JP2012151734A - Radio circuit - Google Patents

Abstract

Provided is a radio circuit capable of reducing leakage of a signal outside a desired path by strengthening isolation at a position where the path of the signal is controlled.
A mixer converts a transmission signal in an intermediate frequency band into a transmission signal in a radio frequency band during transmission, and converts a reception signal in a radio frequency band into a reception signal in an intermediate frequency band during reception. The switch 12 connects the path (1) and the mixer 10 during transmission, and connects the path (2) and the mixer 10 during reception. The switch 6 connects the path (3) and the mixer 10 during transmission, and connects the path (4) and the mixer 10 during reception. The switch 13 is provided on the path (1) and suppresses the signal flow in the direction opposite to the direction in which the transmission signal in the intermediate frequency band flows. The switch 7 is provided on the path (4), and suppresses the signal flow in the direction opposite to the direction in which the reception signal of the radio frequency band flows.
[Selection] Figure 1

Description

  The present invention relates to a radio circuit.

  Conventionally, a superheterodyne system has been used as a configuration of a radio signal transmission / reception circuit (see, for example, Japanese Patent Laid-Open No. 6-252792). In the superheterodyne method, the transmission unit does not directly convert the transmission signal from the baseband signal to a radio frequency signal, but converts it to an intermediate frequency signal and performs various processes, and then converts it to a radio frequency signal. Convert. The receiving unit does not convert the received signal from the radio frequency signal directly to the baseband signal, but converts the received signal to an intermediate frequency signal and performs various processes, and then converts the signal to the baseband signal.

  In general, a superheterodyne wireless communication circuit includes a mixer and a bandpass filter in a transmission unit and a reception unit, respectively. However, when transmission and reception are not performed simultaneously, it is possible to use both transmission and reception with a single mixer and band-pass filter.

  FIG. 11 is a diagram illustrating a configuration of a radio circuit that uses a mixer and a bandpass filter for both transmission and reception, and a signal flow during transmission. FIG. 12 is a diagram illustrating a configuration of a radio circuit that uses both a mixer and a bandpass filter for transmission and reception, and a signal flow during reception.

  As shown in FIGS. 11 and 12, the mixer 10 and the band pass filters 9 and 11 are used for both transmission and reception. As a result, the scale of the radio circuit can be reduced.

JP-A-6-252792

(Signal flow during transmission)
Referring to FIG. 11, at the time of transmission, DAC (Digital-Analog Converter) 17 → amplifier 15 → switch 12 → band pass filter 11 → mixer 10 → band pass filter 9 → switch 6 → amplifier 4 → circulator 3 → transmission / reception antenna 2 Signals flow in order.

  Here, since the isolation of the switch 12 which is an element for controlling the path is not perfect (isolation of 25 to 30 dB), a part of the signal input to the switch 12 leaks toward the amplifier 16. Since the leaked signal passes through the amplifier 16 and the ADC 18 and is sent to the baseband processing unit, there is a possibility that some erroneous processing is performed in the baseband processing unit.

  Further, since the isolation of the switch 6 which is an element for controlling the path is not perfect (isolation of 25 to 30 dB), a part of the signal input to the switch 6 leaks out to the amplifier 15. A voltage is applied to the amplifier 15 in the reverse direction due to the leaked signal, so that the amplifier 15 is damaged or its life is shortened.

(Signal flow during reception)
Referring to FIG. 12, at the time of reception, transmission / reception antenna 2 → circulator 3 → amplifier 5 → switch 6 → band pass filter 9 → mixer 10 → band pass filter 11 → switch 12 → amplifier 16 → ADC (Analog-Digital Converter) 18 A signal flows.

  Here, since the isolation of the switch 6 which is an element for controlling the path is not perfect (isolation of 25 to 30 dB), a part of the signal input to the switch 6 leaks toward the amplifier 4. Since the leaked signal passes through the amplifier 4 and the circulator 3 and is sent to the transmission / reception antenna 2, there is a possibility that some meaningless signal is transmitted from the transmission / reception antenna 2.

  In addition, since the isolation of the switch 12 that controls the path is not perfect (isolation of 25 to 30 dB), a part of the signal input to the switch 12 leaks out to the amplifier 15. A voltage is applied to the amplifier 15 in the reverse direction due to the leaked signal, so that the amplifier 15 is damaged or its life is shortened.

  SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a radio circuit capable of reducing leakage of a signal outside a desired path by strengthening isolation at a position where the signal path is controlled. .

  In order to solve the above problems, the radio circuit of the present invention mixes a transmission signal in the intermediate frequency band and a local oscillation signal at the time of transmission, converts the signal to a transmission signal in the radio frequency band, and transmits the radio frequency band at the time of reception. A mixer that mixes the reception signal and the local oscillation signal and converts the mixed signal into a reception signal in the intermediate frequency band, a first path that is a transmission signal path in the intermediate frequency band, and a first reception signal path in the intermediate frequency band A first path control element that is provided at an intersection with the two paths, connects the first path and the mixer at the time of transmission, and connects the second path and the mixer at the time of reception; and a transmission signal of a radio frequency band Provided at the intersection of the third path, which is the path, and the fourth path, which is the path of the received signal in the radio frequency band, connecting the third path and the mixer at the time of transmission, and the fourth path and the mixer at the time of reception A second path control element connecting the first path and the first path A third path control element that suppresses a signal flow in a direction opposite to the direction in which the transmission signal in the intermediate frequency band flows, and a direction in which a reception signal in the radio frequency band flows in the fourth path. And a fourth path control element that suppresses the flow of signals in the reverse direction.

  According to the present invention, it is possible to reduce leakage of a signal outside a desired path by strengthening isolation at a position where the path of the signal is controlled.

It is a figure for demonstrating the structure of the radio | wireless circuit of 1st Embodiment, and the flow of the signal at the time of transmission in this radio | wireless circuit. It is a figure for demonstrating the flow of the signal at the time of reception in the radio | wireless circuit of 1st Embodiment. It is a figure for demonstrating the structure of the radio | wireless circuit of the modification 1 of 1st Embodiment, and the flow of the signal at the time of transmission in this radio | wireless circuit. It is a figure for demonstrating the flow of the signal at the time of reception in the radio | wireless circuit of the modification 1 of 1st Embodiment. It is a figure for demonstrating the structure of the radio | wireless circuit of the modification 2 of 1st Embodiment, and the flow of the signal at the time of transmission in this radio | wireless circuit. It is a figure for demonstrating the flow of the signal at the time of reception in the radio | wireless circuit of the modification 2 of 1st Embodiment. It is a figure for demonstrating the structure of the radio | wireless circuit of 2nd Embodiment, and the flow of the signal at the time of transmission in this radio | wireless circuit. It is a figure for demonstrating the flow of the signal at the time of reception in the radio | wireless circuit of 2nd Embodiment. It is a figure for demonstrating the structure of the radio | wireless circuit of 3rd Embodiment. It is a figure for demonstrating the structure of the radio | wireless circuit of 4th Embodiment. It is a figure showing the structure of the radio | wireless circuit which shared the mixer and the band pass filter by transmission and reception, and the flow of the signal at the time of transmission. It is a figure showing the structure of the radio | wireless circuit which used both the mixer and the band pass filter for transmission and reception, and the flow of the signal at the time of reception.

Embodiments of the present invention will be described below with reference to the drawings.
[First Embodiment]
FIG. 1 is a diagram for explaining a configuration of a radio circuit according to the first embodiment and a signal flow during transmission in the radio circuit.

  Referring to FIG. 1, a radio circuit 1 includes a DAC 17, an amplifier 15, a switch 13, a switch 14, an amplifier 16, a switch 12, an ADC 18, a band pass filter 11, a mixer 10, and a band. A pass filter 9, a switch 6, a switch 8, a switch 7, an amplifier 4, a circulator 3, an amplifier 5, a transmission / reception antenna 2, and a local oscillator 81 are provided.

  The DAC 17, the amplifier 15, and the switch 13 are provided in a path (1) through which a transmission signal in the intermediate frequency band flows. The switch 14, the amplifier 16, and the ADC 18 are provided in the path (2) through which the reception signal in the intermediate frequency band flows. The switch 8 and the amplifier 4 are provided in a path (3) through which a transmission signal in the radio frequency band flows. The amplifier 5 and the switch 7 are provided in a path (4) through which a reception signal in the radio frequency band flows.

  A switch 12 is provided at the intersection of the route (1) and the route (2). A switch 6 is provided at the intersection of the route (3) and the route (4).

  The DAC 17 converts a baseband signal output from a baseband processing unit (not shown) into an analog signal in the intermediate frequency band, and outputs the analog signal to the amplifier 15.

  The amplifier 15 amplifies the intermediate frequency band signal output from the DAC 17 and outputs the amplified signal to the switch 13.

  The amplifier 16 amplifies the intermediate frequency band signal output from the switch 14 and outputs the amplified signal to the ADC 18.

  The ADC 18 converts the intermediate frequency band signal output from the amplifier 16 into a digital signal and outputs the digital signal to the baseband processing unit.

  The switch 12 has a terminal P1, a terminal P2, and a terminal P3. The terminal P1 is connected to the mixer 10 via the band pass filter 11. The terminal P2 is connected to the route (1). The terminal P3 is connected to the route (2). At the time of transmission, the terminal P1 and the terminal P2 are connected, so that the mixer 10 is connected to the path (1) via the bandpass filter 11. During reception, the terminal P1 and the terminal P3 are connected, so that the mixer 10 is connected to the path (2) via the bandpass filter 11.

  The switch 13 has a terminal P1, a terminal P2, and a terminal P3. The terminal P1 and the terminal P2 are on the path (1). The terminal P1 is closer to the switch 12 than the terminal P2. The terminal P3 is connected to the fixed potential by being connected to the ground via the resistor R. At the time of transmission, the terminal P1 and the terminal P2 are connected, so that a transmission signal in the intermediate frequency band flows through the path (1). During reception, the terminal P1 and the terminal P3 are connected to suppress the leakage signal of the reception signal leaking from the switch 12 in the reverse direction to the forward direction in which the transmission signal in the intermediate frequency band flows in the path (1). To do.

  The switch 14 has a terminal P1, a terminal P2, and a terminal P3. The terminal P1 and the terminal P2 are on the path (2). The terminal P1 is closer to the switch 12 than the terminal P2. The terminal P3 is connected to the fixed potential by being connected to the ground via the resistor R. At the time of reception, the terminal P1 and the terminal P2 are connected, so that the reception signal in the intermediate frequency band flows through the path (2). During transmission, the terminal P1 and the terminal P3 are connected to suppress the leakage signal of the transmission signal leaking from the switch 12 in the reverse direction to the forward direction in which the reception signal in the intermediate frequency band flows in the path (2). To do.

  The bandpass filter 11 removes unnecessary signal components from the intermediate frequency band signal output from the switch 12 during transmission, and outputs the signal to the mixer 10. The bandpass filter 11 removes unnecessary signal components from the intermediate frequency band signal output from the mixer 10 and outputs the signal to the switch 12 during reception.

  At the time of transmission, the mixer 10 multiplies the signal in the intermediate frequency band output from the bandpass filter 11 and the local oscillation signal Lo output from the local oscillator 81, and applies the up-converted radio frequency band signal to the bandpass filter. Output to 9. During reception, the mixer 10 multiplies the radio frequency band signal output from the bandpass filter 9 by the local oscillation signal Lo output from the local oscillator 81 and applies the downconverted intermediate frequency band signal to the bandpass filter. 11 to output. As the mixer 10, for example, a dual gate FET (Field effect transistor) as described in JP-A-6-350478 can be used.

  The bandpass filter 6 removes unnecessary signal components from the radio frequency band signal output from the mixer 10 during transmission, and outputs the signal component to the switch 6. The bandpass filter 6 removes unnecessary signal components from the intermediate frequency band signal output from the switch 6 and outputs the signal to the mixer 10 during reception.

  The switch 6 has a terminal P1, a terminal P2, and a terminal P3. The terminal P1 is connected to the mixer 10 via the band pass filter 9. The terminal P2 is connected to the path (3). The terminal P3 is connected to the route (4). At the time of transmission, the terminal P1 and the terminal P2 are connected, so that the mixer 10 is connected to the path (3) via the bandpass filter 9. At the time of reception, the terminal P1 and the terminal P3 are connected, so that the mixer 10 is connected to the path (4) via the bandpass filter 9.

  The switch 8 has a terminal P1, a terminal P2, and a terminal P3. The terminal P1 and the terminal P2 are on the path (3). The terminal P1 is closer to the switch 6 than the terminal P2. The terminal P3 is connected to the fixed potential by being connected to the ground via the resistor R. At the time of transmission, the terminal P1 and the terminal P2 are connected, so that a transmission signal in the radio frequency band flows through the path (3). During reception, the terminal P1 and the terminal P3 are connected to suppress the leakage signal of the reception signal leaking from the switch 6 in the reverse direction to the forward direction in which the transmission signal of the radio frequency band flows in the path (3). To do.

  The switch 7 has a terminal P1, a terminal P2, and a terminal P3. The terminal P1 and the terminal P2 are on the path (4). The terminal P1 is closer to the switch 6 than the terminal P2. The terminal P3 is connected to the fixed potential by being connected to the ground via the resistor R. At the time of transmission, the terminal P1 and the terminal P2 are connected, so that the reception signal in the radio frequency band flows through the path (4). At the time of transmission, the terminal P1 and the terminal P3 are connected to suppress the leakage signal of the transmission signal leaking from the switch 6 in the reverse direction to the forward direction in which the reception signal of the radio frequency band flows in the path (4). To do.

  The amplifier 4 amplifies the radio frequency band signal output from the switch 8 and outputs the amplified signal to the circulator 3.

  The amplifier 5 amplifies the radio frequency signal output from the circulator 3 and outputs the amplified signal to the switch 7.

  The circulator 3 outputs a radio frequency signal output from the amplifier 4 to the transmission / reception antenna 2 during transmission. The circulator 3 outputs a radio frequency signal output from the transmission / reception antenna 2 to the amplifier 5 during reception.

  The transmitting / receiving antenna 2 transmits a signal of a radio frequency band output from the circulator 3 to another communication device at the time of transmission. The transmitting / receiving antenna 2 receives a radio frequency band signal from another communication device and outputs it to the circulator 3 at the time of reception.

(Signal flow during transmission)
During transmission, signals flow in the order of DAC 17 → amplifier 15 → switch 13 → switch 12 → bandpass filter 11 → mixer 10 → bandpass filter 9 → switch 6 → switch 8 → amplifier 4 → circulator 3 → transmission / reception antenna 2.

  Since the two-stage isolation of the switch 12 and the switch 14 (about 50 to 60 dB) is stronger than the isolation of the conventional switch 12 alone (about 25 to 30 dB), the signal leaking to the amplifier 16 is made lower than before. be able to. As a result, the signal leaked to the amplifier 16 can prevent any erroneous processing from occurring in the baseband processing unit.

  In addition, since the two-stage isolation of the switch 6 and the switch 7 (about 50 to 60 dB) is stronger than the isolation of the conventional switch 6 alone (about 25 to 30 dB), the signal leaking to the amplifier 5 is more than conventional. Can be lowered. As a result, it is possible to make it difficult for the amplifier 5 to break down or shorten the life due to the leaked signal.

(Signal flow during reception)
FIG. 2 is a diagram for explaining a signal flow at the time of reception in the radio circuit according to the first embodiment.

  Referring to FIG. 2, at the time of reception, a signal is transmitted to transmission / reception antenna 2 → circulator 3 → amplifier 5 → switch 7 → switch 6 → bandpass filter 9 → mixer 10 → bandpass filter 11 → switch 12 → switch 14 → amplifier 16 → ADC 18. Flows.

  Since the two-stage isolation of the switch 6 and the switch 8 (about 50 to 60 dB) is stronger than the isolation of the conventional switch 6 alone (about 25 to 30 dB), the signal leaking to the amplifier 4 is made lower than before. be able to. This makes it difficult to transmit any meaningless signal from the transmission / reception antenna 2 due to the signal leaking to the amplifier 4.

  Further, the two-stage isolation of the switch 12 and the switch 13 (about 50 to 60 dB) is stronger than the isolation of only the conventional switch 12 (about 25 to 30 dB), so that the signal leaking to the amplifier 15 is more than conventional. Can be lowered. As a result, it is possible to make it difficult for the amplifier 15 to break down or shorten its life due to the leaked signal.

[Modification 1 of the first embodiment]
FIG. 3 is a diagram for explaining the configuration of the radio circuit according to the first modification of the first embodiment and the flow of signals during transmission in the radio circuit.

  The wireless circuit 51 of FIG. 3 does not include the switch 14 and the switch 8 included in the wireless circuit 1 of FIG.

(Signal flow during transmission)
During transmission, signals flow in the order of DAC 17 → amplifier 15 → switch 13 → switch 12 → bandpass filter 11 → mixer 10 → bandpass filter 9 → switch 6 → amplifier 4 → circulator 3 → transmission / reception antenna 2.

  Since the two-stage isolation of the switch 6 and the switch 7 (about 50 to 60 dB) is stronger than the isolation of the conventional switch 6 alone (about 25 to 30 dB), the signal leaking to the amplifier 5 is made lower than before. be able to. As a result, it is possible to make it difficult for the amplifier 5 to break down or shorten the life due to the leaked signal.

  Unlike the first embodiment, the signal leaking from the switch 12 to the amplifier 16 cannot be made lower than in the prior art, but the signal leaking to the amplifier 16 does not adversely affect the baseband processing unit, or has an adverse effect. This is not a problem if measures are taken not to give

(Signal flow during reception)
FIG. 4 is a diagram for explaining a signal flow at the time of reception in the wireless circuit according to the first modification of the first embodiment.

  Referring to FIG. 4, at the time of reception, a signal flows through transmission / reception antenna 2 → circulator 3 → amplifier 5 → switch 7 → switch 6 → bandpass filter 9 → mixer 10 → bandpass filter 11 → switch 12 → amplifier 16 → ADC 18.

  Since the two-stage isolation of the switch 12 and the switch 13 (about 50 to 60 dB) is stronger than the isolation of the conventional switch 12 alone (about 25 to 30 dB), the signal leaking to the amplifier 15 is made lower than before. be able to. As a result, it is possible to make it difficult for the amplifier 15 to break down or shorten its life due to the leaked signal.

  Unlike the first embodiment, the signal leaking from the switch 6 to the amplifier 4 cannot be made lower than in the prior art. However, when the signal leaking to the amplifier 4 does not adversely affect the transmission / reception antenna 2, or It is not a problem if measures are taken to avoid giving.

[Modification 2 of the first embodiment]
FIG. 5 is a diagram for explaining a configuration of a radio circuit according to the second modification of the first embodiment and a signal flow during transmission in the radio circuit.

  The wireless circuit 52 in FIG. 5 does not include the switch 13 and the switch 7 included in the wireless circuit 1 in FIG.

(Signal flow during transmission)
During transmission, signals flow in the order of DAC 17 → amplifier 15 → switch 12 → bandpass filter 11 → mixer 10 → bandpass filter 9 → switch 6 → switch 8 → amplifier 4 → circulator 3 → transmission / reception antenna 2.

  Since the two-stage isolation of the switch 12 and the switch 14 (about 50 to 60 dB) is stronger than the isolation of the conventional switch 12 alone (about 25 to 30 dB), the signal leaking to the amplifier 16 is made lower than before. be able to. As a result, the signal leaked to the amplifier 16 can prevent any erroneous processing from occurring in the baseband processing unit.

  Unlike the first embodiment, the signal leaking from the switch 6 to the amplifier 5 cannot be made lower than in the prior art. However, the amplifier 5 may fail or have a shorter life with respect to the leaked signal. If not, it will not be a problem.

(Signal flow during reception)
FIG. 6 is a diagram for explaining a signal flow at the time of reception in the wireless circuit according to the second modification of the first embodiment.

  Referring to FIG. 6, at the time of reception, a signal flows through transmission / reception antenna 2 → circulator 3 → amplifier 5 → switch 6 → bandpass filter 9 → mixer 10 → bandpass filter 11 → switch 12 → switch 14 → amplifier 16 → ADC 18.

  Since the two-stage isolation of the switch 6 and the switch 8 (about 50 to 60 dB) is stronger than the isolation of the conventional switch 6 alone (about 25 to 30 dB), the signal leaking to the amplifier 4 is made lower than before. be able to. This makes it difficult to transmit any meaningless signal from the transmission / reception antenna 2 due to the signal leaking to the amplifier 4.

  Unlike the first embodiment, the signal leaking from the switch 12 to the amplifier 15 cannot be made lower than in the prior art. However, the amplifier 15 may fail or have a shorter lifetime with respect to the leaked signal. If not, it will not be a problem.

[Second Embodiment]
FIG. 7 is a diagram for explaining the configuration of the radio circuit according to the second embodiment and the flow of signals during transmission in the radio circuit.

  The radio circuit 53 of FIG. 7 includes a circulator 33 and a circulator 32 instead of the switch 13, the switch 14, the switch 8, and the switch 7 included in the radio circuit 1 of FIG. 1.

  The circulator 33 has a terminal P1, a terminal P2, and a terminal P3. The terminal P1 and the terminal P2 are on the path (1). The terminal P2 is closer to the switch 12 than the terminal P1. The terminal P3 is connected to the fixed potential by being connected to the ground via the resistor R. At the time of transmission, the transmission signal in the intermediate frequency band input to the terminal P1 is output from the terminal P2, so that the transmission signal in the intermediate frequency band flows through the path (1). During reception, the leakage signal of the reception signal leaked from the switch 12 input to the terminal P2 is suppressed from being output from the terminal P1, so that the transmission signal in the intermediate frequency band flows in the path (1). In the opposite direction, the leakage signal of the reception signal leaking from the switch 12 is prevented from flowing.

  The circulator 32 has a terminal P1, a terminal P2, and a terminal P3. The terminal P1 and the terminal P2 are on the path (4). The terminal P2 is closer to the switch 6 than the terminal P1. The terminal P3 is connected to the fixed potential by being connected to the ground via the resistor R. At the time of reception, the reception signal in the radio frequency band input to the terminal P1 is output from the terminal P2, so that the reception signal in the radio frequency band flows through the path (4). During transmission, the leakage signal of the transmission signal leaked from the switch 6 input to the terminal P2 is suppressed from being output from the terminal P1, so that the reception signal in the radio frequency band flows in the path (4). In the opposite direction, the leakage signal of the transmission signal leaked from the switch 6 is prevented from flowing.

(Signal flow during transmission)
During transmission, signals flow in the order of DAC 17 → amplifier 15 → circulator 33 → switch 12 → bandpass filter 11 → mixer 10 → bandpass filter 9 → switch 6 → amplifier 4 → circulator 3 → transmission / reception antenna 2.

  Since the two-stage isolation of the switch 6 and the circulator 32 (about 50 to 60 dB) is stronger than the isolation of the conventional switch 6 alone (about 25 to 30 dB), the signal leaking to the amplifier 5 is made lower than before. be able to. As a result, it is possible to make it difficult for the amplifier 5 to break down or shorten the life due to the leaked signal.

  Unlike the first embodiment, the signal leaking from the switch 12 to the amplifier 16 cannot be made lower than in the prior art, but the signal leaking to the amplifier 16 does not adversely affect the baseband processing unit, or has an adverse effect. This is not a problem if measures are taken not to give

(Signal flow during reception)
FIG. 8 is a diagram for explaining a signal flow at the time of reception in the radio circuit according to the second embodiment.

  Referring to FIG. 8, at the time of reception, a signal flows through transmission / reception antenna 2 → circulator 3 → amplifier 5 → circulator 32 → switch 6 → bandpass filter 9 → mixer 10 → bandpass filter 11 → switch 12 → amplifier 16 → ADC 18.

  Since the two-stage isolation of the switch 12 and the circulator 33 (about 50 to 60 dB) is stronger than the isolation of the conventional switch 12 alone (about 25 to 30 dB), the signal leaking to the amplifier 15 is made lower than before. be able to. As a result, it is possible to make it difficult for the amplifier 15 to break down or shorten its life due to the leaked signal.

  Unlike the first embodiment, the signal leaking from the switch 6 to the amplifier 4 cannot be made lower than in the prior art. However, when the signal leaking to the amplifier 4 does not adversely affect the transmission / reception antenna 2, or It is not a problem if measures are taken to avoid giving.

[Third Embodiment]
FIG. 9 is a diagram for explaining the configuration of the wireless circuit according to the third embodiment.

  The wireless circuit 54 includes a circulator 37 instead of the switch 12 included in the wireless circuit 1 of FIG. 1 and includes a circulator 38 instead of the switch 6.

  The circulator 37 has a terminal P1, a terminal P2, and a terminal P3. The terminal P1 is connected to the mixer 10 via the band pass filter 11. Terminal P3 is connected to path (1). The terminal P2 is connected to the path (2). At the time of transmission, the transmission signal in the intermediate frequency band input to the terminal P3 is output from the terminal P1, so that the mixer 10 is connected to the path (1) via the bandpass filter 11. At the time of reception, the received signal in the intermediate frequency band input to the terminal P1 is output from the terminal P2, so that the mixer 10 is connected to the path (2) via the bandpass filter 11.

  The circulator 38 has a terminal P1, a terminal P2, and a terminal P3. The terminal P1 is connected to the mixer 10 via the band pass filter 9. The terminal P2 is connected to the path (3). The terminal P3 is connected to the route (4). At the time of transmission, the transmission signal in the radio frequency band input to the terminal P1 is output from the terminal P2, so that the mixer 10 is connected to the path (3) via the bandpass filter 9. At the time of reception, the reception signal in the radio frequency band input to the terminal P3 is output from the terminal P1, so that the mixer 10 is connected to the path (4) via the bandpass filter 9.

(Signal flow during transmission)
During transmission, signals flow in the order of DAC 17 → amplifier 15 → switch 13 → circulator 37 → bandpass filter 11 → mixer 10 → bandpass filter 9 → circulator 38 → switch 8 → amplifier 4 → circulator 3 → transmission / reception antenna 2.

  Since the two-stage isolation of the circulator 37 and the switch 14 (about 50 to 60 dB) is stronger than the isolation of only the conventional switch 12 (about 25 to 30 dB), the signal leaking to the amplifier 16 is made lower than before. be able to. As a result, the signal leaked to the amplifier 16 can prevent any erroneous processing from occurring in the baseband processing unit.

  Further, the two-stage isolation (about 50 to 60 dB) of the circulator 38 and the switch 7 is stronger than the isolation of only the conventional switch 6 (about 25 to 30 dB), so that the signal leaking to the amplifier 5 is more than conventional. Can be lowered. As a result, it is possible to make it difficult for the amplifier 5 to break down or shorten the life due to the leaked signal.

(Signal flow during reception)
At the time of reception, a signal flows through the transmission / reception antenna 2 → circulator 3 → amplifier 5 → switch 7 → circulator 38 → bandpass filter 9 → mixer 10 → bandpass filter 11 → circulator 37 → switch 14 → amplifier 16 → ADC 18.

  The two-stage isolation of the circulator 38 and the switch 8 (about 50 to 60 dB) is stronger than the isolation of only the conventional switch 6 (about 25 to 30 dB), so that the signal leaking to the amplifier 4 is lower than the conventional one. be able to. This makes it difficult to transmit any meaningless signal from the transmission / reception antenna 2 due to the signal leaking to the amplifier 4.

  Further, the two-stage isolation (about 50 to 60 dB) of the circulator 37 and the switch 13 is stronger than the isolation of only the conventional switch 12 (about 25 to 30 dB). Can be lowered. As a result, it is possible to make it difficult for the amplifier 15 to break down or shorten its life due to the leaked signal.

[Fourth Embodiment]
FIG. 10 is a diagram for explaining the configuration of the wireless circuit according to the fourth embodiment.

  The wireless circuit 55 includes a circulator 37 instead of the switch 12 of the wireless circuit 53 of FIG. 7 and includes a circulator 38 instead of the switch 6.

(Signal flow during transmission)
During transmission, signals flow in the order of DAC 17 → amplifier 15 → circulator 33 → circulator 37 → bandpass filter 11 → mixer 10 → bandpass filter 9 → circulator 38 → amplifier 4 → circulator 3 → transmission / reception antenna 2.

  The two-stage isolation (about 50 to 60 dB) of the circulator 38 and the circulator 32 is stronger than the isolation of only the conventional switch 6 (about 25 to 30 dB), so that the signal leaking to the amplifier 5 is made lower than before. be able to. As a result, it is possible to make it difficult for the amplifier 5 to break down or shorten the life due to the leaked signal.

  Unlike the third embodiment, the signal leaking from the circulator 37 to the amplifier 16 cannot be made lower than in the past, but the signal leaking to the amplifier 16 does not adversely affect the baseband processing unit, or has an adverse effect. This is not a problem if measures are taken not to give

(Signal flow during reception)
During reception, a signal flows through the transmission / reception antenna 2 → circulator 3 → amplifier 5 → circulator 32 → circulator 38 → bandpass filter 9 → mixer 10 → bandpass filter 11 → circulator 37 → amplifier 16 → ADC 18.

  The two-stage isolation (about 50 to 60 dB) of the circulator 37 and the circulator 33 is stronger than the isolation of only the conventional switch 12 (about 25 to 30 dB), so that the signal leaking to the amplifier 15 is made lower than before. be able to. As a result, it is possible to make it difficult for the amplifier 15 to break down or shorten its life due to the leaked signal.

  Unlike the first embodiment, the signal leaking from the circulator 38 to the amplifier 4 cannot be made lower than in the past, but if the signal leaking to the amplifier 4 does not adversely affect the transmission / reception antenna 2, It is not a problem if measures are taken to avoid giving.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  1, 51, 52, 53, 54, 55, 56 Radio circuit, 2 Transmit / receive antenna, 3, 32, 33, 37, 38 Circulator, 4, 5, 15, 16 Amplifier, 6, 7, 8, 12, 13, 14 switches, 9, 11 bandpass filter, 10 mixer, 17 DAC, 18 ADC, 81 local oscillator.

Claims (13)

The transmission signal of the intermediate frequency band and the local oscillation signal are mixed at the time of transmission and converted into the transmission signal of the radio frequency band, and the reception signal and the local oscillation signal of the radio frequency band are mixed at the time of reception to obtain the intermediate frequency band. A mixer for converting the received signal to
Provided at the intersection of the first path, which is the path of the transmission signal in the intermediate frequency band, and the second path, which is the path of the reception signal in the intermediate frequency band, and connects the first path and the mixer during transmission A first path control element that connects the second path and the mixer during reception;
Provided at the intersection of the third path, which is the path of the transmission signal in the radio frequency band, and the fourth path, which is the path of the reception signal in the radio frequency band, and connects the third path and the mixer during transmission. A second path control element connecting the fourth path and the mixer at the time of reception;
A third path control element that is provided on the first path and suppresses a signal flow in a direction opposite to a direction in which the transmission signal of the intermediate frequency band flows;
A radio circuit comprising a fourth path control element provided on the fourth path and suppressing a signal flow in a direction opposite to a direction in which a reception signal of the radio frequency band flows. The first path control element has a first terminal connected to the mixer, a second terminal connected to the first path, and a third terminal connected to the second path. Switch,
The wireless circuit according to claim 1, wherein the first terminal and the second terminal are connected during transmission, and the first terminal and the third terminal are connected during reception. The second path control element has a first terminal connected to the mixer, a second terminal connected to the third path, and a third terminal connected to the fourth path. Switch,
The wireless circuit according to claim 1, wherein the first terminal and the second terminal are connected during transmission, and the first terminal and the third terminal are connected during reception. The third path control element is a switch having a first terminal on the first path, a second terminal on the first path, and a third terminal connected to a fixed potential; The first terminal is closer to the first path control element than the second terminal,
The wireless circuit according to claim 1, wherein the first terminal and the second terminal are connected during transmission, and the first terminal and the third terminal are connected during reception. The fourth path control element is a switch having a first terminal on the fourth path, a second terminal on the fourth path, and a third terminal connected to a fixed potential; The first terminal is closer to the third path control element than the second terminal,
The wireless circuit according to claim 1, wherein the first terminal and the second terminal are connected during reception, and the first terminal and the third terminal are connected during transmission.   The first path control element has a first terminal connected to the mixer, a second terminal connected to the second path, and a third terminal connected to the first path. 2. The circulator, wherein a signal input to the third terminal is output from the first terminal, and a signal input to the first terminal is output from the second terminal. The described radio circuit.   The second path control element has a first terminal connected to the mixer, a second terminal connected to the third path, and a third terminal connected to the fourth path. 2. The circulator, wherein a signal input to the first terminal is output from the second terminal, and a signal input to the third terminal is output from the first terminal. The described radio circuit. The third path control element is a circulator having a first terminal on the first path, a second terminal on the first path, and a third terminal, and the second terminal Is closer to the first path control element than the first terminal,
The radio circuit according to claim 1, wherein the signal input to the first terminal is output from the second terminal. The fourth path control element is a circulator having a first terminal on the fourth path, a second terminal on the fourth path, and a third terminal, and the second terminal Is closer to the third path control element than the first terminal,
The radio circuit according to claim 1, wherein the signal input to the first terminal is output from the second terminal. The radio circuit further includes:
A fifth path control element that is provided on the second path and suppresses a signal flow in a direction opposite to a direction in which the reception signal of the intermediate frequency band flows;
The radio circuit according to claim 1, further comprising: a sixth path control element that is provided on the third path and suppresses a signal flow in a direction opposite to a direction in which the transmission signal of the radio frequency band flows. The fifth path control element is a switch having a first terminal on the second path, a second terminal on the second path, and a third terminal connected to a fixed potential; The first terminal is closer to the first path control element than the second terminal,
The wireless circuit according to claim 10, wherein the first terminal and the second terminal are connected during reception, and the first terminal and the third terminal are connected during transmission. The sixth path control element is a switch having a first terminal on the third path, a second terminal on the third path, and a third terminal connected to a fixed potential; The first terminal is closer to the third path control element than the second terminal,
The wireless circuit according to claim 10, wherein, during transmission, the first terminal and the second terminal are connected, and the first terminal and the third terminal are connected to a reception path. The transmission signal of the intermediate frequency band and the local oscillation signal are mixed at the time of transmission and converted into the transmission signal of the radio frequency band, and the reception signal and the local oscillation signal of the radio frequency band are mixed at the time of reception to obtain the intermediate frequency band. A mixer for converting the received signal to
Provided at the intersection of the first path, which is the path of the transmission signal in the intermediate frequency band, and the second path, which is the path of the reception signal in the intermediate frequency band, and connects the first path and the mixer during transmission A first path control element that connects the second path and the mixer during reception;
Provided at the intersection of the third path, which is the path of the transmission signal in the radio frequency band, and the fourth path, which is the path of the reception signal in the radio frequency band, and connects the third path and the mixer during transmission. A second path control element connecting the fourth path and the mixer at the time of reception;
A fifth path control element that is provided on the second path and suppresses a signal flow in a direction opposite to a direction in which the reception signal of the intermediate frequency band flows;
A radio circuit comprising a sixth path control element that is provided on the third path and suppresses a signal flow in a direction opposite to a direction in which a transmission signal of the radio frequency band flows.

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