AU670130B2

AU670130B2 – A dipole
– Google Patents

AU670130B2 – A dipole
– Google Patents
A dipole

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Publication number
AU670130B2

AU670130B2
AU49862/93A
AU4986293A
AU670130B2
AU 670130 B2
AU670130 B2
AU 670130B2
AU 49862/93 A
AU49862/93 A
AU 49862/93A
AU 4986293 A
AU4986293 A
AU 4986293A
AU 670130 B2
AU670130 B2
AU 670130B2
Authority
AU
Australia
Prior art keywords
dipole
radiating elements
radiating
proximal
radiating element
Prior art date
1992-08-07
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)

Ceased

Application number
AU49862/93A
Other versions

AU4986293A
(en

Inventor
Roger John Butland
William Emil Heinz
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Commscope Technologies LLC

Original Assignee
Deltec New Zealand Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
1992-08-07
Filing date
1993-08-06
Publication date
1996-07-04

1993-08-06
Application filed by Deltec New Zealand Ltd
filed
Critical
Deltec New Zealand Ltd

1994-03-03
Publication of AU4986293A
publication
Critical
patent/AU4986293A/en

1996-07-04
Application granted
granted
Critical

1996-07-04
Publication of AU670130B2
publication
Critical
patent/AU670130B2/en

2000-11-30
Assigned to DELTEC TELESYSTEMS INTERNATIONAL LIMITED
reassignment
DELTEC TELESYSTEMS INTERNATIONAL LIMITED
Request to Amend Deed and Register
Assignors: DELTEC NEW ZEALAND LIMITED

2002-09-12
Assigned to ANDREW CORPORATION
reassignment
ANDREW CORPORATION
Alteration of Name(s) in Register under S187
Assignors: DELTEC TELESYSTEMS INTERNATIONAL LIMITED

2013-08-06
Anticipated expiration
legal-status
Critical

Status
Ceased
legal-status
Critical
Current

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Classifications

H—ELECTRICITY

H01—ELECTRIC ELEMENTS

H01Q—ANTENNAS, i.e. RADIO AERIALS

H01Q9/00—Electrically-short antennas having dimensions not more than twice the operating wavelength and consisting of conductive active radiating elements

H01Q9/04—Resonant antennas

H01Q9/16—Resonant antennas with feed intermediate between the extremities of the antenna, e.g. centre-fed dipole

H01Q9/28—Conical, cylindrical, cage, strip, gauze, or like elements having an extended radiating surface; Elements comprising two conical surfaces having collinear axes and adjacent apices and fed by two-conductor transmission lines

Description

{P
OPI DATE 03/03/94 APPLN. ID 49862/93 AOJP DATE 26/05/94 PCT NUMBER PCT/NZ93/00064 I1illlll lll11111111 Ill 11111 Il il lill I AU9349862 IN1 (51) International Patent Classification 5 (11) International Publication Number: WO 94/03940 H01Q 9/16 Al (43) International Publication Date: 17 February 1994 (17.02.94) (21) International Application Number: (22) International Filing Date: Priority data: 243877 7 August PCT/NZ93/00064 6 August 1993 (06.08.93) (81) Designated States: AT, AU, BB, BG, BR, BY, CA, CH, CZ, DE, DK, ES, FI, GB, HU, JP, KP, KR, KZ, LK, LU, MG, MN, MW, NL, NO, NZ, PL, PT, RO, RU, SD, SE, SK, UA, US, VN, European patent (AT, BE, CH, DE, DK, ES, FR, GB, GR, IE, IT, LU, MC, NL, PT, SE), OAPI patent (BF, BJ, CF, CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG).
Published With international search report.
1992 (07.08.92) (71) Applicant (for all designated States except US): DELTEC NEW ZEALAND LIMITED [NZ/NZ]; 84 Main Road, Tawa, Wellington 6230 (NZ).
(72) Inventors; and Inventors/Applicants (for US only) BUTLAND, Roger, John [NZ/NZ]; 47 John Sims Drive, Broadmeadows, Wellington 6004 HEINZ, William, Emil [NZ/ NZ]; 47 Beazley Avenue, Wellington 6004 (NZ).
(74) Agents: TERRY, John, Kinnear et al.; Baldwin, Son Carey, 342 Lambton Quay, Wellington 6001 (NZ).
(54) Title: A DIPOLE (57) Abstract A dipole having radiating elements 14) which taper from the proximal end of the radiating element to the distal end of the radiating element. Electrical coupling is provided between adjacent lateral edges of the radiating elements by means of spaced apart tabs (10, 11, 12, 13). Cut-away portions 5a) are provided between the proximal end and the tabs By adjusting the distance between and the extent to which the tabs (10, 11, 12, 13) overlap the real part of the impedance of the dipole may be adjusted. The dipole may thus be configured to be directly driven from a feed-line without requiring matching components. This results in reduced complexity and losses. The dipole also exhibits reduced impedance variation, increasing the bandwidth of the dipole.
A h -rZ~Z~u~L m-l-i~ ~I WO 94/03940 PCT/NZ93/0064 -1- A DIPOLE Technical Field The present invention relates to a dipole. The radiating elements of the antenna have a novel shape with electrical coupling being provided between adjacent lateral edges of the radiating elements.
Background of the invention To the present time various radiating elements have been used in dipole antennas ranging from cylindrical radiating elements to planar radiating elements such as the «bow tie» dipole. The radiating elements of the «bow tie» dipole antenna increase in width from the antenna drive point to the distal ends of the radiating elements. Conventional analysis suggests that best performance will be obtained when the i i radiating elements increase in width from the drive point to their distal ends.
Conventional thinking also suggests that matching should be effected at the antenna drive point. Dipole antennas incorporating known radiating elements have however suffered from relatively large impedance variations, restricting the bandwidth of the dipole i antenna. Further, it has been difficult to adjust the resistive part of the impedance of a dipole antenna, resulting in the need for complex matching and incurring matching losses.
-I Y C- -2- Disclosure of the invention It is desirable to provide a dipole and radiating elements therefor which overcome at least some of the aforegoing disadvantages, or at least provide the public with a useful choice.
According to one aspect of the invention there is provided a dipole having first and second radiating elements, the proximal ends of said radiating elements being connected to respective terminals of a drive point, the distal ends of said radiating elements extending outwardly from said drive point, wherein reactive coupling is provided between said first and second radiating elements by spaced apart tabs positioned towards respective proximal ends and lateral edges of said radiating c* I elements.
o o Preferably reactive coupling is provided between both lateral edges of both radiating elements. The radiating elements preferably taper from the proximal end to the distal end thereof. Preferably, cut-away portions are provided between the tabs and the proximal ends of the radiating elements.
ipti :Brief Description of the drawings The invention will now be described by way of example with reference to the accompanying drawings in which: Figure 1: shows the preferred form of radiating element.
i L-.3 JRG:NB:#17215.SPC I May 1996 -91. Id.- I I WO 94/03940 PCT/NZ93/00064 -3- Figure 2: Figure 3: Figure 4a: Figure 4b: Figure 5: shows a perspective view of a dipole incorporating two radiating elements of the form shown in figure i.
shows a cross-sectional side view of the feed arrangement to the dipole shown in figure 2.
shows an alternative feed arrangement to that shown in figure 3.
shows the shape of the radiating element used in the embodiments shown in figures 4a and shows a further alternative feed arrangement.
shows an alternative feed arrangement for use in compact antennas.
shows an alternative feed arrangement to increase the height of a dipole above the ground plane for beam width adjustment.
shows an alternative feed arrangement in which the radiating elements are fed directly by the supports.
indicates the dimensions of the preferred radiating element shown in figure i.
shows an alternative coupling arrangement between the tabs of the radiating elements.
Figure 6: Figure 7: Figure 8: Figure 9: Figure 10: CIIYZ WO 94/03940 PC/NZ93/00064 -4- Best mode for carryin out the invention Referring to figure 1 the preferred form of radiating element according to the invention is shown. The radiating element is of generally diamond shape having truncated proximal and distal ends, 1 and 2 respectively. Tabs 3 and 4 are provided proximate the lateral edges 6,6a of the radiating element towards the proximal end thereof. The tabs 3 and 4 step up or down relative to the plane of the radiating element at transitions 8. Cut-away portions 5 and 5a are provided between the proximal end and the respective tabs 3 and 4. These cut-away portions are preferably angled away from the proximal end towards the distal end of the radiating element. Apertures 7 may be provided to secure a terminal 15 (see figure 3) to the radiating element.
Referring now to figure 2 a dipole antenna incorporating two radiating elements of the form shown in figure 1 is shown in perspective. Figure 3 is a side cross-sectional view showing the feed arrangement I of the antenna shown in figure 2. Radiating elements 9 and 14 are supported above a ground plane 17 by stand-offs 18. Stand-offs 18 provide the mechanical support for radiating elements 9 and 14 as well as electrically connecting the radiating elements to the ground plane 17.
Feed-line 20 supplies the driving signal to radiating elements 9 and 14. The external conductor of feedline 20 is electrically connected to radiating element 9 and ground plane 17. The central conductor 1 is electrically connected to terminal 15 at the drive point. A dielectric block 19 may be provided between stand-offs 18 for mechanical stability and matching a It.- PCT/Nz 9 3 0 0 0 64 RECEIVED 30 SEP 194 purposes. Terminal 15 may be secured to radiating element 14 by suitable fastening means 16.
Referring again to figure 2 it will be seen that the tabs 10 and 11 of radiating element 9 are off-set with respect to the plane of radiating element 9. Tabs 12 and 13 of radiating element 14 are likewise offset with respejt to the plane of radiating element 14.
The pairs of tabs 11 and 12 and 10 and 13 overlap to provide electrical coupling between the adjacent lateral edges of the radiating elements. Adjustment of this «electrical coupling» enables the real part of the drive point impedance to be adjusted. By altering the degree to which the tabs overlap and the space between the tabs the real part of the drive point impedance of a dipole can be adjusted to a desired magnitude. The susceptive imaginary) part of the drive point admittance can be adjusted by varying the drive point capacitance or the length of standoffs 18. For the embodiment shown in figure 3 the drive point capacitance may be varied by bending terminal 15 closer to radiating element 9 or by altering the size of dielectric block 19. The drive point admittance can additionally be varied by positioning a short circuit between the transmission stand-offs 18 at the required height.
The applicant has found that by providing impedance matching by way of tabs on the lateral edges of the radiating elements the impedance variation at the dipole drive point is decreased. This results in an increased useable bandwidth for the dipole antenna.
Matching this way also allows the real part of the impedance of a dipole to be reduced, making matching easier and reducing feed losses. Where a single dipole is used the dipole may be directly connected to a driving signal without matching (the real part of R the impedance can be brought close to 50 ohms by adjusting the tab positions).
Lij 2/AMNDED SHEET
IPEA/AU
fA PT/Nz 9 3 0 006 4 o RECEIVED 3 0 SEP 1994 -6- Contrary to conventional practice the radiating element of the present invention tapers from the proximal end to the distal end thereof. The distal end is preferably less than half the width of the proximal end (i.e between lateral edges 6 and 6a) More preferably the distal end is about a quar..er the width of the radiating element at the proximal end.
The cut-away portions 5 and 5a between the tabs and the proximal end 1 give improved performance. Cutaway portions 5 and 5a are preferably of the triangular shape shown. The proximal edges la and Ib are preferably inclined towards the distal end of the radiating element.
Referring now to figures 4a and 4b an alternative feed arrangement is shown. In this embodiment the proximal ends of the radiating elements 24a and 24b have been extended to form a point 24 (see figure 4b). The points 24a and 24b overlap at the drive point between the stand-offs to provide a susceptance control gap The distance between points 24a and 24b can be adjusted to provide appropriate susceptive compensation. The external conductor ed-line 27 is electrically connected to radiating element 22 and the central conductor 28 is connected to point 24b of radiating element 23.
Referring now to figure 5 an alternative feed arrangement is shown. The radiating elements used in this embodiment are of the same shape as shown in figure 4b. In this case rather than bending the points 24a and 24b as in figure 4a the points 28a and 28b overlap. This means that radiating elements 29 and 30 .lo not lie in the same plane (as.in the AMaANIDED SHEET
IPEA/AU
‘C NOW- I PCT/Nzg 3/ 0 0 0 6 4 SRECEIVED 3 O SEP 1994 -7embodiment shown in figure 4a). The external conductor of feed-line 31 is connected to radiating element 29 and the central conductor 32 is connected to point 28b of radiating element 30. To achieve a better radiation pattern in the far field radiating element 30 may be angled slightly down from its proximal end to its distal end and radiating element 29 may be angled slightly up from its proximal end to its distal end. In this way the average height of each radiating element above the ground plane may be substantially the same.
Referring now to figure 6 an embodiment for use in compact antennas is shown. The dipole shown in figure 6 is of the same general construction as the dipole shown in figures 2 and 3. In this case however a greater volume of dielectric 32 has been provided between stand-offs 33. Dielectric 32 may be shaped to i fit the entire’or any fraction of the space between supports 33 depending on the required shortening of the stand-offs 33. The shortening factor is inversely proportional to the square root of the dielectric constant. Shortening in this manner enables the stand-offs 33 to be reduced in length whilst still maintaining a quarter wavelength electrical balun section.
i Figure 7 shows an alternative feed arrangement in j which the dipole is raised higher than usual above the ground plane. Normally, the radiating elements are 1 positioned a quarter wavelength above the ground plane. In some cases however it is desirable to increase the height of the dipole above the ground plane for beam width adjustment. In this case a stub short circuit 34 is provided between stand-offs 35 at the position the ground plane would normally be so that the distance between the stub short circuit V 0 AMENDED SHEET
IPEA/AU
‘iz093 0 0 0 6 4 RECEIVED 3 0 SEP 1994 -8and the dipole is about a quarter wave length). The susceptive part of the drive point admittance can be adjusted by varying the position of stub 34.
Referring now to figure 8 an embodiment is shown in which the dipole is fed directly via the stand-offs.
This does away with the need for feed-line 20 shown in figure 3. By controlling the relative positions of the tabs and the drive point reactance of the dipole can be adjusted for 100 ohms balanced feed. In this case the stand-offs 37, 38 are electrically isolated from the ground plane 36. Stand-offs 37 and 38 are adjusted in size and spacing to form a 100 ohm transmission line. Stand-offs 37 and 38 are electrically connected to radiating elements 39 and 40. Stand-offs 37 and 38 may be directly connected to a 100 ohm feed-line which may also feed an adjacent dipole of a corporate feed assembly. The feeding junction of this interconnecting transmission line will be equivalent to 50 ohms. This enables the direct connection of a 50 ohm co-axial cable with a simple balun to feed the pair of dipoles, without requiring an impedance transformation. This reduces the cost of matching components and reduces power loss.
Referring now to figure 9 the dimensions of the preferred radiating element are given below in table i 1. The distances are given as fractions of the wavelength at the frequency of operation. It will be appreciated that these lengths will be scaled depending upon the frequency of operation. Angle m is the angle between the edge of the cut-away portions and the longitudinal direction of the radiating elements. Angle m will preferably be between 450 to 750, most preferably m will be about 600.
SRA4> AMENDED SHEET
IPEA/AU
1 L. 1 A I I RECEIVED 30 SEP 1994 -9- Table 1 A 0.18L G 0.066L B 0.048L H 0.015L C 0.08L I 0.065L D 0.053L J 0.053L E 0.08L K 0.065L F 0.18L L 0.015L Where L is the wavelength at the frequency of operation.
It is to be appreciated that the dipole of the present invention may be utilised in a number of antenna configurations. For example, the dipole of the invention may be incorporated into microstrip, matstrip or printed circuit board antennas. The radiating elements may-be printed on opposite sides of a thin insulating board with the printed tabs overlapping. The board could be mounted above a ground plane with insulating material between the printed board and ground plane. It is to be appreciated that the dipole of the invention may find application in a wide range of antennas.
It will thus be seen that the present invention provides a dipole antenna in which both the real part of the drive point impedance and the susceptive part of the admittance can be varied. This makes matching simpler and results in lower losses. The i dipole of the invention also has decreased impedance variation resulting in a dipole having a greater bandwidth.
Industrial Applicability RA, The dipole of the invention may find wide application in a number of antenna configurations. The dipole of the invention is suitable for use in wide bandwidth TO» low loss antennas. The dipole of the invention may find particular application in panel antennas and other multi-element antennas. AMJENED SHEET TPA.AI I i

Claims (18)

1. A dipole having first and second radiating elements, the proximal ends of said radiating elements being connected to respective terminals of a drive point, the distal ends of said radiating elements extending outwardly from said drive point, wherein reactive coupling is provided between said first and second radiating elements by spaced apart tabs positioned towards respective proximal ends and lateral edges of said radiating elements.

2. A dipole as claimed in claim 1 wherein pairs of adjacent tabs connected to said first and second radiating elements lie in substantially overlapping relationship.

3. A dipole as claimed in claim 1 or claim 2 wherein reactive coupling t is provided between both lateral edges of both radiating elements. a a:a

4. A dipole as claimed in any one of the preceding claims wherein for each pair of tabs one tab is above and the other is below the plane of the respective radiating element.

5. A dipole as claimed in any one of the preceding claims wherein the radiating elements taper from the proximal ends to the distal ends thereof.

6. A dipole as claimed in any one of the preceding claims wherein the a width of each radiating element at its distal end is less than half the width of the radiating element between its lateral edges towards its proximal end.

7. A dipole as claimed in any one of claims 1 to 4 wherein the width of each radiating element at its distal end is about one quarter of the width of each radiating element between its lateral edges towards its proximal end.

8. A dipole as claimed in any one the preceding claims wherein the radiating elements lie in substantially the same plane.

9. A dipole as claimed in any one of the preceding claims wherein the longitudinal axes of the radiating elements are generally co-axial. A dipole as claimed in any of the preceding claims wherein proximal edges extend from the proximal ends to the lateral edges and are inclined towards the distal ends of the radiating elements.

Z JRG:NB:#17215.SPC 1 May 1996 0 A’ A’. ,I .u 3– 11

11. A dipole as claimed in claim 10 wherein the proximal edges of the radiating elements are inclined at an angle of about 450 to 750 to the longitudinal axes of each radiating element.

12. A dipole as claimed in claim 10 wherein the proximal edges of the radiating elements are inclined at an angle of about 600 to the longitudinal axes of each radiating element.

13. A dipole as claimed in any one of the preceding claims wherein the reactive coupling between said tabs provides for adjustment of the substantially real part of the drive point impedance.

14. A dipole as claimed in any one of the preceding claims wherein the proximal ends of the radiating elements overlap to provide susceptive compensation.

A dipole as claimed in any one of the preceding claims wherein the radiating elements are driven directly from a feed-line via stand-offs.

16. A dipole substantially as herein described with reference to the accompanying drawings.

17. An antenna including a dipole according to any one of the preceding claims.

18. An antenna including two dipoles as claimed in claim 15 wherein the dipoles are driven from a common feed-line via respective standoffs. C DATED: I May 1996 CARTER SMITH BEADLE Patent Attorneys for the Applicant: 4 DELTEC NEW ZEALAND LIMITED «».sI JRG:NB:#17215.SPC I Mhy 1996

AU49862/93A
1992-08-07
1993-08-06
A dipole

Ceased

AU670130B2
(en)

Applications Claiming Priority (3)

Application Number
Priority Date
Filing Date
Title

NZ24387792

1992-08-07

NZ243877

1992-08-07

PCT/NZ1993/000064

WO1994003940A1
(en)

1992-08-07
1993-08-06
A dipole

Publications (2)

Publication Number
Publication Date

AU4986293A

AU4986293A
(en)

1994-03-03

AU670130B2
true

AU670130B2
(en)

1996-07-04

Family
ID=19924051
Family Applications (1)

Application Number
Title
Priority Date
Filing Date

AU49862/93A
Ceased

AU670130B2
(en)

1992-08-07
1993-08-06
A dipole

Country Status (4)

Country
Link

JP
(1)

JPH07509822A
(en)

AU
(1)

AU670130B2
(en)

NZ
(1)

NZ255598A
(en)

WO
(1)

WO1994003940A1
(en)

Families Citing this family (4)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

DE19646100A1
(en)

*

1996-11-08
1998-05-14
Fuba Automotive Gmbh

Flat antenna

RU2001113151A
(en)

*

2001-05-16
2003-06-10
Сергей Васильевич Белоусов

ANTENNA, VIBRATOR AND DIRECTOR

US7205953B2
(en)

*

2003-09-12
2007-04-17
Symbol Technologies, Inc.
Directional antenna array

US10992066B2
(en)

*

2017-05-12
2021-04-27
Telefonaktiebolaget Lm Ericsson (Publ)
Broadband antenna

Citations (3)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US2523728A
(en)

*

1947-05-14
1950-09-26

Bendix Aviat Corp

High impedance antenna

JPS60233701A
(en)

*

1984-05-07
1985-11-20

Fuji Electric Co Ltd

Acceleration arithmetic device

JPS62122304A
(en)

*

1985-11-21
1987-06-03

Mitsubishi Electric Corp

Printed dipole antenna

Family Cites Families (4)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

FR2451113A2
(en)

*

1978-06-19
1980-10-03
France Etat
Folded dipole aerial giving circular polarisation – supply wire short relative to two excited half plates to provide aerial short circuited at its ends

FR2441278A1
(en)

*

1978-11-13
1980-06-06
Coppin Georges
Metallic mesh UHF aerial – uses two circular symmetrical planar active elements to provide enhanced reception and transmission

JPS60237701A
(en)

*

1984-05-11
1985-11-26
Yagi Antenna Co Ltd
Self-complementary antenna

GB2208043B
(en)

*

1987-08-11
1991-11-06
Gen Electric Co Plc
A triplate fed dipole

1993

1993-08-06
WO
PCT/NZ1993/000064
patent/WO1994003940A1/en
active
Application Filing

1993-08-06
AU
AU49862/93A
patent/AU670130B2/en
not_active
Ceased

1993-08-06
NZ
NZ255598A
patent/NZ255598A/en
unknown

1993-08-06
JP
JP6505207A
patent/JPH07509822A/en
active
Pending

Patent Citations (3)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US2523728A
(en)

*

1947-05-14
1950-09-26
Bendix Aviat Corp
High impedance antenna

JPS60233701A
(en)

*

1984-05-07
1985-11-20
Fuji Electric Co Ltd
Acceleration arithmetic device

JPS62122304A
(en)

*

1985-11-21
1987-06-03
Mitsubishi Electric Corp
Printed dipole antenna

Also Published As

Publication number
Publication date

AU4986293A
(en)

1994-03-03

WO1994003940A1
(en)

1994-02-17

NZ255598A
(en)

1996-06-25

JPH07509822A
(en)

1995-10-26

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Legal Events

Date
Code
Title
Description

2000-11-30
HB
Alteration of name in register

Owner name:
DELTEC TELESYSTEMS INTERNATIONAL LIMITED

Free format text:
FORMER NAME WAS: DELTEC NEW ZEALAND LIMITED

2002-09-12
PC
Assignment registered

Owner name:
ANDREW CORPORATION

Free format text:
FORMER OWNER WAS: DELTEC TELESYSTEMS INTERNATIONAL LIMITED

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