CN214959528U - High-frequency signal transceiving circuit - Google Patents
High-frequency signal transceiving circuit Download PDFInfo
- Publication number
- CN214959528U CN214959528U CN202120673912.0U CN202120673912U CN214959528U CN 214959528 U CN214959528 U CN 214959528U CN 202120673912 U CN202120673912 U CN 202120673912U CN 214959528 U CN214959528 U CN 214959528U
- Authority
- CN
- China
- Prior art keywords
- frequency
- signal
- reception
- band
- filter
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
Images
Landscapes
- Transceivers (AREA)
Abstract
The utility model provides a high frequency signal transceiver circuit of influence between suppression signal. Comprises the following steps: a power amplifier; a transmission band-pass filter for passing a high-frequency input signal; a1 st reception band-pass filter for passing a1 st high-frequency reception signal; a1 st low noise amplifier for amplifying the 1 st high frequency reception signal and outputting a1 st high frequency output signal; a1 st transmission/reception filter having one end electrically connected to the 1 st antenna terminal, passing the high-frequency input signal and the 1 st high-frequency reception signal therethrough, and attenuating a high-frequency signal having at least a part of frequencies different from the frequencies of the high-frequency input signal and the 1 st high-frequency reception signal; and a switch for electrically connecting the other ends of the transmission bandpass filter and the 1 st transmission/reception filter when outputting the high-frequency input signal to the 1 st antenna terminal as a high-frequency transmission signal, and for electrically connecting the other ends of the 1 st reception bandpass filter and the 1 st transmission/reception filter when receiving the 1 st high-frequency reception signal from the 1 st antenna terminal.
Description
Technical Field
The utility model relates to a high frequency signal transceiver circuit.
Background
A mobile communication device exemplified by a mobile phone device uses a front-end circuit that outputs a high-frequency transmission signal to an antenna and receives a high-frequency reception signal from the antenna.
Currently, a 5 th generation mobile communication system (5G) is being put into practical use. Suppression of the influence between the 5G signal and other (4 th generation mobile communication system (4G), WiFi, etc.) signals is required.
SUMMERY OF THE UTILITY MODEL
Problem to be solved by utility model
The present invention has been made in view of the above circumstances, and an object of the present invention is to suppress influence between signals.
Means for solving the problems
(1) The utility model discloses a high frequency signal transceiver circuit of an aspect's characterized in that contains: a power amplifier which amplifies the high frequency input signal; a transmission band-pass filter that passes the high-frequency input signal amplified by the power amplifier; a1 st reception band-pass filter for passing a1 st high-frequency reception signal; a1 st low noise amplifier for amplifying the 1 st high frequency reception signal passed through the 1 st reception band-pass filter and outputting a1 st high frequency output signal; a1 st transmission/reception filter having one end electrically connected to the 1 st antenna terminal, passing the high-frequency input signal and the 1 st high-frequency reception signal therethrough, and attenuating a high-frequency signal having at least a part of a frequency different from the frequencies of the high-frequency input signal and the 1 st high-frequency reception signal; and a switch for electrically connecting the other ends of the transmission bandpass filter and the 1 st transmission/reception filter when outputting the high-frequency input signal to the 1 st antenna terminal as a high-frequency transmission signal, and for electrically connecting the other ends of the 1 st reception bandpass filter and the 1 st transmission/reception filter when receiving the 1 st high-frequency reception signal from the 1 st antenna terminal.
(2) In the high-frequency signal transmission/reception circuit described in (1), the high-frequency input signal and the 1 st high-frequency reception signal may be high-frequency signals of a band n79 of the 5 th generation mobile communication system, and the 1 st transmission/reception filter may pass the high-frequency input signal and the 1 st high-frequency reception signal and attenuate high-frequency signals from a lower limit frequency of the 5GHz band of IEEE802.11 to a predetermined frequency.
(3) In the high-frequency signal transmission/reception circuit according to (2), the 1 st transmission/reception filter may be a low-pass filter or a notch filter.
(4) The high-frequency signal transmission/reception circuit according to any one of (1) to (3) above, further comprising: a2 nd reception band-pass filter for passing the 2 nd high-frequency reception signal; a2 nd low noise amplifier for amplifying the 2 nd high frequency reception signal passed through the 2 nd reception band-pass filter and outputting a2 nd high frequency output signal; and a2 nd transmission/reception filter having one end electrically connected to the 2 nd antenna terminal, passing the high frequency input signal and the 2 nd high frequency reception signal, and attenuating a high frequency signal having at least a part of a frequency different from the frequencies of the high frequency input signal and the 2 nd high frequency reception signal, wherein the switch electrically connects the other end of the transmission bandpass filter and the other end of the 2 nd transmission/reception filter when outputting the high frequency input signal to the 2 nd antenna terminal as a high frequency transmission signal, and the switch electrically connects the other end of the 2 nd reception bandpass filter and the other end of the 2 nd transmission/reception filter when receiving the 2 nd high frequency reception signal from the 2 nd antenna terminal.
(5) In the high-frequency signal transmission/reception circuit described in (4), the high-frequency input signal and the 2 nd high-frequency reception signal may be high-frequency signals of a band n79 of the 5 th generation mobile communication system, and the 2 nd transmission/reception filter may pass the high-frequency input signal and the 2 nd high-frequency reception signal and attenuate high-frequency signals having a frequency from a lower limit frequency of the 5GHz band of IEEE802.11 to a predetermined frequency.
(6) In the high-frequency signal transmission/reception circuit according to (5), the 2 nd transmission/reception filter may be a low-pass filter or a notch filter.
Effect of the utility model
According to the utility model discloses, can restrain the influence between the signal.
Drawings
Fig. 1 is a diagram showing a configuration of a high-frequency signal transmitting/receiving circuit of a comparative example.
Fig. 2 is a diagram showing a state at the time of reception of the high-frequency signal transmitting/receiving circuit of the comparative example.
Fig. 3 is a diagram showing frequency bands of a high-frequency signal of a frequency Band n77 of 5G and high-frequency signals of an uplink of each of Band3 and Band1 of 4G.
Fig. 4 is a diagram showing a circuit simulation result of the high-frequency signal transmission/reception circuit of the comparative example.
Fig. 5 is a diagram showing the configuration of the high-frequency signal transmission/reception circuit according to embodiment 1.
Fig. 6 is a diagram showing a circuit simulation result of the high-frequency signal transmission/reception circuit according to embodiment 1.
Fig. 7 is a diagram showing a circuit simulation result of the high-frequency signal transmission/reception circuit according to embodiment 1.
Fig. 8 is a diagram showing a state in the transmission of the high-frequency signal transmitting/receiving circuit of the comparative example.
Fig. 9 is a diagram showing frequency bands of a high-frequency signal of a frequency band n79 of 5G and a high-frequency signal of a 5GHz band of WiFi.
Fig. 10 is a diagram showing the configuration of the high-frequency signal transmission/reception circuit according to embodiment 2.
Fig. 11 is a diagram showing a circuit simulation result of the high-frequency signal transmission/reception circuit according to embodiment 2.
Fig. 12 is a diagram showing an example of the layout of the high-frequency signal transmission/reception circuit according to embodiment 3.
Fig. 13 is a diagram showing an example of a state in which the high-frequency signal transmitting/receiving circuit according to embodiment 3 transmits signals.
Fig. 14 is a diagram showing an example of a state of the high-frequency signal transmission/reception circuit according to embodiment 3 at the time of reception.
Description of the reference numerals
1. 1A, 10: a high-frequency signal transmitting/receiving circuit;
2: a control unit;
ANT1, ANT 2: an antenna;
BPF1, BPF2, BPF 3: a band-pass filter;
CPL: a coupler;
HPF1, HPF 2: a high-pass filter;
LNA1, LNA 2: a low noise amplifier;
LPF1, LPF 2: a low-pass filter;
PA: a power amplifier;
SW: and (4) switching.
Detailed Description
Hereinafter, embodiments of the high-frequency signal transmitting/receiving circuit according to the present invention will be described in detail with reference to the drawings. The present invention is not limited to the embodiment. It is needless to say that the respective embodiments are examples, and partial replacement or combination of the structures described in the different embodiments can be performed. In embodiment 2 and thereafter, descriptions of common matters with embodiment 1 are omitted, and only differences will be described. In particular, the same operational effects based on the same structure will not be mentioned in each embodiment.
< embodiment 1 and comparative example >
Hereinafter, embodiment 1 will be described, but comparative examples will be described to make embodiment 1 easier to understand.
Comparative example
Fig. 1 is a diagram showing a configuration of a high-frequency signal transmitting/receiving circuit of a comparative example. The high-frequency signal transmission/reception circuit 10 is a front-end module (front-end circuit) 1 upstream (upstream) and downstream (downstream) that can output a high-frequency transmission signal Tx to the antennas ANT1 and ANT2 and receive high-frequency reception signals Rx1 and Rx2 from the antennas ANT1 and ANT2 in a mobile communication device exemplified by a mobile phone device. The high-frequency signal transmission/reception circuit 10 may be implemented by a hybrid IC in which a plurality of components (semiconductor integrated circuits and the like) are mounted on one substrate, but the present disclosure is not limited thereto.
The high-frequency reception signal Rxl corresponds to the "1 st high-frequency reception signal" of the present disclosure. The high-frequency reception signal Rx2 corresponds to the "2 nd high-frequency reception signal" of the present disclosure.
The high-frequency signal transmission/reception circuit 10 includes a control unit 2, a power amplifier PA, low noise amplifiers LNA1 and LNA2, band pass filters BPF1, BPF2 and BPF3, a coupler CPL, and a switch SW. The control unit 2 controls the power amplifier PA, the low noise amplifiers LNA1 and LNA2, the coupler CPL, and the switch SW.
The low noise amplifier LNA1 corresponds to the "1 st low noise amplifier" of the present disclosure. The low noise amplifier LNA2 corresponds to the "2 nd low noise amplifier" of the present disclosure. The band pass filter BPF1 corresponds to the "transmission band pass filter" of the present disclosure. The band pass filter BPF2 corresponds to the "1 st reception band pass filter" of the present disclosure. The band pass filter BPF3 corresponds to the "2 nd reception band pass filter" of the present disclosure.
The power amplifier PA amplifies a high-frequency input signal RFIN input from a circuit (for example, RFIC) of a preceding stage to the terminal 11, and outputs to the band-pass filter BPF 1.
The band-pass filter BPF1 passes the high-frequency input signal RFIN amplified by the power amplifier PA and outputs to the coupler CPL. The coupler CPL detects the high-frequency input signal RFIN passing through the bandpass filter BPF1, and outputs a detection signal CPL _ OUT from the terminal 14. The high-frequency input signal RFIN that has passed through the coupler CPL is input to the terminal 21 of the switch SW.
The switch SW includes terminals 21, 22 and 23 of group 1 and terminals 24, 25 and 26 of group 2. The switch SW electrically connects the 1 st group of terminals 21, 22 and 23 and the 2 nd group of terminals 24, 25 and 26.
The terminal 24 of the switch SW is electrically connected to the antenna ANT1 through the 1 st antenna terminal 15. The terminal 26 of the switch SW is electrically connected to the antenna ANT2 through the 2 nd antenna terminal 17. Terminal 25 of switch SW is electrically connected to terminal 16.
In the case of transmitting the high-frequency transmission signal Tx, the switch SW electrically connects the terminal 21 with the terminal 24 or the terminal 26. When an SRS (Sounding Reference Signal) Signal is transmitted, the switch SW electrically connects the terminal 21 and the terminal 25.
When the switch SW electrically connects the terminal 21 and the terminal 24, the high-frequency input signal RFIN passing through the coupler CPL is output as a high-frequency transmission signal Tx to the antenna ANT1 via the terminal 21, the terminal 24, and the 1 st antenna terminal 15.
When the switch SW electrically connects the terminal 21 and the terminal 26, the high-frequency input signal RFIN passing through the coupler CPL is output as a high-frequency transmission signal Tx to the antenna ANT2 via the terminal 21, the terminal 26, and the 2 nd antenna terminal 17.
When receiving the high-frequency reception signals Rx1 and Rx2, the switch SW electrically connects the terminal 22 and the terminal 24, and electrically connects the terminal 23 and the terminal 26.
In a case where the switch SW electrically connects the terminal 22 and the terminal 24, a high-frequency reception signal Rx1 received by the antenna ANT1 is input to the band-pass filter BPF2 via the 1 st antenna terminal 15, the terminal 24, and the terminal 22. The band-pass filter BPF2 passes the high-frequency reception signal Rx1 and outputs to the low noise amplifier LNA 1. The low noise amplifier LNA1 amplifies the high frequency reception signal Rx1 passed through the band pass filter BPF2 and outputs it as a high frequency output signal RFOUT1 from the terminal 12.
The high frequency output signal RFOUT1 corresponds to the "1 st high frequency output signal" of the present disclosure.
In the case where the switch SW electrically connects the terminal 23 and the terminal 26, a high-frequency reception signal Rx2 received by the antenna ANT2 is input to the band-pass filter BPF3 via the 2 nd antenna terminal 17, the terminal 26, and the terminal 23. The band-pass filter BPF3 passes the high-frequency reception signal Rx2 and outputs to the low noise amplifier LNA 2. The low noise amplifier LNA2 amplifies the high frequency reception signal Rx2 having passed through the band pass filter BPF3 and outputs the amplified signal as a high frequency output signal RFOUT2 from the terminal 13.
The high frequency output signal RFOUT2 corresponds to the "2 nd high frequency output signal" of the present disclosure.
Fig. 2 is a diagram showing a state at the time of reception of the high-frequency signal transmitting/receiving circuit of the comparative example. In detail, fig. 2 is a diagram showing a state of the high-frequency signal transmission/reception circuit 10 when the antenna ANT1 receives the radio wave 31 of the frequency band n77 of the 5 th generation mobile communication system (5G). The frequency of the radio wave 31 of the frequency band n77 of 5G is 3300MHz (megahertz) to 4200 MHz. Arrow 41 shows the receive signal path. In addition, the frequency of the band n77 overlaps with the frequencies of the 4 th generation bands 42, 43, 48.
The antenna ANT1 receives the radio wave 31 and outputs a high-frequency reception signal Rx1 to the 1 st antenna terminal 15. At this time, the antenna ANT1 also receives the uplink radio wave 32 of the Band3 and the uplink radio wave 33 of the Band1 of the 4 th generation mobile communication system (4G). The frequency of the uplink electric wave 32 of Band3 of 4G is 1710MHz to 1785 MHz. The frequency of the uplink electric wave 33 of the Band1 of 4G is 1920MHz to 1980 MHz. The uplink radio wave 32 of the Band3 of 4G and the uplink radio wave 33 of the Band1 may be radio waves transmitted from the own apparatus or radio waves transmitted from another apparatus.
A high-frequency reception signal Rx1 including a high-frequency signal of a frequency Band n77 of 5G and high-frequency signals of an uplink of each of Band1 and Band3 of 4G is input to the Band-pass filter BPF2 via the 1 st antenna terminal 15, the terminal 24, and the terminal 22. The band-pass filter BPF2 passes the high-frequency reception signal Rx1 and outputs to the low noise amplifier LNA 1. The low noise amplifier LNA1 amplifies the high frequency reception signal Rx1 passed through the band pass filter BPF2 and outputs it as a high frequency output signal RFOUT1 from the terminal 12.
In the low noise amplifier LNA1, harmonics may be generated due to distortion of a signal caused by a nonlinear element or the like. The harmonics include, for example, the 2 nd harmonic of the uplink high-frequency signal of Band3 of 4G and the 2 nd harmonic of the uplink high-frequency signal of Band1 of 4G. The frequency of 2 th harmonic of the high frequency signal of the uplink of Band3 of 4G is 3420MHz to 3570 MHz. The frequency of 2 th harmonic of the high frequency signal of the uplink of Band1 of 4G is 3840MHz to 3960 MHz. Harmonics are generated in the low noise amplifier LNA1 as indicated by arrow 42 and output from terminal 12.
The high frequency output signal RFOUT1 output from the terminal 12 contains 2 nd harmonics of the high frequency signal of Band n77 of 5G and the high frequency signal of uplink of Band1 and Band3 of 4G.
Fig. 3 is a diagram showing frequency bands of a high-frequency signal of a frequency Band n77 of 5G and high-frequency signals of an uplink of each of Band3 and Band1 of 4G.
The frequency band 51 shows the frequency band of the high-frequency signal of the frequency band n77 of 5G. Band 51 is 3300MHz to 4200 MHz.
As shown in fig. 3, bands 54 and 55 are included in band 51. That is, the Band of the 2 nd harmonic of the uplink high-frequency signal of each of Band3 and Band1 of 4G is included in the Band of the high-frequency signal of Band n77 of 5G. In other words, the high-frequency output signal RFOUT1 includes, as unwanted signals (noise), 2 nd harmonics of the uplink high-frequency signals of Band3 and Band1 of 4G, respectively. Therefore, the reception sensitivity of the circuit in the preceding stage receiving the high-frequency output signal RFOUT1 output from the terminal 12 is lowered.
Fig. 4 is a diagram showing a circuit simulation result of the high-frequency signal transmission/reception circuit of the comparative example. In detail, fig. 4 is a diagram showing the S parameter of the band pass filter BPF2 of the high frequency signal transmission/reception circuit 10 of the comparative example.
The band pass filter BPF2 attenuates the signal in band 62 to the extent of-50 dB to-65 dB. However, the high frequency signal transmission/reception circuit 10 preferably attenuates the signal in the frequency band 62 further. For example, the high-frequency signal transmission/reception circuit 10 preferably attenuates the signal in the frequency band 62 to a level of-70 dB or more.
(embodiment 1)
Fig. 5 is a diagram showing the configuration of the high-frequency signal transmission/reception circuit according to embodiment 1.
Among the components of the high-frequency signal transmission/reception circuit 1, the same components as those of the high-frequency signal transmission/reception circuit 10 of the comparative example are denoted by the same reference numerals, and description thereof is omitted. The high-frequency signal transmission/reception circuit 1 may be implemented by a hybrid IC in which a plurality of components (semiconductor integrated circuits and the like) are mounted on one substrate, but the present disclosure is not limited thereto.
The high-frequency signal transmission/reception circuit 1 according to embodiment 1 further includes high-pass filters HPF1 and HPF2, as compared with the high-frequency signal transmission/reception circuit 10 according to the comparative example.
In embodiment 1, the high-frequency signal transmission/reception circuit 1 further includes the high-pass filters HPF1 and HPF2, but the present disclosure is not limited thereto. The high frequency signal transceiver circuit 1 may include two notch filters (band elimination filters) instead of the high pass filters HPF1 and HPF 2.
The high pass filter HPF1 (or notch filter) is equivalent to the "1 st transceiver filter" of the present disclosure. The high pass filter HPF2 (or notch filter) is equivalent to the "2 nd transceiver filter" of the present disclosure.
The high pass filters HPF1 and HPF2 are each an LC multilayer filter, but the present disclosure is not limited thereto. The high pass filters HPF1 and HPF2 may each also be IPDs (Integrated Passive devices). The LC multilayer filter is a component having a filter function, for example, which is formed by laminating via electrodes, wirings, and parallel plates using low temperature co-fired ceramic (LTCC) or the like, and is used as an inductor or a capacitor. The LC multilayer filter includes a case of being formed of IPD.
The high pass filter HPF1 is electrically connected between the terminal 24 and the 1 st antenna terminal 15. The high pass filter HPF2 is electrically connected between terminal 26 and the 2 nd antenna terminal 17.
Each of the high-pass filters HPF1 and HPF2 preferably passes a high-frequency signal of Band n77 of 5G and attenuates a high-frequency signal of an uplink of Band3 and Band1 of 4G. That is, the high-pass filters HPF1 and HPF2 preferably pass high-frequency signals of Band n77 of 5G (3300MHz to 4200MHz), and attenuate high-frequency signals of uplink of Band3 of 4G (1710MHz to 1785MHz) and high-frequency signals of uplink of Band1 of 4G (1920MHz to 1980MHz), respectively.
When the high frequency signal transceiver circuit 1 includes two notch filters instead of the high pass filters HPF1 and HPF2, each notch filter preferably attenuates the high frequency signal (1710MHz to 1785MHz) of the uplink of the 4G Band3 and the high frequency signal (1920MHz to 1980MHz) of the uplink of the 4G Band 1.
Fig. 6 is a diagram showing a circuit simulation result of the high-frequency signal transmission/reception circuit according to embodiment 1. In detail, fig. 6 is a diagram showing the S parameter of the high-pass filter HPF1 of the high-frequency signal transceiver circuit 1. The same applies to the S parameter of the high pass filter HPF 2.
Both in the case where the high-pass filter HPF1 is constituted by an LC multilayer filter (line 71) and in the case where the high-pass filter HPF1 is constituted by an SMD (line 72), the high-frequency signals of the uplink of Band3 of 4G (1710MHz to 1785MHz) and the high-frequency signals of the uplink of Band1 of 4G (1920MHz to 1980MHz) can be attenuated by-30 dB to the maximum.
However, when the high pass filter HPF1 is formed by the SMD (line 72), the high frequency signal of the 5G band n77 (3300MHz to 4200MHz) is attenuated by-3.29 dB at 3300MHz and by-1.76 dB at 4200 MHz.
On the other hand, when the high-pass filter HPF1 is formed by an LC multilayer filter (line 71), the attenuation of the high-frequency signal (3300MHz to 4200MHz) of the frequency band n77 of 5G can be suppressed to about-0.3 dB.
Therefore, each of the high-pass filters HPF1 and HPF2 is preferably formed of an LC multilayer filter.
Even when the high-pass filters HPF1 and HPF2 are formed of IPD, the characteristics of the filters are preferably the same as those of the LC multilayer filter.
Fig. 7 is a diagram showing a circuit simulation result of the high-frequency signal transmission/reception circuit according to embodiment 1. In detail, fig. 7 is a diagram showing the S parameter of the reception path of the high-frequency reception signal Rx1 including the high-pass filter HPF1 and the band-pass filter BPF2 of the high-frequency signal transceiving circuit 1. The same applies to the S-parameters of the reception path of the high-frequency reception signal Rx2 including the high-pass filter HPF2 and the band-pass filter BPF 3.
The phase of the high-pass filter HPF1 and the phase of the band-pass filter BPF2 have a dependency on each other. Likewise, the phase of the high-pass filter HPF2 and the phase of the band-pass filter BPF3 have a dependency on each other. Fig. 7 shows S parameters after adjusting the respective phases of the high-pass filters HPF1 and HPF2, and the band-pass filters BPF2 and BPF 3.
A line 81 shows the S parameters of the reception path of the high frequency reception signal Rx1, i.e., the high pass filter HPF1 and the band pass filter BPF 2. Line 82 shows the lower frequency limit (1710MHz) for the uplink of Band3 for 4G. Line 83 shows the upper frequency limit of the uplink of Band1 for 4G (1980 MHz).
As shown by line 81, the high pass filter HPF1 and the Band pass filter BPF2 attenuate the high frequency signal of the 4G Band3 uplink and the high frequency signal of the 4G Band1 uplink by a degree of-80 dB to-90 dB.
Therefore, the high-frequency signal transceiver circuit 1 can suppress the signal levels of the high-frequency signal of the uplink of Band3 of 4G and the high-frequency signal of the uplink of Band1 of 4G, from among the high-frequency reception signals Rx 1. Thus, the high-frequency signal transmission/reception circuit 1 can suppress signal levels of the 2 nd harmonic of the high-frequency signal in the uplink of Band3 of 4G and the 2 nd harmonic of the high-frequency signal in the uplink of Band1 of 4G, which may be generated in the low noise amplifiers LNA1 and LNA 2. Thus, the high-frequency signal transmission/reception circuit 1 can suppress a decrease in the reception sensitivity of the circuit at the preceding stage.
In addition, it is also conceivable to configure the high-pass filter HPF1 between the low-noise amplifier LNA1 and the band-pass filter BPF2 or between the band-pass filter BPF2 and the switch SW. However, harmonics may be generated not only in the low noise amplifier LNA1 but also in the switch SW. Therefore, in order to suppress harmonics that may be generated in the switch SW, the high-pass filter HPF1 is preferably disposed between the switch SW and the antenna ANT 1. Similarly, the high pass filter HPF2 is preferably disposed between the switch SW and the antenna ANT 2.
< embodiment 2 and comparative example >
Hereinafter, embodiment 2 will be described, but comparative examples will be described to make embodiment 2 easier to understand.
Comparative example
Fig. 8 is a diagram showing a state in the transmission of the high-frequency signal transmitting/receiving circuit of the comparative example. In detail, fig. 8 is a diagram showing a state of the high-frequency signal transmission/reception circuit 10 when the antenna ANT1 transmits the radio wave 101 of the frequency band n79 of 5G. The frequency of the electric wave 101 of the frequency band n79 of 5G is 4400MHz to 5000 MHz. Arrow 91 shows the transmit signal path.
The power amplifier PA amplifies a high-frequency input signal RFIN of a frequency band n79 of 5G input from a circuit of a preceding stage to the terminal 11, and outputs the amplified signal to the band-pass filter BPF 1.
The band-pass filter BPF1 passes the high-frequency input signal RFIN amplified by the power amplifier PA and outputs to the coupler CPL. The coupler CPL detects the high-frequency input signal RFIN passing through the bandpass filter BPF1, and outputs a detection signal CPL _ OUT from the terminal 14. The high-frequency input signal RFIN that has passed through the coupler CPL is input to the terminal 21 of the switch SW.
The high-frequency input signal RFIN input to the terminal 21 is output as a high-frequency transmission signal Tx to the antenna ANT1 via the terminal 24 and the 1 st antenna terminal 15. When the high-frequency transmission signal Tx is input to the antenna ANT1, the radio wave 101 of the frequency band n79 of 5G is transmitted toward the base station.
At this time, the antenna 111 receiving the radio wave of 5GHz band of WiFi (IEEE802.11a/n/ac/ax) receives the radio wave 101. The frequency of the radio wave of the 5GHz band of WiFi is 5150MHz to 5925 MHz. The antenna 111 may be an antenna of the present apparatus or an antenna of another apparatus.
Fig. 9 is a diagram showing frequency bands of a high-frequency signal of a frequency band n79 of 5G and a high-frequency signal of a 5GHz band of WiFi.
Band 123 shows the band of the high frequency signal of 6E for WiFi. Band 123 is 5925MHz to 7150 (or 7125) MHz.
(embodiment 2)
Fig. 10 is a diagram showing the configuration of the high-frequency signal transmission/reception circuit according to embodiment 2.
Of the components of the high-frequency signal transmission/reception circuit 1A, the same components as those of the high-frequency signal transmission/reception circuit 10 of the comparative example or the high-frequency signal transmission/reception circuit 1 of embodiment 1 are denoted by the same reference numerals, and description thereof is omitted. The high-frequency signal transmission/reception circuit 1A may be implemented by a hybrid IC in which a plurality of components (semiconductor integrated circuits and the like) are mounted on one substrate, but the present disclosure is not limited thereto.
The high-frequency signal transmission/reception circuit 1A according to embodiment 2 further includes low-pass filters LPF1 and LPF2, as compared with the high-frequency signal transmission/reception circuit 10 according to the comparative example.
In embodiment 2, the high-frequency signal transmission/reception circuit 1A further includes the low-pass filters LPF1 and LPF2, but the present disclosure is not limited thereto. The high frequency signal transmission/reception circuit 1A may include two notch filters (band rejection filters) instead of the low pass filters LPF1 and LPF 2.
The low pass filter LPF1 (or notch filter) corresponds to the "1 st transmit-receive filter" of the present disclosure. The low pass filter LPF2 (or notch filter) is equivalent to the "2 nd transmit-receive filter" of the present disclosure.
Each of the low pass filters LPF1 and LPF2 is an LC multilayer filter, but the present disclosure is not limited thereto. The low pass filters LPF1 and LPF2 may each also be IPDs.
The low pass filter LPF1 is electrically connected between the terminal 24 and the 1 st antenna terminal 15. The low pass filter LPF2 is electrically connected between the terminal 26 and the 2 nd antenna terminal 17.
The low pass filters LPF1 and LPF2 preferably pass high frequency signals of the 5G band n79 and attenuate high frequency signals of the WiFi 5GHz band. That is, the low pass filters LPF1 and LPF2 each preferably pass a high frequency signal of band n79 of 5G (4400MHz to 5000MHz) and attenuate a high frequency signal of a 5GHz band of WiFi (5150MHz to 5925 MHz). However, the low pass filters LPF1 and LPF2 do not need to attenuate all of the high frequency signals (5150MHz to 5925MHz) of the WiFi 5GHz band. The low pass filters LPF1 and LPF2 may each attenuate high frequency signals from the lower limit frequency (5150MHz) of the WiFi 5GHz band to a predetermined frequency (e.g., 5400MHz, 5500MHz, etc.). That is, the low pass filters LPF1 and LPF2 may each attenuate the frequency component 102 (see fig. 9) of the radio wave 101.
When the high frequency signal transmission/reception circuit 1A includes two notch filters instead of the low pass filters LPF1 and LPF2, each notch filter preferably attenuates a high frequency signal (5150MHz to 5925MHz) of a WiFi 5GHz band. However, the notch filter does not need to attenuate all of the high frequency signals (5150MHz to 5925MHz) of the WiFi 5GHz band. The notch filter may attenuate a high-frequency signal from the lower limit frequency (5150MHz) of the WiFi 5GHz band to a predetermined frequency (for example, 5400MHz, 5500MHz, or the like). That is, the notch filter may attenuate the frequency component 102 (see fig. 9) of the radio wave 101.
Fig. 11 is a diagram showing a circuit simulation result of the high-frequency signal transmission/reception circuit according to embodiment 2. In detail, fig. 11 is a diagram showing the S parameters of the low pass filters LPF1 and LPF2 of the high frequency signal transceiver circuit 1A.
Even when the low pass filters LPF1 and LPF2 are formed of IPD, the characteristics can be obtained to the same extent as when they are formed of LC multilayer filters.
As shown by a line 131, each of the low pass filters LPF1 and LPF2 passes a high frequency signal of band n79 of 5G. Further, the low pass filters LPF1 and LPF2 each attenuate high frequency signals of 5.4GHz to the extent of-33 dB among the frequency bands 133 of the 5GHz band of WiFi.
Therefore, when transmitting the high-frequency transmission signal Tx in the frequency band n79 of 5G, the high-frequency signal transmission/reception circuit 1A can suppress the signal level of the high-frequency signal in the 5GHz band of WiFi. Thus, the high-frequency signal transmission/reception circuit 1A can suppress a decrease in the reception sensitivity of another circuit that receives a radio wave of the WiFi 5GHz band.
In addition, it is also conceivable to dispose the low-pass filter LPF1 between the power amplifier PA and the band-pass filter BPF1 or between the band-pass filter BPF1 and the switch SW. However, when receiving a radio wave of the band n79 of 5G, the antenna ANT1 also receives a radio wave of the 5GHz band of WiFi. Therefore, the low pass filter LPF1 is preferably arranged between the switch SW and the antenna ANT1 to attenuate a high frequency signal of the 5GHz band of WiFi among the high frequency reception signals Rx 1. Similarly, the low pass filter LPF2 is preferably disposed between the switch SW and the antenna ANT 2.
< embodiment 3 >
Fig. 12 is a diagram showing an example of the layout of the high-frequency signal transmission/reception circuit according to embodiment 3. The circuit configuration of the high-frequency signal transmission/reception circuit 1B according to embodiment 3 is the same as that of the high-frequency signal transmission/reception circuit 1 (see fig. 5) according to embodiment 1 or the high-frequency signal transmission/reception circuit 1A (see fig. 10) according to embodiment 2, and therefore illustration and description thereof are omitted.
The high-frequency signal transmitting/receiving circuit 1B includes a substrate 140. The substrate 140 may be a non-semiconductor substrate such as a PCB (Printed Circuit Board) or an LTCC (Low Temperature Co-Fired Ceramic), or may be a semiconductor chip (semiconductor substrate).
The substrate 140 has: an area 141 where the power amplifier PA is configured; an area 142 in which the control unit 2 is disposed; region 143 configuring switch SW and low noise amplifier LNA1 and LNA 2; and an area 144 in which the band pass filters BPF1, BPF2, and BPF3, and the 1 st transmit-receive filter (high pass filter HPF1 or low pass filter LPF1) and the 2 nd transmit-receive filter (high pass filter HPF2 or low pass filter LPF2) are arranged.
The region 143 is a quadrangle (e.g., a rectangle) having a short dimension direction along the X direction and a long dimension direction along the Y direction. The region 144 is U-shaped surrounding the two long sides and one short side of the region 143.
The region 143 corresponds to "region 1" of the present disclosure. Region 144 corresponds to "region 2" of the present disclosure.
The signal levels of the high frequency reception signals Rx1 and Rx2 are lower than the signal level of the high frequency transmission signal Tx. Therefore, the band pass filters BPF2 and BPF3 are preferably disposed in the vicinity of the switch SW and the low noise amplifiers LNA1 and LNA 2. Further, the band pass filter BPF2 and the band pass filter BPF3 are preferably isolated. Therefore, the band-pass filter BPF2 and the band-pass filter BPF3 are preferably arranged with the region 143 interposed therebetween. Therefore, it is preferable that one of the band-pass filters BPF2 and BPF3 is disposed in the region 145 facing one long side of the region 143, and the other of the band-pass filters BPF2 and BPF3 is disposed in the region 146 facing the other long side of the region 143.
One of the region 145 and the region 146 corresponds to "region 3" of the present disclosure. The other of the region 145 and the region 146 corresponds to "region 4" of the present disclosure.
The remaining band pass filter BPF1, the 1 st transmission/reception filter, and the 2 nd transmission/reception filter are arranged in the region 144, and are arranged in a region 147 facing the short side of the region 145, a region 148 facing the short side of the region 143, and a region 149 facing the short side of the region 146. As an example, the band pass filter BPF1 is disposed in the region 147, the 1 st transmission/reception filter (the high pass filter HPF1 or the low pass filter LPF1) is disposed in the region 148, and the 2 nd transmission/reception filter (the high pass filter HPF2 or the low pass filter LPF2) is disposed in the region 149.
Fig. 13 is a diagram showing an example of a state in which the high-frequency signal transmitting/receiving circuit according to embodiment 3 transmits signals. Arrow 151 shows the transmit signal path.
The power amplifier PA disposed in the area 141 amplifies the high-frequency input signal RFIN and outputs the amplified signal to the band-pass filter BPF1 disposed in the area 147. The band-pass filter BPF1 passes the high-frequency input signal RFIN amplified by the power amplifier PA and outputs the signal to the switch SW disposed in the region 143. The high-frequency input signal RFIN having passed through the switch SW is input to the 1 st transmission/reception filter (high-pass filter HPF1 or low-pass filter LPF1) disposed in the region 148. The 1 st transmission/reception filter (high pass filter HPF1 or low pass filter LPF1) passes the high frequency input signal RFIN (high frequency pass or low frequency pass) and outputs it as a high frequency transmission signal Tx.
Fig. 14 is a diagram showing an example of a state of the high-frequency signal transmission/reception circuit according to embodiment 3 at the time of reception. Arrow 161 shows the receive signal path.
The 2 nd transceiver filter (the high pass filter HPF2 or the low pass filter LPF2) disposed in the region 149 passes (passes high frequency or low frequency) the high frequency reception signal Rx2 and outputs the high frequency reception signal to the switch SW disposed in the region 143. The high-frequency reception signal Rx2 having passed through the switch SW is input to the band-pass filter BPF3 disposed in the region 146. The band-pass filter BPF3 passes the high-frequency reception signal Rx2 and outputs the signal to the low noise amplifier LNA2 disposed in the region 143. The low noise amplifier LNA2 amplifies the high frequency receive signal Rx2 and outputs a high frequency output signal RFOUT 2.
The above-described embodiments are intended to facilitate understanding of the present invention, and are not intended to limit the present invention. The present invention can be modified without departing from the gist thereof, and the present invention also includes equivalents thereof.
Claims (6)
1. A high-frequency signal transmitting/receiving circuit, comprising:
a power amplifier which amplifies the high frequency input signal;
a transmission band-pass filter that passes the high-frequency input signal amplified by the power amplifier;
a1 st reception band-pass filter for passing a1 st high-frequency reception signal;
a1 st low noise amplifier amplifying the 1 st high frequency reception signal passed through the 1 st reception band pass filter and outputting a1 st high frequency output signal;
a1 st transmission/reception filter having one end electrically connected to the 1 st antenna terminal, passing the high-frequency input signal and the 1 st high-frequency reception signal therethrough, and attenuating a high-frequency signal having at least a part of frequencies different from the frequencies of the high-frequency input signal and the 1 st high-frequency reception signal; and
and a switch that electrically connects the other ends of the transmission bandpass filter and the 1 st transmission/reception filter when the high-frequency input signal is output as a high-frequency transmission signal to the 1 st antenna terminal, and that electrically connects the other ends of the 1 st reception bandpass filter and the 1 st transmission/reception filter when the 1 st high-frequency reception signal is received from the 1 st antenna terminal.
2. The high-frequency signal transceiving circuit according to claim 1,
the high frequency input signal and the 1 st high frequency reception signal are high frequency signals of a frequency band n79 of a 5 th generation mobile communication system,
the 1 st transmission/reception filter passes the high-frequency input signal and the 1 st high-frequency reception signal, and attenuates a high-frequency signal from a lower limit frequency of a 5GHz band of IEEE802.11 to a predetermined frequency.
3. The high-frequency signal transceiving circuit according to claim 2,
the 1 st transceiver filter is a low pass filter or a notch filter.
4. The high-frequency signal transceiver circuit according to any one of claims 1 to 3, further comprising:
a2 nd reception band-pass filter for passing the 2 nd high-frequency reception signal;
a2 nd low noise amplifier amplifying the 2 nd high frequency reception signal passed through the 2 nd reception band pass filter and outputting a2 nd high frequency output signal; and
a2 nd transmission/reception filter having one end electrically connected to the 2 nd antenna terminal, passing the high-frequency input signal and the 2 nd high-frequency reception signal therethrough, and attenuating a high-frequency signal having at least a part of a frequency different from the frequencies of the high-frequency input signal and the 2 nd high-frequency reception signal,
the switch electrically connects the other ends of the transmission bandpass filter and the 2 nd transmission/reception filter when outputting the high-frequency input signal as the high-frequency transmission signal to the 2 nd antenna terminal,
when the 2 nd high-frequency reception signal is received from the 2 nd antenna terminal, the switch electrically connects the 2 nd reception bandpass filter and the other end of the 2 nd transmission/reception filter.
5. The high-frequency signal transceiving circuit according to claim 4,
the high frequency input signal and the 2 nd high frequency reception signal are high frequency signals of a frequency band n79 of a 5 th generation mobile communication system,
the 2 nd transmission/reception filter passes the high-frequency input signal and the 2 nd high-frequency reception signal, and attenuates a high-frequency signal having a frequency from a lower limit frequency of a 5GHz band of IEEE802.11 to a predetermined frequency.
6. The high-frequency signal transceiving circuit according to claim 5,
the 2 nd transceiver filter is a low pass filter or a notch filter.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2020075447A JP2021175032A (en) | 2020-04-21 | 2020-04-21 | High-frequency signal transmission/reception circuit |
JP2020-075447 | 2020-04-21 |
Publications (1)
Publication Number | Publication Date |
---|---|
CN214959528U true CN214959528U (en) | 2021-11-30 |
Family
ID=78278828
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN202120673912.0U Active CN214959528U (en) | 2020-04-21 | 2021-04-01 | High-frequency signal transceiving circuit |
Country Status (2)
Country | Link |
---|---|
JP (1) | JP2021175032A (en) |
CN (1) | CN214959528U (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN113630143A (en) * | 2020-04-21 | 2021-11-09 | 株式会社村田制作所 | High-frequency signal transceiving circuit |
-
2020
- 2020-04-21 JP JP2020075447A patent/JP2021175032A/en active Pending
-
2021
- 2021-04-01 CN CN202120673912.0U patent/CN214959528U/en active Active
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN113630143A (en) * | 2020-04-21 | 2021-11-09 | 株式会社村田制作所 | High-frequency signal transceiving circuit |
Also Published As
Publication number | Publication date |
---|---|
JP2021175032A (en) | 2021-11-01 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US11265028B2 (en) | Radio frequency module and communication device | |
US11121733B2 (en) | Semiconductor device, radio-frequency circuit, and communication apparatus | |
US9917615B2 (en) | Radio-frequency module | |
US11476226B2 (en) | Radio-frequency module and communication device | |
US7167688B2 (en) | RF transceiver module formed in multi-layered ceramic | |
US10148249B2 (en) | High frequency circuit and communication apparatus | |
US9252832B2 (en) | High-frequency circuit and communication device | |
CN112005501B (en) | High-frequency module and communication device provided with same | |
US11201637B2 (en) | Radio frequency module and communication device | |
US9941859B2 (en) | Ladder-type filter, duplexer, and module | |
US11463116B2 (en) | Radio frequency module and communication device | |
KR102417477B1 (en) | High-frequency module and communication device | |
CN214959528U (en) | High-frequency signal transceiving circuit | |
CN110710119B (en) | High frequency module | |
CN113630143A (en) | High-frequency signal transceiving circuit | |
CN214507062U (en) | High-frequency signal transceiving circuit | |
JP2006073673A (en) | High frequency module and radio communication equipment | |
JP2010273215A (en) | High frequency module | |
CN104094527A (en) | High-frequency module | |
KR100700967B1 (en) | Front end module used in mobile communication device | |
KR100882102B1 (en) | Gsm front-end module | |
CN115885481A (en) | High-frequency module and communication device | |
KR20080078482A (en) | Integrated communication module | |
KR20060095348A (en) | Front end module |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
GR01 | Patent grant | ||
GR01 | Patent grant |