WO2014085383A1 - Dielectric waveguide filter with direct coupling and alternative cross-coupling - Google Patents

Dielectric waveguide filter with direct coupling and alternative cross-coupling Download PDF

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Publication number
WO2014085383A1
WO2014085383A1 PCT/US2013/071859 US2013071859W WO2014085383A1 WO 2014085383 A1 WO2014085383 A1 WO 2014085383A1 US 2013071859 W US2013071859 W US 2013071859W WO 2014085383 A1 WO2014085383 A1 WO 2014085383A1
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WO
WIPO (PCT)
Prior art keywords
block
dielectric material
dielectric
resonators
waveguide filter
Prior art date
Application number
PCT/US2013/071859
Other languages
English (en)
French (fr)
Inventor
Alexandre Rogozine
Reddy Vangala
Original Assignee
Cts Corporation
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Priority claimed from US14/088,471 external-priority patent/US9130255B2/en
Application filed by Cts Corporation filed Critical Cts Corporation
Priority to DE112013005683.6T priority Critical patent/DE112013005683T5/de
Priority to KR1020157014197A priority patent/KR102244162B1/ko
Priority to CN201380062168.9A priority patent/CN104871364B/zh
Priority to GB1509253.9A priority patent/GB2522587B/en
Priority to CA2892969A priority patent/CA2892969A1/en
Priority to JP2015545172A priority patent/JP2015536624A/ja
Publication of WO2014085383A1 publication Critical patent/WO2014085383A1/en

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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
    • H01P1/207Hollow waveguide filters
    • H01P1/208Cascaded cavities; Cascaded resonators inside a hollow waveguide structure
    • H01P1/2088Integrated in a substrate
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P1/00Auxiliary devices
    • H01P1/20Frequency-selective devices, e.g. filters
    • H01P1/2002Dielectric waveguide filters
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P1/00Auxiliary devices
    • H01P1/20Frequency-selective devices, e.g. filters
    • H01P1/207Hollow waveguide filters
    • H01P1/209Hollow waveguide filters comprising one or more branching arms or cavities wholly outside the main waveguide
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P7/00Resonators of the waveguide type
    • H01P7/10Dielectric resonators

Definitions

  • the invention relates generally to dielectric waveguide filters and, more specifically, to a dielectric waveguide filter with direct coupling and alternative cross*coupling.
  • This invention is related to a dielectric waveguide filter of the type disclosed in U.S. Patent No. 5,926,079 to Heine et at. in which a plurality of resonators are spaced longitudinally along the length of a monobfock and in which a plurality of slots/notches are spaced longitudinally along the Iength of the monoblock and define a plurality of bridges between the plurality of resonators which provide a direct inductive/capacitive coupling between the plurality of resonators.
  • the attenuation characteristics of a waveguide filter of the type disclosed in U.S. Patent No. 5,926,079 to Heine et al. can be increased through the
  • additional resonators located at one or both ends of the waveguide filter.
  • a disadvantage associated with the incorporation of additional resonators, however, is that it also increases the length of the filter which, in some applications, may not be desirable or possible due to, for example, space limitations on a customer's motherboard.
  • the attenuation characteristics of a filter can also be increased by both direct and cross-coupling the resonators as disclosed in, for example, U.S.
  • Patent No, 7,714,880 to Vangala et al which discloses a monobfock filter with both inductive direct coupling and quadruplet cross-coupling of resonators created in part by respective metallisation patterns which are defined on the top surface of the filter and extend between selected ones of the resonator through- holes to provide the disclosed direct and cross-coupling of the resonators.
  • the present invention is thus directed to a dielectric waveguide filter with both direct and optional cross-coupled resonators which allow for an increase in the attenuation characteristics of the waveguide filter without an increase in the length of the waveguide f ilter or the use of metallization patterns on the top surface of the filter.
  • the present invention is directed to a dielectric waveguide filter
  • a block of dielectric material including a plurality of exterior surfaces covered with an exterior layer of conductive material, a plurality of stacked resonators defined i th block of dieiectric materia! by one or more slots extending into the block of dielectric materia! and an interior layer of conductive materiaf that separates the plurality of stacked resonators, at least a first RF signal input output electrode defined on the block of dielectric material, and a first RF signai transmission window defined in the inferior layer of conductive material and defining a direct path for the transmission of an RF signal between the plurality of stacked resonators.
  • first and second slots extend into one or more of the exterior surfaces of the block of dielectric material and separate the block of dielectric material into at least first and second stacked resonators and third and fourth stacked resonators, the first RF signal transmission window being defined in the interior layer of conductive material between the first and second stacked resonators and a second RF signal transmission window is defined in the interior layer of conductive material and defines an indirect path for the transmission of the RF signal between the third and fourth stacked resonators.
  • a second RF signal Input/output electrode is defined in the block of dielectric material in a relationship relative to the first RF signal input/output electrode to define a generally oval shaped direct path for the transmission of the RF signal through the dielectric waveguide fitter.
  • the block of dielectric material defines a longitudinal axis and the first and second RF signal input output electrodes are defined by respective first and second through-holes extending through the block of dielectric material, the first and second slots and the first and second through- holes extending in a direction transverse to the direction of the longitudinal axis, and the first and second through-holes being disposed in a diametrically opposed and co-iinear relationship on opposite sides of the interior layer of conductive material.
  • the block of dielectric materia! is comprised of first and second separate blocks of dielectric material each including a plurality of exterior surfaces covered with an exterior layer of conductive material and defining the interior layer of conductive material when the first and second separate blocks of dielectric material are stacked on each other, the first slot being defined in the first block of dielectric materiaf and separating the first block of dielectric material into the first and third resonators, the second s!ot being defined in the second biock of dielectric material and separating the second block of dielectric material into the second and fourth resonators, the respective first and second RF signal transmission windows being defined by respective windows in the layer of conductive material which covers the exterior surface of each of the first and second blocks of dielectric material.
  • the present invention is also directed to a dielectric waveguide fitter comprising a first block of dielectric material including a plurality of exterior surfaces covered with a !ayer of conductive material and at least a first siof extending into one or more of the exterior surfaces and separating the first block of dielectric material into at least first and second resonators, a first RF signal input output electrode defined at one end of the first block of dielectric material, and a second block of dielectric material including a plurality of exterior surfaces covered with a layer of conductive material and at least a second slot extending into one or more of the exterior surfaces and separating the second block of dielectric material into at least third and fourth resonators, the second block of dielectric material being stacked on the first block of dielectric material in a relationship wherein the first and fourth resonators are stacked on each other and the second and third resonators are stacked on each other and a first direct generally oval shaped RF signal transmission path is defined through the waveguide f ilter.
  • the first direct RF signal transmission path is defined in part by a first RF signal transmission window located between the second and third stacked resonators.
  • the first direct RF signal transmission window is defined by respective first and second windows in the layer of conductive material covering the exterior surface of the respective first and second blocks of dielectric materia ⁇ .
  • a second RF signal transmission window located is between the first and fourth stacked resonators for providing an indirect path for the transmission of the RF signal between the first and fourth resonators.
  • the second F signal transmission window is defined by respective third and fourth windows in the layer of conductive materiai covering the exterior surface of the respective first and second blocks of dielectric material.
  • a second RF signal input output electrode is defined at one end of the second biock of dielectric material and positioned in a relationship diametrically opposed to the first RF signal input/output electrode defined at the one end of the first block of dielectric material, the first and second RF signal input/output electrodes being defined by respective first and second through-holes extending through the respective first and second blocks of dielectric material.
  • respective first and second steps are defined in the respective one ends of the first and second blocks of dielectric material, the respective first and second through-holes extending throug the respective first and second steps.
  • the present invention is further directed to a dielectric waveguide filter comprising a first biock of dielectric material defining a first longitudinal axis and including a plurality of exterior surfaces covered with a layer of conductive material, a first plurality of slots defined in the first block of dielectric materiai and extending in a direction opposite the direction of the first longitudinal axis and separating the first block of dielectric material info a first plurality of resonators extending along the first longitudinal axis, and a first step defined at one end of th first block of dielectric material, a first RF signal input/output through-hole defined in the ste of the first biock of dielectric material, a second block of dielectric material seated against the first block of dielectric material, the second block of dielectric material defining a second longitudinal axis and including a plurality of exterior surfaces covered with a layer of conductive material, a second plurality of slots defined in the second biock of dielectric materiai and extending in a direction opposite the direction of the second longitudinal
  • the first direct RF signal transmission path is defined in part by a first direct RF signal transmission means located between a first one of the first plurality of resonators in the first block of dielectric material and a first one of the second plurality of resonators in the second block of dielectric material.
  • the first direct RF signal transmission means is defined by respective first and second windows defined in the layer of conductive material covering the exterior surface of the respective irst and second blocks of dielectric mate rial
  • a first indirect RF signal transmission means defines a first indirect coupling path for the transmission of the RF signal f om a second one of the first plurality of resonators in the first block of dielectric material to a second one of the second plurality of resonators in the second block of dielectric material.
  • the first indirect RF signal transmission line means is defined by respective third and fourth windows defined in the layer of conductive material covering the plurality of exterior surfaces of the respective first and second blocks of dielectric material.
  • the first direct RF signal transmission path is generally ova! in shape.
  • FIGURE 1 is an enlarged perspective view of a dielectric waveguide filter according to the present invention.
  • FIGURE 2 is an enlarged, part phantom, perspective view of the dielectric waveguide filter shown in FIGURE 1;
  • FIGURE 3 is an enlarged, exploded, part phantom, perspective view of the two blocks of the dielectric waveguide filter shown in FIGURE 1 ;
  • FIGURE 4 is a graph depicting the performance of the dielectric
  • FIGURE 5 is an enlarged, part phantom, perspective view of another embodiment of a dielectric waveguide filter according to the present invention.
  • FIGURE 8 is an enlarged, exploded, broken, part phantom, perspective view of the two blocks of the dielectric waveguide filter shown in FIGURE 5,
  • FIGURES 1, , and 3 depict a waveguide fitter 1 00 incorporating both direct and alternative cross-coupling/indirect coupling features and
  • the waveguide fitter 1100 is made from a pair of separate generally parallelepiped-shaped monoblocks of dielectric material 1 01 and 1103 which have been coupled together in a stacked relationship to form the waveguide filter 1100.
  • the bottom monoblock 1101 is comprised of a suitable solid block or core of dielectric material , such as for example ceramic, and includes opposed longitudinal horizontal exterior surfaces 1102a and 1104a, opposed longitudinal side vertical exterior surfaces 1106a and 108a that are disposed in a
  • relationship norma! to and extend between the horizontal exterior surfaces 1102a and 1104a, and opposed transverse end side vertical exterior end surfaces 10a and 1112a that are disposed in a relationship generally norma! to and extend between the longitudinal horizontal exterior surfaces 1102a and 104a and the longitudinal vertical exterior surfaces 1 02a and 1102b,
  • each of the surfaces 102a, 1104a, 1106a, and 1108a extends in the same direction as the longitudinal axis L1 (FIGURE 3) of the monoblock 1101 and each of the end surfaces 1110a and 1112a extends in a direction transverse or normal to the direction of the longitudinal axis L1 of the monoblock 1101.
  • the top monoblock 1 103 is also comprised of a suitable solid block or core of dielectric material, such as for example ceramic, and includes opposed longitudinal horizontal exterior surfaces 1102b and 1104b, opposed longitudinal side vertical exterior surfaces 1106b and 1108b disposed in a relationship normal to and extending between the horizontal exterior surfaces 1102b and 1104b, and opposed transverse end side vertical exterior surfaces 1110b and 1 1 2b disposed in a relationship normal to and extending between the horizontal exterior surfaces 1 02b and 1 04b and the longitudinal side vertical exterior surfaces 1106b and 1108b.
  • a suitable solid block or core of dielectric material such as for example ceramic
  • each of the surfaces 1102b, 1104b, 1106b, and 1108b extends in the same direction as the longitudinal axis L2 ⁇ FIGURE 3) of the monoblock 11 3 and each of the surfaces 1 1 0b and 1112b extends in a direction transverse or normal to the direction of the longitudinal axis L2 of the monoblock 1103.
  • the monobiocks 1101 and 1103 include respective first and second pluralities of resonant sections (also referred to as cavities or cells or resonators) 114, 1 6, and 1118 and 1120, 11 1 , and 1122 which are spaced longitudinally along the length of, and extend co-linearly with and in the same direction as the longitudinal axis L1 and L2 of, the respective monobiocks 1101 and 103 and are separated from each other by a plurality of (and more specifically a pair in the embodiment of FIGURES 1 , 2, and 3) spaced-apart and generall parallel vertical slits or slots 11 4a in the monoblock 1 101 that are cut into the vertical exterior surface 1106a and, more specif ically, are cut into the surfaces 102a, 1104a, and 1 08a of the monoblock 1 101 , and a pair of spaced-apart and generally parallel vertical slits or slots 1124b in th monoblock 1103 that are cut into the vertical exterior surface 06b and, more specifically, ar cut
  • each of the vertical slits or slots 1124a and 1124b extend in a direction generally transverse or normal to the direction of the longitudinal axis L1 and 12 of the respective monoblocks 1101 and 1 3.
  • monoblock 1101 defines a first bridge or through-way or pass 1128 on the monoblock 1101 for the passage and transmission of an RF signal between the resonator 1114 and the resonator 11 6 while the other of the slits 1124a in the monoblock 1101 defines a second bridge or through-way or pass 1 30 on the monoblock 101 for the passage and transmission of an RF signal between the resonator 1116 and the resonator 1118.
  • the one of the slits 1124b in the monoblock 1103 defines a first bridge or through-way or pass 1134 on the monoblock 1103 for the passage and transmission of an RF signal between the resonator 122 and the resonator 1 21 while the other of the silts 1124b in the monoblock 1103 defines a second bridge or through -way or pass on the monoblock 1 03 for the passage and transmission of an RF signal between the resonator 1 1 and the resonator 11 0.
  • the monobiock 1 101 and more specifically the end resonator 1114 of the monoblock 1101, additionally comprises and defines an end step 1136a comprising, in the embodiment shown, a generally L-shaped recessed o grooved or shouldered or notched region or section of the longitudinal surface 102a, opposed side surfaces 1106a and 108a, and side end surface 1112a of the monoblock 1101 from which dielectric ceramic material has been removed or is absent.
  • the monoblock 1103, and more specifically the end resonator 1122 of the monoblock 1103, similarly additionally comprises and defines an end step 136b comprising, in the embodiment shown, a generally L-shaped recessed or grooved or shouldered or notched region or section of the longitudinal surface 1104b, opposed side surfaces 1106b and 108b, and side end surface 1112b of the monobfock 1103 from which dielectric material has been removed or is absent.
  • the respective steps 1136a and 1138b are defined in and by an end section or region of the respective monobiocks 101 and 1 03 having a height or thickness less than the height or thickness of the remainder of the respective monobiocks 1101 and 1103,
  • the respective end steps 1136a and 1136b each comprise a generally L-shaped recessed or notched portion of the respective end resonators 1 14 and 1122 defined on the respective monobiocks 1101 and 1103 which include respective first generally horizontal surfaces 1140a and 1140b located or directed inwardly of, spaced from, and parallel to the surfaces 1102a and 1104b of the respective monobiocks 1 01 and 1103 and respective second generally vertical surfaces or wails 1142a and 1142b located or directed inwardly of, spaced from, and parallel to, the respective side end surfaces 1110a and 1112a and 1110b and 11 b of the respective monobiocks 1101 and 1103.
  • end steps 1136a and 1 136b could also be defined by an outwardly extending end section or region of the respective monobiocks 1101 and 103 having a height or thickness greater than the height or thickness of the remainder of the respective monobiocks 101 and 1103.
  • the monobiocks 1 101 and 103 additionally each comprise an electrical F signal input/output electrode which, in the embodiment shown, is in the form of respective cylindrically shaped through-holes 1146a and 1146b (FIGURES 2 and 3) which extend through the body of the respective monobiocks 1101 and 1103 and, more specifically, extend through the respective steps 1136a and 1136b thereof and, stiil more specifically, through the body of the respective end resonators 1114 and 1122 defined in the respective monobiocks 1101 and 1103 between, and in relationship generally normal to, the respective surfaces 1140a and 1 140b of the respective steps 1 136a and 1 136b and the respective surfaces 104a and 1 102b of the respective monobiocks 1 101 and 1 03.
  • the respective input/output through -holes 1 46a and 1 46b are spaced from and generally parallel to the respective transverse side end surfaces 1112a and 1 112b of the respective monobiocks 1 01 and 1103 and define respective generally circular openings 1 147a and 1147b located and terminating in the respective step surfaces 1 140a and 1 140b and respective opposed openings 1 148a and 1 148b terminating in the respective block surfaces 1104a and 1102b ⁇ FIGURE 3).
  • the respective RF signal input output through-holes 1146a and 1146b are also located and positioned in and extend through the interior of the respective monobiocks 1101 and 1103 in a relationship generally spaced from and parallel to the respective ste wail or surfaces 1 142a and 1 142b and in a relationship and direction generally normal or transverse to the longitudinal axis of the respective monobiocks 1101 and 1 03.
  • All of the external surfaces 1 102a, 1104a, 1106a, 1 08a, 1 10a, and 112a of the monob!ock 1 01 , the external surfaces of the monoblock 1 101 defining the slits 1124a, and the interior cylindrical surface of the monoblock 1 101 defining the RF signal input/output through-hole 46a are covered with a suitable conductive material, such as for example silver, with the exception of the regions described in more detail be!ow including a ring shaped region 1 170a (FIGURES 2 and 3) on the surface 140a and surrounding the opening 1 47a def ined in the surface 1 140a by the through-hole 46a.
  • a suitable conductive material such as for example silver
  • all of the exterior surfaces 1 102b, 1 104b, 1 06b, 111 b, and 12b of the monoblock 1103, the external surfaces of the monoblock 1 03 defining the slits 1124b, and the interior cylindrical surface of the monoblock 1 03 defining the RF signal input/output through-hole 1146b are covered with a suitable conductive material, such as for example silver, with the exception of the regions described in more detail below including a ring shaped region 1170b (FIGURES 1 , 2 » and 3) on the surface 1140b and surrounding the opening 1147b defined in the surface 1140b by the through-hole 1 46b.
  • a suitable conductive material such as for example silver
  • the monoblocks 101 and 1103 still further comprise respective RF signal input output connectors 1400 protruding outwardly from the respective openings 1147a and 1147b def ined in the respective surfaces 1140a and 1140b by the respective through-holes 1148a and 146b,
  • the separate monoblocks 1 01 and 1103 are coupled to and stacked on each other in an overlying and abutting and stacked relationship to define and form the waveguide filter 1100 in a manner in which the separate monoblocks 101 and 1103, and more specifically the respective resonators thereof, are arranged in an overlying, abutting, and stacked relationship against each other as described in more detail below.
  • the monoblocks 101 and 1103 are coupled to each other in a relationship wherein, as shown in FIGURES 1 , 2 S and 3, the longitudinal horizontal exterior surface 1102b of the top monoblock 1103 is seated on and abutted against the longitudinal horizontal exterior surface 1104a of the bottom monoblock 1101.
  • the monoblocks 1101 and 103 are stacked against each other in a relationship wherein the horizontal surface 104a of the
  • a central interior layer 1150 of conductive material (FIGURES 1 and 2) which extends the length and width of the interior of the waveguide filter 100 is sandwiched between the surface 1104a of the monoblock 1101 and the surface 1102b of the monoblock 1103, and is defined by the layer of conductive material covering the length and width of the external surfaces 1104a and 1102b of the respective monoblocks 1101 and 1 03;
  • the longitudinal side vertical exterior surface 1106a of the monoblock 1101 is co-planarly aligned with the longitudinal side vertical exterior surface 1106b of the monoblock 1 03;
  • the slots 1124a on the monoblock 1101 are co-linearly aligned with the slots 1124b on the monoblock 103;
  • the opposed longitudinal side vertical exterior surface 1108a of the monoblock 1101 is co-planarly aligned with the longitudinal side vertical exterior surface 1108b of the monoblock 1 03;
  • the transverse end side vertical exterior surface 1110a of the monoblock 1101 is co-planarty aligned with the transverse
  • the respective end steps 1136a and 1138b on the respective monoblocks 1 01 and 1103 are disposed in an opposed, abutting, and stacked relationship; the respective resonators 1 114 and 1122 on the respective monoblocks 1101 and 1103 are disposed in an opposed, abutting, and stacked relationship; the respective resonators 1116 and 1121 on the respective monoblocks 1101 and 1103 are disposed in an opposed, abutting, and stacked relationship; and the respective resonators 1 18 and 1 0 on the respective monoblocks 1101 and 1103 are disposed in an opposed, abutting, and stacked relationship.
  • the waveguide filter 1100 is a generally parallelepiped-shaped block of dielectric material defining a longitudinal axis L3 and includes opposed, spaced-apart, and parallel bottom and top longitudinal horizontal exterior surfaces 1102 and 1104 that correspond to the respective exterior surfaces 1102a and 1102b of the respective monoblocks 101 and 1103 and extend in th same direction as, and below and above and generally parallel to, the longitudinal axis L3; a central inferior layer 1150 of conductive material that corresponds to th layer of conductive material on each of the surfaces 1104a and 102b of the respective monoblocks 1101 and 1103 and extends through the full length and width of the interior of the waveguide filter 1 00 in a generaily horizontal co-planar relationship with the longitudinal axis 13 and further in a relationship spaced from and generally parallel to, the bottom and top horizontal longitudinal exterior surfaces 102 and 1104; opposed, spaced-apart and parallel side vertical exterior surfaces 1106 and 1108 that correspond to the vertically co-pianarly align
  • the end section or region 1136 defines a first generally L-shaped step or shoulder 1138a corresponding to the step 1136a defined in the monobiock 1101, which is located below and spaced from the longitudinal axis L3, and includes an exterior surface 1140a extending inwardly and spaced from and parallel to the bottom exterior surface 1102 of the waveguide filter 1100; and a diametrically opposed second generally L-shaped step or shoulder 1136b corresponding to the step 1136b in the monobiock 103, which is located above and spaced from the longitudinal axis L3 and including an exterior surface 1140b extending inwardly and spaced f rom and parallel to the top exterior surface 1104 of the waveguide filter 100.
  • a generally cylindrical ⁇ shaped through-hole 1 46a corresponding to the through-hole 1146a defined in the monobiock 1101 extends through the end section 1136, in a relationship and direction transverse and normal to and below the longitudinal axis L3, between a generally cylindrical shaped opening 1147a defined in the step surface 1140a and the central layer 1150 of conductive material.
  • a generally cylindrically shaped through-hole 1146b corresponding to the through-hole 1146b in the monoblock 1103 extends through the end section 1136, in a relationship co-linear with and diametrically opposed to the through- hole 1146b and in a relationship and direction transverse and normal to and above the longitudinal axis L3, between a generally cylindrically shaped opening 1147b defined i th step surface 1140b and the central layer 1150 of
  • the through-holes 1146a and 1146b are located in a diametrically opposed and co-linear relationship on opposite sides of, and in a relationship generally normal to, the central layer 1150 of conductive material and the longitudinal axis L3 of the waveguide f ilter 10O.ip
  • each of the exterior surfaces 1102, 1104, 106, 1108, 1110, 1 112 of the waveguide filter 1100, the interior surface of the waveguide filter 100 defining the respective slits/slots 1 4, and the interior surface of the waveguide filter 1100 defining the respective through- holes 1146a and 1146b are covered or coated with a layer of conductive material with the exception of respective circular or ring shaped regions 1170a and 1170b 1151 surrounding the respectiv openings 1147a and 1 47b defined by the respective through-holes 1146a and 146b in the respective step surfaces 1140a and 1 40b of the end section 1136.
  • the waveguide filter 1100 further comprises a first interior or internal RF signal transmission window or means or coupling 1622 (FIGURES 2 and 3), which in the embodiment shown is in the shape of a rectangle extending in a direction transverse to and intersecting the longitudinal axis L3, that provides for a direct inductive path or window or coupling for the transmission of the RF signal between the respective resonator 1118 and 1 0 of the waveguide filter 1100 and, more specifically, between the resonators 1 8 and 1120 of the respective monob!ocks 1101 and 1103 coupfed together to define the waveguide filter 1100.
  • FIGURES 2 and 3 first interior or internal RF signal transmission window or means or coupling 1622
  • the window 1622 comprises a generally rectangularly shaped aperture or void or opening or window that is defined in the central layer 1150 of conductive material and is formed in the region of the central layer 1150 located between the resonators 1118 and 1120. More specifically, the window 1622 is defined by respective generally rectangularly shaped apertures or voids or openings or windows 1622a and 1622b that are formed in the layer of conductive material that covers th respective exterior surfaces 1104a and 1102b of the respective monoblocks 101 and 103 and located thereon in the region of the respective resonators 1118 and 1120. The windows 1622a and 1622b are aligned with each other when the monoblocks 1101 and 1 03 are coupled together to define the central layer 150 of conductive material and the window 1622 therein.
  • the window 1622 is defined by respective generally rectangularly shaped regions 1622a and 1622b of dielectric material on the respective exterior surf aces 1 04a and 1102b of the respective monoblocks 1101 and 1103 which upon alignment with each other when the monoblocks 1101 and 1103 are coupled together defines the interior RF signal transmission window 1622.
  • the window 1622 located In the interior of the waveguide filter 1100 between the resonators 1116 and 1 20 allows for the internal or interior direct inductive passage or transmission of an RF signal from the resonator 1118 into the resonator 1120 of the waveguide filter 100.
  • the waveguide filter 1100 additionally comprises a first indirect or cross- coupling interior or internal capacitive RF signal transmission window or means or coupling 1722 located in the interior of the waveguide filter 1100 between the resonators 1116 and 1121, which in th embodiment shown is in the shape of a rectangle extending in the same direction as and co-linear with the longitudinal axis L3 and the window 1622 , for transmitting an RF transmission signal between the respective resonators 1116 and 121 of the waveguide filter 1 00
  • the window 1722 comprises a generally rectangularly shaped aperture or void or opening or window that is defined in the central layer 1150 of conductive material and is formed in the region of the central layer 1150 located between the resonators 1116 and 1121 ,
  • the window 1722 is defined by respective generally rectangularly shaped apertures or voids or openings or windows 1722a and 1722b that are formed in the layer of conductive material that covers the respective exterior surfaces 1104a and 1102b of the respective monobiocks 1101 and 1103 and are located in the region of the respective resonators 1116 and 11 1.
  • the windows 1722a and 1722b are aligned with each other when the monobiocks 1101 and 11 3 are coupled together to define the central layer 1150 of conductive material and the window 1 22 therein.
  • the window 1722 is defined by respective generally rectangularly shaped regions 1722a and 1722b of dielectric material on the respective exterior surfaces 1104a and 1102b of the respective monobiocks 1101 and 1103 which upon alignment with each other when the monobiocks 1101 and 1103 ar coupled together defines the interior RF signai transmission window 1722.
  • the waveguide fiiter 1100 defines a first magnetic or inductive generally oval-shaped direct coupling RF signal
  • FIGURE 2 as described below.
  • the RF signal is transmitted into the connector 1400 and the through-hole 1146a in the embodiment where the through-hole 1146a in the monoblock 1101 defines the RF signai input through-hole.
  • the RF signai is transmitted into the end section 1136 and, more specifically, the end step 1 36a on the monoblock 1101; then into the resonator 11 14 in monoblock 101 ; then into the resonator 1116 in monoblock 1101 via the RF signal transmission bridge or pass 1128; and then into the resonator 1 118 in
  • the RF signal is transmitted from the monoblock 1 101 into the monoblock 1103 and, more specifically, from the resonator 1118 in the monoblock 1 101 into the resonator 1 120 In the monoblock 1 03 via the interior inductive RF signal transmission window 1622 located in the interior of the waveguide filter 1 100 between the resonators 11 18 and 1 20,
  • the RF signal is transmitted into the resonator 1121 in the monoblock 1103 via the RF signal transmission bridge or pass 1 132; then into the resonator 1122 in monoblock 1 103 via the RF signal transmission bridge or pass 1 134; then into the end section 136 of monoblock 1 03 and, more specifically, into the step 1 136b of monoblock 1 103; and then out through the through-hole 1 46b and the connector 1400 in the end section 1136 of monoblock 103 in the embodiment where the through-hole 1146b in the monoblock 1 103 defines the RF signal output through-hole.
  • the waveguide filter 100 also defines and provides an alternate or indirect- or cross- coupling RF signal transmission path for RF signals generally designated by the arrow c In FIGURE 2.
  • the cross-coupling or indirect capacitive RF signal is the cross-coupling or indirect capacitive RF signal
  • transmission path c is defined and created by the interior RF signal transmission means or window 1722 located between the resonators 11 16 and 1121 which allows for the transmission of a small portion of the direct RF signal being transmitted through the resonator 1 1 16 of the monoblock 101 directly into the resonator 1 121 of the monoblock 1 103.
  • the internal RF signal transmission window 1622 between and interconnecting the respective resonators 1 1 18 and 1 1 0 of the respective monoblocks 1 101 and 1 103 of waveguide filter 100 is designed/sized to create an inductive direct RF signal coupling stronger than the indirect, capacitive cross-coupling created and defined by the internal RF transmission window 1722 between and
  • FIGURE 4 is a graph which shows the calculated frequency response of the high performance dieiectric waveguide filter 1100 which, in the embodiment shown, is comprised of and includes the following performance characteristics: monoblocks 1103 and 1103 each comprised of a high quality C14 ceramic material with a dielectric constant of about 37 or above; monoblocks 1101 and 1103 each being approximately 2 inches in length, 0.5 inches in width, and 1.1 inches in height; a bandwidth up to five percent (5%) of the center frequency; power handling up to two hundred watts (200W); resonators having a Q in the range between about one thousand to tw thousand (1000-2000); insertion loss of about minus two dB ( ⁇ 2 dB ⁇ ; out of band rejection of about minus seventy dB (-70 dB); bandwidth in the range of between about forty to one hundred
  • FIGURE 5 is another embodiment of a dielectric waveguide fitter 2100 in accordance with the present invention which is identical, in aii but one respect as discussed below, to the structure, elements, and function of the dielectric waveguide filter 1100, and thus th numerals used to designate the various elements of the waveguide filter 1100 in FIGURES 1-3 have been used to identify and designate the same elements in the waveguide filter 2100 shown in FIGURE 5 and thus the earlier description of the structure and function of each of the elements of the waveguide filter 1 00 is incorporated herein by reference and applies to and is repeated herein with respect to each of the elements identified in FIGURE 5 with respect to the waveguide filter 2100 as though such description was fully set forth herein.
  • the waveguid filter 2100 shown in FIGURE 5 differs from the waveguide filter 1100 shown in FIGURES 1-3 in that the rectangularly shaped indirect or cross-coup! ing interior or internal capacitive RF signal transmission window or means or coupling 1722 located in the interior of the waveguide fitter 1 100 between the resonators 1 116 and 1 121 has been substituted in the waveguide filter 2100 shown in FIGURE 5 with a round or circular shaped indirect or cross- coupling interior or internal capacitive RF signal transmission window or means or coupling 2722 located in the interior of the waveguide filter 2100 between the resonators 11 18 and 1121 ,
  • the window 2722 comprises a generally round or circular shaped region or portion or patch or pad of the conductive or metal materia! defining the central interior layer 1 150 of conductive material that is surrounded by a generally ring shaped region 2723 which is devoid of conductive material (i.e., a region of dielectric material) that isolates the window or patch of conductive materia! 2722 from the remainder of the conductive material of the central interior layer 1 150 of conductive material and is formed in the region of the central layer 1150 located between the resonators 1118 and 121 .
  • conductive material i.e., a region of dielectric material
  • the window 2722 is defined by respective generally circular shaped regions or portions or patches or pads 2722a and 2722b of the conductive materiaf on the respective exterior surf aces 1 104a and 1102b of the respective monoblocks 1101 and 1 103 that are surrounded by respective ring shaped regions 2723a and 2723b of the respective exterior surfaces 1 104a and 1 102b which are devoid of conductive materia! ⁇ i.e., respective regions of dielectric material) that isolate the respective windows or patches of conductive material 2722a and 2722b from the remainder of the layer of conductive material covering the respective exterior surfaces 1104a and 102b.
  • the respective windows 2722a and 2722b are located on the respective exterior surfaces 1104a and 1102b of the respective monoblocks 1 101 and 1 03 in the region of the respective resonators 1118 and 1 121.
  • the windows 2722a and 2722b are aligned with and connected to each other when the monobiocks 1101 and 1 103 are coupled together to define the central layer 1 150 of conductive material and the windo 2722 therein.
  • a cross-coupling or indirect capacitive RF signal transmission path c is defined and created by the interior RF signal transmission means or window 2722 located between the resonators 1116 and 1121 which allows for the transmission of a small portion of the direct RF signal being transmitted through the resonator 1116 of the monobiock 1101 directly into the resonator 1121 of the monobiock 1103,
  • the configuration, size, shape, and location of several of the elements of the waveguide filter including, but not limited to, the windows, steps, through-holes, and slits/slots of the waveguide filter may be adjusted depending upon the particular application or desired performance characteristics of the waveguide filter,

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DE112013005683.6T DE112013005683T5 (de) 2012-11-28 2013-11-26 Dielektrischer Wellenleiterfilter mit direkter Kopplung und alternativer Kreuzkopplung
KR1020157014197A KR102244162B1 (ko) 2012-11-28 2013-11-26 직접 결합 및 대안적인 상호 결합을 갖는 유전체 도파관 필터
CN201380062168.9A CN104871364B (zh) 2012-11-28 2013-11-26 具有直接耦合和交替交叉耦合的电介质波导滤波器
GB1509253.9A GB2522587B (en) 2012-11-28 2013-11-26 Dielectric waveguide filter with direct coupling and alternative cross-coupling
CA2892969A CA2892969A1 (en) 2012-11-28 2013-11-26 Dielectric waveguide filter with direct coupling and alternative cross-coupling
JP2015545172A JP2015536624A (ja) 2012-11-28 2013-11-26 直接結合および代替交差結合を伴う誘電体導波管フィルタ

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US201261730615P 2012-11-28 2012-11-28
US61/730,615 2012-11-28
US14/088,471 US9130255B2 (en) 2011-05-09 2013-11-25 Dielectric waveguide filter with direct coupling and alternative cross-coupling
US14/088,471 2013-11-25

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CN107683546B (zh) * 2015-07-01 2020-03-20 Cts公司 Rf电介质波导双工器滤波器模块
CN105356016A (zh) * 2015-11-18 2016-02-24 苏州艾福电子通讯股份有限公司 一种波导滤波器
KR20170112583A (ko) * 2016-03-31 2017-10-12 안종석 유전체 도파관 필터
KR101884984B1 (ko) * 2016-07-29 2018-08-02 쌍신전자통신주식회사 세라믹 도파관 공진기 필터
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CN106910968A (zh) * 2017-04-25 2017-06-30 四川省韬光通信有限公司 一种介质波导滤波器
KR101939056B1 (ko) * 2017-05-22 2019-01-16 안종석 유전체 도파관 필터
CN109449557B (zh) * 2018-11-01 2024-04-30 京信通信技术(广州)有限公司 介质谐振块、介质波导滤波器及其耦合结构
CN111384497A (zh) * 2018-12-29 2020-07-07 深圳市大富科技股份有限公司 一种介质滤波器及通信设备
CN111384558A (zh) * 2018-12-31 2020-07-07 深圳市大富科技股份有限公司 一种介质滤波器、制备介质滤波器的方法及通信设备
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KR102244162B1 (ko) 2021-04-26
DE112013005683T5 (de) 2015-09-10
KR20150088809A (ko) 2015-08-03
CN104871364A (zh) 2015-08-26
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JP2015536624A (ja) 2015-12-21
GB201509253D0 (en) 2015-07-15

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