1. Field of the Invention
The invention relates to coupling lines for use in a YIG band-pass filter or a YIG oscillator and a method for producing such coupling lines, suitable for use in a YIG band-pass filter or a YIG oscillator.
2. Related Technology
YIG band-pass filters or YIG oscillators have at least one resonator, which is preferably constructed as spherical and made from an yttrium iron garnet (YIG). The resonator action is conveyed by means of coupling lines which must be constructed and arranged in such a way that the center point of the resonator and the center point of the bend radius of a coupling line match exactly.
A YIG band-pass filter with appropriately constructed coupling lines is known from U.S. Pat. No. 4,480,238, for example. The variable frequency YIG band-pass filter here has a basic body, comprising slits for accommodating insulated chips which have a conductive coating on one edge, which acts as coupling lines. Furthermore, filter chambers are provided to accommodate the YIG elements. The chips are inserted in the slits via the YIG elements in such a way that the YIG elements are arranged in indentations in the edges provided with the conductive coating. The YIG elements and the chips are fixed in permanent positions.
A disadvantage of the YIG band-pass filter known from the aforementioned document is, in particular, the complicated production of the chips forming the coupling lines. The insulator acting as support must first be appropriately formed and then provided with the conducting coating. This is complicated and liable to rejects, as the coating is susceptible to damage, owing to its small layer thickness.
The invention therefore provides coupling lines which are easy to produce, unsusceptible to damage and easy to install, and a method for producing such coupling lines.
The invention provides coupling lines for a YIG filter or YIG oscillator with a coupling line, the coupling line having at least one curved section, which at least partially encompasses at least one YIG element, and at least one line section, the coupling line having at least one contact lug constructed in one piece with it, wherein the contact lug acts on the one hand as bonding point of the coupling line in a basic body and on the other hand as fixing for the coupling line in slits in the basic body. The invention also provides a method for producing a coupling line for a YIG filter or a YIG oscillator, the coupling line having at least one curved section, which at least partially encompasses at least one YIG element, and at least one line section, and the coupling line being made of metal foil, said method comprising producing the coupling line by at least one of eroding, cutting, blanking and etching.
Preferred embodiment examples of the invention are illustrated below as examples using the drawings and explained in greater detail in the following description.
The YIG elements 6 are in this case constructed as spherical from an yttrium iron garnet, mounted on holders 10, by gluing with epoxy resin, for example, and electromechanically coupled by coupling lines 1.
The filter chambers 4 are connected to one another by slits 5, into which the coupling lines 1 are placed. In the embodiment example two of the filter chambers 4 are constructed identically in each case. Coaxial cables 11, via which signals come in and go out, run into the filter chambers 4 designated as 4a. The filter chambers 4 designated as 4b, on the other hand, have only the YIG elements 6. The number of filter chambers 4b is not restricted to two, but may also amount to one or more, so the total number of filter chambers 4 may amount to either three or five or more.
In the embodiment example the coupling lines 1 are designed in two different forms. The coupling line 1 mutually connecting the filter chambers 4b is designed as an input and output line 1a, while the, in the embodiment example three, further coupling lines 1 are designed as connecting lines 1b.
As emerges from
If one looks at
The two embodiments have in common the fact that in each case at least one curved section 17 is provided, which in each case at least partially encompasses a YIG element 6 in such a way that a center point of the YIG element 6 coincides with a center point of the curved section 17. Furthermore, at least one line section 18 is provided.
The coupling line 1 according to the prior art illustrated in
By contrast, the coupling lines 1 configured according to the invention according to
The foil 7 comprises a copper-beryllium alloy, in order to meet both the requirements for elasticity and for stability. The thickness of the foil 7 preferably amounts to 10 μm to 100 μm, more preferably 25 μm to 75 μm, and most preferably approximately 50 μm.
Production of the coupling lines 1 from the foil 7 is done in several processing steps. Firstly the foil 7 is cleaned and then a positive resist is applied to both sides at an adjustment accuracy of approximately 5 μm in a layer thickness of approximately 5 μm, to create a mask. This is followed by the production of the coupling lines 1, for example by sputter etching with iron chloride (FeCl3). Then the foils in the form of a support 9 with a previously established number of coupling lines 1 are freed of remnants of varnish and provided galvanically with a gold coating of approximately 5 μm. Then a hardening process takes place for an hour at 325° C., for example. The coupling lines can then be released from the foil support 9 and built in.
Because of the production method described, the coupling lines 1 have a permanent shape with a precisely defined radius of curvature in the curved sections 17 with even curvature. The YIG elements 6 are then aligned relative to the coupling lines 1. This is simpler than the prior art and associated with an appreciably smaller outlay, because the accuracy of production with the coupling lines 1 configured according to the invention is appreciably greater than with manually bent coupling lines 1.
As mentioned above, in the embodiment example the coupling lines 1 are in the form of an input and output line 1a and three connecting lines 1b. The former is arranged right at the bottom of the foil support 9 in
It can be seen from
The invention is not confined to the embodiment example illustrated and is suitable for YIG filters 2 or YIG oscillators configured in any way. The individual features can be combined with one another in any way.
Number | Date | Country | Kind |
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10 2004 056 259 | Nov 2004 | DE | national |
This is a division of U.S. application Ser. No. 11/667,897, which is the U.S. national phase of PCT/EP2005/011885 filed Nov. 7, 2005, which claims the Convention priority of German application 10 2004 056 259.8 filed Nov. 22, 2004.
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Number | Date | Country | |
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20090144964 A1 | Jun 2009 | US |
Number | Date | Country | |
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Parent | 11667897 | US | |
Child | 12369498 | US |