RF power combiner functioning as higher-order harmonics filter

Abstract

An RF power combiner functioning as a higher-order harmonics filter comprises: at least one pair of coaxially arranged disc-shaped metal conductors, at least one of the conductors having a central axial opening to accommodate a waveguide is provided. Facing surfaces of the disk-shaped metal conductors are shaped symmetrically with respect to the plane of symmetry of the disk-shaped metal conductors to form a plurality of consecutive, radially communicating concentric cavities having isosceles trapezoids with different bases in section. The smaller base of each trapezoid disposed closer to the central axis. The number of the concentric cavities is (2 k+1), where K is the number of signal harmonics being filtered.

Claims

1. An RF power combiner functioning as a higher-order harmonics filter, comprising: at least one pair of coaxially arranged disc-shaped metal conductors, at least one of said conductors having a central axial opening to accommodate a waveguide, wherein facing surfaces of the disk-shaped metal conductors are shaped symmetrically with respect to a plane of symmetry of the disk-shaped metal conductors to form a plurality of consecutive, radially communicating concentric cavities having isosceles trapezoids with different bases in section, with a smaller base of each trapezoid disposed closer to a central axis of the concentric cavities, wherein the number of the concentric cavities is (2 k+1), where k is a number of signal harmonics being filtered; all concentric cavities have a same radial length; all concentric cavities have a different angle at the trapezoid base, the angle being dependent on a wave impedance of a segment of a radial transmission line formed by each of the concentric cavities; a plurality of horn antennae arranged uniformly around the periphery of the disc-shaped metal conductors and connected to the disk-shaped metal conductors, the radial length of a cavity of each horn antenna of said plurality being equal to the radial length of the concentric cavity, and the outer side of each horn antenna being adapted to connect an RF module, which is a source of an RF signal and has an output in the form of a strip line; the concentric cavities in the disc-shaped metal conductors and the cavities of the horn antennae form segments of radial non-dispersive transmission lines, in which electromagnetic T-wave propagates, an impedance magnitude of each of the segments having a constant value of line impedance in a cylindrical section parallel to the central axis of the concentric cavities, which is determined by the values of complex output impedances of the RF module on analyzed harmonics.

2. The RF power combiner according to claim 1, wherein the number of concentric cavities is an odd number equal to at least three.

3. The RF power combiner according to claim 1, wherein the disk-shaped metal conductors are made of copper.

4. The RF power combiner according to claim 1, wherein the number of horn antennae is determined by the number of connected RF modules, each of the RF modules having an output power, and the total output power of the RF modules is the output power of the power combiner.

5. The RF power combiner according to claim 1, wherein a second disc-shaped metal conductor comprises a unit for connecting an end of a waveguide.

6. The RF power combiner according to claim 1, wherein when connecting an end of a waveguide made in the form of a coaxial waveguide an outer conductor is connected to one of the disks, and an inner conductor is connected to the other disk.

7. The RF power combiner according to claim 1, wherein when connecting a waveguide to the power combiner both metal conductors are connected to the outer conductor of the coaxial waveguide.

8. The RF power combiner according to claim 1, comprising a housing in the form of a hollow cylinder to accommodate the disk-shaped metal conductors, said housing being arranged coaxially with the conductors and having a plurality of windows in the cylindrical side wall, equal to the number of horn antennae, to connect RF modules to the horn antennae, and a central opening in at least one end face to pass the coaxial waveguide.

9. The RF power combiner according to claim 1, comprising two or more pairs of coaxially arranged disc-shaped metal conductors.

10. An RF power combiner functioning as a higher-order harmonics filter, comprising: at least one pair of coaxially arranged disc-shaped metal conductors, at least one of said conductors having a central axial opening to accommodate a waveguide, wherein facing surfaces of the disk-shaped metal conductors are shaped symmetrically with respect to a plane of symmetry of the disk-shaped metal conductors to form a plurality of consecutive, radially communicating concentric cavities having isosceles trapezoids with different bases in section, with a smaller base of each trapezoid disposed closer to a central axis of the concentric cavities, wherein the number of the concentric cavities is (2 k+1), where k is a number of signal harmonics being filtered; all concentric cavities have the same radial length; all concentric cavities have a different angle at each of the different bases, the angle being dependent on a wave impedance of a segment of a radial transmission line formed by each of the concentric cavities; a plurality of horn antennae made integrally with the disk-shaped metal conductors and arranged uniformly around the periphery of the disc-shaped metal conductors, the radial length of a cavity of each horn antenna of said plurality being equal to the radial length of a concentric cavity, and the outer side of each horn antenna being adapted to connect an RF module, which is the source of RF signal and has an output in the form of a strip line; the concentric cavities in the disc-shaped metal conductors and the cavities of the horn antennae form segments of radial non-dispersive transmission lines, in which electromagnetic T-wave propagates, an impedance magnitude of each of the segments having a constant value of wave impedance in a cylindrical section parallel to the central axis of the concentric cavities, which is determined by the value of complex output resistance of the RF module on the analyzed harmonic.

11. The RF power combiner according to claim 10, wherein the number of concentric cavities is an odd number equal to at least three.

12. The RF power combiner according to claim 10, wherein the disk-shaped metal conductors are made of copper.

13. The RF power combiner according to claim 10, wherein the number of horn antennae is determined by the number of connected RF modules, each of the RF modules having an output power, and the total output power of the RF modules is the output power of the power combiner.

14. The RF power combiner according to claim 10, wherein a second disc-shaped metal conductor comprises a unit for connecting an end of a waveguide.

15. The RF power combiner according to claim 10, wherein when connecting an end of a waveguide made in the form of a coaxial waveguide an outer conductor is connected to one of the disks, and an inner conductor is connected to the other disk.

16. The RF power combiner according to claim 10, wherein when connecting a waveguide to the power combiner both metal conductors are connected to the outer conductor of the coaxial waveguide.

17. The RF power combiner according to claim 10, comprising a housing in the form of a hollow cylinder to accommodate the disk-shaped metal conductors, said housing being arranged coaxially with the conductors and having a plurality of windows in the cylindrical side wall, equal to the number of horn antennae, to connect RF modules to the horn antennae, and a central opening in at least one end face to pass the coaxial waveguide.

18. The RF power combiner according to claim 10, comprising two or more pairs of coaxially arranged disc-shaped metal conductors.

Description

BRIEF DESCRIPTION

(1) Some of the embodiments will be described in detail, with reference to the following figures, wherein like designations denote like members, wherein:

(2) FIG. 1 depicts a schematic view of RF power combiner functioning as a higher-order harmonics filter, (longitudinal section);

(3) FIG. 2 depicts a schematic view of concentric cavities formed in the RF power combiner with the horn antennae;

(4) FIG. 3 depicts a perspective view of the disc-shaped metal conductors and the horn antennae (broken-out section view) formed integrally with the disc-shaped metal conductors;

(5) FIG. 4 depicts a top view of the disc-shaped metal conductors with the horn antennae;

(6) FIG. 5 depicts a schematic view of one more embodiment of the concentric cavities formed in the RF power combiner with the horn antennae (longitudinal section), the concentric cavities having shape that differs from FIG. 1;

(7) FIG. 6 depicts a schematic view of one more embodiment of the RF power combiner concentric cavities formed in the RF power combiner (longitudinal section), where the concentric cavities having shape that differs from FIG. 1 and wherein an outer conductor is connected to one of the disks and the inner conductor is connected to the other disk;

(8) FIG. 7 depicts a schematic view of RF power combiner functioning as a higher-order harmonics filter, (longitudinal section) wherein the housing comprises two openings to pass the coaxial waveguide;

(9) FIG. 8 depicts a perspective view the RF power combiner functioning as a higher-order harmonics; and

(10) FIG. 9 depicts a schematic view of RF power combiner (longitudinal section) comprising two pairs of coaxially arranged disc-shaped metal conductors.

DETAILED DESCRIPTION

(11) The RF power combiner 1 (as shown in FIG. 1) functioning as a higher-order harmonics filter comprises at least one pair of coaxially arranged disc-shaped metal conductors 2, 3 located coaxially. At least one of said conductors 2 having a central axial opening 4 to accommodate a waveguide 5. Facing surfaces of the disk-shaped metal conductors 2, 3 are shaped symmetrically with respect to the plane of symmetry A-A of the disk-shaped metal conductors to form a plurality of consecutive, radially communicating concentric cavities 6, 7, 8 having isosceles trapezoids (as shown in FIG. 2) with different bases B-B1, C-C1, D-D1, E-E1, F-F1, G-G1 in section, with the smaller base B-B1, D-D1, F-F1 of each trapezoid disposed closer to the central axis CA.

(12) The number of the concentric cavities is (2 k+1), where K is the number of signal harmonics being filtered. In FIG. 2 the device comprises three concentric cavities 6, 7, 8

(13) All concentric cavities 6, 7, 8 of said plurality of cavities have the same radial length L and a different angle α1, α2, α3 at the trapezoid base, the angle being dependent on the wave impedance of a segment of a radial transmission line formed by each of the concentric cavities.

(14) The RF power combiner 1 (FIG. 1) comprises a plurality of horn antennae 9 (FIG. 3) arranged uniformly around the periphery of the disc-shaped metal conductors 2, 3 and connected to the disk-shaped metal conductors. The radial length M (abu.2) of a cavity of each horn antenna 9 of said plurality being equal to the radial length L of the concentric cavity, and the outer side 10 of each horn antenna 9 being adapted to connect an RF module, which is the source of RF signal and has an output in the form of a strip line.

(15) The concentric cavities 6, 7, 8 in the disc-shaped metal conductors and the cavities of the horn antennae 9 form segments of radial non-dispersive transmission lines, in which electromagnetic T-wave propagates, the impedance magnitude of each of the segments having a constant value of line impedance in the cylindrical section parallel to the central axis, which is determined by the values of complex output impedances of the RF module on the analyzed harmonics. Arrow Y shows the direction of the electric field.

(16) According to the second aspect of the claimed embodiments of the invention the RF power combiner 1 functioning as a higher-order harmonics filter has the same construction as in the first embodiment but a plurality of horn antennae 9 are made integrally with the disk-shaped metal conductors and arranged uniformly around the periphery of the disc-shaped metal conductors (FIG. 4). Similarly to the first embodiment the radial length M of a cavity of each horn antenna of said plurality being equal to the radial length L of the concentric cavity, and the outer side of each horn antenna being adapted to connect an RF module, which is the source of RF signal and has an output in the form of a strip line.

(17) The number of concentric cavities in said plurality of cavities is an odd number equal to at least three.

(18) Preferably the disk-shaped metal conductors 2 and 3 are made of copper. Also it is possible to form from an alloy, for example, from aluminum with copper coating.

(19) In general, the number of horn antennae 9 is determined by the number of connected RF modules 10, each of the RF modules having an output power, and the total output power of the RF modules 1 is the output power of the power combiner.

(20) Preferably, the second disc-shaped metal conductor 3 comprises a unit 12 (as shown in FIG. 1, FIG. 5) for connecting an end 13 of a waveguide 5.

(21) When connecting an end of a waveguide 5 made in the form of a coaxial waveguide (as shown in FIG. 5, FIG. 6) the outer conductor 14 is connected to one of the disks 2, and the inner conductor 15 is connected to the other disk 3.

(22) In another embodiment when connecting a waveguide 5 to the power combiner both metal conductors 2, 3 are connected to the outer conductor 14 of the coaxial waveguide 5.

(23) The RF power combiner further comprises a housing 16 (as shown in FIG. 1) in the form of a hollow cylinder to accommodate the disk-shaped metal conductors 2, 3. Said housing 16 being arranged coaxially with the conductors and has a plurality of windows 18 in the cylindrical side wall 17, the number of walls is equal to the number of horn antennae 9 such that to connect RF modules 11 to the horn antennae 9. Said housing 16 comprises and a central opening 19 in at least one end face 20 to pass the coaxial waveguide 5.

(24) It is shown in FIG. 7 that said housing 16 comprises two central openings 19, 21 in both end faces 20, 22 correspondingly to pass the coaxial waveguide 5.

(25) FIG. 8 depicts a perspective view the RF power combiner 1 functioning as a higher-order harmonics.

(26) Preferably the RF power combiner 1 comprises two or more pairs of coaxially arranged disc-shaped metal conductors. It is shown in FIG. 9 that RF power combiner 1 comprises two pairs of coaxially arranged disc-shaped metal conductors.

(27) The RF power combiner 1 functioning as a higher-order harmonics filter operates in the following way.

(28) Fundamental harmonic is fed to the RF modules 11. Said RF modules 11 form the higher-order harmonics. All of the harmonics are fed to the RF power combiner 1.

(29) Higher-order harmonics should be filtered.

(30) During operation of the RF power combiner 1 functioning as a higher-order harmonics filter, the fundamental harmonic passes through all segments of the transmission lines formed by horn antennae and concentric cavities. The signals from all RF modules, consisting only of the fundamental harmonic, are summed and fed to the output coaxial waveguide.

(31) The higher-order harmonics, the number of which is determined according to the total number of the segments of the transmission lines, formed by the horn antennae and the concentric cavities, are reflected “in phase” (the phase of the reflected wave is equal to the phase of the incident wave) and then are fed back to each RF module. Complex reflection coefficient is defined by the line impedances and lengths of the horn antennae and the line impedances and lengths of the concentric cavities excited on a wave of type TEM. The reflection of the signals on higher-order harmonies is necessary, particularly, since it allows class F operation of the RF modules.

(32) Although the present invention has been disclosed in the form of preferred embodiments and variations thereon, it will be understood that numerous additional modifications and variations could be made thereto without departing from the scope of the invention.

(33) For the sake of clarity, it is to be understood that the use of “a” or “an” throughout this application does not exclude a plurality, and “comprising” does not exclude other steps or elements.