequency and disposed in directive relationship in front of said driven dipole, and a parasitic phase reversing dipole element dimensioned for half-wave resonance at said second frequency, said parasitic phase reverser being disposed in closely spaced parallel relationship with the center portion of said director.
10. An antenna comprising a driven folded dipole dimensioned for operation as a half-wave dipole at a first selected frequency, a parasitic phase reversing dipole element associated therewith for giving said dipole essentially a two-lobe radiation pattern at a second frequency approximately three times said first frequency, a parasitic director dimensioned as a half-wave director at said first frequency and disposed in directive relationship in front of said driven dipole, and a second parasitic phase reversing dipole element dimensioned for half-wave resonance at said second frequency, said phase reverser being disposed in closely spaced parallel relationship with the center portion of said director on the opposite side thereof from said driven dipole.
References Cited in the file of this patent UNITED STATES PATENTS 2,580,798 Kolster Jan. 1, 1952. 2,691,730 Lo Oct. 12, 1954 2,705,283 Thomas Mar. 29, 1955 2,726,390 Weiss Dec. 6, 1955
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US555097A US2893004A (en) | 1955-12-23 | 1955-12-23 | Dual band antenna array |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US555097A US2893004A (en) | 1955-12-23 | 1955-12-23 | Dual band antenna array |
Publications (1)
Publication Number | Publication Date |
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US2893004A true US2893004A (en) | 1959-06-30 |
Family
ID=24215942
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US555097A Expired - Lifetime US2893004A (en) | 1955-12-23 | 1955-12-23 | Dual band antenna array |
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US (1) | US2893004A (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4097868A (en) * | 1976-12-06 | 1978-06-27 | The United States Of America As Represented By The Secretary Of The Army | Antenna for combined surveillance and foliage penetration radar |
US4114163A (en) * | 1976-12-06 | 1978-09-12 | The United States Of America As Represented By The Secretary Of The Army | L-band radar antenna array |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2580798A (en) * | 1947-05-22 | 1952-01-01 | Kolster Muriel | Broad-band antenna system |
US2691730A (en) * | 1954-03-25 | 1954-10-12 | Channel Master Corp | Wide band antenna |
US2705283A (en) * | 1954-02-12 | 1955-03-29 | Technical Appliance Corp | Sharply directional wide band antenna |
US2726390A (en) * | 1955-09-12 | 1955-12-06 | Finney Mfg Company | Radio frequency antennas |
-
1955
- 1955-12-23 US US555097A patent/US2893004A/en not_active Expired - Lifetime
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2580798A (en) * | 1947-05-22 | 1952-01-01 | Kolster Muriel | Broad-band antenna system |
US2705283A (en) * | 1954-02-12 | 1955-03-29 | Technical Appliance Corp | Sharply directional wide band antenna |
US2691730A (en) * | 1954-03-25 | 1954-10-12 | Channel Master Corp | Wide band antenna |
US2726390A (en) * | 1955-09-12 | 1955-12-06 | Finney Mfg Company | Radio frequency antennas |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4097868A (en) * | 1976-12-06 | 1978-06-27 | The United States Of America As Represented By The Secretary Of The Army | Antenna for combined surveillance and foliage penetration radar |
US4114163A (en) * | 1976-12-06 | 1978-09-12 | The United States Of America As Represented By The Secretary Of The Army | L-band radar antenna array |
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