JP2012217119A - Dielectric filter, radio communication module using the same, and radio communication device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a miniaturized dielectric filter, a radio communication module using the same and a radio communication device.SOLUTION: The dielectric filter includes a dielectric block 10 and a shield conductor 20 forming a cavity by surrounding the dielectric block 10. The dielectric block 10 includes a recess 11 formed at the center in a longitudinal direction and a protrusion protruding to a first direction perpendicular to the longitudinal direction. The dielectric filter forms a pass band by use of: a first resonance mode in which the whole of electric field directions inside the dielectric block 10 are parallel to a second direction perpendicular to both the longitudinal direction and the first direction; a second resonance mode in which the electric field directions inside the dielectric block 10 are parallel to the second direction, with opposite directions between one side and the other side of the dielectric block 10 in the longitudinal direction; and a third resonance mode in which the electric field directions inside the dielectric block 10 are parallel to the first direction.

Description

  The present invention relates to a dielectric filter that can be miniaturized, and a wireless communication module and a wireless communication apparatus using the dielectric filter.

  There is known a dielectric filter configured by arranging a plurality of dielectric blocks in a cavity to form a plurality of resonators and electromagnetically coupling the plurality of resonators to each other (for example, Patent Document 1). See).

Japanese Utility Model Publication No. 3-98503

  However, the conventional dielectric filter as proposed in Patent Document 1 has a problem that it is difficult to reduce the size because a plurality of dielectric blocks need to be arranged in the cavity.

  The present invention has been devised in view of such problems in the prior art, and an object of the present invention is to provide a dielectric filter that can be reduced in size, and a wireless communication module and a wireless communication device using the dielectric filter. There is.

  The first dielectric filter of the present invention has at least a dielectric block and a shielding conductor that surrounds the dielectric block and forms a cavity, and the dielectric block has a central portion in the length direction. At least a formed concave portion and a convex portion protruding in a first direction perpendicular to the length direction, and the direction of the electric field inside the dielectric block is the length direction and the first direction. A resonance frequency of a first resonance mode that is parallel to a second direction perpendicular to both of the first and second sides in the length direction of the dielectric block, and is in the same direction in the length direction of the dielectric block; The resonance frequency of the second resonance mode in which the direction of the electric field inside is parallel to the second direction and is opposite on one side and the other side in the length direction of the dielectric block; Electric field orientation of the said projecting portions of the serial dielectric block is characterized in that the resonant frequency of the third resonance mode is parallel to the first direction is a frequency within the passband.

  The second dielectric filter of the present invention includes the two convex portions in the first dielectric filter, the resonance frequency of the first resonance mode, and the resonance frequency of the second resonance mode. The resonance frequency of the fourth resonance mode in which the directions of the electric fields at the two protrusions are both parallel to the first direction and the electric fields at the two protrusions are the same, and the two protrusions. The resonance frequency of the fifth resonance mode in which the direction of the electric field at the part is parallel to the first direction and the direction of the electric field at the two convex parts is opposite to each other is a frequency within the passband. It is characterized by.

According to a third dielectric filter of the present invention, in the first or second dielectric filter, the dielectric block surrounds at least a part of the dielectric block with a space therebetween, and is formed integrally with the dielectric block. The dielectric container is further provided, and at least a part of the shielding conductor is constituted by a conductor disposed on the outer surface of the dielectric container.

  The wireless communication module of the present invention includes at least an RF unit including the first dielectric filter and a baseband unit connected to the RF unit.

  The wireless communication device of the present invention includes at least the wireless communication module and an antenna connected to the RF unit.

  According to the dielectric filter of the present invention, a dielectric filter capable of being miniaturized can be obtained.

  According to the wireless communication module of the present invention, a wireless communication module that can be reduced in size can be obtained.

  According to the wireless communication apparatus of the present invention, a wireless communication apparatus that can be reduced in size can be obtained.

It is a perspective view showing typically the dielectric filter of the 1st example of an embodiment of the invention. It is a top view which shows the lower surface of the dielectric material filter shown in FIG. It is a longitudinal cross-sectional view of the dielectric filter shown in FIG. It is a disassembled perspective view which shows typically the dielectric material filter of the 2nd example of embodiment of this invention. It is a top view which shows the lower surface of the dielectric material filter shown in FIG. It is a longitudinal cross-sectional view of the dielectric filter shown in FIG. It is a disassembled perspective view which shows typically the dielectric material filter of the 3rd example of embodiment of this invention. It is a top view which shows the lower surface of the dielectric material filter shown in FIG. It is a longitudinal cross-sectional view of the dielectric filter shown in FIG. FIG. 8 is a horizontal sectional view of the dielectric filter shown in FIG. 7. It is a block diagram which shows typically the radio | wireless communication apparatus of the 4th example of embodiment of this invention. It is a graph which shows the simulation result of the electrical property of the dielectric filter of the 2nd example of embodiment of this invention. It is a graph which shows the simulation result of the electrical property of the dielectric filter of the 3rd example of an embodiment of the invention.

Hereinafter, a dielectric filter of the present invention will be described in detail with reference to the accompanying drawings.
(First example of embodiment)
FIG. 1 is a perspective view schematically showing a dielectric filter of a first example of an embodiment of the present invention. FIG. 2 is a plan view showing the lower surface of the dielectric filter shown in FIG. FIG. 3 is a longitudinal sectional view of the dielectric filter shown in FIG. FIG. 1 shows a state where the shielding conductor 20 is seen through in order to make the structure easy to understand.

  As shown in FIGS. 1 to 3, the dielectric filter of this example includes a dielectric block 10 and a shielding conductor 20.

  The dielectric block 10 is formed of a dielectric. In addition, the dielectric block 10 has a central portion in the length direction (x-axis direction in the figure) and a first direction perpendicular to the length direction (the width direction of the dielectric block 10 and the y-axis direction in the figure). A protruding convex part 14 and a concave part 11 recessed in a second direction (the height direction of the dielectric block 10 and the z-axis direction in the figure) perpendicular to both the length direction and the first direction are provided. .

  The recess 11 penetrates the dielectric block 10 in the width direction (y direction in the figure), and both ends of the dielectric block 10 in the length direction (x-axis direction in the figure) are higher than the recess 11. High convex portions 12 and 13 are formed.

  The convex part 14 is located in the center part (center part of the recessed part 11) of the dielectric material block 10 in the length direction (x-axis direction in the figure), and protrudes on both sides in the width direction (y-axis direction in the figure). Yes. Moreover, the convex part 14 is a rectangular flat plate shape, and a portion where one end face (+ y direction in the figure) of the dielectric block 10 and the upper face (end face in the + z direction in the figure) contact each other is cut at 45 °. The tapered portion 15 is provided. A conductor is disposed in the tapered portion 15, and an electric field in the width direction (y-axis direction in the figure) of the dielectric block 10 is excited in the convex portion 14 by the conductor disposed in the tapered portion 15.

  The shielding conductor 20 is a rectangular parallelepiped box-shaped conductor, and is disposed so as to surround the dielectric block 10. The shield conductor 20 forms a cavity (resonance cavity), and the dielectric block 10 is accommodated in the cavity. The shielding conductor 20 is disposed so as to contact the entire lower surface of the dielectric block 10 and the upper surfaces of the convex portions 12, 13, and 14 of the dielectric block. Further, the shielding conductor 20 is in contact with both end portions of the convex portion 14 in the width direction (y direction in the figure) of the dielectric block 10, and the side surface (in the z direction in the drawing) of the portion other than the convex portion 14 of the dielectric block 10. (Parallel surface) and a space. And the dielectric block 10 is arrange | positioned in the center of the cavity which the shielding conductor 20 forms. The shielding conductor 20 is connected to a reference potential (ground potential).

  In addition, openings 25 and 26 are formed in portions of the shielding conductor 20 located below the convex portions 12 and 13 (the −z direction side in the drawing) of the dielectric block 10, respectively. Then, a portion of the lower surface of the dielectric block 10 (the surface on the −z direction side in the figure) exposed to the outside through the openings 25 and 26 of the shielding conductor 20 is spaced apart from the shielding conductor 20. Terminal electrodes 31 and 32 are arranged. That is, on the lower surface of the dielectric block 10, the terminal electrode 31 is disposed in a portion exposed through the opening 25 located below the convex portion 12, and the opening located below the convex portion 13. A terminal electrode 32 is disposed to be exposed through the terminal 26.

  In the dielectric filter of this example having such a configuration, for example, when an electric signal is input from the terminal electrode 31, the direction of the electric field is the height direction of the dielectric block (z-axis direction in the figure), and the dielectric filter The direction of the electric field is the same on one side and the other side in the length direction of the body block 10 (x-axis direction in the figure), and the amplitude of the standing wave is maximum in the length direction of the dielectric block 10 in the cavity. Is generated (resonance in which a wave of a half wavelength exists in the cavity), and this becomes the first resonance mode.

In addition, the direction of the electric field is the height direction of the dielectric block (the z-axis direction in the figure), and the direction of the electric field is reversed on one side and the other side in the length direction of the dielectric block 10, so that the cavity Resonance such that there are two points of maximum amplitude of the standing wave in the length direction (x-axis direction in the figure) of the dielectric block 10 inside (resonance where a wave of one wavelength exists in the cavity) occurs. This is the second resonance mode. The convex portions 12 and 13 are positioned in the vicinity of the point of maximum amplitude of the standing wave in the second resonance mode. The length direction of the dielectric block 10 (
As the dimension in the x-axis direction in the figure increases, the resonance frequency of the first and second resonance modes decreases.

  Then, due to the conductor disposed on the tapered portion 15 of the convex portion 14, the direction of the electric field is on the convex portion 14 of the dielectric block 10 in the width direction of the dielectric block 10 (y-axis direction in the figure), and the dielectric block Resonance in which there is one standing wave in the height direction (z-axis direction in the figure) of 10 occurs (resonance in which waves of half wavelength exist in the convex portion 14), which is the third resonance mode. It becomes. Note that as the dimension of the convex portion 14 in the height direction (z-axis direction in the figure) increases, the resonance frequency of the third resonance mode decreases. In addition, since the dielectric constant in the dielectric block 10 is higher than the dielectric constant of other regions in the cavity, most of the electric field is concentrated inside the dielectric block 10 in the first to third resonance modes. Exist.

  When the inside of the cavity is uniform, the frequency of the second resonance mode is twice that of the first resonance mode. However, in the dielectric filter of this example, the dielectric block 10 is disposed in the cavity. A recess 11 is formed at the center of the dielectric block 10 in the length direction. And since the inside of the recessed part 11 is filled with air, the dielectric constant in the recessed part 11 becomes lower than the dielectric constant of the other dielectric block 10.

  In the first resonance mode, the electric field is strongest at the central portion of the dielectric block 10 in the length direction (x-axis direction in the figure), and the electric field becomes weaker from there toward both sides of the dielectric block 10 in the length direction. Thus, the electric field distribution is such that the magnitude of the electric field becomes zero at both end portions of the cavity in the x-axis direction (portion in contact with the shielding conductor 20). For this reason, the resonance frequency of the first resonance mode is greatly affected by the formation of the concave portion 11 in the central portion in the length direction of the dielectric block 10 and the lowering of the dielectric constant of that portion. Therefore, by forming the recess 11 in the dielectric block 10, the resonance frequency of the first resonance mode is greatly shifted to the high frequency side. The direction in which the convex portion 14 projects (y-axis direction in the drawing) is preferably perpendicular to the direction in which the concave portion 11 is depressed (z-axis direction in the drawing), and the length of the dielectric block 10 in the convex portion 14 The dimension in the vertical direction (x-axis direction in the figure) is preferably smaller than the dimension in the length direction (x-axis direction in the figure) of the dielectric block 10 in the recess 11. Alternatively, it is desirable that the convex portion 14 does not protrude in the direction in which the concave portion 11 is concave (z-axis direction in the figure). Thereby, it can reduce that the convex part 14 inhibits the effect of the recessed part 11 which shifts the resonant frequency of a 1st resonance mode to a high frequency side.

  On the other hand, in the second resonance mode, the length of the dielectric block 10 is added to both ends of the cavity in the length direction of the dielectric block 10 (x-axis direction in the drawing) (portions in contact with the shielding conductor 20). Even at the central portion in the vertical direction, the magnitude of the electric field is almost zero. For this reason, the resonance frequency of the second resonance mode is not significantly affected by the formation of the concave portion 11 at the central portion in the length direction of the dielectric block 10 and the lowering of the dielectric constant of that portion. Therefore, by forming the recess 11 in the dielectric block 10, the resonance frequency of the second resonance mode is slightly shifted to the high frequency side.

  In this way, the dielectric filter of the present example can shift the resonance frequency of the first resonance mode to the high frequency side to approach the resonance frequency of the second resonance mode. Therefore, by appropriately setting the dimensions of the dielectric block 10 in the length direction (x-axis direction in the figure) and the dimensions of the convex portion 14 in the height direction (z-axis direction in the figure), It can be set so that the resonance frequencies of the third resonance mode are all in the pass band of the filter.

That is, in the dielectric filter of the present example, the direction of the electric field inside the dielectric block 10 is parallel to the height direction (z-axis direction in the figure), and one side in the length direction of the dielectric block 10 is The resonance frequency of the first resonance mode that is in the same direction on the other side and the direction of the electric field inside the dielectric block 10 are parallel to the height direction (z-axis direction in the figure), and the dielectric block 10 The resonance frequency of the second resonance mode that is opposite on one side and the other side in the length direction and the direction of the electric field in the convex portion 14 of the dielectric block 10 are parallel to the width direction (y-axis direction in the figure). The resonance frequency of a certain third resonance mode is set to be a frequency within the pass band of the filter. Therefore, the dielectric filter of this example can form a pass band using the first resonance mode, the second resonance mode, and the third resonance mode. Therefore, according to the dielectric filter of this example, a bandpass filter having a wide pass band can be easily obtained.

  As described above, in the dielectric filter of this example, when an electric signal is input from the terminal electrode 31, an electric signal in a frequency band including the resonance frequencies of the first to third resonance modes is selectively transmitted to the terminal electrode 32. And function as a bandpass filter. Note that the resonance frequencies of the first to third resonance modes are the length of the dielectric block 10 and the height of the convex portion 14, the relative dielectric constant of the dielectric block 10, the size of the concave portion 11, the shape of the cavity, and the like. Can be adjusted as appropriate.

  Further, according to the dielectric filter of this example, since the filter can be constituted by one dielectric block 10 and the shielding conductor 20 surrounding the dielectric block 10, a dielectric filter capable of being miniaturized can be obtained.

  Furthermore, according to the dielectric filter of this example, since the shielding conductor 20 surrounds the dielectric block 10 with a gap from the side surface of the dielectric block 10, the resonance Q value can be increased, Higher order mode resonance can be moved away from the pass band to the high frequency side.

(Second example of embodiment)
FIG. 4 is an exploded perspective view schematically showing a dielectric filter according to a second example of the embodiment of the present invention. FIG. 5 is a plan view showing the lower surface (end surface in the −z direction in the drawing) of the dielectric filter shown in FIG. 4. FIG. 6 is a schematic longitudinal sectional view of the dielectric filter shown in FIG. In this example, parts different from the example of the embodiment described above will be described, and the same constituent elements will be denoted by the same reference numerals and redundant description will be omitted.

  The dielectric filter of this example has the dielectric block 10, the dielectric container 40, and the shielding conductor 20, as shown in FIGS.

  The dielectric container 40 is integrated with the dielectric block 10, and together with a part of the dielectric block 10, forms a rectangular parallelepiped box-like shape whose upper surface is open. That is, the bottom of the box is joined and integrated with the bottom of the dielectric block 10 (the end on the −z direction side in the figure), and the side walls of the box are both ends of the convex part 14 in the y-axis direction in the figure. It is joined and integrated with the part. And it arrange | positions so that most parts of the side surface (surface parallel to the z direction of a figure) in parts other than the convex part 14 of the dielectric block 10 may be spaced, and the most part of the side surface may be surrounded. That is, the dielectric container 40 surrounds at least a part of the dielectric block 10 with a space therebetween, and is integrally formed with the dielectric block 10. The dielectric container 40 is formed integrally with the dielectric block 10 using the same dielectric material as that of the dielectric block 10.

The shield conductor 20 includes a conductor 21 and a conductor plate 22. The conductor 21 is disposed on the outer surface of a rectangular parallelepiped box formed by a part of the dielectric block 10 and the dielectric container 40. That is, the conductor 21 includes the bottom surface of the dielectric block 10 (the end surface in the −z direction in the figure), the both end surfaces in the y-axis direction in the figure of the convex portion 14, and the dielectric container 40 constituting the other part of the box. It is arranged on the outer surface. The conductor plate 22 is disposed on the upper surfaces (end surfaces in the + z direction in the figure) of the dielectric container 40 and the dielectric block 10 and connected to the conductor 21. That is, a part of the shielding conductor 20 is constituted by the conductor 21 arranged on the outer surface (outer surface) of the dielectric container 40.

  According to the dielectric filter of this example having such a configuration, the dielectric block 10 and the dielectric container 40 can be integrally formed of the same dielectric, and the conductor formed on the outer surface of the dielectric container 40 Since the shielding conductor 20 can be constituted by the conductor plate 22 and the conductor plate 22, a dielectric filter that can be easily manufactured can be obtained.

(Third example of embodiment)
FIG. 7 is an exploded perspective view schematically showing a dielectric filter according to a third example of the embodiment of the present invention. FIG. 8 is a plan view showing the lower surface (end surface in the −z direction in the figure) of the dielectric filter shown in FIG. 7. FIG. 9 is a schematic longitudinal sectional view of the dielectric filter shown in FIG. FIG. 10 is a schematic horizontal sectional view of the dielectric filter shown in FIG. Note that in this example, a different part from the second example of the above-described embodiment will be described, and the same components will be denoted by the same reference numerals and redundant description will be omitted.

  The dielectric filter of this example has the dielectric block 10, the dielectric container 40, and the shielding conductor 20, as shown in FIGS. The dielectric block 10 has two convex portions 14a and 14b having the same shape.

  Each of the convex portions 14a and 14b has a rectangular flat plate shape protruding on both sides in the width direction. Each of the convex portions 14a and 14b is a tapered portion in which a portion where one end surface in the width direction (+ y direction in the drawing) of the dielectric block 10 and the upper surface (end surface in the + z direction in the drawing) are cut is 45 °. 15 is provided. A conductor is disposed in the tapered portion 15, and an electric field in the width direction (y-axis direction in the drawing) of the dielectric block 10 is excited in the convex portions 14 a and 14 b by the conductor disposed in the tapered portion 15. The Specifically, the electric field directions at the two convex portions 14a and 14b are both parallel to the width direction (y-axis direction in the figure), and the electric field directions at the two convex portions 14a and 14b are the same. The fourth resonance mode and the direction of the electric field at the two convex portions 14a and 14b are both parallel to the width direction (the y-axis direction in the figure), and the direction of the electric field at the two convex portions 14a and 14b is opposite to each other. The fifth resonance mode is generated.

  Further, the convex portions 14 a and 14 b are formed in the vicinity of both end portions in the length direction (x-axis direction in the figure) of the dielectric block 10, and are integrated with the convex portions 12 and 13. That is, the convex portion 14 a is formed near the end of the dielectric block 10 on the −x direction side (near the central portion of the convex portion 12), and is integrated with the convex portion 12. The convex portion 14 b is formed near the end of the dielectric block 10 on the + x direction side (near the central portion of the convex portion 13), and is integrated with the convex portion 13. The convex portions 14a and 14b are separately arranged on both sides of the center in the length direction of the dielectric block 10 (x-axis direction in the figure), and the length direction of the dielectric block 10 (x-axis direction in the figure). It is desirable to arrange them symmetrically with respect to the center of Thereby, a dielectric filter having excellent characteristics can be obtained. In addition, it is desirable that the convex portions 14a and 14b are respectively disposed in the vicinity of the point of the amplitude maximum of the standing wave in the second resonance mode, so that the fourth resonance mode and the fifth resonance mode can be efficiently performed. Can be excited.

In the dielectric filter of this example, the resonance frequency of the first resonance mode, the resonance frequency of the second resonance mode, and the direction of the electric field at the two convex portions 14a and 14b are all in the first direction (y-axis direction in the figure). And the direction of the electric field in the two convex portions 14a and 14b and the direction of the electric field in the two convex portions 14a and 14b are both in the first direction (see FIG. The resonance frequency of the fifth resonance mode, which is parallel to the y-axis direction) and the directions of the electric fields of the two convex portions 14a and 14b are opposite to each other, is set to be a frequency within the passband of the filter. Has been. The fourth resonance mode and the fifth resonance mode are included in the third resonance mode described above. Therefore, the dielectric filter of the present example can form a pass band using the first resonance mode, the second resonance mode, the third resonance mode, and the fourth resonance mode. Therefore, according to the dielectric filter of this example, a bandpass filter having a wider pass band can be easily obtained.

In the dielectric filter of the present example and the first to third examples of the above-described embodiment, the material of the dielectric block 10 can be a resin such as an epoxy resin or a ceramic such as a dielectric ceramic. For example, a dielectric ceramic material containing BaTiO ₃ , Pb ₄ Fe ₂ Nb ₂ O ₁₂ , TiO ₂ or the like is preferably used. As a material of the shielding conductor 20 and the terminal electrodes 31 and 32, for example, a conductive material mainly composed of an Ag alloy such as Ag, Ag-Pd, or Ag-Pt, or a Cu-based, W-based, Mo-based, or Pd-based conductive material. Etc. are preferably used.

(Fourth example of embodiment)
FIG. 11 is a block diagram schematically showing a wireless communication apparatus 80 of the fourth example of the embodiment of the present invention. As shown in FIG. 11, the wireless communication device 80 of this example includes a wireless communication module 81 and an antenna 82 connected to the wireless communication module 81. The wireless communication module 81 includes an RF unit 83 connected to the antenna 82 and a baseband unit 84 connected to the RF unit 83.

  The baseband unit 84 includes a baseband IC 87 and has a function of processing a baseband signal. The RF unit 83 includes an RFIC 86 connected to the baseband unit 84, and dielectrics of the first to third examples of the embodiment of the present invention shown in FIGS. 1 to 10 connected to the RFIC 86 and the antenna 82. And a filter 85, and has a function of processing an RF signal after modulation of the baseband signal and before demodulation. In addition, an RF signal obtained by modulating the baseband signal or a signal other than the communication band in the received RF signal is attenuated by the dielectric filter 85.

  According to the wireless communication module 81 and the wireless communication device 80 of the present example having such a configuration, the communication signal is filtered using the dielectric filter 85 of the present invention that can be reduced in size, so that the size can be reduced. A wireless communication module 81 and a wireless communication device 80 that can be reduced in size can be obtained.

(Modification)
The present invention is not limited to the embodiments described above, and various modifications and improvements can be made without departing from the scope of the present invention.

  In the first to third examples of the above-described embodiment, the example in which the concave portion 11 penetrating in the width direction is formed on the upper surface of the dielectric block 10 is shown, but the present invention is not limited to this. For example, a recess 11 that does not penetrate in the width direction may be formed on the upper surface of the dielectric block 10.

  In the first to third examples of the above-described embodiment, the example in which the concave portion 11 is formed on the upper surface of the dielectric block 10 is shown, but the present invention is not limited to this. For example, the recess 11 may be formed on the side surface or the lower surface of the dielectric block 10.

  Furthermore, in the first to third examples of the above-described embodiment, the example in which the rectangular parallelepiped recess 11 is formed in the rectangular parallelepiped dielectric block 10 is shown, but the present invention is not limited to this. For example, the dielectric block 10 may have a shape close to an ellipse with rounded corners, or the concave portion 11 having a shape close to a sphere.

  Furthermore, the portion other than the dielectric block 10 in the cavity formed by the shielding conductor 20 may be air or vacuum, and further, the relative permittivity is higher than that of the dielectric block 10. Small items may be filled.

  Next, specific examples of the dielectric filter of the present invention will be described.

  First, the electrical characteristics of the dielectric filter of the second example of the embodiment of the present invention shown in FIGS. 4 to 6 were calculated by simulation using a finite element method. In the simulation, the dielectric constant of the dielectric block 10 was set to 70. As shown in FIGS. 4 to 6, the dielectric block 10 has a shape in which a concave portion 11 and a convex portion 14 are formed with respect to a basic shape of a rectangular parallelepiped. The dimensions of the rectangular parallelepiped that is the basic shape are 39 mm in the length direction (x-axis direction in the figure), 6 mm in the width direction (y-axis direction in the figure), and the height direction (z-axis direction in the figure). The dimension was set to 22 mm.

  The recess 11 is formed on the upper surface at the center in the length direction (x-axis direction in the figure) of the rectangular parallelepiped that is the basic shape, the dimension in the x-axis direction in the figure is 24 mm, and the depth in the z-axis direction in the figure Is 20 mm and has a shape penetrating in the width direction (y-axis direction in the figure) of the dielectric block 10. The convex portion 14 is formed on the side surface at the center in the length direction (x-axis direction in the figure) of the rectangular parallelepiped that is the basic shape, the dimension in the y-axis direction in the figure is 14.4 mm, and the z-axis direction in the figure The flat plate shape was 22 mm in thickness and 2 mm in thickness (dimension in the x-axis direction in the figure). Further, the convex portion 14 includes a tapered portion 15 in which a portion where one end surface (+ y direction in the drawing) in the width direction of the dielectric block 10 is in contact with the upper surface (end surface in the + z direction in the drawing) is cut at 45 °. Shape. The cavity surrounded by the shielding conductor 20 has a length direction (x-axis direction in the figure) of 49 mm, a width direction (y-axis direction in the figure) of 14.4 mm, and a height direction (z in the figure). A shape in which a tapered portion 15 cut at 45 ° is provided at a portion where a side surface (an end surface in the + y direction in the figure) and a top surface (an end surface in the + z direction in the figure) of a rectangular parallelepiped having an axial dimension of 22 mm contact did. The thickness of the dielectric container 40 was 2 mm.

  The simulation result is shown in the graph of FIG. In the graph, the horizontal axis is frequency and the vertical axis is attenuation. In addition, the solid line indicates the pass characteristic, and the broken line indicates the reflection characteristic. According to this graph, it can be seen that a three-stage band-pass filter having good pass characteristics is obtained.

  Next, the electrical characteristics of the dielectric filter of the third example of the embodiment of the present invention shown in FIGS. 7 to 10 were calculated by simulation using a finite element method. In the simulation, the dielectric constant of the dielectric block 10 was set to 70. As shown in FIGS. 4 to 10, the shape of the dielectric block 10 is a shape in which the concave portion 11 and the convex portions 14 a and 14 b are formed on the basic shape of the rectangular parallelepiped. The dimensions of the rectangular parallelepiped that is the basic shape are 39.18 mm in the length direction (x-axis direction in the figure), 6 mm in the width direction (y-axis direction in the figure), and the height direction (z-axis in the figure). Direction) was 22.5 mm.

  The concave portion 11 is formed on the upper surface of a rectangular parallelepiped that is a basic shape, has a length direction (x-axis direction in the figure) dimension of 24.22 mm, and a depth in the z-axis direction of the figure is 21.5 mm. The dielectric block 10 has a shape penetrating in the width direction (y-axis direction in the figure).

The protrusions 14a and 14b have a dimension in the width direction (y-axis direction in the figure) of 14.4 mm, a dimension in the height direction (z-axis direction in the figure) of 22.5 mm, and a thickness (x-axis in the figure). The dimension in the direction) is 1.92 mm, and the portion where one end face (y direction in the figure) of the dielectric block 10 is in contact with the upper face (end face in the + z direction in the figure) is 45 °. Cut taper 15
It was set as the shape provided with. The cavity surrounded by the shield conductor 20 has a length direction (x-axis direction in the figure) of 49 mm, a width direction (y-axis direction in the figure) of 14.4 mm, and a height direction (z-axis in the figure). Side) (end surface in the + y direction in the figure) and upper surface (+ z in the figure)
A shape in which a tapered portion cut at 45 ° is provided at a portion in contact with a direction end face). The thickness of the dielectric container 40 was 1 mm at the bottom surface (end surface in the -z direction in the figure), and 2 mm at other portions.

  The simulation result is shown in the graph of FIG. In the graph, the horizontal axis is frequency and the vertical axis is attenuation. In addition, the solid line indicates the pass characteristic, and the broken line indicates the reflection characteristic. According to this graph, it can be seen that a four-stage bandpass filter having good pass characteristics is obtained.

  From these results, the effect of the present invention was confirmed.

10: Dielectric block 11: Concave portion 12, 13, 14, 14a, 14b: Convex portion 20: Shielding conductor 40: Dielectric container 80: Wireless communication device 81: Wireless communication module 82: Antenna 83: RF unit 84: Baseband Part 85: Dielectric filter

Claims (5)

At least a dielectric block and a shielding conductor surrounding the dielectric block to form a cavity;
The dielectric block has at least a concave portion formed at a central portion in the length direction and a convex portion protruding in a first direction perpendicular to the length direction, and an electric field inside the dielectric block. Are parallel to a second direction perpendicular to both the length direction and the first direction, and are in the same direction on one side and the other side in the length direction of the dielectric block. A resonance frequency of the first resonance mode;
The resonance frequency of the second resonance mode in which the direction of the electric field inside the dielectric block is parallel to the second direction and is opposite on one side and the other side in the length direction of the dielectric block. When,
The dielectric filter according to claim 1, wherein the direction of the electric field at the convex portion of the dielectric block is such that the resonance frequency of the third resonance mode, which is parallel to the first direction, is a frequency within a pass band.   Two convex portions, the resonance frequency of the first resonance mode, the resonance frequency of the second resonance mode, and the direction of the electric field at the two convex portions are parallel to the first direction. And the resonance frequency of the fourth resonance mode in which the electric field directions of the two convex portions are the same, and the electric field directions of the two convex portions are both parallel to the first direction, and the 2 2. The dielectric filter according to claim 1, wherein the resonance frequency of the fifth resonance mode in which the directions of the electric fields in the two convex portions are opposite to each other is a frequency within the passband.   A conductor that surrounds at least a portion of the dielectric block with a space therebetween and further has a dielectric container integrally formed with the dielectric block, and is disposed on an outer surface of the dielectric container. The dielectric filter according to claim 1, wherein at least a part of the shielding conductor is constituted by the structure.   A wireless communication module comprising at least an RF unit including the dielectric filter according to claim 1 and a baseband unit connected to the RF unit.   5. A wireless communication apparatus comprising at least the wireless communication module according to claim 4 and an antenna connected to the RF unit.

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