JP4893616B2 - Inductor - Google Patents

Description

  The present invention provides a matching circuit that converts a signal between one balanced circuit system and another balanced circuit system, or between a balanced circuit system and an unbalanced circuit system. It relates to the inductor used.

  FIG. 10 shows the structure of a conventional inductor. A conventional inductor D10 is shown in FIG. 10B in order to perform the function of the transformer described in Patent Documents 1 to 3 below between the unbalanced circuit system and the unbalanced circuit system. As shown in the figure, a first winding W10 and a second winding W20, which are two spiral windings, are formed on a substrate SB with a passivation layer PV therebetween.

  More specifically, the first winding W10 includes a spiral winding main body WD10 and an end ED10a on the center side of the winding main body WD10 as one external terminal or one external circuit (not shown). And the wiring LN10 extending from the end ED10a to the outer end ED10b.

  Similarly, the second winding W20 includes a spiral winding main body WD20 and an end ED20a on the center side of the winding main body WD20 in order to connect the other end to another external terminal or another external circuit. And a wiring LN20 extending from the portion ED20a to the outer end ED20b.

JP 2002-231817 A Japanese Patent Laid-Open No. 2005-340658 JP-A-6-347142

  However, in the conventional inductor D10, for the first winding W10, the wiring LN10 is formed in the first layer L10 on the passivation layer PV, and the winding body WD10 is the first winding W10. The second winding L20 is formed on the second layer L20. Further, for the second winding W20, the winding body WD20 is formed on the third layer L30 on the second layer L20. The wiring LN20 is formed in the fourth layer L40 on the third layer L30. As a result, in order to form the inductor D10, four layers, that is, the first layer L10 to the fourth layer L40 are required, and the “thinning” that the inductor D10 is configured with fewer layers than four layers. I could n’t.

  The present invention is realized by the following application examples in order to solve the above-described problems.

[Application Example 1]
The inductor of application example 1 is
(1) (1a) Of the first layer, the second layer formed on the first layer, and the third layer formed on the second layer, the second layer A first winding body provided in the layer of
(1b) a second winding body smaller than the first winding body provided in the first layer;
(1c) a third winding body smaller than the second winding body, provided in the second layer;
(1d) A pair of first input / output wirings for performing one of input and output of a balanced first signal extending from the first winding body in the second layer;
(1e) a pair of first connection wires for connecting the first winding body and the second winding body;
(1f) a first winding having a pair of second connection wirings for connecting the second winding body and the third winding body;
(2) (2a) a fourth winding body provided in the third layer;
(2b) A fifth winding body smaller than the fourth winding body provided between the first winding body and the third winding body in the second layer. When,
(2c) a sixth winding body smaller than the fifth winding body provided in the third layer;
(2d) a pair of second input / output wirings for performing the other of the input and output of the balanced second signal extending from the fourth winding body in the third layer; 2e) a pair of third connection wires for connecting the fourth winding body and the fifth winding body;
(2f) a second winding having a pair of fourth connection wirings for connecting the fifth winding body and the sixth winding body, the first winding being connected to the first winding; And the overlapping second winding.

  According to the inductor of Application Example 1, for the first winding, the first winding body and the third winding body are provided in the second layer, and the second winding A winding body is provided in the first layer, and for the first winding, the fourth winding body and the sixth winding body are provided in the third layer. And the fifth winding body is provided in the second layer, and the fifth winding body is between the first winding body and the third winding body. Located in. Thereby, unlike the conventional inductor, the inductor of the application example 1 can be configured by only three layers of the first layer to the third layer, and can be “thinned” compared to the conventional one. It becomes.

[Application Example 2]
The inductor of application example 2 is
(1) (1a) Of the first layer, the second layer formed on the first layer, and the third layer formed on the second layer, the second layer A first winding body provided in the layer of
(1b) a second winding body smaller than the first winding body provided in the first layer;
(1c) a third winding body smaller than the second winding body, provided in the second layer;
(1d) A pair of first input / output wirings for performing one of input and output with respect to a balanced signal extending from the first winding body in the second layer;
(1e) a pair of first connection wires for connecting the first winding body and the second winding body;
(1f) a first winding having a pair of second connection wirings for connecting the second winding body and the third winding body;
(2) (2a) a spiral fourth winding body provided in the third layer;
(2b) starting from an end on the center side of the fourth winding body, a third connection wiring provided across the third layer and the second layer;
(2c) In the second layer, the pair of first input wires is directed toward the outside of the fourth winding body starting from an end of the third connection wiring in the second layer. A second input / output wiring extending through a space defined by the output wiring, wherein the input and the output in cooperation with an outer end portion of the fourth winding body for an unbalanced signal; A second winding having the second input / output wiring for performing the other of the first winding and the second winding superimposed on the first winding.

  According to the inductor of Application Example 2, the input / output wiring of the second winding is defined by the twist relationship of the pair of first connection wirings of the first winding in the second layer. Since the input / output wiring does not need to be provided in a layer other than the first layer to the third layer by extending toward the outside of the second winding through the region to be conventional, Unlike the conventional example, the inductor of the application example 2 can be configured by only three layers, ie, the first layer to the third layer, and can be “thinned” compared to the conventional one.

[Application Example 3]
The inductor of application example 3 is the inductor of application example 1,
The pair of first connection wires, the pair of second connection wires, the pair of third connection wires, and the pair of fourth connection wires are twisted and obtuse. A convex portion having an apex angle is provided.

[Application Example 4]
The inductor of application example 4 is the inductor of application example 2,
The pair of first connection wirings and the pair of second connection wirings are in a twisted relationship with each other and include convex portions having apex angles that are obtuse angles.

[Application Example 5]
The inductor of application example 5 is the inductor of application example 1,
The pair of first connection wirings, the pair of second connection wirings, the pair of third connection wirings, and the pair of fourth connection wirings have curved portions that are twisted with each other. Prepare.

[Application Example 6]
The inductor of application example 6 is the inductor of application example 2,
The pair of first connection wirings and the pair of second connection wirings include curved portions that are twisted with each other.

[Application Example 7]
The inductor of application example 7 is the inductor of application example 1,
The pair of first connection wirings, the pair of second connection wirings, the pair of third connection wirings, and the pair of fourth connection wirings include notch portions.

[Application Example 8]
The inductor of application example 8 is the inductor of application example 2,
The pair of first connection wirings and the pair of second connection wirings include notch portions.

  An inductor according to an embodiment will be described with reference to the drawings.

Example 1
<First winding and second winding>
FIG. 1 is a perspective view illustrating the configuration of the inductor according to the first embodiment, and FIG. 2 is a plan view and a cross-sectional view illustrating the configuration of the inductor according to the first embodiment. The inductor D1 according to the first embodiment functions as a transformer between one balanced circuit system and another balanced circuit system (for example, a balanced signal input from a high impedance circuit system). Converted to another balanced signal that matches the low-impedance circuit system and outputs it, or, on the contrary, matches the balanced signal input from the low-impedance circuit system to the high-impedance circuit system. As shown in FIGS. 1 and 2 (A), a first winding W1 and a second winding W2 are included.

  Layers L1 to L3 (shown in FIG. 2B), such as the connection wiring W1 (L1-L2) em1 and W1 (L1-L2) em2 of the first winding W1, which are clearly shown in FIG. .) A detailed configuration of the connection wiring between them will be described later with reference to FIG.

  As shown in FIG. 2B, the first winding W1 and the second winding W2 are a first layer L1 and a second layer formed on the substrate SB with a passivation layer PV therebetween. L2 is provided over the third layer L3. That is, the first winding W1 and the second winding W2 are superimposed as shown in FIGS. 2A and 2B, and in detail, as shown in FIG. 2B. The fourth winding body WD4 of the second winding W2 is located above the first winding body WD1 of the first winding W1, and the fifth winding of the second winding W2 The wire body WD5 is above the second winding body WD2 of the first winding W1 and the third winding body WD1 of the first winding W1 and the third winding body WD3 of the first winding W1. The sixth winding body WD6 of the second winding W2 is located above the third winding body WD3 of the first winding W1.

  FIG. 3A is a plan view showing the configuration of the second winding of the first embodiment, and FIG. 3B is a plan view showing the configuration of the first winding of the first embodiment. 4A is a perspective view showing the configuration of the second winding of the first embodiment, and FIG. 4B is a perspective view showing the configuration of the first winding of the first embodiment. is there.

<First winding>
As shown in FIGS. 3B and 4B, the first winding W1 includes the first winding body WD1, the second winding body WD2, and the third winding body WD3. A pair of input / output wirings W1 (L2) eA, W1 (L2) eB, a pair of connection wirings W1 (L1-L2) em1, W1 (L1-L2) em2, and a pair of connection wirings W1 (L1-L2). ) Mi1, W1 (L1-L2) mi2.

  As shown in FIG. 2B, the first winding body WD1 is provided in the second layer L2, and as shown in FIGS. 3B and 4B, It is composed of six line portions, that is, line portions W1 (L2) e1 to W1 (L2) e6. Also, an input for inputting or outputting one balanced signal from the first winding body WD1 from the line portions W1 (L2) e3, W1 (L2) e4 of the first winding body WD1. The output wirings W1 (L2) eA and W1 (L2) eB extend or project along the Y direction.

  As shown in FIG. 2B, the second winding body WD2 is provided in the first layer L1 below the second layer L2, and the second winding body WD2 is also shown in FIGS. As shown in FIG. 4B, it is formed slightly smaller than the first winding body WD1. The second winding main body WD2 includes six line portions, that is, line portions W1 (L1) m1 to W1 (L1) m6.

  As shown in FIG. 2B, the third winding body WD3 is provided in the second layer L2 similarly to the first winding body WD1, and the third winding body WD3 and FIG. As shown in FIG. 4B, it is formed slightly smaller than the second winding body WD2. The third winding body WD3 includes five line portions, that is, line portions W1 (L2) i1 to W1 (L2) i5.

  As shown in FIGS. 3B and 4B, the first winding body WD1 and the second winding body WD2 are a pair of connection wirings W1 (L1-L2) in a twisted relationship. em1, W1 (L1-L2) em2, and more specifically, the line W1 (L2) e1 of the first winding body WD1 and the line W1 (L1) m6 of the second winding body WD2 Are connected by connection wiring W1 (L1-L2) em1, and line portion W1 (L2) e6 of first winding body WD1 and line portion W1 (L1) m1 of second winding body WD2 are connected. Are connected by a connection wiring W1 (L1-L2) em2.

  As shown in FIGS. 3B and 4B, the second winding body WD2 and the third winding body WD3 are a pair of connection wirings W1 (L1-L2) in a twisted relationship. mi1, W1 (L1-L2) mi2, and more specifically, the line W1 (L1) m4 of the second winding body WD2 and the line W1 (L2) i5 of the third winding body WD3 Are connected by connection wiring W1 (L1-L2) mi1, and line portion W1 (L1) m3 of second winding body WD2 and line portion W1 (L2) i1 of third winding body WD3 are connected. Are connected by a connection wiring W1 (L1-L2) mi2.

<Second winding>
As shown in FIGS. 3A and 4A, the second winding W2 includes a fourth winding body WD4, a fifth winding body WD5, and a sixth winding body WD6. A pair of connection wirings W2 (L2-L3) em1, W2 (L2-L3) em2, a pair of connection wirings W2 (L2-L3) mi1, W2 (L2-L3) mi2, and a pair of input / output wirings W2. (L3) eA, W2 (L3) eB.

  As shown in FIG. 2B, the fourth winding main body WD4 is provided in the third layer L3 that is above the second layer L2, and the fourth winding body WD4 is also shown in FIGS. As shown in FIG. 4 (A), it is composed of six line portions, that is, line portions W2 (L3) e1 to W2 (L3) e6. Further, from the line portions W2 (L3) e1 and W2 (L3) e6 of the fourth winding body WD4, another balanced type signal different from the one balanced type from the fourth winding body WD4. Input / output wirings W2 (L3) eA and W2 (L3) eB for extending or projecting.

  The fifth winding body WD5 is provided in the second layer L2, as shown in FIG. 2B, and as shown in FIGS. 3A and 4A, It is formed slightly smaller than the fourth winding body WD4. In addition, the fifth winding body WD5 has the same relationship as the first winding body WD1 and the third winding body WD3 with respect to the first winding body WD1 and the third winding body WD3. Between the winding body WD3. The fifth winding main body WD5 includes six line portions, that is, line portions W2 (L2) m1 to W2 (L2) m6.

  As shown in FIG. 2 (B), the sixth winding body WD6 is provided in the third layer L3 similarly to the fourth winding body WD4. As shown in FIG. 4A, it is formed slightly smaller than the fifth winding body WD5. The sixth winding body WD6 includes five line portions, that is, line portions W2 (L3) i1 to W2 (L3) i5.

  As shown in FIGS. 3A and 4A, the fourth winding body WD4 and the fifth winding body WD5 are a pair of connecting wires W2 (L2-L3) in a twisted relationship. em1, W2 (L2-L3) em2, and more specifically, a line W2 (L3) e3 of the fourth winding body WD4 and a line W2 (L2) m4 of the fifth winding body WD5 Are connected by connection wiring W2 (L2-L3) em1, and line portion W2 (L3) e4 of fourth winding body WD4 and line portion W2 (L2) m3 of fifth winding body WD5 are connected. Are connected by a connection wiring W2 (L2-L3) em2.

  As shown in FIGS. 3A and 4A, the fifth winding body WD5 and the sixth winding body WD6 are a pair of connection wires W2 (L2-L3) in a twisted relationship. mi1, W2 (L2-L3) mi2 are connected. Specifically, the line portion W2 (L2) m6 of the fifth winding body WD5 and the line portion W2 (L3) i1 of the sixth winding body WD6. Are connected by a connection wiring W2 (L2-L3) mi1, and the line W2 (L2) m1 of the fifth winding body WD5 and the line W2 (L3) of the sixth winding body WD6. i5 is connected to the connection wiring W2 (L2-L3) mi2.

<effect>
As described above, the inductor D1 according to the first embodiment is configured to overlap the first winding W1 and the second winding W2, and is provided in the second layer L2. The fifth winding body WD5 of the second winding W2 is located between the first winding body WD1 and the third winding body WD3 of the first winding W1. Therefore, unlike the conventional case, the inductor D1 can be configured by only three layers, that is, the first layer L1 to the third layer L3, thereby “thinning” the inductor D1. It becomes possible.

Example 2
<First winding and second winding>
FIG. 5 is a perspective view illustrating the configuration of the inductor according to the second embodiment, and FIG. 6 is a plan view and a cross-sectional view illustrating the configuration of the inductor according to the second embodiment. Inductor D2 of the second embodiment has a first winding W1 as shown in FIGS. 5 and 6A to function as a transformer between a balanced circuit system and an unbalanced circuit system. And a second winding W2.

  Layers L1 to L3 (illustrated in FIG. 6B) such as the connection wiring W1 (L1-L2) mi1 and W1 (L1-L2) mi2 of the first winding W1, which are clearly shown in FIG. .) A detailed configuration of the connection wiring between them will be described later with reference to FIG.

  As shown in FIG. 6B, the first winding W1 and the second winding W2 are a first layer L1 and a second layer formed on the substrate SB with a passivation layer PV therebetween. L2 and the third layer L3 are provided. Specifically, the first winding W1 and the second winding W2 overlap each other.

  FIG. 7A is a plan view showing the configuration of the second winding of Example 2, and FIG. 7B is a plan view showing the configuration of the first winding of Example 2. FIG. 8 is a perspective view showing the configuration of the second winding of the second embodiment. FIG. 8B is a perspective view showing the configuration of the first winding of the second embodiment.

<First winding>
As shown in FIGS. 7B and 8B, the first winding W1 includes the first winding body WD1, the second winding body WD2, and the third winding body WD3. A pair of input / output wirings W1 (L2) eA, W1 (L2) eB, a pair of connection wirings W1 (L1-L2) em1, W1 (L1-L2) em2, and a pair of connection wirings W1 (L1-L2). ) Mi1, W1 (L1-L2) mi2.

  As shown in FIG. 6B, the first winding body WD1 is provided in the second layer L2, and as shown in FIGS. 7B and 8B, It is composed of six line portions, that is, line portions W1 (L2) e1 to W1 (L2) e6. Input / output wiring W1 for inputting or outputting a parallel signal from the first winding body WD1 from the line portions W1 (L2) e1 and W1 (L2) e6 of the first winding body WD1 ( L2) eA and W1 (L2) eB respectively extend or protrude in the Y direction.

  As shown in FIG. 6B, the second winding main body WD2 is provided in the first layer L1, which is below the second layer L2, and the second winding main body WD2 is also shown in FIGS. As shown in FIG. 8B, it is formed slightly smaller than the first winding body WD1. The second winding main body WD2 includes six line portions, that is, line portions W1 (L1) m1 to W1 (L1) m6.

  As shown in FIG. 6B, the third winding body WD3 is provided in the second layer L2 similarly to the first winding body WD1, and the third winding body WD3 and FIG. As shown in FIG. 8B, it is formed slightly smaller than the second winding body WD2. The third winding body WD3 includes five line portions, that is, line portions W1 (L2) i1 to W1 (L2) i5.

  As shown in FIGS. 7B and 8B, the first winding body WD1 and the second winding body WD2 are a pair of connection wirings W1 (L1-L2) in a twisted relationship. em1, W1 (L1-L2) em2, and more specifically, a line W1 (L2) e3 of the first winding body WD1 and a line W1 (L1) m4 of the second winding body WD2 Are connected by connection wiring W1 (L1-L2) em1, and line portion W1 (L2) e4 of first winding body WD1 and line portion W1 (L1) m3 of second winding body WD2 are connected. Are connected by a connection wiring W1 (L1-L2) em2.

  As shown in FIGS. 7B and 8B, the second winding body WD2 and the third winding body WD3 are a pair of connection wirings W1 (L1-L2) in a twisted relationship. mi1, W1 (L1-L2) mi2 are connected. Specifically, the line portion W1 (L1) m6 of the second winding body WD2 and the line portion W1 (L2) i1 of the third winding body WD3. Are connected by a connection wiring W1 (L1-L2) mi1, and the line W1 (L1) m1 of the second winding body WD2 and the line W1 (L2) of the third winding body WD3. i5 is connected to the connection wiring W1 (L1-L2) mi2.

<Second winding>
As shown in FIGS. 7A and 8A, the second winding W2 includes the fourth winding body WD4, the connection wiring W2 (L2-L3), and the input / output wiring W2 (L2). ) And.

  As shown in FIG. 6B, the fourth winding main body WD4 is provided in the third layer L3, which is above the second layer L2, and is also shown in FIGS. As shown in FIG. 8 (A), it is composed of 12 line portions, line portions W2 (L3) 1 to W2 (L3) 12.

  The line portions W2 (L3) 1 to W2 (L3) 12 cooperate to form a spiral shape.

  As shown in FIGS. 7A and 8B, the connection wiring W2 (L2-L3) starts from the end ED4 on the center side of the fourth winding main body WD4, and the third wiring It extends in the Z direction across the layer L3 and the second layer L2.

  The input / output wiring W2 (L2) is provided in the second layer L2, as shown in FIG. 6B, and further, as shown in FIG. 8A, the connection wiring W2 (L2-). L3) toward the outside of the fourth winding body WD4 starting from the end ED5, as shown in FIG. 7B and FIG. It extends through the area AR1 defined by the output wirings W1 (L2) eA and W1 (L2) eB. The input / output wiring W2 (L2) is used to perform the other of the input and the output in cooperation with the outer end ED6 of the fourth winding body WD4 for an unbalanced signal.

  As described above, in the inductor D2 of the second embodiment, the first winding W1 for input / output of the balanced signal and the second winding W2 for input / output of the unbalanced signal are provided. , Superimposed. Moreover, the input / output wiring W2 (L2) connected to the end ED4 of the fourth winding body WD4 of the second winding W2 via the connection wiring W2 (L2-L3) is connected to the first winding W1. By extending through the area AR1 defined by the pair of input / output wirings W1 (L2) eA and W1 (L2) eB, the input / output wiring W2 (L2) is connected to the first layer L1 to the third layer. Since it is not necessary to provide in layers other than L3, it becomes possible to comprise the inductor D2 of the said Example 2 only by the 1st layer L1-the 3rd layer L3, ie, compared with the former. It can be “thinned”.

<< Connection wiring between layers of Example 1 and Example 2 >>
FIG. 9 is a perspective view illustrating the configuration of the connection wiring between the layers in the first and second embodiments. 4A and 4B, connection wirings W1 (L1-L2) em1, W1 (L1-L1), which are wirings between the layer L1 and the layer L2 in the first winding W1 of the first embodiment. L2) em2, W1 (L1-L2) mi1, W1 (L1-L2) mi2, and connection wires W2 (L2-L3) mi1, W2 that are wires between the layers L2 and L3 in the second winding W2. (L2-L3) mi2, W2 (L2-L3) em1, W2 (L2-L3) em2, and the layers L1, L2 in the first winding W1 of the second embodiment, which is clearly shown in FIG. 8B. The detailed structure of the connection wirings W1 (L1-L2) mi1, W1 (L1-L2) mi2, W1 (L1-L2) em1, and W1 (L1-L2) em2 as the wiring between them is as follows. is there.

  That is, for example, the connection wirings W1 (L1-L2) em1 and W1 (L1-L2) em2 of the first embodiment have convex portions having apex angles that are obtuse angles as shown in FIG. And have a twisted relationship with each other, as shown in FIG. 9B, have curved portions and have a twisted relationship with each other, or shown in FIG. 9C. As shown, it has a notch. By having such a structure, it can be avoided that one of the connection wiring W1 (L1-L2) em1 and the connection wiring W1 (L1-L2) em2 becomes an obstacle to the other.

  Other connection wirings W1 (L1-L2) mi1, W1 (L1-L2) mi2, W2 (L2-L3) mi1, W2 (L2-L3) mi2, W2 (L2-L3) em1, W2 (L2-L3) em2, W1 (L1-L2) mi1, and W1 (L1-L2) mi2 also have a similar structure, whereby the same effects as described above can be obtained.

FIG. 3 is a perspective view illustrating a configuration of an inductor according to the first embodiment. FIG. 2 is a plan view and a cross-sectional view illustrating the configuration of the inductor according to the first embodiment. FIG. 3 is a plan view illustrating configurations of a first winding and a second winding according to the first embodiment. FIG. 3 is a perspective view illustrating configurations of a first winding and a second winding according to the first embodiment. FIG. 6 is a perspective view illustrating a configuration of an inductor according to a second embodiment. FIG. 6 is a plan view and a cross-sectional view illustrating a configuration of an inductor according to a second embodiment. The top view which shows the structure of the 1st coil | winding of Example 2, and a 2nd coil | winding. The perspective view which shows the structure of the 1st coil | winding of Example 2, and a 2nd coil | winding. The perspective view which shows the detailed structure of the connection wiring between the layers of Example 1 and Example 2. FIG. The top view and sectional drawing which show the structure of the conventional inductor.

Explanation of symbols

  D1 ... inductor, W1 ... first winding, W2 ... second winding, WD1 to WD6 ... first winding body to sixth winding body.

Claims (8)

(1) (1a) Of the first layer, the second layer formed on the first layer, and the third layer formed on the second layer, the second layer A first winding body provided in the layer of
(1b) a second winding body smaller than the first winding body provided in the first layer;
(1c) a third winding body smaller than the second winding body, provided in the second layer;
(1d) A pair of first input / output wirings for performing one of input and output of a balanced first signal extending from the first winding body in the second layer;
(1e) a pair of first connection wires for connecting the first winding body and the second winding body;
(1f) a first winding having a pair of second connection wirings for connecting the second winding body and the third winding body;
(2) (2a) a fourth winding body provided in the third layer;
(2b) A fifth winding body smaller than the fourth winding body provided between the first winding body and the third winding body in the second layer. When,
(2c) a sixth winding body smaller than the fifth winding body provided in the third layer;
(2d) a pair of second input / output lines for performing the other of the input and output of the balanced second signal extending from the fourth winding body in the third layer;
(2e) a pair of third connection wires for connecting the fourth winding body and the fifth winding body;
(2f) a second winding having a pair of fourth connection wirings for connecting the fifth winding body and the sixth winding body, the first winding being connected to the first winding; And an inductor that overlaps the second winding. (1) (1a) Of the first layer, the second layer formed on the first layer, and the third layer formed on the second layer, the second layer A first winding body provided in the layer of
(1b) a second winding body smaller than the first winding body provided in the first layer;
(1c) a third winding body smaller than the second winding body, provided in the second layer;
(1d) a pair of first input / output wirings for performing one of input and output with respect to a balanced signal extending from the first winding body in the second layer; A pair of first connection wires for connecting the first winding body and the second winding body;
(1f) a first winding having a pair of second connection wirings for connecting the second winding body and the third winding body;
(2) (2a) a spiral fourth winding body provided in the third layer;
(2b) starting from an end on the center side of the fourth winding body, a third connection wiring provided across the third layer and the second layer;
(2c) In the second layer, the pair of first input wires is directed toward the outside of the fourth winding body starting from an end of the third connection wiring in the second layer. A second input / output wiring extending through a space defined by the output wiring, wherein the input and the output in cooperation with an outer end portion of the fourth winding body for an unbalanced signal; A second winding having the second input / output wiring for performing the other of the first winding and the second winding superimposed on the first winding. Inductor.   The pair of first connection wires, the pair of second connection wires, the pair of third connection wires, and the pair of fourth connection wires are twisted and obtuse. The inductor according to claim 1, further comprising a convex portion having an apex angle.   3. The pair of first connection wirings and the pair of second connection wirings are in a twisted relationship with each other and have convex portions having apex angles that are obtuse angles. The described inductor.   The pair of first connection wirings, the pair of second connection wirings, the pair of third connection wirings, and the pair of fourth connection wirings have curved portions that are twisted with each other. The inductor according to claim 1, further comprising:   3. The inductor according to claim 2, wherein the pair of first connection wirings and the pair of second connection wirings include curved portions having a twisted relationship with each other.   The pair of first connection wirings, the pair of second connection wirings, the pair of third connection wirings, and the pair of fourth connection wirings include notch portions. The inductor according to claim 1.   3. The inductor according to claim 2, wherein the pair of first connection wirings and the pair of second connection wirings include notch portions.

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