GB2202091A

GB2202091A - Microstrip antenna

Info

Publication number: GB2202091A
Application number: GB08705430A
Authority: GB
Inventors: David John Gunton
Original assignee: British Gas PLC
Current assignee: British Gas PLC
Priority date: 1987-03-09
Filing date: 1987-03-09
Publication date: 1988-09-14
Anticipated expiration: 2007-03-09
Also published as: GB8705430D0; GB2202091B

Abstract

An antenna assembly comprises a first laminar structure which includes a sheet of dielectric material 1 having on one side a contiguous metal sheet 3 and on the other side a strip transmission line 2 adapted to be coupled with signal feeding means, and a second laminar structure, one side of which is in contact with the transmission line, and having on the other side, at least one region but preferably at least two concentrically arranged regions of a coated or cladded metal which serves as a radiator, characterised in that the transmission line is non-symetrically disposed with respect to the radiator. <IMAGE>

Description

BROADBAND MICROSTRIP ANTENNAS This invention relates to radar antennas and, more particularly, to microstrip antennas for broadband transmission.

Known log periodic micros trip antennas are known which consist of a set or series of isolated metal patches on the surface of a thin dielectric sheet. The area of each of the particles varies with its neighbours by some log periodic progression. The thin dielectric sheet is placed above a second sheet, on the lower surface of which is an earth plane and on the upper surface is provided a straight transmission line. A signal is applied to the transmission line and energy is coupled by E & BR< H fields to the metal patches which resonate and radiate.

Such known antennas suffer from the disadvantage that they are large and are not readily amenable for use in portable applications such as ground probing radar for locating buried objects such as non metallic pipework.

We have found that more compact structures can be produced which take the advantages of microstrip antennas i.e. the inherent shielding from transission or reception in the backward direction and yet are portable.

According to the present invention there is provided a broadband antenna assembly comprising a first laminar structure which includes a sheet of a dielectric material, on one side of which is mounted a contiguous metal sheet and on the opposing side is mounted a strip transmission line adapted to be coupled with signal feeding means, and a second laminar structure comprising a laminar dielectric sheet, one side of which is in contact with the strip transmission line and on the other side, in at least the peripheral regions, is a coating or clading of a metal which serves as the radicator, characterised in that the transmission line is non-symetrically disposed with respect to the radiator.

The upper surface of the second laminar structure may be clad or coated with a single sheet of metallic radiator or the radiators may be in the form of a series of concentrically formed regions.

Alternatively the second laminar structure may be a multi-laminate structure comprising layers of dielectric sheets, the lower surfaces of which contact the strip transmission line and the upper surfaces of which bear metallic sheets of radicators.

The invention will be illustrated by reference to the accompanying drawings.

Referring to the drawings, a typical antenna assembly was constructed as follows : All circuits are made in etched copper film mounted on 1.6 mm GRP boards, whose relative permitivity is 4.7.

The feed line 2 was of width 2.5 mm, was mounted in or on a GPR board 1, (Fig. 1) approximately 30 x 30 Ocm. A continuous metal film 3 was present on the back of the board. On the top of the board 1 is found a conventional microstrip transmission line 2. Its impedance was measured as approximately 75 ohm and the velocity of propagation along it measured as 0.55C, where C is the velocity of light (3 x 108 ms1). The signal was introduced to the line through a SMA-style microstrip connector (not shown) mounted with its axis perpendicular to the plane of the board. A like connector at the other end of the stripline carried a 50 ohm load.

On a metal coated GPR board 4 of dimensions 21 cm x 21 cm a gap 7 of 1.0 mm was etched to define two regions (Figure 2). The inner region 5 was a 10 x 10 cm square and was surrounded by a concentric region 6 whose outer edges were 14.5 cm. There was no metal backing to the board.

The two boards 1 and 4 were clamped together with a film of petroleum jelly between them to aid dielectric continuity. Short wires were soldered at A, B and C so as to give electrical continuity. The performance of the antenna varied depending on the positioning of the pattern relative to the stripline below it. Useful configurations are shown in figures 3(a), (b) (c).

Two identical antennas were produced, one used as transmitter and one as receiver. Transmission was observed to occur at 550 MHz and 760 MHz. These frequencies corresponded to those at which the overall length (14.7 cm) and the length of the inner rectangle (10 cm) corresponded to a half-wavelength, taking account of the dielectric slowing properties of the substrate.

Thus the frequency response of structure 3(c) (550 MHz) could be extended through the addition of a second passband at 760 MHz by the use of structure 3(c). (Structure 3B had a response at 760 NHz with no appreciable transmission at 550 MHz).

It was also observed that if the connection at Y was removed then the structure still radiated at two frequencies, but these were now 480 MHz and 870 MHz, with a smaller response at 760 MHz.

In addition to all the results described above there were the harmonics (multiples) at higher frequencies.

The power of the method of coupling of the input signal by fields rather than by direct connection, as in conventional microstrip 'patch' antennas, is that the feeding transmission line can itself be adjusted in its properties. For example, it need not be straight, it could divide so as to feed several parts of the radiator at once, it could include frequency sensitive components such as filters or directional couplers. Examples are illustrated in figures 4(a), (b) (c).

For an extended passband the sections into which the antenna is divided are suitably formed. For example, the width of the transmission peaks observed experimentally was approximately 10% of the centre frequency.

Thus, if the ratio of successive sections is approximately 5% the passbands will merge, and the total number of sections will determine the overall bandwidth.

In a further example (Fig. 5), the upper GPR board was configurated to provide three regions 8,9,10.

Metallic links were soldered at X,X',X", and the position of the feeding transmission line is shown at 21.

The antenna was observed to transmit in frequency bands (of width between 50 and 100 MHz) centered on 550MHz, 700 MHz and 950 MHz, which approximately correspond to the frequencies at which the length of each rectangle is a half-wavelength.

Figure 7 illustrates the multilaminate structure arrangement. In this embodiment, the upper GRP board is provided as a stacked layer of boards 14,15,16. In alternate interlayers are a plurality of radiators 11,12,13 whose sizes conform to a log periodic progression, and the transmission strip 2.

Claims

1. An antenna assembly is provided which comprises a first laminar structure which includes a sheet of dielectric material having on one side a contiguous metal sheet and on the other side a strip transmission line adapted to be coupled with signal feeding means, and a second laminar structure, one side of which is in contact with the transmission line, and having on the other side, at least one region but preferable at least two concentrically arranged regions of a coated or cladded metal which serves as a radiator, characterised in that the transmission line is non-symetrically disposed with respect to the radiator.

2. An assembly as claimed in claim 1, wherein the other side of said second laminar structure has at least two regions concentrically arranged.

3. An assembly as claimed in claim 2 wherein said regions are in direct electrical contact.

4. An assembly as claimed in any of the preceding claims wherein said second laminar structure is a multi-laminate structure comprising a plurality of laminar structures having a radiator provided on one surface and the other surface is in contact with the transmission line.

5. An antenna assembly according to claim 1 and substantially as hereinbefore described with reference to the accompanying drawings. CLAIMS 1. An antenna comprising a laminar conductive earth plane region, laminar conductive element regions above and parallel to said earth plane region and spaced from it, a conductive feed strip extending beneath at least one of said element regions in electric field coupling relationship therewith, any remaining element region being conductively connected to a region thus coupled, and dielectric material interposed between said earth plane region and said element regions and between said feed strip and said regions, said element regions as viewed in plan being mutually concentric of progressively decreasing area and lying within the outline of said earth plane region, each element region except the largest lying within the outline of the largest and the or each element region in said field coupling relationship with said feed strip being divided thereby non-symmetrically as viewed in said plan.

2. An antenna according to claim 1 said element regions being coplanar.

3. An antenna according to claim 1 said element regions being mutually parallel, spaced apart and decreasing in area in the direction away from said earth plane region.

4. An antenna according to claim 2 said element regions comprising a square region and one or more encircling regions each bounded by an outer square boundary, the inner boundary of each encircling region being spaced from the outer boundary of the adjacent inner region by a gap which is uniform throughout itself.

5. An antenna according to claim 3 each element region being square.

6. An antenna according to claim 3 the areas of said element regions conforming to a log periodic progression.

7. An antenna according to claim 3 or claim 6 feed strip extending in zig-zag manner and having runs interleaved between said element regions.

8. An antenna according to any claim of claims 1 to 6 said feed strip comprising a branch or branches.

9. An antenna according to claim 1 substantially as herein described with reference to Figures 1 & 2 of the accompanying drawings.

10. An antenna according to claim 1 substantially as herein described with reference to Figures 1 & 5 of the accompanying drawings.

11. An antenna according to claim 1 substantially as herein described with reference to Figure 6 of the accompanying drawings.

12. An antenna according to claim 9 substantially as herein described with reference to Figure 3(a), Figure 3(b) or Figure 3(c) of the accompanying drawings.