US3020549A - Matched antenna array - Google Patents

Matched antenna array Download PDF

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US3020549A
US3020549A US835155A US83515559A US3020549A US 3020549 A US3020549 A US 3020549A US 835155 A US835155 A US 835155A US 83515559 A US83515559 A US 83515559A US 3020549 A US3020549 A US 3020549A
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coupler
series
port
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antenna
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Morris L Kales
Herman N Chait
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q3/00Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system
    • H01Q3/26Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the relative phase or relative amplitude of energisation between two or more active radiating elements; varying the distribution of energy across a radiating aperture
    • H01Q3/30Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the relative phase or relative amplitude of energisation between two or more active radiating elements; varying the distribution of energy across a radiating aperture varying the relative phase between the radiating elements of an array
    • H01Q3/34Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the relative phase or relative amplitude of energisation between two or more active radiating elements; varying the distribution of energy across a radiating aperture varying the relative phase between the radiating elements of an array by electrical means

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  • This invention relates to antenna systems in general and in particular to directive antennas wherein the axis of directivity is caused to scan through a sector of space by electrical variation as contrasted to mechanical varia tion.
  • the invention relates to antennas employing a plurality of radiating elements which are series fed.
  • Direct radiator antenna arrays used for narrow beam operation such as conventional form of radar systems, generally must employ a plurality of antenna elements, spaced critical distances apart, and radiating in phase so that the energy from the elements is additive in the broadside direction providing a peak that falls off rapidly away from the broadside direction.
  • the elements do not radiate in phase, but progressively differ in phase across the array, the maximum does not occur in the broadside direction but rather at some angle with respect thereto.
  • an electrical scanning antenna is set forth wherein the direction of major response of the antenna can be swept across a sector of space without requiring physical motion of the antenna.
  • the plurality of antenna elements must be fed from a single source of energy or connected to a single receiver depending upon whether the device is used for transmission or reception. In either case the problem of connecting many elements to one utilization device still exists.
  • One way to accomplish this requires a symmetrically arranged plurality of tiers of T-junctions, each branch of each junction of one tier feeding two subse--.
  • each of the last tier of junctions feeds two antenna elements. This is referred to as parallel feed.
  • a second form of feed and that to which the device of the present invention is directed is termed a series feed because of the fact that it is in efiect a Single line that goes to each element in sequence, each such element withdrawing a portion of the energy in the line, the balance of the energy continuing down the line.
  • the matching of impedances and phasing of the elements in such arrays requires careful consideration if undesired reflections are to be avoided and the desired directivity obtained.
  • the series fed system achieves in-phase excitation of the elements by spacing the feed points for the elements one wavelength apart along the line or a half wavelength apart with some arrangement for introducing 180 degree phase change. Either arrangement achieves scanning by the insertion of similar controllable phase shifters in the line between each such feed point.
  • Such a system is subject to a particular disadvantage however in that when the in-phase condition exists, reflections from all similar components are additive at the input end of the line, producing serious impedance mismatch.
  • Another object of the present invention is to provide an antenna feed system wherein reflections from the elements do not occur regardless of whether the elements are matched to their feed line.
  • FIG. 1 shows an antenna system embodying the teach ings of the present invention.
  • FIG. 2 shows details of the internal structure of th antenna system of FIG. 1.
  • an antenna system employing a plurality of radiator elements wherein beam positioning is obtained by varying the relative phasing of excitation of the elements, the elements being coupled in sequence (series) to a single lead-in circuit.
  • Iii-phase excitation of the elements ' is made possible in this antenna, a condition not practical in the prior art, by placing the elements in branches of directive couplers each of which has the property of providing overall matched transmission therethrough without reflection independent of actual element impedance.
  • Phase variation of element excitation is provided by combinin into the system phase shifters each of which has the property of providing overall matched transmission therethrough regardless of the amount of phase shift.
  • the apparatus shown therein indicates in general a radio frequency system including an antenna structure having a base member 10 carrying supports 11 and 12 and braces 13 and 14. Mounted upon this framework is a Waveguide structure having a connector 15 for connection to a radio frequency operative device 16.
  • the radio frequency operative device 16 can be either a transmitter or a receiver, or both, provided that it include appropriate transmit-receive switching to provide alternation between the transmit and receive phases.
  • the following description will be directed primarily to a situation wherein the device 16 is a high frequency transmitter which produces energy to be radiated -by the antenna system. 7
  • the waveguides 17 are connected through two banks of couplers indicated generally as to location by the numerals 19 and 20 which are internal to the waveguides being shown in greater schematic detail in FIG. 2.
  • the individual waveguides 17 further are adjustably short circuit terminated at the ends 21 and 22 and includea series of slots 23 in the side walls by means of which energy leaves the waveguides and is radiated.
  • the beam is sharpened in the plane passing through the slots by virtue of the multiplicity of the slots and is restricted in the other plane by the members 24 and 25.
  • Energy not radiated by the slots 23 continues through the waveguides where it is absorbed in load 18, load 18 being constructed in a suitable manner so as to provide a matched impedance termination for the waveguides so that reflection of energy back to source 16 does not occur.
  • the apparatus shown therein indicates the internal structure of the waveguide slot antenna of FIG. 1, similar reference advantageous, however constant eifort is beingexpended numerals indicating similar parts.
  • the device of FIG. 2 has waveguides 17-a, 17-h, 17c, 17-d, 17-e, 17- 17-g, and 17-11 which are all supplied by energy from input and which are connected to an energy absorptive terminating device or load 18 as indicated.
  • the combination of waveguides acts as a matched transmission line terminated by load 18, however in regions near the ends of each of the waveguides, from each one of the couplers 19 and 20 to the respective near end, standing waves do exist and are utilized to control the amount and phasing of radiation from each slot, by adjustment of the position of the short circuit members at the ends 22 and 21, respectively, to produce variation of the direction of major response of the antenna.
  • the couplers 19 and 20 as shown may be given for convenience the generic name duplex coupler and refer to devices well known in the art of radio frequency transmission lines.
  • a typical duplex coupler is shown in FIG. 2 as that known in the art as a 3-db coupler, however other equivalents, namely, a four port junction having the property that if two ports are terminated in suitably placed shorts, all the energy entering a third port is transmitted to the fourth port, may be used.
  • the socalled magic-T" could also be used to advantage as a duplex coupler.
  • the waveguides 17-a and 17-b are not operated in a matched impedance condition but are terminated in adjustable short circuit plungers at the ends 22 which can be varied to control the radiation or loss from slots 23a and 23-b. It is important however that the waveguides 17-a and 17-h be identical in this regard so that the portions of energy reflected by the short circuit termination and traveling downward in the two waveguides are equal. When these reflected energy portions reach coupler 20, equal amplitude splitting and 90 degree phase change again occur.
  • Waveguide 17-17 as thus fed by coupler 20 operates in matched impedance with the energy therein traveling downward to coupler 19.
  • Coupler 19 operates similar to the previously described coupler 20, being used to feed two short sections of waveguide which are terminated in adjustable shorting members, which introduces an adjustable phase shift in the transmission of energy to waveguide 17-c.
  • This phase shift arrangement does not provide reflections upward in waveguide 17-b beyond the coupler 19, regardless of the amount of phase shift introduced as long as the waveguides 17-11 and 17-c between the coupler 19 and ends 21 thereof are identical, but it does provide control over the phase of the energy delivered to waveguide 17c from coupler 19.
  • the balance of the apparatus of FIG. 2 is constructed in a continuation of the foregoing principles, with the output from the last waveguide 17-h going to a matched impedance load 18 where it is absorbed without reflection.
  • the result is a device wherein reflections from the various components do not return to feed 15 so that broadside operation is not accompanied by the additive reflections producing large mis-match so that scanning through the broadside condition by operation of the phase shifters at ends 21 is possible and practical.
  • the antenna system contains a plurality of slots 23 which may be considered as primary radiating elements which are fed by a single waveguide, each deriving its energy at a point along said waveguide and efiectively therefore being fed in series rather than a parallel feed arrangement whereby a plurality of elements are fed from a plurally branched circuit.
  • the in-phase reflections which were described as normally being produced in the broadside condition of prior art antennas are not produced by this antenna because of the fact that the couplers prevent the return of energy back toward the feed 15 from the slots 23, the slots 23 with drawing only a certain amount of energy and the balance passing on down the system to succeeding slots 23 or the load 18.
  • An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers each having four ports; means for short circuit terminating first and second ones of said ports of each duplex coupler; means individually connecting an antenna element between each of said first and second ports and the terminations thereof; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
  • An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers each having four ports; means for short circuit terminating first and second ones of said ports of each duplex coupler; an individual section of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to each section of transmission line; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the frequency operative device.
  • An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers each having four ports; means for short circuit terminating first and second ones of said ports of each duplex coupler; an individual section of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to each section of transmission line; said first and second ports, transmission line, antenna elements and means connecting being in matched pairs for each coupler; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
  • An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers each having four ports; means for short circuit terminating first and second ones of said ports of each duplex coupler; an individual section of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to each section of transmission line; means for varying the electrical length of each transmission line between the short circuit termination and the point of connection of an antenna element thereto; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to the --third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio operative device.
  • An antenna system for a radio frequency energy ones of said ports of each duplex coupler; an individual section'of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to each section of transmission line; means for varying the electrical length of each transmission line between the short circuit termination and the point of connection of an antenna element thereto; said first and second ports, transmission lines, antenna elements, means connecting, and means for varying the electrical length of each transmission line being in matched pairs for each coupler; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
  • An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers having four ports interconnected such that when the third port is terminated in a matched impedance energy applied to the fourth port is delivered to the first and second ports in equal amplitude and 90-degree phase relationship; means for short circuit terminating first and second ones of said ports of each duplex coupler; an individual section of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to each section of transmission line; means for varying the electrical length of each transmission line between the short circuit termination and the point of connection of an antenna element thereto; said first and second ports, transmission lines, antenna elements, means connecting, and means for varying the electrical length of each transmission line being in matched pairs for each coupler; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to the third
  • An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers having four ports interconnected such that when the third port is terminated in a matched impedance energy applied to the fourth port is delivered to the first and second ports in equal amplitude and -degree phase relationship; means for short circuit terminating first and second ones of said ports of each duplex coupler; means individually connecting an antenna element between each of said first and second ports and the terminations thereof; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to .the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
  • An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers having four ports interconnected such that when the third port is terminated in a matched impedance energy applied to the fourth port is delivered to the first and second ports in equal amplitude and 90-degree phase relationship, means for short circuit terminating first and second ones of said ports of each duplex coupler; means individually connecting an antenna element between each of said first and second ports and the terminations thereof; adjustable 7 phase control means for each coupler; means connecting the radio frequency operative device.
  • An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers having four ports interconnected such that when the third port is terminated in a matched impedance energy applied to the fourth port is delivered to, the first and second ports in equal amplitude and 90-degree phase relationship; means for short circuit terminating first and second ones of said ports of each duplex coupler; an individual section of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to 1 each section of transmission line; means for varying the electrical length of each transmission line between the short circuit termination and the point of connection of an antenna element thereto; said first and second ports, transmission lines, antenna elements, means connecting, and means for varying the electrical length of each transmission line being in matched pairs for each coupler; adjustable phase control means for each coupler; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series through said adjustable phase
  • An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers having four ports interconnected such that then the third port is terminated in a matched impedance energy applied to the fourth port is delivered to the first and second ports in equal amplitude and 90-degree phase relationship; means for short circuit terminating first and second ones of said ports of each duplex coupler; means individually connecting an succedent coupler of the series through said adjustable phase control means; means gauging the adjustable phase shift control means for the couplers whereby substantially equal phase shifts are produced simultaneously in the coupling between adjacently connected couplers; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
  • An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers having four ports interconnected such that when the third port is terminated in a matched impedance energy applied to the fourth port is delivered to the first and second ports in equal amplitude and 90-degree phase relationship; means for short circuit terminating first and second ones of said ports of each duplex coupler; an individual section of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to each section of transmission line; means for varying the electrical length of each transmission line between the short circuit termination and the point of connection of an antenna element thereto; said first and second ports, transmission lines, antenna elements, means connecting, and means for varying the electrical length of each transmission line being in matched pairs for each coupler; adjustable phase control means for each coupler; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series through said adjustable phase control means
  • An antenna system for a radio frequency energy operative device comprising; a plurality of duplex couplers having four ports interconnected such that when the third port is terminated in a matched impedance; energy applied to the fourth port is delivered to the first and second ports in equal amplitude and -degree phase relationship; means for short circuit terminating first and second ones of said ports of each duplex coupler; a plurality of sections of transmission line, each having a portion that provides substantially more electromagnetic coupling to surrounding space than other portions thereof, said sections of transmission line individually connecting each said first and second ports to the corresponding short circuit termination thereof; means for varying the electrical length of each section of transmission line between the short circuit termination and the adjacent coupler port; said first and second ports, corresponding sections of transmission line, and corresponding means for varying the electrical length of each transmission line section being in matched pairs for each coupler; adjustable phase control means for each coupler; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of

Description

Feb. 6, 1962 KALES ET AL MATCHED ANTENNA ARRAY 2 Sheets-Sheet 1 I Filed Aug. 20, 1959 Am? i INVENTORS IS L. KALES AN N. CHAIT ATTORNEY Feb. 6, 1962 Filed Aug. 20, 1959 M. L. KALES ET AL MATCHED ANTENNA ARRAY 2 Sheets-Sheet 2 LOAD l8 I? INVENTORE:
MORRIS L. KALES GANGED HERMAN N. CHAIT E1515 BY W ATTORNEY United States Patent Calif.
Filed Aug. 20, 1959. Ser. No. 835,155 12Claims. (Cl. 343-771) (Granted under Title 35, US. Code (1952), see. 266) The invention described herein may be manufactured and used by or for the Government of the United States of America for governmental purposes without the payment of any royalties thereon or therefor.
This invention relates to antenna systems in general and in particular to directive antennas wherein the axis of directivity is caused to scan through a sector of space by electrical variation as contrasted to mechanical varia tion. In greater particularity the invention relates to antennas employing a plurality of radiating elements which are series fed.
Direct radiator antenna arrays used for narrow beam operation, such as conventional form of radar systems, generally must employ a plurality of antenna elements, spaced critical distances apart, and radiating in phase so that the energy from the elements is additive in the broadside direction providing a peak that falls off rapidly away from the broadside direction. In such systems, if the elements do not radiate in phase, but progressively differ in phase across the array, the maximum does not occur in the broadside direction but rather at some angle with respect thereto. Thus the basis of an electrical scanning antenna is set forth wherein the direction of major response of the antenna can be swept across a sector of space without requiring physical motion of the antenna.
In general the plurality of antenna elements must be fed from a single source of energy or connected to a single receiver depending upon whether the device is used for transmission or reception. In either case the problem of connecting many elements to one utilization device still exists. One way to accomplish this requires a symmetrically arranged plurality of tiers of T-junctions, each branch of each junction of one tier feeding two subse--.
quent junctions in the subsequent tier, until finally each of the last tier of junctions feeds two antenna elements. This is referred to as parallel feed.
A second form of feed and that to which the device of the present invention is directed is termed a series feed because of the fact that it is in efiect a Single line that goes to each element in sequence, each such element withdrawing a portion of the energy in the line, the balance of the energy continuing down the line.
The matching of impedances and phasing of the elements in such arrays requires careful consideration if undesired reflections are to be avoided and the desired directivity obtained. In general the series fed system achieves in-phase excitation of the elements by spacing the feed points for the elements one wavelength apart along the line or a half wavelength apart with some arrangement for introducing 180 degree phase change. Either arrangement achieves scanning by the insertion of similar controllable phase shifters in the line between each such feed point. Such a system is subject to a particular disadvantage however in that when the in-phase condition exists, reflections from all similar components are additive at the input end of the line, producing serious impedance mismatch. This mismatch is of such proportions that prior art devices were seldom operated through the broadside condition in scanning, the scanning being deliberately limited so as to result in scanning only to one side or the other of the broadside condition. Such operation provides results which to some extent can be considered 3,020,549 Patented Feb. 6, 1962 to increase the possible scan angle so that some arrange ment for avoiding the undesired reflections in the broad side condition would substantially increase the practical scan angle.
It is accordingly an object of the present invention to provide a series fed multi-elernent antenna system wherein the foregoing impedance mismatch in the broadside condition is avoided.
Another object of the present invention is to provide an antenna feed system wherein reflections from the elements do not occur regardless of whether the elements are matched to their feed line.
Other and further objects and features of the present invention will become apparent upon consideration of the accompanying description and drawings, wherein:
FIG. 1 shows an antenna system embodying the teach ings of the present invention.
FIG. 2 shows details of the internal structure of th antenna system of FIG. 1.
In accordance with the present invention, an antenna system is provided employing a plurality of radiator elements wherein beam positioning is obtained by varying the relative phasing of excitation of the elements, the elements being coupled in sequence (series) to a single lead-in circuit. Iii-phase excitation of the elements 'is made possible in this antenna, a condition not practical in the prior art, by placing the elements in branches of directive couplers each of which has the property of providing overall matched transmission therethrough without reflection independent of actual element impedance. Phase variation of element excitation is provided by combinin into the system phase shifters each of which has the property of providing overall matched transmission therethrough regardless of the amount of phase shift.
With reference now to FIG. 1 of the drawing, the apparatus shown therein indicates in general a radio frequency system including an antenna structure having a base member 10 carrying supports 11 and 12 and braces 13 and 14. Mounted upon this framework is a Waveguide structure having a connector 15 for connection to a radio frequency operative device 16. Typicallythe radio frequency operative device 16 can be either a transmitter or a receiver, or both, provided that it include appropriate transmit-receive switching to provide alternation between the transmit and receive phases. To facilitate the description of the antenna however the following description will be directed primarily to a situation wherein the device 16 is a high frequency transmitter which produces energy to be radiated -by the antenna system. 7
Energy applied to the antenna system at connector 15 travels through a series of parallel waveguides 17 toward load 18. The waveguides are connected through two banks of couplers indicated generally as to location by the numerals 19 and 20 which are internal to the waveguides being shown in greater schematic detail in FIG. 2. The individual waveguides 17 further are adjustably short circuit terminated at the ends 21 and 22 and includea series of slots 23 in the side walls by means of which energy leaves the waveguides and is radiated. The beam is sharpened in the plane passing through the slots by virtue of the multiplicity of the slots and is restricted in the other plane by the members 24 and 25. Energy not radiated by the slots 23 continues through the waveguides where it is absorbed in load 18, load 18 being constructed in a suitable manner so as to provide a matched impedance termination for the waveguides so that reflection of energy back to source 16 does not occur. 7
With reference now to FIG. 2 of the drawing, the apparatus shown therein indicates the internal structure of the waveguide slot antenna of FIG. 1, similar reference advantageous, however constant eifort is beingexpended numerals indicating similar parts. For simplicity, ;sub-
stantially fewer waveguides and slots are indicated in the apparatus of FIG. 2, it being understood however that a larger number of waveguides could be placed side by side in the same manner. Thus the device of FIG. 2 has waveguides 17-a, 17-h, 17c, 17-d, 17-e, 17- 17-g, and 17-11 which are all supplied by energy from input and which are connected to an energy absorptive terminating device or load 18 as indicated. The combination of waveguides acts as a matched transmission line terminated by load 18, however in regions near the ends of each of the waveguides, from each one of the couplers 19 and 20 to the respective near end, standing waves do exist and are utilized to control the amount and phasing of radiation from each slot, by adjustment of the position of the short circuit members at the ends 22 and 21, respectively, to produce variation of the direction of major response of the antenna.
} The couplers 19 and 20 as shown may be given for convenience the generic name duplex coupler and refer to devices well known in the art of radio frequency transmission lines. A typical duplex coupler is shown in FIG. 2 as that known in the art as a 3-db coupler, however other equivalents, namely, a four port junction having the property that if two ports are terminated in suitably placed shorts, all the energy entering a third port is transmitted to the fourth port, may be used. The socalled magic-T" could also be used to advantage as a duplex coupler.
In operation of such a coupler, typically coupler 20 between waveguides 17-a and 17b, energy traveling upward in waveguide 17-a from input 15 splits into two equal parts at the coupler 20 with half the energy transferring and proceeding upward in waveguide 17-b. One
important distinction in the two portions of energy exists,
however, and that is that the two are at 90-degree phase relationship to each other. Above the coupler 20, the waveguides 17-a and 17-b are not operated in a matched impedance condition but are terminated in adjustable short circuit plungers at the ends 22 which can be varied to control the radiation or loss from slots 23a and 23-b. It is important however that the waveguides 17-a and 17-h be identical in this regard so that the portions of energy reflected by the short circuit termination and traveling downward in the two waveguides are equal. When these reflected energy portions reach coupler 20, equal amplitude splitting and 90 degree phase change again occur. Thus the portion of downward traveling energy of waveguide 17-a becomes additive in waveguide 17-b with the downward traveling energy of waveguide 17-]; which did not transfer to waveguide 17-a and the downward traveling energy of waveguide 17-b which does transfer to waveguide 17-a is at 180 degree phase relationship to the downward traveling energy in waveguide 17-h, and being equal, cancel each other. Thus there is no return of energy toward input 15 beyond the coupler 20 so that the coupler 20, the slots 23, and the short circuit termination all appear to be a matched impedance to the waveguide 17-a. This condition further prevails regardless of the actual impedance presented by the radiating elements, the slots 23.
Waveguide 17-17, as thus fed by coupler 20 operates in matched impedance with the energy therein traveling downward to coupler 19. Coupler 19 operates similar to the previously described coupler 20, being used to feed two short sections of waveguide which are terminated in adjustable shorting members, which introduces an adjustable phase shift in the transmission of energy to waveguide 17-c. This phase shift arrangement does not provide reflections upward in waveguide 17-b beyond the coupler 19, regardless of the amount of phase shift introduced as long as the waveguides 17-11 and 17-c between the coupler 19 and ends 21 thereof are identical, but it does provide control over the phase of the energy delivered to waveguide 17c from coupler 19.
The balance of the apparatus of FIG. 2 is constructed in a continuation of the foregoing principles, with the output from the last waveguide 17-h going to a matched impedance load 18 where it is absorbed without reflection. The result is a device wherein reflections from the various components do not return to feed 15 so that broadside operation is not accompanied by the additive reflections producing large mis-match so that scanning through the broadside condition by operation of the phase shifters at ends 21 is possible and practical.
It is thus seen that the antenna system contains a plurality of slots 23 which may be considered as primary radiating elements which are fed by a single waveguide, each deriving its energy at a point along said waveguide and efiectively therefore being fed in series rather than a parallel feed arrangement whereby a plurality of elements are fed from a plurally branched circuit. The in-phase reflections which were described as normally being produced in the broadside condition of prior art antennas are not produced by this antenna because of the fact that the couplers prevent the return of energy back toward the feed 15 from the slots 23, the slots 23 with drawing only a certain amount of energy and the balance passing on down the system to succeeding slots 23 or the load 18.
From the foregoing it is apparent that an antenna feed system having desired characteristic is provided. Obviously many modifications and variations of the present invention is possible in the light of the above teachings. It is therefore understood that within the scope of the appended claims that the invention may be practiced otherwise than as specifically described.
What is claimed is:
1. An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers each having four ports; means for short circuit terminating first and second ones of said ports of each duplex coupler; means individually connecting an antenna element between each of said first and second ports and the terminations thereof; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
2. An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers each having four ports; means for short circuit terminating first and second ones of said ports of each duplex coupler; an individual section of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to each section of transmission line; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the frequency operative device.
3. An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers each having four ports; means for short circuit terminating first and second ones of said ports of each duplex coupler; an individual section of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to each section of transmission line; said first and second ports, transmission line, antenna elements and means connecting being in matched pairs for each coupler; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
4. An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers each having four ports; means for short circuit terminating first and second ones of said ports of each duplex coupler; an individual section of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to each section of transmission line; means for varying the electrical length of each transmission line between the short circuit termination and the point of connection of an antenna element thereto; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to the --third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio operative device.
5. An antenna system for a radio frequency energy ones of said ports of each duplex coupler; an individual section'of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to each section of transmission line; means for varying the electrical length of each transmission line between the short circuit termination and the point of connection of an antenna element thereto; said first and second ports, transmission lines, antenna elements, means connecting, and means for varying the electrical length of each transmission line being in matched pairs for each coupler; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
6. An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers having four ports interconnected such that when the third port is terminated in a matched impedance energy applied to the fourth port is delivered to the first and second ports in equal amplitude and 90-degree phase relationship; means for short circuit terminating first and second ones of said ports of each duplex coupler; an individual section of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to each section of transmission line; means for varying the electrical length of each transmission line between the short circuit termination and the point of connection of an antenna element thereto; said first and second ports, transmission lines, antenna elements, means connecting, and means for varying the electrical length of each transmission line being in matched pairs for each coupler; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
7. An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers having four ports interconnected such that when the third port is terminated in a matched impedance energy applied to the fourth port is delivered to the first and second ports in equal amplitude and -degree phase relationship; means for short circuit terminating first and second ones of said ports of each duplex coupler; means individually connecting an antenna element between each of said first and second ports and the terminations thereof; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series; means providing a matched impedance termination connected to .the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
8. An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers having four ports interconnected such that when the third port is terminated in a matched impedance energy applied to the fourth port is delivered to the first and second ports in equal amplitude and 90-degree phase relationship, means for short circuit terminating first and second ones of said ports of each duplex coupler; means individually connecting an antenna element between each of said first and second ports and the terminations thereof; adjustable 7 phase control means for each coupler; means connecting the radio frequency operative device.
9. An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers having four ports interconnected such that when the third port is terminated in a matched impedance energy applied to the fourth port is delivered to, the first and second ports in equal amplitude and 90-degree phase relationship; means for short circuit terminating first and second ones of said ports of each duplex coupler; an individual section of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to 1 each section of transmission line; means for varying the electrical length of each transmission line between the short circuit termination and the point of connection of an antenna element thereto; said first and second ports, transmission lines, antenna elements, means connecting, and means for varying the electrical length of each transmission line being in matched pairs for each coupler; adjustable phase control means for each coupler; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series through said adjustable phase control means; means providing a matched impedance'termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
10. An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers having four ports interconnected such that then the third port is terminated in a matched impedance energy applied to the fourth port is delivered to the first and second ports in equal amplitude and 90-degree phase relationship; means for short circuit terminating first and second ones of said ports of each duplex coupler; means individually connecting an succedent coupler of the series through said adjustable phase control means; means gauging the adjustable phase shift control means for the couplers whereby substantially equal phase shifts are produced simultaneously in the coupling between adjacently connected couplers; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
11. An antenna system for a radio frequency energy operative device comprising; a plurality of antenna elements; a plurality of duplex couplers having four ports interconnected such that when the third port is terminated in a matched impedance energy applied to the fourth port is delivered to the first and second ports in equal amplitude and 90-degree phase relationship; means for short circuit terminating first and second ones of said ports of each duplex coupler; an individual section of transmission line connecting each said first and second ports to the corresponding short circuit termination thereof; means individually connecting an antenna element to each section of transmission line; means for varying the electrical length of each transmission line between the short circuit termination and the point of connection of an antenna element thereto; said first and second ports, transmission lines, antenna elements, means connecting, and means for varying the electrical length of each transmission line being in matched pairs for each coupler; adjustable phase control means for each coupler; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series through said adjustable phase control means; means gauging the adjustable phase shift control means for the couplers whereby substantially equal phase shifts are produced simultaneously in the coupling between adjacently connected couplers; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
12. An antenna system for a radio frequency energy operative device comprising; a plurality of duplex couplers having four ports interconnected such that when the third port is terminated in a matched impedance; energy applied to the fourth port is delivered to the first and second ports in equal amplitude and -degree phase relationship; means for short circuit terminating first and second ones of said ports of each duplex coupler; a plurality of sections of transmission line, each having a portion that provides substantially more electromagnetic coupling to surrounding space than other portions thereof, said sections of transmission line individually connecting each said first and second ports to the corresponding short circuit termination thereof; means for varying the electrical length of each section of transmission line between the short circuit termination and the adjacent coupler port; said first and second ports, corresponding sections of transmission line, and corresponding means for varying the electrical length of each transmission line section being in matched pairs for each coupler; adjustable phase control means for each coupler; means connecting said couplers in series wherein the third port of a preceding coupler of the series is connected to the fourth port of the succedent coupler of the series through said adjustable phase control means; means gauging the adjustable phase shift control means for the couplers whereby substantially equal phase shifts are produced simultaneously in the coupling between adjacently connected couplers; means providing a matched impedance termination connected to the third port of the last coupler of the series; and means connecting the fourth port of the first coupler of the series to the radio frequency operative device.
References Cited in the file of this patent UNITED STATES PATENTS 2,461,005 Southworth Feb. 8, 1949 2,848,716 Mattingly Aug. 18, 1958 2,878,472 Sterns Mar. 17, 1959 2,913,723 Thourel Nov. 17, 1959
US835155A 1959-08-20 1959-08-20 Matched antenna array Expired - Lifetime US3020549A (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3276026A (en) * 1962-05-10 1966-09-27 Lab For Electronics Inc Doppler array with plural slotted waveguides and feed switching
US3311917A (en) * 1963-08-06 1967-03-28 Csf Stepped beam slot antenna array
US3324475A (en) * 1964-02-13 1967-06-06 Decca Ltd Scanning antenna array wherein feed utilizes dispersive elements to provide nonlinear scan-frequency relationship
US3419870A (en) * 1965-05-24 1968-12-31 North American Rockwell Dual-plane frequency-scanned antenna array

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2461005A (en) * 1940-04-05 1949-02-08 Bell Telephone Labor Inc Ultra high frequency transmission
US2848716A (en) * 1957-05-03 1958-08-19 Bell Telephone Labor Inc Compartmental antenna with hybrid feed
US2878472A (en) * 1954-12-14 1959-03-17 Hughes Aircraft Co High efficiency broadband antenna array
US2913723A (en) * 1956-01-23 1959-11-17 Csf Variable pattern radar aerial

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2461005A (en) * 1940-04-05 1949-02-08 Bell Telephone Labor Inc Ultra high frequency transmission
US2878472A (en) * 1954-12-14 1959-03-17 Hughes Aircraft Co High efficiency broadband antenna array
US2913723A (en) * 1956-01-23 1959-11-17 Csf Variable pattern radar aerial
US2848716A (en) * 1957-05-03 1958-08-19 Bell Telephone Labor Inc Compartmental antenna with hybrid feed

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3276026A (en) * 1962-05-10 1966-09-27 Lab For Electronics Inc Doppler array with plural slotted waveguides and feed switching
US3311917A (en) * 1963-08-06 1967-03-28 Csf Stepped beam slot antenna array
US3324475A (en) * 1964-02-13 1967-06-06 Decca Ltd Scanning antenna array wherein feed utilizes dispersive elements to provide nonlinear scan-frequency relationship
US3419870A (en) * 1965-05-24 1968-12-31 North American Rockwell Dual-plane frequency-scanned antenna array

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