JPH1188009A - Stacked dielectric filter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a stacked dielectric filter which can set an attenuation pole at the optional frequency near a pass band despite its inter-digital structure. SOLUTION: This strip line filter consists of a dielectric chip 30 where many dielectric sheets are laminated and bonded together by sintering. The chip 30 includes plural buried intra-resonator conductors 32 with each of both ends of them opened and the other end short-circuited respectively and also plural buried interpolating input/output electrodes 38. The out-resonator conductors 34 and the external input/output electrodes 36 are provided on the outer face of the chip 30. In such a constitution, the filter has an inter-digital pole where the short circuit and open ends of conductors 32 are arranged alternately to each other. Then a short circuit and connection pattern 40 is buried in a layer other than those including the conductors 32 to connect together the conductors 34 placed near the short-circuit ends of conductors 32. The pattern 40 is replaceable with a resonator connection pattern which directly connects together the conductors 32. The pattern 40 and the resonator connection pattern can be formed either of step-wise or in linear shapes.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a laminated dielectric filter obtained by laminating and sintering a plurality of dielectric sheets so that a plurality of conductors inside a resonator are embedded therein. More specifically, the present invention provides an interdigital converter by arranging conductors in a resonator such that short-circuit ends and open ends are alternately arranged, and connecting adjacent short-circuit ends of the conductors in a resonator with a conductor pattern. The present invention relates to a laminated dielectric filter having a structure in which an attenuation pole is set near a pass band to improve an attenuation characteristic. The laminated dielectric filter is used in various mobile communication devices such as a mobile phone and a mobile phone using microwaves.

[0002]

2. Description of the Related Art As a microwave filter using a dielectric material, there is a type in which a resonator is constituted by a strip line. In the case of a quarter-wave resonator type, a strip line type having an open end and a short-circuited end at an odd multiple of 1/4 of the resonance wavelength is provided inside a dielectric material. And an input / output electrode on the outer surface. By arranging a plurality of such in-resonator conductors inside the dielectric material so as to have a coupling degree corresponding to the filter characteristics, bandpass filter characteristics can be obtained.

[0003] With the recent miniaturization of communication equipment, dielectric filters have been required to be further miniaturized, and in order to cope with this, a laminated structure has been partially adopted. This is manufactured by a method in which a large number of unfired dielectric sheets (green sheets) are laminated, integrated under pressure, and sintered. For example, the inner resonator inner conductor is formed on a dielectric sheet by screen printing of a conductor paste, and a number of dielectric sheets including the inner conductor are laminated and crimped and integrated, and the outer surface is connected to the input and output of the resonator outer conductor. An electrode is formed and sintered. Normally, a large dielectric sheet is used, and a large number of necessary conductor patterns are regularly and vertically arranged on the large dielectric sheet so that a large number of pieces can be formed. Later, a manufacturing method is employed in which the plate-shaped dielectric block is cut lengthwise and crosswise and separated into chips.

FIGS. 8 to 10 show examples of a conventional two-stage comb-line filter. Each shows a horizontal cross section at the position of the capacitive coupling means of the conductor in the resonator. In order to make the drawing easy to understand, the conductor layer in the outer peripheral portion is drawn quite thick. However, in reality, the conductor layer is printed and baked by a screen printing method or the like, and is an extremely thin layer. The hatched portions inside represent the capacitive coupling means of adjacent conductors in the resonator. To simplify the explanation,
In those figures, functionally corresponding parts are denoted by the same reference numerals.

In the example of FIG. 8, two resonator inner conductors 12 which are open at one end and short-circuited at the other end are arranged inside the dielectric chip 10, and the outer surface of the dielectric chip 10 becomes an external ground conductor. An outer resonator conductor and an external input / output electrode are formed.
Here, the conductor 12 in the resonator has a band-like pattern,
The dielectric chip 10 is provided in parallel with each other so as to extend from one side surface to the other side surface facing the dielectric chip 10. One end is open (not connected to the resonator outer conductor 14), and the other end is short-circuited (resonant). (Connected to external conductor 14)
It has become. The two resonator inner conductors 12 are provided such that their open ends are on the same side surface.

[0006] An interposed earth pattern 18 is provided on a layer different from the inside of the resonator inner conductor 12 at a position on the open end side so as to be orthogonal to the resonator inner conductor 12.
Connect to The interpolated earth pattern 18 is for shortening the length of the conductor in the resonator to further reduce the size of the dielectric chip. In addition, a rectangular capacitive coupling pattern 20 is provided on a layer different from that of the resonator inner conductor 12 so as to connect between the two resonator inner conductors 12. This capacitive coupling pattern 20 has a function equivalent to substantially inserting a capacitor between the conductors in both resonators, and thereby has a function of polarizing the filter and improving the filter attenuation characteristics. Further, an internal insertion output electrode 22 that is electrically connected to the external input / output electrode 16 is also buried.

[0007] As another example of the dielectric filter, as shown in FIG.
There is a configuration in which the capacitive coupling electrode 24b is formed so as to protrude from the side edge of “a”. By arranging the capacitive coupling electrodes 24b so as to be close to each other between the adjacent resonator internal conductors 24, a capacitor is equivalently formed. As a result, an attenuation pole is formed, and the filter attenuation characteristics are improved. However, when forming the protruding pattern in the same plane, it is necessary to make the facing distance extremely narrow or to move the protruding pattern to the open end side. Therefore, it has been proposed to arrange adjacent conductors in the resonator in different layers so that the protruding patterns face each other in the thickness direction to increase the coupling capacitance.However, since the coupling capacitance is determined by the facing area, It is susceptible to stacking misalignment.

In the laminated dielectric filter having the structure shown in FIG. 8, the capacitive coupling pattern 20 is formed on a different layer so as to partially overlap the adjacent resonator inner conductor 12.
, The attenuation peak can be provided outside the pass band, and the filter attenuation characteristics can be improved. However, on the other hand, the capacitive coupling pattern causes a half-wave resonance, and the second harmonic of the fundamental wave, respectively. This is a factor that deteriorates characteristics in a frequency range such as a third harmonic. Therefore, as a measure for improving the harmonic characteristics of the filter, there has been proposed a dielectric filter in which the coupling capacitance pattern as shown in FIG. 10 is of a step impedance type. In this dielectric filter, the in-resonator conductor 26 is a band-shaped pattern, whereas the capacitive coupling pattern 28 is a central pattern extending in a direction connecting the two in-resonator conductors and extends perpendicularly to both ends thereof. The side pattern that overlaps the inner conductor is continuous,
The whole has an H shape. When the capacitive coupling pattern 28 is of a step impedance type as described above, FIG.
In this case, the apparent electrical length is longer than that in the case of a simple band as seen in the conventional example, and the half-wavelength resonance can be shifted to the lower frequency side. However, in this method, 2
The problem may remain in the frequency range of the harmonic or the third harmonic.

[0009]

In any case, in the prior art, in order to set the attenuation pole outside the pass band by capacitively coupling adjacent conductors in the resonator, the conductors in the resonator are disposed inside the dielectric chip. Are arranged in the same direction (open ends or short-circuit ends are located on the same side surface of the dielectric chip). In the case of such a comb-line type filter, magnetic field coupling is predominant because the short-circuited end is connected by the outer conductor (earth pattern) on the side surface, and an attenuation pole is formed on the higher frequency side than the pass band. Therefore, as described above, the position of the attenuation pole (the frequency at which the attenuation pole occurs) is adjusted by providing a capacitive coupling pattern or a pattern in which the conductors in the resonator are capacitively coupled to each other.

However, when the attenuation pole is set on the lower frequency side than the pass band, a relatively large coupling capacity is required, and the coupling must be performed on the open end side of the resonator conductor having a large electric field energy. In addition, there are problems that the conductor pattern is concentrated on the open end side and interferes with an interposed ground pattern for downsizing.

On the other hand, in the case of an interdigital filter, the short-circuit ends of adjacent conductors in the resonator are separated, and capacitive coupling is dominant, and there is an attenuation pole on the lower frequency side than the pass band. Therefore, the attenuation pole cannot be set to an arbitrary frequency by providing a capacitive coupling pattern such as a comb-line type filter or a pattern in which conductors in the resonator are capacitively coupled to each other.

An object of the present invention is to provide a laminated dielectric filter which can set an attenuation pole at an arbitrary frequency near a pass band while having an interdigital structure. It is another object of the present invention to provide a laminated dielectric filter having a resonator-to-resonator coupling structure that does not interfere with an internal ground pattern for miniaturization provided on the open end side.

[0013]

SUMMARY OF THE INVENTION According to the present invention, there are provided a plurality of resonators having one end open and the other end short-circuited inside a dielectric chip in which a large number of dielectric sheets are laminated, joined and sintered and integrated. A conductor and an internal insertion output electrode that is opposed to the conductor in the resonator located at both ends at an interval in the laminating direction are embedded, and the outer surface of the dielectric chip has an outer conductor and a resonator outside the resonator. An external input / output electrode independent of a conductor is provided, and a stripline type laminated dielectric filter having a structure in which one end of the internal insertion output electrode is connected to the external input / output electrode. It is an interdigital type in which the short-circuited end and open end of each conductor in the resonator are alternated, and short-circuiting of adjacent conductors in the resonator is performed in a layer different from the layer provided with each conductor in the resonator. A short-circuit end connection pattern connecting between the resonator outer conductors near the ends is embedded. Here, the short-circuit end connection pattern may have a stepped shape or a straight shape.

Position of attenuation pole (frequency at which attenuation pole occurs)
Varies depending on the balance between the electric field coupling and the magnetic field coupling between the resonators. However, in the case of the interdigital filter, the magnetic field coupling is weak and the electric field coupling is dominant since the short-circuit end is far away. Therefore, an attenuation pole occurs at a frequency considerably lower than the pass band. When the short-circuit connection pattern is added, the magnetic field coupling increases, and the attenuation pole can be moved near the pass band.
At this time, by changing the pattern shape such as the layer position and the pattern width of the short-circuit end connection pattern, the strength of the magnetic field coupling can be adjusted, whereby the frequency at which the attenuation pole occurs can be set arbitrarily.

[0015]

As another example of the present invention, on the premise of the above-mentioned strip-line type laminated dielectric filter, an interface in which the short-circuit end and the open end of each conductor in the resonator are alternately arranged. In a digital type, there is a structure in which conductors in each resonator are formed in the same layer, and a resonator connection pattern that connects adjacent short-circuit ends of adjacent conductors in the resonator is embedded in the same layer. . Also in this case, the resonator connection pattern may be stair-like or linear.

Also in this case, by connecting the short-circuited ends of the conductors in the resonator having a large magnetic field energy with the resonator connection pattern, the magnetic field coupling can be increased and the attenuation pole can be set near the pass band.

The laminated dielectric filter is provided on a layer different from the conductor in the resonator near the open end of the conductor in the resonator.
A structure in which an L-shaped interpolated earth pattern having both ends connected to the outer conductor of the resonator may be provided. In the present invention, since only a pattern for connecting the short-circuit end side is added, there is no interference with the interpolated earth pattern on the open end side.

[0018]

1 and 2 show an embodiment of a laminated dielectric filter according to the present invention, which is a two-stage interdigital type. 1A shows the appearance with the mounting surface facing upward, FIG. 1B shows the see-through state of only the internal conductor layer, and C shows the horizontal cross section at the short-circuit end connection pattern position. The hatched portion in FIG. 1A is the surface on which the conductor layer is formed. In FIGS. 1B and 1C, the short-circuited end connection pattern is hatched for easy understanding of the features of the present invention. FIG. 2 shows a laminated state of each dielectric sheet in the laminated dielectric filter.

Two resonator inner conductors 32, one end open and the other end short-circuited, are embedded in the dielectric chip 30, and the outer surface of the dielectric chip 30 is a resonator outer conductor 3 serving as an external ground conductor.
4 and an external input / output electrode 36 are formed. Conductor 3 in each resonator
Numerals 2 are provided in parallel with each other so as to extend from one side surface of the dielectric chip 30 to the other side surface opposite thereto, and one end is in an open state (not connected to the resonator outer conductor 34), and Are in a short-circuit state (connected to the resonator outer conductor 34). Two resonator inner conductors 3
2 are provided alternately so that each open end has a different side surface (therefore, a short-circuit end also has a different side surface). The external input / output electrode 36 has a configuration independent (electrically insulated) from the resonator outer conductor 34, is formed on an end surface different from the side surface having the open end or the short-circuited end, and has one main surface therefrom. (The upper surface in FIG. 1A).

Inside the dielectric chip 30, an internal insertion output electrode 38 is provided on one side (the lower side in FIGS. 1A and 1B) of the in-resonator conductor 32 at an interval. In addition, the conductor 32 in the resonator
The short-circuited end connection pattern 40 and the interposed earth pattern 42 are provided at intervals on the opposite surface side (the upper side in FIGS. 1A and 1B). One end of the short-circuit end connection pattern 40 is connected to the outer resonator 34 near the short-circuit end of the one inner conductor 32, and the other end is connected to the outer conductor near the short-circuit end of the other inner conductor 32. The present invention is characterized in that an interdigital filter is provided with such a short-circuited end connection pattern 40 in the interdigital filter. Here, a step-like pattern composed of a linear pattern that overlaps the half of the conductor in the resonator on the short-circuit end side and a linear pattern that connects the ends near the center at right angles is adopted.

One end of the internal insertion output electrode 38 is exposed at the end face of the dielectric chip and is connected to the external input / output electrode 36. The internal insertion output electrode 38 has a large area and closely opposes the conductor 32 inside the resonator. Such a T-shaped pattern has a function of increasing input / output coupling capacitance and strengthening first-stage coupling (coupling between the resonator inner conductor located at both ends and external input / output electrodes). The insertion ground pattern 42 has two ends near the open end of the internal conductor 32 of the resonator.
It is an L-shaped pattern that is exposed on the side and end faces of
Each is connected to the resonator outer conductor 34. This interpolated earth pattern 42 is for shortening the length of the conductor in the resonator to further reduce the size of the dielectric chip 30.

Such a laminated dielectric filter can be manufactured, for example, by a lamination procedure as shown in FIG. First, a number of unfired dielectric sheets (green sheets) are prepared. These are microwave dielectric materials (eg, B
aO-TiO ₂ —Nd ₂ O ₃ -based material having a high dielectric constant and a low-temperature sintering material in which a glass material is added) to which an organic binder is added to form a sheet. is there. In addition to a simple dielectric sheet (dielectric sheet having no conductive pattern) 50, a dielectric sheet having a required conductive pattern formed on the surface by a screen printing method using a conductive paste (for example, silver paste) is prepared. I do. These include a dielectric sheet 51 on which an outer surface earth pattern is printed on the entire surface, a dielectric sheet 52 on which internal insertion output electrodes are printed, and a dielectric sheet 5 on which conductors inside the resonator are printed.
3. There is a dielectric sheet 54 printed with a short-circuited end connection pattern and an interpolated earth pattern, and a dielectric sheet 55 printed on both ends with an external ground pattern and two external input / output electrode patterns insulated therefrom. .

At the lowermost part, a dielectric sheet 55 having an external ground pattern and two external input / output electrode patterns insulated from the external ground pattern disposed on both ends is disposed. , A dielectric sheet 53 printed with conductors in the resonator,
The dielectric sheets 52 on which the internal insertion output electrodes are printed are stacked in that order, and the dielectric sheet 51 on which the outer surface earth pattern is printed on the entire surface is disposed at the top. In addition, a simple dielectric sheet (dielectric sheet having no conductor pattern) 50 may be provided between the above-described dielectric sheets, if necessary.
For the required number of layers. However, the lowermost dielectric sheet 55 is laminated on the outer surface (the lower surface in FIG. 2) so that the outer surface earth pattern and the external input / output electrode pattern appear.
Then, the whole is pressurized and integrated by pressing. Thereafter, a conductor paste serving as an outer conductor of the resonator and an external input / output electrode is printed on the side surface and the end surface of the dielectric chip, and sintered to obtain a laminated dielectric filter. Actually, it is manufactured by a multi-cavity method using a large dielectric sheet, and cut and sintered vertically and horizontally after integration by pressure bonding.

The basic operation of the dielectric filter is as follows.
This is similar to a normal interdigital filter. The filter center frequency of the dielectric filter is substantially determined by the length of the conductor in the resonator. A bandpass filter can be obtained by arranging a plurality of such in-resonator conductors in the dielectric material at predetermined intervals so as to obtain a coupling degree corresponding to the filter characteristics.

When the short-circuited ends of adjacent conductors in the resonator of the interdigital filter are connected in a pattern, an attenuation pole can be provided outside the pass band as in the case of the comb-line filter. The frequency at which the attenuation pole is formed depends on the balance between the electric field coupling and the magnetic field coupling between the resonators. In the case of an interdigital filter, the magnetic field coupling is weak and the electric field coupling is dominant since the short-circuit end side is far away, so that an attenuation pole is formed at a frequency considerably lower than the pass band. When the magnetic field coupling is increased by adding a short-circuit end connection pattern, it becomes possible to set an attenuation pole near the pass band. The position of the attenuation pole can be arbitrarily adjusted by changing the layer position or shape of the short-circuit end connection pattern. Further, as is clear from FIG. 1, since the short-circuited end connection pattern connects short-circuited ends, it can be arranged so as not to interfere with the interposed earth pattern on the open end side.

FIG. 4 is a diagram showing the relationship between the layer position of the short-circuited connection pattern 40 and the position of the attenuation pole in the interdigital type two-stage laminated dielectric filter provided with the stepped short-circuited connection pattern 40 of the embodiment shown in FIG. 3 is shown. The dimensions of each part of the dielectric filter are as follows. The dimensions of the dielectric chip are 4.5 mm in length and 3.2 mm in width. Each conductor pattern has a width of 1.0 mm for the conductor in the resonator, a space between adjacent conductors in the resonator of 0.5 mm, and a width of the interpolation ground pattern of 0 mm. 0.3 mm, and the short-circuit end connection pattern width is 0.4 mm. In FIG. 3, the layer spacing between the short-circuit end connection pattern and the conductor in the resonator is A, and is 1
60 μm, B is 120 μm, C is 100 μm, D is 60
μm. The larger the layer spacing between the short-circuit end connection pattern and the conductor in the resonator, the weaker the magnetic field coupling and the lower the attenuation pole is on the low frequency side, and the narrower the layer spacing, the stronger the magnetic field coupling and the attenuation pole is displaced to the higher frequency side. I understand. In this data, the layer interval is changed, but the position of the attenuation pole changes even if the width of the short-circuited end connection pattern is changed. Increasing the width of the short-circuited connection pattern increases the magnetic field coupling because the current flows in the positive direction. Conversely, decreasing the width of the short-circuited connection pattern results in the direction in which the current hardly flows. Becomes weaker.

FIG. 4 shows another embodiment of the present invention.
Since the basic configuration other than the shape of the short-circuit end connection pattern is the same as that of FIG. 1, the corresponding portions are denoted by the same reference numerals and description thereof will be omitted. Here, the short-circuit end connection pattern 44 is a pattern that linearly and obliquely connects between the resonator outer conductors 34 near the short-circuit end of the adjacent resonator inner conductor 32. Also in this case, the position of the attenuation pole can be adjusted by changing the layer position and width of the short-circuit end connection pattern 44.

FIG. 5 shows still another embodiment of the present invention, which is also an example of an interdigital type two-stage filter. A shows a see-through state of only the internal conductor layer, and B shows a horizontal cross section at the position of the resonator connection pattern. For simplicity also in FIG. 5, the portion of the resonator connection pattern which is a feature of the present invention is hatched. The appearance is the same as A in FIG.

Two resonator inner conductors 62, one end open and the other end short-circuited, are buried inside the dielectric chip 60. The outer surface of the dielectric chip 60 has a resonator outer conductor 6 serving as an external ground conductor.
4 and an external input / output electrode 66 are formed. Here, the in-resonator conductors 62 are provided in parallel with each other so as to extend from one side surface of the dielectric chip 60 to the other side surface facing the dielectric chip 60, and one end is open and the other is short-circuited. . The two in-resonator conductors 62 are provided alternately so that each open end has a different side surface (and thus a short-circuit end also has a different side surface). The external input / output electrode 66 has a configuration independent of the resonator outer conductor 64, is formed on an end surface different from the side surface having the open end or the short-circuit end, and extends therefrom to one main surface. Dielectric chip 60
, An internal insertion output electrode 68 is provided on one side of the resonator internal conductor 62 at an interval. On the opposite side of the resonator conductor 62, an interposed earth pattern 72 is provided at an interval.

The two resonator inner conductors 62 are provided on the same layer, and further on the same layer, a resonator connection pattern 70 for connecting adjacent short-circuit ends of the adjacent resonator inner conductors 62 is provided. The present invention is characterized in that such a resonator connection pattern 70 is provided in the interdigital filter. Here, a step-like pattern consisting of a linear pattern extending perpendicular to the direction of the adjacent resonator inner conductor from the position near the short-circuit end of the conductor in the resonator and a linear pattern connecting the ends near the center thereof at a right angle is used. The pattern is adopted.

Since the shapes and functions of the internal insertion output electrode 68 and the internal ground pattern 72 are the same as those of the above-described embodiment, the description thereof will be omitted. Such a laminated dielectric filter can also be manufactured, for example, by a substantially similar lamination procedure as shown in FIG. However, the difference is that the resonator connection pattern is formed on the same dielectric sheet together with the conductor pattern in the resonator.

When the short circuit ends of adjacent conductors in the resonator of the interdigital filter are connected in a pattern, an attenuation pole can be provided outside the pass band as in the case of the comb line filter. The frequency at which the attenuation pole can be formed varies depending on the balance between the electric field coupling and the magnetic field coupling between the resonators. However, in the case of an interdigital filter, the magnetic field coupling is weak and the electric field coupling is dominant because the short-circuit end is far away. for that reason,
Since the attenuation pole is formed at a frequency considerably lower than the pass band, the attenuation pole can be set near the pass band by adding a resonator connection pattern to increase the magnetic field coupling. The position of the attenuation pole can be arbitrarily adjusted by changing the connection position or shape of the resonator connection pattern with the conductor in the resonator. As is clear from FIG. 5, since the resonator connection pattern connects the short-circuited ends to each other, it can be arranged so as not to interfere with the interposed earth pattern on the open end side. In addition, since the resonator connection pattern is provided on the same layer as the internal conductor of the resonator, it can be accurately formed by screen printing.

FIG. 6 shows an example of the attenuation characteristics of an interdigital type two-stage laminated dielectric filter provided with such a stepwise resonator connection pattern.

FIG. 7 shows still another embodiment of the present invention. Since the basic configuration other than the shape of the resonator connection pattern is the same as that of FIG. 5, corresponding portions are denoted by the same reference numerals and description thereof will be omitted. Here, the resonator connection pattern 74 is a pattern that linearly and obliquely connects the vicinity of the short-circuited end of the adjacent resonator inner conductor 72. Also in this case, the position of the attenuation pole can be arbitrarily adjusted by changing the connection position and width of the resonator connection pattern 74 with the conductor 72 in the resonator.

Each of the above embodiments is a two-stage filter.
The present invention can be applied to a filter having three or more stages. Although the short-circuit end connection pattern is provided only on one side of the conductor in the resonator, it may be provided on both sides. The interpolated earth pattern may not be required. In the case of the configuration in which the short-circuit end connection pattern is provided, all the conductors in the resonator do not necessarily need to be provided in the same layer. Further, the short-circuit end connection pattern and the interpolated earth pattern may be the same layer or different layers.

[0036]

As described above, the present invention is a laminated dielectric filter in which a short-circuited end connection pattern or a resonator connection pattern is buried as described above, so that an attenuation pole is formed at an arbitrary frequency near the pass band even though it has an interdigital structure. Can be set. Further, according to the present invention, there is also an advantage that the degree of freedom of pattern formation is high and the manufacturing is easy because it does not interfere with an interposed earth pattern for miniaturization provided on the open end side.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing one embodiment of a laminated dielectric filter according to the present invention.

FIG. 2 is an explanatory view showing a laminated state of the dielectric sheets.

FIG. 3 is an explanatory diagram showing a change in filter characteristics.

FIG. 4 is an explanatory view showing another embodiment of the laminated dielectric filter according to the present invention.

FIG. 5 is an explanatory view showing still another embodiment of the laminated dielectric filter according to the present invention.

FIG. 6 is an explanatory diagram showing the filter characteristics.

FIG. 7 is an explanatory view showing still another embodiment of the laminated dielectric filter according to the present invention.

FIG. 8 is an explanatory diagram showing an example of a conventional technique.

FIG. 9 is an explanatory diagram showing another example of the related art.

FIG. 10 is an explanatory diagram showing another example of the related art.

[Explanation of symbols]

 REFERENCE SIGNS LIST 30 dielectric chip 32 internal conductor of resonator 34 external conductor of resonator 36 external input / output electrode 38 internal output electrode 40, 44 short-circuited end connection pattern 42 internal insertion ground pattern 70, 74 resonator connection pattern

 ────────────────────────────────────────────────── ─── Continued on front page (72) Inventor Kazuhisa Yamazaki 5-36-11 Shimbashi, Minato-ku, Tokyo Inside Fuji Electric Chemical Co., Ltd.

Claims (5)

[Claims] 1. A dielectric chip in which a large number of dielectric sheets are laminated and joined and sintered and integrated, a plurality of conductors in a resonator, one end of which is open and the other end is short-circuited, and resonances located at both ends. An internal insertion output electrode facing the internal conductor at an interval in the stacking direction is buried, and on the outer surface of the dielectric chip,
A strip line type laminated dielectric filter having a structure in which an outer resonator conductor and an external input / output electrode independent of the resonator outer conductor are provided, and one end of the internal insertion output electrode is connected to the external input / output electrode In the inter-digital type, the short-circuit end and the open end of each of the internal conductors of the resonator are interdigitated, and the adjacent internal conductor of the resonator is provided on a layer different from the layer provided with the internal conductors of the resonator. Wherein a short-circuited end connection pattern for connecting between the resonator outer conductors near the short-circuited end is embedded. 2. The laminated dielectric filter according to claim 1, wherein the short-circuit end connection pattern has a stepped or linear shape. 3. Inside a dielectric chip in which a large number of dielectric sheets are laminated and joined together and sintered and integrated, a plurality of resonator inner conductors open at one end and shorted at the other end, and resonances located at both ends. An internal insertion output electrode facing the internal conductor at an interval in the stacking direction is buried, and on the outer surface of the dielectric chip,
A strip line type laminated dielectric filter having a structure in which an outer resonator conductor and an external input / output electrode independent of the resonator outer conductor are provided, and one end of the internal insertion output electrode is connected to the external input / output electrode In the above, an interdigital type in which the short-circuited end and the open end of each conductor in the resonator are alternately arranged, each conductor in the resonator is formed in the same layer, A resonator dielectric pattern, wherein a resonator connection pattern that connects the short-circuited ends of adjacent conductors in the resonator is embedded. 4. The multilayer dielectric filter according to claim 3, wherein the resonator connection pattern has a stepped or linear shape. 5. An L-shaped interpolated ground pattern having both ends connected to an outer resonator conductor is provided on a layer different from the inner resonator conductor at a position near an open end of the inner resonator conductor. 5. The laminated dielectric filter according to any one of items 1 to 4.