EP0755577A1 - Hochtemperatursupraleitende filter mit hoher leistung - Google Patents

Hochtemperatursupraleitende filter mit hoher leistung

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Publication number
EP0755577A1
EP0755577A1 EP95916934A EP95916934A EP0755577A1 EP 0755577 A1 EP0755577 A1 EP 0755577A1 EP 95916934 A EP95916934 A EP 95916934A EP 95916934 A EP95916934 A EP 95916934A EP 0755577 A1 EP0755577 A1 EP 0755577A1
Authority
EP
European Patent Office
Prior art keywords
hts
filter
ground plane
high temperature
filters
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP95916934A
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English (en)
French (fr)
Inventor
Zhi-Yuan Shen
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
EIDP Inc
Original Assignee
EI Du Pont de Nemours and Co
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Filing date
Publication date
Application filed by EI Du Pont de Nemours and Co filed Critical EI Du Pont de Nemours and Co
Publication of EP0755577A1 publication Critical patent/EP0755577A1/de
Withdrawn legal-status Critical Current

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Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P1/00Auxiliary devices
    • H01P1/20Frequency-selective devices, e.g. filters
    • H01P1/201Filters for transverse electromagnetic waves
    • H01P1/203Strip line filters
    • H01P1/20327Electromagnetic interstage coupling
    • H01P1/20354Non-comb or non-interdigital filters
    • H01P1/20381Special shape resonators
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P1/00Auxiliary devices
    • H01P1/20Frequency-selective devices, e.g. filters
    • H01P1/201Filters for transverse electromagnetic waves
    • H01P1/203Strip line filters
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P1/00Auxiliary devices
    • H01P1/20Frequency-selective devices, e.g. filters
    • H01P1/201Filters for transverse electromagnetic waves
    • H01P1/203Strip line filters
    • H01P1/20327Electromagnetic interstage coupling
    • H01P1/20354Non-comb or non-interdigital filters
    • H01P1/20363Linear resonators

Definitions

  • BACKGROUND OF THE INVENTION Filters are an important microwave component with widely spread applications in commercial and military microwave systems, such as telecommunication, instruments, radar and electronic warfare systems.
  • High performance bandpass filters require narrow bandwidth with sharp skirts, high rejection in the off-band, low insertion loss in the passing band, high power handling capability all in a compact and light package.
  • the conventional filters made of normal conductors, such as copper, silver, gold, aluminum and the like, have limited conductivity which cause unacceptable high inband insertion loss and are unable to satisfy all the requirements for high performance.
  • HTS high temperature superconductors
  • T c transition temperature
  • 77 K liquid nitrogen temperature
  • HTS filters can be classified into three categories : the one dimensional, the two dimensional and the three dimensional.
  • the conventional one dimensional filter is made of a series of coupled half-wave-length transmission line resonators.
  • the rf current distribution in the resonator is in a standing-wave form along its length with the maximum current density at the center. Along the line width direction, the current also has an uneven distribution with maximum current density at the two edges.
  • the critical current density, J c is defined as the maximum current density for which the HTS materials can carry without significant degradation of its conductivity.
  • C. Walker et al., IEEE-Trans MTT., Vol. 39, 1462-1467 (1991) described a 5 GHz HTS half- wave-length resonator.
  • This resonator has a section of HTS microstrip line. In this particular case, it is a
  • the resonator At operating temperature (77 K) , the resonator has a loaded Q-value of 7,000-8,000 at input power below 1 mW and it begins to drop above 1 mW. At 32 mW of input power, the loaded Q-value reduced to 6,000. If this resonator is a part of HTS filter, which requires a minimum loaded Q-value of 6,000, then it will not handle input power more than 32 mW without significant performance degradation.
  • the 500- ⁇ m-wide HTS line on 20-mil LaAl ⁇ 3 substrate is not a 50-ohm line.
  • the 50-ohm microstrip line on a 20-mil LaA103 substrate has a width of only 165 ⁇ , which handles much lower power than the 500 ⁇ m line.
  • the power handling capability of this resonator is in the range of milliwatts and is limited by narrow line width. It is desirable to have HTS filters with a higher power handling capability for many applications.
  • the building block of the two dimensional HTS filters is in two dimensional planar forms wherein the dimensions along both directions are comparable to the wave length.
  • the most commonly used form of two dimensional filters is the "dual mode" cut-corner square form, as described by A. Curtis et al. 1991 IEEE MTT-S International Microwave Symposium Digest, Vol. 2, pp. 443-446.
  • Figure 6a shows a typical layout of an 8-pole (a pole represents a resonance) dual mode HTS filter.
  • the building block of such a filter is an HTS cut-corner square pattern deposited on a substrate. Each cut-corner square represents two modes, therefore, the four cut-corner squares in Figure 6a represent 8 poles instead of just four.
  • the two dimensional HTS filters handle more power than the one dimensional HTS filters because the rf current is distributed over a large area.
  • the planar layout of known two dimensional HTS filters such as the one shown in Figures 6a and 6b, have a problem of occupying too much substrate area and require a very large package to house the filter circuit. This problem becomes severe as the number of poles increases and the operating frequency decreases.
  • the size of the HTS square needed would be approximately 7 cm x 7 cm on a LaAl ⁇ 3 substrate with a dielectric constant, ⁇ r — 24.
  • the total area for a dual mode 8-pole filter such as shown in Figure 6a would be at least 20 cm x 20 cm, which is unacceptably large.
  • such large substrates require an even larger enclosure which creates severe cryogenic problems.
  • the basic building block of such a filter is a cut-corner square HTS resonator 51a, 51b, 51c or 51d deposited on a substrate 54 with HTS ground plane 55 on the back side.
  • the HTS square can support two resonance modes as shown in Figures 7a-7c.
  • the TEio mode has a current flowing along the x direction
  • the TEoi mode has a current flowing along the y direction.
  • both TEio mode and TEoi mode co-exist and are coupled to one another by the cut- corner. The coupling can be adjusted by varying the size of the cut-corner.
  • each cut-corner square in Figure 6a represents two modes and the filter has eight poles.
  • the inter-square coupling is provide by HTS line sections 53a, 53b and 53c and the gaps between cut-corner squares 51a, 51b, 51c, and 51d and the HTS line sections 53a, 53b and 53c.
  • the input and output coupling are provided by HTS line section 52a and 52b and the gap between 52a and 51a and the gap between 52b and 51d.
  • This two dimensional HTS filter can handle more power than the one dimensional HTS filter. But a problem remains in that the two dimensional HTS filter requires a large substrate area, especially when the number of poles is large and the frequency is low, because the side of each square is approximately equal to a half wavelength.
  • the two dimensional HTS filters have moderate power handling capability in the low watts.
  • the present invention provides an unique method to make them in low characteristic impedance with broader line width and to combine them to increase the power handling capability significantly.
  • the present invention provides a structure which greatly reduces the substrate size and makes its package more compact. This structure is particularly suitable for low frequency, multi-pole high power HTS filters.
  • Figures la, lb, 2a, 2b, 3a and 3b are schematic drawings of structures in accordance with this invention of the HTS converted impedance junctions for combining the HTS filters including the microstrip line version shown in Figures la and lb, the strip line version shown in Figures 2a and 2b and the coplanar line version shown in Figure 3a and 3b.
  • Figures 4a and 4b are a schematic drawing of a parallel low impedance HTS filter pair in the microstrip line configuration in accordance with this invention combined by two converted impedance junctions to handle high power.
  • Figures 5a and 5b are schematic drawings of a combined parallel low impedance HTS filter, i.e., 5a, the single pair configuration; 5b, the multi-pair configuration.
  • Figures 6a and 6b are a schematic drawing of a layout of a planar HTS 8-pole dual mode bandpass filter.
  • Figures 7a-7c illustrate the rf (radio frequency) current distributions in HTS planar resonators having a square circuit pattern: 7a, TEio mode; 7b, TEoi mode; 7c, TEio mode and TEoi mode co-exist and are coupled to each other by the cut-corner.
  • Figure 8 schematically represents a structure in accordance with this invention of a stacked configuration 8-pole dual mode HTS bandpass filter and its separated different parts.
  • Figures 9a to 9f depict the individual parts of the stacked configuration 8-pole dual mode HTS bandpass filter of Figure 8: 9a, an unpatterned HTS ground plane; 9b, the layout of the input/output section with coupling to a TEio mode HTS cut-corner dual mode square resonator; 9c, the layout of the input/output section with coupling to a TEoi mode HTS cut-corner dual mode square resonator; 9d, the layout of the HTS ground plane with a coupling slot for the TEoi modes on both sides; 9e, the layout of the HTS ground plane with a coupling slot for the Eio modes on both sides; 9f, the layout of a HTS dual mode square resonator with a cut-corner.
  • Figures lOa-lOc are schematic drawings of a structure in accordance with this invention and the mechanism of the E-field coupling for the dual mode filter: 10a, an HTS ground plane with a rectangular opening for the E-field coupling for the TEoi mode; 10b, an HTS ground plane with a rectangular opening for the E-field coupling for the TEio mode; 10c, a cross section view of an HTS dual mode 4-pole bandpass filter with the E-field coupling and the E-field distribution showing the coupling mechanism.
  • Figures 11a and lib are a cross section view of an assembled 4-pole HTS dual mode bandpass filter in accordance with this invention with tuning rods for fine tuning of the resonant frequencies of the resonators and the grounding mechanism for connecting separate ground planes.
  • Figures 12a-g are the parts for a stacked HTS dual mode filter with round shape configuration according to this invention.
  • Figure 12a shows an HTS ground plane for use in a stacked round shape HTS dual mode filer.
  • Figures 12b and 12c show alternate circuit patterns for use in the resonator components of the filters of the present invention: 12b shows a round pattern with a rectangular notch coupling mechanism for coupling two distinct modes: TEoi and TEio- 12c shows a round pattern with a rectangular stub coupling mechanism for coupling two distinct modes: TEoi and TEio- Figure 12d shows the layout of a round HTS ground plane with a coupling slot for the TEoi mode on both sides.
  • Figure 12e shows the layout of a round HTS ground plane with a coupling slot for coupling the TEio mode on both sides .
  • Figure 12f shows an alternative round HTS ground plane with an elliptical opening E-field coupling mechanism for coupling the TEoi mode on both sides.
  • Figure 12g shows an alternative round HTS ground plane with an elliptical opening E-field coupling mechanism for coupling the TEio mode on both sides.
  • the present invention comprises a structure for combining filters in parallel comprising 1) at least two filters each comprising one or two substrates each having a high temperature superconductor ground plane and a patterned high temperature superconductor circuit, 2) an input splitting converted impedance junction connecting said filters in branches arranged symmetrically to an output combining converted impedance junction, and 3) input and output lines which are impedance matched with the high temperature superconductor circuit .
  • the present invention further comprises a converted impedance junction comprising a) a common port, b) two branch ports connected to said common port combining or splitting circuits in parallel, and c) a matching impedance transformer at the common port.
  • the present invention further comprises a dual mode filter comprising a) alternating stacked ground planes and dual mode resonators, b) a high temperature superconducting transmission line connected to two of said resonators, c) coupling means comprising a mode selective coupling mechanism on each internal ground plane oriented 45° with respect to a coupling mechanism on each resonator adjacent to each internal ground plane, d) tuning rods between adjacent ground planes, and e) grounding links connected to said ground planes.
  • a dual mode filter comprising a) alternating stacked ground planes and dual mode resonators, b) a high temperature superconducting transmission line connected to two of said resonators, c) coupling means comprising a mode selective coupling mechanism on each internal ground plane oriented 45° with respect to a coupling mechanism on each resonator adjacent to each internal ground plane, d) tuning rods between adjacent ground planes, and e) grounding links connected to said ground planes.
  • ground planes and resonators in the dual mode filter each comprise a substrate having a high temperature superconducting film deposited thereon and are arranged in a stacked formation comprising a) two end ground planes, (b) two resonators, one adjacent to each end ground plane and coupled to said high temperature superconducting transmission line, and c) additional internal alternating ground planes and resonators each having a coupling mechanism.
  • the coupling means comprises
  • each resonator adjacent to each internal ground plane comprising a discontinuity in the perimeter of the patterned high temperature superconducting film of said resonator.
  • the coupling mechanism on each ground plane provides coupling between two like resonant modes, while the coupling mechanism on each resonator provides coupling between two distinct resonant modes.
  • the required orientation of the coupling mechanisms provides the mode selection function and permits coupling to a particular desired resonant mode at a particular location within the filter.
  • N is an integer, identical HTS filters in parallel which has N times more power handling capability than the individual one.
  • a second way to increase the power handling capability is to increase the line width of the HTS lines in the filter which can carry more current and much more power, since power is proportional to the square of the current. It would be even better by using a combination of these two methods, i.e., to combine N identical filters with wider line width in parallel. But a simple combination does not work, because these two methods have contradictory requirements.
  • the input and output require 50-ohm matching which translates into a N x 50 ohm characteristic impedance for the filters in a parallel combination.
  • the increase of the line width in the filter translates into a lower characteristic impedance.
  • the present invention provides a converted impedance junction as shown in Figures la, lb, 2a, 2b, 3a and 3b to combine the wide line filters in parallel as shown in Figures 4a and 4b to solve the problem and thereby to increase the power handling capability of the one dimensional HTS filters significantly (10 to 25 times compared to a conventional single 50-ohm filter) .
  • Another way to further increase the power handling capability is to use two dimensional HTS filters.
  • This invention provides a compact structure for two dimensional dual mode HTS filters by stacking the individual dual mode resonators as shown in Figures 8, 9a-9f, lOa-lOc, and lla-llb.
  • the present invention comprises three basic elements.
  • the first is a combination of a plurality of one dimensional low impedance HTS filters with broader line width formed by using a converted impedance junction.
  • the second is the converted impedance junction used to combine the one dimensional filters in parallel.
  • the third is an HTS two dimensional dual mode filter formed by stacking a plurality of HTS coated substrates with coupling means, tuning mechanism and grounding connections.
  • Figures 1(a)-3(b) show three versions of the converted impedance junction of the present invention, which is used for combining HTS filters in accordance with the structures of this invention.
  • the converted impedance junction comprises a) a common or sum port, b) two branch ports connected to said common port combining or splitting circuits in parallel, and c) a matching impedance transformer at the common port.
  • the converted impedance junction serves two purposes: one is as a one-to-two splitter or a two-to-one combiner for microwave signals; the other is as an impedance converter to convert the characteristic impedance Z c at the sum port or common port to the characteristic impedance Z c /2 at the two branch ports and vice versa.
  • Figures la and lb show the microstrip line version. It comprises a substrate 4, an HTS ground plane 5 on the back side of 4 and a patterned HTS circuit on the front side of 4.
  • Figure la shows a top view of the HTS circuit.
  • HTS microstrip line 1 with a characteristic impedance Z c serves as the sum port .
  • the two branch HTS microstrip lines 2 with a characteristic impedance of Z c /2 serve as the branch ports.
  • HTS microstrip line 3 with a characteristic impedance Z c /2 and a length of ⁇ /4, serves as an ⁇ /4 impedance converter where ⁇ represents the guided wavelength at the center frequency of the filters to be combined.
  • a ⁇ /4 impedance converter having a characteristic impedance Z3 matches two impedances Zi and Z2 at its input and output, respectively, when
  • the impedance converted junctions provide a way to combine the two low impedance branch lines in parallel with the sum line and maintains impedance matched at the sum port, which satisfies the requirement for combining two low impedance filters in parallel.
  • FIGS 2a and 2b show the strip line version. It comprises a substrate 14, a superstrate 16, two HTS ground planes 15 on the back side of 14 and 16, and a patterned HTS circuit 17 between the substrate 14 and the superstrate 16.
  • Figure 2a shows a top view of the circuit 17.
  • HTS strip line 11 with a characteristic impedance Z c serves as the sum port .
  • the two branch HTS strip lines 12 with a characteristic impedance of Z c /2 serve as the branch ports.
  • this arrangement serves the same purpose as the microstrip line version in a strip line configuration.
  • Figures 3a and 3b show the coplanar line version of the converted impedance junction. It comprises a substrate 34, and a patterned HTS circuit 37 on the front side of 34. Figure 3a shows a top view of the circuit 37.
  • the HTS center line 31 with a characteristic impedance Z c serves as the sum port.
  • the two branch HTS center lines 32 with a characteristic impedance of Z c /2 serve as the branch ports.
  • the HTS center line 33 with a characteristic impedance Z c /2 and a length of ⁇ /4, serves as an ⁇ /4 impedance converter.
  • the ground planes 35 are on the same side of the substrate 34 as the center lines and are divided into three pieces, as show in Figure 3a.
  • Two air bridges 36 are used to link the three ground planes to suppress the unwanted odd mode which is generated by the junction. According to the same principle described for the microstrip line version, this arrangement serves the same purpose as the microstrip line version in a coplanar line configuration.
  • the present invention further comprises a structure for combining filters in parallel comprising 1) at least two filters each comprising one or two substrates each having a high temperature superconductor ground plane and a patterned high temperature superconductor circuit, 2) an input splitting converted impedance junction connecting said filters in branches arranged symmetrically to an output combining converted impedance junction, and 3) input and output lines which are impedance matched with the high temperature super ⁇ conductor circuit.
  • the ground plane and the patterned circuit can be on the same side of the substrate or on opposite sides of the substrate, or when two substrates are present they can be on the same side in one and on the opposite sides in another.
  • the compositions of the substrates when more than one is present can vary, but preferably the compositions of multiple substrates in each filter are the same.
  • the high temperature superconductor compositions can vary, but preferably are the same for a particular filter.
  • Figures 4a and 4b show an example of two HTS low impedance filters 6 and 6a combined by two converted impedance junctions 7a and 7b at the input and the output in a microstrip line form. It comprises a substrate 4 with HTS ground plane 5 on the back side and patterned HTS circuit 8 on the front side.
  • the two identical 3-pole HTS filters 6 and 6a are combined by two converted impedance joints 7a and 7b at the input and output, respectively.
  • the line width is only 165 ⁇ m, which limits the power handling capability of a filter made of such lines.
  • the 25 ohm HTS microstrip line has a line width of 830 ⁇ m on the same substrate, which is 5 times wider than the 50 ohm line. If the current distribution does not change with line width, the 830 ⁇ m wide 25 ohm line can carry 5 times more current than the 165 ⁇ m wide 50 ohm line with the same current density.
  • the 25 ohm HTS line has 12.5 times higher power handling than the 50 ohm HTS line. Since there are two 25 ohm filters 6 and 6a in the circuit shown in Figure 4a, comparable to a regular 50-ohm HTS filter, this HTS circuit has 25 times higher power handling capability, which is a significant improvement. However, because the current tends to concentrate at the edges of the HTS lines, the increase in current carrying capacity may not be proportional to the increase of the line width. This factor reduces the power handling capability advantage of the 25 ohm HTS filter compared to the 50-ohm filter, i.e., the power handling capability improvement may not be as high as 25 times.
  • the HTS filter circuit shown in Figure 4a still has a significant improvement of power handling capability ranging from about 10 to about 25 times.
  • the two branches in the circuit shown in Figure 4a are preferably identical, i.e., the upper half and the lower half of the circuit are preferably in a mirror image symmetry with respect to the center line.
  • Deviations from symmetry will result in a performance degradation due to either the amplitude or the phase difference between these two branches.
  • Figure 4a The configuration can be in a strip line version and a coplanar line version by using the converted impedance junctions shown in Figures 2a and 2b and Figures 3a and 3b, respectively, and obtain the same advantages .
  • a general form of the HTS filter combination of the present invention is shown in Figure 5a, in which 42 is any form of one dimensional HTS filter with any number of poles, and 41 is the converted impedance junction as shown in Figures la and lb, 2a and 2b or 3a and 3b.
  • the input power is split equally into four channels with four HTS filters in parallel, which increases the power handling capability.
  • the 12.5 ohm line has a much wider line width than the 25 ohm line which further increases the power handling capability.
  • the cascade is not restricted to 2-stage. It can have multiple stages to increase the number of filters in parallel and to further increase the power handling capability. However, there are two factors which limit the number of filters in parallel.
  • a one dimensional filter should not have a line width as large as a half-wave length.
  • the HTS thin film materials useful in the practice of this invention include superconductors with a T c greater than 77 K.
  • Preferred materials include YBa 2 Cu 3 ⁇ 7 , TlBaCaCuO (2212, or 1223), (TlPb)SrCaCuO (1212, or 1223) .
  • the substrate materials suitable for use herein include any dielectric material with close lattice match to the HTS thin film deposited on it and with a loss tangent of less than 0.0001.
  • Preferred are LaA103, MgO, LiNb ⁇ 3, LiTa ⁇ 3, sapphire, and quartz. Stacked Two dimensional Dual Mode HTS Filters
  • the present invention further comprises a dual mode filter comprising a) alternating stacked ground planes and dual mode resonators, b) a high temperature superconducting transmission line connected to two of said resonators, c) coupling means comprising a mode selective coupling mechanism on each internal ground plane oriented 45° with respect to a coupling mechanism on each resonator adjacent to each internal ground plane, d) tuning rods between adjacent ground planes, and e) grounding links connected to said ground planes.
  • a dual mode filter comprising a) alternating stacked ground planes and dual mode resonators, b) a high temperature superconducting transmission line connected to two of said resonators, c) coupling means comprising a mode selective coupling mechanism on each internal ground plane oriented 45° with respect to a coupling mechanism on each resonator adjacent to each internal ground plane, d) tuning rods between adjacent ground planes, and e) grounding links connected to said ground planes.
  • Each ground plane comprises a substrate having a high temperature superconducting film deposited thereon, and each resonator comprises a substrate having a patterned high temperature superconducting film deposited thereon.
  • the substrate and film compositions can vary, but preferably in a particular filter the substrates all have the same composition and preferably the films all have the same composition.
  • the ground planes and dual mode resonators are arranged in a stacked formation comprising a) two end ground planes, b) two resonators, one adjacent to each end ground plane and coupled to said high temperature superconducting transmission line, and c) additional alternating internal ground planes and resonators each having a coupling mechanism.
  • the coupling means comprises a) a mode selective coupling mechanism on each internal ground plane comprising an opening which is oriented 45 degrees with respect to b) a coupling mechanism on each resonator adjacent to each internal ground plane comprising a discontinuity in the perimeter of the patterned high temperature superconducting film of said resonator.
  • the coupling mechanism on the ground plane comprises an opening located at the edge of the ground plane or an opening in the form of a slot located at the center of the ground plane
  • the coupling mechanism on the resonator comprises a discontinuity in the perimeter of the high temperature superconducting film in the form of a notch, cut corner or stub.
  • Each ground plane has two distinct modes on each side thereof, e.g., TEio an d TEoi.
  • the mode selective coupling mechanism on the ground plane couples two like resonance modes, such as TEoi an TEoi, or TEio and TEio, on either side of the ground plane.
  • the coupling mechanism of the resonator couples two distinct resonance modes, such as TEoi and TEio-
  • the required 45 degree orientation of the two coupling mechanisms provides the mode selection function and permits coupling to a particular desired resonant mode at a particular location within the filter.
  • Figures 8 and 9a-9f show a stacked two dimensional dual mode 8-pole HTS filter and its parts .
  • Figure 8 shows the subassembly.
  • FIG. 9a, 9b, 9c, 9d, 9e, and 9f The HTS parts are shown in Figures 9a, 9b, 9c, 9d, 9e, and 9f.
  • the combination of HTS filters shown in Figure 8 is not restricted to eight poles. There can be any number of poles.
  • Figure 8 shows the sub-assembly 67, in which 60 is an unpatterned HTS film deposited on a substrate. There are two of them used as two end ground planes. There are two in- between HTS circuits 63 and two end HTS circuits 61 serving as the dual mode resonators to form the 8-pole filter.
  • the circuits are shown as a square pattern having a cut-corner coupling mechanism, other patterns are suitable as discussed hereinafter in reference to Figures 12a-12g.
  • the resonators 61 also include a section of HTS line coupled to the cut-corner square as the input or output.
  • HTS ground planes 62 and 62a each having a coupling slot are placed between the adjacent HTS resonators 63 and 61 to isolate them and to provide the mode selective couplings.
  • the slot 64 in the HTS ground plane 62 as shown in Figure 9d cuts the current of the TEoi mode shown in Figure 7b, which provides the coupling of TEoi modes on both sides of the ground plane 62.
  • the slot 64a in the HTS ground plane 62a as shown in Figure 9e cuts the current of the TEio mode as shown in Figure 7a, which provides the coupling of TEio modes on both sides of ground plane 62a.
  • the mode sequence in the sub-assembly shown in Figure 8 is TEio- (by the cut-corner on the resonator 61)-TEoi-(by the slot 64 in ground plane 62) -TEoi- (by the cut-corner on the resonator 63)-TE o- (by the slot 64a in ground plane 62a)-TEio-(by the cut-corner on the resonator 63)-TEoi (by the slot 64 in ground plane 62)-TEoi- (by the cut-corner on the resonator 61)-TEio-
  • the slot coupling is highly mode selective due to the fact that it cuts only the current perpendicular to it of one mode and it does not cut the current parallel to it of the other mode.
  • Figure 9a shows the unpatterned HTS film 60 used as a ground plane.
  • Figure 9b shows an HTS pattern of an HTS cut-corner square 61 serving as a dual mode resonator and a section of HTS line coupled to the HTS cut-corner square via a gap serving as the input or output circuit for the TEio mode.
  • Figure 9c shows an HTS pattern of an HTS cut-corner square serving as a dual mode resonator and a section of HTS line coupled to the HTS cut-corner square via a gap serving as the input or output circuit for the TEoi mode.
  • Figure 9d shows an HTS ground plane with a horizontal slot 64, which serves as a coupling apparatus for the TEoi modes on both sides of the ground plane.
  • the coupling mechanism is that the slot cuts the current of the TEoi mode and provides the current/H-field coupling for the TEoi mode on both sides of the ground plane.
  • Figure 9e shows an HTS ground plane with a vertical slot 64a, which serves as a coupling apparatus for the TEio modes on both sides of the ground plane.
  • the coupling mechanism is that the slot cuts the current of TEio mode and provides the current/H-field coupling for the TEio mode on both sides of the ground plane.
  • Figure 9f shows a cut-corner square serving as a dual mode resonator.
  • the HTS patterns in all the parts in Figure 9a-9f are deposited on a lattice matched substrate comprising a dielectric material having a loss tangent of less than 0.0001.
  • Preferred substrates include LaAl ⁇ 3 , MgO, LiNb ⁇ 3 , LiTa ⁇ 3 , sapphire ( ⁇ -Al 2 ⁇ 3) quartz, and the like.
  • the entire subassembly shown in Figure 8 would have a size of 7 cm x 7 cm x 0.5 cm, which will fit in a slightly larger outer enclosure, say 8 cm x 8 cm x 2 cm, which is very compact and easy for maintenance at cryogenic temperature.
  • the savings in the overall size for the stacked version in accordance with this invention is clear.
  • the stacked dual mode HTS filter in accordance with this invention also has a higher power handling capability than a conventional dual mode HTS filter.
  • the conventional filter shown in Figures 6a and 6b has only one substrate and one ground plane. Due to the high dielectric constant of the substrate, the electromagnetic fields of the filter are primarily located between the cut-corner squares 51a, 51b, 51c and 51d, and the ground plane 55. The rf current is primarily located on the inner side of the cut-corner square resonators and ground plane facing the substrate 5 .
  • the stacked dual mode HTS filter of this invention, shown in Figure 8 has two ground planes per each section and the electromagnetic fields are spread on both sides of the cut-corner square resonators.
  • the rf current is also spread between the two sides of the cut-corner square resonators as well as between the two ground planes. Therefore, for the same input power, the current density in the HTS films is approximately reduced to one half for the stacked version compared to the conventional version, which translates into a 4-times higher power handling capability under the same conditions.
  • Figures lOa-lOc show another way in accordance with this invention to provide the E-field coupling between adjacent HTS resonators.
  • Figure 10a shows a HTS ground plane 65 with a rectangular opening 66 located at the maximum E-field of the TEoi mode which lets the E-field go through it, and which provides coupling for the TEoi modes on both sides of the ground plane.
  • Figure 10b shows a HTS ground plane 65a with a rectangular opening 66a located at the maximum E-field of the TEio mode which lets the E-field go through it, and which provides coupling for the TEio modes on both sides of the ground plane.
  • Figure 10c shows a 4-pole dual mode HTS filter with E-field coupling as an example.
  • the dual mode HTS resonator 61a on top acts as an input and excites a TEoi mode in the dual mode square. It is coupled to a TEio mode via a cut-corner in 61a.
  • the cross section E-field distribution pattern is shown in Figure 10c. The E-field on the right side goes through the coupling opening 66a on ground plane 65a from the top section into the bottom section to excite the TEio mode with the E-field as shown.
  • the TEio mode in the bottom section excites the TEoi mode via the cut-corner coupling mechanism in dual mode HTS resonator 61a and provides the output.
  • the E-field coupling opening 66a on ground plane 65a does not provide coupling for the TEoi mode, because there is virtually no E-field of the TEoi mode at the opening 66a.
  • the opening 66 on 65 provides coupling for the TEoi mode only. Therefore, this E-field couplings are also mode selective because of the location of the openings.
  • the E-field coupling can handle more power than a slot coupling due to the fact that the opening is large and is not located at the rf current peak, as the slot is.
  • FIGS 11a and lib show a cross section view of an assembled dual mode 4-pole HTS filter with the invented stacked structure.
  • the filter subassembly comprises two end HTS ground planes 60, two cut-corner HTS square resonators with input and output couplings 61, and HTS ground plane 62 or 65 with coupling slot 64 (not shown) or rectangular opening 66 (not shown) depending upon the coupling mechanism chosen. All the HTS films are deposited on four substrates as shown.
  • the subassembly is placed in and held by a metal case or outer enclosure, which includes a top cover 70a, a bottom cover 70b and a case body or sidewalls 70. 71 and 71a are the input and output connectors.
  • Tuning rods 72 and 72a are used for tuning as shown in Figure 11a. Two tuning rods 72 are used for tuning the two TEio modes: one in the top section and the other on in the bottom section.
  • the other two tuning rods 72a are used for tuning the two TEoi modes: also one in the top section and the other one in the bottom section.
  • the tuning rods are made of dielectric materials with high dielectric constant and low loss tangent such as sapphire, quartz, ceramic, and the like.
  • the dielectric constant of the tuning rod material preferably is within 50% of the highest dielectric constant of any substrate material employed in a ground plane or resonator of the filter.
  • the tuning rod is placed at the maximum E-field of the mode to be tuned. Since the maximum E-field of the TEoi mode is located at the minimum E-field of the TEio mode and vice versa, the tuning can be done separately for each mode without interference.
  • HTS ground planes there are three HTS ground planes in the filter shown in Figures 11a and lib: two end ground planes 60 and one in-between ground plane 62. These three ground planes must be well connected electrically for the filter to perform properly. This can be achieved by the metal (gold or silver) wrap arounds or contacts on the edge of each ground plane and a gasket as shown in the exploded view in Figure lib, in which two metal wraparound contacts 73 are deposited on top of HTS grounds 60, 62 and extended to the edges of the two substrates. A gasket 74 is placed against the left side wall of the case 70, which provides secure electrical contacts between the case and the ground planes as shown in the exploded view.
  • the stacked dual mode multi-pole filter shown in Figures 11a and lib is not restricted to four poles . It can be as any number of poles.
  • the HTS thin film materials can include any superconductor with a T c greater than 77 K and preferably is YBa 2 Cu3 ⁇ 7 , TlBaCaCuO (2212, or 1223), (TlPb)SrCaCuO (1212, or 1223).
  • the substrate materials can be any dielectric material with close lattice match to the HTS thin film deposited on it and with a loss tangent of less than 0.0001, and preferably is LaA103, MgO, LiNb ⁇ 3, LiTa ⁇ 3, sapphire, or quartz.
  • the HTS ground planes and the HTS dual mode resonators are not necessarily confined to the square shape. In fact, since most available substrates are round in shape, the round shape configuration of the HTS ground planes and the HTS dual mode resonators is more favorable for taking advantage of the largest physical area of the substrate.
  • Figures 12a-g show some examples.
  • Figure 12a shows an unpatterned round shaped HTS ground plane 86 deposited on a substrate (not shown) , which can be used as an end plane of a stacked HTS dual mode filter, such as to replace the end planes 60 in Figure 8.
  • Figure 12b shows a round shaped circuit 80(a) having an HTS dual mode resonator 85(a) deposited on a substrate 84(a) .
  • the dual mode resonator 85(a) supports two modes: TEoi and TEio similar to the square version with the current distributions shown in Figure 7.
  • a rectangular notch 81(a) provides the coupling mechanism for these two modes.
  • Figure 12c show a round shaped circuit 80(b) having an HTS resonator 85 (b) deposited on a substrate 84(b) .
  • the dual mode resonator 85(b) supports two modes: TEoi and TEio similar to the square version with the current distributions shown in Figure 7.
  • a rectangular stub 81 (b) provides the coupling mechanism for these two modes.
  • Both circuits 80(a) and 80(b) can be used as the dual mode resonators in a stacked HTS dual mode filter, such as to replace the dual mode resonators 63 shown in Figure 8.
  • Figure 12d shows an HTS ground plane 87 (a) with a horizontal coupling slot 82 (a) providing coupling for the TEoi modes on both sides of the ground plane.
  • Ground plane 87(a) can be used as an internal ground plane in a stacked HTS dual mode filter such as to replace the ground plane 62 in Figure 8.
  • Figure 12e shows an HTS ground plane 87 (b) with a vertical coupling slot 82 (b) providing coupling for the TEio modes on both sides of the ground plane.
  • Ground plane 87(b) can be used as an internal ground plane in a stacked HTS dual mode filter, such as to replace the ground plane 62a in Figure 8.
  • Figure 12f shows an HTS ground plane 88 (a) with an elliptical shaped opening 83 (a) providing the E-field coupling for the TEoi modes on both sides of the ground plane.
  • Figure 12g shows an HTS ground plane 88(b) with an elliptical shaped opening 83(b) providing the E-field coupling for the TEio modes on both sides of the ground plane.
  • Ground plane 88(b) can be used as an internal ground plane in a stacked HTS dual mode filter, such as to replace the ground plane 65a in Figure 10c.
  • All the filters of the present invention are useful as frequency selectors in microwave components having widespread applications in commercial and military microwave systems. Examples include telecommunication, instruments as well as radar and electronic systems.

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  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Control Of Motors That Do Not Use Commutators (AREA)
  • Superconductor Devices And Manufacturing Methods Thereof (AREA)
EP95916934A 1994-04-14 1995-04-12 Hochtemperatursupraleitende filter mit hoher leistung Withdrawn EP0755577A1 (de)

Applications Claiming Priority (3)

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US22743794A 1994-04-14 1994-04-14
US227437 1994-04-14
PCT/US1995/004302 WO1995028746A2 (en) 1994-04-14 1995-04-12 High power high-temperature superconductive filters

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JP (1) JPH09512150A (de)
CA (1) CA2185666A1 (de)
WO (1) WO1995028746A2 (de)

Cited By (1)

* Cited by examiner, † Cited by third party
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CN105720333A (zh) * 2016-01-28 2016-06-29 华为技术有限公司 滤波器

Families Citing this family (11)

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Publication number Priority date Publication date Assignee Title
JP2001345601A (ja) 2000-03-30 2001-12-14 Toshiba Corp フィルタ回路
JP3562442B2 (ja) * 2000-05-23 2004-09-08 株式会社村田製作所 デュアルモード・バンドパスフィルタ
JP2005229304A (ja) * 2004-02-12 2005-08-25 Nippon Telegr & Teleph Corp <Ntt> 高周波回路
EP1782496B1 (de) * 2004-07-30 2010-04-28 Raython Company Vorrichtugnen und verfahren für zweigspeisungs-koppelringresonatorpaar-filter mit elliptischen funktionen
JP2008028836A (ja) * 2006-07-24 2008-02-07 Fujitsu Ltd 超伝導フィルタデバイスおよびその作製方法
KR100867042B1 (ko) * 2007-01-30 2008-11-04 레이티언 캄파니 분산-공급 커플드-링 공진기-쌍 타원-함수 필터용 장치 및 방법과 이 필터를 포함하는 전송기 및 수신기
US8600330B2 (en) 2011-10-05 2013-12-03 Kathrein-Werke Kg Filter arrangement
CN103022599A (zh) * 2012-11-28 2013-04-03 杨磊 Pcb滤波器
JP6334316B2 (ja) * 2014-08-20 2018-05-30 株式会社東芝 フィルタ装置、受信装置、送信装置、アンテナ装置、及び切替装置
RU2688826C1 (ru) * 2018-06-18 2019-05-22 Федеральное государственное автономное образовательное учреждение высшего образования "Сибирский федеральный университет" Микрополосковый полосно-пропускающий фильтр
US11211676B2 (en) * 2019-10-09 2021-12-28 Com Dev Ltd. Multi-resonator filters

Family Cites Families (2)

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Publication number Priority date Publication date Assignee Title
JPH0682998B2 (ja) * 1986-07-30 1994-10-19 日本電信電話株式会社 電力増幅器
JP2516984B2 (ja) * 1987-06-24 1996-07-24 松下電器産業株式会社 ▲ろ▼波器

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
See references of WO9528746A3 *

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105720333A (zh) * 2016-01-28 2016-06-29 华为技术有限公司 滤波器

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