DE19725492C1 - Square hollow conductor to microstripline coupling arrangement - Google Patents

Abstract

The arrangement includes a feeder network (2) and a planar line structure (5) of an antenna which are applied on different sides of a two layered substrate (3,4) with an earth surface (6) between both substrate layers. The square hollow conductor (1) is a hollow conductor elbow which is overlapped with a microstripline (2). A first hollow conductor section (7) is provided in the substrate plane and a second hollow conductor section (8) is provided orthogonally to the substrate plane. The hollow conductor does not have a wall in the substrate plane and the walls which are orthogonal on the substrate are contacted with the earth surface. A bridge (9) is provided in the hollow conductor and has a first section (10) in the first hollow conductor section contacting the microstripline. A second section of the bridge is provided in the second hollow conductor section.

Description

State of the art

The invention has an arrangement for ankop a rectangular waveguide to a microstrip line of a feed network for a planar antenna.

Planar antennas usually consist of a large number of planar antenna elements (patches), which over a Spei network are interconnected. The one in the dish signals that are coupled in and out of the network are becoming more common guided over waveguide filters. Therefore it is required Lich, transitions from the microstrip lines of the food network to create waveguides to which the hollow line filters can be connected.

Transitions from microstrip lines to waveguides are on known. In the conference proceedings of the 26th EuMC, September 9-12 1996, Prague, pages 836 to 838 is e.g. B. a transition from egg described microstrip line on a ridge waveguide ben. The substrate with the microstrip line is in inserted the waveguide, and the web of the waveguide is contacted with the microstrip line. The waveguide runs here in the substrate plane.

Task and solution

The feed network of a planar antenna is usually very complex and there is little space for the coupling nes waveguide available. The invention is therefore based on the object an order to Coupling a rectangular waveguide to a microstrip to lead a feed network for a planar antenna give the smallest possible space.

This object is the subject of claim 1 solved. Have the subclaims Embodiments of the invention for Object.

Advantages of the invention

The dining network and a planar lei tion structure of the antenna are on different sides in the subject matter a two-layer substrate, with a ground surface between the two layers of substrate. The rectangular hollow ter is a waveguide angle with a microstrip line device covering, extending in the substrate plane first waveguide section and one perpendicular to the Substrate level standing second waveguide section, wherein the waveguide angle in the substrate plane has no wall points and its walls perpendicular to the substrate are in contact with the ground plane. In the waveguide There is a bridge in the first hollow conductor sections extending and with the microstrip line device contacted first section to which a second one running in the second waveguide section Section of the web connects. By separating the Feed network from the line structure of the antenna and the use of a space-consuming hollow the angle of the conductor can be coupled to the waveguide cheapest place of the dining network, so that long lossy microstrip lines to a ge suitable coupling location can be omitted.  

Description of exemplary embodiments

On the basis of two exemplary embodiments shown in the drawing games, the invention is explained in more detail below. It demonstrate:

Fig. 1 shows a longitudinal section through a waveguide coupled to a Mikrostrei fenleitung and

Fig. 2 is a side view A of the longitudinal section of a waveguide coupled to a microstrip line.

The two FIGS. 1 and 2 show the coupling of a rectangular waveguide 1 to a microstrip line 2 , which belongs to a feed network for a planar antenna. In Fig. 1 is a longitudinal section through the arrangement along the line and micro tire in Fig. A is a view shown on the longitudinal section. 2 Both views in FIGS. 1 and 2 show that the microstrip line 2 belonging to the feed network is brought up on a two-layer substrate. The feed network is located on a first substrate layer 2 and the patches 5 of the planar antenna are on the opposite side of a second substrate layer 4 . Between the two substrate layers 3 and 4 there is a common ground area 6 for the microstrip line 2 of the feed network and for the patches 5 of the planar antenna.

On the first substrate layer 3 , the rectangular hollow conductor 1 is arranged over a section of the microstrip line 2 of the feed network. It is a Hohlleit terwinkel, which cover a microstrip line 2 , which runs in the substrate plane, first waveguide section 7 and which are perpendicular to the substrate plane and have the second waveguide section 8 . The second hollow conductor 8 has at its end a Normalhohllei ter cross-section with the narrow side b and the broad side a to z. B. to be able to connect a waveguide filter.

The longitudinal section through the rectangular waveguide 1 shows only one half of the waveguide with the broad side a / 2. In order to expose the view into the interior of the waveguide 1 , in FIG. 1, unlike in the side view A of FIG. 2, the front wall of the broad side of the waveguide has not been drawn. The waveguide angle has no wall in the substrate plane. The electrical function of the waveguide wall is replaced by the ground surface 6 . For this purpose, the ground surface 6 in the first substrate layer 3 is exposed at least at the points on which the side walls of the waveguide angle rest. The perpendicular to the substrate walls of the waveguide angle 1 are electrically connected to the ground surface 6 by soldering, welding or conductive adhesive.

For the optimal transition of the electromagnetic field of the microstrip line 2 into the second waveguide section 8 , a web 9 arranged in the waveguide angle 1 ensures. This web 9 has a first section 10 , which is in the most waveguide section 7, on the one hand with the waveguide wall running parallel to the substrate and on the other hand over a certain length (2 to 5 mm at an operating frequency of 20 GHz) with the microstrip line 2 . The first web section 10 merges into a second web section 11 , which extends into the second waveguide section 8 . The height of the second web section 11 is reduced in height in the direction of the exit of the second waveguide section 8 . The height of the web can be reduced in stages (as shown in the drawing) or continuously.

The second waveguide section 8 has a cross-section transformation 12 , which widens the cross section of the waveguide section 8 from the smaller waveguide cross section from section 7 to a desired standard waveguide cross section at the output of the second waveguide section 8 .

At an operating frequency of 20 GHz, the first Hohllei terabschnit 7 has a broad side of 5 mm lying parallel to the substrate plane and a narrow side of 2.5 mm. In contrast, the standard cross section of the second waveguide section 8 has a broad side a of 10.668 mm and a narrow side b of 4.318 mm.

To further optimize the adaptation of the field of the microstrip line 2 to the field in the waveguide section 8 , as shown in FIG. 2, the transition from the first web section 10 to the second web section 11 is not ruptured (see FIG. 1) but by a bevel 13 of the bridge gradually. The bevel 13 can, as shown in FIG. 2, run linearly, but it can also have a stepped or non-linear shape.

The first substrate layer 2 , on which the microstrip line 2 runs, is removed in the region of the second waveguide section 8 . The first web section 10 makes a jump 14 in the direction of the ground surface 6 at the point where it extends beyond the end of the first substrate layer 3 . The gradual transition 13 to the second web section 11 begins at this step 14 . The jump 14 compensates for the reduced capacity by removing the first substrate layer.

Advantageously, additional adjustment elements can be provided in the web 9 , which can not be realized in microstrip technology. So z. B. as a matching element in the first web section 10 above the first substrate layer 3, a hole 15 (see Fig. 2). The web 9 can also be provided with several holes at points suitable for the adaptation.

Claims (6)

1. Arrangement for coupling a rectangular waveguide to a microstrip line of a feed network for a planar antenna with the features,

• 1. - That the feed network ( 2 ) and a planar line structure ( 5 ) of the antenna on different sides of a two-layer substrate ( 3 , 4 ), with a ground surface ( 6 ) between the two substrate layers ( 3 , 4 ), are applied ,
• 2. - that the rectangular waveguide ( 1 ) is a waveguide angle with a microstrip line ( 2 ) covering the first waveguide section ( 7 ) extending in the substrate plane and a second waveguide section ( 8 ) perpendicular to the substrate plane, the waveguide angle ( 1 ) has no wall in the substrate plane and its walls, which are perpendicular to the substrate, are in contact with the ground surface ( 6 ),
• 3. - And that in the waveguide angle ( 1 ) a web ( 9 ) is detin, which he in the first waveguide section ( 7 ) he stretching and with the microstrip line ( 2 ) contacting th first section ( 10 ) to which one second in the second waveguide section ( 8 ) from section ( 11 ) of the web connects.

2. Arrangement according to claim 1, characterized in that within the first substrate layer ( 3 ) on which the feed network is located, the ground surface ( 6 ) for contacting tion with the waveguide walls is exposed. 3. Arrangement according to claim 1, characterized in that the second web portion ( 11 ) to the output of the second hollow conductor section ( 8 ) is reduced in height. 4. Arrangement according to claim 1, characterized in that the second waveguide section ( 8 ) has a cross-sectional formation ( 12 ) from the cross section of the first waveguide section ( 7 ) to a Normhohllei ter cross section at the end of the second waveguide section ( 8 ). 5. Arrangement according to claim 1, characterized in that the transition from the first web portion ( 10 ) to the second web portion ( 11 ) by a bevel ( 13 ) takes place gradually. 6. Arrangement according to claim 1, characterized in that in the first web portion ( 10 ) above the first substrate layer ( 3 ) of the microstrip line ( 2 ) at least one hole ( 15 ) is inserted as an adaptation element.