US3656167A - Dipole radio antennae - Google Patents

Abstract

Dipole whip antenna arrangements are disclosed which are capable of operating over a wide frequency band without the use of continual manual or automatic tuning. This is achieved by connecting the dipole whip antenna to the ground plane through a reactance network which is specially designed so as to match the impedance at the feed point of the dipole arrangement to a desired value over the desired frequency band. For this purpose, the reactance network is an active network, and operates by effectively cancelling out the reactance of the antenna.

Description

United States Patent Lea [15] 3,656,167 [451 Apr. 11, 1972 [73] Assignee: The Plessey Company Limited, llford, En-

gland [22] Filed: Nov. 25, 1969 [21] Appl.No.: 879,753

[52] US. Cl ..343/793, 343/816, 343/822, 343/850, 343/853, 343/860 [51] Int. Cl. ..II0lg9/l6, HOlg 21/06 [58] Field of Search ..343/793-798, 810-816, 343/799, 850-853, 845-849, 825-831, 700703, 792

[56] References Cited UNITED STATES PATENTS 2,505,511 4/1950 Vogel ..333/17 A UX 2,745,067 5/1956 True et al. ..333/17 3,160,832 12/1964 Beitman, Jr. et al.. ..333/17 1,314,095 8/1919 Reuthe ..343/845 X 2,283,617 5/1942 Wilmette ..343/828 X 2,283,618 5/1942 Wilmette ..343/828 X 2,283,619 5/1942 Wilmotte ..343/828 X 2,485,457 10/1949 Potter ..343/827 X 2,913,722 11/1959 Brueckmann ..343/724 OTHER PUBLICATIONS Microwave Transmission Circuits Ragan McGraw- Hill New York, 1958, TX 6553 R34; pp. 182-184 and 311- 314 Antennas Kraus McGraw-Hill New York, 1950 TX 7872 A6K7; pp. 279- 283 The ARRL Antenna Book The American Radio Relay League West Hartford, Conn. 1956 TK 6565 A6A6; p, 107

Primary Examiner-Herman Karl Saalbach Assistant Examiner-Marvin Nussbaum Attorney-Mason, Mason & Albright [57] ABSTRACT Dipole whip antenna arrangements are disclosed which are capable of operating over a wide frequency band without the use of continual manual or automatic tuning. This is achieved by connecting the dipole whip antenna to the ground plane through a reactance network which is specially designed so as to match the impedance at the feed point of the dipole arrangement to a desired value over the desired frequency band, For this purpose, the reactance network is an active network, and operates by effectively cancelling out the reactance of the antenna.

2 Claims, 14 Drawing Figures PATENTEBAPR 11 I972 3. 656, l 67 SHEET 3 OF 4 36 38 V K 42j 7 INVENTOR C/m Ag 55'A. L 5/:

ATTORNEYJ) DIPOLE RADIO ANTENNAE BRIEF SUMMARY OF THE INVENTION The invention relates to radio antennae, and is particularly though not exclusively, concerned with whip antennae.

The invention is concerned with the problem of providing a dipole antenna which can operate over a wide frequency band without the need for automatic or manual continuous tuning. A simple dipole antenna suffers from the disadvantage that it can only be used within a narrow frequency band. Outside the narrow frequency band for which it has been designed, a dipole antenna presents an unacceptable impedance to the equipment to which it is connected. In order to overcome this problem, it is known to provide a variable antenna tuning or matching unit which transforms the antenna impedance into a value which is acceptable to the equipment. Such aunit may be tuned manually by an operator, in which case this places demands on the operatorss time and skill. Instead, the antenna tuning unit may be designed to set itself automatically, but this inevitably results in a large increase in cost and complexity and a corresponding reduction in reliability. Even with such an automatic antenna tuning unit, the antenna can only be used for a narrow band of frequency at any one time: it cannot be used for transmission or reception of wide band signals nor for transmission or reception of a number of widely spaced frequencies simultaneously.

Accordingly, the invention provides a dipole antenna arrangement comprising a dipole antenna having a reactance network connected in series with one element of the dipole, the reactance/frequency characteristic of the network being such as to match the impedance at the feed point of the dipole to a desired value over a wide frequency band.

The use of the reactance network, in accordance with the invention, thus enables the antenna arrangement to operate over a wide frequency band without the necessity for manual or automatic tuning, and in addition enables the antenna arrangement to be used for transmission or reception of wide band signals or of a plurality of widely spaced frequency simultaneously.

BRIEF DESCRIPTION OF THE DRAWINGS Dipole whip antenna arrangements embodying the invention will now be described, by way of example only, with reference to the accompanying drawings in which:

FIGS. 1 to 13 each show, diagrammatically, a different embodiment of the invention, the circuit connections of which are shown schematically; and

FIG. 14 is a schematic circuit diagram of a reactance network for use with the antenna arrangements.

An item in anFigure which corresponds to a similar item in any other Figure is given the same reference number.

DETAILED DESCRIPTION In Figure I, the dipole whip antenna comprises twoelements 5 and 6 having afeed point 8 by means of which the energy to be radiated can be fed in or by means of which radiation energy received by the antenna can be fed out, and thelower element 5 of the dipole is connected to aground plane 9 through a two-terminal reactance network 10 having a reactance X) which varies in a predetermined manner with frequency.

The impedance, Zf, at thefeed point 8 depends on the lengths l and 1 of the two elements and 6 of the dipole. The lengths I and 1 control Zf because they determine the way in which the amplitude and phase of the current flowing in the dipole varies along its length. The two-tenninal reactance network is so designed that the reactance at its terminals so varies with frequency that the impedance Zf maintains a desired value over a wide range of frequencies. In this way, the dipole whip antenna of FIG. 1 can be used over a wide frequency range without the need for a manually or automatically tunable antenna tuning unit, and the value of Zf is automatically maintained at a value which is acceptable to the equipment to which the antenna is to be connected. The antenna can thus be used for transmission or reception of any frequency over a wide range, or for transmission or reception of wide-band signals or simultaneously occurring signals having a number of widely spaced different frequencies.

FIG. 2 shows how a connection may be made to thefeed point 8 from or to the associated equipment, not shown.

In FIG.2, thelower element 5 of the dipole whip antenna is formed by ahollow tube 12 which is electrically connected, at itsupper end 14, to theouter conductor 16 of acoaxial feeder 18 whosecentral conductor 20 connects to theupper element 6 of the antenna. Thetube 12 is connected through thetwoterminal reactance network 10 to theground plane 9. Therefore, thecoaxial feeder 18 connects thefeed point 8 of the dipole to the associated equipment, not shown.

In FIG.2, the annular space between thetube 12 and theouter conductor 16 of the coaxial feeder acts as a short-circuited length of transmission line and thus presents a reactance in parallel with the two-terminal network 10.This parallel reactance is taken into account in designing the twoterminal network.

The impedance presented to the associated equipment, not shown, by thecoaxial feeder 18 of FIG.2 will not be equal to the feed point impedance Zf; the coaxial feeder, of characteristic impedance Z0, will transform the feed point impedance Zf to a new value, Z. By appropriately dimensioning the coaxial feeder l8,.so as correspondingly to determine the characteristic impedance Z0, the impedance Zf can be transformed to Z in such a way as to provide a corresponding reduction in the effect, on the impedance Z, of variations in Z0) with frequency. Thus, the impedance transforming action of thecoaxial feeder 18 augments the effect of thereactance 10 in increasing the operating band width of the antenna.

F IG.3 shows an antenna in which the augmenting effect provided by thecoaxial feeder 18 is further increased. The arrangement of FIG.3 is generally similar to that of FIG.2, except that the diameter of theinner conductor 20 of the coaxial feeder is varied over its length. Thus, the diameter has one value over the length another diameter over a length 1 and another diameter over a length 1 In this way, the coaxial feeder acts as three impedance transformers connected in cascade thus further reducing the value of Z as compared with Z0) and thus further reducing variations in Z resulting from variations in Z0). In the embodiment of FIG.4, theouter conductor 22 of acoaxial feeder 24 itself forms thelower element 5 of the dipole whip antenna and, in a manner analogous to that shown in the previous Figures, is connected to theground plane 9 through thereactance 10. In order to prevent the coaxial feeder from short-circuiting thereactance 10, the coaxial feeder itself is coiled up, over :aregion 26, to form an inductor and thus provides r.f. isolation of the bottom of the dipole from theground plane 9. The inductance provided by thecoil region 26 of the coaxial feeder, and its variation with frequencies, has to be taken into account in designing thereactance 10. The coiled upregion 26 of thecoaxial feeder 24 of the embodiment of FIG.4 does not effect the impedancetransforming action of the coaxial feeder which, as in the embodiment of Figures 2 and 3, again augments the impedance matching effect of thereactance 10; as in the case of FIG.3, this augmenting effect can be increased by varying the relative sizes of the two conductors of the feeder along its length.

FIG.5 shows an arrangement corresponding to that of F [6.4, but thereactance network 10 and thecoiled region 26 of thecoaxial feeder 24 are enclosed in a screening tube 28 below and connected to theground plane 9. Such an arrangement can be used on vehicles and the like where it is desirable for physical protection purposes. The reactance presented at the bottom of the dipole by thenetwork 10 and theinductive region 26 is transformed by the length of transmission line formed between theouter conductor 22 of the coaxial feeder and the screening tube 28, and this has to be taken into account in designing thereactance network 10.

In the embodiment of FIG.6, the external equipment is connected to thefeed point 8 of the dipole whip antenna by means of a twin-wire or twin-strip transmission line 30, oneconductor 32 of which provides the lower element of the dipole and the other of which is connected to theother element 6. Theconductor 32 of thetransmission line 30 is connected to theground plane 9 through thereactance 10, and the bottom of the dipole is isolated, at radio frequencies, from theground plane 9 by coiling up both conductors of thetransmission line 30 over aregion 34 to form a bifilar inductor. The operation is generally similar to that described in connection with the preceding Figures, and again the impedance matching effect of thereactance 10 is augmented by the impedance transforming effect of thetransmission line 30. In a manner analogous to that shown in FIG.3, the impedance transforming effect of thetransmission line 30 of F [6.6 can be further increased by varying the sizes of the two conductors of the transmission line along their lengths as shown.

F IG.7 shows an embodiment analogous to that of FIGS in which the twin-wire transmission line 30 is arranged within a screening tube 28.

FIGS. 8 and 9 show embodiments of the invention for use where noground plane 9 is available (such as on the mast of a ship). F IG.8 corresponds to FIG.4 and consists of two dipole whip antennae arrangements, each as illustrated in FIG.4, which are combined to form a balanced pair. Thecoaxial feeders 24 of each of the two antennae of Fig. 8 are connected together to acommon feeder 34 which is arranged to feed both antennae in phase so as to provide maximum radiation at right angles to the axis of the antennae.

FIG. 9 shows an arrangement analogous to FIG. 8 in which each of the two dipole whip antennae is an antenna as shown in F IG.6.

F 16.10 shows an embodiment of the invention providing a wide band directional array. It comprises twodipole whip antennae 36 and 38, each of which is shown symbolically only but which may be of the form shown in FIGS. 1 to 7. The twoantennae 36 and 38 are spaced apart by a distance equal to one quarter of the wave-length at the mid band frequency. They are connected to be driven through acommon feeder 40 which feeds through aphase shifting circuit 42 to provide a 90 phase difference between the signals supplied to each of the antenna.

FlG.l1 shows a directional array comprising a first pair ofbalanced antennae 44 and 46, and a second pair ofbalanced antennae 48 and 50. Theantennae 44 to 50 are shown symbolically only, but each is of the form shown in FIGS. 2, 3, 4 or 6. The antennae are fed through acommon feeder 52 and aphase shifting network 54, the latter ensuring that there is a 90 phase difference between the signals supplied to the pair ofantennae 44, 46 and the signals supplied to the pair ofantennae 48, 50.

Each of the arrangement of FIGS.10 and 11 may be modified by incorporating more than two antennae, or two pairs of antennae, in order to obtain higher directivity, and the phase shift between adjacent elements or adjacent pairs of elements may be made to change with frequency so as to maintain the directivity approximately constant over a wide frequency band.

Instead of the arrangements of Figs. 10 and 11, a wide-band directional array can be constructed from a plurality of dipole whip antennae, each as disclosed herein, in which only one of the antennae is driven and the remainder parasitic. FIG.12 shows such an arrangement in which adipole whip antenna 56, which is shown only symbolically but which may take the form of an antenna as disclosed in one of the FIGS. 1 to 7, is driven through afeeder 58, while anotherdipole whip antenna 60, which again may take the form of an antenna disclosed in one of the FIGS. 1 to 7, is parasitic and has its feeder terminals short-circuited. FIG.13 shows an arrangement comprising a balanced pair ofdipole whip antennae 62, 64, connected to be driven through acommon feeder 66, and a further pair ofantennae 68, 70 which are parasitic and which have their feeder terminals cross-connected. Each of theantennae 62, 64, 68, is shown symbolically only but may be as disclosed in any one ofthe FIGS. 2, 3, 4 and 6.

It will be appreciated that each antenna shown symbolically in FIGS. 10 to 13 includes itsrespective network 10.

In the arrangement of FIGS. 12 and 13, the directivity of the array can be altered by adjusting the reactance/frequency characteristics of the twoterminal reactance networks 10 associated with the parasitic elements of the arrays.

The method of designing thereactance network 10, as used in the embodiments described, is first to calculate or measure the value of reactance required at each frequency. In one example of a centre-fed whip antenna with a bandwidth of approximately one octave, the reactance required is inductive at the lowest frequency. The reactance falls with increasing frequency, becoming zero, i.e. a short-circuit, at mid-band. At higher frequencies the reactance becomes capacitive and increases steadily up to the top frequency. This reactance variation is a mirror-image of the reactance of a series resonant circuit. Because it has a negative slope, it cannot be realised by a passive network. It can, however, be derived from a seriesresonant circuit by means of an impedance converter. One example of impedance converter which can be used is shown in FIG. 14 and consists of a wide-band amplifier 70 with a voltage gain of +2, a high input impedance and a low output impedance. If an impedance Z is connected as a feed-back path between output and input, the input impedance is-Z.Thus, a suitable seriesresonant circuit 72 is connected as the feedback path, so that the input impedance of the amplifier has the desired mirror-image reactance variation. The reactance network produced in this way may be said to produce the desired wide-band propoerty by cancelling out the reactance of the antenna. In order to do this it has to supply the reactive power associated with this reactance. Hence an active, or power-conversion device is necessary.

It will be appreciated that many modifications may be made to the embodiments described without departing from the scope of the invention. As an example, it may be noted that the arrangement of FIG. 1 may be modified by connecting thereactance network 10 to thefeed point 8, and feeding the antenna between the bottom end of theelement 5 and the ground plane.

Although the specific embodiments described are all whip antennae, the invention is not limited to whip antennae.

What is claimed is:

l. A dipole antenna arrangement, comprising a dipole antenna having two antenna elements and a feedpoint,

a reactance network comprising a wide-band amplifier constituting an active impedance-converting device, a series resonant circuit, and means connecting the series resonant circuit to provide a negative feed-back path across the amplifier, and

means connecting the reactance network in circuit with one element of the dipole,

the gain of the amplifier and the impedance of the resonant circuit being so chosen that the effective overall input impedance of the amplifier varies with frequency to give the network a reactance/frequency characteristic such as to match the impedance at the feedpoint of the dipole to a desired value over a wide frequency range.

2. An antenna arrangement according to claim 1, comprising afurther dipole antenna having two antenna elements and a feedpoint,

a further reactance network comprising a wide-band amplifier constituting an active impedance-converting device, a series resonant circuit, and means connecting the series resonant circuit to provide a negative feedback path across the amplifier,

means connecting the further reactance network in series with one element of the further dipole,

the gain of the amplifier and the impedance of the resonant circuit being so chosen that the effective overall input impedance of the amplifier varies with frequency to give the further network a reactance/frequency characteristic such as to match the impedance at the feedpoint of the 5 further dipole to a desired value over a wide frequency range.

Claims (2)

1. A dipole antenna arrangement, comprising a dipole antenna having two antenna elements and a feedpoint, a reactance network comprising a wide-band amplifier constituting an active impedance-converting device, a series resonant circuit, and means connecting the series resonant circuit to provide a negative feed-back path across the amplifier, and means connecting the reactance network in circuit with one element of the dipole, the gain of the amplifier and the impedance of the resonant circuit being so chosen that the effective overall input impedance of the amplifier varies with frequency to give the network a reactance/frequency characteristic such as to match the impedance at the feedpoint of the dipole to a desired value over a wide frequency range.

2. An antenna arrangement according to claim 1, comprising a further dipole antenna having two antenna elements and a feedpoint, a further reactance network comprising a wide-band amplifier constituting an active impedance-converting device, a series resonant circuit, and means connecting the series resonant circuit to provide a negative feedback path across the amplifier, means connecting the further reactance network in series with one element of the further dipole, the gain of the amplifier and the impedance of the resonant circuit being so chosen that the effective overall input impedance of the amplifier varies with frequency to give the further network a reactance/frequency characteristic such as to match the impedance at the feedpoint of the further dipole to a desired value over a wide frequency range.

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