WO2018139321A1 - Dielectric waveguide filter, high-frequency front-end circuit, and communication device - Google Patents

Abstract

A dielectric waveguide filter (1J) is provided with: a first resonator group (10) including a plurality of first resonators (11, 13) disposed along a predetermined plane (principal surface (70a) of a mounting substrate (70)); and a second resonator group (20) including a second resonator (21) disposed above the first resonator group (10) in the vertical direction which is perpendicular to the predetermined plane. The first resonators (11, 13) and the second resonator (21) are each formed of a dielectric block. In at least two combinations from among combinations of at least one first resonator from the plurality of first resonators and at least one second resonator from one or more second resonators, such first and second resonators lying atop one another in the vertical direction, the resonators are coupled to one another by electromagnetic field coupling. In a combination that has, as one set, at least two first resonators, from the plurality of first resonators, that are adjacent to one another along the predetermined plane, the resonators are coupled to one another by electromagnetic field coupling.

Description

Dielectric waveguide filter, high-frequency front-end circuit, and communication device

The present invention relates to a dielectric waveguide filter including a plurality of resonators, a high-frequency front-end circuit, and a communication device.

Conventionally, a waveguide filter including a plurality of resonators is known as a band pass filter.

As an example of this type of waveguide filter, Patent Document 1 discloses a structure in which resonators composed of dielectric blocks are arranged in a matrix. In the waveguide filter described in Patent Document 1, a plurality of resonators are arranged adjacent to each other in the horizontal direction so that the plurality of resonators are electromagnetically coupled to each other.

In addition, the waveguide filter described in Patent Document 2 includes a plurality of resonators each having a rectangular tube arranged in a horizontal row to form one set, and the above-mentioned one set of resonators are stacked in the vertical direction. Has a structure. In this waveguide filter, a high-frequency signal is input to the upper resonator, and sequentially output from the lower side through the resonator located in the side, the resonator located under the resonator, and the resonator located further down. Is done.

JP 2014-521278 A JP 2010-28381 A

However, the waveguide filter disclosed in Patent Document 1 has a structure in which a plurality of resonators are horizontally adjacent to each other. For example, when the number of resonators is increased in order to widen the passband width, There is a problem that the entire area of the body waveguide filter becomes large. Further, since the electromagnetic field coupling can be performed only in a state where the plurality of resonators are adjacent to each other in the lateral direction, the region to be electromagnetically coupled is limited to the side surface of the dielectric block. Therefore, there is a problem that the degree of freedom in selecting a signal path in the waveguide filter is lowered. In addition, in this configuration, when the signal path is bypassed on the side surface, at least two resonators must be skipped and electromagnetically coupled, and the degree of freedom in selecting the signal path in the waveguide filter is increased. There is a problem of being lowered.

The waveguide filter described in Patent Document 2 is composed of two resonators in the upper layer and two resonators in the lower layer. In this configuration, when the signal path is bypassed from top to bottom, at least two or more resonators must be skipped and electromagnetically coupled, and the degree of freedom in selecting the signal path in the waveguide filter is increased. There is a problem of being lowered.

Therefore, an object of the present invention is to improve the degree of freedom in selecting a signal path in a dielectric waveguide filter.

In order to achieve the above object, a dielectric waveguide filter according to an aspect of the present invention includes a first resonator group including a plurality of first resonators arranged along a predetermined plane, and a perpendicular to the predetermined plane. A second resonator group including one or more second resonators disposed on the first resonator group in a vertical direction, each of the first resonator and the second resonator being a dielectric block. A combination of at least one first resonator of the plurality of first resonators and at least one second resonator of the one or more second resonators, which is formed by In the combination of at least two of the plurality of first resonators that are electromagnetically coupled to each other and are adjacent to each other in a predetermined plane in at least two or more combinations, They are electromagnetically coupled to each other.

In this way, the second resonator group is arranged on the first resonator group, and the dielectric waveguide filter has a laminated structure including the first resonator group and the second resonator group, so that the patent document Compared with the case where all the resonators are arranged in the horizontal direction as in 1, the area of the entire dielectric waveguide filter can be reduced. Further, in this configuration, electromagnetic coupling can be performed both on the upper and lower surfaces and on the side surfaces, so that the degree of freedom in selecting a signal path in the dielectric waveguide filter can be increased. Furthermore, since the second resonator is arranged on the first resonator group, unlike in the case of Patent Document 2, the electromagnetic field coupling is performed only with the resonators arranged in the horizontal row and the vertical direction, the predetermined plane is set. It is possible to perform electromagnetic field coupling by skipping at least one second resonator in the direction along the direction, so that the degree of freedom of electromagnetic field coupling can be increased and the degree of freedom of selection of signal paths can be improved.

Further, the predetermined plane may be a plane on a mounting board.

According to this, the first resonator group can be arranged on a plane on the mounting substrate.

The second resonator group includes a plurality of second resonators arranged on the first resonator group, and two sets of the first resonator and the second resonator overlapping in the vertical direction are in each set. The two or more second resonators that are electromagnetically coupled to each other and have two adjacent second resonators on the first resonator group as one set may be electromagnetically coupled to each other in each combination. Good.

Thus, by having a plurality of combinations of second resonators to be electromagnetically coupled, the number of combinations to be electromagnetically coupled within the first resonator group, that is, of the first resonators arranged along a predetermined plane The number can be reduced, and the entire area of the dielectric waveguide filter can be reduced. In addition, by coupling the adjacent second resonators to each other by electromagnetic field, it is possible to increase the choices of places where electromagnetic coupling is performed by overlapping in the vertical direction. Thereby, the freedom degree of the location which electromagnetically couples can be raised and the freedom degree of selection of a signal path | route can be improved.

Also, ground electrodes are formed on the top, bottom and side surfaces of the dielectric block, and the first resonator and the second resonator overlapping in the vertical direction are respectively provided on the top surface of the first resonator and the bottom surface of the second resonator. The coupling portion including a region where the surface of the dielectric block is exposed may be provided, and the coupling portion of the first resonator and the coupling portion of the second resonator may be opposed to each other.

According to this configuration, the first resonator and the second resonator overlapping in the vertical direction can be electromagnetically coupled.

The coupling portion of the first resonator is provided along at least part of the outer periphery of the upper surface of the first resonator, and the coupling portion of the second resonator is at least part of the outer periphery of the lower surface of the second resonator. It may be provided along.

According to this configuration, the first resonator and the second resonator overlapping in the vertical direction can be magnetically coupled.

The coupling portion of the first resonator is provided at a position including the center of the upper surface of the first resonator, and the coupling portion of the second resonator is provided at a position including the center of the lower surface of the second resonator. May be.

According to this configuration, the first resonator and the second resonator overlapping in the vertical direction can be electric field coupled.

Further, the connecting portion may be polygonal, circular, frame-shaped, O-shaped, C-shaped or U-shaped.

結合 By appropriately selecting these shapes, the coupling degree of electromagnetic field coupling can be changed.

Also, an electrode pattern made of the same material as the ground electrode may be formed at the center of the upper surface or the center of the lower surface.

For example, if the exposed area of the dielectric is too large at the coupling portion, the capacitance component of the resonator is reduced, and the resonance frequency is increased more than necessary. To reduce the resonance frequency, it is necessary to enlarge the resonator. is there. On the other hand, by forming an electrode pattern at the center of the upper surface or the lower surface of the resonator having a strong electric field, a sufficient capacitance component can be added to the resonator, and an increase in the size of the resonator can be suppressed.

In addition, ground electrodes are formed on the upper surface, the lower surface, and the side surface of the dielectric block, and a coupling portion including a region where the surface of the dielectric block is exposed is provided on each of the side surfaces of the first resonator adjacent to each other along a predetermined plane. And the coupling portion of the first resonator may be opposed to each other.

According to this configuration, adjacent first resonators can be electromagnetically coupled to each other.

In addition, a ground electrode is formed on the upper surface, the lower surface, and the side surface of the dielectric block, and includes a region where the surface of the dielectric block is exposed on each side surface of the second resonator adjacent on the first resonator group. It has a coupling part and the above-mentioned coupling part of the 2nd resonator may face mutually.

According to this configuration, the adjacent second resonators can be electromagnetically coupled to each other.

Further, the coupling part may have a T-shaped electrode.

According to this configuration, the first resonators adjacent to each other or the second resonators adjacent to each other can be electric field coupled.

In addition, the coupling portion on the side surface is provided with an electrode projection that is connected to the ground electrode and projects in the vertical direction from one end of the coupling portion toward the other end. The other end of the coupling portion and the electrode projection are predetermined. You may oppose with a gap.

According to this, the first resonators adjacent to each other or the second resonators adjacent to each other can be electric field coupled.

Furthermore, the dielectric waveguide filter includes a mounting substrate, and the first resonator group includes a mounting substrate such that a surface opposite to the surface on which the second resonator is disposed faces the main surface of the mounting substrate. It may be joined to.

For example, when the waveguide filter shown in Patent Document 2 is joined to a mounting substrate and signals are input / output from the mounting substrate, wiring for inputting signals to the resonator disposed on the upper side is separately required. However, in the dielectric waveguide filter of the present invention, signals can be input and output to the first resonator group using the mounting substrate, and wiring can be simplified.

The first resonator group includes four or more first resonators arranged in a matrix along a predetermined plane, and the second resonator group is arranged in a matrix on the first resonator group. Four or more second resonators may be included.

For example, by increasing the number of resonators to four or more, or to four or more resonators, the number of combinations of electromagnetic coupling can be increased, and the passband width of the dielectric waveguide filter can be widened.

Further, in the dielectric waveguide filter, of the first resonator and the second resonator that are electromagnetically coupled to each other in the vertical direction, the first resonator is at least one located next to the first resonator. The first resonator may be electromagnetically coupled, and the second resonator may be electromagnetically coupled with at least one second resonator located next to the second resonator.

In this way, the area of the entire dielectric waveguide filter can be reduced by electromagnetically coupling the resonators that are electromagnetically coupled to each other in the vertical direction to the adjacent resonators. In addition, it is possible to increase the degree of freedom of the electromagnetic wave coupling portion in the dielectric waveguide filter and improve the degree of freedom of selection of the signal path.

Further, in the dielectric waveguide filter, two or more combinations of first resonators adjacent to each other along a predetermined plane, two sets of first and second resonators overlapping in the vertical direction, and two or more combinations of The second resonators adjacent on the first resonator group may be electromagnetically coupled to each other in each combination.

In this way, the resonators adjacent to each other along the predetermined plane, the resonators overlapping in the vertical direction, and the resonators adjacent on the first resonator group are electromagnetically coupled in each combination, so that dielectric induction is achieved. The area of the entire wave tube filter can be reduced. In addition, it is possible to increase the degree of freedom of the electromagnetic wave coupling portion in the dielectric waveguide filter and improve the degree of freedom of selection of the signal path.

Further, the electromagnetic field coupling may be magnetic field coupling.

Thus, the electromagnetic field design of the dielectric waveguide filter can be efficiently performed by using all the electromagnetic field couplings as the magnetic field couplings.

In addition, the electromagnetic coupling between the first resonators adjacent along the predetermined plane is defined as the first coupling, and the electromagnetic coupling between the first resonator and the second resonator overlapping in the vertical direction is defined as the second coupling. When the electromagnetic field coupling of the second resonators adjacent to each other on the resonator group is the third coupling, each of the first coupling and the third coupling is one of the magnetic field coupling and the electric field coupling. The second coupling may be the other of the magnetic field coupling and the electric field coupling.

Thus, the electromagnetic coupling design in the dielectric waveguide filter can be efficiently performed by setting the first coupling and the third coupling to electromagnetic coupling different from the second coupling.

Further, each of the first coupling and the third coupling may be a magnetic field coupling, and the second coupling may be an electric field coupling.

As described above, when the first coupling and the third coupling are the magnetic field coupling and the second coupling is the electric field coupling, it is possible to increase the degree of coupling.

The dielectric waveguide filter further includes a first input / output electrode provided in one of the four or more first resonators, and one first of the four or more first resonators. A second input / output electrode provided in a first resonator different from one resonator, and an input / output path for outputting a signal input to the first input / output electrode from the second input / output electrode via a plurality of electromagnetic couplings And may be provided.

Thus, by outputting the input signal via a plurality of electromagnetic couplings, the passband of the dielectric waveguide filter can be easily formed.

Furthermore, the dielectric waveguide filter includes a bypass path for bypassing a signal propagated between the first input / output electrode and the second input / output electrode through electromagnetic coupling different from the input / output path, The signal propagating through the bypass path and the signal propagating through the input / output path may have different phases in a frequency band different from the pass band of the dielectric waveguide filter.

As described above, in the dielectric waveguide filter, by changing the phase of the signal of the bypass path with respect to the input / output path, a signal having a predetermined frequency can be canceled and a plurality of attenuation poles can be formed. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

Further, the signal propagating through the bypass path and the signal propagating through the input / output path may be 180 ° out of phase in a frequency band different from the pass band of the dielectric waveguide filter.

As described above, in the dielectric waveguide filter, the amount of cancellation of the signal of the predetermined frequency is increased and the large attenuation pole is formed by changing the phase of the signal of the bypass path by 180 ° with respect to the input / output path. Can do. By forming this large attenuation pole in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

A dielectric waveguide filter according to an aspect of the present invention includes a first resonator group including a plurality of first resonators arranged along a predetermined plane, and a first resonance in a vertical direction perpendicular to the predetermined plane. A second resonator group including a plurality of second resonators disposed on the resonator group, and a third resonator group including one or more third resonators disposed on the second resonator group in the vertical direction. And two sets of the first resonator and the second resonator that are overlapped in the vertical direction are electromagnetically coupled to each other in the set, and the vertical direction Two combinations of the second resonator and the third resonator, each including the second resonator and the third resonator overlapping each other, are electromagnetically coupled to each other in each combination.

Thus, by making the dielectric waveguide filter a laminated structure including the first resonator group, the second resonator group, and the third resonator group, the area of the entire dielectric waveguide filter can be reduced. Can do. In addition, since the number of electromagnetic coupling points can be increased, the degree of freedom in selecting a signal path can be improved.

The first resonator group includes two or more first resonators disposed along a predetermined plane, and the second resonator group includes two or more second resonances disposed on the first resonator group. The total of the first resonator and the second resonator is 6 or more, and the dielectric waveguide filter has a first resonator in the input stage and a second resonator in the output stage. A main path formed by electromagnetic field coupling that connects the first resonator of the input stage and the first resonator of the output stage, and a sub path that has weaker electromagnetic field coupling than the main path, A predetermined resonator of the first resonator and the second resonator is adjacent to another resonator at least on three surfaces orthogonal to each other, and the predetermined resonator is adjacent to another resonator on three surfaces. The electromagnetic field coupling on the three surfaces may constitute a part of the main path and the sub path.

According to this configuration, it is possible to obtain a steep attenuation due to the polar characteristics without increasing the mounting area.

A high-frequency front-end circuit according to an aspect of the present invention includes a dielectric waveguide filter connected to an antenna element, a transmission amplifier circuit that amplifies a high-frequency transmission signal transmitted to the antenna element, and a high-frequency signal received by the antenna element. A reception amplifier circuit that amplifies a reception signal, a transmission amplifier circuit and a reception amplifier circuit, and a switch circuit that switches connection between the dielectric waveguide filter.

A high-frequency front-end circuit according to an aspect of the present invention includes a transmission amplifier circuit that amplifies a high-frequency transmission signal output from an RF signal processing circuit, and a reception amplifier circuit that amplifies the high-frequency reception signal and outputs the amplified signal to the RF signal processing circuit. And the dielectric waveguide filter disposed between the RF signal processing circuit and the transmission amplification circuit or between the RF signal processing circuit and the reception amplification circuit.

By configuring the high-frequency front end circuit using the dielectric waveguide filter having a small area, the high-frequency front end circuit can be reduced in size.

A communication device according to an aspect of the present invention is connected to an antenna element, the high-frequency front end circuit that is connected to the antenna element, amplifies a high-frequency signal transmitted and received by the antenna element, and the high-frequency front-end circuit, An RF signal processing circuit that performs signal processing including frequency conversion between a high-frequency signal and a baseband signal, and a baseband signal processing circuit that is connected to the RF signal processing circuit and performs signal processing on the baseband signal.

The communication apparatus can be reduced in size by configuring the communication apparatus using the downsized high-frequency front end circuit.

According to the present invention, it is possible to improve the degree of freedom in selecting a signal path in the dielectric waveguide filter while reducing the area of the entire dielectric waveguide filter. In addition, the high-frequency front-end circuit and communication device using the dielectric waveguide filter of the present invention can be reduced in size.

FIG. 1A is a perspective view of the dielectric waveguide filter according to Embodiment 1 when viewed obliquely from above. FIG. 1B is a perspective view of the dielectric waveguide filter according to Embodiment 1 when viewed obliquely from below. 1C is an exploded perspective view of the dielectric waveguide filter according to Embodiment 1. FIG. 2A is a diagram illustrating a coupling portion of the dielectric waveguide filter according to Embodiment 1. FIG. FIG. 2B is a diagram illustrating an example of the coupling unit illustrated in FIG. 2A. FIG. 2C is a diagram illustrating another example of the coupling unit illustrated in FIG. 2A. FIG. 3 is a schematic diagram showing an electromagnetic field generated in a part of the dielectric waveguide filter according to the first embodiment, where (a) is a side view, and (b) is IIIb-IIIb in (a). It is the figure seen from the direction shown to a line. FIG. 4 is a diagram showing pass characteristics of the dielectric waveguide filter according to the first embodiment. FIG. 5A is a diagram illustrating still another example of the coupling portion illustrated in FIG. 2A. FIG. 5B is a diagram illustrating still another example of the coupling unit illustrated in FIG. 2B. FIG. 6 is an exploded perspective view of the dielectric waveguide filter according to the first modification of the first embodiment. FIG. 7 is a diagram illustrating an example of a coupling portion of the dielectric waveguide filter according to the first modification of the embodiment. 8A is a perspective view of a dielectric waveguide filter according to Modification 2 of Embodiment 1. FIG. 8B is an exploded perspective view of a dielectric waveguide filter according to Modification 2 of Embodiment 1. FIG. 9A is a perspective view of a dielectric waveguide filter according to Modification 3 of Embodiment 1. FIG. FIG. 9B is an exploded perspective view of a dielectric waveguide filter according to Modification 3 of Embodiment 1. 10A is a perspective view of a dielectric waveguide filter according to Modification 4 of Embodiment 1. FIG. 10B is an exploded perspective view of a dielectric waveguide filter according to Modification 4 of Embodiment 1. FIG. FIG. 11 is an exploded perspective view of the dielectric waveguide filter according to the second embodiment. FIG. 12 is a block diagram showing a circuit configuration of the dielectric waveguide filter according to the second embodiment. FIG. 13 is a diagram showing pass characteristics of the dielectric waveguide filter according to the second exemplary embodiment. FIG. 14 is an exploded perspective view of a dielectric waveguide filter according to a modification of the second embodiment. FIG. 15 is an exploded perspective view of the dielectric waveguide filter according to the third embodiment. FIG. 16 is a diagram illustrating pass characteristics of the dielectric waveguide filter according to the third embodiment. FIG. 17A is an exploded perspective view of a dielectric waveguide filter according to Modification 1 of Embodiment 3. FIG. 17B is an exploded perspective view of a dielectric waveguide filter according to Modification 2 of Embodiment 3. 18A is an exploded perspective view of a dielectric waveguide filter according to Modification 3 of Embodiment 3. FIG. FIG. 18B is an exploded perspective view of a dielectric waveguide filter according to Modification 4 of Embodiment 3. FIG. 18C is an exploded perspective view of a dielectric waveguide filter according to Modification 5 of Embodiment 3. FIG. 19 is an exploded perspective view of the dielectric waveguide filter according to the fourth embodiment. FIG. 20 is a diagram illustrating pass characteristics of the dielectric waveguide filter according to the fourth embodiment. FIG. 21A is an exploded perspective view of a dielectric waveguide filter according to Modification 1 of Embodiment 4. FIG. 21B is an exploded perspective view of a dielectric waveguide filter according to Modification 2 of Embodiment 4. FIG. 22 is an exploded perspective view of the dielectric waveguide filter according to the fifth embodiment. FIG. 23 is a diagram illustrating pass characteristics of the dielectric waveguide filter according to the fifth embodiment. FIG. 24 is an exploded perspective view of the dielectric waveguide filter according to the sixth embodiment. FIG. 25 is a diagram illustrating pass characteristics of the dielectric waveguide filter according to the sixth embodiment. FIG. 26 is an exploded perspective view of the dielectric waveguide filter according to the first modification of the sixth embodiment. FIG. 27A is a perspective view of a dielectric waveguide filter according to Embodiment 7. FIG. 27B is an exploded perspective view of the dielectric waveguide filter according to Embodiment 7. FIG. 28 is a block diagram showing a part of the circuit configuration of the dielectric waveguide filter according to the first modification of the seventh embodiment. FIG. 29 is an exploded perspective view of the dielectric waveguide filter according to the eighth embodiment. FIG. 30 is an exploded perspective view of the dielectric waveguide filter according to the ninth embodiment. FIG. 31 is an exploded perspective view of the dielectric waveguide filter according to the tenth embodiment. FIG. 32 is a diagram showing types of coupling of the dielectric waveguide filter according to the tenth embodiment. FIG. 33 is a diagram showing pass characteristics of the dielectric waveguide filter according to the tenth embodiment. FIG. 34 is a circuit diagram showing the high-frequency front-end circuit and communication apparatus according to Embodiment 11. FIG. 35 is a circuit diagram showing a Massive MIMO system according to the twelfth embodiment. FIG. 36 is a perspective view showing a communication apparatus of the Massive MIMO system according to the twelfth embodiment. FIG. 37 is a perspective view showing a dielectric waveguide filter in another form.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. It should be noted that each of the embodiments described below shows a comprehensive or specific example. Numerical values, shapes, materials, constituent elements, arrangement of constituent elements, connection forms, and the like shown in the following embodiments are merely examples, and are not intended to limit the present invention. Among the constituent elements in the following embodiments, constituent elements not described in the independent claims are described as optional constituent elements. Further, the size of components shown in the drawings or the ratio of sizes is not necessarily strict.

(Embodiment 1)
[1-1. Configuration of Dielectric Waveguide Filter]
First, the structure of the dielectric waveguide filter 1 according to the first embodiment will be described. FIG. 1A is a perspective view of the dielectric waveguide filter 1 as viewed obliquely from above. FIG. 1B is a perspective view of the dielectric waveguide filter 1 as viewed obliquely from below. FIG. 1C is an exploded perspective view of the dielectric waveguide filter 1.

The dielectric waveguide filter 1 includes a first resonator group 10 and a second resonator group 20 disposed on the first resonator group 10. The first resonator group 10 has four first resonators 11, 12, 13, and 14, and the second resonator group 20 has four second resonators 21, 22, 23, and 24. Yes. Hereinafter, the first resonators 11, 12, 13, 14, and the second resonators 21, 22, 23, 24 may be referred to as resonators 11, 12, 13, 14, 21, 22, 23, 24, respectively. .

The resonator 11 is provided with a first input / output electrode 61 to which a high-frequency signal is input. The resonator 13 is provided with a second input / output electrode 62 from which a high-frequency signal input from the first input / output electrode 61 is output. A ground electrode 65 is provided in a region different from the region where the first input / output electrode 61 and the second input / output electrode 62 are provided on the surfaces of the resonators 11 to 14 and 21 to 24.

Further, the dielectric waveguide filter 1 includes a mounting substrate 70. The mounting substrate 70 is formed of a resin material such as epoxy or phenol, for example. On the mounting substrate 70, input / output patterns 71 and 72 and a ground pattern 75 corresponding to the first input / output electrode 61, the second input / output electrode 62, and the ground electrode 65 are formed. The input / output patterns 71 and 72 and the ground pattern 75 are formed of, for example, copper foil.

The first resonator group 10 is disposed on the mounting substrate 70 such that the surface (lower surface) opposite to the surface (upper surface) on which the second resonators 21 to 24 are disposed faces the main surface 70a of the mounting substrate 70. It is joined. Specifically, the first input / output electrode 61 and the input / output pattern 71, the second input / output electrode 62 and the input / output pattern 72, and the ground electrode 65 and the ground pattern 75 are joined by a conductive joining material such as solder. ing.

Here, the direction in which the resonator 13 and the resonator 11 are arranged is the X direction, the direction in which the resonator 11 and the resonator 21 overlap vertically is the Z direction, and the resonator 11 and the resonator 12 are arranged in the direction. A direction perpendicular to both the X direction and the Z direction is defined as a Y direction. A plane including both the X-direction axis and the Y-direction axis and including the main surface 70a of the mounting substrate 70 is defined as a predetermined plane.

In this case, the resonators 11 to 14 and 21 to 24 have the following arrangement relationship. Specifically, the resonators 11 to 14 are arranged in a matrix along a predetermined plane. The resonators 11 and 12 are adjacent in the Y direction, the resonators 13 and 14 are adjacent in the Y direction, the resonators 11 and 13 are adjacent in the X direction, and the resonators 12 and 14 are adjacent in the X direction. The resonators 21 and 22 are adjacent in the Y direction, the resonators 23 and 24 are adjacent in the Y direction, the resonators 21 and 23 are adjacent in the X direction, and the resonators 22 and 24 are adjacent in the X direction. Each of the resonators 21 to 24 is arranged in a matrix on the first resonator group 10 so as to correspond to each of the resonators 11 to 14, and overlaps each of the resonators 11 to 14 in the Z direction. ing.

The resonators 11 and 12 are formed by a dielectric block 51a, the resonators 13 and 14 are formed by a dielectric block 51b, the resonators 21 and 22 are formed by a dielectric block 51c, and the resonators 23 and 24 are dielectrics. It is formed by the block 51d. Each of the dielectric blocks 51a to 51d has a prismatic shape, and a part of the surface is covered with the ground electrode 65 described above. Each of the dielectric blocks 51a to 51d is a resonance block formed by integrally molding a dielectric material such as quartz or ceramic. The ground electrode 65 is formed, for example, by applying a conductive paste containing silver or copper to the surface 52 of each of the dielectric blocks 51a to 51d.

The resonators 11 and 12, the resonators 13 and 14, the resonators 21 and 22, and the resonators 23 and 24 are electromagnetically coupled to each other via the coupling portion 55. The coupling portion 55 is formed by providing a groove near the center in the longitudinal direction (Y direction) of each of the dielectric blocks 51a to 51d. For example, the resonators 11 and 12 are formed by providing a groove near the center in the longitudinal direction of the dielectric block 51a.

In the present embodiment, “electromagnetic field coupling” means coupling by an electromagnetic field having at least one of an electric field and a magnetic field.

The resonators 11 to 14 and 21 to 24 have a rectangular parallelepiped shape and have an upper surface f1, a lower surface f2, and a side surface f3. The above-described ground electrode 65 is formed on the upper surface f1, the lower surface f2, and the side surface f3 of each of the resonators 11-14 and 21-24. Further, a first input / output electrode 61 is formed on the lower surface f2 of the resonator 11, and a second input / output electrode 62 is formed on the lower surface f2 of the resonator 13.

The first resonator group 10 is formed by joining the opposing side surfaces of the dielectric blocks 51a and 51b using a conductive paste. The second resonator group 20 is formed by joining the opposing side surfaces of the dielectric blocks 51c and 51d using a conductive paste. The dielectric waveguide filter 1 is formed by joining the upper surface of the first resonator group 10 and the lower surface of the second resonator group 20 using a conductive paste.

FIG. 2A is a diagram showing the coupling portion 56 of the dielectric waveguide filter 1. FIG. 2B is a diagram illustrating an example of the coupling portion 56 and is a diagram when the resonator 23 is viewed from the resonator 21 side. FIG. 2C is a diagram illustrating another example of the coupling portion 56 and is a diagram when the resonator 12 is viewed from above.

A coupling portion 56 including a region where the surface 52 of the dielectric blocks 51c and 51d is exposed is provided on each of the side surfaces f3 of the resonator 21 and the resonator 23 facing each other. The coupling portion 56 of the resonator 21 and the coupling portion 56 of the resonator 23 are opposed to each other, and the resonators 21 and 23 are electromagnetically coupled through the coupling portion 56. The coupling portion 56 of the resonator 21 has a rectangular shape and is provided at a position including the center of the side surface f3 of the resonator 21. The coupling portion 56 of the resonator 23 has a rectangular shape and is provided at a position including the center of the side surface f3 of the resonator 23 (see FIG. 2B).

A coupling portion 56 including a region where the surface 52 of the dielectric blocks 51a and 51c is exposed is formed on each of the upper surface f1 of the resonator 12 and the lower surface f2 of the resonator 22. The coupling portion 56 of the resonator 12 and the coupling portion 56 of the resonator 22 are opposed to each other, and the resonator 12 and the resonator 22 are electromagnetically coupled via the coupling portion 56. The coupling portion 56 of the resonator 12 has a circular shape, and is provided at a position including the center of the upper surface f1 of the resonator 12 when viewed in plan (see FIG. 2C). The coupling portion 56 of the resonator 22 has a circular shape, and is provided at a position including the center of the lower surface f2 of the resonator 22 when viewed from the bottom surface.

On each of the upper surface f1 of the resonator 14 and the lower surface f2 of the resonator 24, a coupling portion 56 including a region where the surface 52 of the dielectric blocks 51b and 51d is exposed is formed. The resonator 14 and the resonator 24 are electromagnetically coupled via the coupling portion 56. The coupling portion 56 of the resonator 14 has a circular shape, and is provided at a position including the center of the upper surface f1 of the resonator 14 in a plan view. The coupling portion 56 of the resonator 24 has a circular shape, and is provided at a position including the center of the lower surface f2 of the resonator 24 when viewed from the bottom surface.

Next, electromagnetic coupling generated in the resonators 11 to 14 and 21 to 24 will be described with reference to FIG.

3A and 3B are schematic diagrams showing an electromagnetic field generated in a part of the dielectric waveguide filter 1, wherein FIG. 3A is a side view, and FIG. 3B is a view from the direction indicated by the line IIIb-IIIb in FIG. FIG. FIG. 3 shows a state where a signal having a predetermined frequency is input to the dielectric waveguide filter 1.

When a signal having a predetermined frequency is input from the first input / output electrode 61, the resonator 11 resonates, and as shown in FIGS. 3A and 3B, the resonator 11 has an electric field directed in the Z direction. And a magnetic field that surrounds the axis in the Z direction. At that time, as shown in FIG. 3B, the electric field is strongly generated at the center of the resonator 11, and the magnetic field is strongly generated along the outer peripheral side surface of the resonator 11.

A coupling portion 55 is provided on the side surfaces of the resonator 11 and the resonator 12 facing each other. Therefore, a magnetic field is generated in the resonator 12 so as to be coupled with the magnetic field generated in the resonator 11, and an electric field is generated in the resonator 12 along with the generated magnetic field.

A coupling portion 56 is provided at the center of each of the upper surface f1 of the resonator 12 and the lower surface f2 of the resonator 22. Therefore, an electric field is generated in the resonator 22 so as to be coupled with the electric field generated in the resonator 12, and a magnetic field is generated in the resonator 22 along with the generated electric field.

A coupling portion 55 is provided between the resonator 22 and the resonator 21, and the resonators 22 and 21 are magnetically coupled to each other. In addition, a coupling portion 56 is provided between the resonator 21 and the resonator 23, and the resonators 21 and 23 are magnetically coupled to each other. Further, the resonator 23 and the resonator 24 are magnetically coupled to each other by a coupling portion 55 provided therebetween, and the resonator 24 and the resonator 14 are electrically coupled to each other by a coupling portion 56 provided therebetween. The resonator 14 and the resonator 13 are magnetically coupled to each other by a coupling portion 55 provided therebetween.

In this way, the high-frequency signal input to the first input / output electrode 61 is output from the second input / output electrode 62 through a plurality of electromagnetic field couplings. That is, the dielectric waveguide filter 1 passes the signals input to the first input / output electrode 61 through the resonators 11, 12, 22, 21, 23, 24, 14, 13 in order, and the second input / output electrode It has an input / output path P1 that outputs from 62 (see FIG. 1C).

FIG. 4 is a diagram showing the pass characteristics of the dielectric waveguide filter 1. Specifically, FIG. 4 shows insertion loss (simulation result) when the second input / output electrode 62 is viewed from the first input / output electrode 61. As shown in FIG. 4, the dielectric waveguide filter 1 according to the present embodiment constitutes a bandpass filter having a passband in a frequency range of 26, 5 GHz to 29, 5 GHz.

[1-2. Effect]
The dielectric waveguide filter 1 according to the present embodiment includes a first resonator group 10 including a plurality of first resonators 11 to 14 arranged along a predetermined plane (a main surface 70a of the mounting substrate 70). And a second resonator group 20 including a plurality of second resonators 21 to 24 arranged on the first resonator group 10 in the vertical direction perpendicular to the predetermined plane. Each of the first resonators 11 to 14 and the second resonators 21 to 24 is formed by dielectric blocks 51a to 51d. And at least one first resonator of the plurality of first resonators 11 to 14, and at least one second resonator of the one or more second resonators 21 to 24, which overlap in the vertical direction, Among the combinations, a plurality of first resonators 11 to 11 which are electromagnetically coupled to each other and adjacent to each other along a predetermined plane in at least two combinations ( resonators 12, 22 and resonators 24, 14). In the combination ( resonators 11 and 12 and resonators 14 and 13) in which at least two of the first resonators are one set, 14 are electromagnetically coupled to each other.

As described above, the second resonator group 20 is disposed on the first resonator group 10, and the dielectric waveguide filter 1 has a laminated structure including the first resonator group 10 and the second resonator group 20. Thus, the area of the entire dielectric waveguide filter 1 can be reduced as compared with a case where all the resonators are arranged in the horizontal direction as in Patent Document 1. Further, in this configuration, electromagnetic coupling can be performed on both the upper and lower surfaces and the side surfaces, so that the degree of freedom in selecting a signal path in the dielectric waveguide filter 1 can be increased. Further, since the second resonators 21 to 24 are arranged on the first resonator group 10, unlike the case of Patent Document 2, electromagnetic coupling is performed only by the resonators arranged in the horizontal row and the vertical direction. , It is possible to perform electromagnetic field coupling in the X direction, the Y direction, and the vertical direction (Z direction) along a predetermined plane, the degree of freedom of electromagnetic field coupling can be increased, and the degree of freedom of selection of signal paths is improved. be able to.

Further, in the dielectric waveguide filter 1 of the present embodiment, a plurality of combinations of resonators 22 and 21 including two adjacent second resonators on the first resonator group 10, and the resonator 21. , 23 and the resonators 23, 24 are electromagnetically coupled to each other in respective combinations.

Thus, by having the plurality of combinations of the second resonators 21 to 24 to be electromagnetically coupled, the number of combinations to be electromagnetically coupled in the first resonator group 10, that is, the first resonators arranged along a predetermined plane. The number of one resonator can be reduced, and the entire area of the dielectric waveguide filter 1 can be reduced. In addition, by coupling the adjacent second resonators to each other by electromagnetic field, it is possible to increase the choices of places where electromagnetic coupling is performed by overlapping in the vertical direction. Thereby, the freedom degree of the location which electromagnetically couples can be raised and the freedom degree of selection of a signal path | route can be improved.

Note that the shape of the coupling portion 56 for electromagnetic field coupling is not limited to a circular shape, and may be a polygonal shape such as a rectangle, a frame shape, or a U-shape. Further, the shape of the coupling portion 56 may be an O-shape (ring shape) as shown in FIG. 5A (a), or may be a C-shape as shown in FIG. 5A (b). Good. For example, if the exposed area of the dielectric is too large at the coupling portion 56, the capacitive component of the resonator becomes small, and the resonator may have to be enlarged in order to resonate at a specific frequency. On the other hand, by making the shape of the coupling portion 56 O-shaped or C-shaped, it is possible to add a capacitive component to the resonator and suppress an increase in size of the resonator.

Further, an electrode pattern 66 made of the same material as the ground electrode 65 may be formed at the center of the upper surface f1 of the resonators 12 and 14 or the lower surface f2 of the resonators 22 and 24 and at the center of the coupling portion 56. Good (see (a) and (b) of FIG. 5A). For example, when the exposed area of the dielectric is too large at the coupling portion 56, the capacitance component of the resonator is reduced, and the resonance frequency is increased more than necessary. In order to lower the resonance frequency, it is necessary to enlarge the resonator. On the other hand, by forming the electrode pattern 66 at the center of the upper surface f1 or the lower surface f2 of the resonator having a strong electric field, a sufficient capacitance component can be added to the resonator, and an increase in size of the resonator can be suppressed.

Moreover, as shown to (a) of FIG. 5B, the coupling | bond part 56 of the side surface f3 is connected to the ground electrode 65, and the electrode protrusion which protrudes toward the other end 56b side from the one end 56a of the coupling | bond part 56 in an up-down direction. A portion 56c is provided, and the other end 56b of the coupling portion 56 and the electrode protruding portion 56c may face each other with a predetermined gap. The shape of the electrode protrusion 56c may be T-shaped, L-shaped, or π-shaped. The electrode protruding portion 56c may be formed to protrude from the other end 56b of the coupling portion 56 toward the one end 56a. The outer shape of the coupling portion 56 may be rectangular or circular.

According to this, for example, as shown in FIG. 5B (b), an electric field as indicated by an arrow can be generated between the other end 56b of the coupling portion 56 and the electrode protruding portion 56c. As a result, adjacent resonators can be coupled to each other via the coupling portion 56 on the side surface f3.

The number of resonators 11 to 14 and 21 to 24 is not limited to eight in total. That is, the first resonator group 10 of the dielectric waveguide filter 1 includes four or more first resonators arranged in a matrix along a predetermined plane, and the second resonator group 20 includes the first resonance. Four or more second resonators arranged in a matrix on the resonator group 10 may be included.

For example, by increasing the number of resonators 11 to 14 or the number of resonators 21 to 24 to four or more, the number of combinations of electromagnetic coupling can be increased, and the passband of the dielectric waveguide filter 1 can be increased. The width can be increased.

Moreover, in the dielectric waveguide filter 1 according to the present embodiment, of the resonators 12 and 22 that are electromagnetically coupled to each other in the vertical direction, the resonator 12 is the same as the resonator 11 positioned next to the resonator 12. The electromagnetic field coupling is performed, and the resonator 22 is electromagnetically coupled to the resonator 21 located next to the resonator 22. Of the resonators 14 and 24 that are electromagnetically coupled to each other in the vertical direction, the resonator 14 is electromagnetically coupled to the resonator 13 positioned next to the resonator 14, and the resonator 24 is adjacent to the resonator 24. Electromagnetic field coupling with the resonator 23 located at

As described above, the resonators that are electromagnetically coupled to each other in the vertical direction are electromagnetically coupled to the adjacent resonators, whereby the entire area of the dielectric waveguide filter 1 can be reduced. Further, the degree of freedom in selecting the signal path can be improved by increasing the degree of freedom of the electromagnetic wave coupling portion in the dielectric waveguide filter 1.

Further, in the dielectric waveguide filter 1 according to the present embodiment, the resonators 11 and 12 and the resonators 14 and 13 that are adjacent to each other along two predetermined planes, and two sets of the resonators 12 that overlap in the vertical direction, 22 and the resonators 24 and 14 and three combinations of the resonators 22 and 21, the resonators 21 and 23 and the resonators 23 and 24 arranged on the first resonator group 10 are mutually combined. It is electromagnetically coupled.

As described above, the resonators adjacent in the predetermined plane, the resonators overlapping in the vertical direction, and the resonators adjacent on the first resonator group 10 are electromagnetically coupled in each combination, thereby providing a dielectric. The area of the entire waveguide filter 1 can be reduced. Further, the degree of freedom in selecting the signal path can be improved by increasing the degree of freedom of the electromagnetic wave coupling portion in the dielectric waveguide filter 1.

Moreover, in the dielectric waveguide filter 1 according to the present embodiment, the respective electromagnetic field coupling of the resonators 11 and 12 and the resonators 14 and 13 adjacent along the predetermined plane is the first coupling, and the vertical direction The respective electromagnetic field couplings of the resonators 12 and 22 and the resonators 24 and 14 that overlap each other are used as the second coupling, and the adjacent resonators 22 and 21, the resonators 21 and 23, and the resonance on the first resonator group 10. When the electromagnetic field coupling of each of the devices 23 and 24 is the third coupling, each of the first coupling and the third coupling is one of the magnetic field coupling and the electric field coupling, and the second coupling is The other of the magnetic field coupling and the electric field coupling may be different from the above one.

As described above, the electromagnetic coupling in the dielectric waveguide filter 1 can be efficiently performed by setting the first coupling and the third coupling to electromagnetic coupling different from the second coupling. Further, when the first coupling and the third coupling are magnetic field couplings, and the second coupling is electric field coupling, the respective coupling degrees can be increased.

Furthermore, the dielectric waveguide filter 1 according to the present embodiment includes a first input / output electrode 61 provided in the resonator 11, a second input / output electrode 62 provided in the resonator 13, An input / output path P1 for outputting a signal input to one input / output electrode from the second input / output electrode 62 through a plurality of electromagnetic couplings.

As described above, the passband of the dielectric waveguide filter 1 can be easily formed by outputting the input signal through a plurality of electromagnetic couplings.

The input / output path P1 includes the resonator 11, the resonator 12 that is located farthest in the Y direction with respect to the resonator 11, the resonator 22 that overlaps the resonator 12 in the Z direction, and the resonator 22 With respect to the resonator 21, the resonator 23 adjacent to the resonator 21 in the X direction, and the resonator 24 farthest from the resonator 23 in the Y direction. This is a path that sequentially connects the resonator 14 that overlaps the resonator 24 in the Z direction and the resonator 13 that is located farthest in the Y direction with respect to the resonator 14.

In this way, a plurality of electromagnetic couplings can be formed using the resonators 11, 12, 22, 21, 23, 24, 14, and 13 arranged in order on the input / output path P1, and the dielectric conductor can be formed. The area of the entire wave tube filter 1 can be reduced. Further, the pass band of the dielectric waveguide filter 1 can be easily formed.

[1-3. Modification 1 of Embodiment 1]
FIG. 6 is an exploded perspective view of a dielectric waveguide filter 1A according to the first modification of the first embodiment.

In the dielectric waveguide filter 1A according to Modification 1, all of the electromagnetic field coupling in the input / output path P1 is magnetic field coupling.

FIG. 7 is a diagram illustrating an example of the coupling portion 56 of the dielectric waveguide filter 1A.

A coupling portion 56 shown in FIG. 7A is formed on the upper surface f1 of the resonator 12 of the dielectric waveguide filter 1A. The coupling portion 56 of the resonator 12 has a rectangular shape, and a plurality of coupling portions 56 are provided along the outer periphery of the upper surface f1 of the resonator 12 when viewed in plan. The coupling portion 56 of the resonator 22 has a rectangular shape, and a plurality of coupling portions 56 are provided along the outer periphery of the lower surface f2 of the resonator 22 when viewed from the bottom surface. The coupling portion 56 of the resonator 22 is formed at a position facing the coupling portion 56 of the resonator 12.

A coupling portion 56 having the same shape as the coupling portion 56 shown in FIG. 7A is formed on the upper surface f1 of the resonator 14. The coupling portion 56 of the resonator 14 has a rectangular shape, and is provided along the outer periphery of the upper surface f1 of the resonator 14 when viewed in plan. The coupling portion 56 of the resonator 24 has a rectangular shape, and is provided along the outer periphery of the lower surface f2 of the resonator 24 when viewed from the bottom surface. The coupling portion 56 of the resonator 24 is formed at a position facing the coupling portion 56 of the resonator 14.

As described above, since the magnetic field is generated strongly along the outer peripheral side surfaces of the resonators 12 and 22, the coupling portions 56 are provided along the outer peripheries of the resonators 12 and 22. Magnetic field coupling. Further, by providing the coupling portion 56 along the outer periphery of each of the resonators 24 and 14, the resonators 24 and 14 are magnetically coupled to each other.

The coupling portion 56 of the resonator 12 is not limited to the shape shown in FIG. 7A. For example, as shown in FIG. 7B or FIG. It is only necessary to be provided along at least a part. Further, the coupling portion 56 of the resonator 22 may be provided at a position facing the coupling portion 56 of the resonator 12 along at least a part of the outer periphery of the lower surface f <b> 2 of the resonator 22. The same applies to the resonators 14 and 24.

In the dielectric waveguide filter 1A according to the first modification, the resonators 11 and 12 and the resonators 14 and 13 which are adjacent to each other along two combinations of predetermined planes, and the two sets of resonators 12 and 22 which overlap in the vertical direction and the resonance. The resonators 24 and 23, and the three combinations of the resonators 22 and 21, the resonators 21 and 23, and the resonators 23 and 24 arranged on the first resonator group 10 are electromagnetically coupled to each other in each combination. is doing. And the main coupling | bonding of these electromagnetic couplings is made into magnetic coupling.

As described above, the resonators adjacent in the predetermined plane, the resonators overlapping in the vertical direction, and the resonators adjacent on the first resonator group 10 are electromagnetically coupled in each combination, thereby providing a dielectric. The area of the entire waveguide filter 1 can be reduced. Moreover, the electromagnetic field design of the dielectric waveguide filter 1A can be efficiently performed by using the magnetic field coupling as the main coupling of the electromagnetic field coupling.

[1-4. Modification 2 and Modification 3 of Embodiment 1]
8A is a perspective view of a dielectric waveguide filter 1B according to Modification 2 of Embodiment 1. FIG. FIG. 8B is an exploded perspective view of the dielectric waveguide filter 1B.

The dielectric waveguide filter 1B according to the modification 2 includes three resonators 11, 13, and 21. The first resonator group 10 of the dielectric waveguide filter 1 </ b> B has two resonators 11 and 13, and the second resonator group 20 has one resonator 21. Each resonator 11, 13, 21 is formed by each dielectric block 51a, 51b, 51c and a ground electrode 65 provided on the upper surface f1, the lower surface f2, and the side surface f3 of each dielectric block 51a, 51b, 51c. ing.

The coupling portion 56 of the resonators 11 and 13 is provided along a part of the outer periphery of the upper surface f1 of each resonator 11 and 13 as illustrated in FIG. The coupling portion 56 of the resonator 21 is provided at a position facing the coupling portion 56 of each of the resonators 11 and 13. As shown by the input / output path P1 in FIG. 8B, the signal input to the dielectric waveguide filter 1B is output via the electromagnetic coupling of the resonators 11 and 21 and the electromagnetic coupling of the resonators 21 and 13. The

FIG. 9A is a perspective view of a dielectric waveguide filter 1C according to Modification 3 of Embodiment 1. FIG. FIG. 9B is an exploded perspective view of the dielectric waveguide filter 1C.

A dielectric waveguide filter 1C according to Modification 3 includes three resonators 11, 13, and 21. The first resonator group 10 of the dielectric waveguide filter 1 </ b> C includes two resonators 11 and 13, and the second resonator group 20 includes one resonator 21. The resonator 21 has an area twice that of the resonator 11 and is disposed so as to cover the upper surface f1 of the resonators 11 and 13. Each resonator 11, 13, 21 is formed by each dielectric block 51a, 51b, 51c and a ground electrode 65 provided on the upper surface f1, the lower surface f2, and the side surface f3 of each dielectric block 51a, 51b, 51c. ing.

The coupling portion 56 of the resonators 11 and 13 is provided along a part of the outer periphery of the upper surface f1 of each resonator 11 and 13 as illustrated in FIG. The coupling portion 56 of the resonator 21 is provided at a position facing the coupling portion 56 of each of the resonators 11 and 13. As shown by the input / output path P1 of FIG. 9B, the signal input to the dielectric waveguide filter 1C is output via the electromagnetic coupling of the resonators 11 and 21 and the electromagnetic coupling of the resonators 21 and 13. The

Each of the dielectric waveguide filters 1B and 1C according to Modification 2 and Modification 3 includes a first resonator group 10 including a plurality of first resonators 11 and 13 arranged along a predetermined plane, and a predetermined plane. And a second resonator group 20 including a second resonator 21 disposed on the first resonator group 10 in a vertical direction perpendicular to the first resonator group 10. The two combinations of the resonators 11 and 21 and the resonators 21 and 13 including the first resonator and the second resonator overlapping in the vertical direction are electromagnetically coupled to each other in each combination.

As described above, the second resonator group 20 is disposed on the first resonator group 10, and the dielectric waveguide filters 1B and 1C are formed in a laminated structure, so that each dielectric waveguide filter 1B, The area of 1C can be reduced. Further, the degree of freedom in selecting the signal path can be improved by increasing the degree of freedom of the electromagnetic wave coupling portions in the dielectric waveguide filters 1B and 1C.

[1-5. Modification 4 of Embodiment 1]
10A is a perspective view of a dielectric waveguide filter 1D according to Modification 4 of Embodiment 1. FIG. FIG. 10B is an exploded perspective view of the dielectric waveguide filter 1D.

The dielectric waveguide filter 1D according to the modification 4 includes four resonators 11, 13, 21, and 23. The first resonator group 10 of the dielectric waveguide filter 1D includes two resonators 11 and 13, and the second resonator group 20 includes two resonators 21 and 23. Each of the resonators 11, 13, 21, and 23 includes dielectric blocks 51a, 51b, 51c, and 51d, and grounds provided on the upper surface f1, the lower surface f2, and the side surface f3 of the dielectric blocks 51a, 51b, 51c, and 51d. The electrode 65 is formed.

The coupling portion 56 of each resonator 11, 13 is provided at a position including the center of the upper surface f1 of each resonator 11, 13 as illustrated in FIG. 2C or FIG. 5A. The coupling portion 56 of each resonator 21, 23 is provided at a position facing the coupling portion 56 of each resonator 11, 13. 2B, the coupling portion 56 of the resonator 23 is provided at a position including the center of the side surface f3 of the resonator 23, and the coupling portion 56 of the resonator 21 is connected to the coupling portion 56 of the resonator 23. It is provided at an opposing position. As shown by the input / output path P1 in FIG. 10B, the signal input to the dielectric waveguide filter 1D is an electromagnetic field coupling of each set of the resonators 11 and 21, the resonators 21 and 23, and the resonators 23 and 13. Is output via.

A dielectric waveguide filter 1D according to Modification 4 includes a first resonator group 10 including a plurality of first resonators 11 and 13 arranged along a predetermined plane, and a vertical direction perpendicular to the predetermined plane. And a second resonator group 20 including a plurality of second resonators 21 and 23 disposed on the first resonator group 10. The two combinations of the resonators 11 and 21 and the resonators 23 and 13 including the first resonator and the second resonator overlapping in the vertical direction are electromagnetically coupled to each other in each combination.

As described above, the area of the dielectric waveguide filter 1D is reduced by disposing the second resonator group 20 on the first resonator group 10 and forming the dielectric waveguide filter 1D in a laminated structure. be able to. Further, the degree of freedom in selecting the signal path can be improved by increasing the degree of freedom of the electromagnetic wave coupling portion in the dielectric waveguide filter 1D.

(Embodiment 2)
[2-1. Configuration of Dielectric Waveguide Filter]
FIG. 11 is an exploded perspective view of a dielectric waveguide filter 1E according to the second embodiment. FIG. 12 is a block diagram showing a circuit configuration of the dielectric waveguide filter 1E.

The dielectric waveguide filter 1E according to the second embodiment has the first bypass path B1 and the second bypass path B2 based on the dielectric waveguide filter 1 according to the first embodiment. . In FIG. 11, the input / output path P1 is indicated by a thick line, and the first bypass path B1 and the second bypass path B2 are indicated by thin lines. Hereinafter, the first bypass path B1 and the second bypass path B2 may be referred to as a bypass path B1 and a bypass path B2, respectively.

The bypass path B1 is a path that bypasses a signal propagated between the first input / output electrode 61 and the second input / output electrode 62 via electromagnetic field coupling different from that of the input / output path P1. In the present embodiment, the resonator 11 and the resonator 21 are electromagnetically coupled on the bypass path B1.

The signal propagating through the bypass path B1 and the signal propagating through the input / output path P1 are set to have different phases in a frequency band different from the pass band of the dielectric waveguide filter 1E. For example, as shown in FIG. 12, the resonators 12 and 22 in the input / output path P1 are electrically coupled to each other (capacitive coupling), and the resonators 11 and 21 in the bypass path B1 are magnetically coupled to each other. Thereby, the signal phases of the input / output path P1 and the bypass path B1 can be different from each other by 180 °.

The bypass path B2 is a path for bypassing a signal propagated between the first input / output electrode 61 and the second input / output electrode 62 through electromagnetic coupling different from that of the input / output path P1 and the bypass path B1. . In the present embodiment, the resonator 23 and the resonator 13 are electromagnetically coupled on the bypass path B2.

The signal propagating through the bypass path B2 and the signal propagating through the input / output path P1 are different in frequency band from the pass band of the dielectric waveguide filter 1E (other than the frequency band in which the phase of the signal is different in the bypass path B1). The frequency is set to be different in the frequency band. For example, as shown in FIG. 12, the resonators 24 and 14 are electrically coupled to each other (capacitive coupling), and the resonators 23 and 13 are magnetically coupled to each other. As a result, the signal phases of the input / output path P1 and the bypass path B2 can be different from each other by 180 °.

With respect to the dielectric waveguide filter 1E, in the low frequency side band of the filter pass band, the magnetic field coupling works in the same phase and the electric field coupling works in the opposite phase. Further, in the band on the high frequency side of the filter pass band, there is a property that magnetic field coupling works in opposite phase and electric field coupling works in phase.

When the above property is applied to the bypass path B1, the resonators 12 and 22 in the input / output path P1 are electric field coupled, whereas the resonators 11 and 21 in the bypass path B1 are magnetically coupled. The phase is inverted with respect to P1. Due to this phase inversion, signals cancel each other at a predetermined frequency on the low frequency side to generate an attenuation pole, and signals also cancel each other even at a predetermined frequency on the high frequency side to generate an attenuation pole.

When the above property is applied to the bypass path B2, the resonators 24 and 14 in the input / output path P1 are electric field coupled, whereas the resonators 23 and 13 in the bypass path B2 are magnetically coupled. The phase is inverted with respect to the output path P1. Due to this phase inversion, signals cancel each other at a predetermined frequency on the low frequency side to generate an attenuation pole, and signals also cancel each other even at a predetermined frequency on the high frequency side to generate an attenuation pole.

In this way, by changing the phase of the signals of the bypass paths B1 and B2 with respect to the input / output path P1, a signal having a predetermined frequency can be canceled and a plurality of attenuation poles can be formed. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

FIG. 13 is a diagram showing pass characteristics of the dielectric waveguide filter 1E. As shown in FIG. 13, in the dielectric waveguide filter 1E, two attenuation poles are formed on each of the low frequency side and the high frequency side of the pass band. Therefore, the insertion loss outside the pass band is large, and the steepness on the low frequency side and the high frequency side of the pass band is improved.

[2-2. Effect]
A dielectric waveguide filter 1E according to the present embodiment includes a first resonator group 10 including four or more first resonators 11 to 14 arranged in a matrix along a predetermined plane, and a first resonator. A second resonator group 20 including four or more second resonators 21 to 24 arranged in a matrix on the group 10, a first input / output electrode 61 provided in the first resonator 11, and a first resonance A second input / output electrode 62 provided in the device 13 and an input / output path P1 for outputting a signal input to the first input / output electrode 61 from the second input / output electrode 62 through a plurality of electromagnetic couplings. And a bypass path B1 (or B2) for bypassing a signal propagated between the first input / output electrode 61 and the second input / output electrode 62 through electromagnetic field coupling different from that of the input / output path P1. I have. A signal propagating through the bypass path B1 (or B2) and a signal propagating through the input / output path P1 have different phases in a frequency band different from the pass band of the dielectric waveguide filter 1E.

As described above, in the dielectric waveguide filter 1E, by changing the phase of the signal of the bypass path B1 (or B2) with respect to the input / output path P1, a signal having a predetermined frequency is canceled, and a plurality of attenuation poles are set. Can be formed. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

The bypass path B1 (or B2) of the dielectric waveguide filter 1E is different from the electromagnetic coupling of the resonators 12 and 22 (or 24 and 14) on the input / output path P1, and the resonators 11 and 21 (or 23, 13). As described above, since the bypass path B1 (or B2) has electromagnetic field coupling different from that of the input / output path P1, a signal having a predetermined frequency can be canceled and a plurality of attenuation poles can be formed.

Further, in the dielectric waveguide filter 1E, the electromagnetic coupling of the resonators 12, 22 (or 24, 14) overlapping in the vertical direction in the input / output path P1 is the fourth coupling, and the bypass path B1 (or B2) When the electromagnetic field coupling of the resonators 11 and 21 (or 23 and 13) overlapping in the vertical direction is the fifth coupling, the fourth coupling is one of the magnetic field coupling and the electric field coupling. Is the other of the magnetic field coupling and the electric field coupling. In this way, by setting the fifth coupling to an electromagnetic field coupling different from the fourth coupling, a signal having a predetermined frequency can be canceled and a plurality of attenuation poles can be formed. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

The first resonator group 10 of the dielectric waveguide filter 1E includes four first resonators 11 to 14 arranged in a matrix (2 rows and 2 columns) along a predetermined plane, and includes a second resonance. The resonator group 20 includes four second resonators 21 to 24 arranged in a matrix (2 rows and 2 columns) on the first resonator group 10. As an example of applying the prior art shown in Patent Document 2, a structure in which a plurality of resonators are arranged in a horizontal row to form one set, and the above-mentioned one set of resonators are stacked in the vertical direction is also conceivable. Then, only three bypass paths can be formed. On the other hand, in the dielectric waveguide filter 1E, in addition to between the resonators 11 and 21 and between the resonators 23 and 13, between the resonators 11 and 13, between the resonators 12 and 14, and between the resonators 22 and 24. A total of five bypass paths can be formed. Therefore, more attenuation poles can be formed than in the example to which the prior art is applied, and the insertion loss outside the passband can be increased.

The first resonator group 10 of the dielectric waveguide filter includes three first resonators 11, 12, and 13 arranged in a matrix along a predetermined plane, and the second resonator group 20 includes: The first resonator group 10 may be constituted by three second resonators 21, 22, and 23 arranged in a matrix. In that case, the resonator 12 is disposed such that the side surface f3 of the resonator 12 is in contact with both side surfaces f3 of the resonators 11 and 13. The resonator 22 is arranged such that the side surface f3 of the resonator 22 is in contact with both side surfaces f3 of the resonators 21 and 23. As an example of applying the prior art shown in Patent Document 2, a structure in which a plurality of resonators are arranged in a horizontal row to form one set, and the above-mentioned one set of resonators are stacked in the vertical direction is also conceivable. Then, only two bypass paths can be formed. On the other hand, in the dielectric waveguide filter having the above configuration, for example, the input / output path P1 is a path configured in the order of the resonators 11, 12, 22, 21, 23, and 13, and the bypass path is a resonance It is possible to form a total of three units between the resonators 11 and 13, between the resonators 12 and 13, and between the resonators 22 and 23. Therefore, more attenuation poles can be formed than in the example to which the prior art is applied, and the insertion loss outside the passband can be increased.

[2-3. Modification 1 of Embodiment 2]
FIG. 14 is an exploded perspective view of a dielectric waveguide filter 1F according to the first modification of the second embodiment.

In the dielectric waveguide filter 1F according to the first modification, the input / output path P1 is magnetic field coupling, and the bypass paths B1 and B2 are electric field coupling.

Specifically, the resonators 12 and 22 in the input / output path P1 are magnetically coupled to each other, and the resonators 11 and 21 in the bypass path B1 are electrically coupled to each other. As a result, the signal phases of the input / output path P1 and the bypass path B1 are different from each other by 180 °. Further, the resonators 24 and 14 in the input / output path P1 are magnetically coupled to each other, and the resonators 23 and 13 in the bypass path B2 are electrically coupled to each other. As a result, the phases of the signals of the input / output path P1 and the bypass path B2 are different by 180 °.

That is, the dielectric waveguide filter 1F bypasses the signal propagated between the first input / output electrode 61 and the second input / output electrode 62 through electromagnetic coupling different from that of the input / output path P1. A route B1 (or B2) is provided. The signal propagating through the bypass path B1 (or B2) and the signal propagating through the input / output path P1 have different phases in a frequency band different from the pass band of the dielectric waveguide filter 1F.

As described above, in the dielectric waveguide filter 1F, by changing the phase of the signal of the bypass path B1 (or B2) with respect to the input / output path P1, a signal having a predetermined frequency is canceled, and a plurality of attenuation poles are provided. Can be formed. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

(Embodiment 3)
[3-1. Configuration of Dielectric Waveguide Filter]
FIG. 15 is an exploded perspective view of a dielectric waveguide filter 1G according to the third embodiment.

A dielectric waveguide filter 1G according to the third embodiment has a basic configuration of the dielectric waveguide filter 1A according to the first modification of the first embodiment, further includes a bypass path B1, and has an X direction on the bypass path. The resonators 11 and 13 adjacent to each other are electromagnetically coupled.

Specifically, the resonators 21 and 23 in the input / output path P1 are magnetically coupled to each other, and the resonators 11 and 13 in the bypass path B1 are electrically coupled to each other. As a result, the signal phases of the input / output path P1 and the bypass path B1 are different from each other by 180 °.

FIG. 16 is a diagram showing pass characteristics of the dielectric waveguide filter 1G. As shown in FIG. 16, in the dielectric waveguide filter 1G, attenuation poles are formed on the low frequency side and the high frequency side of the pass band, respectively. Therefore, the insertion loss outside the pass band is large, and the steepness on the low frequency side and the high frequency side of the pass band is improved.

[3-2. Effect]
The dielectric waveguide filter 1G according to the present embodiment transmits a signal propagated between the first input / output electrode 61 and the second input / output electrode 62 via electromagnetic coupling different from that of the input / output path P1. Bypass path B1 is provided. The signal propagating through the bypass path B1 and the signal propagating through the input / output path P1 have different phases in a frequency band different from the pass band of the dielectric waveguide filter 1G.

As described above, in the dielectric waveguide filter 1G, by changing the phase of the signal of the bypass path B1 with respect to the input / output path P1, a signal having a predetermined frequency can be canceled and a plurality of attenuation poles can be formed. it can. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

The bypass path B1 of the dielectric waveguide filter 1G is a path having the electromagnetic coupling of the resonators 11 and 13, unlike the electromagnetic coupling of the resonators 21 and 23 on the input / output path P1. As described above, the bypass path B1 has electromagnetic coupling different from that of the input / output path P1, so that a plurality of attenuation poles can be formed.

In the dielectric waveguide filter 1G, the electromagnetic coupling of the resonators 21 and 23 adjacent in the X direction in the input / output path P1 is defined as a sixth coupling, and the resonator 11 adjacent in the X direction in the bypass path B1 When the electromagnetic coupling of 13 is the seventh coupling, the sixth coupling is one of the magnetic field coupling and the electric field coupling, and the seventh coupling is different from one of the magnetic field coupling and the electric field coupling. The other. As described above, the sixth coupling is an electromagnetic field coupling different from the seventh coupling, whereby a plurality of attenuation poles can be formed. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

[3-3. Modification 1 and Modification 2 of Embodiment 3]
FIG. 17A is an exploded perspective view of a dielectric waveguide filter 1H according to Modification 1 of Embodiment 3.

In the dielectric waveguide filter 1H according to the modified example 1, the resonators 12 and 14 adjacent in the X direction on the bypass path B1 are electromagnetically coupled.

Specifically, the resonators 21 and 23 in the input / output path P1 are magnetically coupled to each other, and the resonators 12 and 14 in the bypass path B1 are electrically coupled to each other. As a result, the signal phases of the input / output path P1 and the bypass path B1 are different from each other by 180 °.

FIG. 17B is an exploded perspective view of the dielectric waveguide filter 1I according to the second modification of the third embodiment.

In the dielectric waveguide filter 1I according to the modified example 2, the resonators 22 and 24 adjacent in the X direction on the bypass path B1 are electromagnetically coupled.

Specifically, the resonators 21 and 23 in the input / output path P1 are magnetically coupled to each other, and the resonators 22 and 24 in the bypass path B1 are electrically coupled to each other. As a result, the signal phases of the input / output path P1 and the bypass path B1 are different from each other by 180 °.

In this way, in each dielectric waveguide filter 1H, 1I, the signal of the bypass path B1 is made different in phase with respect to the input / output path P1, thereby canceling a signal of a predetermined frequency and forming a plurality of attenuation poles. can do. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

[3-4. Modification Example 3, Modification Example 4, Modification Example 5 of Embodiment 3]
FIG. 18A is an exploded perspective view of a dielectric waveguide filter 1J according to Modification 3 of Embodiment 3.

The dielectric waveguide filter 1J according to the modification 3 has a basic configuration of the dielectric waveguide filter 1B according to the modification 2 of the first embodiment, further includes a bypass path B1, and has an X direction on the bypass path B1. The resonators 11 and 13 adjacent to each other are electromagnetically coupled.

Specifically, the resonators 11 and 21 and the resonators 21 and 13 in the input / output path P1 are magnetically coupled to each other, and the resonators 11 and 13 in the bypass path B1 are electrically coupled to each other. As a result, the signal phases of the input / output path P1 and the bypass path B1 are different from each other by 180 °.

FIG. 18B is an exploded perspective view of a dielectric waveguide filter 1K according to Modification 4 of Embodiment 3.

The dielectric waveguide filter 1K according to the modification 4 has a basic configuration of the dielectric waveguide filter 1C according to the modification 3 of the first embodiment and further includes a bypass path B1, and the X-direction on the bypass path B1. The resonators 11 and 13 adjacent to each other are electromagnetically coupled.

Specifically, the resonators 11 and 21 and the resonators 21 and 13 in the input / output path P1 are magnetically coupled to each other, and the resonators 11 and 13 in the bypass path B1 are electrically coupled to each other. As a result, the signal phases of the input / output path P1 and the bypass path B1 are different from each other by 180 °.

Thus, by making the phase of the signal of the bypass path B1 different from the dielectric waveguide filters 1J and 1K and the input / output path P1, a plurality of attenuation poles can be formed. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased. Further, each of the dielectric waveguide filters 1J and 1K is described in Patent Document 2 because, when the signal path is bypassed, one resonator (for example, the resonator 21) may be skipped and electromagnetically coupled. Compared with the waveguide filter, it is possible to increase the degree of freedom of the places where electromagnetic coupling is performed in each dielectric waveguide filter 1J, 1K, and to improve the degree of freedom of selection of the signal path.

In addition, each dielectric waveguide filter 1J, 1K according to Modifications 3 and 4 includes a first resonator group 10 including a plurality of first resonators 11 and 13 arranged along a predetermined plane, and a predetermined plane. And a second resonator group 20 including a second resonator 21 disposed on the first resonator group 10 in a vertical direction perpendicular to the first resonator group 10. Each of the first resonators 11 and 13 and the second resonator 21 is formed by dielectric blocks 51a, 51b, and 51c. Then, two or more combinations (resonators 11 and 13) among the combinations of at least one first resonator of the plurality of first resonators 11 and 13 and the second resonator 21 that overlap in the vertical direction. 21 and resonators 21 and 13), which are electromagnetically coupled to each other and are adjacent to each other along a predetermined plane, and a combination of at least two first resonators among a plurality of first resonators 11 and 13 (Resonators 11 and 13) are electromagnetically coupled to each other.

As described above, since the second resonator 21 is disposed on the first resonator group 10, it is possible to perform electromagnetic field coupling in the X direction and the vertical direction (Z direction) along a predetermined plane. The degree of freedom of coupling can be increased, and the degree of freedom of selection of signal paths can be improved. In addition, in this configuration, since it is possible to perform electromagnetic field coupling on both the upper and lower surfaces and between the side surfaces, the degree of freedom in selecting the signal path in each dielectric waveguide filter 1J, 1K is increased. Can do.

FIG. 18C is an exploded perspective view of a dielectric waveguide filter 1L according to Modification 5 of Embodiment 3.

The dielectric waveguide filter 1L according to the modification 5 has the basic configuration of the dielectric waveguide filter 1D according to the modification 4 of the first embodiment, further includes a bypass path B1, and has an X direction on the bypass path B1. The resonators 11 and 13 adjacent to each other are electromagnetically coupled on the bypass path B1.

Specifically, the resonators 21 and 23 in the input / output path P1 are magnetically coupled to each other, and the resonators 11 and 13 in the bypass path B1 are electrically coupled to each other. As a result, the signal phases of the input / output path P1 and the bypass path B1 are different from each other by 180 °.

Thus, in each dielectric waveguide filter 1L, a plurality of attenuation poles can be formed by making the signal phase of the bypass path B1 different from the input / output path P1. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased. In addition, the degree of freedom in selecting a signal path can be improved by increasing the degree of freedom of the electromagnetic wave coupling portion in the dielectric waveguide filter 1L.

In addition, each dielectric waveguide filter 1L according to Modification 5 includes a first resonator group 10 including a plurality of first resonators 11 and 13 arranged along a predetermined plane, and upper and lower portions perpendicular to the predetermined plane. And a second resonator group 20 including a plurality of second resonators 21 and 23 arranged on the first resonator group 10 in the direction. Each of the first resonators 11 and 13 and the second resonators 21 and 23 is formed by dielectric blocks 51a, 51b, 51c, and 51d. And at least one first resonator among the plurality of first resonators 11 and 13, and at least one second resonator among the one or more second resonators 21 and 23, which overlap in the vertical direction, Among the combinations, a plurality of first resonators 11 that are electromagnetically coupled to each other and are adjacent to each other along a predetermined plane in at least two combinations ( resonators 11, 21 and resonators 23, 13). In a combination (resonators 11 and 13) in which at least two first resonators of 13 are combined, each of them is electromagnetically coupled to each other.

As described above, since the second resonator 21 is disposed on the first resonator group 10, it is possible to perform electromagnetic field coupling in the X direction and the vertical direction (Z direction) along a predetermined plane. The degree of freedom of coupling can be increased, and the degree of freedom of selection of signal paths can be improved. Further, in this configuration, it is possible to perform electromagnetic field coupling on both the upper and lower surfaces and the side surfaces, so that the degree of freedom in selecting a signal path in the dielectric waveguide filter 1L can be increased.

(Embodiment 4)
[4-1. Configuration of Dielectric Waveguide Filter]
FIG. 19 is an exploded perspective view of a dielectric waveguide filter 1M according to the fourth embodiment.

In the dielectric waveguide filter 1M according to the fourth exemplary embodiment, the resonators 11 and 13 adjacent in the X direction on the bypass path B1 are electromagnetically coupled.

Specifically, the resonators 21 and 23 in the input / output path P1 are electrically coupled to each other, and the resonators 11 and 13 in the bypass path B1 are magnetically coupled to each other. As a result, the signal phases of the input / output path P1 and the bypass path B1 are different from each other by 180 °.

FIG. 20 is a diagram showing the pass characteristics of the dielectric waveguide filter 1M. As shown in FIG. 20, in the dielectric waveguide filter 1M, attenuation poles are formed on the low frequency side and the high frequency side of the pass band, respectively. Therefore, the insertion loss outside the pass band is large, and the steepness on the low frequency side and the high frequency side of the pass band is improved.

[4-2. Effect]
The dielectric waveguide filter 1M according to the present embodiment transmits a signal propagated between the first input / output electrode 61 and the second input / output electrode 62 via electromagnetic coupling different from that of the input / output path P1. Bypass path B1 is provided. The signal propagating through the bypass path B1 and the signal propagating through the input / output path P1 have different phases in a frequency band different from the pass band of the dielectric waveguide filter 1M.

In this way, in the dielectric waveguide filter 1M, by changing the phase of the signal of the bypass path B1 with respect to the input / output path P1, a signal having a predetermined frequency can be canceled and a plurality of attenuation poles can be formed. it can. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

[4-3. Modification 1 and Modification 2 of Embodiment 4]
FIG. 21A is an exploded perspective view of a dielectric waveguide filter 1N according to Modification 1 of Embodiment 4.

In the dielectric waveguide filter 1N according to the modified example 1, the resonators 12 and 14 adjacent in the X direction on the bypass path B1 are electromagnetically coupled.

Specifically, the resonators 21 and 23 in the input / output path P1 are electrically coupled to each other, and the resonators 12 and 14 in the bypass path B1 are magnetically coupled to each other. As a result, the signal phases of the input / output path P1 and the bypass path B1 are different from each other by 180 °.

FIG. 21B is an exploded perspective view of the dielectric waveguide filter 1O according to the second modification of the fourth embodiment.

In the dielectric waveguide filter 1O according to the modified example 2, the resonators 22 and 24 adjacent in the X direction on the bypass path B1 are electromagnetically coupled.

Specifically, the resonators 21 and 23 in the input / output path P1 are electrically coupled to each other, and the resonators 22 and 24 in the bypass path B1 are magnetically coupled to each other. As a result, the signal phases of the input / output path P1 and the bypass path B1 are different from each other by 180 °.

Thus, in each dielectric waveguide filter 1N, 1O, a plurality of attenuation poles can be formed by making the phase of the signal of the bypass path B1 different from the input / output path P1. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

(Embodiment 5)
[5-1. Configuration of Dielectric Waveguide Filter]
FIG. 22 is an exploded perspective view of a dielectric waveguide filter 1P according to the fifth embodiment.

In the dielectric waveguide filter 1P according to the fifth embodiment, the resonators 12 and 14 adjacent in the X direction on the bypass path B1 are electromagnetically coupled, and the resonator 22 adjacent in the X direction on the bypass path B2 24 is electromagnetically coupled.

Specifically, the resonators 21 and 23 in the input / output path P1 are electrically coupled to each other, the resonators 12 and 14 in the bypass path B1 are magnetically coupled to each other, and the resonators 22 and 24 in the bypass path B2 are electrically coupled to each other. .

FIG. 23 is a diagram showing pass characteristics of the dielectric waveguide filter 1P. As shown in FIG. 23, in the dielectric waveguide filter 1P, attenuation poles are formed on the low frequency side and the high frequency side of the pass band, respectively. Therefore, the insertion loss outside the pass band is large, and the steepness on the low frequency side and the high frequency side of the pass band is improved.

[5-2. Effect]
The dielectric waveguide filter 1P according to the present embodiment transmits a signal propagated between the first input / output electrode 61 and the second input / output electrode 62 through electromagnetic field coupling different from that of the input / output path P1. Bypass paths B1 and B2 are provided. The signal propagating through the bypass paths B1 and B2 and the signal propagating through the input / output path P1 have different phases in a frequency band different from the pass band of the dielectric waveguide filter 1P.

As described above, in the dielectric waveguide filter 1P, by changing the phase of the signals of the bypass paths B1 and B2 with respect to the input / output path P1, a signal having a predetermined frequency is canceled and a plurality of attenuation poles are formed. be able to. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

(Embodiment 6)
[6-1. Configuration of Dielectric Waveguide Filter]
FIG. 24 is an exploded perspective view of a dielectric waveguide filter 1Q according to the sixth embodiment.

The dielectric waveguide filter 1Q according to the sixth embodiment has the basic configuration of the dielectric waveguide filter 1 according to the first embodiment, and further, resonators 12 and 14 adjacent in the X direction on the bypass path B1. Are electromagnetically coupled, and the resonators 22 and 24 adjacent in the X direction on the bypass path B2 are electromagnetically coupled.

Specifically, the resonators 21 and 23 in the input / output path P1 are magnetically coupled to each other, the resonators 12 and 14 in the bypass path B1 are magnetically coupled to each other, and the resonators 22 and 24 in the bypass path B2 are electrically coupled to each other. .

FIG. 25 is a diagram showing pass characteristics of the dielectric waveguide filter 1Q. As shown in FIG. 25, in the dielectric waveguide filter 1Q, an attenuation pole is formed on the low frequency side of the pass band. Therefore, the insertion loss outside the pass band is large and the steepness on the low frequency side of the pass band is improved.

[6-2. Effect]
The dielectric waveguide filter 1Q according to the present embodiment transmits a signal propagated between the first input / output electrode 61 and the second input / output electrode 62 via electromagnetic coupling different from that of the input / output path P1. Bypass paths B1 and B2 are provided. The signal propagating through the bypass paths B1 and B2 and the signal propagating through the input / output path P1 have different phases in a frequency band different from the pass band of the dielectric waveguide filter 1Q.

As described above, in the dielectric waveguide filter 1Q, the signals of the bypass paths B1 and B2 are made different in phase with respect to the input / output path P1, thereby canceling a signal of a predetermined frequency and forming a plurality of attenuation poles. be able to. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

[6-3. Modification 1 of Embodiment 6]
FIG. 26 is an exploded perspective view of a dielectric waveguide filter 1R according to the first modification of the sixth embodiment.

The dielectric waveguide filter 1R according to the first modification has the basic configuration of the dielectric waveguide filter 1A according to the first modification of the first embodiment, and further, the resonator 12 adjacent in the X direction on the bypass path B1. , 14 are electromagnetically coupled, and the resonators 22 and 24 adjacent in the X direction on the bypass path B2 are electromagnetically coupled.

Specifically, the resonators 21 and 23 in the input / output path P1 are magnetically coupled to each other, the resonators 12 and 14 in the bypass path B1 are magnetically coupled to each other, and the resonators 22 and 24 in the bypass path B2 are electrically coupled to each other. .

As described above, in the dielectric waveguide filter 1R, by changing the phase of the signals of the bypass paths B1 and B2 with respect to the input / output path P1, a signal having a predetermined frequency is canceled and a plurality of attenuation poles are formed. be able to. By forming these attenuation poles in a specific frequency band different from the pass band, the insertion loss outside the pass band can be increased.

(Embodiment 7)
FIG. 27A is a perspective view of a dielectric waveguide filter 1S according to Embodiment 7. FIG. 27B is an exploded perspective view of the dielectric waveguide filter 1S. The dielectric waveguide filter 1S according to the seventh embodiment has a three-layer laminated structure.

The dielectric waveguide filter 1S includes a first resonator group 10, a second resonator group 20 disposed on the first resonator group 10, and a third resonance disposed on the second resonator group 20. The instrument group 30 is provided. The first resonator group 10 includes four first resonators 11, 12, 13, and 14, and the second resonator group 20 includes four second resonators 21, 22, 23, and 24. The third resonator group 30 has four third resonators 31, 32, 33, and 34.

The two resonators 12 and 22 and the resonators 24 and 14 each having the first resonator and the second resonator overlapping in the vertical direction are electromagnetically coupled to each other in the vertical direction. Two combinations of the resonators 21 and 31 and the resonators 33 and 23 each including the overlapping second resonator and third resonator are electromagnetically coupled to each other.

Specifically, the dielectric waveguide filter 1S converts the signal input to the first input / output electrode 61 into the resonators 11, 12, 22, 21, 31, 32, 34, 33, 23, 24, 14 , 13 in order, and an input / output path P1 for outputting from the second input / output electrode 62 is provided.

As described above, the dielectric waveguide filter 1S has a laminated structure including the first resonator group 10, the second resonator group 20, and the third resonator group 30, so that the area of the dielectric waveguide filter 1S is increased. Can be reduced.

FIG. 28 is a block diagram showing a part of the circuit configuration of the dielectric waveguide filter 1T according to the first modification of the seventh embodiment.

In the dielectric waveguide filter 1T according to the first modification, the resonators 21 and 22 and the resonators 22 and 24 are electromagnetically coupled to each other on the input / output path P1, and the resonator is on the bypass path B1. 22 and 12 are electromagnetically coupled to each other, and the resonators 22 and 32 are electromagnetically coupled to each other on the bypass path B2.

As described above, the dielectric waveguide filter 1T has a laminated structure of three or more layers. For example, the resonators 22 and 12 that overlap vertically and the resonators 22 and 32 that overlap vertically are electromagnetically coupled. And the degree of freedom of electromagnetic field coupling can be improved.

(Embodiment 8)
Next, the structure of the dielectric waveguide filter 1U according to Embodiment 8 will be described. FIG. 29 is an exploded perspective view of the dielectric waveguide filter 1U.

The dielectric waveguide filter 1U includes a first resonator group 10 and a second resonator group 20 disposed on the first resonator group 10. The first resonator group 10 includes three first resonators 11, 12, and 13, and the second resonator group 20 includes three second resonators 21, 22, and 23. Hereinafter, the first resonators 11, 12, 13, and the second resonators 21, 22, 23 may be referred to as the resonators 11, 12, 13, 21, 22, 23, respectively.

The resonator 11 as the input stage is provided with a first input / output electrode 61 (see FIG. 1B) to which a high frequency signal is input. The resonator 13 which is an output stage is provided with a second input / output electrode 62 (see FIG. 1B) from which a high-frequency signal input from the first input / output electrode 61 is output. A ground electrode 65 is provided in a region different from the region where the first input / output electrode 61 and the second input / output electrode 62 are provided on the surfaces of the resonators 11 to 13 and 21 to 23.

Further, the dielectric waveguide filter 1U includes a mounting substrate 70. On the mounting substrate 70, input / output patterns 71 and 72 and a ground pattern 75 corresponding to the first input / output electrode 61, the second input / output electrode 62, and the ground electrode 65 are formed.

The first resonator group 10 is disposed on the mounting substrate 70 such that the surface (lower surface) opposite to the surface (upper surface) on which the second resonators 21 to 23 are disposed faces the main surface 70a of the mounting substrate 70. It is joined. Specifically, the first input / output electrode 61 and the input / output pattern 71, the second input / output electrode 62 and the input / output pattern 72, and the ground electrode 65 and the ground pattern 75 are joined by a conductive joining material such as solder. ing.

The resonators 11 to 13 and 21 to 23 have the following arrangement relationship. Specifically, the resonators 11 to 13 are arranged along a predetermined plane (a plane including the main surface 70a of the mounting substrate 70). As shown in FIG. 29, the resonators 11 and 12 are adjacent to each other in the Y direction, and the resonators 11 and 13 are adjacent to each other in the X direction. The resonators 21 and 22 are adjacent to each other in the Y direction, and the resonators 21 and 23 are adjacent to each other in the X direction. In addition, each of the resonators 21, 22, and 23 is disposed on the first resonator group 10 so as to correspond to each of the resonators 11, 12, and 13, and each of the resonators 11, 12, and 13 is in the Z direction. Overlap each other.

The resonators 11 and 12 are formed by the dielectric block 51a, the resonator 13 is formed by the dielectric block 51b, the resonators 21 and 22 are formed by the dielectric block 51c, and the resonator 23 is formed by the dielectric block 51d. Has been.

The resonators 11 to 13 and 21 to 23 have a rectangular parallelepiped shape, and have an upper surface f1, a lower surface f2, and a side surface f3. In addition, each of the resonators 11 and 12 and the resonators 21 and 22 has a connection surface f4. When attention is paid to the resonator 21, the three surfaces of the resonator 21, the connection surface f4, the side surface f3, and the lower surface f2, are orthogonal to each other.

For example, the resonators 21 and 22 are electromagnetically coupled to each other via the coupling surface f4. The connection surface f4 is a boundary surface between the resonator 21 and the resonator 22, and specifically, is a cross section of a portion connecting the resonator 21 and the resonator 22. The connecting surface f4 is formed by providing a groove near the center in the longitudinal direction (Y direction) of the dielectric block 51c, for example.

The first resonator group 10 is formed by joining the opposing side surfaces of the dielectric blocks 51a and 51b using a conductive paste. The second resonator group 20 is formed by joining the opposing side surfaces of the dielectric blocks 51c and 51d using a conductive paste. The dielectric waveguide filter 1U is formed by joining the upper surface of the first resonator group 10 and the lower surface of the second resonator group 20 using a conductive paste.

The dielectric waveguide filter 1U has electromagnetic field coupling in the main path C1 and electromagnetic field coupling in the sub path C2 different from the main path C1. The electromagnetic field coupling in the main path C1 is formed by the resonators 11 and 12, the resonators 12 and 22, the resonators 22 and 21, the resonators 21 and 23, or the resonators 23 and 13. It is a bond. The electromagnetic field coupling in the sub path C2 is coupling formed between the resonators 11 and 21.

The coupling formed by the resonators 11 and 21 in the sub path C2 is weaker than the coupling formed by the resonators 12 and 22 in the main path C1. Further, the coupling formed by the resonators 11 and 21 in the sub path C2 is weaker than the coupling in any resonator in the main path C1.

Here, the electromagnetic field coupling in the main path C1 will be described.

When a signal having a predetermined frequency is input from the first input / output electrode 61, the resonator 11 resonates, and an electric field directed in the Z direction and a magnetic field surrounding an axis in the Z direction are generated in the resonator 11. At that time, the electric field is strongly generated at the center of the resonator 11, and the magnetic field is strongly generated along the outer peripheral side surface of the resonator 11.

At the boundary between the resonator 11 and the resonator 12, the connecting surface f4 described above is provided. Therefore, a magnetic field is generated in the resonator 12 so as to be coupled with the magnetic field generated in the resonator 11, and an electric field is generated in the resonator 12 along with the generated magnetic field.

A coupling portion 56 (see FIG. 2C) is provided at the center of each of the upper surface f1 of the resonator 12 and the lower surface f2 of the resonator 22. Therefore, an electric field is generated in the resonator 22 so as to be coupled with the electric field generated in the resonator 12, and a magnetic field is generated in the resonator 22 along with the generated electric field.

A connecting surface f4 is provided between the resonator 22 and the resonator 21, and the resonators 22 and 21 are magnetically coupled to each other. Further, a coupling portion 56 (see FIG. 2B) is provided between the resonator 21 and the resonator 23, and the resonators 21 and 23 are magnetically coupled to each other. Furthermore, the resonator 23 and the resonator 13 are electrically coupled to each other by a coupling portion 56 (see FIG. 2C) provided therebetween.

Next, electromagnetic field coupling in the sub route C2 will be described.

A coupling portion 56 (see FIG. 7) is provided on the upper surface f1 of the resonator 11 and the lower surface f2 of the resonator 21. Therefore, a magnetic field is generated in the resonator 21 so as to be coupled with the magnetic field generated in the resonator 11. The coupling coefficient between the resonators 11 and 21 in the sub path C2 is smaller than the coupling coefficient between the resonators 12 and 22 in the main path C1, and is smaller than the coupling coefficient between any resonators in the main path C1.

The dielectric waveguide filter 1U of the eighth embodiment is a path connecting the input stage resonator 11 and the output stage resonator 13 and is formed by a main path C1 formed by electromagnetic coupling and the main path C1. Has a sub-path C2 having weak electromagnetic coupling. Among the resonators 11 to 13 and the resonators 21 to 23, a predetermined resonator (for example, the resonator 21) has other three resonators 22 and 23 on three surfaces (coupling surface f4, side surface f3, and bottom surface f2) orthogonal to each other. , 11 is adjacent. The predetermined resonator 21 is electromagnetically coupled with the other resonators 22, 23, 11 adjacent on the three surfaces, and the electromagnetic coupling on the three surfaces is performed by the main path C <b> 1 and the sub-path C <b> 2. Part of the path.

Since the dielectric waveguide filter 1U has the above-described configuration, it is possible to obtain steep attenuation due to the polar characteristics without increasing the mounting area of the dielectric waveguide filter 1U.

Although the dielectric waveguide filter 1U including the three first resonators 11 to 13 and the three second resonators 21 to 23 is shown in the eighth embodiment, the number of resonators is limited to that. I can't. The dielectric waveguide filter 1U includes two or more first resonators as the first resonator group 10, and includes two or more second resonators as the second resonator group 20, and the first resonator and the first resonator The total of the second resonators may be 6 or more. In addition, it is sufficient that at least one predetermined resonator that is electromagnetically coupled to another adjacent resonator exists in the dielectric waveguide filter 1U.

(Embodiment 9)
Next, the structure of the dielectric waveguide filter 1V according to Embodiment 9 will be described. FIG. 30 is an exploded perspective view of the dielectric waveguide filter 1V.

The dielectric waveguide filter 1 </ b> V includes a first resonator group 10 and a second resonator group 20 arranged on the first resonator group 10. The first resonator group 10 has four first resonators 11, 12, 13, and 14, and the second resonator group 20 has two second resonators 22 and 24. Hereinafter, the first resonators 11, 12, 13, 14 and the second resonators 22, 24 may be referred to as resonators 11, 12, 13, 14, 22, 24, respectively.

The resonator 11 as the input stage is provided with a first input / output electrode 61 (see FIG. 1B) to which a high frequency signal is input. The resonator 13 which is an output stage is provided with a second input / output electrode 62 (see FIG. 1B) from which a high-frequency signal input from the first input / output electrode 61 is output. A ground electrode 65 is provided in a region different from the region in which the first input / output electrode 61 and the second input / output electrode 62 are provided on the surfaces of the resonators 11 to 14, 22, and 24.

The resonators 11 to 14, 22, and 24 have the following arrangement relationship. Specifically, the resonators 11 to 14 are arranged along a predetermined plane (a plane including the main surface 70a of the mounting substrate 70). As shown in FIG. 30, the resonators 11 and 12 are adjacent in the Y direction, the resonators 13 and 14 are adjacent in the Y direction, the resonators 11 and 13 are adjacent in the X direction, and the resonators 12 and 14 are in the Y direction. Adjacent to the direction. The resonators 22 and 24 are adjacent to each other in the X direction. Each of the resonators 22 and 24 is arranged on the first resonator group 10 so as to correspond to each of the resonators 12 and 14 and overlaps each of the resonators 12 and 14 in the Z direction.

The resonators 11 and 12 are formed by a dielectric block 51a, the resonator 13 is formed by a dielectric block 51b, and the resonators 22 and 24 are formed by a dielectric block 51c.

Each of the resonators 11 to 14, 21, and 24 has a rectangular parallelepiped shape, and has an upper surface f1, a lower surface f2, and a side surface f3. In addition, each of the resonators 11 and 12, the resonators 13 and 14, and the resonators 22 and 24 has a coupling surface f4. When attention is paid to the resonator 12, the three surfaces of the resonator 12, the coupling surface f4, the upper surface f1, and the side surface f3, are orthogonal to each other. When attention is paid to the resonator 14, the top surface f1, the connecting surface f4, and the side surface f3 of the resonator 14 are orthogonal to each other.

For example, the resonators 11 and 12 are electromagnetically coupled to each other via the coupling surface f4. The connection surface f4 is a boundary surface between the resonator 11 and the resonator 12, and specifically, is a cross section of a portion connecting the resonator 11 and the resonator 12. The connecting surface f4 is formed, for example, by providing a groove near the center in the longitudinal direction (Y direction) of the dielectric block 51a.

The first resonator group 10 is formed by joining the opposing side surfaces of the dielectric blocks 51a and 51b using a conductive paste. The second resonator group 20 is formed by one dielectric block 51c. The dielectric waveguide filter 1V is formed by joining the lower surface of the second resonator group 20 and the upper surface of the first resonator group 10 using a conductive paste.

The dielectric waveguide filter 1V has electromagnetic field coupling in the main path C1 and electromagnetic field coupling in the sub path C2 different from the main path C1. The electromagnetic field coupling in the main path C1 is formed by the resonators 11 and 12, the resonators 12 and 22, the resonators 22 and 24, the resonators 24 and 14, or the resonators 14 and 13. It is a bond. The electromagnetic field coupling in the sub path C2 is a coupling formed between the resonators 12 and 14.

The coupling formed by the resonators 12 and 14 in the sub-path C2 is weaker than the coupling formed by the resonators 22 and 24 in the main path C1. Further, the coupling formed by the resonators 12 and 14 in the sub path C2 is weaker than the coupling in any resonator in the main path C1.

Here, the electromagnetic field coupling in the main path C1 will be described.

When a signal having a predetermined frequency is input from the first input / output electrode 61, the resonator 11 resonates, and an electric field directed in the Z direction and a magnetic field surrounding an axis in the Z direction are generated in the resonator 11. At that time, the electric field is strongly generated at the center of the resonator 11, and the magnetic field is strongly generated along the outer peripheral side surface of the resonator 11.

The connecting surface f4 described above is provided at the boundary between the resonator 11 and the resonator 12. Therefore, a magnetic field is generated in the resonator 12 so as to be coupled with the magnetic field generated in the resonator 11, and an electric field is generated in the resonator 12 along with the generated magnetic field.

A coupling portion 56 (see FIG. 2C) is provided at the center of each of the upper surface f1 of the resonator 12 and the lower surface f2 of the resonator 22. Therefore, an electric field is generated in the resonator 22 so as to be coupled with the electric field generated in the resonator 12, and a magnetic field is generated in the resonator 22 along with the generated electric field.

A connecting surface f4 is provided between the resonator 22 and the resonator 24, and the resonators 22 and 24 are magnetically coupled to each other. In addition, a coupling portion 56 (see FIG. 2C) is provided between the resonator 24 and the resonator 14, and the resonators 24 and 14 are electrically coupled to each other. Furthermore, the resonator 14 and the resonator 13 are magnetically coupled to each other via the coupling surface f4.

Next, electromagnetic field coupling in the sub route C2 will be described.

A coupling portion 56 (see FIG. 5B) is provided on each side surface f3 located between the resonator 12 and the resonator 14, and the resonators 12 and 14 are electrically coupled to each other. The coupling coefficient between the resonators 12 and 14 in the sub path C2 is smaller than the coupling coefficient between the resonators 22 and 24 in the main path C1, and is smaller than the coupling coefficient between any resonators in the main path C1.

The dielectric waveguide filter 1V according to the eighth embodiment is a path connecting the input stage resonator 11 and the output stage resonator 13 and is formed by electromagnetic coupling and the main path C1. Has a sub-path C2 having weak electromagnetic coupling. Among the resonators 11 to 14 and the resonators 22 and 24, a predetermined resonator (for example, the resonator 12) has other three resonators 11 and 22 on three surfaces (coupling surface f4, upper surface f1, and side surface f3) orthogonal to each other. , 14 is adjacent. The predetermined resonator 12 is electromagnetically coupled with the other resonators 11, 22, and 14 adjacent on the three surfaces, and the electromagnetic coupling on the three surfaces is performed by the main path C <b> 1 and the sub-path C <b> 2. Part of the path.

Further, a predetermined resonator (for example, the resonator 14) different from the resonator 12 is adjacent to the other resonators 24, 13, and 12 on three surfaces (upper surface f1, connecting surface f4, and side surface f3) orthogonal to each other. . The predetermined resonator 14 is electromagnetically coupled with the other resonators 24, 13, and 12 adjacent on the three surfaces. The electromagnetic field coupling on the three surfaces is the main path C <b> 1 and the sub-path C <b> 2. Part of the path.

Since the dielectric waveguide filter 1V has the above-described configuration, it is possible to obtain steep attenuation due to the polar characteristics without increasing the mounting area of the dielectric waveguide filter 1V.

In the ninth embodiment, the dielectric waveguide filter 1V including the four first resonators 11 to 14 and the two second resonators 22 and 24 is shown. However, the number of resonators is limited to that. I can't. The dielectric waveguide filter 1V includes two or more first resonators as the first resonator group 10, and two or more second resonators as the second resonator group 20, and the first resonator and the first resonator The total of the second resonators may be 6 or more. In addition, it is sufficient that at least one predetermined resonator that is electromagnetically coupled to another adjacent resonator exists in the dielectric waveguide filter 1V.

(Embodiment 10)
Next, the structure of the dielectric waveguide filter 1W according to the tenth embodiment will be described. FIG. 31 is an exploded perspective view of the dielectric waveguide filter 1W according to the tenth embodiment.

The dielectric waveguide filter 1 </ b> W includes a first resonator group 10 and a second resonator group 20 disposed on the first resonator group 10. The first resonator group 10 has four resonators 11, 12, 13 and 14, and the second resonator group 20 has four resonators 21, 22, 23 and 24.

The resonator 11 as the input stage is provided with a first input / output electrode 61 (see FIG. 1B) to which a high frequency signal is input. The resonator 13 which is an output stage is provided with a second input / output electrode 62 (see FIG. 1B) from which a high-frequency signal input from the first input / output electrode 61 is output. A ground electrode 65 is provided in a region different from the region where the first input / output electrode 61 and the second input / output electrode 62 are provided on the surfaces of the resonators 11 to 14 and 21 to 24.

The resonators 11 to 14 and 21 to 24 have the following arrangement relationship. Specifically, the resonators 11 to 14 are arranged in a matrix along a predetermined plane (a plane including the main surface 70a of the mounting substrate 70). As shown in FIG. 31, resonators 11 and 12 are adjacent in the Y direction, resonators 13 and 14 are adjacent in the Y direction, resonators 11 and 13 are adjacent in the X direction, and resonators 12 and 14 are in X direction. Adjacent to the direction. The resonators 21 and 22 are adjacent in the Y direction, the resonators 23 and 24 are adjacent in the Y direction, the resonators 21 and 23 are adjacent in the X direction, and the resonators 22 and 24 are adjacent in the X direction. Each of the resonators 21 to 24 is arranged in a matrix on the first resonator group 10 so as to correspond to each of the resonators 11 to 14, and overlaps each of the resonators 11 to 14 in the Z direction. ing.

The resonators 11 and 12 are formed by a dielectric block 51a, the resonators 13 and 14 are formed by a dielectric block 51b, the resonators 21 and 22 are formed by a dielectric block 51c, and the resonators 23 and 24 are dielectrics. It is formed by the block 51d.

The resonators 11 to 14 and 21 to 24 have a rectangular parallelepiped shape and have an upper surface f1, a lower surface f2, and a side surface f3. Further, each of the resonators 11 to 14 and 21 to 24 has a connecting surface f4. When attention is paid to the resonator 21, the three surfaces of the resonator 21, the connection surface f4, the side surface f3, and the lower surface f2, are orthogonal to each other.

For example, the resonators 21 and 22 are electromagnetically coupled to each other via the coupling surface f4. The connection surface f4 is a boundary surface between the resonator 21 and the resonator 22, and specifically, is a cross section of a portion connecting the resonator 21 and the resonator 22. The connecting surface f4 is formed by providing a groove near the center in the longitudinal direction (Y direction) of the dielectric block 51c, for example.

The first resonator group 10 is formed by joining the opposing side surfaces of the dielectric blocks 51a and 51b using a conductive paste. The second resonator group 20 is formed by joining the opposing side surfaces of the dielectric blocks 51c and 51d using a conductive paste. The dielectric waveguide filter 1W is formed by joining the upper surface of the first resonator group 10 and the lower surface of the second resonator group 20 using a conductive paste.

The dielectric waveguide filter 1W has electromagnetic field coupling in the main path C1 and electromagnetic field coupling in the sub path C2 different from the main path C1. The electromagnetic field coupling in the main path C1 includes resonators 11 and 12, resonators 12 and 22, resonators 22 and 21, resonators 21 and 23, resonators 23 and 24, resonators 23 and 24, and resonators 24 and 14 Or a coupling formed by the resonators 14 and 13. The electromagnetic field coupling in the sub path C2 is a coupling formed by the resonators 11 and 21, the resonators 22 and 24, or the resonators 23 and 13.

The coupling formed by the resonators 11 and 21 in the sub path C2 is weaker than the coupling formed by the resonators 12 and 22 in the main path C1. The coupling formed by the resonators 22 and 24 in the sub path C2 is weaker than the coupling formed by the resonators 21 and 23 in the main path C1. The coupling formed by the resonators 23 and 13 in the sub path C2 is weaker than the coupling formed by the resonators 24 and 14 in the main path C1. In addition, the coupling formed by the resonators 11 and 21 in the sub path C2, the resonators 22 and 24, and the resonators 23 and 13 is weaker than the coupling in any resonator in the main path C1.

Here, the electromagnetic field coupling in the main path C1 will be described. FIG. 32 is a diagram showing the types of coupling of the dielectric waveguide filter 1W.

When a signal having a predetermined frequency is input from the first input / output electrode 61, the resonator 11 resonates, and an electric field directed in the Z direction and a magnetic field surrounding an axis in the Z direction are generated in the resonator 11. At that time, the electric field is strongly generated at the center of the resonator 11, and the magnetic field is strongly generated along the outer peripheral side surface of the resonator 11.

The connecting surface f4 described above is provided at the boundary between the resonator 11 and the resonator 12. Therefore, a magnetic field is generated in the resonator 12 so as to be coupled with the magnetic field generated in the resonator 11, and an electric field is generated in the resonator 12 along with the generated magnetic field.

A coupling portion 56 (see FIG. 2C) is provided at the center of each of the upper surface f1 of the resonator 12 and the lower surface f2 of the resonator 22. Therefore, an electric field is generated in the resonator 22 so as to be coupled with the electric field generated in the resonator 12, and a magnetic field is generated in the resonator 22 along with the generated electric field.

A connecting surface f4 is provided between the resonator 22 and the resonator 21, and the resonators 22 and 21 are magnetically coupled to each other. Further, a coupling portion 56 (see FIG. 5B) is provided between the resonator 21 and the resonator 23, and the resonators 21 and 23 are electrically coupled to each other. Further, a coupling surface f4 is provided between the resonator 23 and the resonator 24, and the resonators 23 and 24 are magnetically coupled to each other. The resonator 24 and the resonator 14 are electrically coupled to each other by a coupling portion 56 (see FIG. 2C) provided therebetween. A coupling surface f4 is provided between the resonator 14 and the resonator 13, and the resonators 14 and 13 are magnetically coupled to each other.

Next, electromagnetic field coupling in the sub route C2 will be described.

A coupling portion 56 (see FIG. 7) is provided between the resonator 11 and the resonator 21, and the resonators 11 and 21 are magnetically coupled to each other. The coupling coefficient between the resonators 11 and 21 is smaller than the coupling coefficient between the resonators 12 and 22 in the main path C1, and is smaller than the coupling coefficient between any resonators in the main path C1.

A coupling portion 56 having an opening area smaller than that of the coupling portion 56 shown in FIG. 2B is provided on the side surface f3 between the resonator 22 and the resonator 24, and the resonators 22 and 24 are magnetically coupled to each other. The coupling coefficient between the resonators 22 and 24 is smaller than the coupling coefficient between the resonators 21 and 23 in the main path C1 and smaller than the coupling coefficient between any resonators in the main path C1.

A coupling portion 56 (see FIG. 7) is provided between the resonator 23 and the resonator 13, and the resonators 23 and 13 are magnetically coupled to each other. The coupling coefficient between the resonators 23 and 13 is smaller than the coupling coefficient between the resonators 24 and 14 in the main path C1 and smaller than the coupling coefficient between any resonators in the main path C1.

FIG. 33 is a diagram showing pass characteristics of the dielectric waveguide filter 1W according to the tenth embodiment. As shown in FIG. 33, in the dielectric waveguide filter 1W, the electromagnetic coupling in the sub-path C2 is provided for the electromagnetic coupling in the main path C1, so that the low-frequency side and the high-frequency side of the pass band are provided. Two attenuation poles are formed in each. Therefore, the insertion loss outside the pass band is large, and the steepness on the low frequency side and the high frequency side of the pass band is improved.

The dielectric waveguide filter 1W according to the tenth embodiment is a path connecting the input stage resonator 11 and the output stage resonator 13, which is formed by electromagnetic coupling, and the main path C1. Has a sub-path C2 having weak electromagnetic coupling. Among the resonators 11 to 14 and the resonators 21 to 24, a predetermined resonator (for example, the resonator 21) has other three resonators 22 and 23 on three surfaces (coupling surface f4, side surface f3, and bottom surface f2) orthogonal to each other. , 11 is adjacent. The predetermined resonator 21 is electromagnetically coupled with the other resonators 22, 23, 11 adjacent on the three surfaces, and the electromagnetic coupling on the three surfaces is performed by the main path C <b> 1 and the sub-path C <b> 2. Part of the path.

Further, a predetermined resonator different from the resonator 21 (for example, the resonator 22) is adjacent to the other resonators 12, 21, and 24 on three surfaces (lower surface f2, connecting surface f4, and side surface f3) orthogonal to each other. . The predetermined resonator 22 is electromagnetically coupled with the other resonators 12, 21, and 24 adjacent on the three surfaces, and the electromagnetic coupling on the three surfaces is performed by the main path C <b> 1 and the sub-path C <b> 2. Part of the path.

In addition, a predetermined resonator (for example, the resonator 23) different from the resonators 21 and 22 is adjacent to the other resonators 21, 24, and 13 on three surfaces (side surface f3, connecting surface f4, and lower surface f2) orthogonal to each other. ing. The predetermined resonator 23 is electromagnetically coupled with the other resonators 21, 24, and 13 adjacent on the three surfaces, and the electromagnetic coupling on the three surfaces is performed by the main path C <b> 1 and the sub-path C <b> 2. Part of the path.

Further, a predetermined resonator (for example, the resonator 24) different from the resonators 21 to 23 is adjacent to the other resonators 23, 14, and 22 on three surfaces (coupling surface f4, lower surface f2, and side surface f3) orthogonal to each other. ing. The predetermined resonator 24 is electromagnetically coupled with the other resonators 23, 14, and 22 adjacent on the three surfaces, and the electromagnetic coupling on the three surfaces is performed by the main path C <b> 1 and the sub-path C <b> 2. Part of the path.

Since the dielectric waveguide filter 1W has the above-described configuration, it is possible to obtain steep attenuation due to the polar characteristics without increasing the mounting area of the dielectric waveguide filter 1W.

(Embodiment 11)
In the present embodiment, a high-frequency front end circuit 110 including the dielectric waveguide filter according to the first to tenth embodiments and a communication apparatus 100 including the high-frequency front end circuit 110 will be described.

FIG. 34 is a circuit diagram showing the high-frequency front-end circuit 110 and the communication device 100 according to the eleventh embodiment. In the figure, a high-frequency front-end circuit 110, an antenna element 150, an RF signal processing circuit 191 and a baseband signal processing circuit 192 are shown.

The high-frequency front end circuit 110 includes filters 161, 162, and 163, a switch circuit 170, a power amplifier circuit 181, and a low noise amplifier circuit 182.

The power amplifier circuit 181 is a transmission amplification circuit that amplifies the high-frequency transmission signal output from the RF signal processing circuit 191 and outputs the amplified signal to the antenna element 150 via the switch circuit 170 and the filter 161.

The low noise amplifier circuit 182 is a reception amplification circuit that amplifies a high-frequency signal that has passed through the antenna element 150, the filter 161, and the switch circuit 170 and outputs the amplified signal to the RF signal processing circuit 191.

The filter 161 is an antenna filter that is connected to the antenna element 150 and selectively allows high-frequency signals in the transmission band and the reception band to pass therethrough, for example. The filter 162 is an interstage filter that is disposed between the power amplifier circuit 181 and the RF signal processing circuit 191 and selectively passes a high-frequency signal in the transmission band. The filter 163 is an interstage filter that is disposed between the low noise amplifier circuit 182 and the RF signal processing circuit 191 and selectively passes a high frequency signal in the reception band.

The switch circuit 170 is a switch that switches connection between the antenna element 150 and the transmission signal path and the reception signal path.

The RF signal processing circuit 191 is connected to the high frequency front end circuit 110. The RF signal processing circuit 191 is, for example, an RFIC (Radio Frequency Integrated Circuit), and performs signal processing including frequency conversion between a high-frequency signal and a baseband signal. The RF signal processing circuit 191 processes the high-frequency reception signal input from the antenna element 150 via the reception signal path by down-conversion or the like, and the baseband signal processing circuit 192 generates the reception signal generated by the signal processing. Output to. Further, the RF signal processing circuit 191 performs signal processing on the transmission signal input from the baseband signal processing circuit 192 by up-conversion or the like, and outputs the high-frequency transmission signal generated by the signal processing to the power amplifier circuit 181.

The baseband signal processing circuit 192 is connected to the RF signal processing circuit 191 and performs signal processing on the baseband signal. The signal processed by the baseband signal processing circuit 192 is used, for example, for displaying an image as an image signal or for calling as an audio signal.

The high-frequency front end circuit 110 may include other circuit elements between the filters 161, 162, and 163, the switch circuit 170, the power amplifier circuit 181, and the low noise amplifier circuit 182.

Here, in high-frequency front end circuit 110 and communication apparatus 100 according to the present embodiment, dielectric waveguide filters 1 to 1W according to Embodiments 1 to 10 can be used as filters 161, 162, and 163. .

According to the above configuration, since the areas of the filters 161, 162, and 163 can be reduced, the high-frequency front-end circuit 110 and the communication device 100 can be reduced in size.

(Embodiment 12)
In the present embodiment, a Massive MIMO system including the dielectric waveguide filter according to Embodiments 1 to 10 is exemplified.

FIG. 35 is a circuit diagram showing a Massive MIMO system according to the twelfth embodiment. FIG. 36 is a perspective view showing communication apparatus 100A of the Massive MIMO system according to Embodiment 12.

The communication device 100A includes a plurality of antenna elements 150 arranged in a matrix. The antenna element 150 is configured by a patch antenna.

The antenna element 150 is connected with band- pass filters 161a, 161b and 161c. A switch circuit 170a is connected between the filter 161a, the power amplifier circuit 181a, and the low noise amplifier circuit 182a. A switch circuit 170b is connected between the filter 161b, the power amplifier circuit 181b, and the low noise amplifier circuit 182b. A switch circuit 170c is connected between the filter 161c, the power amplifier circuit 181c, and the low noise amplifier circuit 182c. The low noise amplifier circuits 182a, 182b, and 182c are connected to the baseband signal processing circuit 192. A band pass filter 162a and a mixer 194a are connected between the baseband signal processing circuit 192 and the power amplifier circuit 181a. A band-pass filter 162b and a mixer 194b are connected between the baseband signal processing circuit 192 and the power amplifier circuit 181b. A band-pass filter 162c and a mixer 194c are connected between the baseband signal processing circuit 192 and the power amplifier circuit 181c. A local oscillator 193 is connected to the mixers 194a, 194b and 194c. The local oscillator 193 outputs, to the mixers 194a to 194c, a reference frequency for up-conversion to a high frequency and down-conversion to a low frequency in the mixers 194a to 194c.

Filters 161a to 161c pass the transmission / reception frequency band and remove other frequency components. The switch circuits 170a to 170c switch between a transmission signal and a reception signal. The filters 162a to 162c pass the frequency band of the transmission signal and remove other frequency components.

As the filters 161a to 161c and 162a to 162c, for example, the dielectric waveguide filter 1 according to the first embodiment can be used. As shown in FIG. 36, in the communication device 100A, one dielectric waveguide filter 1 is connected to one antenna element 150. The dielectric waveguide filter 1 is disposed such that a predetermined plane (the main surface 70a of the mounting substrate 70) of the dielectric waveguide filter 1 is perpendicular to the arrangement direction of the antenna elements 150. Therefore, the communication device 100A can be reduced in size by using the dielectric waveguide filter 1 having a small area shown in the first embodiment.

That is, according to the above configuration, the areas of the filters 161a to 161c and 162 to 162c can be reduced, so that the communication device 100A of the Massive MIMO system can be downsized.

(Other forms)
Although the dielectric waveguide filter, the high frequency front end circuit, and the communication device according to the embodiments of the present invention have been described above, the present invention is not limited to the individual embodiments. Unless it deviates from the gist of the present invention, various modifications conceived by those skilled in the art have been made in this embodiment, and forms constructed by combining components in different embodiments are also applicable to one or more of the present invention. It may be included within the scope of the embodiments.

For example, the input / output path P1 of the dielectric waveguide filters 1 to 1W may be in the opposite direction to that of the first embodiment. That is, the second input / output electrode 62 may be on the input side and the first input / output electrode 61 may be on the output side. Further, the input / output path P1 of the dielectric waveguide filter 1 is not limited to the path shown in the first embodiment. For example, in the input / output path P1, the signal input to the first input / output electrode 61 passes through the resonators 11, 21, 22, 12, 14, 24, 23, and 13 in order and is output from the second input / output electrode 62. The route may be a route.

Further, the coupling portions 56 facing each other in the dielectric waveguide filters 1 to 1W are not limited to the same size, and one coupling portion 56 may be larger than the other coupling portion 56. The coupling portion 56 is not limited to being formed by exposing a part of the surface of the dielectric block, and may be formed by providing a groove like the coupling portion 55.

Further, the dielectric waveguide filters 1 to 1W may not have the mounting substrate 70. For example, like the dielectric waveguide filter 1X shown in FIG. 37, a pair of input / output connectors 79 may be attached to the first resonator group 10 and signals may be input / output using the input / output connectors 79. Further, the dielectric waveguide filter 1X may include a trap resonator (band-resonating resonator).

The present invention can be widely used as a dielectric waveguide filter having a small area in communication devices such as a millimeter wave band mobile communication system and a Massive MIMO system.

1, 1A, 1B, 1C, 1D, 1E, 1F, 1G, 1H, 1I, 1J, 1K, 1L, 1M, 1N, 1P, 1Q, 1R, 1S, 1T, 1U, 1V, 1W, 1X Body waveguide filter 10 First resonator group 11, 12, 13, 14 First resonator 20 Second resonator group 21, 22, 23, 24 Second resonator 30 Third resonator group 31, 32, 33 , 34 Third resonator 51a, 51b, 51c, 51d Dielectric block 52 Surface 55, 56 Coupling portion 56a One end 56b The other end 56c Electrode projecting portion 61 First input / output electrode 62 Second input / output electrode 65 Ground electrode 66 Electrode pattern 70 Mounting board 70a Main surface of mounting board (predetermined plane)
71, 72 Input / output pattern 75 Ground pattern 79 Input / output connector 100, 100A Communication device 110 High-frequency front-end circuit 150 Antenna element 161, 161a-161c, 162, 162a-162c, 163 Filter 170, 170a- 170c Switch circuit 181, 181a 181c Power amplifier circuit 182, 182a to 182c Low noise amplifier circuit 191 RF signal processing circuit 192 Baseband signal processing circuit 193 Local oscillator 194a to 194c Mixer f1 Upper surface f2 Lower surface f3 Side surface f4 Connection surface P1 Input / output path B1 First bypass path B2 Second bypass route C1 Main route C2 Sub route

Claims (27)

1. A first resonator group including a plurality of first resonators arranged along a predetermined plane;
   A second resonator group including one or more second resonators disposed on the first resonator group in a vertical direction perpendicular to the predetermined plane;
   With
   Each of the first resonator and the second resonator is formed by a dielectric block,
   Of the combinations of at least one first resonator of the plurality of first resonators and at least one second resonator of the one or more second resonators, which overlap in the vertical direction, In at least two or more combinations, each is electromagnetically coupled to each other,
   In a combination of at least two first resonators among the plurality of first resonators adjacent to each other along the predetermined plane, each is electromagnetically coupled to each other.
   Dielectric waveguide filter.
2. The predetermined plane is a plane on the mounting substrate.
   The dielectric waveguide filter according to claim 1.
3. The second resonator group includes a plurality of the second resonators disposed on the first resonator group,
   Two sets of the first resonator and the second resonator overlapping in the vertical direction are electromagnetically coupled to each other in each set,
   The two or more second resonators including one combination of the two second resonators adjacent on the first resonator group are electromagnetically coupled to each other in each combination.
   The dielectric waveguide filter according to claim 1 or 2.
4. Ground electrodes are formed on the top, bottom and side surfaces of the dielectric block,
   The first resonator and the second resonator overlapping in the vertical direction have regions where the surface of the dielectric block is exposed on the upper surface of the first resonator and the lower surface of the second resonator, respectively. The coupling portion of the first resonator and the coupling portion of the second resonator face each other,
   The dielectric waveguide filter according to any one of claims 1 to 3.
5. The coupling portion of the first resonator is provided along at least a part of the outer periphery of the upper surface of the first resonator;
   The coupling portion of the second resonator is provided along at least a part of the outer periphery of the lower surface of the second resonator.
   The dielectric waveguide filter according to claim 4.
6. The coupling portion of the first resonator is provided at a position including a center of the upper surface of the first resonator;
   The coupling portion of the second resonator is provided at a position including the center of the lower surface of the second resonator.
   The dielectric waveguide filter according to claim 4.
7. The coupling portion has a polygonal shape, a circular shape, a frame shape, an O shape, a C shape, or a U shape.
   The dielectric waveguide filter according to claim 6.
8. In the center of the upper surface or the center of the lower surface, an electrode pattern made of the same material as the ground electrode is formed,
   The dielectric waveguide filter according to claim 6.
9. Ground electrodes are formed on the top, bottom and side surfaces of the dielectric block,
   Each of the side surfaces of the first resonator adjacent to each other along the predetermined plane has a coupling portion including a region where the surface of the dielectric block is exposed, and the coupling portions of the first resonator are mutually connected. Facing each other,
   The dielectric waveguide filter according to any one of claims 1 to 3.
10. Ground electrodes are formed on the top, bottom and side surfaces of the dielectric block,
    Each of the side surfaces of the second resonator adjacent to each other on the first resonator group has a coupling portion including a region where the surface of the dielectric block is exposed, and the coupling portion of the second resonator Are facing each other,
    The dielectric waveguide filter according to claim 3.
11. The coupling portion has a T-shaped electrode,
    The dielectric waveguide filter according to claim 9 or 10.
12. The coupling portion on the side surface is provided with an electrode projecting portion that is connected to the ground electrode and projects from one end of the coupling portion to the other end side in the vertical direction, and the other end of the coupling portion and the The electrode protrusion is opposed to the electrode with a predetermined gap.
    The dielectric waveguide filter according to claim 9 or 10.
13. In addition, equipped with a mounting board,
    The first resonator group is bonded to the mounting substrate such that the surface opposite to the surface on which the second resonator is disposed is opposed to the main surface of the mounting substrate.
    The dielectric waveguide filter according to any one of claims 1 to 12.
14. The first resonator group includes four or more first resonators arranged in a matrix along the predetermined plane,
    The second resonator group includes four or more second resonators arranged in a matrix on the first resonator group.
    The dielectric waveguide filter according to any one of claims 1 to 12.
15. Of the first resonator and the second resonator that are electromagnetically coupled to each other in the vertical direction, the first resonator is electromagnetically coupled to at least one of the first resonator located next to the first resonator. Field coupled and the second resonator is electromagnetically coupled to at least one second resonator located next to the second resonator;
    The dielectric waveguide filter according to claim 14.
16. Two or more combinations of the first resonators adjacent to each other along the predetermined plane, two sets of the first resonator and the second resonator overlapping in the vertical direction, and two or more combinations of the first resonators The second resonators adjacent on the group are electromagnetically coupled to each other in each combination.
    The dielectric waveguide filter according to claim 14.
17. The electromagnetic field coupling is a magnetic field coupling.
    The dielectric waveguide filter according to claim 16.
18. Electromagnetic field coupling of the first resonators adjacent along the predetermined plane is defined as first coupling,
    The electromagnetic coupling between the first resonator and the second resonator overlapping in the vertical direction is a second coupling,
    When the electromagnetic coupling of the second resonators adjacent on the first resonator group is the third coupling,
    Each of the first coupling and the third coupling is one of magnetic field coupling and electric field coupling;
    The second coupling is the other of the magnetic field coupling and the electric field coupling different from the one;
    The dielectric waveguide filter according to claim 16.
19. Each of the first coupling and the third coupling is a magnetic field coupling;
    The second coupling is electric field coupling;
    The dielectric waveguide filter according to claim 18.
20. further,
    Of the four or more first resonators, a first input / output electrode provided in one first resonator;
    A second input / output electrode provided on a first resonator different from the one first resonator among the four or more first resonators;
    An input / output path for outputting a signal input to the first input / output electrode from the second input / output electrode via a plurality of electromagnetic couplings;
    The dielectric waveguide filter according to any one of claims 14 to 19, further comprising:
21. And a bypass path for bypassing a signal propagated between the first input / output electrode and the second input / output electrode via electromagnetic coupling different from the input / output path,
    The signal propagating through the bypass path and the signal propagating through the input / output path have different phases in a frequency band different from the pass band of the dielectric waveguide filter,
    The dielectric waveguide filter according to claim 20.
22. The signal propagating through the bypass path and the signal propagating through the input / output path are different in phase by 180 ° in a frequency band different from the pass band of the dielectric waveguide filter.
    The dielectric waveguide filter according to claim 21.
23. A first resonator group including a plurality of first resonators arranged along a predetermined plane;
    A second resonator group including a plurality of second resonators disposed on the first resonator group in a vertical direction perpendicular to the predetermined plane;
    A third resonator group including one or more third resonators disposed on the second resonator group in the vertical direction;
    With
    Two sets of the first resonator and the second resonator, which are the first resonator and the second resonator overlapping in the vertical direction, are electromagnetically coupled to each other in each set,
    Two combinations of the second resonator and the third resonator, the second resonator and the third resonator overlapping in the vertical direction being electromagnetically coupled to each other in each combination;
    Dielectric waveguide filter.
24. The first resonator group includes two or more first resonators arranged along the predetermined plane,
    The second resonator group includes two or more second resonators disposed on the first resonator group,
    The sum of the first resonator and the second resonator is 6 or more,
    The dielectric waveguide filter is:
    The first resonator of the input stage and the second resonator of the output stage;
    A path connecting the first resonator of the input stage and the first resonator of the output stage, which has a main path formed by electromagnetic coupling, and a sub-path having weaker electromagnetic coupling than the main path. And
    A predetermined resonator of the first resonator and the second resonator is adjacent to another resonator at least in three planes orthogonal to each other;
    The predetermined resonator is electromagnetically coupled with the other resonator adjacent in the three planes;
    The electromagnetic coupling on the three surfaces constitutes a part of the main path and the sub path.
    The dielectric waveguide filter according to any one of claims 1 to 5.
25. The dielectric waveguide filter according to any one of claims 1 to 24, which is connected to an antenna element;
    A transmission amplifier circuit for amplifying a high-frequency transmission signal to be transmitted to the antenna element;
    A reception amplification circuit for amplifying a high-frequency reception signal received by the antenna element;
    A switch circuit for switching connection between the transmission amplifier circuit and the reception amplifier circuit, and the dielectric waveguide filter;
    High frequency front-end circuit with
26. A transmission amplifier circuit for amplifying a high-frequency transmission signal output from the RF signal processing circuit;
    A reception amplification circuit that amplifies a high-frequency reception signal and outputs the amplified signal to the RF signal processing circuit;
    The dielectric conductor according to any one of claims 1 to 24, disposed between the RF signal processing circuit and the transmission amplifier circuit, or between the RF signal processing circuit and the reception amplifier circuit. A wave tube filter,
    High frequency front-end circuit with
27. An antenna element;
    The high frequency front end circuit according to claim 25 or 26, wherein the high frequency front end circuit is connected to the antenna element and amplifies a high frequency signal transmitted and received by the antenna element
    An RF signal processing circuit connected to the high-frequency front-end circuit for performing signal processing including frequency conversion between the high-frequency signal and a baseband signal;
    A baseband signal processing circuit connected to the RF signal processing circuit and processing the baseband signal;
    A communication device comprising:

Images