JP2005086248A - Rf front end circuit - Google Patents

Abstract

An object of the present invention is to support a broadband wireless communication system without greatly changing the circuit scale.
A receiving connection switch provided between an antenna terminal and a receiving terminal, a receiving terminal grounding switch provided between the receiving terminal and the ground terminal, and an antenna terminal. The transmission connection switch 30 provided between the transmission terminal 3 and the transmission terminal 3 and the transmission terminal ground switch 33 provided between the transmission terminal 3 and the ground terminal 15. A band pass filter 26a having one pass band, switching transistors 25a and 27a for switching the band pass filter 26a, and a second pass band different from the first pass band and connected in parallel with the band pass filter 26a. And the switching transistors 25b and 27b for switching the band pass filter 26b.
[Selection] Figure 1

Description

  The present invention relates to an RF front-end circuit that is used in a mobile radio terminal and switches a transmission / reception circuit, and more particularly to an RF front-end circuit that supports a wideband or multiband system.

An example of a conventional RF front-end circuit is shown in Non-Patent Document 1.
K. Numata et al., "A + 2.4 / 0 V Controlled High Power GaAs SPDT Antenna Switch IC for GSM Application", 2002, Proceedings of 2002 IEEE Radio Frequency Integrated Circuites Symposium, pp.141-4 KMLakin et al., "Filter Banks Implemented With Integrated Thin Film Resonators", 2000, IEEE Ultrasonics Symposium, paper 3H-1, October 24, 2000

  However, when the RF front-end circuit based on Non-Patent Document 1 described above is used, for a wireless communication system having a wide bandwidth or a wireless communication system using a plurality of bands, a pass band of an RF filter or a power amplifier In order to cope with the shortage of width, a plurality of RF filters and power amplifiers are arranged in parallel, such as a filter bank used when applying a plurality of filters shown in Non-Patent Document 2, for example. There is a need. However, even if RF filters and power amplifiers are simply arranged in parallel, the circuit scale, price, and insertion loss increase.

  For example, in the 5 GHz band wireless LAN system (IEEE802.11a standard), which has been rapidly increasing recently, the maximum is 4.9-5.25 GHz for Japanese specifications, 5.15-5.35 GHz for US specifications, and 5.725-5.825 GHz, European specifications 5.15-5.35 GHz and 5.47-5.825 GHz. If one unit covers all these frequency bands, the specific bandwidth becomes 17% or more at 4.9 to 5.825 GHz, and any filter or power amplifier cannot handle it alone.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an RF front-end circuit that can be used in a broadband wireless communication system without greatly changing the circuit scale.

  According to an aspect of the present invention, in an RF front end circuit that performs switching of an output of a reception signal from an antenna terminal to a reception terminal and an output of a transmission signal from a transmission terminal to the antenna terminal, the antenna terminal A receiving connection switch provided between the receiving terminal, a receiving terminal grounding switch provided between the receiving terminal and the first ground terminal, and between the antenna terminal and the transmitting terminal. A transmission connection switch provided; and a transmission terminal grounding switch provided between the transmission terminal and the second grounding terminal, and one of the reception connection switch and the transmission connection switch. One is a first transmission line having a first pass band, a first switching transistor for switching the first transmission line, and a second different from the first pass band. An RF front end circuit comprising: a second transmission line having an overband and connected in parallel with the first transmission line; and a second switching transistor for switching the second transmission line. Provided.

  Further, the present invention is also established as a transmission / reception switching method using this RF front end circuit.

  As described above, according to the present invention, the present invention can be used for a broadband wireless communication system without significantly changing the circuit scale.

  Embodiments of the present invention will be described below.

(First embodiment)
FIG. 1 is a circuit diagram showing an example of an RF front end circuit 1 according to the first embodiment of the present invention. The RF front end circuit 1 includes an antenna terminal 4, a reception terminal 2, and a transmission terminal 3. A reception signal received from a transmission / reception antenna (not shown) via the antenna terminal 4 is received downstream from the reception terminal 2. While outputting to a side circuit (not shown), the transmission signal input via the transmission terminal 3 from the upstream transmission side circuit (not shown) is output to a transmission / reception antenna via the antenna terminal 4. The RF front end circuit 1 has a switching function of the reception signal and the transmission signal.

  A reception connection switch 20 is connected between the antenna terminal 4 and the reception terminal 2. A receiving terminal grounding switch 23 and a capacitor 24 are connected in series between the receiving terminal 2 and the ground terminal 11.

  The reception connection switch 20 includes a switching transistor group 21, a first parallel reception transmission path 22a connected in series to the switching transistor group 21, and a second parallel connection connected in parallel to the first parallel reception transmission path 22a. It consists of a reception transmission path 22b. The switching transistor group 21 includes two switching transistors. In the following description, unless otherwise indicated, the switching transistor is composed of a transistor and a resistor connected to the gate of the transistor, and by controlling the voltage applied to the gate, the current flowing through the source and drain of the transistor is controlled on and off. Switch. Moreover, in order to ensure the withstand voltage with respect to a power amplifier output, the several switching transistor connected in series is used, and this is the same also in the other switch shown by the following embodiment. Individual switching transistors include various transistors such as HBT (Heterojunction Bipolar Transistor), HEMT (High Electron Mobility Transistor), MES-FET (Metal Semiconductor-Field Effect Transistor), and MOS-FET (Metal Oxide Semiconductor-Field Effect Transistor). Can be used.

  Each gate of the switching transistor group 21 is connected to the control terminal 13 through a resistor, and the switching of the switching transistor group 21 is controlled by the control terminal 13.

  The first parallel reception transmission line 22a connects the reception terminal 2 and the antenna terminal 4 via the switching transistor group 21, and the switching transistor 25a, the RF filter 26a, and the switching transistor 27a are connected in series. . The RF filter 26a is disposed between the switching transistors 25a and 27a. The gates of the switching transistors 25a and 27a are connected to the control terminal 14 through a resistor. The control terminal 14 controls switching of the switching transistors 25a and 27a.

  The second parallel reception transmission line 22b connects the reception terminal 2 and the antenna terminal 4 via the switching transistor group 21 and is connected in parallel to the first parallel reception transmission line 22a. The switching transistor 25b The RF filter 26b and the switching transistor 27b are connected in series. The RF filter 26b is disposed between the switching transistors 25b and 27b. Since the center frequency is different from that of the RF filter 26a, a signal in a frequency band different from that of the RF filter 26a can be passed. The gates of the switching transistors 25b and 27b are connected to the control terminal 12 through resistors. The control terminal 12 controls switching of the switching transistors 25b and 27b.

  The reception terminal grounding switch 23 includes four switching transistors, and performs switching of a transmission line connecting the ground terminal 11 and the reception terminal 2. The gate of each switching transistor of the receiving terminal grounding switch 23 is connected to the control terminal 17 through a resistor. The control terminal 17 controls the switching of the receiving terminal grounding switch 23.

  A transmission connection switch 30 is connected between the antenna terminal 4 and the transmission terminal 3. A transmission terminal grounding switch 33 and a capacitor 34 are connected in series between the transmission terminal 3 and the ground terminal 15.

  The transmission connection switch 30 includes a switching transistor group 31, a first parallel transmission transmission line 32a connected in series to the switching transistor group 31, and a second parallel connection connected in parallel to the first parallel transmission transmission line 32a. The transmission transmission path 32b. The switching transistor group 31 includes two switching transistors, each gate of which is connected to the control terminal 17 via a resistor. This control terminal 17 controls the switching of the switching transistor group 31.

  The first parallel transmission transmission line 32a connects the transmission terminal 33 and the antenna terminal 4 via the switching transistor group 31, and the switching transistor 35a, the RF filter 36a, and the switching transistor 37a are connected in series. . The RF filter 36a is disposed between the switching transistors 35a and 37a. The gates of the switching transistors 35a and 37a are connected to the control terminal 18 via a resistor. The control terminal 18 controls the switching of the switching transistors 35a and 37a.

  The second parallel transmission transmission line 32b connects the transmission terminal 33 and the antenna terminal 4 via the switching transistor group 31, and is connected in parallel to the first parallel transmission transmission line 32a. The switching transistor 35b The RF filter 36b and the switching transistor 37b are connected in series. The RF filter 36b is disposed between the switching transistors 35b and 37b. Since the center frequency is different from that of the RF filter 36a, a signal having a frequency band different from that of the RF filter 36a can be passed. The gates of the switching transistors 35b and 37b are connected to the control terminal 16 through a resistor. The control terminal 16 controls the switching of the switching transistors 35b and 37b.

  The transmission terminal grounding switch 33 is composed of four switching transistors, and performs switching of a transmission line connecting the ground terminal 15 and the transmission terminal 3. The gate of each switching transistor of the transmission terminal grounding switch 33 is connected to the control terminal 13 via a resistor. The control terminal 13 controls the switching of the transmission terminal grounding switch 33.

  The control terminal 17 is connected to both the receiving terminal grounding switch 23 and the switching transistor group 31, and the switching of the switch 23 and the switching transistor group 31 can be controlled simultaneously by the control of the control terminal 17. The control terminal 13 is connected to both the transmission terminal grounding switch 33 and the switching transistor group 21, and the switching of the switch 33 and the switching transistor group 21 can be controlled simultaneously by the control of the control terminal 13.

Next, the operation of the above embodiment will be described below.
When performing the reception connection, two types of reception connection using the first parallel reception transmission path 22a and reception connection using the second parallel reception transmission path 22b are possible.
When the reception connection using the first parallel reception transmission path 22a is performed, only the control terminals 13 and 14 are turned on, and all the other control terminals 12 and 16 to 18 are turned off. Thereby, the first parallel reception transmission line 22a including the RF filter 26a is conducted, and the first reception transmission line connecting the antenna terminal 11 and the reception terminal 2 is secured. Further, since the transmission terminal 3 and the ground terminal 15 are short-circuited and the control terminals 16 to 18 are off, the transmission transmission path is not secured. Therefore, the RF front end circuit 1 is switched to the reception side, and the reception signal received from the transmission / reception antenna via the antenna terminal 11 is output to the reception side circuit connected to the reception terminal 2 via the RF filter 26a.

  When the reception connection using the second parallel reception transmission path 22b is performed, only the control terminals 12 and 13 are turned on, and all the other control terminals 14 and 16 to 18 are turned off. As a result, the second parallel reception transmission line 22b including the RF filter 26b becomes conductive, and a second reception transmission line connecting the antenna terminal 11 and the reception terminal 2 is secured. The transmission transmission path is not secured as in the reception connection using the first parallel reception transmission path 22a. Therefore, the RF front end circuit 1 is switched to the reception side, and a reception signal received from the antenna via the antenna terminal 11 is output to the reception side circuit connected to the reception terminal 2 via the RF filter 26b.

When performing transmission connection, two types of transmission connection using the first parallel transmission transmission path 32a and transmission connection using the second parallel transmission transmission path 32b are possible.
When performing transmission connection using the first parallel transmission transmission line 32a, only the control terminals 17 and 18 are turned on, and all the other control terminals 12 to 14 and 16 are turned off. Thereby, the first parallel transmission transmission line 32a including the RF filter 36a is conducted, and the first transmission transmission line connecting the antenna terminal 11 and the transmission terminal 3 is secured. Further, since the reception terminal 2 and the ground terminal 11 are short-circuited and the control terminals 12 to 14 are off, the reception transmission path is not secured. Therefore, the RF front end circuit 1 is switched to the transmission side, and a transmission signal from the transmission side circuit connected to the transmission terminal 3 is output from the transmission terminal 3 to the transmission / reception antenna via the antenna terminal 11 via the RF filter 36a. .

  When performing transmission connection using the second parallel transmission transmission line 32b, only the control terminals 16 and 17 are turned on, and all the other control terminals 12 to 14 and 18 are turned off. As a result, the second parallel transmission transmission line 32b including the RF filter 36b becomes conductive, and a second transmission transmission line connecting the antenna terminal 11 and the transmission terminal 3 is secured. The reception transmission path is not ensured as in the transmission connection using the first parallel transmission transmission path 32a. Therefore, the RF front end circuit 1 is switched to the transmission side, and a transmission signal from the transmission side circuit connected to the transmission terminal 3 is output from the transmission terminal 3 to the transmission / reception antenna via the RF filter 36b and the antenna terminal 11. .

The advantages of the RF front end circuit 1 of this embodiment will be described below.
FIG. 2 is a block diagram of a general superheterodyne RF front-end circuit 200 used in an ordinary time division multiple access (TDMA) system that is not a code division multiple access (CDMA) system in a mobile radio terminal system. FIG.

  A transmission / reception changeover switch 202 is connected to the transmission / reception antenna 201. The transmission / reception changeover switch 202 is connected to a reception side circuit RX and a transmission side circuit TX. The reception side circuit RX includes an RF filter 203 that filters a reception signal received by the transmission / reception antenna 201, and a low noise amplifier 204 that amplifies the signal of the RF filter 203 and outputs the amplified signal to a downstream reception circuit. The transmission side circuit TX includes a driver amplifier 211 that amplifies the transmission signal from the upstream side transmission circuit, an RF filter 212 that filters the output signal of the driver amplifier 211, and an output signal of the RF filter 212 that amplifies the output signal. A power amplifier 213 that outputs to 201. The downstream receiving circuit and the upstream transmitting circuit include a mixer, an RF amplifier, an IF filter, a baseband circuit, and the like. Of course, FIG. 2 shows an example, and it goes without saying that there are many other modifications.

  In the RF front end circuit 200 as shown in FIG. 2, when the carrier frequency band to be used is wide or when a plurality of bands are used, the RF filters 203 and 212 may not be able to respond to the bandwidth. Especially when a small SAW (Surface Acoustic Wave) filter or FBAR (Film Bulk Acoustic Resonator) filter is used, the maximum bandwidth is determined by the physical property value of the piezoelectric material causing the resonance phenomenon. It is difficult to accommodate the passband width.

  FIG. 3 shows an example of a block diagram of an RF front-end circuit for coping with the wide band which is the problem shown in FIG. The same components as those in FIG. 2 are denoted by the same reference numerals, and detailed description thereof is omitted. Instead of the single RF filter 203 shown in FIG. 2, in FIG. 3, two switches 221 and 222 and two RF filters 223 and 224 having different bands sandwiched between the switches 221 and 222 are used. A broadband filter circuit 225 is used. However, when this wideband filter circuit 225 is used, there are problems that inserting the two switches 221 and 222 increases the circuit scale and price, and increases the switch insertion loss. Since a loss of 0.2 to 0.3 dB occurs every time one switch is inserted, it cannot be ignored.

  In this embodiment, the mobile radio terminal system is reviewed and attention is paid to the antenna switch. An example of the internal structure of a conventional antenna switch is as shown in Non-Patent Document 1.

  On the other hand, by using the RF front end circuit 1 shown in the present embodiment, it is possible to achieve a wide band by incorporating two systems of filters having different center frequencies in the reception transmission path and the transmission transmission path. 3 is common to the RF front end circuit 220 in FIG. 3, but the number of switching transistors added at that time is disclosed by a specific switching circuit configuration for realizing the circuit shown in FIG. 1 or FIG. Compared to the conventional RF front-end circuit shown in Non-Patent Document 1, the number is limited to four. In addition, despite the fact that a plurality of transmission lines are provided, the number of switching transistors intervening in the transmission line is reduced to one (4), and an increase in insertion loss can be prevented.

  As described above, according to the present embodiment, when a wide band system is used and a plurality of RF filters are arranged in parallel to increase the bandwidth, the circuit scale and the cost are increased. As a result, it is possible to minimize the increase in insertion loss, or to minimize the increase in insertion loss, and a broadband mobile radio terminal system can be easily realized.

(Second Embodiment)
FIG. 4 is a circuit diagram showing an example of the RF front-end circuit 40 with a built-in impedance matching circuit according to the second embodiment of the present invention. The RF front end circuit 40 includes an antenna terminal 41, a reception terminal 42, and a transmission terminal 43, and outputs a reception signal received from the transmission / reception antenna via the antenna terminal 41 from the reception terminal 42 to a downstream reception side circuit. At the same time, the transmission signal input from the upstream transmission side circuit via the transmission terminal 43 is transmitted via the antenna terminal 41. The RF front end circuit 1 has a switching function of the reception signal and the transmission signal.

  A reception connection switch 61 is connected between the antenna terminal 41 and the reception terminal 42. A receiving terminal grounding switch 62 and a capacitor 63 are connected in series between the receiving terminal 42 and the ground terminal 51.

  The reception connection switch 61 includes four switching transistors. Each gate of the switching transistor constituting the reception connection switch 61 is connected to the control terminal 52 through a resistor, and the control terminal 52 controls the switching of the reception connection switch 61.

  The reception terminal grounding switch 62 includes four switching transistors, and performs switching of a transmission line connecting the ground terminal 51 and the reception terminal 42. The gate of each switching transistor of the receiving terminal grounding switch 62 is connected to the control terminal 55 through a resistor. The control terminal 55 controls the switching of the receiving terminal grounding switch 62.

  A transmission connection switch 71 is connected between the antenna terminal 41 and the transmission terminal 43. A transmission terminal grounding switch 72 and a capacitor 73 are connected in series between the transmission terminal 43 and the ground terminal 53.

  The transmission connection switch 71 includes a switching transistor group 74, a first parallel transmission transmission line 75a connected in series to the switching transistor group 74, and a second parallel connection connected in parallel to the first parallel transmission transmission line 75a. The transmission transmission path 75b. The switching transistor group 74 includes two switching transistors, each gate of which is connected to the control terminal 55 via a resistor. This control terminal 55 controls switching of the switching transistor group 74.

  The first parallel transmission transmission line 75a connects the transmission terminal 43 and the antenna terminal 41 via a switching transistor group 74. A switching transistor 76a, a power amplifier output impedance matching circuit 77a, and a switching transistor 78a are connected in series. It is connected to the. The impedance matching circuit 77a is disposed between the switching transistors 76a and 78a. The gates of the switching transistors 76a and 78a are connected to the control terminal 56 through resistors. The control terminal 56 controls switching of the switching transistors 76a and 78a.

  The second parallel transmission transmission line 75b connects the transmission terminal 43 and the antenna terminal 41 via the switching transistor group 74 and is connected in parallel with the first parallel transmission transmission line 75a. The switching transistor 76b A power amplifier output impedance matching circuit 77b and a switching transistor 78b are connected in series. The impedance matching circuit 77b is disposed between the switching transistors 76b and 78b. In order to perform matching with an impedance different from that of the impedance matching circuit 77a, a signal having a frequency band different from that of the impedance matching circuit 77a is passed. The gates of the switching transistors 76b and 78b are connected to the control terminal 54 through resistors. The control terminal 54 controls the switching of the switching transistors 76b and 78b.

  The transmission terminal grounding switch 72 includes four switching transistors, and performs switching of a transmission line connecting the ground terminal 53 and the transmission terminal 43. The gate of each switching transistor of the transmission terminal grounding switch 72 is connected to the control terminal 52 via a resistor. The control terminal 52 controls the switching of the transmission terminal grounding switch 72.

  The control terminal 55 is connected to both the receiving terminal grounding switch 62 and the switching transistor group 74, and the switching of the switch 62 and the switching transistor group 74 can be controlled simultaneously by the control of the control terminal 55. The control terminal 52 is connected to both the transmission terminal grounding switch 72 and the reception connection switch 61, and the switching of the switches 72 and 61 can be controlled simultaneously by the control of the control terminal 52.

  A power amplifier 70 a and a power amplifier input impedance matching circuit 70 b are connected to the transmission terminal 43. The transmission signal from the transmission side circuit is impedance-matched by this power amplifier input impedance matching circuit, outputted to the power amplifier 70a, amplified by the power amplifier 70a, and inputted to the transmission terminal 43.

Next, the operation of the above embodiment will be described below.
When performing a reception connection, the control terminal 52 is turned on, and all other control terminals 54 to 56 are turned off. Thereby, the antenna terminal 41 and the reception terminal 42 are short-circuited, and a reception transmission path connecting the antenna terminal 41 and the reception terminal 42 is secured. Further, since the control terminals 54 to 56 are off, the transmission transmission path is not secured. Therefore, the RF front end circuit 40 is switched to the reception side, and the reception signal received from the transmission / reception antenna via the antenna terminal 41 is output to the reception side circuit connected to the reception terminal 42.

  When performing transmission connection, two types of transmission connection using the first parallel transmission transmission path 75a and transmission connection using the second parallel transmission transmission path 75b are possible.

  When the reception connection using the first parallel transmission transmission line 75a is performed, only the control terminals 55 and 56 are turned on, and the other control terminals 52 and 54 are turned off. Thereby, the first parallel transmission transmission line 75a including the impedance matching circuit 77a is conducted, and the first transmission transmission line connecting the antenna terminal 41 and the transmission terminal 43 is secured. Further, since the reception terminal 42 and the ground terminal 51 are short-circuited and the control terminals 52 and 54 are off, the reception transmission path is not secured. Therefore, the RF front end circuit 40 switches to the transmission side, and a transmission signal from the transmission side circuit connected to the transmission terminal 43 passes through the impedance matching circuit 77a from the transmission terminal 43 and is output to the transmission / reception antenna via the antenna terminal 41. The

  When the reception connection using the second parallel transmission transmission line 75b is performed, only the control terminals 54 and 55 are turned on, and the other control terminals 52 and 56 are turned off. As a result, the second parallel transmission transmission line 75b including the impedance matching circuit 77b becomes conductive, and a second transmission transmission line connecting the antenna terminal 41 and the transmission terminal 43 is secured. The reception transmission path is not secured in the same manner as the transmission connection using the first parallel transmission transmission path 75a. Therefore, the RF front end circuit 40 switches to the transmission side, and the transmission signal from the transmission side circuit connected to the transmission terminal 43 passes through the impedance matching circuit 77b from the transmission terminal 43 and is output to the transmission / reception antenna via the antenna terminal 41. Is done.

The advantages of the RF front end circuit 40 of this embodiment will be described below.
FIG. 2 of the first embodiment shows the configuration of a general superheterodyne RF front-end circuit 200. However, when a carrier frequency band to be used is wide or when a plurality of bands are used, a power amplifier is used. There may be a case where the bandwidth cannot be handled at 213. The power amplifier 213 generally used has an impedance matching circuit on the input side and output side for matching the internal impedance and the impedance of the external transmission system. However, the power amplifier 213 supports a wide frequency band. It is because it cannot be completed.

  FIG. 5 shows an example of a block diagram of the RF front-end circuit 230 for coping with the wide band which is the problem shown in FIG. The same components as those in FIG. 2 are denoted by the same reference numerals, and detailed description thereof is omitted. Instead of the single power amplifier 113 shown in FIG. 2, in FIG. 5, two switches 231 and 232 and two power amplifiers 233 and 234 having different bands sandwiched between the switches 231 and 232 are used. An amplifying circuit 235 is used. However, when this amplifier circuit 235 is used, there is a problem that the insertion of the two switches 231 and 232 increases the circuit scale and price and increases the insertion loss of the switches. Since a loss of 0.2 to 0.3 dB occurs every time one switch is inserted, it cannot be ignored.

  On the other hand, by using the RF front-end circuit 40 shown in the present embodiment, in the transmission transmission line, by incorporating two impedance matching circuits having different center frequencies used for power amplifier output matching, the bandwidth can be increased. 5 is common to the front end circuit 230 of FIG. 5, but the number of switching transistors added at that time is a specific example for realizing the circuits shown in FIG. 1 and FIG. The configuration of the switching circuit is at least two as compared with the conventional RF front-end circuit disclosed in Non-Patent Document 1 disclosed. In addition, despite the fact that a plurality of transmission lines for transmission are provided, the number of switching transistors intervening in the transmission line is reduced to one (4), and an increase in insertion loss can be prevented.

  As described above, according to the present embodiment, an increase in circuit scale and cost occurs when a wide bandwidth system or a system using a plurality of bands is used to increase the bandwidth by arranging a plurality of impedance matching circuits in parallel. In addition, the increase in insertion loss can be eliminated or minimized, and a broadband mobile radio terminal system can be easily realized.

(Third embodiment)
FIG. 6 is a circuit diagram showing an example of the RF front-end circuit 80 according to the third embodiment of the present invention. The RF front end circuit 80 includes an antenna terminal 81, a reception terminal 2, a connection terminal 83 to a driver amplifier, a first transmission terminal 104, and a second transmission terminal 105, via the antenna terminal 81. The reception signal received from the transmission / reception antenna is output from the reception terminal 2 to the downstream reception side circuit, and the transmission signal input from the upstream transmission side circuit via the driver connection terminal 83 is transmitted to the first transmission terminal 104 and the first transmission terminal 104. The signal is output to the transmitting / receiving antenna via the antenna terminal 81 via any one of the two transmission terminals 105. The RF front end circuit 80 has a switching function of the reception signal and the transmission signal.

  Note that the configuration on the receiving side of the RF front end circuit 80 of this embodiment is the same as that of the first embodiment, and therefore, common constituent elements are denoted by the same reference numerals and detailed description thereof is omitted. That is, the receiving connection switch 20 is disposed between the antenna terminal 81 and the receiving terminal 2, and the receiving terminal grounding switch 23 and the capacitor 24 are connected between the receiving terminal 2 and the ground terminal 11.

  Between the antenna terminal 81 and the driver connection terminal 83, a transmission connection switch 90, power amplifier modules 93a and 93b, high frequency filters 94a and 94b, and switching transistors 95a and 95b are connected. The transmission connection switch 90 includes a switching transistor group 91, a first parallel transmission transmission line 92a connected in series to the switching transistor group 91, and a second parallel connection connected in parallel to the first parallel transmission transmission line 92a. The transmission transmission path 92b. The switching transistor group 91 includes two switching transistors, each gate of which is connected to the control terminal 86 via a resistor. This control terminal 86 controls switching of the switching transistor group 91.

  The first parallel transmission transmission line 92a connects the driver connection terminal 83 and the antenna terminal 81 via the switching transistor group 91. The switching transistor 101a, the RF filter 102a, and the switching transistor 103a are connected in series. Yes. The RF filter 102a is disposed between the switching transistors 101a and 103a. The gates of the switching transistors 101a and 103a are connected to the control terminal 87 via a resistor. The control terminal 87 controls switching of the switching transistors 101a and 103a.

  The second parallel transmission transmission line 92b connects the driver connection terminal 83 and the antenna terminal 81 via the switching transistor group 91 and is connected in parallel to the first parallel transmission transmission line 92a. 101b, RF filter 102b and switching transistor 103b are connected in series. The RF filter 102b is disposed between the switching transistors 101b and 103b. Since the center frequency is different from that of the RF filter 102a, a signal having a frequency band different from that of the RF filter 102a can be passed. The gates of the switching transistors 101b and 103b are connected to the control terminal 85 via a resistor. The control terminal 85 controls the switching of the switching transistors 101b and 103b.

  A power amplifier module 93a, a high frequency filter 94a, and a switching transistor 95a are connected in series to the first parallel transmission transmission path 92a. The gate of the switching transistor 95a is connected to the control terminal 87 via a resistor. A power amplifier module 93b, a high frequency filter 94b, and a switching transistor 95b are connected in series to the second parallel transmission transmission path 92b. The gate of the switching transistor 95b is connected to the control terminal 85 via a resistor. The switching transistors 95a and 95b are connected to the driver connection terminal 83.

  The transmission terminal grounding switch 96 includes five switching transistors 96a to 96e, and performs switching of a transmission path connecting the ground terminal 84 and the driver connection terminal 83. The gates of the switching transistors 96a to 96e are connected to the control terminal 13 through resistors. The control terminal 13 controls the switching of the transmission terminal grounding switch 96.

  Each of the source and the drain of the switching transistor 96 a is disposed between one end of the switching transistor 96 c and the first transmission terminal 104. The first transmission terminal 104 is drawn from a transmission line connecting the first parallel transmission transmission line 92a and the output line of the power amplifier module 93a. Each of the source and drain of the switching transistor 96 b is disposed between one end of the switching transistor 96 c and the second transmission terminal 105. The second transmission terminal 105 is drawn from a transmission line connecting the second parallel transmission transmission line 92b and the output line of the power amplifier module 93b. The switching transistors 96c to 96e are connected in series. Thus, when the control terminal 13 is turned on, the transmission line connecting the ground terminal 84 and both the first transmission terminal 104 and the second transmission terminal 105 is simultaneously turned on, while when the control terminal 13 is turned off, the ground terminal 84 and the second transmission terminal 105 are turned on. Both transmission lines of the first transmission terminal 104 and the second transmission terminal 105 can be turned off simultaneously.

  The control terminal 86 is connected to both the receiving terminal grounding switch 23 and the switching transistor group 91, and the switching of the switch 23 and the switching transistor group 91 can be controlled simultaneously by the control of the control terminal 86. The control terminal 13 is connected to both the transmission terminal grounding switch 96 and the switching transistor group 21, and the switching of the switch 96 and the switching transistor group 21 can be controlled simultaneously by the control of the control terminal 13.

Next, the operation of the above embodiment will be described below.
When performing the reception connection, two types of reception connection using the first parallel reception transmission path 22a and reception connection using the second parallel reception transmission path 22b are possible.

  When the reception connection using the first parallel reception transmission path 22a is performed, only the control terminals 13 and 14 are turned on, and all the other control terminals 12, 85 to 87 are turned off. As a result, the first parallel reception transmission line 22a including the RF filter 26a becomes conductive, and the first reception transmission line connecting the antenna terminal 81 and the reception terminal 2 is secured. In addition, since the ground terminal 84, the first transmission terminal 104, and the second transmission terminal 105 are short-circuited, the potentials of the first transmission terminal 104 and the second transmission terminal 105 are held at the same potential as the ground terminal 84, and a transmission transmission path is secured. Not. Therefore, the RF front end circuit 80 is switched to the reception side, and the reception signal received from the transmission / reception antenna is output to the reception side circuit connected to the reception terminal 2 via the antenna terminal 81 and the RF filter 26a.

  When the reception connection using the second parallel reception transmission path 22b is performed, only the control terminals 12 and 13 are turned on, and all the other control terminals 14, 85 to 87 are turned off. As a result, the second parallel reception transmission line 22b including the RF filter 26b becomes conductive, and a second reception transmission line connecting the antenna terminal 81 and the reception terminal 2 is secured. The transmission transmission path is not secured as in the reception connection using the first parallel reception transmission path 22a. Therefore, the RF front end circuit 80 is switched to the reception side, and the reception signal received from the antenna via the antenna terminal 81 is output to the reception side circuit connected to the reception terminal 2 via the RF filter 26b.

  When performing transmission connection, two types of transmission connection using the first parallel transmission transmission path 92a and transmission connection using the second parallel transmission transmission path 92b are possible.

  When the reception connection using the first parallel transmission transmission line 92a is performed, only the control terminals 86 and 87 are turned on, and all the other control terminals 12 to 14 and 85 are turned off. As a result, the first parallel transmission transmission line 92a including the RF filter 102a and the transmission line including the power amplifier module 93a and the high frequency filter 94a are electrically connected, and the first transmission transmission line connecting the antenna terminal 81 and the driver connection terminal 83 is provided. Secured. In addition, since the reception terminal 2 and the ground terminal 11 are short-circuited and the control terminal 12 and the control terminal 14 are off, the reception transmission path is not secured. Therefore, the RF front end circuit 80 switches to the transmission side, and the transmission signal from the transmission side circuit connected to the driver connection terminal 83 is filtered by the high frequency filter 94a and amplified by the power amplifier module 93a, and then the RF filter 36a. Via the antenna terminal 81 and output to the transmitting / receiving antenna.

  When the reception connection using the second parallel transmission transmission path 92b is performed, only the control terminals 85 and 86 are turned on, and all the other control terminals 12 to 14 and 87 are turned off. As a result, the second parallel transmission transmission line 92b including the RF filter 102b becomes conductive, and a second transmission transmission line connecting the antenna terminal 81 and the driver connection terminal 83 is secured. The reception transmission path is not secured as in the transmission connection using the first parallel transmission transmission path 102a. Therefore, the RF front end circuit 80 switches to the transmission side, and the transmission signal from the transmission side circuit connected to the driver connection terminal 83 is filtered by the high frequency filter 94b and amplified by the power amplifier module 93b, and then the RF filter 102b. Via the antenna terminal 81 and output to the transmitting / receiving antenna.

  As described above, by using the RF front end circuit 80 shown in the present embodiment, two systems of filters having different center frequencies are incorporated in the reception transmission path and the transmission transmission path, respectively, and the center frequencies are different in the transmission transmission path. By incorporating two power amplifier modules, it is possible to increase the bandwidth. The number of switching transistors added at this time is compared with the conventional RF front-end circuit shown in Non-Patent Document 1 in which a specific switching circuit configuration for realizing the circuit shown in FIG. 1 is disclosed. The number of switching transistors intervening in the transmission path is reduced by one compared to the conventional one even though the number of reception transmission paths is limited to six, and a transmission transmission path is reduced. Although the number of switching transistors provided in the transmission line is the same as that of the conventional one, the increase in insertion loss can be minimized.

  As described above, according to the present embodiment, the circuit scale and cost generated when a plurality of power amplifiers are arranged in parallel to increase the bandwidth for a system having a wide bandwidth or a system using a plurality of bands. The increase can be minimized, and the increase in insertion loss can be eliminated or minimized, and a broadband mobile radio terminal system can be easily realized.

  As described above with reference to the first to third embodiments, the essence of the first to third embodiments reuses the reception and transmission connection switches in which a plurality of transistors are connected in series, and supports a wide band. It is also used as a filter or amplifier changeover switch installed in parallel.

  That is, a part of the switching transistors constituting the connection switch is multiplexed in parallel, and a filter or an impedance matching circuit is sandwiched between the multiplexed switching transistors, or a power amplifier is connected to the multiplexed switching transistors. By minimizing the number of switching transistors to be added by multiplexing filters and amplifiers, the insertion loss associated with the addition of switching transistors can be eliminated or minimized.

The present invention is not limited to the above embodiment.
In the above embodiment, the switching transistor has a configuration including a transistor and a resistor connected to the gate of the transistor. However, the present invention is not limited to this, and any switching element capable of switching the current flowing through the transmission line is used. Can be replaced.

  The switching transistor groups 21 and 31 shown in FIG. 1 of the first embodiment, the switching transistor group 74 shown in FIG. 4 of the second embodiment, and the switching transistor groups 21 and 91 shown in FIG. 6 of the third embodiment are 2 Although a configuration including one switching transistor is shown, one or three or more may be used.

  Further, each of the RF filters 26a, 26b, 36a, 36b, 102a, and 102b of the first embodiment and the third embodiment is configured to be sandwiched between switching transistors, but is not limited thereto. For example, a switching transistor connected to one end of each of the RF filters may be omitted. Further, the number of switching transistors connected in series to each of the RF filters is not limited to one at each end, and two or more switching transistors may be arranged.

  Similarly, one end of the switching transistors 76a, 76b, 78a and 78b arranged at both ends of each of the impedance matching circuits 77a and 77b of the second embodiment may be omitted, or the number thereof may be changed. Also good.

  In the first embodiment, the configuration in which two RF filters are connected in parallel on both the transmission side and the reception side has been described. However, the present invention is not limited to this. For example, only the transmitting side has the configuration shown in FIG. 1 of the first embodiment, and the receiving side has a plurality of switching transistors, as in the conventional RF front-end circuit as shown in Non-Patent Document 1. You may comprise only. Further, only the receiving side is configured as shown in FIG. 1, and the transmitting side is composed of only a plurality of switching transistors as in the conventional RF front end circuit as shown in Non-Patent Document 1. Also good. Similarly, in the third embodiment, only one of the transmission side and the reception side may be configured as shown in FIG. 6, and the other may be configured similarly to the conventional RF front-end circuit.

  In the second embodiment, the configuration in which the two impedance matching circuits are arranged in parallel only on the transmission side is shown, but the reception side may have the same configuration as that of the first embodiment.

  As described above, the present invention is effective in the technical field of an RF front-end circuit that switches between transmission and reception circuits in a wireless communication system.

1 is a circuit diagram showing an example of an RF front end circuit according to a first embodiment of the present invention. FIG. 3 is a block diagram of a general superheterodyne RF front-end circuit. FIG. 3 is a block diagram of an RF front end circuit for coping with a wider band. The circuit diagram which shows an example of RF front end circuit which concerns on 2nd Embodiment of this invention. FIG. 3 is a block diagram of an RF front end circuit 230 for coping with a wider band. The circuit diagram which shows an example of RF front end circuit which concerns on 3rd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,40,80 ... RF front end circuit, 2,42 ... Reception terminal, 3, 43, 83 ... Transmission terminal, 11, 15, 51, 53, 83 ... Grounding terminal, 12-14, 16-18, 52, 54-56, 85-87 ... control terminal, 20, 61 ... reception connection switch, 30, 71, 90 ... transmission connection switch, 23, 62 ... reception terminal grounding switch, 33, 73, 96 ... transmission terminal grounding Switch 26a, 26b, 36a, 36b, 102a, 102b ... RF filter, 77a, 77b ... impedance matching circuit, 93a, 93b ... power amplifier module, 94a, 94b ... high frequency filter

Claims (6)

In the RF front-end circuit that switches the output of the reception signal from the antenna terminal to the reception terminal and the output of the transmission signal from the transmission terminal to the antenna terminal,
A receiving connection switch provided between the antenna terminal and the receiving terminal;
A receiving terminal grounding switch provided between the receiving terminal and the first grounding terminal;
A transmission connection switch provided between the antenna terminal and the transmission terminal;
A transmission terminal grounding switch provided between the transmission terminal and the second grounding terminal;
Any one of the reception connection switch and the transmission connection switch includes a first transmission line having a first passband, a first switching transistor for switching the first transmission line, and the first transmission line. A second transmission line having a second pass band different from the pass band and connected in parallel with the first transmission line, and a second switching transistor for switching the second transmission line. A featured RF front-end circuit.   The first transmission path includes a first bandpass filter having the first passband, and the second transmission path includes a second bandpass filter having the second passband. The RF front end circuit according to claim 1. A third switching transistor for switching the first bandpass filter;
A fourth switching transistor for switching the second bandpass filter;
The first bandpass filter is disposed between the first switching transistor and the third switching transistor;
The RF front-end circuit according to claim 2, wherein the second band-pass filter is arranged between the second switching transistor and the fourth switching transistor.   The first transmission path includes a first impedance matching circuit having the first pass band, and the second transmission path includes a second impedance matching circuit having the second pass band. The RF front end circuit according to claim 1. A third switching transistor for switching the first impedance matching circuit;
A fourth switching transistor for switching the second impedance matching circuit,
The first impedance matching circuit is disposed between the first switching transistor and the third switching transistor,
The RF front end circuit according to claim 4, wherein the second impedance matching circuit is disposed between the second switching transistor and the fourth switching transistor.   The first transmission path includes a first power amplifier that amplifies a signal that passes through the first pass band, and the second transmission path amplifies a signal that passes through the second pass band. The RF front end circuit according to claim 1, comprising a second power amplifier.

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