JP3925771B2 - High frequency switch module - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a high-frequency composite component used in a high-frequency band such as a quasi-microwave band, and relates to a high-frequency switch module that handles a transmission / reception system with at least one antenna.
[0002]
[Prior art]
In recent years, the spread of mobile phones has been remarkable, and the functions and services of mobile phones have been improved. Initially, it started with a single-band mobile phone sharing one antenna for one transmission / reception system. For this purpose, a high-frequency switch using a laminated body has also been developed (see, for example, Japanese Patent Laid-Open Nos. 6-197040 and 9-36603).
Since then, with the rapid increase in the number of subscribers, dual-band mobile phones and the like have appeared on the market. This dual-band mobile phone handles two transmission / reception systems, whereas an ordinary mobile phone handles only one transmission / reception system. Thereby, the user can select and use a convenient transmission / reception system.
For example, in a dual-band mobile phone, the GSM1800 system (transmission TX. 1710 to 1785 MHz, reception RX. 1805 to 1880 MHz) and the EGSM 900 system (transmission TX. 880 to 915 MHz, reception RX. 925 to 960 MHz) as the second transmission / reception system It corresponds to two systems.
In such a cellular phone, a signal module corresponding to each frequency, and a switch module configured by using a branching circuit and a switch circuit as a switch for switching a plurality of frequencies are used (for example, JP-A-9-36604). No., JP 11-55002 A).
[0003]
[Problems to be solved by the invention]
Even in conventional high-frequency switch modules, the importance of ground patterns has been vaguely recognized by those skilled in the art. For example, in JP-A-6-197040, as shown in FIG. 8, a wide side electrode GND is connected to an internal ground electrode, and one end of a first diode of a switch circuit is connected to the ground side via a capacitor. A high frequency switch module is described.
That is, the conventional high-frequency switch module often has the external connection terminal EXT on the side surface. This is because when the high frequency switch module is soldered to the printed circuit board, a fillet is formed and the solder strength is increased. The external connection terminals include a transmission terminal TX, a reception terminal RX, a control terminal VC of the switch circuit, a ground terminal GND, and the like.
However, when the external connection terminal EXT is provided on the side surface portion, there is a possibility that a short circuit occurs due to a solder bridge (bridge) with an electronic component DP such as a PIN diode constituting an antenna switching switch circuit mounted on the multilayer ML. This is because the distance between them is too close.
This has become prominent in the trend toward miniaturization of high-frequency switch modules. The trend toward miniaturization often leads to not only a short circuit between the external connection terminal EXT and the electronic component DP but also a short circuit between the external connection terminals EXT. This is a problem that significantly limits the degree of freedom of design in a high-frequency switch module in which a trend toward downsizing is inevitable.
In addition, in the grounding method described in Japanese Patent Laid-Open No. Hei 6-197040, the ground is not stable in terms of high frequency, stray capacitance is generated, isolation is deteriorated, and sometimes the operation becomes unstable. It was. It was often vulnerable to sudden noise and surges such as electrostatic discharge.
Accordingly, the present invention has been made to solve such problems, and provides a high-frequency switch module that is ultra-compact and has a stable grounding, and has no fear of a solder bridge, and has excellent electrical characteristics. The purpose is to do.
[0004]
[Means for Solving the Problems]
  The present inventionA high-frequency switch module in which a switch circuit and a low-pass filter circuit are configured by a switch element mounted on a laminate and an electrode pattern formed on a dielectric layer of the laminate, and an external connection terminal is provided on a bottom surface of the laminate. Although formed on the side surface, the electrode patterns between the dielectric layers and the connection between the electrode patterns and the external connection terminals are all made through holes, and on the bottom side of the multilayer body. A ground electrode is formed on the dielectric layer, a plurality of through holes are extended from the ground electrode to the bottom surface of the multilayer body, and are connected to a plurality of ground terminals of the external connection terminals. The dielectric layer in the region is formed with a through hole connected to the high frequency terminal of the external connection terminals and the switch circuit control terminal. A frequency switch module.
  In the present invention, a demultiplexing circuit for demultiplexing a plurality of transmission / reception signals is provided, and the electrode pattern constituting the demultiplexing circuit and the high-frequency terminal have a plurality of through-holes continuous in the stacking direction of the dielectric layers. It is also preferable to connect them via.
  Only the ground terminal formed in a larger area than the other external connection terminals is formed on the opposite side surfaces of the laminate, and the wide area ground terminal and the ground electrode are connected by a plurality of through holes. It is also preferable. Further, it is preferable to form a high frequency terminal, a switch circuit control terminal, and a ground terminal on the other side surface of the laminate.
  In the present invention, another ground electrode is disposed on the upper side of the ground electrode, and the other ground electrode is formed by extracting a part of the ground electrode, and the electrode disposed between the ground electrodes at the extracted portion. It is preferable that a through hole connected to the pattern is formed.
  In the present invention, a ground terminal or a switch circuit control terminal is preferably arranged next to the high frequency terminal among the external connection terminals.
  In the present invention, a diode or a transistor is preferably used as the switch element.
  In the present invention, it is preferable that a SAW filter is disposed in the laminated body, and the SAW filter is connected to the external connection terminal through a plurality of through holes continuous in the laminating direction of the dielectric layers.
[0005]
In the present invention, a high-frequency switch module circuit is configured only by through holes (also referred to as via holes and via holes) without using side electrodes, and a wide ground (GND) pattern is formed by a plurality of through holes. I found out that earth can be secured.
(Function)
In the present invention, since a wide ground (GND) pattern is formed at the bottom of the multilayer body by a plurality of through holes, the following effects are obtained.
(1) A plurality of through holes were formed in a wide ground (GND) pattern. Therefore, when the high frequency switch module of the present invention is mounted on a substrate such as a mobile phone and soldered, an electrically stable ground can be secured. A wide ground (GND) pattern area can be ensured, and all the ground (GND) patterns can be electrically grounded at a zero potential by a plurality of through holes. It becomes the ground of the same potential in high frequency.
(2) A plurality of through holes, in other words, through holes arranged at a short pitch function as blocking bars in the waveguide. Accordingly, there is an effect of blocking electromagnetic waves below a certain frequency, and a shielding effect is achieved, and in this sense, the earth is stabilized. The shorter the pitch of the through holes, the higher the frequency can be cut off and the better the potential uniformity.
(3) When the shape of the through hole is not a normal circular hole but a long hole, the “blocking bar” effect described in the above (2) is emphasized. Depending on the case, it can be used properly.
[0006]
DETAILED DESCRIPTION OF THE INVENTION
First, a high-frequency switch module according to the present invention will be described with reference to the drawings. 1 shows a single band, and FIG. 2 shows an equivalent circuit when applied to a dual band.
[0007]
FIG. 1 shows a circuit of a high-frequency switch module used in a single-band mobile phone according to an embodiment of the present invention.
The function of the switch circuit is to electrically switch and separate the transmission circuit and the reception circuit at high speed and to connect to the antenna via the antenna terminal. This switch circuit includes two diodes DP1 and DP2 and two transmission lines LP1 and LP2. The diode DP1 has an anode connected to the antenna terminal ANT side, a cathode connected to the transmission TX side, and a ground connected to the cathode side. Is connected to the transmission line LP1.
Usually, a lot or wire is attached outside the high-frequency switch module and connected to the antenna terminal ANT of the high-frequency switch module. However, if the demand for modularization becomes stronger in the future, the planar antenna will be further combined. A high-frequency switch module incorporated in The present invention exemplifies an externally attached antenna as an embodiment, but can also be applied to a composite module including an antenna.
A transmission line LP2 is connected between the antenna side and the reception RX, a diode DP2 having a cathode connected to the reception RX side is connected, and a capacitor CP6 is connected between the anode of the diode DP2 and the ground. In the meantime, an inductor is connected to the control circuit VC2. When a voltage (for example, + 3V, + 2.6V) is applied to the control circuit VC2, the diodes DP2 and DP1 are turned on to connect the transmission circuit TX and the antenna terminal ANT. When no voltage is applied to the control circuit, the antenna terminal ANT and the receiving system RX are connected. In this way, both antennas can share one antenna. The inductor LP connected to the terminal VC2 of the control circuit has a function of preventing the influence even if the impedance on the power supply side fluctuates due to a load fluctuation or the like by increasing the impedance seen from the power supply side.
In this embodiment, since the diode is used for the switch circuit, it has excellent power resistance at high frequencies and low loss.
In this embodiment, a low-pass filter circuit is further inserted on the transmission TX circuit side. That is, the transmission line LP3 and the capacitors CP3, CP4, and CP7 are inserted between the diode DP1 of the switch circuit SW and the transmission line LP1. When a low-pass filter is inserted, harmonics generated from an amplifier (amplifier) or the like can be suppressed.
FIG. 2 is a perspective view of an embodiment in which the single-band high-frequency switch module of FIG. 1 is mounted. DP is an electronic component in which the diode DP1 and the diode DP2 are packaged. Side electrodes were not used at all, and all the electrical connections between the layers of the laminate were made through holes.
[0008]
FIG. 3 shows one embodiment of the dual band.
This embodiment is a high-frequency switch module that handles a first transmission / reception system (EGSM900) and a second transmission / reception system (GSM1800) having different passbands, and switches between a transmission signal and a reception signal of the first transmission / reception system (EGSM900). A first switch circuit; a first low-pass filter circuit connected to a transmission line of the first switch circuit; a second switch circuit that switches between a transmission signal and a reception signal of the second transmission / reception system (GSM1800); A second low-pass filter circuit connected to the transmission line of the switch circuit, and a demultiplexing circuit for demultiplexing the first transmission / reception system and the second transmission / reception system.
The branching circuit portion connected to the antenna terminal ANT has two notch circuits as main circuits. That is, the transmission line LF1 and the capacitor CF1 constitute one notch circuit, and the transmission line LF2 and the capacitor CF2 constitute another notch circuit.
A capacitor CF3 connected to the ground is connected to one notch circuit. The capacitor CF3 is connected for the purpose of improving the low-pass filter characteristic of the demultiplexing characteristic. Further, the transmission line LF3 connected to the ground and the capacitor CF4 are connected in series to the other notch circuit. The transmission line LF3 and the capacitor CF4 are connected for the purpose of improving the high-pass filter characteristic of the demultiplexing characteristic.
As the branching circuit, for example, a bandpass circuit, a lowpass circuit, a highpass circuit, or the like other than the notch circuit may be used, and these may be combined as appropriate.
Next, the first switch circuit will be described. The first switch circuit is a switch circuit on the upper side of FIG. 3 and switches between EGSM900 transmission TX and reception RX. The switch circuit SW includes two diodes DG1 and DG2 and two transmission lines LG1 and LG2. The diode DG1 has an anode connected to the antenna terminal ANT side, a cathode connected to the transmission TX side, and a cathode side thereof. A transmission line LG1 connected to the ground is connected. A transmission line LG2 is connected between the antenna side and the reception RX, a diode DG2 having a cathode connected to the reception side is connected, and a capacitor CG6 is connected between the anode of the diode DG2 and the ground, In the meantime, the inductor LG is connected to the control circuit VC1.
The low-pass filter circuit inserted on the transmission TX circuit side includes a transmission line LG3 and capacitors CG3, CG4, and CG7, and is inserted between the diode DG1 of the switch circuit SW and the transmission line LG1.
Next, the second switch circuit will be described. The second switch circuit is a switch circuit on the lower side of FIG. 3 and switches between GSM1800 transmission TX and reception RX. The switch circuit SW includes two diodes DP1 and DP2 and two transmission lines LP1 and LP2. The diode DP1 has an anode connected to the antenna terminal ANT side, a cathode connected to the transmission TX side, and a cathode side thereof. A transmission line LP1 connected to the ground is connected. A transmission line LP2 is connected between the antenna side and the reception RX, a diode DP2 having a cathode connected to the reception RX side is connected, and a capacitor CP6 is connected between the anode of the diode DP2 and the ground. In the meantime, an inductor is connected to the control circuit VC2.
The operation of the control circuit will be described. In order to validate the transmission of the EGSM900 system, a predetermined voltage is applied to the voltage terminal VC1. Similarly, when a predetermined voltage is applied to the voltage terminal VC2, GSM1800 transmission becomes effective. At the time of reception, no voltage is applied to either voltage terminal VC1, VC2.
The low-pass filter circuit inserted on the transmission TX circuit side includes a transmission line LP3 and capacitors CP3, CP4, and CP7, and is inserted between the diode DP1 of the switch circuit SW and the transmission line LP1.
[0009]
In the embodiment shown in FIG. 3, a band-pass filter using surface acoustic wave elements (SAW) indicated by SG and SP is provided between the transmission lines LG2 and LP2 and the reception RX (RX / EGSM900, RX / GSM1800). Connected. By using the SAW filter, it is possible to reduce the size, and the filter is electrically high in Q (sharpness of the resonance circuit), and has an effect of being small and improving the selectivity of the received signal.
In FIG. 3, the function of the capacitor CGP is to reduce the impedance between the connection point N1 of the transmission lines LG1 and LP1 and the ground in a high frequency manner.
The function of the resistor R in FIG. 3 is to control the value of current flowing through the diode. In this embodiment, since it is configured to be common to the control circuits VC1 and VC2 of the EGSM900 system and the GSM1800 system, the number of parts can be reduced.
In FIG. 3, a DC (direct current) cut capacitor is not required between the transmission line and the SAW filter. This is because the SAW filter can block DC (direct current) due to its structure.
The present invention has been described with respect to the single-band and dual-band high-frequency switch modules. However, the present invention can be applied to a multimode of triple band or higher.
[0010]
FIG. 4 is a perspective view of a high-frequency switch module using a band-pass filter using surface acoustic wave elements (SAW) indicated by SG and SP. In FIG. 4, the circuit is configured with only through holes without using the side electrodes, and the electrodes are concentrated on the bottom of the high-frequency switch module.
Except for the SAW filter (SG, SP), PIN diode (DG1, DG2, DP1, DP2), capacitor (CG1, CGP), and resistor R, all were formed as a printed circuit in the multilayer ML. The outline of the arrangement is that two SAW filters SP and SG are arranged in front of FIG. 4, a duplexer is arranged on the left side of FIG. 4, and a switch circuit is provided below the dielectric layer on which a ground pattern is formed. And a low-pass filter, and a dielectric layer on which a ground pattern is formed are sandwiched, a dielectric layer on which a capacitor pattern is printed, and a ground pattern at the bottom. With the sandwich structure, an electric field when a signal propagates through a circuit does not leak to the outside, no interference occurs, and isolation is improved, and electrical characteristics are improved.
In the mounting shown in FIG. 4, since the SAW filters (SG, SP) are arranged by providing steps in the stacked bodies ML1 and ML2, it is possible to reduce the height and further reduce the size. The stacked bodies ML1 and ML2 have an integral structure.
[0011]
In the present invention, as shown in FIG. 4, the high-frequency switch module can be configured in a small size by arranging a chip structure on the laminated structure and the laminated body.
An antenna terminal ANT, which is a common terminal for a plurality of transmission / reception systems, a transmission system terminal TX for each transmission / reception system, and a reception system terminal RX are terminals for high-frequency signals, which are called high-frequency terminals. The high frequency terminals are formed on the back surface of the laminate as illustrated in FIG. 5 and are arranged so that the high frequency terminals are not adjacent to each other. The symbol of each high frequency terminal corresponds to the equivalent circuit of FIG. There is an antenna terminal ANT as a common terminal of the EGSM900 and GSM1800. This is an input / output terminal for an externally connected antenna. In this embodiment, an example in which the antenna is externally mounted has been shown. However, as the multi-functionalization progresses and modularization proceeds in the future, a planar antenna may be combined with the laminate. The present invention can also be applied to this case.
In FIG. 5, for TX and RX, the former is a transmission terminal and the latter is a reception terminal in both EGSM900 and GSM1800. VC1 and VC2 are control terminals that switch the switch circuit from the external power source through the control circuit and control the switching of transmission / reception.
Between the high-frequency terminals, a ground terminal GND or a switch circuit control terminal (VC1, VC2) is disposed. Further, it is preferable that at least one ground terminal GND is disposed between the high frequency terminals. In this way, by preventing the high frequency terminals from being adjacent to each other and arranging the ground terminals sandwiched between the high frequency terminals, interference between the high frequency terminals can be suppressed and loss can be reduced.
[0012]
The transmission system terminal and the reception system terminal are preferably arranged close to each other so that the transmission system terminals and the reception system terminals are not adjacent to each other. Moreover, it is preferable to arrange | position a transmission type | system | group terminal and a receiving system terminal in a respectively separate area | region with respect to the centerline of a laminated body. Further, it is preferable that the transmission system terminal and the reception system terminal are arranged in line symmetry. With this configuration, in a device that handles a plurality of transmission / reception systems on which the high-frequency switch module is mounted, it is easy to connect to a transmission system circuit and a reception system circuit.
[0013]
The common terminal and the transmission terminal and the reception terminal of each transmission / reception system are preferably formed in different regions when the laminate is divided into two parts by a plane perpendicular to the mounting surface. Since this high-frequency switch module is arranged between the antenna and the transmission / reception circuit, this terminal arrangement allows the antenna and the high-frequency switch module, and the transmission / reception circuit and the high-frequency switch module to be connected with the shortest line, resulting in an extra loss. Can be prevented.
[0014]
In the present invention, it is preferable to dispose a metal case so as to surround the chip component disposed on the laminate. This is because not only the shielding effect but also the user of the high-frequency switch module can easily vacuum the metal case when soldering with a chip mounter. If the shielding effect is not required, and it is only for forming a flat surface for supplying a chip mounter, the high-frequency switch module is molded with a heat-resistant resin that can withstand the heat during reflow soldering, or a metal coating is applied on it. Also good.
This metal case can be fixed to the upper surface of the laminate by soldering. Moreover, the high frequency switch module of this invention can be mounted with a mounter apparatus by this metal case.
In addition, when a SAW (surface acoustic wave) filter is used as a reception band-pass filter, a commercially available SAW filter may be used, but a bare chip or flip chip SAW filter may be used. If the whole is packaged, the size and performance can be improved.
[0015]
The internal structure of this laminate will be described. 6 and 7 show print pattern diagrams of the respective layers. In this example, electrodes of each layer are printed on a dielectric sheet having a thickness of 50 μm (size after integral firing) and connected by through holes. 6 and 7, the through hole is a land marked with a cross. A through hole is formed by opening a hole in the x portion.
Examples of the dielectric include alumina-based glass ceramic low-temperature sintered material.
FIG. 6 shows the layers from the uppermost layer (1) to the seventh layer (7) every 50 μm, and FIG. 7 shows the lower layers, the eighth layer (8) to the seventeenth layer. Up to layer (17) is shown. Symbols such as DG1, CG1, and DG2 attached to the pattern correspond to the equivalent circuit of FIG.
[0016]
For this laminate, a green sheet made of a ceramic dielectric material that can be fired at a low temperature is prepared, and a conductive paste such as Ag, Pd, or Cu is printed on the green sheet to form a desired electrode pattern. Are appropriately laminated and integrally fired. Hereinafter, the structure of each layer after baking is demonstrated in an order from the lowest layer. The sheet thickness is generally in the range of 80 to 250 μm, and is controlled by the doctor blade method or the like depending on the intended use. After laminating large sheets on which a large number of predetermined internal electrode patterns are formed and cutting them into individual chip sizes, firing and terminal electrode formation are performed to produce a dielectric multilayer body. The terminal electrode usually has a three-layer structure of Ag—Ni—solder, and the solder resistance of the solder is obtained by the Ni layer and the solder wettability is sufficiently obtained by the solder layer. Solder printing using a metal mask is performed on this dielectric multilayer body, and then a PIN diode, a chip capacitor with a large capacitance value that could not be formed in the multilayer body, and in some cases a surface acoustic wave filter, etc. Reflow solder.
First, on the seventeenth layer (FIG. 7 (17)), which is the lowermost layer, the ground electrode GND is formed on almost the entire surface (the GND electrode is filled with a pattern for easy understanding). It is so-called solid earth. As a result, a stable ground can be secured. In particular, in this embodiment, a plurality of through-holes (in the case of FIG. 7 (17), six left and right through-holes) communicate with the back surface, and can be used for connection to an external circuit as a wide and narrow GND shown in FIG. A stable grounding effect can be obtained. In one embodiment shown in FIG. 7 (17), six through holes are formed on each of the left and right sides and electrically connected to the ground electrode GND at the bottom of the wide rectangular laminate shown in FIG.
Capacitor electrodes (CG6, CGL, CP6, CPL) are formed on the sixteenth layer (FIG. 7 (16)). These capacitors are used in a control circuit that controls the opening and closing of the diode of the switch circuit.
In the 15th layer (FIG. 7 (15)), a GND electrode is formed on almost the entire surface.
The GSM1800 system is arranged on the front side and the EGSM900 system is arranged on the opposite side, with the dot-and-dash line of the 14th layer (FIG. 7 (14)) as a boundary. As a result, the connection can be shortened and the electrical characteristics can be improved.
From the 14th layer (FIG. 7 (14)) to the 10th layer (FIG. 7 (10)), the inductances LG and LP of the control circuit were coiled in the right half of the layer over multiple layers. On the left half of the 14th layer (FIG. 7 (14)), capacitor patterns (CG3, CG4, CP3, CP4) of low-pass filters are arranged.
In the 13th layer (FIG. 7 (13)), a part of the above-described inductance LG, LP pattern is arranged on the right half, and capacitors CG7, CP7 of low-pass filters are arranged on the left half.
In the twelfth layer (FIG. 7 (12)), a part of the above-described inductance LG, LP pattern is arranged on the right half, and transmission lines LG1, LG2, LP2, LP3 of the switch circuit are arranged on the left side. Since the switch circuit and the low-pass filter are arranged on the same plane, the matching between them is further improved.
In the eleventh layer (FIG. 7 (11)), a part of the above-mentioned inductance LG, LP pattern is shown on the right half, and a part of the above-mentioned switch circuit transmission line, LG1, LG2, LP2, LP3 is shown on the left side. Similarly, the transmission lines LG1 and LP1 of the switch circuit are arranged.
In the tenth layer (FIG. 7 (10)), a part of the above-mentioned inductance LG, LP pattern is shown on the right half, and a part of the above-mentioned switch circuit transmission line, LG1, LG2, LP2, LP3 is shown on the left side. Similarly, a part of the pattern of the transmission lines LG1 and LP1 of the switch circuit is arranged.
In the ninth layer (FIG. 7 (9)), a part of the pattern of the transmission lines LG2 and LG3 of the EGSM900 series switch circuit is arranged.
In the eighth layer (FIG. 7 (8)), patterns for SAW filters SG and SP, which are reception low-pass filters, are arranged on the right side from the vertical line shown in the center. A demultiplexer circuit pattern is arranged on the left side of the vertical line shown in the center.
[0017]
Each layer shown in FIG. 6 has a shape lacking the right side, unlike each layer shown in FIG. The broken lines in FIG. 6 indicate portions corresponding to the respective layers in FIG. With such a combination of shapes, stepped laminates ML1 and ML2 as shown in FIG. 4 were obtained, and a compact high-frequency switch module having SAW filters SG and SP mounted on the stepped portions was obtained. The laminated body ML1 corresponds to FIG. 6, and the laminated body ML2 corresponds to FIG.
An example of a method for forming this step will be described. First, each electrode pattern shown in FIGS. 6 and 7 is printed on a green sheet having the same dimensions. In the case of the pattern of FIG. 6, only the left part is printed, and there is no print pattern on the right part. Next, each green sheet is laminated, and after laminating from the 17th layer (FIG. 7 (17)) and the 8th layer (FIG. 7 (8)), the thickness of the green sheet is reduced to about 80 μm. A PET (polyethylene terephthalate) sheet or the like (referred to as a release sheet) that is sufficiently thin (about 20 μm) and peelable from the green sheet is inserted into the portion indicated by the broken line in FIG. )) To the first layer (FIG. 6 (1)) to complete the laminate. After that, when a cut is made from the vertical line portion of FIG. 6 to the top of the release sheet with a carbide blade, and the green sheet laminate on the release sheet is removed, the stepped portion shown in FIG. 4 can be easily formed.
Hereinafter, the arrangement of each layer corresponding to the stacked body ML1 will be described with reference to FIG.
Patterns of capacitors CF1, CF2 and CF4 of the demultiplexing circuit are printed on the seventh layer and the sixth layer (FIGS. 6 (7) and (6)).
In the fifth layer and the fourth layer (FIGS. 6 (5) and (4)), transmission lines LF1 to LF3 constituting filters of the branching circuit are arranged. In the third layer (FIG. 6 (3)), transmission lines LF1 and LF2 constituting the filter of the branching circuit are arranged. As a result, it can be arranged farthest from the ground pattern GND (FIGS. 7 (15) and (17)), and since the distance between the two is maximized, the inductance can be made sufficiently large.
The first layer was provided with patterns of diodes DG1, DG2, DP1, DP2, capacitors CG1, CGP, and resistor R, which are parts to be mounted on the multilayer body ML1. The second layer (FIG. 6 (2)) shows a pattern for connecting these mounted components to other patterns in the laminate.
[0018]
In the above, one embodiment of the high-frequency switch module in which a SAW filter is used as a band-pass filter for a receiving system and a step is provided in the laminated body to reduce the size has been shown. However, the present invention is not limited to the laminated body provided with a step. Alternatively, a SAW filter may be mounted by providing a cavity (concave portion) in the laminate.
[0019]
As described above, according to the present invention, not only a single band but also a dual band or more multi-band mobile phone, one duplexer that separates and synthesizes each signal, an antenna switch that switches a transmission signal and a reception signal, and high frequency rejection One ultra-low-pass filter is built in, and a minimum element is built in a dielectric laminate, and a PIN diode is mounted on the element.
[0020]
【The invention's effect】
According to the present invention, it is possible to provide a high-frequency switch module that can cope with ultra-miniaturization having a stable ground. According to the present invention, this high-frequency switch module can be configured in a small size and on a single chip, preferably by using a laminated structure. This is effective for miniaturization of devices in dual band mobile phones and the like.
[Brief description of the drawings]
FIG. 1 is an equivalent circuit diagram of an embodiment according to the present invention.
FIG. 2 is a perspective view of an embodiment according to the present invention.
FIG. 3 is an equivalent circuit diagram of another embodiment according to the present invention.
FIG. 4 is a perspective view of another embodiment according to the present invention.
FIG. 5 is a diagram showing an electrode arrangement on the bottom surface of the high-frequency switch module according to the present invention.
6 is a diagram showing a pattern of each layer of the laminated body of the equivalent circuit shown in FIG. 3. FIG.
FIG. 7 is a diagram showing the continuation of FIG. 6 with the pattern of each layer of the laminate.
FIG. 8 is a perspective view of a conventional high-frequency switch module.
[Explanation of symbols]
LG1, LP1 transmission line
LF2, LF3 transmission line
LP2, LP3 transmission line
TX transmission system terminal
RX receiver terminal
ANT antenna terminal
SG, SP Surface acoustic wave filter

Claims (8)

A switch element mounted on a laminate, and an electrode pattern formed on a dielectric layer of the laminate, a high frequency switch module comprising a switch circuit and a low-pass filter circuit ,
External connection terminals are formed on the bottom surface of the laminate, but not on the side surfaces.
While connecting the electrode patterns between the dielectric layers, and connecting the electrode patterns and external connection terminals all through holes,
A ground electrode is formed on the dielectric layer on the bottom surface side of the multilayer body, and a plurality of through holes are extended from the ground electrode to the bottom surface of the multilayer body to be connected to a plurality of ground terminals of the external connection terminals. ,
The dielectric layer in the edge region of the ground electrode is formed with a through hole connected to a high frequency terminal of the external connection terminals and a switch circuit control terminal . A demultiplexing circuit for demultiplexing a plurality of transmission / reception signals is provided, and the electrode pattern constituting the demultiplexing circuit and the high-frequency terminal are connected via a plurality of through-holes continuous in the stacking direction of the dielectric layers. The high-frequency switch module according to claim 1. Only the ground terminals formed in a larger area than the other external connection terminals are formed on opposite side surfaces of the laminate, and the large-area ground terminal and the ground electrode are connected by a plurality of through holes. The high-frequency switch module according to claim 1 or 2 , wherein The high frequency switch module according to claim 3 , wherein a high frequency terminal, a switch circuit control terminal, and a ground terminal are formed on the other side surface of the laminate . Another ground electrode is arranged on the upper side of the ground electrode, and the other ground electrode has a cutout part in which no electrode is formed, and the electrode pattern arranged between the ground electrodes in the cutout part The high-frequency switch module according to claim 1, wherein a through-hole connected to is formed . 6. The high frequency switch module according to claim 1, wherein a ground terminal or a switch circuit control terminal is disposed next to the high frequency terminal among the external connection terminals . 7. The high frequency switch module according to claim 1, wherein a diode or a transistor is used as the switch element . 8. The SAW filter according to claim 1, wherein a SAW filter is disposed in the laminate, and the SAW filter is connected to the external connection terminal through a plurality of through holes that are continuous in the lamination direction of the dielectric layers. The high frequency switch module according to any one of the above.

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