The present invention relates generally to waveguide filters, and more particularly to dual-mode waveguide cavity filters utilizing corrugated tubing structures.
Microwave components, such as passive radio frequency (RF) filters, play an important role in wireless communications. For example, RF filters are commonly used to pass only the desired frequencies from the radio to the antenna (and from the antenna to the radio), while blocking spurious transmissions that can otherwise saturate a receiver. Given the density and co-location of equipment at cell sites, component size has become a critical factor. Dual-mode ceramic waveguide filters are particularly useful for such applications given their filtering performance (e.g., ability to easily and simply generate transmission zeros) as well as reduced component size as compared with other filters, such as traditional air coaxial filters, for example.
However, reducing the size of traditional dual-mode waveguide filters can give rise to other disadvantages relating to performance tradeoffs, cost, as well as manufacturing and component assembly issues. For example, a filter assembly can be made more compact by suspending the dielectric element (e.g., ceramic “puck”) inside the filter cavity and extending the dielectric element to the cavity walls. In this arrangement, the dielectric element would require perturbing structures to “break” the degeneracy of the dual modes (e.g., split the frequencies of the otherwise degenerate dual modes) and to define the filter bandwidth (e.g., the more the modes are split, the greater the bandwidth of the filter, etc.). Adding such perturbing structures can increase the overall cost of producing the dielectric element. Additionally, such filter assemblies have added manufacturing and assembly complexity. For example, strict tolerances (e.g., bore and cylinder diameters, temperature variances) make it very difficult to insert and hold, without damage, a ceramic puck inside a rigid cavity when using either mechanical processes (e.g., hydraulic pressing) or temperature-controlled processes (e.g., heating/cooling to effect expansion and contraction of the rigid metal cavity).
In accordance with various embodiments, a compact size waveguide filter utilizes a corrugated tubing structure that allows a dielectric element to be controllably pressed and clamped within a waveguide cavity. A distribution of corrugations provides a cavity structure that can be expanded and contracted without the challenges associated with adhering to strict tolerances (e.g., bore diameter) and controlling temperature variations in a heating/cooling process. The corrugated tubing structure acts as a spring to ease the insertion of the dielectric element and provides a clamping force to hold the dielectric element in place. The geometry of the corrugations in the tubing structure can provide rotational asymmetry to split dual-mode resonant frequencies using an unperturbed dielectric, thus avoiding the cost of adding perturbing structures within the waveguide cavity.
In accordance with an embodiment, a filter comprises a dielectric resonator element (e.g., a ceramic resonator) and a cylindrical waveguide cavity having a corrugated tube structure that surrounds the dielectric resonator element such that an outer encircling wall surface of the dielectric resonator element is in contact with an inner sidewall of the corrugated tube structure. The corrugated tube structure includes one or more spaced-apart corrugations that are configured to provide a spring-like action to controllably expand and contract the corrugated tube structure (e.g., the diameter of the tube) so that the dielectric resonator element can be controllably inserted and clamped within the cylindrical waveguide cavity. According to an embodiment, the geometry of the spaced-apart corrugations define a rotationally asymmetric corrugated tube structure capable of splitting a plurality of modes of electromagnetic waves within the filter, e.g., a first resonant mode and a second substantially degenerate resonant mode in a dual-mode filter configuration. According to another embodiment, the geometry of the spaced-apart corrugations define a rotationally symmetric corrugated tube structure and the dielectric resonator element includes one or more perturbing elements (e.g., “through” holes in the ceramic resonator) for splitting a plurality of modes of electromagnetic waves within the filter. In different embodiments, the spaced-apart corrugations can take the form of half-cylinders, half-squares, triangles, rectangles and various other shapes capable of providing the spring-like action on the corrugated tube structure. The dielectric resonator element can also include a chamfered edge (e.g. on a top and/or bottom surface) to ease insertion into the cavity.
Various illustrative embodiments will now be described more fully with reference to the accompanying drawings in which some of the illustrative embodiments are shown. It should be understood, however, that there is no intent to limit illustrative embodiments to the particular forms disclosed, but on the contrary, illustrative embodiments are intended to cover all modifications, equivalents, and alternatives falling within the scope of the claims. Where appropriate, like numbers refer to like elements throughout the description of the figures. It will be understood that, although the terms first, second, etc. may be used herein to describe various elements, these elements should not be limited by these terms. These terms are only used to distinguish one element from another. For example, a first element could be termed a second element, and, similarly, a second element could be termed a first element, without departing from the scope of illustrative embodiments. As used herein, the term “and/or” includes any and all combinations of one or more of the associated listed items.
According to an embodiment, corrugated tube structure 201 is a metal tube (e.g., aluminum, aluminum alloy, silver-plated steel, copper or other suitable metal) and dielectric resonator element 220 is an unperturbed ceramic resonator (e.g., without structure for “breaking” the degeneracy of the resonant modes). The spaced-apart corrugations 210A-210J allow corrugated tube structure 201 to be deformably expanded and contracted to allow for insertion of dielectric resonator element 220 therein. In particular, the inclusion of spaced-apart corrugations 210A-210J along corrugated tube structure 201 provides resilience in the structure such that it acts like a spring (e.g., provides a spring-like action) that controllably expands and contracts corrugated tube structure 201 so that dielectric resonator element 220 can be controllably inserted and clamped within the cylindrical waveguide cavity. In this manner, the spring-like action of corrugated tube structure 201 eases the insertion of dielectric resonator element 220 as well as serves as a controlled clamping force to hold the dielectric resonator element 220 in place. Although not shown, dielectric resonator element 220 can have chamfered edges (or even slightly chamfered edges) along the periphery of its top and/or bottom end surfaces (not shown), which can aid with the insertion of dielectric resonator element 220 into corrugated tube structure 201.
In general, the spaced-apart corrugations 210A-210J define a series of alternating grooves and ridges (or ribs) around the circumference of corrugated tube structure 201. According to an embodiment, the geometrical shape (e.g., cross-section) of the spaced-apart corrugations 210A-201J can be half-cylinders (as shown in
The number and positioning of spaced-apart corrugations 201A-201J to be included along the circumference of corrugated tube structure 201 is a matter of design choice and may be selected dependent on physical and/or functional performance requirements for waveguide filter 200. As will be apparent, less spaced-apart corrugations may provide less spring-like action while more spaced-apart corrugations will increase the range of the spring-like action (e.g., larger expansion and contraction range). Although the illustrative embodiments shown herein include ten (10) spaced-apart corrugations, even a single corrugation can provide the necessary functionality for waveguide filter 100.
According to an embodiment, waveguide filter 200 is rotationally asymmetric in that the geometry of the one or more spaced-apart corrugations 201A-201J define a rotationally asymmetric corrugated tube structure 201 that is configured to split a plurality of fundamental modes of electromagnetic waves propagating within waveguide filter 200. As used herein, the term rotationally asymmetric is to be understood to refer to a structure in which corrugations are, at least in part, non-uniformly distributed along the circumference of corrugated tube structure 201. For example, waveguide filter 200 in one embodiment is a dual-mode filter that splits dual-mode frequencies, e.g., a first resonant mode and a second substantially degenerate resonant mode. Because rotational asymmetry is provided via the corrugated structure in the cylindrical waveguide structure itself, dielectric resonator element 220 can therefore be an unperturbed ceramic, e.g., no perturbations are required in the ceramic puck.
When viewed in the context of an x-y axis perspective for a top view of waveguide filter 200,
The spaced-apart corrugations 210A-210J are incorporated in a manner that provides the rotational asymmetry in corrugated tube structure 201, e.g., the number and positioning/spacing of spaced-apart corrugations 210A-210J. For example, rotational asymmetry is not present (i.e., the modes remain degenerate) when the corrugations repeat at 360/N degrees where N>2 and where N is an integer representing the number of corrugations.
As described, the number and positioning of spaced-apart corrugations 201A-201J to be included along the circumference of corrugated tube structure 201 is a matter of design choice and may be selected dependent on physical and/or functional performance requirements for waveguide filter 200. For example, the number of corrugations can also affect the mode-splitting performance of waveguide filter 200. As will be apparent, a lesser number of spaced-apart corrugations may enhance mode-splitting performance while a greater number of spaced-apart corrugations may reduce the mode-splitting performance in waveguide filter 200. That is, the more asymmetry that exists, the more the modes will be split.
In another embodiment, the geometry of corrugated tube structure 201 can also be rotationally symmetric, but in this case, perturbations would be incorporated into dielectric resonator element 220 (e.g., “through” holes as perturbing elements) to effectively split the fundamental modes of electromagnetic waves propagating within waveguide filter 200, e.g., dual-mode frequencies for a dual-mode filter.
The foregoing merely illustrates the principles of the disclosure. It will thus be appreciated that those skilled in the art will be able to devise various arrangements that, although not explicitly described or shown herein, embody the principles of the disclosure and are included within its spirit and scope. Furthermore, all examples and conditional language recited herein are principally intended to be only for pedagogical purposes to aid the reader in understanding the principles of the disclosure and the concepts contributed by the inventor to furthering the art, and are to be construed as being without limitation to such specifically recited examples and conditions. Moreover, all statements herein reciting principles, aspects, and embodiments of the disclosure, as well as specific examples thereof, are intended to encompass both structural and functional equivalents thereof. Additionally, it is intended that such equivalents include both currently known equivalents as well as equivalents developed in the future.
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20200381796 A1 | Dec 2020 | US |