KR100961500B1 - Nose filter - Google Patents

Abstract

A signal side coil having one end connected to the signal side input terminal 6 and the other end connected to the signal side output terminal 7 in the dielectric body 1 having a plurality of dielectric layers 1x, 1a to 1g stacked therein. A capacitance component was formed between 2) and the signal side coil 2, and the ground side coil 3 whose one end was connected to the ground terminal 8 via the ground capacitance component Cg was disposed. It is easy to control the filter characteristics and the manufacturing method, and it is possible to provide a noise filter having good band characteristics in a low region with little crosstalk.

Description

Noise Filter {NOSE FILTER}

(A) is a perspective view of the noise filter of this invention, (b) is sectional drawing of the noise filter of this invention.

2 is an exploded perspective view of a portion of a laminate constituting the noise filter of the present invention.

Fig. 3A is a plan view showing a modification of the coil pattern serving as the signal side coil, and Fig. 3B is a plan view showing a modification of the coil pattern serving as the ground side coil.

4 is a characteristic diagram for comparing the characteristics of the noise filter of the present invention and the conventional noise filter, (a) shows the characteristic of the noise filter of the present invention, and (b) shows the characteristic of the conventional noise filter.

5 is an exploded perspective view of a portion of a laminate constituting a conventional noise filter.

6 is an equivalent circuit diagram of a noise filter, (a) is an equivalent circuit diagram of the noise filter of the present invention, and (b) is an equivalent circuit diagram of a conventional noise filter.

7 is an external perspective view of a multiple noise filter in the present invention.

8 is an exploded perspective view of a laminate constituting the multiple noise filter in the present invention.

9 is an equivalent circuit diagram of a multiple noise filter in the present invention.

10 is a characteristic diagram showing filter characteristics caused by displacement of the axial center of the signal-side coil of the noise filter element in the multiple noise filter disposed above and below.

11 (a) to 11 (d) are plan views showing coil patterns used for noise filter elements arranged in the vertical direction of the laminate;

12A to 12D are plan views showing coil patterns used for noise filter elements arranged in the horizontal direction of the laminate.

* Explanation of symbols for brief description of drawings *

1 laminate 1x, 1a to 1e dielectric layer

2 Signal side coil 3 Ground side coil

5 Upper and lower layer connection pattern 6, 7 Signal I / O terminal electrode

8 Ground-side terminal electrode 9 Ground conductor film

21a to 21f, 22a to 22f, 23k to 23f, 24k to 24f Signal Side Coil Pattern

31b to 31e, 32b to 32e, 33j to 33g, 34j to 34g ground side coil pattern

41f Compartmentary Conductor Film 51 ~ 54, 61 ~ 64 Signal Side I / O Terminal Electrode

8 Ground terminal electrode Ls1 to Ls4 signal side coil

Lg1 to Lg6 Ground Side Coil Cg Ground Capacity Components

The present invention relates to a distributed integer noise filter for reducing unnecessary radiation noise generated from digital devices.                         

Moreover, this invention relates to the multiple noise filter in which the several filter element was provided in one laminated body.

In recent years, with the miniaturization of electronic devices, the market demand for miniaturization and high density of component sizes is increasing. One such component is a noise filter.

A general noise filter includes a conductor coil (hereinafter simply referred to as a signal side coil) for transmitting a signal between layers of each dielectric layer in a dielectric in which a plurality of dielectric layers are stacked, and a conductor coil connected to ground (hereinafter simply referred to as a ground side). Coils) are formed respectively. The capacitance was generated between the signal side coil and the ground side coil via the dielectric layer. In addition, the connection between the coil patterns serving as the signal side coils is made through the via holes in the dielectric layer, and the connection between the coil patterns serving as the ground side coils is also made through the via holes in the dielectric layer (Japanese Patent Laid-Open No. 2000-196392).

5 is an exploded perspective view of a laminate showing a coil pattern of a conventional noise filter. In addition, in the figure, the terminal electrode is omitted. 6B is an equivalent circuit diagram of the distributed integer noise filter.

In Fig. 5, the dielectric body is formed by laminating dielectric layers 51x and dielectric layers 51a to 51f serving as upper margin layers.

The coil patterns 52a, 52c, and 52e constituting the signal side coil are formed between the dielectric layer 51x and the dielectric layer 51a, between the dielectric layer 51b and the dielectric layer 51c, and between the dielectric layer 51d and the dielectric layer 51e. It is arranged between floors. The coil patterns 52a, 52c, and 52e on the signal side between the layers include the via hole conductor and the dielectric layer 51a and the dielectric layer 51b, the dielectric layer 51c and the dielectric layer 51d, and the dielectric layer 51e and The signal-side coils are formed as a whole by connecting to each other via the upper and lower connection patterns 54b, 54d, and 54f disposed between the layers of the dielectric layer 51f.

In addition, the coil patterns 53b, 53d, and 53f constituting the ground-side coil include the interlayers of the dielectric layers 51a and 51b, the interlayers of the dielectric layers 51c and 51d, the dielectric layers 51e, and the dielectric layers 51f. Are arranged between layers. The coil patterns 53b, 53d, and 53f on the ground side between the layers are formed of the via hole conductor and the dielectric layer 51x and the dielectric layer 51a, the dielectric layer 51b and the dielectric layer 51c, and the dielectric layer 51d and The upper and lower layer connection patterns 55a, 55c, and 54e disposed between the layers of the dielectric layer 51e are connected to each other to form ground-side coils as a whole.

The equivalent circuit diagram of this noise filter is as showing in FIG.6 (b). The signal side coils are represented by L1a to L1c, and the ground side coils are represented by L2a to L2c. One end of the ground-side coil L2a is grounded, and both coils are coupled by capacitive components C1a to C1c.

As a result, a lowpass noise filter can be manufactured. When the equivalent capacitances C1a to C1c are invariable, the magnetic inductances L1a to L1c of the signal side coil and the magnetic inductances L2a to L2c of the ground side coil and the signal and ground side coils Since it is determined by mutual inductance, by this, the filter characteristic which can control a frequency characteristic arbitrarily is obtained.                         

However, in the conventional filter, since the ground-side coil is directly connected to the ground, inductance does not work in the low frequency band and acts as a capacitor with a distribution capacity. For this reason, the capacity | capacitance to deteriorate the characteristic of a desired frequency, and the attenuation of the predetermined | prescribed degree which is not necessary also occurred in the low frequency part. For this reason, there is a problem that the waveform is slowed and delayed with a high frequency signal, and the circuit does not operate.

Further, further miniaturization has been achieved, and it has become difficult to realize high cutoff frequencies and high frequency attenuation bands of required characteristics.

Moreover, in response to the market demand for miniaturization and high density of the above-mentioned component size, the market demand of the multiple noise filter which accommodates the element of several noise filter in the same board | substrate has increased rapidly.

Such a multiple noise filter has conventionally comprised the noise filter elements comprised by LC filter in parallel on a plane (for example, refer Unexamined-Japanese-Patent No. 2001-60840).

However, in the multiple noise filter having the above structure, when the number of noise filter elements increases, the planar shape of the laminate becomes large and the installation area becomes large accordingly, so that there is a problem that it does not meet the miniaturization of the recently required multiple noise filter. .

That is, it is practically difficult to construct the coil pattern from which the predetermined L (inductance) and C (capacitance) are obtained in the area | region accepted by one noise filter element.

Moreover, when the space | interval between each element was made close, there existed a problem that cross talk (leakage of a signal) between adjacent noise filter elements, specifically, between the signal side coil patterns which comprise a noise filter element becomes large.

SUMMARY OF THE INVENTION An object of the present invention is to provide an LC noise filter in which the inductor component constituting the filter is maximized, the size of the inductor component is reduced, and the frequency characteristic is increased.

Another object of the present invention is to provide a multiple noise filter that can maintain stable characteristics even if it is downsized, and which effectively presses generation of crosstalk.

The noise filter of the present invention includes a dielectric body having a plurality of dielectric layers laminated therein, a signal side input terminal electrode, a signal side output terminal electrode, and a ground terminal electrode formed on an outer surface of the dielectric body, and one end of which is connected to a signal side input terminal electrode. And a signal side coil having the other end connected to the signal side output terminal electrode and a ground side coil having a capacitance component formed between the signal side coil or one end connected to the ground terminal electrode through the ground capacitance component. .

According to the above arrangement, a ground capacitance component is added between one end of the ground-side coil and the ground terminal.

A part of the coil pattern of the signal side coil and the coil pattern of the ground side coil overlap each other through the dielectric layer in the thickness direction and are capacitively coupled to each other. As a result, the coupling degree of the signal-side coil and the ground-side coil constituting one noise filter element can be controlled by the area of the overlapping portion, so that the coupling degree of the two, i.e., the characteristics of the noise filter, can be easily adjusted. Done.

As a result, the basic equivalent circuit is as shown in FIG. Fig. 6 (b) shows the desired filter characteristics by selecting the magnetic inductance of the signal side coil and the magnetic inductance of the ground side coil and the mutual inductance of the ground and signal side coils, as compared with the equivalent circuit. It's simple to get.

Representative characteristics of the filter of the present invention are shown in Fig. 4A, and conventional filter characteristics are shown in Fig. 4B. In the characteristic of the present invention, the inductance of the signal-side coil and the ground side are applied at the low frequency portion of the characteristics of the conventional filter by the ground capacitance component (Cg) to press the current flowing back to the ground and to attenuate it at low frequency without attenuation at low frequency. Attenuation is caused by a resonant circuit formed by the inductance of the coil, the capacitance between the signal-side coil and the ground-side coil, and the ground capacitance component Cg. As a result, the cutoff frequency can be expanded to a high frequency.

As a result, the attenuation characteristics in the high frequency region can be made good by setting the inductor component to the maximum and adjusting the capacitance values of the capacitors formed by dispersing at the same time.

Therefore, the signal attenuates steeply at frequencies above the pass region, and a noise filter with a wide attenuation band can be realized.

Further, a ground capacitance component between the ground terminal electrode and the ground side coil is formed between the ground conductor film formed between the dielectric layers and a coil pattern which becomes the ground side coil facing through the ground conductor film and the dielectric layer. Doing. For this reason, this ground conductor film functions as a shield plate inside. Therefore, in forming a plurality of wiring patterns such as a bus of a microcomputer, even when the lower region of the noise filter of the present invention is used, good filter characteristics with little signal leakage can be obtained.

The multiple noise filter of the present invention includes a dielectric body having a plurality of dielectric layers laminated thereon, a signal side input terminal electrode, a signal side output terminal electrode and a ground terminal electrode formed on an outer surface of the dielectric body, and one end connected to a signal side input terminal electrode. And a signal side coil having the other end connected to the signal side output terminal electrode, and a ground side coil having a capacitance component formed between the signal side coil, and having one end connected to the ground terminal electrode. It is a multiple noise filter which is arrange | positioned at least in the up-down direction of the said laminated body, Comprising: The coil axis of the signal side coil of the noise filter arrange | positioned at the upper part, and the coil axis of the signal side coil of the noise filter arrange | positioned at the lower part mutually mutually. Characterized in that the displacement.

According to this configuration, noise filter elements in which the signal-side coil and the ground-side coil are capacitively coupled to each other are disposed in the vertical direction of the laminate. For this reason, the restriction | limiting of the pattern area of a noise filter element is eased, and the inductor and capacitance of a predetermined value can be obtained easily. Moreover, the installation area of a multiple noise filter is also miniaturized, and it can respond easily also to high density installation on wiring boards, such as a communication device and an electronic device.

In addition, since the coil axis of the signal coil constituting the upper noise filter element is displaced from the coil axis of the coil constituting the lower noise filter element, the magnetic flux is displaced in these two signal-side coils, which is unnecessary in terms of noise characteristics. The crosstalk caused by the magnetic flux between them can be effectively pressed.

This configuration can reduce the installation area of the multiple noise filter, thereby greatly contributing to the miniaturization of the multiple noise filter.

In addition, it is preferable that the noise filter element disposed above and the noise filter element disposed below are partitioned by a partition conductor film of ground potential. As a result, crosstalk due to electric field coupling between the upper noise filter element located on the upper side and the lower noise filter element located on the lower side can be prevented, so that the characteristics of each noise filter element are as designed. The stable characteristic of is obtained.

Further, one end of the ground side coil of the upper noise filter element and one end of the ground side coil of the lower noise filter element are connected to the ground terminal electrode via the partition conductor film. For this reason, the ground terminal electrode can be shared by the upper noise filter element and the lower noise filter element, and the winding of the ground coil pattern constituting the ground coil of each of the noise filter elements stacked up and down is considerably simpler. At the same time, since the potential level of the ground potential in the partition conductor film can be made constant, the ground potential in the upper noise filter element and the lower noise filter element is also stabilized, so that stabilization of characteristics can be achieved by this. have.

The coil axis of the signal-side coil of the noise filter element disposed above and the coil axis of the ground-side coil of the noise filter element disposed below are substantially coaxial, and the ground side of the noise filter element disposed above. The coil axis of the coil and the coil axis of the signal-side coil of the noise filter element disposed below may be substantially coaxial. That is, in plan view, the signal-side coil constituting the noise filter element on one side and the ground-side coil constituting the noise filter element on the other side overlap, resulting in a multiple noise filter with a minimum plane area.

Moreover, the some noise filter element may be provided in the horizontal direction of the said laminated body in the upper side and / or the lower side of the said laminated body divided by the partition conductor film. Thereby, it can be set as the multiple noise filter which has arbitrary number of elements, such as 4 elements, 6 elements, 8 elements, etc. using not only two elements but also a horizontal direction in an up-down direction. In the case where a plurality of noise filter elements are provided in the horizontal direction, at least two noise filter elements may be disposed in the vertical direction. Therefore, the number of elements of the entire noise filter element of the multiple noise filter is three elements. May be 5 elements.

Moreover, in the multiple noise filter provided in the horizontal direction, the coil axis centers of the signal side coils of the noise filter element adjacent to the horizontal direction of the said laminated body are substantially diagonal on the formation area of the said noise filter element adjacent to the said laminated body. It is preferably arranged in. Since the magnetic fluxes formed by the signal-side coils constituting each noise filter element are arranged so as not to be coupled, the spacing between the noise filter elements can be effectively limited, and crosstalk in the entire multiple noise filter can be suppressed. .

Embodiment                     

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail, referring an accompanying drawing.

(First embodiment)

1A is an external perspective view of the noise filter of the present invention, and FIG. 1B is a sectional view of the noise filter of the present invention. 2 is an exploded perspective view showing the laminated structure of the noise filter of the present invention.

In Figs. 1A, 2B and 2, reference numeral 1 denotes a laminate obtained by laminating a plurality of dielectric layers 1x, 1a to 1g and the best margin layers. 6 and 7 are signal side input / output terminal electrodes connected to the signal side coil, and 8 are ground side terminal electrodes connected to the ground conductor film 9 in the laminate. In addition, the illustration of the best margin layer is abbreviate | omitted in FIG.

The laminate 1 is constituted by stacking a plurality of dielectric layers 1x, 1a to 1g. Each dielectric layer (1x, 1a~1g) is made of a mixture of a ceramic material, or magnetic material and a crystallized glass material, such as aluminum oxide, BaTiO _3, TiO _2.

Inside the laminate 1, a signal side coil 2, a ground side coil 3, and a ground conductor film 9 are provided. The coil pattern constituting the signal side coil 2, the coil pattern constituting the ground side coil 3, the ground conductor film 9, the via hole conductor (described later), and the upper and lower layer connection patterns (described later) are, for example, It is formed of silver material or copper material.

Next, the structure of the signal side coil 2 is demonstrated based on FIG. The signal side coil 2 includes a terminal connection pattern formed on the dielectric layer 1x, a coil pattern 2a disposed between the dielectric layer 1x and the dielectric layer 1a beneath the dielectric layer 1a, and a lower portion thereof. Upper and lower layer connection patterns 4b disposed between the dielectric layers 1b, coil patterns 2c disposed between the dielectric layers 1b and the dielectric layers 1c below, the dielectric layers 1c, and the dielectric layers 1d thereunder. The upper and lower layer connection patterns 4d disposed therebetween, the coil pattern 2e disposed between the dielectric layer 1d and the dielectric layer 1e beneath, the dielectric layer 1e and the dielectric layer 1f disposed thereunder. The upper and lower layer connection patterns 4f, and the terminal connection patterns arranged between the dielectric layer 1f and the dielectric layer 1g are constructed. Each coil pattern and the upper and lower layer connection patterns are connected to each other via a via hole conductor shown by a dotted line in the figure. The terminal connection pattern is connected to the signal side input / output terminal electrodes 6 and 7.

In addition, the ground-side coil 3 is a coil disposed between the upper and lower layer connection patterns 5a disposed between the dielectric layer 1x and the dielectric layer 1a below and the dielectric layer 1a and the dielectric layer 1b below. The pattern 3b, the upper and lower connection patterns 5c disposed between the dielectric layer 1b and the dielectric layer 1c thereunder, and the coil pattern 3d disposed between the dielectric layer 1c and the dielectric layer 1d below. And an upper and lower layer connection pattern 5e disposed between the dielectric layer 1d and the dielectric layer 1e thereunder, and a coil pattern 3f disposed between the dielectric layer 1e and the dielectric layer 1f below. have. These coil patterns and the upper and lower layer connection patterns are connected to each other through a via hole conductor shown by a dotted line in the figure. The coil pattern 3f between the dielectric layer 1e and the dielectric layer 1f faces the ground conductor film 9 disposed between the dielectric layer 1f and the dielectric layer 1g. For this reason, the ground side coil 3 forms a ground capacitance component. The ground conductor film 9 is connected to the ground side terminal electrode 8.

As a result of the above structure, the noise filter of this invention consists of the signal side coil 2 which consists of L1a-L1c, and L2a-L2c inside the laminated body 1, as shown to Fig.6 (a). The ground-side coil 3 is formed, and a capacitance component composed of C1a to C1c is formed therebetween, and the ground capacitance component Cg is provided between one end of the ground-side coil 3 and the ground terminal electrode 8. ) Is formed.

6B is an equivalent circuit diagram of a conventional noise filter, and the ground-side coil 3 is grounded at one end thereof.

Next, the shape of the coil pattern which comprises such a signal side coil 2 and the ground side coil 3 is demonstrated in detail, referring FIG.

Attention is directed to the dielectric layer 1c on which the coil pattern 2c constituting the signal side coil 2 is mounted. The coil pattern 2c has a substantially rectangular shape, and is composed of a capacitance forming region 21 and two inductor forming portions 22 and 23 extending from the capacitance forming region 21 to one end side (left side in the drawing). have. In addition, the two conductors 24 and 25 extending from the capacitance formation region 21 to the other short side (right side in the drawing) serve as auxiliary portions of the capacitance formation region.

Next, attention is paid to the dielectric layer 1b on which the coil pattern 3b constituting the ground side coil 3 is mounted. The coil pattern 3b has a substantially rectangular shape and is composed of a capacitance forming region 31 and two inductor forming portions 32 and 33 extending from the capacitance forming region 31 to the other short side (right side in the drawing). It is. In addition, the two conductors 34 and 35 extending from the capacitance formation region 31 to one short side (left side in the drawing) serve as auxiliary portions of the capacitance formation region.

Both coil patterns 3b and 2c face each other through the dielectric layer 1b. That is, the capacitance formation region 21 of the coil pattern 2c and the capacitance formation region 31 of the coil pattern 3b face each other. In addition, the inductors 22 and 23 of the coil pattern 2c and the conductors 34 and 35 of the coil pattern 3b face each other. The inductors 32 and 33 of the coil pattern 3b and the conductors 24 and 25 of the coil pattern 2c face each other.

For this reason, a predetermined capacitance component is formed between both coil patterns 3b and 2c. As a result, both are capacitively coupled.

The same also applies to coil patterns other than those formed between layers of adjacent dielectric layers.

In addition, the upper and lower layer connection patterns 5a and 5c of the ground-side coil 3 are band-shaped so as to overlap the two inductor portions 32 and 33 of the coil pattern 3b to be the ground-side coils disposed in the intermediate dielectric layer. It is formed. One end side of the upper and lower layer connection patterns 5a is, for example, an inductor unit at one end side of the coil pattern 3b through a via hole conductor (shown by a dotted line) passing through the thickness of the dielectric layer 1a positioned below. It is connected to (32). Further, one end side of the upper and lower layer connection patterns 5c is connected to the inductor portion 33 on the other end side of the coil pattern 3b through a via hole conductor (indicated by a dotted line) that passes through the thickness of the dielectric layer 1b positioned above. Connected.

In addition, the ground conductor film 9 is formed on substantially the entire surface on the dielectric layer 1g so as not to short-circuit with the terminal connection pattern of the signal side coil 2. The ground conductor film 9 and the coil pattern 3f of the ground side coil 3 face each other via the dielectric layer 1f. As a result, a predetermined ground capacitance component Cg (see Fig. 6A) is formed between the coil pattern 3f and the ground conductor film 9, and both are capacitively coupled. The ground conductor film 9 extends from a part of the long side thereof and is connected to the ground side terminal electrode 8 formed on the outer surface of the laminate 1.

In Fig. 2, the signal-side coil 2 is approximately three turns in total, and the ground-side coil 3 is also represented by approximately three turns, and there is no significant difference in the number of turns (magnetic inductance).

However, some differences may be made in order to control the attenuation frequency. In this way, when the equivalent capacitance is invariant, the magnetic inductance of the signal side coil 2 and the magnetic inductance of the ground side coil 3 and the mutual inductance of the signal side coil 2 and the ground side coil 3 are arbitrarily selected. The filter characteristic which can be controlled and can arbitrarily control frequency characteristics, such as the attenuation frequency of a noise filter, is obtained.

The inductor sections 22, 23, 32, 33 formed in each of the coil patterns 2a, 2c, 2e, 3b, 3d, and 3f of this embodiment extend the same length on each end side. Moreover, it has a capacitance formation area in the center part side of each other.

The coil pattern portion of each coil is substantially rectangular in shape in plan view, and occupies half of the planar shape of the dielectric layer. Thereby, the planar shape which matched the signal side coil 2 and the ground side coil 3 can be approximated substantially to the planar shape of a dielectric layer.

As a result, the inner area of the coil composed of the coil patterns 2a, 2c, 2e, 3b, 3d and 3f of the dielectric layers 1a to 1e and the upper and lower layer connection patterns 4b, 4d, 4f, 5a, 5c and 5e is obtained. It can be made largest and the dead space around a coil can be minimized. For this reason, the inductance component of a coil can be maximized and the shape of the dielectric layers 1a-1e can be miniaturized, and, thereby, the compact laminated body 1 can be achieved.

Next, the laminated body 1 of the structure mentioned above is made with the following manufacturing methods.

First, the dielectric sheets serving as the dielectric layers 1x, 1a to 1g of the laminate 1 are homogeneously kneaded with a ceramic powder containing at least BaTiO ₃ and TiO ₃ as dielectric materials and an organic vehicle, and have a predetermined thickness (20 μm to 100 μm). Tape or sheet is molded and cut to a predetermined size.

Next, the through hole (hole diameter 50 μm to 200 μm) serving as a via hole conductor is punched at a predetermined position of the dielectric sheet (a position which becomes an end portion of the upper and lower layer connection patterns 4b to 4f and 5a to 5e). To form.

Next, a conductive paste obtained by homogeneously mixing a low-melting-point glass frit and an organic vehicle with Ag-based (Ag-based, Ag-alloy such as Ag-Pd) or Cu-based material in the above-mentioned through hole. It fills and forms a via-hole conductor. On the surface of the sheet, the conductor film to be the coil patterns 2a, 2c and 2e to be the signal side coils, the conductor film to be the coil patterns 3b, 3d and 3f to be the ground side coils, and the upper and lower layer connection patterns 5a, The conductor film which becomes 5c, 5e, 4b, 4d, 4f) is formed in thickness of 1 micrometer-20 micrometers by screen printing of the above-mentioned conductive paste.

Moreover, the conductor film used as the ground conductor film 9 and the conductor film used as a terminal connection pattern are similarly formed in the thickness of 1 micrometer-20 micrometers by screen printing of the above-mentioned conductive paste on the dielectric sheet used as a lowermost layer. Further, a conductor film serving as a terminal connection pattern is similarly formed on the dielectric sheet serving as the dielectric layer 1x.

Next, each dielectric sheet is selectively laminated in consideration of the lamination procedure shown in FIG. 2 and integrated by thermocompression bonding. Thereafter, if necessary, the cutting groove is cut to the final dimension in consideration of sintering shrinkage, or a dividing groove for dividing in the final step is formed.

Next, the laminate formed of the dielectric sheet is fired at a predetermined atmosphere and a predetermined peak temperature. When the Ag-based conductive paste is used for the above-mentioned conductive paste, it is treated with an oxidative atmosphere or a heavy component crisis, and when a Cu-based conductive paste is used, it is treated with a reducing or a heavy component crisis. In addition, the peak temperature is treated to a temperature necessary for the dielectric sheet to sinter.

In this way, the firing process of the conductive paste is carried out on the laminated body 1 subjected to the firing treatment, via-conductors exposed on the outer surface of the laminated body 1, and conductor films serving as the terminal electrodes 6, 7, 8 on the exposed portions of the conductor. It forms by, and plating-processes on the surface of the conductor film after that.

3A and 3B show plan views of two kinds of dielectric layers 1Y and 1Z used in another noise filter of the present invention. In the dielectric layer 1Y, the coil pattern 2Y constituting the signal side coil and the upper and lower layer connection patterns 5Y constituting the ground side coil are formed. In the dielectric layer 1Z, the coil pattern 3Z constituting the ground side coil and the upper and lower layer connection patterns 4Z constituting the signal side coil are formed.

In FIG. 3, the conductors 24, 25, 34, 35 which are the auxiliary capacitance formation areas of the coil pattern shown in FIG. 2 are not formed. That is, the coil pattern is substantially in the "H" shape in FIG. 2, but is substantially in the "C" shape in FIG. This coil pattern is used when the capacitive component formed between both coils is unnecessary or at least good.

As described above, in the present invention, the ground capacitance component Cg between the ground-side coil 3 and the ground terminal 8 and between the ground conductor film 9 and the coil pattern 3f (Fig. 6 (a)). Reference). In this way, by adding the ground capacitance component Cg, the filter characteristic of the low frequency region can be improved.

(Example)

This inventor measured the characteristic with the noise filter of this invention, and the conventional noise filter which has the coil pattern with the coil turns, dimensions, etc. which are shown in FIG.

Fig. 4A is a characteristic of the noise filter of the present invention, and Fig. 4B is a characteristic of the conventional noise filter. The horizontal axis represents frequency (MHz) and the vertical axis represents attenuation amount (dB). From these figures, it is understood that the characteristic of the present invention is that the attenuation up to the low range of the frequency, for example, about 500 MHz is not so large, and that the attenuation poles can be formed rapidly at higher frequencies, so that a sufficient amount of attenuation is obtained in a wide frequency band. Can be.                     

This indicates that the present invention is a noise filter having a high degree of freedom in which the conventional filter characteristics can be arbitrarily set, and means that the attenuation characteristics in the low frequency range are remarkably improved.

In the characteristics of the present invention, the inductance of the signal-side coil at the frequency of suppressing the current flowing back to the ground in the low frequency portion of the characteristics of the conventional filter to suppress the current flowing back to the ground and not attenuate it at the low frequency, Attenuation is caused by the resonance circuit formed by the inductance of the ground-side coil, the capacitance between the signal-side coil and the ground-side coil, and the ground capacitance component Cg.

This embodiment is an example as a noise filter, and the characteristic is suitably optimized by the circuit structure used. Also in the equivalent circuit shown to Fig.6 (a), the value of each element is suitably selected by the filter characteristic and shape calculated | required, and is not limited to a threshold value or a combination of those values.

(2nd embodiment)

Next, the structure and the characteristic of the multiple noise filter of this invention are demonstrated.

In addition, in description, inside a laminated body, two noise filter elements are arrange | positioned in the up-down direction, and two noise filter elements are arrange | positioned in the horizontal direction, and the quadruple noise filter provided with four noise filter elements in total is shown. This will be described as an example. The first noise filter element and the third noise filter element are respectively disposed in the up and down direction in the laminate, the second noise filter element and the fourth noise filter element are respectively disposed in the up and down direction in the laminate, and the first noise filter element And the second noise filter element are arranged in the lateral direction in the laminate, and the third noise filter element and the fourth noise filter element are arranged in the lateral direction in the laminate.

Fig. 7 is an external perspective view of the multiple noise filter of the present invention, and Fig. 8 is an exploded perspective view showing the laminated structure of the multiple noise filter. 9 is an equivalent circuit of a multiple noise filter.

The multiple noise filter includes a laminate 1 including first to fourth noise filter elements, signal side input / output terminal electrodes 51 and 61 of the first noise filter element formed on the outer surface of the laminate 1, Signal side input / output terminal electrodes 53, 63 of the second noise filter element, signal side input / output terminal electrodes 52, 62 of the third noise filter element, signal side input / output terminal electrodes 54, 64 of the fourth noise filter element And ground side terminal electrodes 8 having common first to fourth noise filter elements are formed.

The laminated body 1 is comprised by laminating | stacking the dielectric layers 1a-1k which consist of dielectric materials, such as barium titanate and a barium titanium zirconate, and the dielectric layer used as the upper and lower margin layers abbreviate | omitted in FIG. Coil patterns and conductor films are formed in the dielectric layers 1a to 1k.

When one noise filter element is noticed, the signal side coil and the ground side coil are coupled to each other through a capacitive component. And four such noise filter elements are mounted.

In the equivalent circuit of four multiple noise filters, as shown in FIG. 9, the signal side coil Ls1 and the ground side coil Lg1 which comprise the 1st noise filter element are couple | bonded with the capacitance component C1. Also for the second noise filter element, the signal side coil Ls2 and the ground side coil Lg2 are coupled by the capacitive component C2. Similarly, the signal-side coils Ls3 and Ls4 and the ground-side coils Lg3 and Lg4 are coupled to the third and fourth noise filter elements by the capacitive components C3 and C4, respectively.

Referring to Fig. 8, between the layers of the dielectric layers 1a to 1k, the signal side coil patterns 21a to 21f, 22a to 22f, which constitute the signal side coils Ls1 to Ls4 of the first to fourth noise filter elements, 23f to 23k, 24f to 24k, and ground side coil patterns 31a to 31f, 32a to 32f, 33j to 33f, and 34i to 24f that form the ground side coils Lg1 to Lg4 are formed.

Specifically, the first noise filter element is composed of the signal side coil Ls1 composed of the signal side coil patterns 21a to 21f formed on the dielectric layers 1a to 1f, and the ground side coil patterns 31b to 31e. It consists of the ground-side coil Lg1.

In addition, the second noise filter element includes a signal side coil Ls2 composed of signal side coil patterns 22a to 22f formed on the dielectric layers 1a to 1f, and a ground side coil composed of ground side coil patterns 32b to 32e. It consists of (Lg2).

Similarly, the third noise filter element includes a signal side coil Ls3 composed of signal side coil patterns 23f to 23k formed on dielectric layers 1f to 1k, and a ground side coil composed of ground side coil patterns 33g to 33j. It consists of (Lg3).

The fourth noise filter element includes the signal side coil Ls4 composed of the signal side coil patterns 24f to 24k formed on the dielectric layers 1f to 1k, and the ground side coil Lg4 composed of the ground side coil patterns 34g to 34j. )

Then, the signal side coil patterns 21a to 21f, 22a to 22f, 23f to 23k, 24f to 24k, and the first to the first, which constitute the signal side coils Ls1 to Ls4 in the first to fourth noise filter elements. The ground-side coil patterns 31a to 31f, 32a to 32f, 33g to 33j, and 34g to 33j constituting the ground-side coils Lg1 to Lg4 of the noise filter element have one end of each coil pattern to form a coil of a predetermined turn. The other end of the coil pattern adjacent to the thickness direction is connected via a via hole conductor.

Here, on the dielectric layer 1f, the noise filter elements positioned above and below, i.e., the first noise filter element and the third noise filter element, which are located at the ground potential common to each noise filter element, are simultaneously formed with the second noise filter element and the first noise filter element. A partition conductor film 41f is formed which partitions four noise filter elements.

The partition conductor film 41 is connected to the ground-side coils Lg1 to Lg4 constituting each noise filter element via the capacitance component Cg. For example, the coil pattern 31e of the ground-side coil Lg1 constituting the first noise filter element and the partition conductor film 41f are grounded through the dielectric layer 1e and further constitute the second noise filter element. The coil pattern 32e and the partition conductor film 41f of the side coil Lg2 pass through the dielectric layer 1e and further partition the coil pattern 33g of the ground coil Lg3 constituting the third noise filter element. The conductor film 41f passes through the dielectric layer 1f and the coil pattern 34g of the ground-side coil Lg4 constituting the fourth noise filter element and the partition conductor film 41f respectively pass through the dielectric layer 1f. Connected.

In this embodiment, the partition conductor film 41f and the coil patterns 31e, 32e, 33g, and 34g of each ground-side coil are connected via the capacitive component. In this embodiment, the partition conductor film 41f is connected. ) And the coil hole 31e, 32e, 33g, 34g, the edge part in which the via-hole conductor is not formed may be connected directly via a via-hole conductor.

The signal side coil Ls1 constituting the first noise filter element is connected to, for example, the signal side input terminal electrode 61 through the coil pattern 21a formed in the dielectric layer 1a, and the dielectric layer 1f. It connects to the signal side output terminal electrode 51, for example through the coil pattern 21f provided in the figure. Similarly, the signal side coil Ls2 constituting the second noise filter element is connected to, for example, the signal side input terminal electrode 53 through the coil pattern 22a formed on the dielectric layer 1a, and the dielectric layer 1f. It connects to the signal side output terminal electrode 63, for example through the coil pattern 22f provided in the figure. Further, the signal side coil Ls3 constituting the third noise filter element is connected to the signal side input terminal electrode 52, for example, via the coil pattern 23k formed on the dielectric layer 1k, and the dielectric layer 1f. It connects to the signal side output terminal electrode 62, for example through the coil pattern 23f provided in the figure. Similarly, the signal side coil Ls4 constituting the fourth noise filter element is connected to, for example, the signal side input terminal electrode 64 via the coil pattern 24k formed in the dielectric layer 1k, and the dielectric layer 1f. It connects to the signal side output terminal electrode 54, for example through the coil pattern 24f provided in the figure.

Here, the characteristic is that the first noise filter element and the third noise filter element arranged in the vertical direction are simultaneously arranged by the partition conductor film 41f in the second noise filter element and the fourth noise filter arranged in the vertical direction. The element is partitioned by the partition conductor film 41f.                     

Referring to Fig. 8, the internal structure of the laminate 1 will be described in more detail, so that approximately 3/4 turn is applied between the layers of the dielectric layer 1a and the dielectric layer 1b, for example, on the dielectric layer 1b. Coil patterns 21b and 22b constituting the signal-side coils Ls1 and Ls2 of the first and second noise filter elements having a shape (or a shape) and a substantially I-shape to be about 1/4 turn. Coil patterns 31b and 32b constituting the ground-side coils Lg1 and Lg2 of the first and second noise filter elements are arranged.

Further, the signal-side coils Ls1 and Ls2 of the first and second noise filter elements having substantially I-shape to be about 1/4 turn between the layers of the dielectric layer 1b and the dielectric layer 1c, for example, on the dielectric layer 1c. ) And the ground side coils Lg1 and Lg2 of the first and second noise filter elements having substantially H-shapes (or U-shapes) so as to be about 3/4 turns. Coil patterns 31c and 32c are arranged.

One end of the signal side coil pattern 21b of the signal side coil Ls1 constituting the first noise filter element is connected to the other end of the signal side coil pattern 21c by a via hole conductor (dotted line). The coil of about 1 turn is formed by this. Similarly, also in the ground-side coil Lg1, one end of the ground-side coil pattern 31b is connected to the other end of the ground-side coil pattern 31c by a via hole conductor (dotted line), whereby a coil of about one turn Is formed. The same applies to the third noise filter element. The same applies to the coil pattern in which the coil pattern of such a connection structure is formed in the dielectric layers 1d and 1e.

That is, the other end of the signal side coil pattern 21a of the signal side coil Ls1 of the first noise filter element is connected to the signal side input terminal electrode 61, for example, and one end of the signal side coil pattern 21a is provided. The other end of the signal side coil pattern 21b is connected to the other end of the signal side coil pattern 21b via the via hole conductor, and the other end of the signal side coil pattern 21c is connected to the other end of the signal side coil pattern 21b via the via hole conductor. One end of the signal side coil pattern 21d is connected to the other end of the signal side coil pattern 21d via the via hole conductor, and one end of the signal side coil pattern 21d is connected to the other end of the signal side coil pattern 21e via the via hole conductor. One end of the coil pattern 21e is connected to the other end of the signal side coil pattern 21f via a via hole conductor, and one end of the signal side coil pattern 21f is connected to the signal side output terminal electrode 51, for example. The ground coil Lg1 of the first noise filter element has the ground coil pattern 31b as a starting end, and one end of the ground coil pattern 31b is connected to the other end of the ground coil pattern 31c through the via hole conductor. One end of the ground side coil pattern 31c is connected to the other end of the coil pattern 31d via the via hole conductor, and one end of the ground side coil pattern 31d is connected to the ground side coil pattern 31e via the via hole conductor. The ground-side coil pattern 31e is connected to the partition conductor film 41f at which the ground-side coil pattern 31e becomes a ground potential with respect to the dielectric layer 1e through the capacitor component Cg, and the ground potential terminal electrodes 7 and 8 are connected. Is connected to.

As a result, the first noise filter element disposed on the upper side of the partition conductor film 41f has a signal side coil Ls1 of about 2 turns (although the number of turns increases due to the coil pattern connected to the terminal electrode), It is formed by the ground side coil Lg1. For example, the coil pattern 21b of the signal side coil and the coil pattern 31c of the ground side coil, which are arranged with the dielectric layer 1b interposed therebetween, face each other, and a part of the coupling capacitance Cg Occurs. Similarly, a part of the coupling capacitance Cg is formed in the other dielectric layer 1c to 1e portion, and these capacitance components are synthesized to form the signal side coil Ls1 and the ground side coil Lg1 constituting the first noise filter element. ) Is the combined capacitance component (Cg). The same applies to the second noise filter element.

Here, the axis of the signal-side coil Ls1 constituting the first noise filter element (center line in the longitudinal direction of the wound coil) and the ground-side coil Lg1, the axis of the signal-side coil Ls1 is It is formed in the ground depth side of FIG. 8, and the shaft center of the ground-side coil Lg1 is formed in front of the paper surface of FIG. 8, and is not arrange | positioned so that the shaft centers of both coils Ls1 and Lg1 may overlap each other.

Moreover, when looking at the axial center of each coil of a 2nd noise filter element, the axial center of the signal side coil Ls2 is formed in front of the paper surface of FIG. 8, and the axial center of the ground-side coil Lg2 is located on the paper depth side of FIG. It is formed and is not arrange | positioned so that both shaft centers may mutually overlap.

The shape of the partition conductor film 41f at the ground potential described above is formed in a beta shape so as to match the magnetic inductances of the ground-side coil patterns 31e and 32e.

Similarly to the first noise filter element and the second noise filter element described above, the third noise filter element is also weakly applied to the dielectric layers 1g to 1k stacked below the dielectric layer 1f on which the partition conductor film 41f is formed. A two-turn strong signal-side coil Ls3 and about two-turn ground-side coils Lg3 coupled to the signal-side coil Ls3 as capacitive components C3. The signal-side coil Ls4 of the two-turn steel and the ground-side coil Lg4 of about two turns coupled to the signal-side coil Ls4 by the capacitance component C4.

Here, in the third and fourth noise filter elements, the ground-side coils Lg3 and Lg4 are capacitively coupled to the partition conductor film 41f of the dielectric layer 1f to the terminal electrodes 7 and 8 at ground potential. Connected.

One end of the third and fourth signal side coils Ls3 and Ls4 is connected to, for example, the signal side input terminal electrodes 53 and 64 through the coil patterns 23k and 24k formed on the dielectric layer 1k. The other ends of the third and fourth signal side coils Ls3 and Ls4 are connected to, for example, the signal side output terminal electrodes 63 and 54 through the coil patterns 23f and 24f formed on the dielectric layer 1f. It is.

When the shaft center of the signal-side coil Ls3 and the ground-side coil Lg3 constituting the third noise filter element are viewed, the shaft center of the signal-side coil Ls3 is formed on the front side of the paper in FIG. The shaft center of the coil Lg3 is formed on the paper depth side of FIG. 8, and is not arrange | positioned so that the shaft center of both coils Ls3 and Lg3 may overlap with each other. In addition, when looking at the axial center of each coil of a 4th noise filter element, the axial center of the signal side coil Ls4 is formed in the paper surface depth side of FIG. It is formed and is not arrange | positioned so that both shaft centers may mutually overlap.

In addition, all the coil patterns formed on the dielectric layers 1a to 1k, and the via hole conductors formed in the thickness direction of the dielectric layers 1a to 1k are made of Ag (Ag alone or Ag alloy) or Cu (Cu alone or Cu alloy). It consists of conductor which has a main component. Further, the signal side input / output terminal electrodes 51 to 54, 61 to 64 and the ground side terminal electrodes 7 and 8 are formed on the lower conductor film containing Ag or the like as the main component, such as Ni plating or solder plating on the surface thereof. You may form a layer.

In the present invention, for example, arranged above and below the stacked body 1, in the first noise filter element and in the third noise filter element, the axis of the signal side coil Ls1 constituting the first noise filter element is included. The first noise filter element and the third noise filter element are disposed so that the axis of the signal-side coil Ls3 constituting the third noise filter element is displaced. That is, the shaft center of the signal-side coil Ls1 constituting the first noise filter element is formed on the surface depth side of FIG. 8 (the shaft center of the ground-side coil Lg1 is formed on the front side of the paper in FIG. 8). The axis of the signal-side coil Ls3 of the three noise filter element is formed on the front side of the paper sheet in FIG. 8 (the axis of the ground-side coil Lg3 is formed on the paper depth side in FIG. 8), and the first noise filter. The axis of the signal-side coil Ls1 constituting the element and the axis of the signal-side coil Ls3 constituting the third noise filter element are arranged so as not to substantially overlap each other.

The same applies to the second noise filter element and the fourth noise filter element disposed above and below the right side of the laminate 1.

Such a multiple noise filter forms a through hole serving as a via hole conductor at a predetermined position of the green sheet to be the dielectric layers 1a to 1k, fills the through hole with a conductive paste, and has a predetermined shape on the surface of the green sheet. The conductor film to be a coil pattern or the conductor film to be a partition conductor film is formed by printing conductive paste, and then the green sheet and the green sheet to be the upper and lower margin layers are laminated and pressed in a predetermined lamination order, and the unbaked laminate Is cut and calcined at 800 to 1050 캜 to form the laminate 1. Thereafter, the conductor films serving as the terminal electrodes 51 to 54 and 61 to 64 are formed on the substantially flat surface of the laminate 1 by firing and plating.

In this way, if only the noise filter elements arranged in the up-down direction are implanted, both ends of the signal-side coil and the ground-side coil of each noise filter element are slightly different in shape depending on the connection structure with the terminal electrode. The coil pattern shown to (d) is used. 11, the white coil pattern shows the coil pattern of the signal side coil, for example, and the black coil pattern shows the coil pattern of the ground side coil, for example.

That is, the upper noise filter element is constituted by the coil patterns shown in Figs. 11A and 11B, and the lower noise filter element is formed by the coil patterns shown in Figs. 11C and 11D. It consists of.

That is, the signal side coils constituting the upper noise filter element are constituted by the coil patterns S1 and S1 ', and the ground side coils are constituted by the coil patterns G1 and G1'. The signal side coil constituting the lower noise filter element is constituted by coil patterns S3 and S3 ', and the ground side coil is constituted by coil patterns G3 and G3', and as described above, the upper noise filter element It is possible to displace the axis of the signal side coil Ls1 constituting the circuit and the axis of the signal side coil Ls3 constituting the lower noise filter element. From this, in Figs. 11A to 11D, the signal side coils and the ground side coils constituting the noise filter elements located at the upper and lower portions may be the upside down pattern in the drawing of Fig. 11. In any case, since the axial centers of the signal side coil Ls1 of the upper noise filter element and the signal side coil Ls3 constituting the lower noise filter element are displaced, the first noise filter element is constituted, for example. The magnetic flux passing through the axial center of the signal side coil Ls1 to be applied to the signal side coil Ls3 constituting the third noise filter element disposed below the signal side coil Ls1 constituting the first noise filter element. The impact can be minimized.

In addition, as described above, the first noise filter element and the third noise filter element positioned below the first noise filter element are substantially disposed in the partition conductor film 41f having the ground potential formed in the dielectric layer 1f. Therefore, since the electric field is also cut off, since the influence of the electric field can be reduced simultaneously with the reduction of the influence of the above-described magnetic field, the desired characteristics as designed together with the first noise filter element and the third noise filter element. Can be maintained, the stabilization of characteristics can be measured, and at the same time, two noise filter elements can be arranged in one element formation region, so that the installation area can be reduced.

FIG. 10 is a characteristic diagram showing a change in frequency attenuation characteristics due to cross talk of two noise filter elements arranged in the up-down (thickness) direction in the same laminated body 1 in the multiple noise filter of this invention comprised in this way. . In FIG. 10, T2 shown by a solid line is a characteristic of the multiple noise filter which arranged the signal side coil of the noise filter element arrange | positioned in the up-down direction in the same laminated body 1 so that it may become substantially the same axis, and is shown by the dotted line. T1 is a characteristic when the axial centers of the signal-side coils of the noise filter element are displaced from each other like the first noise filter element and the third noise filter element (or the second noise filter element, the fourth noise filter element) of the present invention. to be.

As can be understood from FIG. 10, in the case where the shaft centers of the signal-side coils constituting the noise filter element are displaced, deterioration of the attenuation characteristic due to cross talk is improved, particularly in a band with a frequency of 50 MHz or more.

In addition, in order to improve the high frequency characteristics of the multiple noise filter, the coil pattern, the partition conductor film 41f, and the terminal electrodes 51 to 54 and 61 to 64 are made of a Cu-based material, and the material of the dielectric layers 1a to 1k. Calcium zirconate titanate or the like may be used as the non-reducing dielectric material of the main component oxide. A crude material such as a glass material capable of low-temperature firing may be added to the composite oxide.

In FIG. 8 and FIG. 11 mentioned above, the coil pattern of the signal side coil of the noise filter element arrange | positioned at the upper side in the laminated body 1, the coil pattern of the ground side coil, and the noise filter arrange | positioned under this noise filter element. The relationship between the coil pattern of the signal-side coil of the element, the coil pattern of the ground-side coil and the action of the partition conductor film were described.

As shown in Fig. 8, in the noise filter element of four elements, coil patterns of other noise filter elements are formed on the same plane of the dielectric layer. In this case, for example, the coil patterns of the signal side coils and / or the ground side coils of the two noise filter elements formed on the dielectric layer 1b are four patterns shown in Figs. 12A to 12D. For example. 12 (a) to 12 (d), the white coil pattern represents, for example, the coil pattern of the signal side coil, and the black coil pattern represents, for example, the coil pattern of the ground side coil. It is shown. In addition, SO has shown the axial part of a signal coil in a figure.

FIG. 12A is a coil pattern shown in FIG. 8. In this case, the two noise filter elements, for example, the first noise filter element and the second noise filter element, which are provided in parallel, are coiled so that the axis of the signal-side coils Ls1 and Ls2 are diagonal to each other in the rectangular dielectric layer 1b. Patterns S1, S2, G1, and G2 are formed. The coil pattern of the 3/4 pattern on the dielectric layer 1b is the coil patterns S1 and S2 of the signal side coil.

12 (b) shows two noise filter elements, for example, a first noise filter element and a second noise filter element, wherein the axis of the signal-side coils Ls1 and Ls2 has a rectangular dielectric layer 1b. Coil patterns S1, S2, G1, and G2 are formed so as to be parallel to each other. In the coil pattern of the 3/4 pattern on the dielectric layer 1b, the coil pattern S1 of the signal side coil and the coil pattern G2 of the ground side coil are mixed.

FIG. 12C shows two noise filter elements, for example, a first noise filter element and a second noise filter element, wherein the axis of the signal-side coils Ls1 and Ls2 is rectangular to each other in a rectangular dielectric layer 1b. Coil patterns S1, S2, G1, and G2 are formed so as to be parallel to each other. Moreover, the coil pattern of the 3/4 pattern on this dielectric layer 1b becomes the coil patterns S1 and S2 of the signal side coil.

12 (d) shows two noise filter elements, for example, a first noise filter element and a second noise filter element, wherein the axis of the signal-side coils Ls1 and Ls2 has a rectangular dielectric layer 1b. The coil patterns S1, S2, G1, and G2 are formed so as to be in a diagonal shape. In the coil pattern of the 3/4 pattern on the dielectric layer 1b, the coil pattern S1 of the signal side coil and the coil pattern G2 of the ground side coil are mixed.

12, only the dielectric layer 1b is shown, but in the coil pattern of the dielectric layer 1c, the coil pattern of 3/4 pattern turns into a coil pattern of 1/4 pattern.                     

12, the magnetic flux passing through the axial center of the signal side coil Ls1 of the first noise filter element and the axial center of the signal side coil Ls2 of the second noise filter element does not influence each other. It is preferable that the axial centers SO are positioned on a diagonal line with each other, for example, the pattern of FIG. 12A and the pattern of FIG. 12D are preferable. 12 (b) and 12 (c), the axis of the signal side coil Ls1 of the first noise filter element and the axis of the signal side coil Ls2 of the second noise filter element are provided in parallel. In this case, the distance between the noise filter elements may be widened to such an extent that the magnetic flux passing through the axial center of the signal-side coil does not influence each other.

The implementation of the present invention is not limited to the above embodiment. Various changes can be made within the scope of the present invention. For example, in the above-mentioned Example, although the noise filter element was arrange | positioned at the upper and lower two stages in the laminated body, you may laminate | stack a noise filter element in three or more stages. In this case, for example, the odd-numbered noise filter elements may have the same axis center of the signal-side coil, and may be different from that of the signal-side coil of the even-numbered noise filter element.

In the second embodiment, the first to fourth noise filter ground side coils Lg1 to Lg4 were grounded through the ground capacitance component Cg. However, it is not limited to this embodiment, and the ground-side coils Lg15 to Lg4 may have a structure which is directly grounded to a ground potential such as the partition conductor film 41f through a via hole conductor passing through the dielectric layer. Even in this structure, by displacing the magnetic flux in the upper and lower signal side coils, the effect of the present invention is effectively realized that the crosstalk caused by the magnetic flux between the two is unnecessary due to the noise characteristics.

As described above, according to the present invention, it is possible to provide an LC noise filter having a high frequency characteristic while achieving miniaturization by minimizing the inductor component constituting the filter to reduce the distribution capacitance value.

In addition, according to the present invention, it is possible to provide a multiple noise filter which can maintain stable characteristics even if it is downsized, and which effectively presses generation of crosstalk.

Claims (23)

A laminate in which a plurality of dielectric layers are stacked; A signal side input terminal electrode, a signal side output terminal electrode, and a ground terminal electrode formed on an outer surface of the laminate; A signal side coil having one end connected to the signal side input terminal electrode and the other end connected to the signal side output terminal electrode; And And a ground side coil having a capacitance component formed between said signal side coil and one end thereof connected to said ground terminal electrode via a ground capacitance component. The coil of claim 1, wherein the signal side coil and the ground side coil are formed of a coil pattern formed between the plurality of dielectric layers, The capacitance component between the signal side coil and the ground side coil is formed between the coil pattern serving as the signal side coil and the coil pattern serving as the ground side coil disposed with the dielectric layer therebetween, The ground capacitance component between the ground terminal electrode and the ground-side coil is formed between a ground conductor film formed between the dielectric layers and a coil pattern that becomes the ground-side coil facing through the ground conductor film and the dielectric layer. Noise filter. The noise filter according to claim 1 or 2, wherein upper and lower layer connection patterns constituting a part of the coil pattern serving as the ground side coil are formed in the dielectric layer having the coil pattern serving as the signal side coil. . The noise layer according to claim 1 or 2, wherein upper and lower layer connection patterns constituting a part of the coil pattern serving as the signal side coil are formed in the dielectric layer in which the coil pattern serving as the ground side coil is formed. filter. 4. The noise filter according to claim 3, wherein the coil pattern and the upper and lower connection patterns are connected by via conductors in the dielectric layer. The coil pattern constituting the signal side coil and the coil pattern constituting the ground side coil have a rectangular shape, and an inductor formation extending from the capacitance forming region is according to claim 1 or 2. Noise filter, characterized in that composed of parts. As a multiple noise filter in which the signal side coil which comprises the said noise filter of Claim 1 is arrange | positioned at least in the up-down direction of the said laminated body, respectively, A coil noise center of a signal side coil of a noise filter disposed above the laminate and a coil axis center of a signal side coil of a noise filter arranged below the laminate are displaced from each other. 8. The coil pattern constituting the signal side coil and the coil pattern constituting the ground side coil are partially overlapped with each other through the dielectric layer in a thickness direction and capacitively coupled to each other. Noise filter. 9. The multiple noise filter according to claim 7 or 8, wherein the noise filter disposed above the laminate and the noise filter disposed below the laminate are partitioned by a partition conductor film of ground potential. . 10. The ground terminal electrode according to claim 9, wherein one end of the ground-side coil of the noise filter disposed above the laminate and one end of the ground-side coil of the noise filter disposed below the laminate are connected to a ground terminal electrode through the partition conductor film. A multiple noise filter, which is connected. The coil axis of the signal-side coil of the noise filter disposed above the laminate and the coil axis of the ground-side coil of the noise filter disposed below the laminate are coaxial. And the coil axis of the ground coil of the noise filter disposed above the laminate and the coil axis of the signal coil of the noise filter disposed below the laminate are coaxial. The multiple noise filter is provided in the transverse direction of the said laminated body in the upper side and / or the lower side of the said laminated body partitioned by the partition conductor film, The multiple noise of Claim 7 or 8 characterized by the above-mentioned. filter. 13. The multiple noise filter according to claim 12, wherein the coil shafts of the signal side coils of the noise filter adjacent in the lateral direction of the laminate are arranged on a diagonal line of the region where the adjacent noise filter is formed. A laminate in which a plurality of dielectric layers are stacked, a signal side input terminal electrode, a signal side output terminal electrode and a ground terminal electrode formed on an outer surface of the laminate, and one end thereof is connected to the signal side input terminal electrode, and the other end thereof is A signal side coil connected to the signal side output terminal electrode, and a ground side coil having a capacitance component formed between the signal side coil and one end thereof connected to the ground terminal electrode; A multiple noise filter in which the signal side coils are arranged at least in the vertical direction of the laminate, A coil noise center of a signal side coil of a noise filter disposed above the laminate and a coil axis center of a signal side coil of a noise filter arranged below the laminate are displaced from each other. The coil pattern constituting the signal side coil and the coil pattern constituting the ground side coil are partially overlapped with each other through the dielectric layer in the thickness direction and capacitively coupled to each other. Noise filter. The noise filter arranged above the laminate and the noise filter arranged below the laminate are partitioned by a partition conductor film having a ground potential. filter. 17. The ground terminal electrode according to claim 16, wherein one end of the ground-side coil of the noise filter disposed above the laminate and one end of the ground-side coil of the noise filter disposed below the laminate are connected to the ground terminal electrode through the partition conductor film. Multiple noise filter, characterized in that connected to. The coil axis of the signal-side coil of the noise filter disposed above the laminate and the coil axis of the ground-side coil of the noise filter disposed below the laminate are coaxial. And the coil axis of the ground coil of the noise filter disposed above the laminate and the coil axis of the signal coil of the noise filter disposed below the laminate are coaxial. The multiple noise filter is provided in the transverse direction of the said laminated body by the upper side and / or the lower side of the said laminated body partitioned by the partition conductor film | membrane. filter. 20. The multiple noise filter according to claim 19, wherein coil centers of the signal side coils of the noise filter adjacent in the transverse direction of the laminate are arranged on a diagonal line of the region where the adjacent noise filter is formed. 16. The multiple noise filter according to claim 14 or 15, wherein the ground side coil is directly connected to the ground terminal electrode. 16. The multiple noise filter according to claim 14 or 15, wherein the ground-side coil is connected to the ground terminal electrode via a capacitance. The noise filter according to claim 4, wherein the coil pattern and the upper and lower layer connection patterns are connected by via conductors in the dielectric layer.

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