Abstract: The invention is a dielectric resonator circuit comprising a housing; first, second, and third resonators positioned substantially in a row within the housing with said second resonator positioned between the first and third resonators, wherein the resonators are positioned relative to each other such that a field generated in each resonator couples to an adjacent resonator; wherein the housing encloses the resonators and has a separating wall positioned between the first and third resonators in order to control electromagnetic coupling between the first and third resonators; and wherein said first separating wall comprises a first end and a second end along a length thereof and wherein the separating wall defines an iris at the first end, the wall comprising a main wall portion positioned substantially between the first and third resonators and an extension wall portion at the first end that extends at an angle from the main wall portion of said wall.

Abstract: In accordance with principles of the present invention, a two or more pole dielectric resonator circuit is provided with resonators that are elliptical in cross section orthogonal to the longitudinal axis. The resonators are mounted so that they are rotatable about their longitudinal axes, such that the straight line distance between two adjacent resonators measured in a straight line between orthogonal to and intersecting the longitudinal axes of the two resonators is a function of the orientation of the resonators about their longitudinal axes. The resonators can be oriented about their longitudinal axes in any orientation to adjust their spacing, which is directly proportional to their coupling magnitude, which, in turn, is proportional to the bandwidth of the circuit.

Abstract: A dielectric resonator with an air (or other dielectric) gap axially interrupting the body of the resonator and circuits employing such resonators. Preferably, the resonator body is conical or a stepped cylinder. However, the invention also is workable with a straight-sided cylindrical resonator body.

Abstract: A dielectric resonator circuit is provided that is tunable over a broad frequency range and/or a broad bandwidth range. The center frequency is made tunable over a broad range by use of a dielectric tuning plug that is positioned in a through hole within the resonator. The bandwidth is made tunable over a broad range by tilting the resonators relative to the enclosure to increase the effective height of the cavity as seen by the resonator.

Abstract: In accordance with the principles of the present invention, a dielectric resonator is provided with a longitudinal through hole with a diameter that varies as a function of height of the resonator so as to increase the frequency spacing between the fundamental mode and the spurious modes.

Abstract: A dielectric resonator radiator comprising first and second portions, each portion being conical or monotonically varying in shape having a larger basal surface and a smaller basal surface and defining a longitudinal axis, the first and second portions being arranged with their longitudinal axes collinear and their larger basal surfaces parallel and adjacent to each other and separated by a gap.

Abstract: In order to permit electronic tuning of the frequency of a circuit including dielectric resonators, such as a dielectric resonator filter, tuning plates are employed adjacent the individual dielectric resonators. The tuning plates comprises two separate conductive portions and an electronically tunable element electrically coupled therebetween. The electronically tunable element can be any electronic component that will permit changing the capacitance between the two separate conductive portions of the tuning plates by altering the current or voltage supplied to the electronically tunable element. Such components include virtually any two or three terminal semiconductor device. However, preferable devices include varactor diodes and PIN diodes.

Abstract: The invention comprises a technique and associated mechanisms by which dielectric resonator circuits, such as filters, can be tuned in both frequency, bandwidth or both without the need for irises, tuning screws and/or tuning plates. In accordance with the invention, the positions of the dielectric resonators are adjustable relative to each other within the cavity in multiple ways, including vertically and horizontally. The dielectric resonators also may tilt relative to each other. Furthermore, an off-center longitudinal hole can be machined in one or more of the dielectric resonators so as to make the electromagnetic field of the resonator non-uniform so that the dielectric resonator can be rotated about its longitudinal axis to alter the coupling between dielectric resonators.

Abstract: The invention is a dielectric resonator circuit comprising a housing; first, second, and third resonators positioned substantially in a row within the housing with said second resonator positioned between the first and third resonators, wherein the resonators are positioned relative to each other such that a field generated in each resonator couples to an adjacent resonator; wherein the housing encloses the resonators and has a separating wall positioned between the first and third resonators in order to control electromagnetic coupling between the first and third resonators; and wherein said first separating wall comprises a first end and a second end along a length thereof and wherein the separating wall defines an iris at the first end, the wall comprising a main wall portion positioned substantially between the first and third resonators and an extension wall portion at the first end that extends at an angle from the main wall portion of said wall.

Abstract: A dielectric resonator having variable cross-section, preferably varying monotonically, and, most preferably, the resonator being in the shape of a truncated cone. Such shapes displace the H11 mode from the TE mode in the longitudinal direction of the cone. Truncating the cone to eliminate the portion of the cone where the H11 mode exists, virtually eliminates the H11 mode. A circuit comprising a plurality of these resonators may be arranged in an enclosure with each resonator longitudinally inverted relative to adjacent resonator(s) to provide a compact design with enhanced coupling and adjustability. A spiral coupling loop provides high magnetic flux in a small physical volume for coupling energy into or out of the circuit. Alternately, the resonator can coupled to a microstrip by placing the resonator upside-down near the microstrip, whereby the TE mode is immediately above the microstrip, providing enhanced coupling there between.

Abstract: In accordance with the principles of the present invention, a resonator puck is provided with one or more vertical and/or horizontal, radial slits that improve the quality factor, Q, of circuits constructed from the resonators. In some embodiments of the invention, the surfaces of the resonators that define the slit are left relatively rough and may even contact each other such that the slit is not of uniform thickness, but essentially comprises a plurality of pockets between the two portions of the resonator.

Abstract: A cross-coupled dielectric resonator circuit. Resonator circuits in accordance with the invention may be used to build low-loss compact filters, oscillators, and other circuits, particularly microwave circuits. The resonators are arranged relatively to each other within an enclosure in a very efficient and compact design that enhances adjustability and coupling between adjacent resonators and the cross-coupling of alternate resonators.

Abstract: In accordance with the principles of the present invention, a resonator puck is provided with one or more vertical and/or horizontal, radial slits that improve the quality factor, Q, of circuits constructed from the resonators. Preferably, the slits are very narrow and, more preferably, about 100 to 1000 atoms wide. In some preferred embodiments of the invention, the surfaces of the resonators that define the slit are left relatively rough and may even contact each other such that the slit is not of uniform thickness, but essentially comprises a plurality of pockets between the two portions of the resonator.

Abstract: A cross-coupled dielectric resonator circuit. Resonator circuits in accordance with the invention may be used to build low-loss compact filters, oscillators, and other circuits, particularly microwave circuits. The resonators are arranged relatively to each other within an enclosure in a very efficient and compact design that enhances adjustability and coupling between adjacent resonators and the cross-coupling of alternate resonators.

Abstract: The invention is a method and apparatus for dissipating heat in a dielectric resonator circuit in which resonators are mounted to an enclosure by highly thermally and electrically conductive supports, such as metal rods, that pass through the longitudinal through hole in the center of the resonator. The supports preferably are attached within the through holes by a highly thermally conductive, but dielectric sleeve positioned between the support and the resonator. The rod or support has a diameter selected to minimize any reduction in quality factor, Q, for the circuit. Alternately, the support can be a highly thermally conductive dielectric and the inner wall of the through hole can be metalized.

Abstract: The invention is a method and apparatus for coupling energy into or out of a dielectric resonator circuit by means of a coupling loop. More particularly, the invention is a method and apparatus for adjustably mounting a coupling loop relative to a resonator, the method and apparatus particularly adapted for use with conical and similar resonators in which the field of interest, typically the TE mode, varies as a function of longitudinal position relative to the resonator.

Abstract: The invention is a dielectric resonator in the shape of a truncated cone and variations with a longitudinal through hole. The truncated cone shape physically displaces the H11l mode from the TE mode in the longitudinal direction of the cone. Particularly, the TE mode tends to concentrate in the base of the cone while the H11 mode tends to concentrate at the top of the cone. By truncating the cone so as to eliminate the portion of the cone where the H11 mode field exists, yet keep the portion of the cone where the TE mode exists, the H11 mode can be virtually eliminated while having no effect on the magnitude of the TE mode.

Abstract: A cross-coupled dielectric resonator circuit. Resonator circuits in accordance with the invention may be used to build low-loss compact filters, oscillators, and other circuits, particularly microwave circuits. The resonators are arranged relatively to each other within an enclosure in a very efficient and compact design that enhances adjustability and coupling between adjacent resonators and the cross-coupling of alternate resonators.

Abstract: A configuration for coupling a dielectric resonator to a microstrip transmission line that maintains a relatively high Q value of the dielectric resonator. The dielectric resonator-to-microstrip transmission line coupling configuration includes a dielectric resonator, a metal wall, and a microstrip conductor mounted on a dielectric substrate surface such that the dielectric resonator is near the microstrip conductor. The dielectric resonator is configured to resonate in an intrinsic non-radiating hybrid electromagnetic mode, and the metal wall is configured as a mirror for conceptually forming an image of the resonating dielectric resonator. When an electromagnetic wave is transmitted on the microstrip transmission line, the dielectric resonator is excited to resonate in the hybrid electromagnetic mode, thereby allowing electromagnetic field coupling between the microstrip transmission line and the dielectric resonator, while maintaining a high Q value of the dielectric resonator.

Abstract: A configuration for coupling a dielectric resonator to a microstrip transmission line that maintains a relatively high Q value of the dielectric resonator. The dielectric resonator-to-microstrip transmission line coupling configuration includes a dielectric resonator, a metal wall, and a microstrip conductor mounted on a dielectric substrate surface such that the dielectric resonator is near the microstrip conductor. The dielectric resonator is configured to resonate in an intrinsic non-radiating hybrid electromagnetic mode, and the metal wall is configured as a mirror for conceptually forming an image of the resonating dielectric resonator. When an electromagnetic wave is transmitted on the microstrip transmission line, the dielectric resonator is excited to resonate in the hybrid electromagnetic mode, thereby allowing electromagnetic field coupling between the microstrip transmission line and the dielectric resonator, while maintaining a high Q value of the dielectric resonator.