JPH0774607A - Antenna switch shaped device - Google Patents

Abstract

PURPOSE:To provide a compact antenna switch shared device which has high performance against the antenna switching diversity. CONSTITUTION:An LPF 145 and a 1st switch device 147 are electrically connected between a transmission antenna 101 and a 1st antenna terminal 102. Then, a 2nd switch device 148 and a 3rd switch device 149 are electrically connected between the terminal 102 and a 2nd antenna terminal 103 so that the device 148 is set at the side of the terminal 102. Then a BPF 146 is electrically connected between a reception terminal 104 and the connection point between both devices 148 and 149.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna switch duplexer mainly used in the field of communication devices such as digital mobile phones.

[0002]

2. Description of the Related Art In recent years, with the spread of digital mobile communication devices, antenna switch duplexers are becoming more important. Along with this, not only small size and high performance but also multi-functionalization such as compatibility with antenna switching diversity reception system is required.

An example of the above-described conventional antenna switch duplexer will be described below with reference to the drawings.

FIG. 5 shows the structure of a conventional antenna switch duplexer. In FIG. 5, 401 is a transmission terminal, 402 is an antenna terminal, 403 reception terminal, 404 is a control terminal, 405 and 406 are PIN diodes, 407.
Is a strip line having a quarter wavelength at the transmission frequency, 408 is a resistor, 409 is an inductor, and 410, 41.
Reference numerals 1, 412 and 413 are capacitors. Here, the resistor 408, the inductance 409, and the capacitor 411 form a control circuit, and the capacitor 411 is the inductor 409.
Is grounded at one end in high frequency. Also, the capacitor 4
10, 412 and 413 have a function of blocking direct current.

The operation of the antenna switch duplexer configured as described above will be described below.

First, at the time of transmission, a positive voltage is applied to the control terminal 404. Control current is control terminal 404, resistor 40
8, inductor 409, PIN diode 405, strip line 407, and PIN diode 406 flow in the order described. Accordingly, PIN diode 405 and P
A low impedance state is established between the anode and the cathode of the IN diode 406. Since the impedance between the anode and the cathode of the PIN diode 406 becomes low, one end of the strip line 407 connected to the anode of the PIN diode 406 is connected to the ground potential point, so that it is viewed from the transmission terminal 401 side. The impedance at the other end of the strip line 407 becomes extremely high. As a result, the transmission signal input from the transmission terminal 401 is output from the antenna terminal 402 and is not output to the reception terminal 403.

No voltage is applied to the control terminal 404 during reception. Therefore, the control current does not flow, and the PIN diode 405 and the PIN diode 406 are in a high impedance state between the anode and the cathode. As a result, the reception signal input from the antenna terminal 402 is received by the reception terminal 40.
3 and not to the transmission terminal 401.

As described above, the conventional antenna switch duplexer can switch between the two connection modes of connecting the antenna terminal and the transmitting terminal or connecting the antenna terminal and the receiving terminal.

[0009]

However, in the above configuration, in order to realize the antenna switching diversity reception system, it is necessary to use a plurality of antenna switch duplexers in combination, and the circuit configuration becomes complicated. Had.

In view of the above problems, it is an object of the present invention to provide an antenna switch duplexer that can realize antenna switching diversity and is small in size and high in performance.

[0011]

In order to solve the above problems, an antenna switch duplexer according to the present invention has a first switch device electrically connected between a transmission terminal and a first antenna terminal, A second switch device is electrically connected between the first antenna terminal and the receiving terminal, and a third switch device is electrically connected between the receiving terminal and the second antenna terminal. is there.

[0012]

With the above-described structure, the present invention provides a compact and high-performance antenna switch duplexer that can realize antenna switching diversity.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An antenna switch duplexer according to an embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 shows a circuit configuration of an antenna switch duplexer according to the first embodiment of the present invention.
[FIG. 3] is an external view of a substrate of the antenna switch duplexer according to the first embodiment of the present invention. 1 and 2, 101 is a transmission terminal, 102 is a first antenna terminal,
103 is a second antenna terminal, 104 is a receiving terminal, 10
5 is the first control terminal, 106 is the second control terminal, 10
8, 109 and 110 are PIN diodes, 114 and 11
5 is a short-circuited dielectric coaxial resonator, 116, 117, 11
8, 119, 120, 121, 122, 123, 124
Is an inductor, 126 and 127 are resistors, 129 and 13
0, 131, 132, 133, 134, 135, 13
6, 137, 138, 139, 140, 141, 14
2, 143 and 144 are capacitors, 150, 151 and 1
52, 153, 154, 155 are ground terminals, and 156 is a ground electrode pattern.

Inductors 116 and 117, capacitor 1
Reference numerals 29, 130, and 131 configure a low-pass filter 145 that allows signals having frequencies in and below the transmission frequency band to pass therethrough and has high impedance with respect to harmonics of the transmission signal. In addition, the tip short-circuited dielectric coaxial resonator 11
4, 115, inductor 124, capacitor 142, 1
Reference numerals 43 and 144 constitute a bandpass filter 146 having a passband within the reception frequency band and having high impedance for other frequencies. The PIN diode 108, the inductor 119, and the capacitor 134 form a first switch device 147. PIN diode 109, inductors 120, 121, capacitors 136, 137, 14
1 constitutes the second switch device 148. In the second switch device 148, when the PIN diode 109 is applied with a voltage in the forward direction to bring the anode-cathode into a low impedance state and the junction point between the inductor 120 and the inductor 121 is connected to substantially the ground potential point, The inductor 120 and the capacitor 136 and the inductor 121 and the capacitor 141 resonate in parallel, and the impedance between the input and output terminals becomes extremely high. PIN diode 1
The inductor 10, the inductor 122, and the capacitor 140 form a third switch device 149.

The circuit composed of the inductor 118, the resistor 126 and the capacitors 132 and 133 also serves as the input matching circuit and the control circuit of the first switch device 147, and the inductor 123, the resistor 127 and the capacitors 138 and 139. The circuit configured by also serves as the input matching circuit and the control circuit of the third switch device 149.

By appropriately selecting the capacitance value of the capacitor 137, when receiving from the first antenna terminal 102, the capacitor 137 contributes to the improvement of impedance matching in the first antenna terminal 102 and the receiving terminal 104.

By using the capacitor 142 as the input coupling element of the bandpass filter 146, the DC blocking capacitor required at the connection between the bandpass filter 146 and the third switch device 149 is not necessary.

As shown in FIG. 2, the transmission terminal 10
1 and the receiving terminal 104, by mounting the ground electrode pattern 156 connected to the ground terminal 155 and the tip short-circuited dielectric coaxial resonators 114 and 115, the low-pass filter 145 and the band-pass filter 146 are electromagnetically coupled. It is possible to prevent deterioration of the isolation between the transmission terminal 101 and the reception terminal 104 due to.

The operation of the antenna switch duplexer configured as described above will be described below with reference to FIGS. 1 and 2.

At the time of transmission, a positive voltage is applied to the first control terminal 105 and no voltage is applied to the second control terminal 106. The control current is the first control terminal 105, the resistor 126,
The inductor 118, the first switch device 147, the inductor 120, and the PIN diode 109 flow in the order described. Along with this, a low impedance state is established between the input / output terminals of the first switch device 147 and between the anode and cathode of the PIN diode 109. PIN diode 1
The low impedance state between the anode and the cathode of 09 causes the inductor 120 and the inductor 121 to
Is connected to the ground potential point, the inductor 120 and the capacitor 136, the inductor 121 and the capacitor 141 resonate in parallel, and the second switch device 14
The impedance between the eight input / output terminals becomes extremely high.
As a result, the transmission signal input from the transmission terminal 101 is output from the first antenna terminal 102 and is not output to the other terminals.

The antenna switch duplexer of the present invention has two reception modes. That is, there are a mode in which reception is performed from the first antenna terminal and a mode in which reception is performed from the second antenna terminal.

First, the operation in the mode of receiving from the first antenna terminal 102 will be described. When receiving from the first antenna terminal 102, the first control terminal 10
No voltage is applied to both 5 and the second control terminal 106.
Therefore, the control current does not flow, and the first switch device 147
Between the input and output terminals of the third switch device 149 and between the anode and cathode of the PIN diode 109 are in a high impedance state. As a result, the reception signal input from the first antenna terminal 102 is output from the reception terminal 104 and is not output to the other terminals.

Next, the operation in the mode of receiving from the second antenna terminal 103 will be described. When receiving from the second antenna terminal 103, the first control terminal 1
No voltage is applied to 05. A positive voltage is applied to the second control terminal 106. The control current is the second control terminal 10
6, resistor 127, inductor 123, third switch device 149, inductor 121, PIN diode 109
Flow in the order listed. Along with that, a high impedance state is established between the input and output terminals of the first switch device 147,
A low impedance state is established between the input / output terminals of the third switch device 149 and between the anode and cathode of the PIN diode 109. Anode of PIN diode 109-
Due to the low impedance state between the cathodes,
Since the junction point between the inductor 120 and the inductor 121 is coupled to the ground potential point, the inductor 120 and the capacitor 136, the inductor 121 and the capacitor 141 resonate in parallel, and the impedance between the input and output terminals of the second switch device 148 is extremely high. Get higher As a result, the reception signal input from the second antenna terminal 103 is output from the reception terminal 104 and is not output to the other terminals.

As described above, with the antenna switch duplexer according to the first embodiment of the present invention, the antenna switch of the antenna switching diversity system has a smaller number of parts than in the case where two conventional antenna switch duplexers are used. A shared device can be realized.

FIG. 3 shows a circuit configuration of an antenna switch duplexer according to the second embodiment of the present invention. Figure 3
, 201 is a transmission terminal, 202 is a first antenna terminal, 203 is a second antenna terminal, 204 is a reception terminal, 205 is a first control terminal, 206 is a second control terminal, and 208, 209 and 210 are PIN diode, 21
4, 215 are short-circuited dielectric coaxial resonators 216, 21
7, 218, 219, 220, 221, 222, 22
3, 224 are inductors, 226, 227 are resistors, 22
9, 230, 231, 232, 233, 234, 23
5, 236, 237, 238, 239, 240, 24
Reference numerals 1 and 242 are capacitors.

Inductors 216 and 217, capacitor 2
Reference numerals 29, 230, and 231 configure a low-pass filter 245 that passes signals in the transmission frequency band and frequencies lower than the transmission frequency band and has high impedance with respect to harmonics of the transmission signal. In addition, the tip short-circuited dielectric coaxial resonator 21
4, 215, inductor 224, capacitors 240, 2
41 and 242 form a band pass filter 246 having a pass band within the reception frequency band and a high impedance for other frequencies. PIN diode 208,
The inductor 219 and the capacitor 234 form a first switch device 247. The PIN diode 209, the inductor 220, and the capacitor 236 form a second switch device 248. The second switch device 248 has two input / output terminals, and when a voltage is applied to the PIN diode 209 in the forward direction and the anode-cathode becomes a low impedance state, the inductor 220 and the capacitor 236 resonate in parallel and enter. The impedance between the output terminals becomes extremely high, and no voltage is applied to the PIN diode 20.
When the anode-cathode 9 has a high impedance state, the inductor 220 and the capacitor 236 do not resonate in parallel, and the impedance between the input and output terminals becomes low.
The PIN diode 210, the inductor 221, and the capacitor 239 form a third switch device 249.

The circuit composed of the inductor 218, the resistor 226, and the capacitors 232 and 233 also serves as the input matching circuit and the control circuit of the first switch device 247, and the inductor 222, the resistor 227, and the capacitors 237 and 238. The circuit configured by also serves as an input matching circuit and a control circuit of the third switch device 249.

By using the capacitor 240 as the input coupling element of the bandpass filter 246, the DC blocking capacitor required at the connecting portion between the bandpass filter 246 and the third switch device 249 is unnecessary.

The operation of the antenna switch duplexer configured as described above will be described below with reference to FIG.

During transmission, a positive voltage is applied to the first control terminal 205 and no voltage is applied to the second control terminal 206. The control current is the first control terminal 205, the resistor 22.
6, the inductor 218, the first switch device 247, the second switch device 248, and the inductor 223 flow in the order described. Accordingly, the input / output terminals of the first switch device 247 are in a low impedance state, and the input / output terminals of the second switch device 248 are in a high impedance state. As a result, the transmission signal input from the transmission terminal 201 is output from the first antenna terminal 202 and is not output to the other terminals.

The antenna switch duplexer of the present invention has two reception modes. That is, the first antenna terminal 20
2 and the second antenna terminal 203
This is a mode for more reception.

First, the operation in the mode of receiving from the first antenna terminal 202 will be described. When receiving from the first antenna terminal 202, the first control terminal 20
No voltage is applied to both 5 and the second control terminal 206.
Therefore, the control current does not flow, and the first switch device 247
Between the input / output terminals of the third switching device 249 and the input / output terminals of
A low impedance state is established between the input and output terminals of the switch device 248. As a result, the reception signal input from the first antenna terminal 202 is output from the reception terminal 204,
It is not output to other terminals.

Next, the operation in the mode of receiving from the second antenna terminal 203 will be described. When receiving from the second antenna terminal 203, the first control terminal 2
05, the positive voltage is applied to the second control terminal 206.
The control current flows through the first control terminal 205, the resistor 226, the inductor 218, the first switch device 247, the second switch device 248, and the inductor 223 in the order described, and also the second control terminal 206, the resistor 227, and the inductor. 222, third switch device 249, inductor 22
3 flows in the order described. Along with that, between the input / output terminals of the first switch device 247 and the third switch device 249.
Between the input and output terminals of the second switch device 248 becomes a low impedance state. As a result, the reception signal input from the second antenna terminal 203 is output from the reception terminal 204 and is not output to the other terminals.

As described above, the antenna switch duplexer according to the second embodiment of the present invention inserts between the first antenna terminal and the receiving terminal more than the case where the conventional antenna switch duplexer is used. It is possible to realize an antenna switch diversity type antenna switch duplexer with low loss.

FIG. 4 shows a circuit configuration of an antenna switch duplexer according to the third embodiment of the present invention. Figure 4
, 301 is a transmission terminal, 302 is a first antenna terminal, 303 is a second antenna terminal, 304 is a reception terminal, 305 is a first control terminal, 306 is a second control terminal, and 307 is a third control. Terminals 311 are PIN diodes, 312 and 313 are field effect transistors, 314,
315 is a short-circuited dielectric coaxial resonator 316, 317,
318, 319, 320, 321, 322 are inductors, 323, 324 are strip lines, 326, 32.
7, 328 are resistors, 329, 330, 331, 332,
333, 334, 335, 336, 337, 338, 3
39 and 340 are capacitors.

Here, the strip line 323 has a characteristic impedance of 50Ω and has a length of a quarter wavelength at the transmission frequency.

Here, the strip line 324 has a characteristic impedance of 50Ω and has a length of a quarter wavelength at the reception frequency.

Inductors 316 and 317, capacitor 3
Reference numerals 29, 330, and 331 configure a low-pass filter 345 that passes signals within and below the transmission frequency band and has high impedance with respect to harmonics of the transmission signal. In addition, the tip short-circuited dielectric coaxial resonator 31
4, 315, inductor 322, capacitors 338, 3
Reference numerals 39 and 340 constitute a band pass filter 346 having a pass band in the reception frequency band and high impedance with respect to other frequencies. The PIN diode 311, the inductor 319, and the capacitor 334 form a first switch device 347. The field effect transistor 312, the strip lines 323 and 324, the control terminal 306, the inductor 320, the resistor 327, and the capacitor 336 form a second switch device 348. Second switch device 34
No. 8 is a case where no voltage is applied to the control terminal 306, the drain-source of the field effect transistor 312 is in a low impedance state, and one end of the strip line 323 and one end of the strip line 324 are connected to substantially the ground potential point. In addition, the impedance between the input and output terminals becomes extremely high. The field effect transistor 313, the control terminal 307, the inductor 321, and the resistor 328 are the third switch device 34.
Make up 9.

The circuit formed by the inductor 318, the resistor 326, and the capacitors 332 and 333 also serves as the input matching circuit and the control circuit of the first switch device 347, and forms a part of the second switch device 348. The formed inductor 320 also serves as a part of the control circuit of the first switch device 347.

The second switch device 348 and the third switch device
By configuring the switching device 349 of (1) using field effect transistors, the power consumption during reception becomes almost zero.

The reason why the PIN diode is used in the first switching device 347 is that the distortion of the signal when passing a large signal is generally smaller than that of the field effect transistor.

By appropriately selecting the capacitance value of the capacitor 336, it contributes to the improvement of impedance matching at the first antenna terminal 302 and the receiving terminal 304 when receiving from the first antenna terminal 302.

By using the capacitor 338 as the input coupling element of the bandpass filter 346, the DC blocking capacitor required at the connection between the bandpass filter 346 and the third switch device 349 becomes unnecessary.

The operation of the antenna switch duplexer configured as described above will be described below with reference to FIG.

At the time of transmission, a positive voltage is applied to the first control terminal 305, a negative voltage below the pinch-off voltage is applied to the third control terminal 307, and no voltage is applied to the second control terminal 306. The control current is the first control terminal 305 and the resistor 32.
6, the inductor 318, the first switch device 347, the strip line 323, and the inductor 320 flow in the order described. By applying each of the control voltages, the input / output terminals of the first switch device 347 and the drain / source of the field effect transistor 312 are brought into a low impedance state, and the third switch device 349 is also provided.
The impedance between the input and output terminals of is high. The low impedance state between the drain and source of the field effect transistor 312 causes the strip line 323.
And one end of the strip line 324 are close to the ground potential, the impedance between the input and output terminals of the second switch device 348 becomes extremely high.

As a result, the transmission signal input from the transmission terminal 301 is output from the first antenna terminal 302 and is not output to the other terminals.

The antenna switch duplexer of the present invention has two reception modes. That is, there are a mode in which reception is performed from the first antenna terminal and a mode in which reception is performed from the second antenna terminal.

First, the operation in the mode of receiving from the first antenna terminal 302 will be described. When receiving from the first antenna terminal 302, the second control terminal 3
A negative voltage equal to or lower than the pinch-off voltage is applied to 06 and the third control terminal 307, and no voltage is applied to the first control terminal 305. By applying the control voltages, the high impedance state is maintained between the input / output terminals of the first switch device 347, the drain-source of the field effect transistor 312, and the input / output terminal of the third switch device 349. become. As a result, the reception signal input from the first antenna terminal 302 is output from the reception terminal 304 and is not output to the other terminals.

Next, the operation in the mode of receiving from the second antenna terminal 303 will be described. When receiving from the second antenna terminal 303, the first control terminal 3
05, the second control terminal 306, and the third control terminal 307 are not applied with voltage. Accordingly, the input / output terminals of the first switch device 347 are in a high impedance state, and the drain-source of the field effect transistor 312 and the input / output terminals of the third switch device 349 are in a low impedance state. Field effect transistor 3
The low impedance state between the drain and source of 12 causes one end of the strip line 323 and one end of the strip line 324 to be substantially close to the ground potential.
The impedance between the input and output terminals of the second switch device 348 becomes extremely high.

As a result, the reception signal input from the second antenna terminal 303 is output from the reception terminal 304 and is not output to the other terminals.

As described above, the antenna switch duplexer according to the third embodiment of the present invention can realize an antenna switch diversity type antenna switch duplexer that consumes almost no power during reception.

By using a low pass filter as the transmission filter and a band pass filter as the reception filter in the above embodiment, spurious emission and reception of unnecessary signals can be prevented.

By using a polar type band pass filter as the receiving filter in the above embodiment, the number of resonators used for the transmitting filter can be reduced as compared with the case of not using the polar type.

In the above embodiment, the first switch device 147 includes the inductor 119 and the capacitor 134.
Is connected in parallel with the diode 108. This is intended to increase the impedance between the input and output terminals of the first switch device 147 when the first switch device 147 is cut off. Therefore, even if the inductor 119 and the capacitor 134 are removed, the impedance between the input and output terminals is reduced, but the same function can be realized. The same applies to the first switch devices 247 and 347 and the third switch devices 149 and 249.

In the third switch device 349, one end of the inductor 321 is connected to the drain terminal of the field effect transistor 313, and the other end of the inductor 321 is connected to the source terminal. When the switch device 349 of the third switch is cut off, the third switch device 34
The purpose is to increase the impedance between the input and output terminals of No. 9, and even if the inductor 321 is removed, the impedance between the input and output terminals is reduced, but the same function can be realized.

[0057]

As described above, according to the present invention, it is possible to realize an antenna switch duplexer that is compatible with antenna switching diversity and is small in size and high in performance.

[Brief description of drawings]

FIG. 1 is a circuit diagram of an antenna switch duplexer according to a first embodiment of the present invention.

FIG. 2 is an external view of the board of the antenna switch duplexer according to the first embodiment of the present invention.

FIG. 3 is a circuit diagram of an antenna switch duplexer according to a second embodiment of the present invention.

FIG. 4 is a circuit diagram of an antenna switch duplexer according to a third embodiment of the present invention.

FIG. 5 is a circuit diagram of a conventional antenna switch duplexer.

[Explanation of symbols]

 101 Transmission Terminal 102 First Antenna Terminal 103 Second Antenna Terminal 104 Reception Terminal 105 First Control Terminal 106 Second Control Terminal 114, 115 Tip Short-Circuited Dielectric Coaxial Resonator 145 Low-Pass Filter 146 Band-Pass Filter 147 First switch device 148 Second switch device 149 Third switch device

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Toru Sakuragawa Toru Sakuragawa 1006 Kadoma, Kadoma City, Osaka Prefecture Matsushita Electric Industrial Co., Ltd. (72) Inventor Hideaki Nakakubo 55-12 Ozazumi, Tanabe-cho, Tsuji-gun, Kyoto Prefecture Issue Matsushita Nitto Electric Co., Ltd. (72) Inventor Toshiro Ota, Tanabe-cho, Tsuzuri-gun, Kyoto Prefecture No. 55-12 Ozumi Kohama, Matsushita Nitto Electric Co., Ltd. (72) Inventor Tsutomu Matsumura, Tanabe-machi, Kyoto Ozumi Kojihama 55-12 Matsushita Nitto Electric Co., Ltd.

Claims (13)

[Claims] 1. A transmission terminal, a reception terminal, a first antenna terminal, a second antenna terminal, a first switch device, a second switch device, and a third switch device, The first switch device is electrically connected between the transmission terminal and the first antenna terminal, and the second switch device is electrically connected between the first antenna terminal and the reception terminal. The antenna switch duplexer is characterized in that the third switch device is electrically connected between the reception terminal and the second antenna terminal. 2. A transmission terminal, a reception terminal, a first antenna terminal, a second antenna terminal, a transmission filter, a reception filter, a first switch device, a second switch device, and a second switch device. 3 switch device, electrically connecting the transmission filter and the first switch device between the transmission terminal and the first antenna terminal, the first antenna terminal and the second antenna The second switch device and the third switch device are electrically connected between terminals so that the second switch device is on the side of the first antenna terminal, and the second switch device and the third switch device are electrically connected to each other. An antenna switch duplexer, wherein the reception filter is electrically connected between a connection point of the third switch device and the reception terminal. 3. The antenna switch according to claim 1, wherein a switch device in which a PIN diode is connected in series between input and output terminals is used in the first switch device or the third switch device. Shared device. 4. A switch comprising a PIN diode, an inductor and a capacitor, wherein a circuit in which the inductor and the capacitor are connected in series and the PIN diode is connected in parallel is electrically connected between input and output terminals. The antenna switch duplexer according to claim 1 or 2, wherein the device is used for the first switch device or the third switch device. 5. A switch device in which a drain terminal and a source terminal of a field effect transistor are electrically connected between input and output terminals and a gate terminal is a control terminal, which is a first switch device, a second switch device, or a second switch device. The antenna switch duplexer according to claim 1 or 2, wherein the antenna switch duplexer is used in the switch device of item 3. 6. A drain terminal and a source terminal of a field effect transistor are electrically connected between input and output terminals, one end of an inductor is connected to the drain terminal of the field effect transistor, and the other end of the inductor is the source terminal. Switch device having a gate terminal as a control terminal
The antenna switch duplexer according to claim 1 or 2, wherein the antenna switch duplexer is used in the switch device, the second switch device, or the third switch device. 7. A first input / output terminal, a second input / output terminal, a first inductor, a second inductor, a first capacitor, a second capacitor, and a PIN diode. , The first input / output terminal is electrically connected to one end of the first inductor and the first capacitor, the other end of the first capacitor is grounded, and the other end of the first inductor is The PIN diode and one end of the second inductor are electrically connected, the other end of the PIN diode is grounded, and the other end of the second inductor and the second capacitor are connected to the second input / output terminal. 3. A switch device configured by electrically connecting one end of the second capacitor and grounding the other end of the second capacitor is used as the second switch device. Antenna switch duplexer. 8. A first input / output terminal, a second input / output terminal, a first quarter-wave transmission line, a second quarter-wave transmission line, and a PIN diode. , One end of the first quarter-wave transmission line is electrically connected to the first input / output terminal, and the PIN diode and the first quarter-wave transmission line are connected to the other end of the first quarter-wave transmission line. One end of the 1/4 wavelength transmission line of 2 is electrically connected, the other end of the PIN diode is grounded, and the second input / output terminal is connected to the second 4
The antenna switch duplexer according to claim 1 or 2, wherein a switch device configured by electrically connecting the other ends of the one-wavelength transmission lines is used as the second switch device. 9. A switch comprising a PIN diode, an inductor and a capacitor, wherein a circuit in which the inductor and the PIN diode are connected in series and the capacitor is connected in parallel is electrically connected between input and output terminals. The antenna switch duplexer according to claim 1 or 2, wherein the device is used as a second switch device. 10. The antenna switch according to claim 1, wherein a PIN diode is used for the first switch device, and a field effect transistor is used for the second switch device and the third switch device. Shared device. 11. A transmission filter is a low-pass filter,
The antenna switch duplexer according to claim 2, wherein the reception filter is a bandpass filter. 12. A polarized band pass filter comprising a resonator formed of a dielectric ceramic, and a coupling circuit formed of at least one inductor and at least one capacitor. The antenna switch duplexer according to claim 2, wherein the antenna switch duplexer is provided. 13. A reception filter comprising a dielectric ceramic and a coupling circuit, a transmission filter, and a switch device, wherein the dielectric ceramic is arranged and mounted on a line connecting the transmission filter and the coupling circuit. An antenna switch duplexer characterized by the above.