JPH07226602A - Laminated dielectric filter - Google Patents

Abstract

PURPOSE:To effectively increase input/output capacitance and to improve filter characteristics by providing the capacitance patterns of input/output on both sides so as to surround an electrode for resonance. CONSTITUTION:By the capacitance 26 between the electrode 14 for the resonance and a grounding conductor 20 in counter electrodes 22, the electrode 14 for the resonance becomes inductive at a resonance frequency, inductive coupling M is generated between resonators and prescribed characteristics as a filter are obtained. Between input/output terminals 24 and the initial stage and final stage of the electrode 14 for the resonance, capacitive coupling by first electrodes 16 for input/output through the capacitiance 28 supplied in a dielectric layer 12b and the capacitive coupling by second electrodes 18 for the input-/ output through the capacitance 30 supplied in the dielectric layer 12c are parallelly provided. By parallelly providing the prescribed input/output capacitance, the pattern area of the entire input/output capacitance is enlarged, the electrode 14 for the resonance is surrounded by the electrodes 16 and 18 on both sides, impedance to ground is increased and the entire input/output capacitance is increased.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a laminated dielectric filter,
In particular, the present invention relates to a structure in which the input / output capacitance can be advantageously increased in a triplate type dielectric filter having an integrally laminated structure.

[0002]

BACKGROUND ART In recent years, filters using various dielectric ceramics have been used to reduce loss in high-frequency circuit wireless devices such as mobile phones and automobile phones, and antenna duplexers. For one,
For example, as disclosed in Japanese Patent Laid-Open No. 59-51606, a triplate-type laminated dielectric filter is known. 5 shows an example of a dielectric filter having such a structure, the dielectric filter 1 shown therein has a plurality of dielectric filters in the dielectric substrate 3 in a pattern as shown. A pair of stripline type resonance electrodes 2 (here, three electrodes) and the first and last stages thereof (the ones located at both ends in the left-right direction in the figure) are respectively connected via a predetermined capacitance. The input / output electrodes 4 and 4 are built in, while the ground conductor 5 and the input / output terminals 6 and 6 corresponding to the input / output electrodes 4 and 4 are provided on the outer peripheral surface. It is made extremely compact. Then, the resonator is configured corresponding to each resonance electrode 2.

By the way, in such a laminated type dielectric filter, the input / output to / from the resonance electrode 2 is interposed between the resonance electrode and the input / output electrode 4 without direct electrical connection. Dielectric layer of specified thickness (3)
Input / output terminal 6 through a predetermined electrostatic capacity given by
It is realized by connecting to. That is, a configuration is adopted in which a capacitor pattern for input / output to / from the resonator is formed from the resonance electrode 2, the input / output electrode 4, and the dielectric layer (3) between them, and the capacitor is used to input / output to / from the resonator. It has been done. Therefore, in such an input / output system via a predetermined capacitance, the input / output impedance is determined by the capacitance of the capacitor, and therefore it is less susceptible to external connection. However, due to restrictions such as chip size and triplate structure, there is a limit to the capacity of the capacitor that can be formed. Therefore, filter size reduction, low frequency, low loss, and large return loss are required. In other words, there is an inherent problem that it is difficult to achieve high return loss.

It is also known that the input / output of the resonator in such a laminated filter is carried out by the L tap method in which a pattern is directly drawn from the resonator. This L tap input / output method is a structure. Easy to use, wide adjustment range of resonator input / output impedance, small filter size,
It is known that there is an advantage that it is easy to reduce the frequency, reduce the loss, and increase the return loss. However, this L-tap input / output method has a problem that it is easily affected by the external connection impedance and the characteristics are easily changed.

[0005]

The present invention has been made in view of such circumstances, and a problem to be solved by the present invention is to provide a tri-plate type integrated laminated structure dielectric filter. A capacitor with a larger capacity can be advantageously formed to effectively increase the input / output capacity of the capacitor, thus improving the filter characteristics, realizing a filter for lower frequencies, and reducing the size of the filter. To achieve.

[0006]

In order to solve the above problems, according to the present invention, a plurality of stripline-type resonance electrodes, which are parallel to each other, are built in a dielectric substrate, and the first and last stages thereof are included. On the other hand, while the input / output electrodes are electrically connected to each other through a predetermined capacitance, the resonance electrodes are electrically connected to a ground conductor provided on the outer surface or inside of the dielectric substrate. In the triplate type integrally laminated dielectric filter, the input / output electrode is provided on one side of the resonance electrode in the laminating direction via a first dielectric layer. A first input / output electrode and a pair of second input / output electrodes provided on the other side of the resonance electrode in the stacking direction via a second dielectric layer, and For first and second input / output Those poles corresponding, respectively,
The gist of a laminated dielectric filter is characterized in that it is electrically connected to a pair of input / output terminals.

Further, according to a preferred embodiment of the laminated dielectric filter according to the present invention, the first and second input / output electrodes are respectively arranged at a first stage and a final stage of the resonance electrode in the laminating direction. It is provided so as to overlap with the object with a predetermined overlapping area.

Further, in a preferred embodiment of the laminated dielectric filter according to the present invention, the first input / output electrode and the second input / output electrode sandwich the resonance electrode in the stacking direction. It is provided so as to face each other.

[0009]

As described above, according to the present invention, unlike the conventional structure in which the capacitor pattern is formed only on one side of the resonance electrode to provide the input / output capacitance, the resonance electrode is provided. By enclosing the input / output capacitance pattern on both sides so as to surround it, the total input / output capacitance pattern area can be expanded, and the resonance electrode is surrounded by the electric field of the input / output electrode to effectively provide impedance to earth. , And as a result of these two effects, it is possible to effectively increase the input / output capacity.

Therefore, in the laminated dielectric filter according to the present invention, a capacitor having a larger capacitance is formed in order to secure an optimum input / output capacitance with respect to the input signal frequency. While maintaining the characteristics of external connection, that is, the characteristics of being less susceptible to external connection, high return loss, low insertion loss, expansion of pass band width, realization of filters for lower frequencies, and further miniaturization Etc. could be effectively achieved.

Further, according to the present invention, the resonance electrode is separated from the pair of first and second input / output electrodes provided on both sides thereof by the first and second dielectric layers, respectively. Due to the fact that it is surrounded by the input and output capacitances from both sides, it is less likely to be affected by the external ground conductor, and thus the passband characteristics of the filter are less likely to be affected by manufacturing variations, operating conditions, etc. It will be.

Further, in the laminated dielectric filter according to the present invention, both sides of the resonance electrode can be formed symmetrically with respect to the resonance electrode, so that the front and back surfaces (upper surface and lower surface) of the filter can be formed. No matter which one is installed,
Since the characteristics are the same, this also has an advantage that the labor for packing and mounting can be effectively saved.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In order to clarify the present invention more specifically, representative examples of a laminated dielectric filter according to the present invention will be described in detail below with reference to the drawings.

First, FIGS. 1 and 2 show an example of a triplate-type dielectric filter according to the present invention. In this case, the dielectric filter 10 includes four filters as shown in FIG. Integrated dielectric substrate 1 configured by stacking dielectric layers 12a, 12b, 12c and 12d
Have two. A plurality of stripline type single-ended short-circuit type resonance electrodes 14 (here, three) are formed on the upper surface of the third dielectric layer 12c from the top, and each resonance electrode 14 is formed. A counter electrode 22 connected to the ground conductor 20 on the outer surface is provided at a position facing the open end of the. As a result, a predetermined capacitance is formed between each resonance electrode 14 and the ground conductor 20.

On the upper and lower dielectric layers sandwiching the dielectric layer 12c provided with the resonance electrodes 14, in other words, on the upper surfaces of the second and fourth dielectric layers 12b and 12d from the top, the resonance is formed. A pair of electrodes 14 for the first and last electrodes for use (resonance electrodes located at both ends in the left-right direction in FIG. 1) are overlapped with each other with a predetermined overlapping area in the stacking direction. (pair)
The first input / output electrodes 16 and 16 and the second input / output electrodes 18 and 18 are symmetrically provided with the resonance electrode 14 in between. That is, with respect to the resonance electrode 14 having the first and last stages, one set of the first input / output electrodes 16 and 16 is provided through the upper dielectric layer 12b, and another set of the second input / output electrodes 16 and 16 is provided. The input / output electrodes 18, 18 are electrically connected to each other via the lower dielectric layer 12c.

Therefore, the first input / output electrodes 16, 16
Is connected to the first and last stages of the resonance electrode 14 through the predetermined capacitance given by the thickness of the dielectric layer 12b at its inner end, while the second input / output electrode is connected. Also, 18, 18 are to be connected to the first and last stages of the resonance electrode 14 via the predetermined capacitance given by the thickness of the dielectric layer 12c at the inner ends thereof. The outer ends of the first and second input / output electrodes 16, 16; 18, 18 are exposed to the outside on the left and right side surfaces of the dielectric substrate 12, respectively. .

A pair of input / output terminals are provided on both left and right side surfaces where the outer ends of the first and second input / output electrodes 16, 16; 18, 18 of the dielectric substrate 12 are exposed. Two
4, 24 are provided respectively, and the input / output terminals 24,
As is apparent from the drawing, the reference numeral 24 extends a predetermined length on the upper surface of the dielectric substrate 12. Also on the lower surface (bottom surface) of the dielectric substrate 12, the input / output terminals 24, 24 are extended similarly to the upper surface. The ground conductor 20 is formed over substantially the entire outer surface of the dielectric substrate 12, leaving a predetermined gap around the pair of input / output terminals 24, 24. That is, a pair of first and second input / output electrodes 16, 16; 18, respectively,
18 corresponding ones are electrically connected to a pair of input / output terminals 24, 24, respectively, while the three resonance electrodes 14 and the counter electrodes 22 facing them are all on the outer surface of the dielectric substrate 12. It is electrically connected to the ground conductor 18 of FIG. Therefore, the pattern of the ground conductor 20 on the outer surface of the dielectric substrate 12 is symmetrical on the corresponding surfaces.

Therefore, the equivalent circuit of the dielectric filter 10 is as shown in FIG. 3, and a resonator is formed corresponding to each resonance electrode 14. The capacitance 26 provided between the resonance electrode 14 and the ground conductor 20 at the counter electrode 22 makes the resonance electrode 14 inductive at the resonance frequency, so that the inductive coupling M occurs between the resonators. Then, a predetermined characteristic as a filter is obtained. Also, the input / output terminals 24, 24 and the resonance electrode 1
4 between the first stage and the last stage.
Capacitive coupling by the first input / output electrodes 16 and 16 via the capacitance 28 given by and the second input / output electrodes 18 and 1 via the capacitance 30 given by the dielectric layer 12c.
Therefore, the capacitive coupling by 8 is provided in parallel.

Thus, the first and second input / output electrodes 16, 16; 1 are provided on both sides of the resonance electrode 14, respectively.
By arranging 8 and 18 and providing predetermined input / output capacitances in parallel, the pattern area of the input / output capacitance as a whole is expanded, and in addition, the resonance electrode 14 is provided.
The first and second input / output electrodes 16 and 1 on both sides thereof.
6; 18 and 18 are sandwiched and surrounded, and the impedance to the ground can be increased, so that the input / output capacity as a whole can be advantageously increased.

A resonator (specifically, the resonance electrode 1)
Since 4) will be surrounded by the input / output capacitance,
It becomes difficult to be influenced by the ground conductor 20 provided on the outer surface of the dielectric substrate 12, which makes it difficult for the pass band characteristic of the filter to be influenced by manufacturing variations, use conditions, and the like. In structure,
A vertically symmetrical pattern centered on the resonance electrode 14 has the same characteristics when mounted with either the upper surface or the lower surface facing down, and the labor for packaging and mounting can be advantageously saved. .

In the dielectric filter 10, a capacitor having a larger capacitance is formed with respect to the resonance electrode 14 to increase the input / output capacitance, thereby increasing the frequency of the signal entering the dielectric filter 10. It is possible to adapt to the optimum input / output capacity for
Thus, the performance as a filter can be advantageously improved. By the way, as shown in FIG. 4, when the input / output capacity is insufficient and smaller than the optimum value, a damping curve having two peaks such as the curve B is obtained. If the output capacitances are formed in parallel and the capacitances are adjusted to have the optimum values, the attenuation curve given by one large peak as shown by the curve A is obtained. By setting the input / output capacitance of the dielectric filter 10 to an optimum value so as to give such a curve A, high return loss, low insertion loss, and widening of the pass bandwidth can be advantageously achieved, and further, It is possible to realize a filter for low frequencies and downsize the filter.

By the way, as another measure for increasing the input / output capacitance, for example, in the dielectric filter 1 shown in FIG. Although it is conceivable to reduce the thickness of the body layer (3), thinning the sheet or tape for providing such a dielectric layer not only makes it difficult to manufacture but also weakens the strength. In addition to the problem that it is difficult to handle, there is an inherent problem that it is easily affected by manufacturing variations. Thus, as in the above example, if the two dielectric layers 12b and 12c and the two sets of input / output electrodes 16, 16; Dielectric layers 12b, 12
Since it is not necessary to thin the sheet or tape that gives c, it is easy to handle during manufacturing and is hardly affected by the variation in the thickness.

As is well known, the dielectric filter 10 shown in the above-mentioned embodiment can be easily manufactured according to a general method for manufacturing a laminated substrate, and such a dielectric filter is used. The electrodes (ground conductor 20, input / output terminal 24) on the side surface of the body filter 10 are generally formed after the layers of the dielectric substrate 12 are laminated and integrated.

Further, in the dielectric filter 10 according to the present invention, the resonance electrode 14 and the input / output electrodes 16 and 18 are provided.
Since these are completely built in the dielectric substrate 12, it is desirable to use conductors having a small specific resistance as the conductors forming these electrodes. This is because the loss in the electrode increases the loss in the pass band of the filter, and particularly when dealing with electromagnetic waves in the microwave band, the resistance of the conductor of the coupling circuit needs to be low, and therefore, A low resistance Au-based, Ag-based or Cu-based conductor is preferably used.

Thus, when Ag-based or Cu-based conductors are used, the melting points of these conductors are low and it is difficult to co-fire with ordinary dielectric materials. It is necessary to use a dielectric material that can be fired at a temperature below 1100 ° C.). Also, due to the characteristics of the device as a microwave filter, the temperature characteristic (temperature coefficient) of the resonance frequency of the formed resonance circuit is ± 50 ppm /
A dielectric material having a temperature of ℃ or less is preferable. Examples of such a dielectric material include glass-based materials such as a mixture of cordierite-based glass powder, TiO ₂ powder and Nd ₂ Ti ₂ O ₇ powder, and BaO—TiO ₂ —RE ₂ O.
There are ceramic dielectric materials such as _3- Bi ₂ O ₃ based composition (RE: rare earth component) to which a small amount of glass forming component or glass powder is added.

Although the typical embodiments of the present invention have been described above in detail, it goes without saying that the present invention is not restricted by the description of such embodiments. Further, in addition to the above-described embodiments, various changes, modifications, and improvements may be added to the present invention based on the knowledge of those skilled in the art without departing from the spirit of the present invention. Should be understood,

Then, the present invention provides a 1/4 in the dielectric substrate.
A wavelength type resonator is formed, in other words, a strip line type resonance electrode of one end short-circuit type is built in, while,
As long as an input / output electrode is provided with a predetermined capacitive coupling, it is applicable to a well-known tri-plate type dielectric filter having various structures, such as each electrode formed on the outer surface of the dielectric filter. The arrangement pattern of each built-in electrode can be changed appropriately.

Further, the ground conductor provided on the dielectric substrate may be provided not only on the outer surface of the substrate but also in a form of being inserted into the dielectric substrate for a predetermined length.
It does not matter, and even if a protective layer is formed on the ground conductor provided on the outer surface of the dielectric substrate using a known insulating material, it does not matter.

[Brief description of drawings]

FIG. 1 is an explanatory diagram showing a laminated structure of an example of a laminated dielectric filter according to the present invention.

FIG. 2 is a perspective view showing an outer electrode pattern of the dielectric filter shown in FIG.

FIG. 3 is an equivalent circuit of the dielectric filter of FIG.

FIG. 4 is a graph showing attenuation amount characteristics when the input / output capacitance of the dielectric filter has an optimum value and is smaller than the optimum value.

FIG. 5 is an explanatory diagram showing a laminated structure in an example of a conventional laminated dielectric filter.

[Explanation of symbols]

10 Dielectric Filters 12a, 12b, 12c, 12d Dielectric Layer 14 Resonance Electrode 16 First Input / Output Electrode 18 Second Input / Output Electrode 20 Earth Conductor 22 Counter Electrode 24 Input / Output Terminal 26, 28, 30 Capacitance

Claims (3)

[Claims] 1. A dielectric substrate is provided with a plurality of parallel stripline-type resonance electrodes, the input and output electrodes of which are electrically connected through a predetermined capacitance to the first and last stages of the resonance electrodes. In addition, the resonance electrode is electrically connected to a ground conductor provided on the outer surface or inside of the dielectric substrate, and the resonance electrode is electrically connected to the grounding conductor. An output electrode is a set of first input / output electrodes provided on one side of the resonance electrode in the stacking direction via a first dielectric layer, and the other of the resonance electrodes in the stacking direction. And a pair of second input / output electrodes provided via a second dielectric layer on the side of, and the corresponding ones of the first and second input / output electrodes, respectively, For one set of input / output terminals Laminated dielectric filter being characterized in that allowed gas connected. 2. The first and second input / output electrodes are provided so as to overlap each other in the stacking direction with respect to the first and last stages of the resonance electrode with a predetermined overlapping area. The laminated dielectric filter according to claim 1. 3. The first input / output electrode and the second input / output electrode are provided so as to face each other with the resonance electrode in between in the stacking direction. Item 3. A laminated dielectric filter according to item 2.