KR20160013892A - Dielectric waveguide filter with direct coupling and alternative cross-coupling - Google Patents

Abstract

The dielectric waveguide filter, in one embodiment, is comprised of a plurality of monoblocks joined together in a parallel relationship. In one embodiment, the waveguide filter includes two inner mono blocks and two end mono blocks, each defining two resonators. The first and second RF signal input / output electrodes are defined on the two end mono blocks. In one embodiment, the direct RF signal transmission path comprises resonators, RF signal transmission bridges on each of the mono blocks interconnecting the resonators on each of the mono blocks, and interconnecting these resonators between adjacent resonators of the mono blocks And is partially defined by a combination of RF signal transmission windows. In one embodiment, alternate or cross-coupled RF signal transmission paths are defined by external RF signal transmission lines extending between adjacent mono blocks.

Description

[0001] DIELECTRIC WAVEGUIDE FILTER WITH DIRECT COUPLING AND ALTERNATIVE CROSS-COUPLING [0002]

Cross-references to related applications and pending applications

This application is related to U.S. Patent Application Serial No. 13 / 373,862 filed on Dec. 3, 2011 entitled " Dielectric Waveguide Filter with Direct Coupling and Alternative Cross-Coupling & Filed on May 9, 2011, entitled " Dielectric Waveguide Filter with Structure and Method for Adjusting Bandwidth ", which claims the benefit of the disclosure and filing date thereof. This patent application also claims the benefit of the disclosure and filing date of U.S. Provisional Patent Application Serial No. 61 / 830,476 (filed June 3, 2013). These patent applications are hereby expressly incorporated by reference as if fully set forth herein.

TECHNICAL FIELD OF THE INVENTION

FIELD OF THE INVENTION The present invention relates generally to dielectric waveguide filters, and more specifically to dielectric waveguide filters with direct coupling and alternative cross-coupling.

The present invention relates to a dielectric waveguide filter of the type disclosed in U.S. Patent No. 5,926,079 (Heine et al.), Wherein a plurality of resonators are longitudinally spaced along the length of the monoblock of dielectric / ceramic material, / Notch defines a plurality of RF signal bridges of dielectric material between the plurality of resonators, providing direct inductive / capacitive coupling between the plurality of resonators.

The attenuation feature of a waveguide filter of the type disclosed in U.S. Patent No. 5,926,079 (Heine et al.) Can be increased through the incorporation of zeros in the form of an additional resonator located at one or both ends of the waveguide filter. However, a disadvantage associated with the incorporation of additional resonators is that it also increases the length of the filter, which may or may not be desirable, for example, due to space constraints on the customer's motherboard, for some applications.

The attenuation feature of the filter may also be applied to each metallization pattern that is defined on the top surface of the monoblock filter and extends between selected ones of the resonator through holes to provide for example the disclosed direct and cross- By both the direct and cross-coupling of the resonator as disclosed in U. S. Patent No. 7,714, 680 (Vangala et al.), Which discloses a monoblock filter having both quadrupole cross-coupling and induced indirect coupling of the partially created resonator Can be increased.

U.S. Patent No. 5,926,079 (Heine et al.), Which includes only slots and does not include a top surface metallization pattern, is disclosed in U.S. Patent No. 7,714,680 (Vangala et al.) And of the type consisting of a top surface metallization pattern, Lt; RTI ID = 0.0 > a < / RTI >

The present invention therefore relates to a dielectric waveguide filter having both direct and alternative or alternating cross-coupled resonators that allow an increase in the attenuation characteristics of the waveguide filter without increasing the length of the waveguide filter.

The present invention relates to an RF signal transmission system comprising a pair of end blocks each defining an RF signal transmission input / output transmission electrode and at least one pair of resonators, at least one inner RF signal located between the pair of end blocks and defining at least one pair of resonators A transmission block, at least one RF signal transmission bridge interconnected with the pair of resonators and defined between each of the end blocks and the inner block between the pair of resonators, Wherein the combination of the RF signal input / output electrodes, the plurality of resonators, the RF signal transmission bridge, and the RF signal transmission window together comprise a plurality of inner RF signal transmission windows for transmission of RF signals through the waveguide filter The present invention relates to a waveguide filter that defines a direct path.

In an embodiment, the end block and the inner block include separate blocks of dielectric material joined together in a side-by-side relationship.

In one embodiment, the outer surface of the end block and the inner block is covered with a layer of conductive material, and the plurality of inner RF signal transmission windows are formed in the regions of the outer surface of the inner block and the end block without conductive material .

In one embodiment, the plurality of inner RF signal transmission windows are located and defined between the end block and the inner block.

In one embodiment, an external RF signal transmission line extends between the end blocks and the inner blocks of the pair to provide a cross-coupled RF signal transmission path between the inner blocks and the pair of end blocks.

In one embodiment, each of the end block and the inner block defines at least one slit in a co-linear relationship with the RF signal transmission bridge.

In one embodiment, the plurality of RF signal transmission windows are positioned between the end block and the inner block in alternating and staggering relationship, and the RF signal is transmitted through the waveguide filter in a serpentine pattern. do.

The invention also relates to a block of dielectric material defining a plurality of resonators arranged in parallel relationship along at least first and second orthogonal axes, first and second RF signal input / output electrodes , A first direct RF signal path transmission path between the first RF signal input / output electrode and a second RF signal input / output electrode, wherein the first direct RF signal transmission path extends in the direction of the first and second axes And a second RF signal input / output electrode between the first RF signal input / output electrode and the second RF signal input / output electrode and extending in the direction of the second axis, wherein the first and second RF signal input / To a dielectric waveguide filter.

In one embodiment, the block of dielectric material defines a plurality of inner RF signal transmission windows defining at least a portion of the direct RF signal transmission path.

In one embodiment, the plurality of inner RF signal transmission windows are alternately arranged on opposite sides of the longitudinal axis of the waveguide filter to define a first meander-shaped first direct RF signal transmission path.

In one embodiment, the outer transmission line and the block of dielectric material define the first indirect RF signal transmission path.

In one embodiment, the blocks of dielectric material are comprised of a plurality of discrete blocks of dielectric material joined together in a parallel relationship, wherein the first and second orthogonal axes comprise an x-axis and a y-axis.

The present invention further relates to a block of first, second, third and fourth dielectric materials defining a plurality of first, second, third and fourth resonators, Second, third, and fourth dielectric materials to transmit RF signals from blocks of the first dielectric material to blocks of the fourth dielectric material, Second, and third direct coupled RF signal transmission windows defined within the block of the first and third dielectric materials, and indirectly coupled between the block of the first dielectric material and the block of the fourth dielectric material. A first and a second dielectric material block extending between a block of said first dielectric material and a block of said second dielectric material and a block of said third dielectric material and a block of said fourth dielectric material to provide cross- For a dielectric waveguide filter comprising a second outer transmission line The.

In one embodiment, the blocks of the first and fourth dielectric materials define RF signal input / output electrodes, respectively, and the RF signal transmission windows are formed from blocks of the first dielectric material to blocks of the fourth dielectric material In a manner to transmit the RF signal in a meandering pattern.

In one embodiment, each of the RF signal input / output electrodes is defined by a through hole extending through each of the blocks of the first and fourth dielectric materials, and the dielectric waveguide filter comprises: Second, third and fourth resonators arranged in a common-linear relationship with respect to each other and with respect to one another in a longitudinal axis and separating the respective first, second, third and fourth pluralities of resonators, Second, third and fourth slots in the block of material.

Other advantages and features of the present invention will become more readily apparent from the following detailed description of the embodiments of the invention, the accompanying drawings, and the appended claims.

These and other features of the present invention may best be understood by the following description of the accompanying drawings, in which:
1 is a perspective view of a dielectric waveguide filter according to the present invention;
Figure 2 is a partial phantom perspective view of the dielectric waveguide filter shown in Figure 1;
FIG. 3 is a partially illusory development perspective view of the dielectric waveguide filter shown in FIGS. 1 and 2; FIG.
4 is a perspective view of another embodiment of a dielectric waveguide filter according to the present invention;
5 is a partially-illusive perspective view of the dielectric waveguide filter shown in FIG. 4;
FIG. 6 is a partially illusory development perspective view of the dielectric waveguide filter shown in FIGS. 4 and 5; FIG.
Figure 7 is a side elevational view of one of the end blocks of the dielectric waveguide filter shown in Figures 4 and 5; And
FIG. 8 is a graph illustrating the performance / frequency response of the ceramic dielectric waveguide filter shown in FIGS. 1 through 7. FIG.

Figures 1, 2 and 3 illustrate one embodiment of a RF signal waveguide filter 100 in accordance with the present invention, which, in the embodiment shown, comprises a direct RF signal couple Ring or transmission characteristics and features and alternating 8-pole or resonator filters with both cross-coupled / indirect RF signal coupling and transmission characteristics and features.

The waveguide filter 100 comprises four separate substantially parallelepiped-shaped monoblocks or blocks 101, 103, 105, and 107, which are coupled and secured together in a parallel relationship in the embodiment of Figures 1, ).

Each of the monoblocks or blocks 101,103, 105, and 107 is comprised of a suitable dielectric material, e.g., ceramic; Define a longitudinal axis L ₁ (Figure 1); Horizontally outer lateral surfaces 102 of opposite spaced apart lengths extending longitudinally in the same direction as the longitudinal axis L ₁ ; Extend longitudinally in the same direction as the longitudinal axis L ₁ and more specifically on opposite sides of the longitudinal axis L ₁ , spaced apart from the axis and facing each other in a parallel relationship to the axis, Longitudinal side lateral vertical surfaces 106; And opposing spaced transverse side vertical extensional end surfaces 110 extending in a direction generally perpendicular to the longitudinal axis L ₁ and intersecting the axes.

In the illustrated embodiment, the entire monoblocks have the same width and height; The two end mono blocks 101 and 107 are equal in length to the length of the two inner or middle mono blocks 103 and 105 of the same length.

The monoblocks 101,103 and 105 and 107 extend longitudinally along the length and longitudinal axis L ₁ of each monoblock 101,103,105 and 107 and are spaced apart, Are separated from each other by vertical slits or slots 124 (monoblocks 101 and 107) and horizontal slits or slots 126 (monoblocks 103 and 105) (Also referred to as cavity or cell or resonator) 114 and 116; (118 and 120); (121 and 122); And 123 and 125, respectively. The RF signal transmission bridge 128 (on the monoblocks 101 and 107) and the RF signal transmission bridge 130 (on the monoblocks 105 and 107) interconnect each resonator as discussed in more detail below, do.

Each of the slots 124 is cut through one of the longitudinally outer vertical surfaces 106 of each monoblock 101 and 107 and through both the upper and lower horizontal outer surfaces 102. Each of the slots 124 extends in a perpendicular relationship to and intersects the longitudinally outboard surface 106 and the longitudinal axis L ₁ and is spaced a short distance apart from the opposing longitudinally- In the body of each of the monoblocks 101 and 107 in FIG.

Each of the slots 130 is cut through one of the longitudinally outer vertical surfaces 106 of each mono block 103 and 105 and both the upper and lower horizontal outer surfaces 102. Each of the slots 130 extends in a perpendicular relationship to and intersects the longitudinally outboard surface 106 and longitudinal axis L ₁ at a short point spaced from the opposing longitudinally- Is terminated or terminated in the body of each monoblock 103 and 105.

Each of the slots 124 and 126 is common-straight with the respective RF signal transmission bridges 128 and 130 in the monoblocks 101 and 107 and 103 and 105, respectively. Each of the RF signal bridges 128 and 130 interconnects a pair of resonators on each of the respective mono blocks and connects between the upper and lower horizontal surfaces 102 of each of the mono blocks 101,103, And a bridge or island of dielectric material extending in a horizontal direction between the end of each of the slots 124 and 126 and the respective vertical outer surface 106 of the dielectric material. In the illustrated embodiment, each of the slots 124 and 126 and each RF signal bridge 128 and 130 is connected to the longitudinal axis L ₁ of each mono block 101, 103, 105 and 107, Perpendicular orientation and on opposite sides of the axis.

Specifically, the RF signal transmission bridge 128 on the monoblock 101 bridges and interconnects the dielectric material of the resonator 114 to the dielectric material of the resonator 116; The RF signal transmission bridge 130 on the monoblock 103 bridges and interconnects the dielectric material of the resonator 118 to the dielectric material of the resonator 120; The RF signal transmission bridge 130 on the monoblock 105 bridges and interconnects the dielectric material of the resonator 121 to the dielectric material of the resonator 122; The RF signal transmission bridge 128 on the monoblock 107 bridges and interconnects the dielectric material of the resonator 123 to the dielectric material of the resonator 125.

In the illustrated embodiment, the slot 126 and each common-line RF signal bridge 130 are positioned substantially centrally on each mono block 103 and 105, and each of the slots 124 and 126 The length is somewhat greater than about half the width of each monoblock 101, 103, 105 and 107 so that the width of each of the common-line RF signal transmission bridges 128 and 130 is greater than the width of the monoblocks 101, 103, 105 and 107, respectively.

Depending on the application and intended performance characteristics, the width, length and height of the slots 124 and 126 may be varied, for example, to vary the width of each RF signal bridge 128 and 130.

The monoblocks 101 and 107 are each connected in a direction perpendicular to its longitudinal axis L ₁ and in common therewith through the body of each monoblock 101 and 107, And adjacent to the transverse vertical end surface 110 of each of the mono blocks 101 and 107 and through the body of each of the end resonators 114 and 123 defined in blocks 101 and 107, And an electrical RF signal input / output electrode in the form of a respective through hole 146 extending in parallel relation thereto. In the illustrated embodiment, each of monoblocks 101 and 107 includes only one through hole 146 and defines at least one RF signal input / output electrode within each of monoblocks 101 and 107 . More specifically, each RF signal input / output through hole 146 is formed in a relationship and direction substantially perpendicular to the horizontal outer surface 102 and the longitudinal axis L ₂ in the upper and lower longitudinal directions, more specifically, Blocks 101 and 107 in relation to defining respective generally circular openings positioned and terminated in the upper and lower longitudinal outer surfaces 102 of the monoblocks 101 and 107 of the monoblocks 101 and 107, do.

The entire outer surfaces 102, 106 and 110 of the monoblocks 101, 103, 105 and 107, the inner surfaces of the respective slots 124 and 126 and the inner surfaces of the input / output through holes 146 are suitable Is coated with a conductive material, for example, silver.

Although not shown in any of the figures, it can be seen that an SMA RF signal input / output coaxial connector can be coupled to and extended through each of the through holes 146 in the monoblocks 101 and 107.

As shown in Figures 1 and 2, the individual monoblocks 101, 103, 105, and 107 are coupled together in adjacent parallel relationship as described in more detail below to define and form the waveguide filter 100 .

Monoblocks 101 and 103 define an outer RF signal input / output transmission block spaced apart opposite the waveguide filter 100, while monoblocks 105 and 107 define two RF signal input / 0.0 > 101 < / RTI > and 103 to define two inner RF signal transmission blocks of the waveguide filter 100. [

Specifically, and as shown in Figures 1 and 2, monoblocks 101,103, 105 and 107 are joined together and secured together in an adjacent, parallel relationship, wherein each monoblock 101,103, 105, 107 are adjacent to one another; The slots 126 of the two inner monoblocks 103 and 105 are generally perpendicular to the longitudinal axis L ₁ of the monoblocks 103 and 105 and common to the longitudinal axis L ₂ of the waveguide filter 100. [ Linearly aligned with each other to define and form an inner or inner elongated slot 135 defined and positioned at the center of the waveguide filter 100 in a linear relationship; The slots 124 in each of the monoblocks 101 and 107 are arranged in a common-linear relationship with the longitudinal axis L ₂ of the waveguide filter 100 and with the slots 126 and 135.

1 and 2, the resonators 114, 118, 121 and 123 on the respective monoblocks 101, 103, 105 and 107 are connected to the longitudinal axis of the waveguide filter 100 (L ₂₎ extending along the axis on one and the same direction as the art one of x- and defining the cavity of the first row is arranged in parallel relationship; The resonators 116, 120, 122 and 125 on the respective monoblocks 101, 103, 105 and 107 are arranged on the opposite side of the longitudinal axis L ₂ of the waveguide filter 100 and in the same direction as the opposite side, - define a second row of resonators extending along the axis and arranged in parallel relation; And each pair of resonators 114 and 116, 118 and 120, 121 and 122, and 123 and 128 extend transversely about the longitudinal axis L ₂ and along the Y-axis The resonators of each column arranged in parallel relation are defined. Thus, in the illustrated embodiment, the blocks 101, 103, 105 and 107, and their respective resonators are arranged and extended along and in the orthogonal XY-axis and direction.

The waveguide filter 100 is formed from one of the respective RF signal input / output through holes 146 defining the RF signal input; Through each of the resonators 114, 116, 120, 118, 121, 122, 125 and 123 on the respective monoblocks 101, 103, 105 and 107; And then directly direct RF signals through the other of the RF signal input / output through holes 146. In this case,

In the embodiment of Figures 1 and 2, the direct-coupled RF signal transmission means is characterized in that the monoblocks 101, 103, 105 and 107 define a direct coupled RF signal transmission means and the resonator in the monoblock 101 116 into the resonator 120 in the monoblock 103; From the resonator 118 in the monoblock 103 to the resonator 121 in the monoblock 105; And are coupled together to induce a path for transmission of an RF signal from the resonator 122 in the monoblock 105 into the resonator 125 in the monoblock 107, Each of the inner or inner RF signal transmission windows or areas or openings 622 (FIGS. 2 and 3) defined on each of the longitudinally-outer vertical surfaces 106 of the first, second, third,

According to an embodiment of the invention as shown in Figures 1 and 2, an inner or inner RF signal transmission window 622 has a length of each of the monoblocks 101, 103, 105 and 107 without conductive material Directional vertical outer surface 106, that is, a region of dielectric ceramic material.

As such and in light of the above description, blocks 101, 103, 105, and 107 each include and include slots, RF signal transmission bridges, and RF signal transmission windows, each of which is described in more detail below. .

That is, each of the end RF signal input / output transmission blocks 101 and 103 includes one slot 124 extending from one of its longitudinally vertical outer surfaces 106 into its body; One RF signal transmission bridge 128 that is common-linear with one slot 124; And one RF signal transmission window (622) delimited and positioned within a slot (124) defined on the other side of the lengthwise vertical outer surface (106) opposite the defined vertical longitudinal outer surface (106); At this time, the RF signal transmission window 622 and the RF signal input / output through hole 146 are located at opposite ends of the respective blocks 101 and 103 and on the opposite side of the RF signal transmission bridge 128 and the slot 124 .

Each of the inner RF signal transmission blocks 103 and 105 includes a slot 126 extending from one of its longitudinally vertical outer surfaces 106 into its body; One RF signal transmission bridge 130 which is common-linear with one slot 126; And opposite longitudinal longitudinal outer surfaces 106 and is located on opposite ends of each block 103 and 105 and on the opposite side thereof and includes a slot 126 and an RF signal transmission bridge 130, And an RF signal transmission window 622 spaced from the RF signal transmission window 622.

In the embodiment of Figures 1, 2 and 3, each of the end blocks 101 and 107 and each of the inner blocks 103 and 105 have the same structure, and more specifically, Figures 1, It will also be appreciated that in the embodiment of FIG. 3, block 107 is a block 101 rotated 180 degrees in parallel and block 105 is also a block 103 rotated 180 degrees in parallel.

Further, in the embodiment of the waveguide filter 100 shown in the figures, an inner or inner RF signal transmission window 622 defines a direct coupled RF signal transmission path in the form of a substantially meandering or sinusoidal wave through the waveguide filter 100 (L ₂ ) axis of the waveguide filter 100 and spaced and alternating or staggered relative to its opposite sides on the longitudinal axis L ₂ of the waveguide filter 100 Lt; / RTI >

The waveguide filter 100 includes a plurality of resonators 114 and 118 in each of the mono blocks 101 and 103 and a plurality of resonators 121 and 123 in the respective mono blocks 105 and 107, Cross-coupled / indirectly coupled, bypassed or alternating RF signal transmission electrodes or bridge members or transmission lines 500 and 501 having a particular impedance and phase that extend between and electrically interconnect and interconnect Alternative, or cross-coupled RF signal transmission means in the form of a second, indirect, alternative, or cross-coupled RF signal.

In the illustrated embodiment, each of the outer cross-coupled transmission lines 500 and 501 includes an upper longitudinal horizontal outer surface 102 of each monoblock 101 and 103, 107 and a substantially rectangular substrate or printed circuit board that is seated and bridged on the upper longitudinally horizontally outer surface 102 of each of the substrates 102, 107, and is defined by the substrate. Each of the outer cross-coupled transfer electrodes 500 and 501 is disposed on each of the resonators 114 and 118 on each of the mono blocks 101 and 103 and on each of the resonators 121 and 127 on the respective mono blocks 105 and 107, And 123 formed on and in the interior of the printed circuit board adapted for electrical connection to the outer layer of conductive material on the outer surface 102 of each monoblock 101, 103, 105, and 107, And further comprises elongate strips or lines 504 (FIG. 2) of conductive material.

Thus, the assembled or completed waveguide filter 100 as shown in the embodiments of FIGS. 1 and ₂ comprises a block of dielectric material defining a central longitudinal axis L ₂ ; Each mono-block (101, 103, 105 and 107) defined by a horizontal outer surface 102 of the upper and lower longitudinal direction and a longitudinal axis (L ₂₎ and spaced oppositely of the pair extending in the same longitudinal direction of the A horizontal outer surface 102 in the upper and lower longitudinal direction; Is defined by the transverse vertical outer surface 110 of each monoblock 101, 103, 105 and 107 and extends in the same direction as the longitudinal axis L ₂ from this axis and on opposite sides of the axis A spaced apart pair of spaced apart longitudinally extending vertical outer surfaces 110; Is defined by each of the longitudinal outer end surface 106 of the monoblock 101 and the vertical outer end surface 106 of the monoblock 107 and extends transversely with respect to the longitudinal axis L ₂ And a pair of opposed, spaced apart transverse vertical outer end surfaces 106 that intersect the axis.

The finished waveguide filter 100 extends through the body and dielectric material of the block terminating in a generally perpendicular relationship and direction to the longitudinal axis L ₂ and at respective openings within each of the upper and lower outer block surfaces 102 And a pair of RF signal input / output or electrodes partially defined by a pair of RF signal input / output through holes.

In the embodiment of Figures 1 and 2, the first of the pairs of through holes 146 is located and defined at the lower corner of the block of dielectric material located below and spaced from the longitudinal axis L ₂ , The second of the pair of through holes 146 is spaced from the axis below the longitudinal axis L ₂ and the opposite of the bottom of the block of dielectric material that is common to the first pair of through holes 146, As shown in Fig.

The waveguide filter 100 is defined by a slot 124 formed in each monoblock 101 and 107 and extends from each of the opposing outer transverse vertical surfaces 106 to the longitudinal axis of the waveguide filter 100 L ₂ ) and a pair of elongated slots 124 extending into the body of the dielectric material of the block of dielectric material that intersects the axis in general. The slot 124 extends between and through the horizontal outer surface 102 of the upper and lower longitudinal direction and the respective transverse end surface 106 of the waveguide filter 100.

Waveguide filter 100 is monobloc being defined by a slot 126 in the 103 and 105 longitudinal axis (L ₂₎ and a generally common - the inner slot extending through the dielectric material and the body of the linear relationship block 135 .

All of the slots 124 and 135 defined in the block of the waveguide filter 100 are positioned in a common-line and are spaced apart from one another and are in a common-linear relation to the longitudinal axis L ₂ .

In the embodiment of Figures 1 and 2, the cross-coupled RF signal transmission lines 500 and 501 are both located below the slots 124 and 135 and the longitudinal axis L ₂ and spaced from and parallel thereto Do.

In the embodiment of Figures 1 and 2, the entire outer surface 102, 106 and 110; An inner surface of each of the slots 124 and 135; And the inner surface of each of the RF signal input / output through holes 146 are covered with a layer of a conductive material.

1 and 2, the plurality of inner layers or walls 700 of conductive material are spaced apart and in a parallel relationship relative to each other and in a relationship that substantially transverses and intersects the longitudinal axis L ₂ Through the entire width and height of the body of the block of the waveguide filter 100. As shown in Fig. Specifically, a layer or wall 700 of conductive material is disposed between monoblocks 101 and 103, between monoblocks 103 and 105, and between monoblocks 105 and 107. In the illustrated embodiment, a layer of conductive material on each longitudinally outer vertical surface 106 of each of the monoblocks 101,103, 105, and 107 is formed of monoblocks 101,103, Each of the inner layers 700 of the conductive material in the waveguide filter 100 is defined.

According to the present invention, the waveguide filter 100 includes an RF signal transmission input through hole 146; Through the resonator 114, more specifically, the resonator 114 in the monoblock 101; And the RF signal bridge 128 interconnecting the resonators 114 and 116 and extending in a generally common-linear relationship with the longitudinal axis L ₂ , A first magnetic or inductive, substantially sinusoidal or sinusoidal, directly coupled RF signal for the RF signal, generally indicated by arrow d in Figure 2, into the resonator 116 in the monoblock 101, and more specifically, Defines the transmission path.

The RF signal is then passed from the resonator 116 into the resonator 120 of the waveguide filter 100 and more particularly to the inner side of the waveguide filter 100 interconnecting them between the resonators 116 and 120 Into the resonator 120 of the mono block 103 via the direct coupled RF signal transmission means defined by the inner RF signal transmission window 622; Which in turn interconnects the resonators 120 and 118 in the waveguide filter 100 and more particularly through the resonator 118 in the waveguide filter 100 and extends in a generally linear relationship with the longitudinal axis L ₂ . Signal bridge 130 and through it through the resonator 118 in the monoblock 103. [

The RF signal is then passed from the resonator 118 to the direct coupling RF signal transmission means defined by the inner RF signal transmission window 622 defined inside the waveguide filter 100 between the resonators 118 and 121 Into the resonator 121 of the waveguide filter 100 and then to the resonator 122 of the waveguide filter 100 and more particularly to the resonators 121 and 122 and to the longitudinal axes L ₂ ) Via the RF signal bridge 130, which extends in a generally common-linear relationship, and into the resonator 122 in the monoblock 103.

The RF signal is then passed from the resonator 122 into the resonator 125 of the waveguide filter 100 and more specifically to the direct RF signal transmission window 622 defined by the inner RF signal transmission window 622 between the resonators 122 and 125 into the cavity 125 of the monoblock 107. the combination RF signal transmitting means, then into the cavity 123 of the waveguide filter 100, and, more specifically, substantially in common with the longitudinal axis (L ₂₎ - linear And is transmitted to the resonator 123 of the monoblock 107 through the RF signal bridge 128 and between the resonators 125 and 123 and interconnecting them.

The RF signal is then passed through the RF signal transmission output through hole 146 defined in the waveguide filter 100 and more specifically defined in the resonator 123 of the mono block 107.

According to this embodiment of the present invention, the waveguide filter 100 also defines and provides alternate or indirect- or cross-coupled RF signal transmission paths for RF signals substantially represented by arrow c in Fig.

One of the cross-coupled or indirect full-wave / capacitive RF signal transmission path (c) includes a resonator of each resonator 114 and 118 of the waveguide filter 100, more specifically a resonator of each of the mono blocks 101 and 103 The resonator 118 of the waveguide filter 100 and more particularly the resonator 118 of the monoblock 103 through the inner or inner strip 504 of conductive material bridging and electrically interconnecting the conductors 114 and 118, An external RF signal transmission line 500 that allows transmission of a small portion of the direct RF signal being transmitted through the resonator 114 of the waveguide filter 100, more specifically, the resonator 114 of the monoblock 101, ). ≪ / RTI >

The other cross-coupled or indirect magnetic / inductive RF signal transmission path c is connected to the resonator 123 of the waveguide filter 100 and, more specifically, to the resonator 123 of the monoblock 107, Is defined by the other external RF signal transmission line 501 that allows transmission of a small portion of the direct RF signal being transmitted through the resonator 121 of the antenna 100, and more specifically, the resonator 121 of the monoblock 105 Respectively.

In accordance with the present invention, the cross-coupling of the RF signals as described above advantageously makes the transmission zeros of each of the first and second pairs, the first pair of which, as shown in Fig. 8 The second pair will be placed above the passband of the waveguide filter 100 and the corresponding pair will be placed over the passband of the waveguide filter 100, A graph of performance / frequency response, in which the attenuation (measured in dB) is plotted along the vertical or Y axis, and the frequency (measured in MHz) is plotted along the horizontal or X axis.

4, 5, 6, and 7 illustrate that the two end mono blocks 101 and 107 of the waveguide filter 100 are replaced with the two end mono blocks 101a and 107a in the waveguide filter 200 And another embodiment of a waveguide filter 200 according to the present invention having the same structure and function as the waveguide filter 100, in which the two end mono blocks 101a and 107a are formed as described in more detail below Are similar in structure and function to the two end mono blocks 101 and 107 except that they further include respective notches or stepped portions 236 and 238. In view of the above description, the description of the structure and function of each monoblock 101, 103, 105, and 107 and the waveguide filter 100 that define the same will be otherwise the same as described above except as otherwise discussed below. Is incorporated herein by reference for each of the monoblocks 101a, 103, 105, and 107a and the waveguide filter 200,

 More specifically, the monoblocks 101a and 107a each further include and define end step or notches 236 and 238, each of which, in the illustrated embodiment, has a dielectric ceramic material removed or absent And more specifically the lower longitudinally horizontal outer surface 102, the opposing longitudinally longitudinally outer surfaces 106 of the respective end resonators 114 and 123 of the respective monoblocks 101a and 107a, Includes generally L-shaped indentations or grooves or shouldered or notch areas or sections of the transverse surface 110.

Described in an alternative manner, each step 236 and 238 includes a respective monoblock 101a and 107a having a height less than the height of the rest of each monoblock 101a and 107a, and more specifically, , Within each end section or region of each of the end resonators 114 and 123, and by them.

Referring now to Figures 4, 5, 6 and 7, each of the stepped portions 236 and 238 includes a lower horizontal outer surface < RTI ID = 0.0 > A first substantially horizontal outer surface 240 that is disposed or oriented within and spaced apart from and parallel to the inner surface 102 of the respective monoblock 101a and 107a, Each of the end resonators 114 and 123, which are disposed on or oriented on each monoblock 101a and 107a that are spaced apart therefrom and are parallel to and parallel to the second generally vertical surface or wall 242, Quot;) < / RTI > includes an L-shaped concave or notch portion.

Monoblock (101a and 107a), respectively, through the body of each of the mono-block (101a and 107a) in perpendicular relationship with respect to its longitudinal axis (L _1), more specifically, its respective step portions (236 and 238 and more specifically between the surface 240 of each of the stepped sections 236 and 238 and the surface 104 of each of the mono blocks 101a and 103a and in a generally perpendicular relationship therewith Further includes an electrical RF signal input / output electrode in the form of a respective through hole 146 through the body of each end resonator 114 and 123 defined in the monoblocks 101a and 103a.

More specifically, each RF signal input / output through hole 146 is spaced from and generally parallel to a respective transverse side end surface 110 of each mono block 101a and 103a, Defines a respective generally circular opening that terminates in a top monoblock surface 102 and a stepped surface 240 of each of the top surfaces 101a and 107a.

The RF signal input / output through holes 146 are spaced apart from the side end surface 110 and the stepped wall or surface 242 such that each step portion 236 and 238 between these surfaces in a substantially parallel, Are positioned and positioned inside the monoblocks 101a and 107a and extend through the inside thereof.

In the illustrated embodiment, the slots 124 in each of the monoblocks 101a and 107a are spaced apart and opposed to and generally parallel to the transverse normal outer end surface 110 of each of the monoblocks 101a and 107a Are located in relation; Each through hole 146 in each of the monoblocks 101a and 107a is defined by a transverse vertical outer end surface 110 of each monoblock 101a and 107a and a slot in each of the monoblocks 101a and 107a 124, respectively, of monoblocks 101a and 107a; And each of its stepped ends 236 and 238, and more specifically, each of its vertical end surfaces 242, terminate at a short point or location in each slot 124, 238 do not extend into each slot 124 but are spaced from the slot in question.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, those skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention. The described embodiments are to be considered in all respects only as illustrative and not restrictive.

For example, waveguide filters 100 and 200 may have RF signal input / output terminals and may include additional intermediate resonators / mono blocks along the x-axis between the end resonators / Or less than eight poles or more than eight poles.

For another example, the waveguide filters 100 and 200 may be implemented as waveguide filters, such as, for example, embodiments in which each monoblock defines three resonators separated by two slots and two RF signal transmission bridges, It can be seen that each of the mono blocks comprising the resonator 100 could be modified to include and define additional resonators along the y-axis.

For another example, waveguide filters 100 and 200 may comprise a plurality of monoblocks with resonators stacked together along this axis in xz orthogonal axes adjacent and in parallel relationship rather than xy orthogonal axis adjacencies and parallel relationships of the embodiments of the figures As will be understood by those skilled in the art.

For additional examples, and as described in co-pending U.S. Patent Application Serial No. 13 / 373,862, incorporated herein by reference, steps 236 and 238 may be implemented using a "step-down" down "or" step in "or" step-up "or" step-out "as described in co-pending U.S. Patent Application Serial No. 13 / 373,862, And the external bandwidth of the waveguide filter can be adjusted by increasing or decreasing the size (i.e., depth or thickness) of the "step-down" or "step-in" It can be controlled by increasing or decreasing the temperature.

Claims (15)

As a waveguide filter,
A pair of end blocks each defining an RF signal transmission input / output transmission electrode and at least one pair of resonators;
One or more inner RF signal transmission blocks each located between the pair of end blocks to define at least one pair of resonators;
At least one RF signal transmission bridge interconnecting the pair of resonators and defined between the pair of resonators on each of the end block and the inner block; And
And a plurality of inner RF signal transmission windows defined between the end block and the inner block, wherein a combination of the RF signal input / output electrodes, the plurality of resonators, the RF signal transmission bridge, and the RF signal transmission window And defines a direct path for transmission of the RF signal through the waveguide filter. The waveguide filter of claim 1, wherein the end block and the inner block comprise separate blocks of dielectric material joined together in a side-by-side relationship. 3. The method of claim 2, wherein the outer surface of the end block and the inner block is covered with a layer of conductive material, and the plurality of inner RF signal transmission windows comprise areas of the outer surface of the inner block, / RTI > The waveguide filter according to claim 3, wherein the plurality of inner RF signal transmission windows are positioned and defined between the end block and the inner block. 5. The apparatus of claim 4, further comprising an external RF signal transmission line extending between the end blocks of the pair and the inner blocks to provide a cross-coupled RF signal transmission path between the inner blocks and the pair of end blocks , The waveguide filter. 6. The waveguide filter of claim 5, wherein each of the end block and the inner block defines at least one slit in a co-linear relationship with the RF signal transmission bridge. 7. The apparatus of claim 6, wherein the plurality of RF signal transmission windows are positioned between the end block and the inner block in alternating and staggered relation, and the RF signal is transmitted through the waveguide filter in a serpentine pattern Being a waveguide filter. As a dielectric waveguide filter,
A block of dielectric material defining a plurality of resonators arranged in parallel relationship along at least first and second orthogonal axes;
First and second RF signal input / output electrodes defined on the block of dielectric material;
A first direct RF signal path transmission path between the first RF signal input / output electrode and a second RF signal input / output electrode, the first direct RF signal transmission path extending in the direction of the first and second axes The first and second RF signal input / output electrodes; And
And a first indirect RF signal transmission path between the first RF signal input / output electrode and the second RF signal input / output electrode and extending in the direction of the second axis. 9. The dielectric waveguide filter of claim 8, wherein the block of dielectric material defines a plurality of inner RF signal transmission windows defining at least a portion of the direct RF signal transmission path. 10. The method of claim 9, wherein the plurality of inner RF signal transmission windows are alternately arranged on opposite sides of the longitudinal axis of the waveguide filter to define a first meander- Waveguide filter. 11. The dielectric waveguide filter of claim 10, further comprising an outer transmission line and a block of dielectric material defining the first indirect RF signal transmission path. 12. The dielectric waveguide filter of claim 11, wherein the blocks of dielectric material are comprised of a plurality of discrete blocks of dielectric material joined together in a parallel relationship, the first and second orthogonal axes comprising an x-axis and a y-axis. As a dielectric waveguide filter,
A first, a second, a third and a fourth dielectric material block defining a first, a second, a third and a fourth plurality of resonators, 2, blocks of third and fourth dielectric materials;
Second, third and fourth dielectric material blocks for transmitting an RF signal from a block of said first dielectric material to a block of said fourth dielectric material; 2 and a third direct coupled RF signal transmission window; And
A block of said first dielectric material and a block of said second dielectric material and a third dielectric layer of said third dielectric material to provide an indirect crossover between said block of said first dielectric material and said block of said fourth dielectric material. And first and second external transmission lines each extending between a block of material and a block of said fourth dielectric material. 14. The method of claim 13, wherein the blocks of the first and fourth dielectric materials define RF signal input / output electrodes, respectively, and the RF signal transmission windows form blocks of a fourth dielectric material from a block of the first dielectric material, Wherein the dielectric waveguide filter is arranged in a manner to transmit the RF signal in a generally meandering pattern. 15. The method of claim 14, wherein each of the RF signal input / output electrodes is defined by a through hole extending through each of the blocks of the first and fourth dielectric materials, and wherein the dielectric waveguide filter comprises: Second, third and fourth resonators arranged in a common-linear relationship with respect to each other and with respect to one another in a longitudinal axis and separating the respective first, second, third and fourth pluralities of resonators, Further comprising first, second, third and fourth slots in a block of material.

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