EP0542447B1

EP0542447B1 - Flat plate antenna

Info

Publication number: EP0542447B1
Application number: EP19920309808
Authority: EP
Inventors: Martin Stevens Dr. Smith; Dean Dr. Kitchener
Original assignee: Northern Telecom Ltd
Current assignee: Nortel Networks Ltd
Priority date: 1991-11-15
Filing date: 1992-10-27
Publication date: 1996-01-24
Anticipated expiration: 2012-10-27
Also published as: GB2261554B; JPH0645820A; EP0542447A1; DE69207865D1; DE69207865T2; GB2261554A; GB9124291D0

Description

This invention relates to flat plate antennas (also known as layered antennas) having either directional or omnidirectional field patterns in azimuth with limited elevation radiation patterns.
Conventional dipole antennas in which a pair of colinear quarter wavelength radiators are fed in anti-phase will produce a substantially omni-directional radiation pattern in a plane normal to the axis of the radiators. If the radiators are placed parallel to and a quarter of a wavelength from a reflecting ground plane the radiation pattern becomes substantially directional, see e.g. EP-A-355898 (Rammos). If several radiators are flat plate vertically, the radiation pattern is substantially in azimuth and restricted in elevation. An important factor in the design of an antenna is the gain of the antenna. Provision of a reflector will increase the gain in front of the antenna while reducing the gain behind. For modern telecommunications application at high frequencies, e.g. above 100 MHz, apart from the electrical performance of the antenna other factors need to be taken into account, such as size, weight, cost and ease of construction of the antenna. Depending on the requirements an antenna can be either a single radiating element (e.g. one dipole) or an array of like radiating elements.
According to one embodiment of the invention there is provided a flat plate antenna having at least one radiating element comprising:

a metallic ground plane having a pair of identical rectangular apertures in alignment;
colinear probes each projecting in opposite direction into a respective aperture to form a dipole, and;
a feed network conductor pattern connected to and arranged to feed the probes in antiphase whereby each probe radiates through its respective aperture;
wherein the feed network conductor pattern and the probes are formed on an insulating substrate adjacent to and spaced at a uniform distance to the ground plane, the probes being continuations of the feed network conductor pattern, and;
wherein the feed network conductor pattern is positioned so as to be in alignment with unapertured portions of the ground plane in a microstrip configuration and the dimensions of the apertures in relation to the overall dimensions of the ground plane are such that the edges of the portions of the ground plane defining the edges of the apertures parallel to the probes act as parasitic radiating elements to thereby determine the beamshape.

In a further embodiment, the antenna includes a second ground plane having the same arrangement of apertures as the first ground plane, wherein the first ground plane, the feed network and the second ground plane together form a triplate structure.
In a further embodiment of the antenna a plurality of like radiating elements are formed in alignment in a common ground plane with a common feed network conductor pattern arranged to feed all the probes having one orientation in phase and all the probes having an opposing orientation in antiphase.
The antenna may further include a reflector plane spaced from the rear of the antenna. The ground planes may be formed as a stamped aluminium sheet. The feed network and the probes can be formed as a printed circuit pattern on an insulating substrate. The feed network can be separated from a ground plane by means of a foamed dielectric sheet.
In accordance with a further aspect of the invention, there is provided a method of transmitting microwave signals comprising the steps of providing microwave signals to a pair of colinear probes in antiphase, the feed probes each being associated with a respective aperture in a ground plane spaced at a uniform distance from the probes, whereby each probe radiates through its respective aperture and couples parasitically with the edges of said aperture to thereby determine the beam shape.
Embodiments of the invention will now be described with reference to the accompanying drawings, in which:-

Fig. 1 illustrates a flat plate antenna having a dipole pair with a feed network formed in microstrip;
Fig. 2 is a schematic side view of the antenna of Fig. 1 on the section line 2-2 of Fig. 1;
Fig. 3 is an exploded perspective view of a triplate version of the single element antenna of Figs. 1 and 2;
Fig. 4 is an exploded perspective view of a triplate single element antenna with a back reflector;
Fig. 5 shows the measured azimuth radiation pattern for an antenna constructed in (a) microstrip and (b) triplate, both with a back reflector, and;
Fig. 6 illustrates a four element microstrip antenna array.

The flat plate antenna element shown in Figs. 1 and 2 comprises an insulating substrate 10 to one side of which is positioned a metallic ground plane 12 having a pair of identical rectangular apertures 14, 16. On the opposite side of the substrate there is positioned a metallic conductor pattern which consists of a pair of radiating probes 18, 20 and a common feed network 22a, 22b. A feed point 24 is provided for connection to an external feed (not shown). The feed network 22a, 22b is positioned so as to form a microstrip transmission line with portions of the ground plane defining the rectangular apertures. The position of the feed point 24 is chosen so that when an r.f. signal of a given frequency is fed to the network the relative lengths of the two portions 22a and 22b of the network are such as to cause the pair of probes 18 and 20 to be fed in antiphase, thereby creating a dipole antenna radiating element structure. Furthermore, the dimensions of the rectangular apertures and the bounding portions of the ground plane are chosen so that the bounding portions 26, 28 parallel with the probes 18, 20 act as parasitic antenna radiating elements, which together with the pair of radiating probes 18, 20 shape the radiation pattern of the antenna.
Fig. 3 shows a triplate version of the antenna of Figs. 1 and 2 in which a second ground plane 30 identical with ground plane 12 is placed on the other side of the substrate 10. The second ground plane is spaced from the plane of the feed network by dielectric spacing means (not shown) so that the feed network is equally spaced from both ground planes. In practice the feed network can be formed by conventional printed circuit techniques on a fibre glass board and the ground planes can be stamped out of aluminium sheets. Spacing between the network and the ground planes can be determined by foamed dielectric sheets or dielectric studs interposed between the various layers. To provide a degree of directionality for the antenna a metallic back reflector 32 can be attached to the antenna as shown in Fig. 4.
An experimental single element antenna was constructed as shown in Fig. 1 and 2 using a fibre glass substrate board 10 of 1.6mm thickness on which the feed network 22a, 22b and radiating probes 18, 20 were formed as printed circuitry. The overall antenna width was 80mm and its length was 115mm. Each aperture was 40mm by 60mm. Each probe was 26.5mm long. The feed network was in general 5mm wide but parts of it were only 3mm wide to achieve suitable impedance matching. A reflector 32, 40mm wide by 115mm long, was spaced 40mm from the radiating element. Fig. 5a shows the measured azimuth radiation pattern for this antenna at a frequency of 1795MHz. It will be noted that a beamwidth of approximately 120° is obtained with a peak gain of 6dBi.
A second single element triplate antenna was constructed as shown in Fig. 4 but with a modified feed network. The wide portions of the feed network were 3.5mm and the narrow portions were 2mm wide. The overall dimensions were still 80mm by 115mm and the dimensions of the apertures were again 40mm by 60mm. The back reflector of 40mm width was retained at a spacing of 40mm but the ground plane spacing was changed to 2.4mm and the effective dielectric constant for the structure was equal to unity. The azimuth radiation pattem at 1795 MHz is shown in Fig. 5b.
Finally a four element microstrip array was built using element apertures 40mm by 60mm as shown in Fig. 6. A modified feed network having a central feed point 40 incorporated additional lengths of printed circuit track 42 to provide the necessary phase adjustments for the individual probe feeds. All the probes having one orientation are fed in phase by the network down one side of the array and all the probes having opposite orientation are fed in antiphase by the network on the other side of the array.
The element spacing was 115mm (0.69 λ at 1795MHz) and a back reflector was attached as before. The array has a 3dB azimuth beamwidth of approximately 120°, a good front-to-back ratio and a low cross-polar level.

Claims

A flat plate antenna having at least one radiating element comprising:
a metallic ground plane (12) having a pair of identical rectangular apertures (14,16) in alignment;

a pair of colinear probes (18,20) each projecting in an opposite direction spaced from a respective aperture to form a dipole, and;

a feed network conductor pattern (22a, 22b) connected to and arranged to feed the probes in antiphase whereby each probe radiates through its respective aperture;

wherein the feed network conductor pattern and the probes are formed on an insulating substrate adjacent to and spaced at a uniform distance to the ground plane, the probes being continuations of the feed network conductor pattern, and;

wherein the feed network conductor pattern is positioned so as to be in alignment with unapertured portions of the ground plane in a microstrip configuration and the dimensions of the apertures in relation to the overall dimensions of the ground plane are such that the edges of the portions of the ground plane defining the edges of the apertures parallel to the probes act as parasitic radiating elements to thereby determine the beam shape.
A flat plate antenna according to claim 1 further comprising:
a second metallic ground plane (30) having a pair of identical rectangular apertures in alignment, and;

wherein the feed network conductor pattern is positioned so as to be in alignment with unapertured portions of the first and second ground planes in a triplate configuration.
A flat plate antenna according to claim 1 or 2, having a plurality of radiating elements formed as a linear array, the pairs of probes of all the radiating elements being in alignment, the antenna having a feed network conductor pattern arranged to feed all the probes having one orientation in phase and all the probes having an opposing orientation in antiphase.
A flat plate antenna according to any one of claims 1 to 3, including a reflector plane (32) spaced from the rear of the antenna.
A flat plate antenna according to any one of claims 1 to 3 wherein the ground planes are each formed as a stamped aluminium sheet.
A flat plate antenna according to any one of claims 1 to 3, wherein the feed network and the probes are formed as a printed circuit pattern on an insulating substrate (10).
A flat plate antenna according to any one of claims 1 to 3, wherein there is a foamed dielectric spacer positioned between the feed network and the ground plane.
A method of transmitting microwave signals comprising the steps of providing microwave signals to a pair of colinear probes in antiphase, the feed probes each being associated with a respective aperture in a ground plane spaced at a uniform distance from the probes, whereby each probe radiates through its respective aperture and couples parasitically with the edges of said aperture to thereby determine the beam shape.