JP2014216980A - Stacked balun - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a stacked balun that excels in an attenuation characteristic outside a usage frequency band and has a wide usage frequency band, a low power loss and an excellent phase characteristic.SOLUTION: A stacked balun 10 includes insulating layers 111, 112, an unbalanced coil 13 and a balanced coil 14. The unbalanced coil 13 is formed on the insulating layer 111 and has linear electrodes 131, 132, 133. The balanced coil 14 is formed on the insulating layer 112 and has linear electrodes 141, 142, 143. A first end portion of the linear electrode 131 is connected to a first end portion of the linear electrode 133 by the linear electrode 132. A first end portion of the linear electrode 141 is connected to a first end portion of the linear electrode 143 by the linear electrode 142. A direction Dand a direction Dform an obtuse angle or a straight angle. The linear electrodes 132, 142 are separate from each other when viewed from a direction perpendicular to a main surface of a stack.

Description

  The present invention relates to a laminated balun having a configuration in which an electrode pattern is formed on a laminated body.

  By realizing a balun (balance-unbalance converter) with a laminated structure, the balun can be miniaturized. An example of a laminated balun made of a laminated body is shown in FIG. 21 (see Patent Document 1). FIG. 21 is an exploded perspective view showing a main part of a conventional laminated balun 60. The laminated balun 60 includes insulating layers 111 and 112, a balance coil 63, and an unbalance coil 64, and the insulating layers 111 and 112 are laminated.

  The balance coil 63 is composed of linear electrodes 631 to 633 that are substantially linear. The first end of the linear electrode 631 is connected to the first end of the linear electrode 632. The second end of the linear electrode 632 is connected to the first end of the linear electrode 633. The second end portion of the linear electrode 631 and the second end portion of the linear electrode 633 are close to each other so as to form an opening. That is, the balance coil 63 has a U shape. The unbalance coil 64 is composed of linear linear electrodes 641 to 643. The linear electrodes 641 to 643 are configured in the same manner as the linear electrodes 631 to 633.

When viewed from the direction perpendicular to the stacking plane (stacking direction), the linear electrode 631 and the linear electrode 641 overlap, the linear electrode 632 and the linear electrode 642 overlap, and the linear electrode 633 and the linear electrode 643 Are overlapping. That is, the balance coil 63 is formed along the unbalance coil 64 when viewed from a direction perpendicular to the lamination surface (lamination direction). With such an arrangement, the balance coil 63 and the unbalance coil 64 are electromagnetically coupled.
The unbalanced signal input to the unbalance coil 64 side is converted into a balanced signal and output from the balance coil 63 side.

JP 2011-124880 A

As shown in FIG. 21, the balance coil 63 is formed along the unbalance coil 64 when viewed from the direction perpendicular to the lamination surface (lamination direction). For this reason, resonance may occur in the balance coil 63 and the unbalance coil 64. This resonance is caused by stray capacitance generated between the balance coil 63 and the unbalance coil 64, and the self-inductance and mutual inductance of the balance coil 63 and the unbalance coil 64. When such resonance occurs, there is a possibility that sufficient attenuation characteristics may not be obtained outside the use frequency band.
As general characteristics of the balun, it is desirable that the frequency band used is wide, the power loss is small, and the phase characteristics of the balanced signal are excellent.

  An object of the present invention is to provide a laminated balun having excellent attenuation characteristics outside the use frequency band, and simultaneously having a wide use frequency band, a small power loss, and excellent phase characteristics.

(1) The laminated balun of the present invention includes first and second insulating layers, a balance coil, and an unbalance coil. The first and second insulating layers constitute a laminate. The balance coil is formed in the first insulating layer and has first, second and third linear electrodes. The unbalance coil is formed in the second insulating layer and has fourth, fifth and sixth linear electrodes.

  The first and third linear electrodes extend substantially in parallel. The second linear electrode extends in a direction orthogonal to the first and third linear electrodes. The first end portion of the first linear electrode is connected to the first end portion of the third linear electrode by the second linear electrode. The second end of the first linear electrode and the second end of the third linear electrode are close to each other so as to form an opening.

  The fourth and sixth linear electrodes extend substantially in parallel. The fifth linear electrode extends in a direction orthogonal to the fourth and sixth linear electrodes. The first end portion of the fourth linear electrode is connected to the first end portion of the sixth linear electrode by the fifth linear electrode. The second end of the fourth linear electrode and the second end of the sixth linear electrode are close to each other so as to form an opening.

The first direction when the second end of the first linear electrode is viewed from the first end of the first linear electrode, and the first direction from the first end of the fourth linear electrode. The second direction when the second end of the linear electrode 4 is viewed forms an obtuse angle or a flat angle. The second and fifth linear electrodes are separated from each other when viewed from the direction perpendicular to the main surface of the multilayer body.
In this configuration, since resonance caused by the unbalance coil and the balance coil is suppressed, a laminated balun having excellent attenuation characteristics outside the used frequency band can be realized.

(2) The first direction and the second direction are substantially opposite to each other.

(3) The second end of the sixth linear electrode is connected to the ground. The third linear electrode overlaps the sixth linear electrode when viewed from the direction perpendicular to the main surface of the multilayer body.
With this configuration, it is possible to realize a laminated balun that simultaneously has a wide use frequency band, a small power loss, and excellent phase characteristics.

(4) The first linear electrode is formed between the fourth linear electrode and the sixth linear electrode when viewed from the direction perpendicular to the main surface of the multilayer body.

(5) The fourth linear electrode is formed between the first linear electrode and the third linear electrode when viewed from the direction perpendicular to the main surface of the multilayer body.

(6) The first linear electrode overlaps the fourth linear electrode when viewed from the direction perpendicular to the main surface of the multilayer body.
In these configurations, since the size of the main surface of the first and second insulating layers can be reduced, the stacked balun can be reduced in size.

(7) The laminated balun of the present invention further includes third and fourth insulating layers, a ground electrode, first and second flat plate electrodes, and first and second via electrodes. The third and fourth insulating layers constitute a laminate. The ground electrode is formed on the third insulating layer. The first and second flat plate electrodes are formed on the fourth insulating layer and face the ground electrode. The second end of the first linear electrode is connected to the first plate electrode via the first via electrode. The second end of the third linear electrode is connected to the second plate electrode via the second via electrode.
In this configuration, a capacitance is generated between the ground electrode and the first and second plate electrodes. Further, the first and second via electrodes include inductance. By setting the capacitance and inductance, the impedance on the balanced terminal side can be adjusted.

(8) The central portion of the second linear electrode is connected to the ground.
With this configuration, the phase reference point of the balance coil can be determined. Thereby, a desired balance characteristic can be realized with high accuracy.

(9) The laminated balun of the present invention further includes a fifth insulating layer, and a second unbalanced coil using the unbalanced coil as a first unbalanced coil. The fifth insulating layer constitutes a stacked body. The second unbalance coil has an electrode structure similar to that of the first unbalance coil. The second unbalance coil is formed in the fifth insulating layer. The second insulating layer is stacked between the first insulating layer and the fifth insulating layer.
In this configuration, electromagnetic field coupling between the balance coil and the first and second unbalance coils can be strengthened. Thereby, the impedance on the balanced terminal side can be adjusted in a wide range.

  According to the present invention, it is possible to realize a laminated balun having excellent attenuation characteristics outside the use frequency band, and simultaneously having a wide use frequency band, a small power loss, and excellent phase characteristics.

It is an equivalent circuit diagram of the laminated balun according to the first embodiment. 1 is an external perspective view of a laminated balun according to a first embodiment. It is a disassembled perspective view of the lamination | stacking balun which concerns on 1st Embodiment. It is a characteristic view which shows the insertion loss between the unbalanced terminal P1 and the balanced terminal P2 in differential mode. 5 (A) is a characteristic diagram for explaining the bandwidth BW and the center frequency _{f 0.} FIG. _5B is a characteristic diagram illustrating the balanced frequency fb. 3 is a plan view showing a design pattern of an unbalance coil 13 and a balance coil 14. FIG. FIG. 7A is a characteristic diagram showing changes in bandwidth BW with respect to changes in distance A in patterns 1 to 3. FIG. 7B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance A in the patterns 1 to 3. FIG. 8A is a characteristic diagram showing a change in bandwidth BW with respect to a change in distance B in patterns 1 to 3. FIG. 8B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the patterns 1 to 3. FIG. 9A is a characteristic diagram showing changes in the bandwidth BW with respect to changes in the distance B in the patterns 4 and 5. FIG. _9B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the patterns 4 and 5. FIG. 10A is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the pattern 5. FIG. _10B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the pattern 6. FIG. 11A is a characteristic diagram showing changes in bandwidth BW with respect to changes in distance A in patterns 1 to 3. FIG. 11B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance A in the patterns 1 to 3. FIG. 12A is a characteristic diagram showing changes in bandwidth BW with respect to changes in distance B in patterns 1 to 3. FIG. 12B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the patterns 1 to 3. FIG. 13A is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the pattern 5. FIG. _13B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the pattern 6. It is an equivalent circuit diagram of the laminated balun according to the second embodiment. It is a disassembled perspective view of the lamination | stacking balun which concerns on 2nd Embodiment. It is an equivalent circuit diagram of the laminated balun according to the third embodiment. It is a disassembled perspective view of the lamination | stacking balun which concerns on 3rd Embodiment. It is a disassembled perspective view of the lamination | stacking balun which concerns on 4th Embodiment. It is a disassembled perspective view of the lamination | stacking balun which concerns on 5th Embodiment. It is a top view which shows the principal part of the lamination | stacking balun which concerns on 6th Embodiment. It is a disassembled perspective view which shows the principal part of the conventional laminated balun.

<< First Embodiment >>
The laminated balun 10 according to the first embodiment of the present invention will be described. FIG. 1 is an equivalent circuit diagram of the laminated balun 10. The equivalent circuit of the multilayer balun 10 includes inductors L1 to L4, a capacitor C1, an unbalanced terminal P1, and balanced terminals P2 and P3.

The unbalanced terminal P1 is connected to the ground via an LC parallel resonance circuit composed of an inductor L1 and a capacitor C1. The inductor L2 is electromagnetically coupled to the inductor L1. The first terminal of the inductor L2 is connected to the balanced terminal P2 via the inductor L3. The second terminal of the inductor L2 is connected to the balanced terminal P3 via the inductor L4. The center portion of the inductor L2 is connected to the ground.
The unbalanced signal input to the unbalanced terminal P1 is converted into a balanced signal and output from the balanced terminals P2 and P3.

  FIG. 2 is an external perspective view of the laminated balun 10. The laminated balun 10 includes a laminated body 11 and external electrodes 121 to 124. The external electrodes 121 and 122 are separated from each other by a predetermined distance and are formed on the first side surface of the multilayer body 11. The external electrode 123 faces the external electrode 121, and the external electrode 124 faces the external electrode 122, and is formed on the second side surface (the surface opposite to the first side surface) of the laminate. The external electrodes 121 to 124 are formed so as to extend on the main surface (upper surface and lower surface) of the multilayer body. The external electrode 122 corresponds to the unbalanced terminal P1. The external electrode 123 corresponds to the balanced terminal P2. The external electrode 124 corresponds to the balanced terminal P3. The external electrode 121 is connected to the ground.

  FIG. 3 is an exploded perspective view of the laminated balun 10. The laminated balun 10 includes insulating layers 111 to 116, an unbalance coil 13, a balance coil 14, plate electrodes 151 to 153, via electrodes 161 to 163, and lead electrodes 171 to 177. The insulating layers 111 to 116 are stacked in this order to constitute the stacked body 11. The insulating layer 111 is the uppermost layer of the stacked body 11, and the insulating layer 116 is the lowermost layer of the stacked body 11.

  An unbalanced coil 13 and lead electrodes 171 and 172 are formed on the insulating layer 111. The unbalance coil 13 includes linear electrodes 131 to 133 that are substantially linear. The first end of the linear electrode 131 is connected to the first end of the linear electrode 132. The linear electrode 131 and the linear electrode 132 form a substantially right angle when viewed from the direction perpendicular to the main surface of the multilayer body 11. The second end of the linear electrode 132 is connected to the first end of the linear electrode 133. The linear electrode 132 and the linear electrode 133 form a substantially right angle when viewed from a direction perpendicular to the main surface of the multilayer body 11. The second end of the linear electrode 131 and the second end of the linear electrode 133 are close to each other so as to form an opening. That is, the unbalance coil 13 has a U shape. The second end of the linear electrode 131 is connected to the external electrode 122 via the extraction electrode 172. The second end of the linear electrode 133 is connected to the external electrode 121 through the extraction electrode 171.

  A balance coil 14 is formed on the insulating layer 112. The balance coil 14 is composed of linear electrodes 141 to 143 that are substantially linear. The first end of the linear electrode 141 is connected to the first end of the linear electrode 142. The linear electrode 141 and the linear electrode 142 form a substantially right angle when viewed from the direction perpendicular to the main surface of the multilayer body 11. The second end of the linear electrode 142 is connected to the first end of the linear electrode 143. The linear electrode 142 and the linear electrode 143 form a substantially right angle when viewed from the direction perpendicular to the main surface of the multilayer body 11. The second end of the linear electrode 141 and the second end of the linear electrode 143 are close to each other so as to form an opening. That is, the unbalance coil 13 has a U-shape like the balance coil 14. The unbalance coil 13 and the balance coil 14 are electromagnetically coupled.

Direction when viewing the second ends of the linear electrode 131 from the first ends of the linear electrodes 131 and D _1. Direction when viewing the second ends of the linear electrode 141 from the first ends of the linear electrodes 141 and D _2. Facing substantially opposite directions to the direction D ₁ and the direction D _2. The linear electrode 132 and the linear electrode 142 are formed away from each other in the extending direction of the linear electrodes 131, 133, 141, and 143 when viewed from the direction perpendicular to the main surface of the multilayer body 11, and do not overlap.

  The second end of the linear electrode 141 is connected to the first end of the via electrode 162. The second end of the linear electrode 143 is connected to the first end of the via electrode 161. The central portion of the linear electrode 142 is connected to the first end portion of the via electrode 163.

The insulating layer 112 corresponds to the first insulating layer of the present invention. The insulating layer 111 corresponds to the second insulating layer of the present invention. The linear electrode 141 corresponds to the first linear electrode of the present invention. The linear electrode 142 corresponds to the second linear electrode of the present invention. The linear electrode 143 corresponds to the third linear electrode of the present invention. The linear electrode 131 corresponds to the fourth linear electrode of the present invention. The linear electrode 132 corresponds to the fifth linear electrode of the present invention. The linear electrode 133 corresponds to the sixth linear electrode of the present invention. Direction D ₂ corresponds to a first direction of the present invention. Direction D ₁ corresponds to the second direction of the present invention.

  Lead electrodes 173 and 174 are formed on the insulating layer 113. A second end of the via electrode 162 is connected to the external electrode 124 through the extraction electrode 174. The second end portion of the via electrode 161 is connected to the external electrode 123 through the extraction electrode 173.

  A flat plate electrode 151 and a lead electrode 175 are formed on the insulating layer 114. A second end of the via electrode 163 is connected to the plate electrode 151. The plate electrode 151 is connected to the external electrode 121 through the extraction electrode 175. A flat plate electrode 152 and a lead electrode 176 are formed on the insulating layer 115. The plate electrode 152 is connected to the external electrode 122 via the extraction electrode 176. A flat plate electrode 153 and a lead electrode 177 are formed on the insulating layer 116. The plate electrode 153 is connected to the external electrode 121 through the extraction electrode 177. The plate electrodes 151 to 153 are formed to face each other.

  The correspondence between the equivalent circuit of FIG. 1 and the configuration of FIG. 3 will be described. The inductor L1 corresponds to the unbalance coil 13. The inductor L2 corresponds to the balance coil 14. The inductor L3 corresponds to the via electrode 161. The inductor L4 corresponds to the via electrode 162. The capacitor C1 is composed of flat plate electrodes 151 to 153 and insulating layers 114 and 115.

  FIG. 4 is a characteristic diagram showing insertion loss between the unbalanced terminal P1 and the balanced terminal P2 in the differential mode. The solid line in FIG. 4 is the insertion loss of the multilayer balun 10 according to this embodiment, and the broken line in FIG. 4 is the insertion loss of the multilayer balun 60 having the conventional configuration shown in FIG. The laminated balun 60 includes a balance coil 63 and an unbalanced coil 64 instead of the unbalance coil 13 and the balance coil 14 of the laminated balun 10. The other structure of the laminated balun 60 is almost the same as that of the laminated balun 10. In the laminated balun 60, the attenuation characteristic is deteriorated in the vicinity of 7 to 8 GHz. On the other hand, in the laminated balun 10, the attenuation characteristic in the vicinity of 7 to 8 GHz is improved as compared with the attenuation characteristic of the laminated balun 60.

  In the laminated balun 60, the resonance characteristics generated by the balance coil 63 and the unbalance coil 64 deteriorate the attenuation characteristics outside the use frequency band. On the other hand, in the laminated balun 10, the linear electrode 132 and the linear electrode 142 do not overlap when viewed from the direction perpendicular to the main surface of the laminated body 11. Thereby, since the resonance produced by the unbalance coil 13 and the balance coil 14 is suppressed, the attenuation characteristic outside the use frequency band can be improved.

  In the laminated balun 10, the unbalance coil 13 is connected to the electrodes of the external electrodes 121 and 122 without passing through the via electrode. Thereby, since the number of via electrodes can be reduced, it is possible to reduce the size and cost of the laminated balun.

  Note that the linear electrode 131 and the linear electrode 141 may overlap with each other, and the linear electrode 133 and the linear electrode 143 may overlap with each other when viewed from the main surface of the multilayer body 11. Thereby, since the size of the main surface of the insulating layers 111 and 112 can be reduced, the stacked balun can be reduced in size.

  In the multilayer balun 10, the inductor L1 is composed of the unbalanced coil 13, and the capacitor C1 is composed of the plate electrodes 151 to 153 and the insulating layers 114 and 115. However, the present invention is not limited thereto. By setting the length of the unbalance coil 13 to ¼ wavelength of the input / output signal, an LC parallel resonance circuit including the inductor L1 and the capacitor C1 may be equivalently configured.

  In this configuration, an insulating layer and an electrode for configuring the capacitor C1 are not required. Moreover, since the length of the unbalance coil 13 can be shortened as the frequency of the input / output signal increases, the size of the laminated balun can be reduced.

Here, the general characteristics of the balun, the bandwidth BW, the center frequency f ₀ and a balanced frequency f _b will be described. FIG. 5A is a characteristic diagram for explaining the bandwidth BW and the center frequency f ₀ and shows the insertion loss between the unbalanced terminal P1 and the balanced terminal P2 in the differential mode. FIG. _5B is a characteristic diagram for explaining the balanced frequency fb, and shows the frequency characteristic of the phase difference between the balanced signals output from the balanced terminals P2 and P3.

Hereinafter, referred to as the center frequency f ₀ frequency insertion loss is minimized. The frequency at the attenuation amount at which the insertion loss is reduced by 3 dB from the insertion loss at the center frequency f ₀ is f ₁ and f ₂ , and the absolute value of f ₂ −f ₁ is referred to as the bandwidth BW. The frequency at which the phase difference of the balanced signals is 180 ° is referred to as a balanced frequency f _b.

Bandwidth BW represents the width of the used frequency band. Moreover, the smaller the absolute value of the frequency difference f ₀ -f _b is, the smaller the power loss and the better the balun with excellent phase characteristics. For this reason, it is desirable that the absolute value of the frequency difference f ₀ -f _b is small.

  Before describing the characteristics of the laminated balun 10, the design patterns of the unbalance coil 13 and the balance coil 14 will be described. FIG. 6 is a plan view showing a design pattern of the unbalance coil 13 and the balance coil 14. Note that the positional relationship described when the design pattern is described is viewed from a direction perpendicular to the main surface of the stacked body 11.

  In the pattern 1, the unbalance coil 13 and the balance coil 14 have the same shape. The linear electrode 132 and the linear electrode 142 are arranged in parallel by being separated by a distance A. The linear electrode 131 and the linear electrode 141 are arranged in parallel by being separated by a distance B.

In the pattern 2, the linear electrode 132 is made longer than the linear electrode 142. The lengths of the linear electrodes 131, 133, 141, and 143 are made equal. The linear electrode 132 and the linear electrode 142 are arranged in parallel by being separated by a distance A. The linear electrode 131 and the linear electrode 141 are arranged in parallel by being separated by a distance B. The linear electrode 133 and the linear electrode 143 are arranged in parallel by being separated by a distance B.
In the pattern 3, the linear electrode 132 is made shorter than the linear electrode 142. Other configurations are the same as those of the pattern 2.

  In the pattern 4, the linear electrode 132 is made longer than the linear electrode 142. The linear electrodes 131 and 141 are arranged so that the linear electrode 131 and the linear electrode 141 overlap and become parallel. The linear electrodes 133 are arranged in parallel at a distance B from the linear electrodes 143. The linear electrode 132 and the linear electrode 142 are arranged in parallel by being separated by a distance A.

  In the pattern 5, the linear electrode 132 is made longer than the linear electrode 142. The linear electrodes 133 and 143 are arranged so that the linear electrode 133 and the linear electrode 143 overlap and are parallel to each other. The linear electrode 131 and the linear electrode 141 are arranged in parallel by being separated by a distance B. The linear electrode 132 and the linear electrode 142 are arranged in parallel by being separated by a distance A. That is, the linear electrode 133 connected to the ground is superimposed on the linear electrode 143, and the linear electrode 141 is disposed between the linear electrode 131 and the linear electrode 133.

  In the pattern 6, the linear electrode 132 is made shorter than the linear electrode 142. Other configurations are the same as those of the pattern 5. That is, the linear electrode 133 connected to the ground is superimposed on the linear electrode 143, and the linear electrode 131 is disposed between the linear electrode 141 and the linear electrode 143.

FIG. 7A is a characteristic diagram showing changes in bandwidth BW with respect to changes in distance A in patterns 1 to 3. FIG. 7B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance A in the patterns 1 to 3. In the pattern 1, the distance B is set to 0 μm. In the patterns 2 and 3, the distance B is set to 50 μm. The unbalance coil 13 and the balance coil 14 are separated by 12.5 μm in the direction perpendicular to the main surface of the laminate 11. Center frequency _{f 0} is set in the vicinity of 5GHz.

Regardless of the patterns 1 to 3, the bandwidth BW increases as the distance A increases. Regardless of the patterns 1 to 3, the frequency difference f ₀ −f _b increases as the distance A increases. Therefore, the distance A is increased in order to avoid resonance caused by the unbalance coil 13 and the balance coil 14 and widen the bandwidth BW.

FIG. 8A is a characteristic diagram showing a change in bandwidth BW with respect to a change in distance B in patterns 1 to 3. FIG. 8B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the patterns 1 to 3. The distance A related to the patterns 1 to 3 is 212.5 μm. Other conditions are the same as those in FIG. In the pattern 3, when the distance B is increased to 150 μm or more, the linear electrode 131 and the linear electrode 133 overlap each other. That is, the pattern 3 is not U-shaped. For this reason, the range in which the distance B is 150 μm or more is not examined.

Regardless of the patterns 1 to 3, the bandwidth BW decreases as the distance B increases. Regardless of the patterns 1 to 3, the frequency difference f ₀ −f _b decreases as the distance B increases. In the pattern 3, when the distance B is about 120 μm, the frequency difference f ₀ −f _b is ₀ GHz. In the pattern 1, when the distance B is about 140 μm, the frequency difference f ₀ −f _b is ₀ GHz. That is, when the distance B is set to a predetermined value, the frequency difference f ₀ −f _b can be set to ₀ GHz, but the bandwidth BW is narrowed. Therefore, as in patterns 4 and 5, it is conceivable that either one of the linear electrodes 131 and 133 is placed on the balance coil 14 and the other is separated by a distance B.

FIG. 9A is a characteristic diagram showing changes in the bandwidth BW with respect to changes in the distance B in the patterns 4 and 5. FIG. _9B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the patterns 4 and 5. The distance A related to the patterns 4 and 5 is 212.5 μm. Other conditions are the same as those in FIG.

Regardless of the patterns 4 and 5, the bandwidth BW becomes narrower as the distance B becomes longer. However, in patterns 4 and 5, the bandwidth BW is kept wider than patterns 1 to 3. In the pattern 4, the frequency difference f ₀ −f _b increases as the distance B increases. In pattern 5, the frequency difference f ₀ −f _b decreases as the distance B increases. As a result, when the distance B of the pattern 5 is about 125 μm, the frequency difference f ₀ −f _b is ₀ GHz.

That is, as shown in the pattern 5, the linear electrode 133 connected to the ground is overlapped on the linear electrode 143, and the linear electrode 141 is disposed between the linear electrode 131 and the linear electrode 133, thereby obtaining a bandwidth. The absolute value of the frequency difference f ₀ -f _b can be reduced while keeping BW wide.

FIG. 10A is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the pattern 5. FIG. _10B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the pattern 6. The distance A related to the pattern 5 is set to 212.5 μm, 162.5 μm, and 137.5 μm. Similarly, the distance A related to the pattern 6 is set to 212.5 μm, 162.5 μm, and 137.5 μm. When the distance B is 120 to 130 μm, the frequency difference f ₀ -f _b is almost ₀ GHz regardless of the patterns 5 and 6 and the distance A.

That is, as in patterns 5 and 6, the line electrode 133 connected to the ground is overlapped on the line electrode 143, and the line electrode 141 and the line electrode 143 are separated by a predetermined distance, thereby widening the bandwidth BW. While maintaining, the absolute value of the frequency difference f ₀ -f _b can be reduced. For example, in the pattern 5, by setting the distance A to 212.5 μm and the distance B to 125 μm, the bandwidth BW can be set to about 3 GHz, and the frequency difference f ₀ -f _b can be set to about ₀ GHz.

Next, the bandwidth BW and the frequency difference f ₀ -f _b when the center frequency f ₀ is set in the vicinity of 2 GHz will be described. FIG. 11A is a characteristic diagram showing changes in bandwidth BW with respect to changes in distance A in patterns 1 to 3. FIG. 11B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance A in the patterns 1 to 3. Center frequency _{f 0} is set in the vicinity of 2GHz. Other conditions are the same as those in FIG. In each of the patterns 1 to 3, the bandwidth BW and the frequency difference f ₀ -f _b tend to increase as the distance A increases. Therefore, the bandwidth BW and the frequency difference f ₀ -f _b change in substantially the same manner as in the case of 5 GHz shown in FIGS.

FIG. 12A is a characteristic diagram showing changes in bandwidth BW with respect to changes in distance B in patterns 1 to 3. FIG. 12B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the patterns 1 to 3. Center frequency _{f 0} is set in the vicinity of 2GHz. Other conditions are the same as in FIG.

The bandwidth BW of the pattern 2 is substantially constant with respect to the change in the distance B. Further, the frequency difference f ₀ -f _b of the pattern 2 tends to decrease as the distance B increases, but increases when the distance B changes from 50 μm to 100 μm. However, as a whole tendency of the patterns 1 to 3, the bandwidth B becomes longer for the bandwidth BW and the frequency difference f ₀ -f _b as in the case of 5 GHz shown in FIGS. 8 (A) and 8 (B). As it gets smaller.

FIG. 13A is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the pattern 5. FIG. _13B is a characteristic diagram showing changes in the frequency difference f ₀ -f _b with respect to changes in the distance B in the pattern 6. Center frequency _{f 0} is set in the vicinity of 2GHz. The distance A related to the patterns 5 and 6 is set to 212.5 μm. Other conditions are the same as in the case of FIG. In both patterns 5 and 6, as in the case of 5 GHz shown in FIGS. 10A and 10B, the frequency difference f ₀ -f _b tends to approach ₀ GHz by increasing the distance B. .

Thus, the result of setting the center frequency f ₀ near 5 GHz, also holds when the center frequency f ₀ near 2 GHz. That is, by arranging the unbalance coil 13 and the balance coil 14 as in patterns 5 and 6, the absolute value of the frequency difference f ₀ −f _b can be obtained while keeping the bandwidth BW wide regardless of the frequency band used. Can be small.

Therefore, in the laminated balun 10, by adjusting the distances A and B appropriately without overlapping the linear electrodes 132 and 142, a wide use frequency band can be obtained regardless of the use frequency band (set value of the center frequency f ₀ ). Small power loss and excellent phase characteristics can be realized at the same time.

In the first embodiment, the center frequency f ₀ is changed in a state where the size of the stacked body 11 is fixed by changing the dielectric constant of the stacked body 11. However, the size of the coil shape of the laminated balun 10 may be changed without changing the dielectric constant of the laminated body 11. Even in this case, the same effect as the first embodiment can be obtained.

  In the first embodiment, the center portion of the inductor L2 is connected to the ground, so that the phase reference point of the balance coil can be determined. Thereby, a desired balance characteristic can be realized with high accuracy, but the central portion of the inductor L2 may not be connected to the ground.

<< Second Embodiment >>
A laminated balun 20 according to a second embodiment of the present invention will be described. FIG. 14 is an equivalent circuit diagram of the laminated balun 20. The equivalent circuit of the multilayer balun 20 includes capacitors C2 and C3 in addition to the configuration according to the first embodiment. A connection point between the inductor L3 and the balanced terminal P2 is connected to the ground via the capacitor C2. A connection point between the inductor L4 and the balanced terminal P3 is connected to the ground via the capacitor C3.

  FIG. 15 is an exploded perspective view of the laminated balun 20. The laminated balun 20 includes flat plate electrodes 251 and 252 and extraction electrodes 271 and 272 in addition to the configuration of the laminated balun 10. The plate electrodes 251 and 252 and the extraction electrodes 271 and 272 are formed on the insulating layer 115. The plate electrodes 251 and 252 are arranged to face the plate electrodes 151 and 153. The plate electrode 251 is connected to the external electrode 123 through the extraction electrode 271. The plate electrode 252 is connected to the external electrode 124 through the extraction electrode 272. The plate electrodes 151, 153, 251 and the insulating layers 114, 115 constitute a capacitor C2. The plate electrodes 151, 153, 252 and the insulating layers 114, 115 constitute a capacitor C3.

The insulating layer 114 or the insulating layer 116 corresponds to the third insulating layer of the present invention. The insulating layer 115 corresponds to the fourth insulating layer of the present invention. The flat plate electrode 151 or the flat plate electrode 153 corresponds to the ground electrode of the present invention. The plate electrode 252 corresponds to the first plate electrode of the present invention. The plate electrode 251 corresponds to the second plate electrode of the present invention. The via electrode 162 corresponds to the first via electrode of the present invention. The via electrode 161 corresponds to the second via electrode of the present invention.
Other configurations are the same as those of the laminated balun 10.

  According to the second embodiment, the impedance on the balanced terminal side can be adjusted by setting the element values of the inductors L3 and L4 and the capacitors C2 and C3. Further, the same effect as that of the first embodiment can be obtained.

<< Third Embodiment >>
A laminated balun 30 according to a third embodiment of the present invention will be described. FIG. 16 is an equivalent circuit diagram of the laminated balun 30. The equivalent circuit of the multilayer balun 30 does not include the inductors L3 and L4 according to the first embodiment. The first terminal of the inductor L2 is directly connected to the balanced terminal P2. The second terminal of the inductor L2 is directly connected to the balanced terminal P3.

FIG. 17 is an exploded perspective view of the laminated balun 30. The laminated balun 30 does not include the insulating layer 113 and the via electrodes 162 and 163 according to the first embodiment. A second end portion of the linear electrode 143 is connected to the external electrode 123 via a lead electrode 173 formed in the insulating layer 112. A second end portion of the linear electrode 141 is connected to the external electrode 124 via a lead electrode 174 formed in the insulating layer 112.
Other configurations are the same as those of the first embodiment.
According to the third embodiment, the same effect as that of the first embodiment can be obtained.

<< Fourth Embodiment >>
A laminated balun 40 according to the fourth embodiment of the present invention will be described. FIG. 18 is an exploded perspective view of the laminated balun 40. The laminated balun 40 includes an unbalance coil 43 and a balance coil 44 instead of the unbalance coil 13 and the balance coil 14 according to the first embodiment. The unbalance coil 43 is composed of linear electrodes 131 to 135 that are substantially linear. The balance coil 44 includes substantially linear linear electrodes 141 to 145.

  The linear electrodes 131 to 133 are formed in the same manner as in the first embodiment. The first end of the linear electrode 134 is connected to the second end of the linear electrode 131 (the side not connected to the linear electrode 132). The first end of the linear electrode 135 is connected to the second end of the linear electrode 133 (the side not connected to the linear electrode 132). The linear electrodes 134 and 135 extend so that the second end of the linear electrode 134 and the second end of the linear electrode 135 are close to each other.

The linear electrodes 141 to 143 are formed in the same manner as in the first embodiment. The first end of the linear electrode 144 is connected to the second end of the linear electrode 141 (the side not connected to the linear electrode 142). The first end of the linear electrode 145 is connected to the second end of the linear electrode 143 (the side not connected to the linear electrode 142). The linear electrodes 144 and 145 extend so that the second end of the linear electrode 144 and the second end of the linear electrode 145 are close to each other.
The unbalance coil 43 corresponds to the inductor L1. The balance coil 44 corresponds to the inductor L2. Other configurations are the same as those of the first embodiment.

According to the fourth embodiment, since the unbalance coil 43 and the balance coil 44 can be increased as compared with the first embodiment, the element values of the inductors L1 and L2 are increased. Accordingly, since the resonance frequency of the laminated balun is lowered, it is possible to reduce the center frequency f _0. Further, the same effect as that of the first embodiment can be obtained.

<< Fifth Embodiment >>
A laminated balun 50 according to the fifth embodiment of the present invention will be described. FIG. 19 is an exploded perspective view of the laminated balun 50. The laminated balun 50 includes an insulating layer 511, an unbalanced coil 53, and extraction electrodes 571 and 572 in addition to the configuration according to the third embodiment.

  The insulating layer 511 is stacked between the insulating layer 112 and the insulating layer 114. Similar to the insulating layer 111, the unbalance coil 13 and the extraction electrodes 171 and 172 according to the third embodiment, the insulation layer 511, the unbalance coil 53 and the extraction electrodes 571 and 572 are configured. The unbalance coils 13 and 53 correspond to the inductor L1.

The insulating layer 511 corresponds to the fifth insulating layer of the present invention. The unbalance coil 13 corresponds to the first unbalance coil of the present invention. The unbalance coil 53 corresponds to the second unbalance coil of the present invention.
Other configurations are the same as those of the third embodiment.

  According to the fifth embodiment, the balance coil 14 is disposed between the unbalance coil 13 and the unbalance coil 53. For this reason, electromagnetic coupling between the inductor L1 and the inductor L2 can be strengthened. Thereby, the impedance on the balanced terminal side can be adjusted in a wide range. Further, the same effect as that of the first embodiment can be obtained.

<< Sixth Embodiment >>
A laminated balun according to the sixth embodiment of the present invention will be described. 20A and 20B are plan views showing the main part of the laminated balun according to the sixth embodiment. The direction D ₂ according to the direction D ₁ and the balance coil 14 in accordance with the unbalanced coil 13, as viewed from the lamination direction, and forms an obtuse angle. Other configurations are the same as those of the first embodiment.

According to this configuration, by adjusting the angle between the direction D ₁ and the direction D _2, it is possible to adjust the degree of coupling unbalanced coil 13 and the balance coil 14. Further, the same effect as that of the first embodiment can be obtained. In order to obtain the effect of the present invention reliably, the angle formed by the direction D ₁ and the direction D ₂ is preferably 175 ° to 180 ° about.

C1 to C3 ... capacitors L1 to L4 ... inductor P1 ... unbalanced terminals P2, P3 ... balanced terminals 10, 20, 30, 40, 50, 60 ... laminated balun 11 ... laminated bodies 13, 43, 64 ... unbalanced coil 53 ... Unbalance coil (second unbalance coil)
14, 44, 63 ... balance coil 111 ... insulating layer (second insulating layer)
112 ... Insulating layer (first insulating layer)
113 ... Insulating layers 114, 116 ... Insulating layer (third insulating layer)
115: Insulating layer (fourth insulating layer)
511 ... Insulating layer (fifth insulating layer)
121 to 124 ... external electrode 131 ... linear electrode (fourth linear electrode)
132: linear electrode (fifth linear electrode)
133 ... linear electrode (sixth linear electrode)
141 ... linear electrode (first linear electrode)
142 ... linear electrode (second linear electrode)
143 ... linear electrode (third linear electrode)
134, 135, 144, 145 ... linear electrodes 631 to 633, 641 to 643 ... linear electrodes 151, 153 ... flat plate electrodes (ground electrodes)
152 ... flat plate electrode 251 ... flat plate electrode (second flat plate electrode)
252 ... Flat plate electrode (first flat plate electrode)
161: Via electrode (second via electrode)
162: Via electrode (first via electrode)
163... Via electrodes 171 to 177, 271, 272, 571, 572.

Claims (9)

First and second insulating layers constituting the laminate;
A balance coil formed on the first insulating layer and having first, second and third linear electrodes;
An unbalanced coil formed on the second insulating layer, having fourth, fifth and sixth linear electrodes, and electromagnetically coupled to the balance coil;
The first and third linear electrodes extend substantially in parallel; the second linear electrode extends in a direction orthogonal to the first and third linear electrodes;
A first end of the first linear electrode is connected to a first end of the third linear electrode by the second linear electrode;
The second end of the first linear electrode and the second end of the third linear electrode are adjacent to form an opening,
The fourth and sixth linear electrodes extend substantially in parallel; the fifth linear electrode extends in a direction perpendicular to the fourth and sixth linear electrodes;
A first end of the fourth linear electrode is connected to a first end of the sixth linear electrode by the fifth linear electrode;
The second end of the fourth linear electrode and the second end of the sixth linear electrode are close to each other so as to form an opening,
A first direction when the second end of the first linear electrode is viewed from a first end of the first linear electrode, and a first end of the fourth linear electrode The second direction when the second end portion of the fourth linear electrode is viewed from the portion forms an obtuse angle or a flat angle,
The second and fifth linear electrodes are laminated baluns separated from each other when viewed from a direction perpendicular to the main surface of the laminated body.   The laminated balun according to claim 1, wherein the first direction and the second direction are substantially opposite to each other. A second end of the sixth linear electrode is connected to the ground;
3. The multilayer balun according to claim 1, wherein the third linear electrode overlaps the sixth linear electrode when viewed from a direction perpendicular to a main surface of the multilayer body.   The first linear electrode is formed between the fourth linear electrode and the sixth linear electrode when viewed from a direction perpendicular to a main surface of the multilayer body. The laminated balun described.   The fourth linear electrode is formed between the first linear electrode and the third linear electrode as viewed from a direction perpendicular to a main surface of the multilayer body. The laminated balun described.   4. The multilayer balun according to claim 3, wherein the first linear electrode overlaps the fourth linear electrode when viewed from a direction perpendicular to a main surface of the multilayer body. Third and fourth insulating layers constituting the laminate;
A ground electrode formed on the third insulating layer;
First and second flat plate electrodes formed on the fourth insulating layer and facing the ground electrode;
First and second via electrodes,
A second end of the first linear electrode is connected to the first plate electrode via a first via electrode;
The laminated balun according to claim 1, wherein a second end of the third linear electrode is connected to the second flat plate electrode via a second via electrode.   The laminated balun according to claim 1, wherein a central portion of the second linear electrode is connected to a ground. A fifth insulating layer constituting the laminate;
The unbalanced coil as a first unbalanced coil, and a second unbalanced coil having an electrode structure similar to the first unbalanced coil,
The second unbalanced coil is formed in the fifth insulating layer;
The stacked balun according to claim 1, wherein the second insulating layer is stacked between the first insulating layer and the fifth insulating layer.

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