JP2011114373A - Structure for connecting high frequency circuit with microstrip line, and high frequency module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a structure for easily connecting a high frequency circuit with a microstrip line using a conducting wire, and provide a high frequency module. <P>SOLUTION: The structure for connecting the high frequency circuit with the microstrip line includes a high frequency component 30, a microstrip line, a second reference wiring 232, a first conducting wire 41, and second conducting wires 42 and 43. The high frequency component 30 has a high frequency circuit which includes a signal terminal 31 and reference potential terminals 32 and 33. The microstrip line includes a substrate 21, a signal wiring 22 for transmitting a high frequency signal, and a first reference wiring used as a reference potential of the signal wiring 22. The second reference wiring 232 is prepared on the substrate 21, located between the signal terminal 31 and the signal wiring 22, and electrically connected to the first reference wiring. The first conducting wire 41 is connected to the signal terminal 31, and extended from the high frequency component 30 toward the signal wiring 22, across the second reference wiring 232. The second conducting wires 42 and 43 are connected to the reference potential terminals 32 and 33, and extended from reference potential terminals 32 and 33 toward the signal wiring 22. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a coupling structure between a high-frequency circuit and a microstrip line, and a high-frequency module.

  In general, when a semiconductor element such as MMIC (Monolithic Microwave Integrated Circuit) is mounted on a high-frequency circuit board and a control signal of the semiconductor element and a high-frequency signal are electrically connected to the high-frequency circuit board, a conductive wire such as a bond wire is used. The signal line on the high frequency circuit board and the semiconductor element are connected. In particular, in a high frequency region represented by millimeter waves, a microstrip line is used as a signal line on a high frequency circuit board.

  When a conductor is extended from a semiconductor element and connected to a signal line on a high-frequency circuit board, an inductance component is mainly generated between the signal line and the semiconductor element according to the length of the line of the conductor. In the low frequency region, since the wavelength is long, the inductance component can be substantially ignored. However, in the high frequency region, since the wavelength is short, the inductance component cannot be ignored. This is because in the high frequency region, transmission characteristics deteriorate due to signal reflection due to impedance mismatching, radiation due to separation from the ground conductor of the semiconductor element, and the like.

  For this reason, in the high-frequency region, it is common knowledge to shorten the length of a conducting wire such as a bond wire as much as possible. Therefore, there is a type in which a part of the high-frequency circuit board is formed as a cavity and a semiconductor element is arranged inside the cavity. The semiconductor element is arranged so that the length of the conductive wire is shortened by making the height of the connection terminal of the semiconductor element coincide with the height of the connection terminal of the high-frequency circuit board as much as possible when arranging inside the cavity.

  On the other hand, there is a method of introducing a capacitance component in order to cancel the generated inductance component. For example, an element such as a single-plate capacitor is mounted on a high-frequency circuit board, and a method of connecting a conductive wire to this element, and a conductive wire is connected to a strip line on the high-frequency substrate to form a stub or the like on the strip line Thus, there is a technique for matching impedance by introducing a capacitance component.

  Actually, in many cases, the above two techniques are used in combination (see, for example, Patent Document 1).

JP 2007-95838 A

  However, the above prior art has the following problems.

  A technique for forming a part of a high-frequency circuit board as a cavity is often used in a ceramic multilayer wiring board. However, in order to employ this technique, high dimensional accuracy is required so that the height of the connection terminal of the semiconductor element and the height of the connection terminal of the high-frequency circuit board are matched as much as possible.

  In addition, in the method of introducing a capacitance component by mounting a single plate capacitor, the capacitance of the single plate capacitor is determined, so that the variation in inductance due to the variation in the length of the conductor due to the mounting deviation of the semiconductor element is corrected. I can't. On the other hand, in the method of forming a stub on the strip line connecting the conducting wires, the frequency band in which impedance matching can be achieved becomes narrower as the inductance component of the conducting wire becomes larger, and it becomes sensitive to the size and position of the stub. For this reason, high dimensional accuracy is required for the high-frequency circuit board.

  The present invention has been devised in view of such problems in the prior art. An object of the present invention is to provide a high-frequency circuit-slot coupling structure and a high-frequency module that can easily couple two high-frequency circuits with a conductive wire.

  The coupling structure of the high-frequency circuit and the microstrip line according to the present invention is a signal terminal used for at least one of input and output of a high-frequency signal, and a reference potential of the high-frequency signal arranged adjacent to the signal terminal. A high-frequency circuit having a reference potential terminal, an insulating substrate, a signal wiring for transmitting the high-frequency signal provided on the insulating substrate, and the signal wiring provided on the insulating substrate A first reference wiring having a first reference potential, and a microstrip line configured on the insulating substrate and positioned between the signal terminal and the signal wiring. A second reference wiring electrically connected to the reference wiring, a first end connected to the signal terminal, and a second end extending from the high-frequency circuit toward the signal wiring. The first conductive wire provided across the second reference wiring and the first end are connected to the reference potential terminal, and the second end extends from the reference potential terminal to the reference wiring. A second conducting wire extending in the direction.

  The high-frequency module of the present invention includes a protective member provided across the high-frequency circuit, the first conductive wire, and the second conductive wire, and the high-frequency circuit and the microstrip line described above. Has a combined structure.

  ADVANTAGE OF THE INVENTION According to this invention, the coupling structure of the high frequency circuit and microstrip line which can couple | bond two high frequency circuits easily with conducting wire, and a high frequency module can be provided.

1 is an external perspective view schematically showing a first embodiment of a coupling structure of a high-frequency circuit and a microstrip line according to the present invention. It is a top view which shows typically the coupling structure of the high frequency circuit shown in FIG. 1, and a microstrip line. It is sectional drawing along the III-III line shown in FIG. FIG. 4 is a sectional view taken along line IV-IV shown in FIG. 2. It is sectional drawing which shows typically other embodiment of the coupling structure of the high frequency circuit of this invention, and a microstrip line.

  Hereinafter, a high-frequency module employing a coupling structure of a high-frequency circuit and a microstrip line according to the present invention will be described in detail with reference to the accompanying drawings.

  The high frequency module 10 according to the first embodiment shown in FIGS. 1, 2, and 3 includes a conductive structure 20, a high frequency component 30 incorporating a high frequency circuit, a conductive wire 40, and a protection member 50. ing.

  The conductive structure 20 includes a base body 21, a signal wiring 22, and a reference wiring 23. In this dielectric structure 20, the signal wiring 22 and a part of the reference wiring 23 are electromagnetically coupled via the base 21 to function as a microstrip line 20 a.

  The substrate 21 functions as a substrate that supports the signal wiring 22 and the reference wiring 23. The base body 21 of the present embodiment also functions as a base material that supports the high-frequency component 30 and the protection member 50. Examples of the material for forming the base material 21 include insulating resins including ceramics, glass, or epoxy resins. The base body 21 is provided with a plurality of via holes 21a penetrating the base body 21 in the thickness direction (z direction).

  The signal wiring 22 has a function of transmitting a high frequency signal. The signal wiring 22 is provided on the first main surface 21 b of the base 21. This signal wiring 22 is provided as a layer extending along the transmission direction x of the high frequency signal shown as the x direction. The signal wiring 22 is provided as a strip line in the microstrip line 20a.

  The reference wiring 23 includes a first reference wiring 231, a second reference wiring 232, and a via conductor 233. The reference wiring 23 functions as a reference potential for a high-frequency signal transmitted through the signal wiring 22.

The first reference wiring 231 is provided on the second main surface 21 c of the base body 22. The second main surface 21c is a surface that spreads in pairs with the first main surface 21b. The first reference wiring 231 is electrically connected to the second reference wiring 232 via the via conductor 233. The first reference wiring 231 is provided so as to overlap the second reference wiring 232 and the signal wiring 22 in a transmission plan view. The first reference wiring 231 is provided such that the length W ₃₁ in the second direction is longer than the length W ₂₂ in the second direction of the second reference wiring 232. The first reference wiring 231 is electromagnetically coupled to the signal wiring 22 through the base 21 and functions as a reference wiring in the microstrip line 20a.

The second reference wiring 232 is provided on the first main surface 21 b of the base body 21. The second reference wiring 232 is disposed between the signal wiring 22 and the high-frequency component 30 in plan view. The second reference wiring 232 is provided as a rectangular layer extending long in the direction intersecting the transmission direction x. Here, the intersecting direction in which the second reference wiring 232 extends long is the second direction. This second direction is shown in FIG. 1 as the y direction. The second reference wiring 232 is provided such that the length W ₃₁ in the second direction is longer than the length W ₂ of the signal wiring 22 in the second direction. The second reference wiring 232 is provided so that the distance from the signal wiring 22 is the shortest at the center.

  A plurality of via conductors 233 are provided inside the via hole 21a of the base 21 and are provided through the via hole 21a. The via conductor 233 electrically connects the first reference wiring 231 and the second reference wiring 232. The via conductor 233 is provided below the central portion of the second reference wiring 232 in the second direction.

  The high-frequency component 30 includes a high-frequency circuit that is transmitted via a high-frequency signal. The high-frequency component 30 is provided on the first main surface 21 b of the base 21. The high frequency component 30 of the present embodiment includes a signal terminal 31 and a reference potential terminal 32.

  The signal terminal 31 is used for at least one of input and output of a high-frequency signal. That is, the signal terminal 31 may be used for inputting a high-frequency signal, used for outputting a high-frequency signal, or used for both input and output of a high-frequency signal. Further, the signal terminal 31 is electrically connected to a high frequency circuit built in the high frequency component 30. The signal terminal 31 of the present embodiment is provided on the upper surface 30 a of the high frequency component 30.

  The reference potential terminal 32 is electrically connected to the reference potential of the high frequency component 30. The reference potential terminal 32 is provided adjacent to the signal terminal 31 while being insulated from the signal terminal 31. In the present embodiment, two reference potential terminals 32 are provided apart from each other, and the signal terminal 31 is provided between the two reference potential terminals 32.

  The conductive wire 40 electromagnetically connects the conductive structure 20 and the high-frequency component 30. The conducting wire 40 includes a first conducting wire 41 and second conducting wires 42 and 43. As what forms the conducting wire 40, metal materials, such as gold | metal | money and aluminum, are mentioned, for example. As the thickness of the conducting wire 40, for example, one having a diameter in the range of 0.01 to 0.05 [mm] is employed. The conductive layer 40 can be easily formed using, for example, a wire bonder. Here, the “conductive wire” refers to a linear or strip-like conductor, and includes, for example, a ribbon wire. “Electromagnetically connecting” means that a high-frequency signal is conducted through electromagnetic waves.

  The first conductive wire 41 electromagnetically connects the signal wiring 22 and the signal terminal 31. The first conducting wire 41 of the present embodiment electrically connects the signal wiring 22 and the signal terminal 31 directly. More specifically, one end of the first conducting wire 41 is physically connected to the signal terminal 31. The other end of the first conducting wire 41 is physically connected to the signal wiring 22 located on the other side of the second reference wiring 232 when viewed from the high frequency component 30. It is provided so as to straddle the reference wiring 232. That is, the first conducting wire 41 is provided so as to cross over the second reference wiring 232. Here, “crossing over the first reference wiring” means that the first conductive wire 41 is provided apart from the second reference wiring 232, and the first conductive wire 41 when viewed in plan from the z direction. It means that the conducting wire 41 intersects the second reference wiring 232. The first conducting wire 41 of the present embodiment passes above one via conductor 23 among the plurality of via conductors 233.

  Further, since the tip of the first conducting wire 41 is in contact with the signal wiring 22, the tip can be regarded as a short end. Therefore, it is preferable that the length of the first conducting wire 41 is an integral multiple of the length of ½ of the signal wavelength.

  Further, the first conductive wire 41 is provided so as to intersect the second reference wiring 232 at the center of the second reference wiring 232 in the second direction (y direction) when viewed in plan from the z direction. Yes. The first conductive wire 41 of the present embodiment is orthogonal to the direction in which the second reference wiring 232 extends long when viewed in plan from the z direction. The first conductive wire 41 does not have to be orthogonal to the direction in which the second reference wiring 232 extends long, and is inclined with respect to the direction in which the second reference wiring 232 extends. Even when they are, they can be electromagnetically coupled. The first conducting wire 41 can strengthen the coupling with the microstrip line 20a by bringing the extending direction closer to the direction in which the second reference wiring 232 extends long.

  The second conductive wires 42 and 43 electromagnetically connect the reference wiring 23 of the conductive structure 20 and the reference potential terminal 32. The second conductive wires 42 and 43 of the present embodiment electrically connect the reference wiring 23 and the reference potential terminal 32 directly. More specifically, the second conductors 42 and 43 have a first end connected to the reference potential terminal 32 and a second end seen from the high-frequency component 30 in front of the signal wiring 22. Is connected to a reference wiring 23 located at

  The second conductive wires 42 and 43 are provided so as to extend along the first conductive wire 41. In addition, by providing the two second conducting wires 42 and 43 along the first conducting wire in this way, the coupling with the first conducting wire 41 can be strengthened, and the leakage of electromagnetic waves can be reduced. Can do.

  The second conductive wires 42 and 43 of the present embodiment extend in parallel to the first conductive wire 41 when viewed from the z direction. The second conductors 42 and 43 do not necessarily have to extend in parallel to the first conductor 41. For example, the second conductive wires 42 and 43 may be provided with their mutual distance extended to the end of the second reference wiring 232.

  The protection member 50 is provided across the signal wiring 22, the second reference wiring 232, the high-frequency component 30, and the conductive wire 40. The protection member 50 protects the signal wiring 22, the second reference wiring 232, the high-frequency component 30, and the conductive wire 40. Here, “protection” refers to mechanical protection, and, for example, disconnection due to external force of the conducting wire 40 is reduced. The protective member 50 is indicated by a dotted line in the drawing in order to visualize the signal wiring 22, the second reference wiring 232, the high-frequency component 30, and the conductive wire 40. The protective member 50 does not seal the signal wiring 22, the second reference wiring 232, the high-frequency component 30, and the conductive wire 40. For example, the protective member 50 does not have a part of the side surface or is provided with a via hole on the upper surface. The top plate may be supported by a plurality of support posts.

  The coupling structure of the high frequency circuit and the microstrip line according to the present embodiment includes a conductive structure 20 having a microstrip line 20a capable of transmitting a high frequency signal, a high frequency component 30 having a high frequency circuit, and a high frequency. A first terminal is electromagnetically connected to a signal terminal 31 used for at least one of input and output of a high-frequency signal in the circuit, and a second reference wiring 232 that constitutes the microstrip line 20a from the signal terminal 31. A first end is electromagnetically connected to the first conductive wire 41 provided across the upper side and the reference potential terminal 32 serving as the reference potential of the high-frequency circuit, and the microstrip is connected to the reference potential terminal 32. Second conductors 42a, 43a having second ends provided toward the signal wiring 22 constituting the line, and a high-frequency circuit and a slot. And sheet 22 are electromagnetically coupled.

  According to the coupling structure of the high-frequency circuit and the slot of the present embodiment having such a structure, the first conductor 41 having the first end connected to the signal terminal 31 of the high-frequency component 30 incorporating the high-frequency circuit is provided. The high-frequency signal transmitted from the first conductor 41 is coupled to the microstrip line 20a because the microstrip line 22a that can be coupled to the high-frequency signal is arranged so as to cross over the second reference wiring 232. can do. Alternatively, a high frequency signal transmitted from the microstrip line 20 a can be coupled to the first conductor 41.

  The first conducting wire 41 and the second conducting wires 42 and 43 of the present embodiment are in contact with the conductor plate 21. By bringing the first conducting wire 41 and the second conducting wires 42 and 43 into contact with each other in this way, an effect of directly feeding power to the microstrip line 20a is also produced. Therefore, from this point of view, it is desirable that the first conductive wire 41 and the second conductive wires 42 and 43 be close to the signal wiring 22 and the second reference wiring 232 constituting the microstrip line 20a, and the effect of direct power feeding is enhanced. The amount of electromagnetic wave leakage can be reduced. In addition, since the length of the 1st conducting wire 41 is lengthened and the frequency couple | bonded with the microstrip line 20a best is shifted to the low frequency side, or the contrary is shortened, the reverse adjustment can be performed, so that high frequency It is possible to design in consideration of the mounting deviation of the component 30 and the size or positional deviation of the microstrip line 20a.

(Modification)
The present invention is not limited to the embodiments described above, and various modifications and improvements can be made without departing from the scope of the present invention.

  In the present embodiment, the first reference wiring 231 is provided on a part of the second main surface 22c of the base 22, but may be provided on the entire surface. Further, the first reference wiring 231A provided on the entire second main surface 22c of the base 22 is a diamond for mounting the high-frequency component 30 via the second via conductor 24, as shown in FIG. The touch conductor 25 may be electrically connected.

  In the present embodiment, the first conductive wire 41 and the second conductive wires 42 and 43 are in contact with the conductive structure 20, but the configuration is not limited to this. For example, the signal wiring 22 and the first conductor 41 may be brought close to each other without being in contact with each other and electromagnetically connected. Here, when the tip of the first conductive wire 41 is not in contact with the conductive structure 20 or is separated to such an extent that it cannot be considered to be in contact, the tip can be regarded as an open end. In these cases, it is desirable that the length of the first conducting wire 41 is ¼ to ½ of the signal wavelength. When the second end of the first conducting wire 41 is suspended in the air, for example, after the first end of the first conducting wire 41 is connected to the signal terminal 31, the second end of the first conducting wire 41 is connected. The second end of the first conductor 41 may be prevented from being connected by adjusting the state of the place where the wire is connected and the setting of the wire bonder. By doing in this way, the 2nd end of the said 1st conducting wire 41 can be floated in the air by the elasticity of the 1st conducting wire 41. FIG. Furthermore, the shape of the first conductor 41 can be stabilized by covering and fixing the first conductor 41 and its periphery with a resin.

  In the present embodiment, the first conductive wire 41 straddles the central portion of the second reference wiring 232 and is connected to the signal wiring 22, but the first conductive wire 41 is other than the central portion of the second reference wiring 232. It may be connected to the part.

  Although the two 2nd conducting wires of this embodiment are provided as 42 and 43, there may be one or three or more.

  In the present embodiment, an example is shown in which the high-frequency component 30 incorporating the high-frequency circuit is provided on the base 21, but the high-frequency component 30 is not provided on the base 21, but on another substrate. May be provided.

  Not only the form shown by this embodiment but it is also possible to couple | bond and use a high frequency circuit with another high frequency line. Further, the signal wiring 22 may not be provided on the surface of the base 21, and a dielectric layer is provided on the base 21, and the first conductor is provided via a via conductor in a via hole provided in the dielectric layer. 41 and the signal wiring 22 may be connected. Further, when the dielectric is thin, it can be electromagnetically coupled to the microstrip line 20a even when the dielectric is not connected via the via conductor.

DESCRIPTION OF SYMBOLS 10 ... High frequency module 20 ... Conductive structure 20a ... Microstrip line 21 ... Base | substrate 21a ... Via hole 22 ... Signal wiring 23 ... Reference wiring 231 ... 1st reference | standard Wiring 232... Second reference wiring 233... Via conductor 30... High frequency component 31... Signal terminal 32... Reference potential terminal 40. 43 ... 2nd conducting wire 50 ... Protection member

Claims (4)

A high-frequency circuit having a signal terminal used for at least one of an input and an output of a high-frequency signal, and a reference potential terminal that is disposed adjacent to the signal terminal and serves as a reference potential of the high-frequency signal;
An insulating substrate, a signal wiring that is provided on the insulating substrate and that transmits the high-frequency signal, and a first reference wiring that is provided on the insulating substrate and serves as a reference potential of the signal wiring. The configured microstrip line,
A second reference wiring which is provided on the insulating substrate and located between the signal terminal and the signal wiring and electrically connected to the first reference wiring;
A first conductive wire provided across the second reference wiring, the first end being connected to the signal terminal and the second end extending from the high-frequency circuit toward the signal wiring ,and,
A high-frequency circuit and a microstrip line having a first end connected to the reference potential terminal and a second end extending from the reference potential terminal toward the reference wiring. And the combined structure. Two reference potential terminals are provided,
The signal terminal is provided between the two reference potential terminals,
2. The high-frequency circuit and the microstrip line according to claim 1, wherein the two second conductors connected to the two reference potential terminals are provided to extend along both sides of the first conductor. 3. And the combined structure. The insulating substrate has via holes;
The coupling between the high-frequency circuit and the microstrip line according to claim 1 or 2, wherein the second reference wiring is connected to the first reference wiring via via conductors provided in the plurality of via holes. Construction. 4. The high-frequency circuit according to claim 1, further comprising a protective member provided across the high-frequency circuit, the first conductive wire, and the second conductive wire. A high-frequency module that has a coupling structure with a microstrip line.

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