This application is a 35 U.S.C. § 371 National Phase Entry Application from PCT/EP2013/056174, filed Mar. 24, 2013, and designating the United States.
The present invention relates to a transition arrangement adapted to provide a signal transition between a substrate integrated waveguide, SIW, to a waveguide interface. The SIW comprises a dielectric material, a first metal layer, a second metal layer and an electric wall element arrangement, the dielectric materiel having a layer thickness and being positioned between the first metal layer and the second metal layer. The electric wall element arrangement comprises a first electric wall element and a second electric wall element, the first electric wall element and the second electric wall element at least partly running mutually parallel, separated by a SIW width in a SIW longitudinal extension and electrically connecting the first metal layer with the second metal layer. Microwave signals are arranged to propagate along the SIW longitudinal extension in a confinement limited by at least the first metal layer, the second metal layer, the first electric wall element and the second wall element. The transition arrangement comprises a coupling aperture in the first metal layer and a third wall element running between the first electric wall element and the second wall element, across the SIW longitudinal extension.
A waveguide interface between different function blocks, and between a function block and test equipment, is needed in many situations in microwave technology. Antennas, duplex filters, and amplifiers are examples of such function blocks, and the test equipment may be constituted by any type of suitable measuring or test device.
One of these function blocks is in this context constituted by a so-called substrate integrated waveguide SIW, and there is a need for an enhanced transition from an air-filled waveguide to a SIW. The following properties are found to be of importance:
Different types of transitions have been made, but none of them have provided a sufficient band width, robustness and low loss, and thus an enhanced transition between a SIW and a waveguide interface is desired.
It is an object of the present invention to provide a transition between a SIW and a waveguide interface which provides enhanced functionality with respect to the properties listed above, in particular band width, robustness and low loss.
Said object is obtained by means of a transition arrangement adapted to provide a signal transition between a substrate integrated waveguide, SIW, to a waveguide interface. The SIW comprises a dielectric material, a first metal layer, a second metal layer and an electric wall element arrangement, the dielectric materiel having a layer thickness and being positioned between the first metal layer and the second metal layer. The electric wall element arrangement comprises a first electric wall element and a second electric wall element, the first electric wall element and the second electric wall element at least partly running mutually parallel, separated by a SIW width in a SIW longitudinal extension and electrically connecting the first metal layer with the second metal layer. Microwave signals are arranged to propagate along the SIW longitudinal extension in a confinement limited by at least the first metal layer, the second metal layer, the first electric wall element and the second wall element. The transition arrangement comprises a coupling aperture in the first metal layer and a third wall element running between the first electric wall element and the second wall element, across the SIW longitudinal extension.
The transition arrangement further comprises an at least partly electrically conducting intermediate transition element which in turn comprises a first main surface, a second main surface and a transition aperture. The transition aperture comprises a first opening with a first width in the first main surface, and a second opening with a second width in the second main surface, the widths extending along the SIW longitudinal extension. The transition element is mounted to the first metal layer such that the first opening faces, and at least partly covers, the coupling aperture, the first width exceeding the second width. Furthermore, the transition from the first width to the second width takes place between the first opening and the second opening in at least one step. The second opening faces, and is mounted to, the waveguide interface, such that a waveguide interface opening partly covers the second opening. The waveguide interface opening is offset relative the second opening towards the third wall element such that a front step is formed on a part of the second main surface that falls within the waveguide interface opening.
According to an example, the waveguide interface has an interface surface that faces to, and makes electrical contact with, the second main surface. Then, the waveguide interface opening is offset relative the second opening towards the third wall element such that a part of the interface surface covers a part of the second opening that faces away from the third wall element. An overlap step is then formed by said part of the interface surface.
According to another example, the electric wall element arrangement either comprises a plurality of via connections, or plated slots running through the dielectric material, electrically connecting the first metal layer to the second metal layer.
Other examples are disclosed in the dependent claims.
A number of advantages are obtained by means of the present invention:
The present invention will now be described more in detail with reference to the appended drawings, where:
With reference to
More in detail, the SIW 2 comprises a dielectric material 4, a first metal layer 5 and a second metal layer 6, where the dielectric materiel 4 has a layer thickness td and is positioned between the first metal layer 5 and the second metal layer 6. The SIW also comprises an electric wall element arrangement 7a, 7b, 7c in the form of vias 21 that run through the dielectric material 4 and electrically connect the metal layers 5, 6. The electric wall element arrangement comprises a first electric wall element 7a and a second electric wall element 7b, where the first electric wall element 7a and the second electric wall element 7b run mutually parallel, separated by a SIW width ws in a SIW longitudinal extension es.
Microwave signals 23 are arranged to propagate along the SIW longitudinal extension es in a confinement limited by at least the first metal layer 5, the second metal layer 6, the first electric wall element 7a and the second wall element 7b.
As a part of a transition arrangement 1 which will be described more in detail later, the SIW 2 comprises a coupling aperture 8 in the first metal layer 5, and a third wall element 7c also being in the form of vias 21 that run through the dielectric material 4 and electrically connect the metal layers 5, 6. The third wall element 7c is running between the first electric wall element 7a and the second wall element 7b, across the SIW longitudinal extension es. Microwave signals 23 propagating in the SIW are thus directed to run via the coupling aperture 8.
According to the present invention, with reference to
Furthermore, as shown in
The widths w1, w2 w3 extend along the SIW longitudinal extension es, and with reference also to
As shown in
The second opening 14 faces, and is mounted to, the waveguide interface 3 such that a waveguide interface opening 17 partly covers the second opening 14. The waveguide interface opening 17 is offset relative the second opening 14 towards the third wall element 7c such that a front step 18 is formed on a part of the second main surface 11 that falls within the waveguide interface opening 17.
As shown in
The present invention is not limited to the example described above, but may vary within the scope of the appended claims. For example, at least one of the waveguide interface 3 and the intermediate transition element 9 may be made in a metal or, alternatively, formed in a plastic material and covered by an electrically conducting coating. These elements 3, 9 are thus at least partly electrically conducting.
The electric wall element arrangement has been shown comprising a plurality of via connections. Other alternatives are possible, such as plated trenches or plated slots, running through the dielectric material 4, electrically connecting the first metal layer 5 to the second metal layer 6.
The first electric wall element 7a and the second electric wall element 7b at least partly run mutually parallel, there may be width changes for example in the form of irises or similar, the SIW width ws being changed between different values.
The transition from the first width w1 to the second width w2 has been shown to take place in two steps 15, 16 via the third width w3, but said transition may take place in only one step. Alternatively, said transition may take place in more than two steps. Among other things, the steps 15, 16, 18, 20 provide enhanced transmission and matching properties.
The waveguide interface opening 17 does not have to be offset relative the second opening 14 towards the third wall element 7c as described previously. In that case, the overlap step 20 is not present.
The first intermediate step 15 is normally relative thin in comparison to the thickness of the transition element 9.
The usage of screws for mounting the transition arrangement 1 is only an example, other types of mounting is conceivable such as conductive glue, solder or press-fit.
The number of guiding pins may be any suitable, the usage of guiding pins being optional.
The transition element 9 and the waveguide interface 3 may be surface-mounted, and mounted in an ordinary pick & place process.
The waveguide interface 3 may be constituted by any suitable waveguide interface that is electromagnetically connectable to the coupling aperture 8 and with the mechanical properties needed for the present invention.
The present invention thus relates to a transition arrangement 1 adapted to provide a signal transition between a substrate integrated waveguide 2, SIW, to a waveguide interface 3. The SIW comprises a dielectric material 4, a first metal layer 5, a second metal layer 6 and an electric wall element arrangement 7a, 7b, 7c. The dielectric materiel 4 has a layer thickness td and is positioned between the first metal layer 5 and the second metal layer 6.
The electric wall element arrangement comprises a first electric wall element 7a and a second electric wall element 7b, where the first electric wall element 7a and the second electric wall element 7b at least partly run mutually parallel, separated by a SIW width ws in a SIW longitudinal extension es and electrically connecting the first metal layer 5 with the second metal layer 6. The SIW width ws may be variable along the SIW longitudinal extension es.
Microwave signals being arranged to propagate along the SIW longitudinal extension es in a confinement limited by at least the first metal layer 5, the second metal layer 6, the first electric wall element 7a and the second wall element 7b. The transition arrangement 1 comprises a coupling aperture 8 in the first metal layer 5 and a third wall element 7c running between the first electric wall element 7a and the second wall element 7b, across the SIW longitudinal extension es.
The transition arrangement 1 further comprises an at least partly electrically conducting intermediate transition element 9 which in turn comprises a first main surface 10, a second main surface 11 and a transition aperture 12. The transition aperture 12 comprises a first opening 13 with a first width w1 in the first main surface 10, and a second opening 14 with a second width w2 in the second main surface, the widths w1, w2 extending along the SIW longitudinal extension es. The transition element 9 is mounted to the first metal layer 5 such that the first opening 13 faces, and at least partly covers, the coupling aperture 8. The first width w1 exceeds the second width w2 and the transition from the first width w1 to the second width w2 takes place between the first opening 13 and the second opening 14 in at least one step 15, 16. The second opening 14 faces, and is mounted to, the waveguide interface 3, such that a waveguide interface opening 17 partly covers the second opening 14, the waveguide interface opening 17 being offset relative the second opening 14 towards the third wall element 7c such that a front step 18 is formed on a part of the second main surface 11 that falls within the waveguide interface opening 17.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/056174 | 3/24/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/154232 | 10/2/2014 | WO | A |
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Number | Date | Country | |
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20160049714 A1 | Feb 2016 | US |