JP2019140670A - High frequency signal transmission/reception circuit - Google Patents

Abstract

To achieve miniaturization.SOLUTION: A high frequency signal transmission/reception circuit which performs transmission/reception of a signal between first to sixth antenna terminals and a plurality of terminals on the high frequency circuit side includes first to sixth circuits respectively connected to the first to sixth antenna terminals. One of the first to sixth circuits performs only transmission/reception of a signal of a time division multiplex communication.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a high-frequency signal transmitting / receiving circuit.

  In mobile communication devices such as mobile phone devices and smartphones, a front-end circuit is provided between an antenna and an RFIC (Radio Frequency Integrated Circuit).

  Patent Document 1 below describes a radio frequency front end circuit.

US Patent Application Publication No. 2017/0251474

  Currently, third generation mobile communication systems (for example, W-CDMA, UMTS, CDMA2000 1x) and fourth generation mobile communication systems (for example, LTE (Long Term Evolution), LTE-Advanced) are in operation.

  In December 2017, the 3GPP TSG RAN Plenary (Third Generation Partnership Project, Technical Specification Group, Radio Access Network Plenary) meeting completed the first edition of the 5G NR (New Radio) standard specification. In response to this, it is considered that a mobile communication device compliant with 5G NR (hereinafter sometimes referred to as “5GNR”) is developed.

  Therefore, there is a need for a front-end circuit provided between the antenna and the 5 GNR RFIC. The front-end circuit is assumed to coexist with an existing communication system. That is, since it is necessary to mount a plurality of communication systems on a mobile communication device exemplified by a smartphone, the front end circuit is required to be downsized.

  The present invention has been made in view of the above, and an object thereof is to enable miniaturization.

  A high-frequency signal transmission / reception circuit according to one aspect of the present invention is a high-frequency signal transmission / reception circuit that transmits / receives a signal between first to sixth antenna terminals and a plurality of terminals connected to the high-frequency circuit. 1 to 6 are connected to the first to sixth antenna terminals, respectively, and one of the first to sixth circuits only transmits and receives signals of time division multiplex communication.

  According to the present invention, downsizing is possible.

It is a figure which shows the circuit using the high frequency signal transmission / reception circuit of 1st Embodiment. It is a figure which shows the structure of the high frequency signal transmission / reception circuit of 1st Embodiment. It is a figure which shows the structure of the 1st circuit of the high frequency signal transmission / reception circuit of 1st Embodiment. It is a figure which shows the structure of the 2nd circuit of the high frequency signal transmission / reception circuit of 1st Embodiment. It is a figure which shows the structure of the 3rd circuit of the high frequency signal transmission / reception circuit of 1st Embodiment. It is a figure which shows the structure of the 4th circuit of the high frequency signal transmission / reception circuit of 1st Embodiment. It is a figure which shows the structure of the 5th circuit of the high frequency signal transmission / reception circuit of 1st Embodiment. It is a figure which shows the structure of the 6th circuit of the high frequency signal transmission / reception circuit of 1st Embodiment. It is a figure which shows the structure of the 4th circuit of the high frequency signal transmission / reception circuit of the 1st modification of 1st Embodiment. It is a figure which shows the structure of the 5th circuit of the high frequency signal transmission / reception circuit of the 1st modification of 1st Embodiment. It is a figure which shows the structure of the 4th circuit of the high frequency signal transmission / reception circuit of the 2nd modification of 1st Embodiment. It is a figure which shows the structure of the 4th circuit of the high frequency signal transmission / reception circuit of the 3rd modification of 1st Embodiment. It is a figure which shows the structure of the 4th circuit of the high frequency signal transmission / reception circuit of the 4th modification of 1st Embodiment. It is a figure which shows the structure of the high frequency signal transmission / reception circuit of 2nd Embodiment. It is a figure which shows the structure of the 3rd circuit of the high frequency signal transmission / reception circuit of 2nd Embodiment. It is a figure which shows the structure of the 4th circuit of the high frequency signal transmission / reception circuit of 2nd Embodiment.

  Embodiments of the high-frequency signal transmitting / receiving circuit of the present invention will be described below in detail with reference to the drawings. In addition, this invention is not limited by this embodiment. Each embodiment is an exemplification, and needless to say, partial replacement or combination of the configurations shown in the different embodiments is possible.

(First embodiment)
FIG. 1 is a diagram illustrating a circuit using the high-frequency signal transmission / reception circuit according to the first embodiment. The high-frequency signal transmitting / receiving circuit 1 is a front provided between a first antenna 11 to a sixth antenna 16 and high-frequency integrated circuits (RFICs) 101 to 104 in a mobile communication device exemplified by a mobile phone device and a smartphone. End circuit. Hereinafter, the high-frequency integrated circuits 101 to 104 are referred to as RFICs 101 to 104.

  The RFIC 101 transmits and receives LTE (Long Term Evolution) high-frequency signals. The RFIC 102 transmits and receives a 5 GNR high-frequency signal. The RFIC 103 transmits and receives a high-frequency signal of WiFi (IEEE (The Institute of Electrical and Electronics Engineers, Inc.) 802.11). The RFIC 104 transmits and receives high-frequency signals from GPS (Global Positioning System). The RFICs 101 to 104 may be a single high-frequency integrated circuit. RFICs 101 to 104 correspond to the “high frequency circuit” of the present disclosure.

  FIG. 2 is a diagram illustrating a configuration of the high-frequency signal transmission / reception circuit according to the first embodiment. The high-frequency signal transmitting / receiving circuit 1 can be configured by being formed on an integrated circuit (IC) different from the RFICs 101 to 104 and mounting the integrated circuit (IC) on a printed board. The first antenna terminal 11a to the sixth antenna terminal 16a may be disposed on the printed circuit board. Further, the first antenna 11 to the sixth antenna 16 may be mounted on the printed circuit board. Further, the RFICs 101 to 104 may be mounted on the printed board.

  The high-frequency signal transmission / reception circuit 1 includes a first circuit 2 that transmits / receives a high-frequency signal between the first antenna terminal 11 a and a plurality of terminals connected to the RFICs 101 and 102.

  The high-frequency signal transmission / reception circuit 1 includes a second circuit 3 that transmits / receives a high-frequency signal between the second antenna terminal 12a and a plurality of terminals connected to the RFICs 101 to 103.

  The high-frequency signal transmission / reception circuit 1 includes a third circuit 4 that transmits / receives a high-frequency signal between the third antenna terminal 13a and a plurality of terminals connected to the RFICs 101 to 104.

  The high-frequency signal transmission / reception circuit 1 includes a fourth circuit 5 that transmits and receives high-frequency signals between the fourth antenna terminal 14a and a plurality of terminals connected to the RFICs 101 to 103. The fourth circuit 5 can transmit and receive high-frequency signals between the fourth antenna terminal 14a and the RFIC of a satellite positioning system exemplified by GLONASS, Galileo, Hokuto satellite positioning system, quasi-zenith satellite system, and the like. There may be.

  The high-frequency signal transmission / reception circuit 1 includes a fifth circuit 6 that transmits and receives high-frequency signals between the fifth antenna terminal 15a and a plurality of terminals connected to the RFICs 101 to 103.

  The high-frequency signal transmission / reception circuit 1 includes a sixth circuit 7 that transmits and receives a high-frequency signal between the sixth antenna terminal 16a and a plurality of terminals connected to the RFICs 101 and 102.

  The first circuit 2 includes an LTE low frequency band signal transmission / reception circuit 21, an LTE middle frequency band signal transmission / reception circuit 22, an LTE high frequency band signal transmission / reception circuit 23, and a multiplexer 24.

  In the first embodiment, each transmission / reception circuit may be divided into a transmission circuit and a reception circuit.

  In the first embodiment, the LTE low frequency range includes the LTE bands 28, 20, 5, 19, 26, and 8, but the present disclosure is not limited thereto.

  The LTE band 28 is Frequency Division Duplex (FDD) with an uplink (transmission) frequency of 703 MHz to 748 MHz and a downlink (reception) frequency of 758 MHz to 803 MHz.

  The LTE band 20 is an FDD having a transmission frequency of 832 MHz to 862 MHz and a reception frequency of 791 MHz to 821 MHz.

  LTE band 5 is an FDD with a transmission frequency of 824 MHz to 849 MHz and a reception frequency of 869 MHz to 894 MHz.

  The LTE band 19 is an FDD with a transmission frequency of 830 MHz to 845 MHz and a reception frequency of 875 MHz to 890 MHz.

  The LTE band 26 is an FDD having a transmission frequency of 814 MHz to 849 MHz and a reception frequency of 859 MHz to 894 MHz.

  LTE band 8 is an FDD with a transmission frequency of 880 MHz to 915 MHz and a reception frequency of 925 MHz to 960 MHz.

  In the first embodiment, the LTE mid-frequency range includes LTE bands 21, 3 and 1, but the present disclosure is not limited to these.

  The LTE band 21 is an FDD having a transmission frequency of 1447.9 MHz to 1462.9 MHz and a reception frequency of 1495.9 MHz to 1510.9 MHz.

  LTE band 3 is an FDD with a transmission frequency of 1710 MHz to 1785 MHz and a reception frequency of 1805 MHz to 1880 MHz.

  LTE band 1 is an FDD with a transmission frequency of 1920 MHz to 1980 MHz and a reception frequency of 2110 MHz to 2170 MHz.

  In the first embodiment, the LTE high frequency region includes the LTE bands 7 and 41, but the present disclosure is not limited thereto.

  LTE band 7 is an FDD with a transmission frequency of 2500 MHz to 2570 MHz and a reception frequency of 2620 MHz to 2690 MHz.

  The LTE band 41 is a time division duplex (TDD) transmission and reception frequency of 2496 MHz to 2690 MHz.

  The multiplexer 24 is a 1 to 3 triplexer. The multiplexer 24 electrically connects the first antenna terminal 11 a and the LTE low frequency signal transmitting / receiving circuit 21, the LTE middle frequency signal transmitting / receiving circuit 22, and the LTE high frequency signal transmitting / receiving circuit 23.

  The multiplexer 24 includes a low pass filter, a band pass filter, and a high pass filter. The low-pass filter passes the LTE low frequency signal. The bandpass filter passes the LTE mid-frequency signal. The high pass filter passes the LTE high frequency band signal.

  The LTE low frequency band signal transmission / reception circuit 21 receives the LTE low frequency band transmission signal from the RFIC 101 and outputs it to the first antenna terminal 11 a via the low pass filter in the multiplexer 24. The LTE low frequency band signal transmission / reception circuit 21 receives the LTE low frequency band reception signal from the first antenna terminal 11 a via the low pass filter in the multiplexer 24 and outputs the received signal to the RFIC 101.

  The LTE middle frequency band signal transmission / reception circuit 22 receives the LTE middle frequency band transmission signal from the RFIC 101 and outputs it to the first antenna terminal 11 a via the bandpass filter in the multiplexer 24. The LTE middle frequency band signal transmitting / receiving circuit 22 receives the LTE middle frequency band received signal from the first antenna terminal 11 a via the bandpass filter in the multiplexer 24 and outputs the received signal to the RFIC 101.

  The LTE high frequency band signal transmission / reception circuit 23 receives the LTE high frequency band transmission signal from the RFIC 101 and outputs it to the first antenna terminal 11 a via the high pass filter in the multiplexer 24. The LTE high frequency band signal transmission / reception circuit 23 receives the LTE high frequency band reception signal from the first antenna terminal 11 a via the high-pass filter in the multiplexer 24 and outputs the received signal to the RFIC 101.

  The second circuit 3 includes a 5 GNR signal and an LTE ultra-high frequency band signal transmission / reception circuit 31.

  In the first embodiment, the 5 GNR includes the TDD of the 3.5 GHz band from 3.3 GHz to 4.2 GHz and 3.3 GHz to 3.8 GHz and the 4.5 GHz band from 4.5 GHz to 4.99 GHz. However, the present disclosure is not limited to these.

  In the first embodiment, the LTE ultra-high frequency region includes the LTE band 42, but the present disclosure is not limited to this.

  The LTE band 42 is TDD with transmission and reception frequencies of 3400 MHz to 3600 MHz.

  The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 31 receives the 5GNR transmission signal from the RFIC 102 and outputs it to the second antenna terminal 12a. The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 31 receives the LTE ultra-high frequency band transmission signal from the RFIC 101 and outputs it to the second antenna terminal 12a.

  The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 31 receives the 5GNR reception signal from the second antenna terminal 12a and outputs it to the RFIC 102. The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 31 receives the LTE ultra-high frequency band reception signal from the second antenna terminal 12a and outputs the received signal to the RFIC 101.

  The third circuit 4 includes an LTE low frequency band signal receiving circuit 41, an LTE medium / high frequency band signal receiving / WiFi 2.4 GHz band signal transmitting / receiving circuit 42, and a multiplexer 43.

  The multiplexer 43 is a one-to-two diplexer. The multiplexer 43 electrically connects the third antenna terminal 13a, the LTE low frequency band signal receiving circuit 41, and the LTE medium / high frequency band signal receiving and WiFi 2.4 GHz band signal transmitting / receiving circuit 42. Here, a configuration in which a low-pass filter and a high-pass filter are combined is called a diplexer.

  The 2.4 GHz region of WiFi includes CSMA / CA (Carrier Sense Multiple Access with Collision Avoidance) with a center frequency of 2412 MHz to 2484 MHz, but the present disclosure is not limited to this.

  The multiplexer 43 includes a low pass filter and a high pass filter. The low-pass filter passes the LTE low frequency signal. The high-pass filter passes the LTE mid-high frequency signal and the WiFi 2.4 GHz signal.

  The LTE low frequency band signal reception circuit 41 receives the LTE low frequency band reception signal from the third antenna terminal 13 a via the low pass filter in the multiplexer 43 and outputs the received signal to the RFIC 101.

  The LTE medium / high frequency band signal reception and WiFi 2.4 GHz signal transmission / reception circuit 42 receives the LTE medium / high frequency band reception signal from the third antenna terminal 13 a via the high-pass filter in the multiplexer 43 and outputs the received signal to the RFIC 101.

  The LTE mid-high frequency band signal reception and WiFi 2.4 GHz band signal transmission / reception circuit 42 receives the WiFi 2.4 GHz band transmission signal from the RFIC 103 and outputs it to the third antenna terminal 13 a via the high-pass filter in the multiplexer 43. The LTE mid-high frequency band signal reception and WiFi 2.4 GHz band signal transmission / reception circuit 42 receives the WiFi 2.4 GHz band reception signal from the third antenna terminal 13 a via the high-pass filter in the multiplexer 43 and outputs the received signal to the RFIC 103.

  The fourth circuit 5 includes a GPS signal receiving circuit 51, an LTE high frequency signal and a WiFi 2.4 GHz signal transmission / reception circuit 52, a 5GNR signal and an LTE ultra high frequency signal transmission / reception circuit 53, an eLAA signal and a WiFi 5 GHz signal. A circuit 54 and a multiplexer 55 are included.

  In the first embodiment, the GPS signal includes 1575.42 MHz in the L1 band, but the present disclosure is not limited to this.

  eLAA (enhanced Licensed Assisted Access) is a technology that performs LTE communication using a frequency band that does not require a license. In the embodiment, the eLAA and WiFi 5 GHz regions include the center frequency from 5180 MHz to 5825 MHz, but the present disclosure is not limited to this.

  The multiplexer 55 is a one-to-four quadplexer. The multiplexer 55 includes a fourth antenna terminal 14a, a GPS signal receiving circuit 51, an LTE high frequency band signal and a WiFi 2.4 GHz band signal transmitting / receiving circuit 52, a 5 GNR signal and an LTE ultra high frequency band signal transmitting / receiving circuit 53, and an eLAA signal and The WiFi 5 GHz band signal transmission / reception circuit 54 is electrically connected.

  Multiplexer 55 includes a low pass filter, a first band pass filter, a second band pass filter, and a high pass filter. The low-pass filter passes the GPS signal. The first band pass filter passes the LTE high frequency band signal and the WiFi 2.4 GHz band signal. The second band pass filter passes the 5GNR signal and the LTE ultra high frequency signal. The high pass filter passes the eLAA signal and the WiFi 5 GHz band signal.

  The GPS signal receiving circuit 51 receives the GPS signal from the fourth antenna terminal 14a via the low-pass filter in the multiplexer 55, and outputs it to the GPS RFIC. Note that the GPS signal receiving circuit 51 may be capable of receiving signals from a satellite positioning system exemplified by GLONASS, Galileo, Hokuto satellite positioning system, quasi-zenith satellite system, and the like.

  The LTE high frequency band signal and WiFi 2.4 GHz band signal transmission / reception circuit 52 receives the WiFi 2.4 GHz band transmission signal from the RFIC 103 and outputs it to the fourth antenna terminal 14 a via the first bandpass filter in the multiplexer 55. The LTE high frequency band signal and WiFi 2.4 GHz band signal transmission / reception circuit 52 receives the WiFi 2.4 GHz band reception signal from the fourth antenna terminal 14a via the first band pass filter in the multiplexer 55, and outputs the received signal to the WiFi RFIC.

  The LTE high frequency band signal and WiFi 2.4 GHz band signal transmission / reception circuit 52 receives the LTE high frequency band transmission signal from the RFIC 101 and outputs it to the fourth antenna terminal 14 a via the first bandpass filter in the multiplexer 55. The LTE high frequency band signal and WiFi 2.4 GHz band signal transmission / reception circuit 52 receives the LTE high frequency band reception signal from the fourth antenna terminal 14 a via the first band pass filter in the multiplexer 55 and outputs the received signal to the RFIC 101.

  The 5GNR signal and LTE ultra-high frequency band signal transmitting / receiving circuit 53 receives the 5GNR transmission signal from the RFIC 102 and outputs it to the fourth antenna terminal 14 a via the second bandpass filter in the multiplexer 55. The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53 receives the LTE ultra-high frequency band transmission signal from the RFIC 101 and outputs it to the fourth antenna terminal 14 a via the second bandpass filter in the multiplexer 55.

  The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53 receives the 5GNR reception signal from the fourth antenna terminal 14 a via the second bandpass filter in the multiplexer 55 and outputs it to the RFIC 102. The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53 receives the LTE ultra-high frequency band reception signal from the fourth antenna terminal 14 a via the second band pass filter in the multiplexer 55 and outputs the received signal to the RFIC 101.

  The eLAA signal and WiFi 5 GHz signal transmission / reception circuit 54 receives the eLAA transmission signal from the RFIC 101 and outputs it to the fourth antenna terminal 14 a via the high-pass filter in the multiplexer 55. The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54 receives the WiFi 5 GHz band transmission signal from the RFIC 103 and outputs it to the fourth antenna terminal 14 a via the high-pass filter in the multiplexer 55.

  The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54 receives the eLAA reception signal from the fourth antenna terminal 14 a via the high-pass filter in the multiplexer 55 and outputs it to the RFIC 101. The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54 receives the WiFi 5 GHz band reception signal from the fourth antenna terminal 14 a via the high-pass filter in the multiplexer 55 and outputs it to the RFIC 103.

  The fifth circuit 6 includes an LTE middle and high frequency band signal receiving circuit 61, a 5 GNR signal and LTE ultra-high frequency band signal transmitting / receiving circuit 62, an eLAA signal and WiFi 5 GHz band signal transmitting / receiving circuit 63, and a multiplexer 64.

  The multiplexer 64 is electrically connected between the fifth antenna terminal 15a, the LTE medium / high frequency signal receiving circuit 61, the 5GNR signal and the LTE ultra-high frequency signal transmitting / receiving circuit 62, and the eLAA signal and the WiFi 5GHz signal transmitting / receiving circuit 63. Connect.

  The multiplexer 64 is a 1 to 3 triplexer. The multiplexer 64 includes a low pass filter, a band pass filter, and a high pass filter. The low-pass filter passes the LTE mid-high frequency signal. The bandpass filter passes the 5GNR signal and the LTE ultra high frequency signal. The high pass filter passes the eLAA signal and the WiFi 5 GHz band signal.

  The LTE medium / high frequency band signal reception circuit 61 receives the LTE medium / high frequency band reception signal from the fifth antenna terminal 15 a via the low-pass filter in the multiplexer 64 and outputs the received signal to the RFIC 101.

  The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 62 receives the 5GNR transmission signal from the RFIC 102 and outputs it to the fifth antenna terminal 15 a via the bandpass filter in the multiplexer 64. The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 62 receives the LTE ultra-high frequency band transmission signal from the RFIC 101 and outputs it to the fifth antenna terminal 15a via the bandpass filter in the multiplexer 64.

  The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 62 receives the 5GNR reception signal from the fifth antenna terminal 15 a via the bandpass filter in the multiplexer 64 and outputs the received signal to the RFIC 102. The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 62 receives the LTE ultra-high frequency band reception signal from the fifth antenna terminal 15a via the bandpass filter in the multiplexer 64 and outputs the received signal to the RFIC 101.

  The eLAA signal and WiFi 5 GHz band signal transmitting / receiving circuit 63 receives the eLAA transmission signal from the RFIC 101 and outputs it to the fifth antenna terminal 15 a via the high-pass filter in the multiplexer 64. The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63 receives the WiFi 5 GHz band transmission signal from the RFIC 103 and outputs it to the fifth antenna terminal 15 a via the high-pass filter in the multiplexer 64.

  The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63 receives the eLAA reception signal from the fifth antenna terminal 15 a via the high-pass filter in the multiplexer 64 and outputs it to the RFIC 101. The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63 receives the WiFi 5 GHz band reception signal from the fifth antenna terminal 15 a via the high-pass filter in the multiplexer 64 and outputs the received signal to the RFIC 103.

  The sixth circuit 7 includes an LTE mid-frequency signal receiving circuit 71, a 5 GNR signal and LTE ultra-high frequency signal transmitting / receiving circuit 72, and a multiplexer 73.

  The multiplexer 73 electrically connects the sixth antenna terminal 16 a, the LTE mid-frequency signal receiving circuit 71, and the 5 GNR signal and LTE ultra-high frequency signal transmitting / receiving circuit 72.

  The multiplexer 73 is a one-to-two diplexer. The multiplexer 73 includes a low pass filter and a high pass filter. The low-pass filter passes the LTE mid-frequency signal. The high pass filter passes the 5GNR signal and the LTE ultra high frequency signal.

  The LTE middle frequency band signal receiving circuit 71 receives the LTE middle frequency band received signal from the sixth antenna terminal 16 a via the low pass filter in the multiplexer 73 and outputs the received signal to the RFIC 101.

  The 5GNR signal and LTE ultra-high frequency band signal transmitting / receiving circuit 72 receives the 5GNR transmission signal from the RFIC 102 and outputs it to the sixth antenna terminal 16 a via the high-pass filter in the multiplexer 73. The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 72 receives the LTE ultra-high frequency band transmission signal from the RFIC 101 and outputs it to the sixth antenna terminal 16a via the high-pass filter in the multiplexer 73.

  The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 72 receives the 5GNR reception signal from the sixth antenna terminal 16a via the high-pass filter in the multiplexer 73 and outputs it to the RFIC 102. The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 72 receives the LTE ultra-high frequency band reception signal from the sixth antenna terminal 16 a via the high-pass filter in the multiplexer 73 and outputs the received signal to the RFIC 101.

  FIG. 3 is a diagram illustrating a configuration of the first circuit of the high-frequency signal transmission / reception circuit according to the first embodiment.

  The LTE low frequency band signal transmission / reception circuit 21, the LTE middle frequency band signal transmission / reception circuit 22, the LTE high frequency band signal transmission / reception circuit 23, and the multiplexer 24 are one module, but the present disclosure is not limited thereto. The LTE low frequency signal transmission / reception circuit 21, the LTE middle frequency signal transmission / reception circuit 22, the LTE high frequency signal transmission / reception circuit 23, and the multiplexer 24 may be separate modules. The module is configured by mounting one or more components on a substrate.

  The LTE low frequency signal transmitting / receiving circuit 21 includes a power amplifier 21a, a low noise amplifier 21b, and a multiplexer 21c.

  The power amplifier 21a is connected in two stages, but the present disclosure is not limited to this. The power amplifier 21a may be a single stage or a connection of three stages or more. The same applies to each power amplifier described below.

  The multiplexer 21c is a 1-to-2 duplexer. The multiplexer 21c electrically connects the low pass filter in the multiplexer 24 and the power amplifier 21a and the low noise amplifier 21b.

  The multiplexer 21c includes a first band pass filter and a second band pass filter. The first band pass filter passes the LTE low frequency band transmission signal. The second band pass filter passes the LTE low frequency band received signal.

  The power amplifier 21a receives the LTE low frequency band transmission signal from the RFIC 101 via the terminal 2a, and outputs it to the first band pass filter in the multiplexer 21c.

  The low noise amplifier 21b receives the LTE low frequency band received signal from the second band pass filter in the multiplexer 21c and outputs the received signal to the RFIC 101 via the terminal 2b.

  The LTE mid-frequency signal transmitting / receiving circuit 22 includes a power amplifier 22a, a low noise amplifier 22b, and a multiplexer 22c.

  The multiplexer 22c is a 1-to-2 duplexer. The multiplexer 22c electrically connects the band pass filter in the multiplexer 24 and the power amplifier 22a and the low noise amplifier 22b.

  The multiplexer 22c includes a first band pass filter and a second band pass filter. The first band pass filter passes the LTE mid-frequency transmission signal. The second band pass filter passes the LTE mid-frequency band received signal.

  The power amplifier 22a receives the LTE mid-frequency band transmission signal from the RFIC 101 via the terminal 2c and outputs it to the first bandpass filter in the multiplexer 22c.

  The low noise amplifier 22b receives the LTE mid-frequency band reception signal from the second band pass filter in the multiplexer 22c and outputs the received signal to the RFIC 101 via the terminal 2d.

  The LTE high frequency band signal transmission / reception circuit 23 includes a power amplifier 23a, a low noise amplifier 23b, and a multiplexer 23c.

  The multiplexer 23c is a 1-to-2 duplexer. The multiplexer 23c electrically connects the high pass filter in the multiplexer 24 and the power amplifier 23a and the low noise amplifier 23b.

  The multiplexer 23c includes a first band pass filter and a second band pass filter. The first band pass filter passes the LTE high frequency band transmission signal. The second band pass filter passes the LTE high frequency band received signal.

  The power amplifier 23a receives the LTE high frequency band transmission signal from the RFIC 101 via the terminal 2e and outputs it to the first band pass filter in the multiplexer 23c.

  The low noise amplifier 23b receives the LTE high frequency band reception signal from the second band pass filter in the multiplexer 23c, and outputs the received signal to the RFIC 101 via the terminal 2f.

  FIG. 4 is a diagram illustrating a configuration of a second circuit of the high-frequency signal transmission / reception circuit according to the first embodiment.

  The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 31 may be a module.

  The 5GNR signal and LTE ultra high frequency signal transmitting / receiving circuit 31 includes switches 31a, 31d, 31e, 31h and 31k, power amplifiers 31b and 31c, bandpass filters 31f and 31g, and low noise amplifiers 31i and 31j. .

  The switches 31a and 31k are dual port dual throw switches. The switches 31d, 31e, and 31h are single port dual throw switches.

  When transmitting a signal from 5 GHz to 4.5 GHz to 4.99 GHz, the switch 31a electrically connects the terminal 3a and the power amplifier 31b. The switch 31d electrically connects the power amplifier 31b and the band pass filter 31f. The switch 31h electrically connects the bandpass filter 31f and the second antenna 12. The power amplifier 31b receives and amplifies a 5 GNR 4.5 GHz to 4.99 GHz transmission signal from the RFIC 102 via the terminal 3a and the switch 31a, and amplifies the 5 GNR 4.5 GHz to 4.99 GHz transmission signal to the switch 31d. And output to the band pass filter 31f. The band-pass filter 31f passes the transmission signal of 4.5 GHz to 4.99 GHz of 5 GNR amplified by the power amplifier 31b, and outputs the transmission signal to the second antenna terminal 12a via the switch 31h.

  When transmitting a signal of 5 GHz from 3.3 GHz to 4.2 GHz, the switch 31a electrically connects the terminal 3a and the power amplifier 31c. The switch 31e electrically connects the power amplifier 31c and the bandpass filter 31g. The switch 31h electrically connects the bandpass filter 31g and the second antenna terminal 12a. The power amplifier 31c receives and amplifies a transmission signal of 3.3 GHz to 4.2 GHz of 5 GNR from the RFIC 102 via the terminal 3a and the switch 31a, and amplifies the transmission signal of 3.3 GHz to 4.2 GHz of 5 GNR after amplification. And output to the band pass filter 31g. The bandpass filter 31g passes the transmission signal of 3.3 GHz to 4.2 GHz of 5 GNR amplified by the power amplifier 31c, and outputs the transmission signal to the second antenna terminal 12a via the switch 31h.

  When transmitting an LTE ultra-high frequency band signal, the switch 31a electrically connects the terminal 3b and the power amplifier 31c. The switch 31e electrically connects the power amplifier 31c and the bandpass filter 31g. The switch 31h electrically connects the bandpass filter 31g and the second antenna terminal 12a. The power amplifier 31c receives and amplifies the LTE ultra-high frequency band transmission signal from the RFIC 102 via the terminal 3b and the switch 31a, and outputs the amplified LTE ultra-high frequency band transmission signal to the bandpass filter 31g via the switch 31e. The band pass filter 31g passes the LTE ultra-high frequency band transmission signal amplified by the power amplifier 31c through the band and outputs the signal to the second antenna terminal 12a via the switch 31h.

  When receiving a signal of 4.5 GHz to 4.99 GHz of 5 GNR, the switch 31h electrically connects the second antenna terminal 12a and the bandpass filter 31f. The switch 31d electrically connects the band pass filter 31f and the low noise amplifier 31i. The switch 31k electrically connects the low noise amplifier 31i and the terminal 3c. The band-pass filter 31f passes the reception signal of 4.5 GHz to 4.99 GHz of 5 GNR received from the second antenna terminal 12a via the switch 31h, and outputs it to the low noise amplifier 31i via the switch 31d. The low noise amplifier 31i amplifies the received signal from 4.5 GHz to 4.99 GHz of 5 GNR, and outputs the amplified received signal from 4.5 GHz to 4.99 GHz of 5 GNR to the RFIC 102 via the switch 31k and the terminal 3c.

  When receiving a signal of 5 GHz from 3.3 GHz to 4.2 GHz, the switch 31 h electrically connects the second antenna terminal 12 a and the bandpass filter 31 g. The switch 31e electrically connects the band pass filter 31g and the low noise amplifier 31j. The switch 31k electrically connects the low noise amplifier 31j and the terminal 3c. The bandpass filter 31g passes the band of the received signal of 3.3 GHz to 4.2 GHz of 5 GNR received from the second antenna terminal 12a via the switch 31h, and outputs it to the low noise amplifier 31j via the switch 31e. The low noise amplifier 31j amplifies the received signal of 5 GHz from 3.3 GHz to 4.2 GHz, and outputs the amplified received signal of 5 GHz from 3.3 GHz to 4.2 GHz to the RFIC 102 via the switch 31k and the terminal 3c.

  When receiving an LTE ultra-high frequency band signal, the switch 31h electrically connects the second antenna terminal 12a and the bandpass filter 31g. The switch 31e electrically connects the band pass filter 31g and the low noise amplifier 31j. The switch 31k electrically connects the low noise amplifier 31j and the terminal 3d. The bandpass filter 31g passes the LTE ultra-high frequency band reception signal received from the second antenna terminal 12a via the switch 31h and outputs it to the low noise amplifier 31j via the switch 31e. The low noise amplifier 31j amplifies the LTE ultra-high frequency band reception signal and outputs the amplified LTE ultra-high frequency band reception signal to the RFIC 101 via the switch 31k and the terminal 3d.

  FIG. 5 is a diagram illustrating a configuration of a third circuit of the high-frequency signal transmitting and receiving circuit according to the first embodiment.

  The LTE low frequency band signal receiving circuit 41, the LTE medium and high frequency band signal receiving and WiFi 2.4 GHz band signal transmitting / receiving circuit 42, and the multiplexer 43 are one module, but the present disclosure is not limited thereto. The LTE low frequency band signal receiving circuit 41, the LTE medium / high frequency band signal receiving and WiFi 2.4 GHz band signal transmitting / receiving circuit 42, and the multiplexer 43 may be separate modules.

  The LTE low frequency band signal receiving circuit 41 includes a multiplexer 41a, low noise amplifiers 41b, 41c and 41e, and a switch 41d.

  The multiplexer 41a is a one-to-four quadplexer. The multiplexer 41a electrically connects the low-pass filter in the multiplexer 43, the low noise amplifiers 41b and 41c, and the switch 41d.

  The multiplexer 41a includes a first band pass filter, a second band pass filter, a third band pass filter, and a fourth band pass filter. The first band-pass filter passes the received signal in the LTE band 28. The second band-pass filter passes the received signal of the LTE band 20. The third band pass filter passes the received signals of LTE bands 5, 19 and 26. The fourth band-pass filter passes the received signal of the LTE band 8.

  The switch 41d is a single port dual throw switch.

  The low noise amplifier 41b receives the received signal of the LTE band 28 from the first band pass filter in the multiplexer 41a and outputs the received signal to the RFIC 101 via the terminal 4a.

  The low noise amplifier 41c receives the received signal of the LTE band 20 from the second band pass filter in the multiplexer 41a and outputs the received signal to the RFIC 101 via the terminal 4b.

  When receiving the signal of LTE band 5, 19 or 26, the switch 41d electrically connects the third bandpass filter in the multiplexer 41a and the low noise amplifier 41e. The low noise amplifier 41e amplifies the received signal of the LTE band 5, 19 or 26 received from the third band pass filter in the multiplexer 41a via the switch 41d, and receives the amplified received signal of the LTE band 5, 19 or 26 after the amplification. Is output to the RFIC 101 via the terminal 4c.

  When receiving the LTE band 8 signal, the switch 41d electrically connects the fourth bandpass filter in the multiplexer 41a and the low-noise amplifier 41e. The low noise amplifier 41e amplifies the received signal of the LTE band 8 received from the fourth band pass filter in the multiplexer 41a via the switch 41d, and outputs the amplified received signal of the LTE band 8 to the RFIC 101 via the terminal 4c. To do.

  The LTE medium / high frequency band signal reception and WiFi 2.4 GHz band signal transmission / reception circuit 42 includes a multiplexer 42a, low noise amplifiers 42b, 42c, 42d, 42f and 42j, switches 42e, 42g and 42i, and a power amplifier 42h.

  The multiplexer 42a is a one-to-four quadplexer. The multiplexer 42a electrically connects the high-pass filter in the multiplexer 43 to the low noise amplifiers 42b, 42c, 42d and the switch 42e.

  The multiplexer 42a includes a first band pass filter, a second band pass filter, a third band pass filter, and a fourth band pass filter. The first band-pass filter passes the received signal of the LTE band 3. The second band-pass filter passes the received signal of LTE band 1. The third band-pass filter passes the received signal of the LTE band 21. The fourth band pass filter passes the reception signals of LTE bands 7 and 41 and the transmission / reception signal of the 2.4 GHz band of WiFi.

  The switches 42e, 42g and 42i are single port dual throw switches.

  The low noise amplifier 42b receives the LTE band 3 reception signal from the first band pass filter in the multiplexer 42a and outputs the received signal to the RFIC 101 via the terminal 4d.

  The low noise amplifier 42c receives an LTE band 1 reception signal from the second bandpass filter in the multiplexer 42a and outputs the received signal to the RFIC 101 via the terminal 4e.

  When receiving the signal of the LTE band 21, the switch 42g electrically connects the low noise amplifier 42d and the terminal 4f. The low noise amplifier 42d amplifies the received signal of the LTE band 21 received from the third bandpass filter in the multiplexer 42a, and outputs the amplified received signal of the LTE band 21 to the RFIC 101 via the switch 42g and the terminal 4f. .

  When receiving the signal of the LTE band 7 or 41, the switch 42e electrically connects the fourth band-pass filter in the multiplexer 42a and the low-noise amplifier 42f. The switch 42g electrically connects the low noise amplifier 42f and the terminal 4f. The low noise amplifier 42f amplifies the received signal of the LTE band 7 or 41 received from the fourth bandpass filter in the multiplexer 42a via the switch 42e, and the amplified signal of the LTE band 7 or 41 after the amplification is supplied to the switch 42g and Output to the RFIC 101 via the terminal 4f.

  When transmitting signals in the 2.4 GHz band of WiFi, the switch 42 i electrically connects the power amplifier 42 h and the switch 42 e. The switch 42e electrically connects the switch 42i and the fourth bandpass filter in the multiplexer 42a. The power amplifier 42h receives and amplifies the WiFi 2.4 GHz transmission signal from the RFIC 103 via the terminal 4g, and amplifies the WiFi 2.4 GHz transmission signal in the multiplexer 42a via the switches 42i and 42e. Output to 4-band pass filter.

  When receiving a signal in the 2.4 GHz band of WiFi, the switch 42e electrically connects the fourth bandpass filter in the multiplexer 42a and the switch 42i. The switch 42i electrically connects the switch 42e and the low noise amplifier 42j. The low noise amplifier 42j receives and amplifies the WiFi 2.4 GHz band received signal from the fourth bandpass filter in the multiplexer 42a via the switches 42i and 42e, and the amplified WiFi 2.4 GHz band received signal is a terminal. Output to the RFIC 103 via 4h.

  FIG. 6 is a diagram illustrating a configuration of a fourth circuit of the high-frequency signal transmitting and receiving circuit according to the first embodiment.

  GPS signal receiving circuit 51, LTE high frequency band signal and WiFi 2.4 GHz band signal transmitting / receiving circuit 52, 5 GNR signal and LTE ultra high frequency band signal transmitting / receiving circuit 53, eLAA signal and WiFi 5 GHz band signal transmitting / receiving circuit 54, and multiplexer 55 are: Although one module is provided, the present disclosure is not limited to this. GPS signal receiving circuit 51, LTE high frequency band signal and WiFi 2.4 GHz band signal transmitting / receiving circuit 52, 5 GNR signal and LTE ultra high frequency band signal transmitting / receiving circuit 53, eLAA signal and WiFi 5 GHz band signal transmitting / receiving circuit 54, and multiplexer 55 are: Each may be a separate module.

  The GPS signal receiving circuit 51 includes a GPS receiver 51a. The GPS receiver 51a receives a GPS signal from the low-pass filter in the multiplexer 55 and outputs it to the RFIC 104 via the terminal 5a.

  The LTE high frequency band signal and WiFi 2.4 GHz band signal transmission / reception circuit 52 includes power amplifiers 52a and 52e, switches 52b, 52f, 52h and 52j, multiplexers 52c and 52i, low noise amplifiers 52d and 52k, and a bandpass filter 52g. And including.

  The multiplexer 52c is a 1-to-2 duplexer. The multiplexer 52c electrically connects the first bandpass filter in the multiplexer 55 and the switches 52b and 52h.

  The multiplexer 52c includes a band pass filter and a high pass filter. The band pass filter passes a signal in the 2.4 GHz band of WiFi. The high-pass filter passes signals in LTE bands 7 and 41.

  The multiplexer 52i is a one-to-two duplexer. The multiplexer 52i electrically connects the switch 52h and the switches 52f and 52j.

  The multiplexer 52i includes a first band pass filter and a second band pass filter. The first bandpass filter passes the transmission signal of the LTE band 7. The second band-pass filter passes the received signal of the LTE band 7.

  The band-pass filter 52g passes the signal of the LTE band 41.

  The switches 52b, 52h and 52j are single port dual throw switches. The switch 52f is a dual port dual throw switch.

  When transmitting a signal in the 2.4 GHz band of WiFi, the switch 52b electrically connects the power amplifier 52a and the bandpass filter in the multiplexer 52c. The power amplifier 52a receives and amplifies the WiFi 2.4 GHz transmission signal from the RFIC 103 via the terminal 5b, and amplifies the amplified 2.4 GHz transmission signal in the multiplexer 52c via the switch 52b. Output to.

  When receiving a signal in the 2.4 GHz band of WiFi, the switch 52b electrically connects the bandpass filter in the multiplexer 52c and the low noise amplifier 52d. The low noise amplifier 52d receives the received signal in the 2.4 GHz band of WiFi from the bandpass filter in the multiplexer 52c via the switch 52b, and outputs it to the RFIC 103 via the terminal 5c.

  At the time of LTE band 7 signal transmission, the switch 52f electrically connects the power amplifier 52e and the first bandpass filter in the multiplexer 52i. The switch 52h electrically connects the first band pass filter in the multiplexer 52i and the high pass filter in the multiplexer 52c. The power amplifier 52e receives and amplifies the LTE band 7 transmission signal from the RFIC 101 via the terminal 5d, and outputs the amplified LTE band 7 transmission signal to the first bandpass filter in the multiplexer 52i via the switch 52f. To do. The first band-pass filter in the multiplexer 52i passes the amplified LTE band 7 transmission signal through the band and outputs it to the high-pass filter in the multiplexer 52c via the switch 52h. The high-pass filter in the multiplexer 52 c passes the amplified LTE band 7 transmission signal through the band and outputs it to the first band-pass filter in the multiplexer 55.

  When transmitting signals in the LTE band 41, the switch 52f electrically connects the power amplifier 52e and the band-pass filter 52g. The switch 52h electrically connects the band pass filter 52g and the high pass filter in the multiplexer 52c. The power amplifier 52e receives and amplifies the transmission signal of the LTE band 41 from the RFIC 101 via the terminal 5d, and outputs the amplified transmission signal of the LTE band 41 to the bandpass filter 52g via the switch 52f. The band-pass filter 52g passes the amplified transmission signal of the LTE band 41 through the band and outputs it to the high-pass filter in the multiplexer 52c via the switch 52h. The high-pass filter in the multiplexer 52 c passes the amplified transmission signal of the LTE band 41 through the band and outputs it to the first band-pass filter in the multiplexer 55.

  When receiving the LTE band 7 signal, the switch 52h electrically connects the high-pass filter in the multiplexer 52c and the second band-pass filter in the multiplexer 52i. The switch 52j electrically connects the second band pass filter in the multiplexer 52i and the low noise amplifier 52k. The low noise amplifier 52k receives and amplifies the LTE band 7 reception signal from the second band pass filter of the multiplexer 52i via the switch 52j, and outputs the amplified LTE band 7 reception signal to the RFIC 101 via the terminal 5e. .

  When receiving the signal of the LTE band 41, the switch 52h electrically connects the high-pass filter in the multiplexer 52c and the band-pass filter 52g. The switch 52f electrically connects the band pass filter 52g and the switch 52j. The switch 52j electrically connects the switch 52f and the low noise amplifier 52k. The low noise amplifier 52k receives and amplifies the received signal of the LTE band 41 from the band pass filter 52g via the switches 52f and 52j, and outputs the amplified received signal of the LTE band 41 to the RFIC 101 via the terminal 5e.

  The circuit components of the 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53 are the same as those of the 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 31 (see FIG. 3). A description thereof will be omitted.

  The 5 GNR signal and LTE ultra high frequency signal transmitting / receiving circuit 53 receives and amplifies a 5 GNR 4.5 GHz to 4.99 GHz transmission signal from the RFIC 102 via the terminal 5f, and amplifies the 5 GNR 4.5 GHz to 4.99 GHz after amplification. Are transmitted to the second band-pass filter in the multiplexer 55.

  The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53 receives and amplifies the LTE ultra-high frequency band transmission signal from the RFIC 101 via the terminal 5g, and the amplified LTE ultra-high frequency band transmission signal is supplied to the second signal in the multiplexer 55. Output to bandpass filter.

  The 5 GNR signal and LTE ultra high frequency signal transmission / reception circuit 53 receives and amplifies the received signal from 4.5 GHz to 4.99 GHz of 5 GNR from the second band pass filter in the multiplexer 55, and the amplified 5 GNR of 4.5 GHz To 4.99 GHz received signal is output to the RFIC 102 via the terminal 5h.

  The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53 receives and amplifies the LTE ultra-high frequency band reception signal from the second bandpass filter in the multiplexer 55, and the amplified LTE ultra-high frequency band reception signal is connected to the terminal 5i. And output to the RFIC 101.

  The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54 includes power amplifiers 54a and 54c, switches 54b and 54d, a band-pass filter 54e, and a low noise amplifier 54f.

  The band pass filter 54e passes the eLAA signal and the signal in the WiFi 5 GHz region.

  The switches 54b and 54d are single port dual throw switches.

  During eLAA signal transmission, the switch 54b electrically connects the power amplifier 54a and the power amplifier 54c. The switch 54d electrically connects the power amplifier 54c and the bandpass filter 54e. The power amplifier 54a receives and amplifies the eLAA transmission signal from the RFIC 101 via the terminal 5j, and outputs the amplified eLAA transmission signal to the power amplifier 54c via the switch 54b. The power amplifier 54c receives and further amplifies the eLAA transmission signal amplified by the power amplifier 54a from the power amplifier 54a via the switch 54b, and outputs the amplified eLAA transmission signal to the bandpass filter 54e via the switch 54d. . The band-pass filter 54 e passes the eLAA transmission signal amplified by the power amplifier 54 c through the band and outputs it to the high-pass filter in the multiplexer 55.

  When transmitting a signal in the 5 GHz range of WiFi, the switch 54b electrically connects the terminal 5k and the power amplifier 54c. The switch 54d electrically connects the power amplifier 54c and the bandpass filter 54e. The power amplifier 54c receives and amplifies the WiFi 5 GHz band transmission signal from the RFIC 103 via the terminal 5k and the switch 54b, and outputs the amplified WiFi 5 GHz band transmission signal to the bandpass filter 54e via the switch 54d. The band-pass filter 54 e passes the transmission signal in the 5 GHz band of WiFi amplified by the power amplifier 54 c and outputs it to the high-pass filter in the multiplexer 55.

  The switch 54d electrically connects the band-pass filter 54e and the low-noise amplifier 54f when receiving an eLAA signal or a WiFi signal of 5 GHz. The band-pass filter 54e passes the eLAA reception signal received from the high-pass filter in the multiplexer 55 or the reception signal in the 5 GHz band of WiFi, and outputs it to the low-noise amplifier 54f via the switch 54d. The low noise amplifier 54f amplifies the eLAA reception signal or the reception signal in the 5 GHz range of WiFi, and outputs the amplified eLAA reception signal to the RFIC 101 via the terminal 5l. The low noise amplifier 54f amplifies the received signal in the 5 GHz band of WiFi, and outputs the amplified received signal in the 5 GHz band of WiFi to the RFIC 103 via the terminal 5m.

  It is preferable that the LTE high frequency band signal / WiFi 2.4 GHz band signal transmission / reception circuit 52 and the 5 GNR signal / LTE ultra high frequency band signal transmission / reception circuit 53 are isolated. Isolation is exemplified by separating a physical distance or separating with a metal shield. Since the frequency of the second harmonic of the LTE band 7 or 41 or the 2.4 GHz signal of WiFi is close to the frequency of the 5 GNR or LTE ultra high frequency signal, the 5 GNR signal and the LTE ultra high frequency signal This is because the transmission / reception circuit 53 may be affected by the second harmonic of the LTE band 7 or 41 or the 2.4 GHz signal of WiFi.

  Further, it is preferable that the 5 GNR signal and LTE ultra high frequency signal transmitting / receiving circuit 53 and the eLAA signal and WiFi 5 GHz signal transmitting / receiving circuit 54 are isolated. Since the frequency of the 5 GNR or LTE ultra high frequency signal is close to the frequency of the eLAA or WiFi 5 GHz signal, the 5 GNR signal and LTE ultra high frequency signal transmitting / receiving circuit 53, the eLAA signal and WiFi 5 GHz signal transmitting / receiving circuit 54 This is because they may affect each other. However, when performing transmission / reception of signals in the 5 GNR or LTE ultra-high frequency range and transmission / reception of signals in the eLAA or WiFi 5 GHz range in a time division manner, isolation is not necessary.

  FIG. 7 is a diagram illustrating a configuration of a fifth circuit of the high-frequency signal transmission / reception circuit according to the first embodiment.

  The LTE medium / high frequency band signal receiving circuit 61, the 5GNR signal and the LTE ultra-high frequency band signal transmitting / receiving circuit 62, the eLAA signal and the WiFi 5 GHz band signal transmitting / receiving circuit 63, and the multiplexer 64 are configured as one module. It is not limited to. The LTE medium / high frequency band signal receiving circuit 61, 5GNR signal and LTE ultra-high frequency band signal transmitting / receiving circuit 62, eLAA signal and WiFi 5 GHz band signal transmitting / receiving circuit 63, and multiplexer 64 may be separate modules.

  The LTE medium / high frequency band signal receiving circuit 61 includes a multiplexer 61a, low noise amplifiers 61b, 61d, 61e and 61f, and a switch 61c.

  The multiplexer 61a is a one-to-four quadplexer. The multiplexer 61a electrically connects the low-pass filter in the multiplexer 64 and the low-noise amplifiers 61b, 61d, 61e, and 61f.

  The multiplexer 61a includes a first band pass filter, a second band pass filter, a third band pass filter, and a fourth band pass filter. The first band pass filter passes the received signals of LTE bands 7 and 41. The second band-pass filter passes the received signal of the LTE band 21. The third band-pass filter passes the received signal of the LTE band 3. The fourth band-pass filter passes the received signal of the LTE band 1.

  The switch 61c is a single port dual throw switch.

  When receiving the signal of the LTE band 7 or 41, the switch 61c electrically connects the low noise amplifier 61b and the terminal 6a. The low noise amplifier 61b receives and amplifies the received signal of the LTE band 7 or 41 from the first band pass filter of the multiplexer 61a, and outputs the amplified received signal of the LTE band 7 or 41 to the RFIC 101 via the terminal 6a. .

  When receiving the signal of the LTE band 21, the switch 61c electrically connects the low noise amplifier 61d and the terminal 6a. The low noise amplifier 61d receives and amplifies the received signal of the LTE band 21 from the second band pass filter of the multiplexer 61a, and outputs the amplified received signal of the LTE band 21 to the RFIC 101 via the terminal 6a.

  The low noise amplifier 61e receives and amplifies the LTE band 3 received signal from the third bandpass filter of the multiplexer 61a, and outputs the amplified LTE band 3 received signal to the RFIC 101 via the terminal 6b.

  The low-noise amplifier 61f receives and amplifies the LTE band 1 received signal from the fourth bandpass filter of the multiplexer 61a, and outputs the amplified LTE band 1 received signal to the RFIC 101 via the terminal 6c.

  The circuit components of the 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 62 are the same as those of the 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 31 (see FIG. 3). A description thereof will be omitted.

  The 5 GNR signal and LTE signal transmission / reception circuit 62 receives and amplifies a 5 GNR 4.5 GHz to 4.99 GHz transmission signal from the RFIC 102 via the terminal 6d, and amplifies the 5 GNR 4.5 GHz to 4.99 GHz after amplification. Are transmitted to a bandpass filter in the multiplexer 64.

  The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 62 receives and amplifies the LTE ultra-high frequency band transmission signal from the RFIC 101 via the terminal 6e, and band-passes the amplified LTE ultra-high frequency band transmission signal in the multiplexer 64. Output to the filter.

  The 5 GNR signal and LTE ultra high frequency signal transmission / reception circuit 62 receives and amplifies the received signal from 4.5 GHz to 4.99 GHz of 5 GNR from the bandpass filter in the multiplexer 64, and 4 to 4.5 GHz from 5 GHz after the amplification. .99 GHz reception signal is output to the RFIC 102 via the terminal 6f.

  The 5GNR signal and LTE ultra-high frequency band signal transmitting / receiving circuit 62 receives and amplifies the LTE ultra-high frequency band received signal from the bandpass filter in the multiplexer 64, and the amplified LTE ultra-high frequency band received signal via the terminal 6g. Output to the RFIC 101.

  The circuit components of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63 are the same as the circuit components of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54 (see FIG. 5). To do.

  The eLAA signal and WiFi 5 GHz signal transmission / reception circuit 63 receives and amplifies the eLAA transmission signal from the RFIC 101 via the terminal 6h, and outputs the amplified eLAA transmission signal to the high-pass filter in the multiplexer 64.

  The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63 receives and amplifies the WiFi 5 GHz band transmission signal from the RFIC 103 via the terminal 6 i and outputs the amplified WiFi 5 GHz band transmission signal to the high-pass filter in the multiplexer 64. .

  The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63 amplifies the eLAA reception signal received from the high-pass filter in the multiplexer 64, and outputs the amplified eLAA reception signal to the RFIC 101 via the terminal 6j.

  The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63 amplifies the reception signal in the 5 GHz band of WiFi received from the high pass filter in the multiplexer 64, and outputs the amplified reception signal in the 5 GHz band of WiFi to the RFIC 103 via the terminal 6k. .

  It is preferable that the LTE medium / high frequency band signal receiving circuit 61 and the 5GNR signal and the LTE ultra-high frequency band signal transmitting / receiving circuit 62 are isolated from each other. Since the frequency of the second harmonic of the signal of the LTE band 7, 41 or 21 is close to the frequency of the 5GNR or LTE ultra-high frequency signal, the 5GNR signal and LTE ultra-high frequency signal transmitting / receiving circuit 62 is This is because there is a possibility of being influenced by the second harmonic of the signal of the band 7, 41 or 21.

  Further, it is preferable that the 5 GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 62 and the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63 are isolated. Since the frequency of the 5 GNR or LTE ultra high frequency signal is close to the frequency of the eLAA or WiFi 5 GHz signal, the 5 GNR signal and LTE ultra high frequency signal transmitting / receiving circuit 62 and the eLAA signal and WiFi 5 GHz signal transmitting / receiving circuit 63 This is because they may affect each other. However, when performing transmission / reception of signals in the 5 GNR or LTE ultra-high frequency range and transmission / reception of signals in the eLAA or WiFi 5 GHz range in a time division manner, isolation is not necessary.

  Further, the GPS signal receiving circuit 51 (see FIG. 6) may be included in the fifth circuit 6 instead of the fourth circuit 5. In this case, the multiplexer 55 (see FIG. 6) of the fourth circuit 5 may be a 1: 3 triplexer, and the multiplexer 64 of the fifth circuit 6 may be a 1: 4 quadplexer.

  FIG. 8 is a diagram illustrating a configuration of a sixth circuit of the high-frequency signal transmitting and receiving circuit according to the embodiment.

  The LTE mid-frequency signal receiving circuit 71, the 5GNR signal and the LTE ultra-high frequency signal transmitting / receiving circuit 72, and the multiplexer 73 are one module, but the present disclosure is not limited to this. The LTE middle frequency band signal receiving circuit 71, 5GNR signal and LTE ultra-high frequency band signal transmitting / receiving circuit 72, and the multiplexer 73 may be separate modules.

  The LTE middle frequency band signal receiving circuit 71 includes a multiplexer 71a and low noise amplifiers 71b, 71c and 71d.

  The multiplexer 71a is a 1: 3 triplexer. The multiplexer 71a electrically connects the low pass filter in the multiplexer 73 and the low noise amplifiers 71b, 71c and 71d.

  The multiplexer 71a includes a first band pass filter, a second band pass filter, and a third band pass filter. The first band-pass filter passes the received signal of the LTE band 21. The second band-pass filter passes the received signal of the LTE band 3. The third band-pass filter passes the received signal of LTE band 1.

  The low noise amplifier 71b receives the received signal of the LTE band 21 from the first band pass filter in the multiplexer 71a and outputs the received signal to the RFIC 101 via the terminal 7a.

  The low noise amplifier 71c receives an LTE band 3 received signal from the second bandpass filter in the multiplexer 71a and outputs the received signal to the RFIC 101 via the terminal 7b.

  The low noise amplifier 71d receives an LTE band 1 reception signal from the third bandpass filter in the multiplexer 71a and outputs the received signal to the RFIC 101 via the terminal 7c.

  The circuit components of the 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 72 are the same as those of the 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 31 (see FIG. 3). A description thereof will be omitted.

  The 5 GNR signal and LTE ultra high frequency signal transmission / reception circuit 72 receives and amplifies a 5 GNR 4.5 GHz to 4.99 GHz transmission signal from the RFIC 102 via the terminal 7d, and amplifies the 5 GNR 4.5 GHz to 4.99 GHz after amplification. Are transmitted to the high-pass filter in the multiplexer 73.

  The 5GNR signal and LTE ultra-high frequency band signal transmitting / receiving circuit 72 receives and amplifies the LTE ultra-high frequency band transmission signal from the RFIC 101 via the terminal 7e, and amplifies the amplified LTE ultra-high frequency band transmission signal in the multiplexer 73. Output to.

  The 5 GNR signal and LTE ultra-high frequency signal transmission / reception circuit 72 receives and amplifies the received signal from 4.5 GHz to 4.99 GHz of 5 GNR from the high pass filter in the multiplexer 73, and the amplified 5 GNR from 4.5 GHz to 4.5 GHz. A 99 GHz reception signal is output to the RFIC 102 via the terminal 7f.

  The 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 72 receives and amplifies the LTE ultra-high frequency band reception signal from the high-pass filter in the multiplexer 73, and the amplified LTE ultra-high frequency band reception signal is connected to the RFIC 101 via the terminal 7g. Output to.

  In addition, it is preferable that the LTE middle frequency band signal receiving circuit 71 and the 5 GNR signal and the LTE ultra-high frequency band signal transmitting / receiving circuit 72 are isolated. Since the frequency of the second harmonic of the signal of the LTE band 21, 3 or 1 is close to the frequency of the 5GNR or LTE ultra-high frequency signal, the 5GNR signal and LTE ultra-high frequency signal transmitting / receiving circuit 72 is This is because there is a possibility of being influenced by the second harmonic of the signal of the band 21, 3 or 1.

  As described above, each of the second circuit 3, the fourth circuit 5, the fifth circuit 6, and the sixth circuit 7 can transmit and receive a 5GNR signal and an LTE ultra-high frequency band signal. That is, the high-frequency signal transmission / reception circuit 1 can realize 4 × 4 MIMO communication (Multiple-Input and Multiple-Output) in 5 GNR and LTE ultra-high frequency regions. Thereby, the high frequency signal transmission / reception circuit 1 can improve communication quality and communication speed in the 5 GNR and LTE ultra-high frequency regions.

  In the 5 GNR signal and LTE ultra-high frequency band signal transmission / reception circuits 31, 53, 62 and 72, the power amplifier 31 c is shared by the 5 GNR 3.5 GHz band and LTE ultra-high frequency band transmission signals. Further, the low noise amplifier 31j is commonly used for amplification of reception signals in the 3.5 GHz region of 5 GNR and the LTE ultra-high frequency region. As a result, the high-frequency signal transmitting / receiving circuit 1 can reduce the size and cost of the circuit.

  Moreover, the high frequency signal transmission / reception circuit 1 can suppress the number of circuit elements added to the existing LTE front-end circuit. As a result, the high-frequency signal transmitting / receiving circuit 1 can reduce the size and cost of the circuit.

  Further, the high-frequency signal transmission / reception circuit 1 can realize LTE, WiFi, 5GNR, and LTE ultra-high frequency communication with as few as six antennas, the first antenna 11 to the sixth antenna 16. Thereby, the high frequency signal transmission / reception circuit 1 can achieve size reduction and cost reduction of the mobile communication device.

  The second circuit 3 is directly connected to the second antenna terminal 12a without going through a multiplexer. Therefore, the second circuit 3 can suppress attenuation of signals in the 5 GNR and LTE ultra-high frequency regions. Thereby, the high frequency signal transmission / reception circuit 1 can improve communication quality in the 5 GNR and LTE ultra-high frequency regions.

(First modification)
FIG. 9 is a diagram illustrating a configuration of a fourth circuit of the high-frequency signal transmission / reception circuit according to the first modification of the first embodiment. FIG. 10 is a diagram illustrating a configuration of a fifth circuit of the high-frequency signal transmitting / receiving circuit according to the first modification of the first embodiment. The first circuit to the third circuit and the sixth circuit of the high-frequency signal transmission / reception circuit of the first modification are the same as the first circuit 2 to the third circuit 4 and the sixth circuit 7 of the high-frequency signal transmission / reception circuit 1 of the embodiment. Since it is the same, illustration and description are omitted.

  Referring to FIG. 9, the fourth circuit 5A includes an eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54A instead of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54 (see FIG. 6). The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54A further includes a switch 54g as compared with the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54.

  The switch 54g is a single port dual throw switch.

  When receiving an eLAA signal, the switch 54d electrically connects the band-pass filter 54e and the low-noise amplifier 54f. The switch 54g electrically connects the low noise amplifier 54f and the terminal 5l. The band pass filter 54e passes the eLAA reception signal received from the high pass filter in the multiplexer 55 through the band, and outputs it to the low noise amplifier 54f via the switch 54d. The low noise amplifier 54f amplifies the eLAA reception signal and outputs the amplified eLAA reception signal to the RFIC 101 via the switch 54g and the terminal 5l.

  When receiving a signal in the 5 GHz range of WiFi, the switch 54d electrically connects the bandpass filter 54e and the low noise amplifier 54f. The switch 54g electrically connects the low noise amplifier 54f and the terminal 5m. The band-pass filter 54e passes the received signal in the 5 GHz band of WiFi received from the high-pass filter in the multiplexer 55, and outputs it to the low-noise amplifier 54f via the switch 54d. The low noise amplifier 54f amplifies the received signal in the 5 GHz band of WiFi, and outputs the amplified received signal in the 5 GHz band of WiFi to the RFIC 103 via the terminal 5m.

  Referring to FIG. 10, the fifth circuit 6A includes an eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63A instead of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63 (see FIG. 7). The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63A further includes a switch 54g as compared with the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63.

  Since the operation of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63A is the same as the operation of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54A, description thereof will be omitted.

  In the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54 of the first embodiment, an eLAA reception signal and a WiFi 5 GHz band reception signal are output from both terminals 5l and 5m. Therefore, when both eLAA signal reception and WiFi 5 GHz signal reception are performed, it is necessary for the RFICs 101 and 103 to separate the eLAA reception signal and the WiFi 5 GHz signal reception.

  On the other hand, in the eLAA signal and WiFi 5 GHz signal transmission / reception circuit 54A of the first modification, the switch 54g can separate the eLAA reception signal and the WiFi reception signal in the 5 GHz region. Accordingly, only the eLAA reception signal is output from the terminal 5l, and only the reception signal in the 5 GHz band of WiFi is output from the terminal 5m. As a result, the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54A can eliminate the need for the RFICs 101 and 103 to separate the eLAA reception signal and the WiFi 5 GHz band reception signal.

(Second modification)
FIG. 11 is a diagram illustrating a configuration of a fourth circuit of the high-frequency signal transmitting and receiving circuit according to the second modification of the first embodiment. The first to third circuits and the fifth to sixth circuits of the high-frequency signal transmission / reception circuit of the second modification are the same as the first circuit 2 to the third circuit 4 and the fourth circuit of the high-frequency signal transmission / reception circuit 1 of the embodiment. Since it is the same as the 5th circuit 6 to the 6th circuit 7, illustration and description are omitted.

Referring to FIG. 11, LTE high frequency band signal and WiFi2.4GHz band signal transmitting and receiving circuit 52 includes a WiFi2.4GHz band signal transmitting and receiving circuit 52 _1, and LTE high frequency band signal transmitting and receiving circuit 52 _2, the are separated.

WiFi2.4GHz band signal transmitting and receiving circuit 52 ₁ includes a power amplifier 52a, and the switch 52 b, a low noise amplifier 52 d, a. LTE high frequency range signal transmitter 52 ₂ includes a multiplexer 52c, a power amplifier 52e, a switch 52f, a band-pass filter 52 g, a switch 52h, and a multiplexer 52i, a switch 52j, a low noise amplifier 52k, the.

WiFi2.4GHz range signal transmitter 52 ₁ and LTE high frequency range signal transmitter 52 ₂ is a single module, the present disclosure is not limited thereto. WiFi2.4GHz range signal transmitter 52 ₁ and LTE high frequency range signal transmitter 52 ₂ each may be a separate module.

  The fourth circuit 5B includes an eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54B instead of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54 (see FIG. 6).

  The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54B may be a module.

  Compared with the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54, the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54B replaces the power amplifier 54a, the switch 54b, the power amplifier 54c and the switch 54d with a power amplifier 54h, a power amplifier 54i and A switch 54j is included.

  The switch 54j is a single port triple throw switch.

  When transmitting an eLAA signal, the switch 54j electrically connects the power amplifier 54h and the bandpass filter 54e. The power amplifier 54h receives and amplifies the eLAA transmission signal from the RFIC 101 via the terminal 5j, and outputs the amplified eLAA transmission signal to the bandpass filter 54e via the switch 54j. The band-pass filter 54 e passes the eLAA transmission signal amplified by the power amplifier 54 h through the band and outputs it to the high-pass filter in the multiplexer 55.

  At the time of WiFi signal transmission in the 5 GHz band, the switch 54j electrically connects the power amplifier 54i and the bandpass filter 54e. The power amplifier 54i receives and amplifies the 5 GHz transmission signal of WiFi from the RFIC 103 via the terminal 5k, and outputs the amplified 5 GHz transmission signal of WiFi to the bandpass filter 54e via the switch 54j. The band pass filter 54 e passes the transmission signal in the 5 GHz band of WiFi amplified by the power amplifier 54 i and outputs it to the high pass filter in the multiplexer 55.

  The switch 54j electrically connects the band-pass filter 54e and the low noise amplifier 54f when receiving an eLAA signal or a WiFi signal of 5 GHz. The band-pass filter 54e passes the eLAA reception signal received from the high-pass filter in the multiplexer 55 or the reception signal in the 5 GHz band of WiFi, and outputs it to the low-noise amplifier 54f via the switch 54j. The low noise amplifier 54f amplifies the eLAA reception signal, and outputs the amplified eLAA reception signal to the RFIC 101 via the terminal 5l. The low noise amplifier 54f amplifies the received signal in the 5 GHz band of WiFi, and outputs the amplified received signal in the 5 GHz band of WiFi to the RFIC 103 via the terminal 5m.

  In the fourth circuit 5 of the first embodiment, the power amplifier 54c is shared by the amplification of the eLAA transmission signal and the WiFi 5 GHz band transmission signal. Therefore, the fourth circuit 5 may not be able to suitably amplify the eLAA transmission signal and the transmission signal in the WiFi 5 GHz region.

  On the other hand, in the fourth circuit 5B of the second modification, the power amplifier 54h amplifies the eLAA transmission signal, and the power amplifier 54i amplifies the WiFi 5 GHz transmission signal. Accordingly, the fourth circuit 5B can suitably amplify the eLAA transmission signal and the WiFi 5 GHz transmission signal.

  Note that the circuit configuration of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63 in the fifth circuit 6 may be the same as that of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54B in the fourth circuit 5B.

  Moreover, you may combine a 1st modification and a 2nd modification. That is, the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54B of the fourth circuit 5B of the second modification are the switches in the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54A of the fourth circuit 5A (see FIG. 9) of the first modification. 54g may be included.

  Further, the fourth circuit 5B of the second modification may not include the GPS signal receiving circuit 51, and the fifth circuit 6 may include the GPS signal receiving circuit 51.

(Third Modification)
FIG. 12 is a diagram illustrating a configuration of a fourth circuit of the high-frequency signal transmitting and receiving circuit according to the third modification example of the first embodiment. The first to third circuits and the fifth to sixth circuits of the high-frequency signal transmitting / receiving circuit of the third modification are the same as the first circuit 2 to the third circuit 4 of the high-frequency signal transmitting / receiving circuit 1 of the embodiment. Since it is the same as the 5th circuit 6 to the 6th circuit 7, illustration and description are omitted.

  Referring to FIG. 12, the fourth circuit 5C includes a 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53C instead of the 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53 (see FIG. 6). The fourth circuit 5C includes an eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54C instead of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54 (see FIG. 6).

  The 5 GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53C and the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54C are one module, but the present disclosure is not limited thereto. The 5 GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53C, and the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54C may be separate modules.

  The 5 GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53C further includes a power amplifier 31l as compared with the 5GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53.

  The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54C includes a power amplifier 54i and a switch 54j instead of the power amplifier 54a, the switch 54b, the power amplifier 54c and the switch 54d, as compared with the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54. .

  When the eLAA signal is transmitted, the switch 54j electrically connects the power amplifier 31l and the bandpass filter 54e. The power amplifier 31l receives and amplifies the eLAA transmission signal from the RFIC 101 via the terminal 5j, and outputs the amplified eLAA transmission signal to the bandpass filter 54e via the switch 54j. The band-pass filter 54 e passes the eLAA transmission signal amplified by the power amplifier 31 l through the band and outputs it to the high-pass filter in the multiplexer 55.

  At the time of WiFi signal transmission in the 5 GHz band, the switch 54j electrically connects the power amplifier 54i and the bandpass filter 54e. The power amplifier 54i receives and amplifies the 5 GHz transmission signal of WiFi from the RFIC 103 via the terminal 5k, and outputs the amplified 5 GHz transmission signal of WiFi to the bandpass filter 54e via the switch 54j. The band pass filter 54 e passes the transmission signal in the 5 GHz band of WiFi amplified by the power amplifier 54 i and outputs it to the high pass filter in the multiplexer 55.

  The switch 54j electrically connects the band-pass filter 54e and the low noise amplifier 54f when receiving an eLAA signal or a WiFi signal of 5 GHz. The band-pass filter 54e passes the eLAA reception signal received from the high-pass filter in the multiplexer 55 or the reception signal in the 5 GHz band of WiFi, and outputs it to the low-noise amplifier 54f via the switch 54j. The low noise amplifier 54f amplifies the eLAA reception signal, and outputs the amplified eLAA reception signal to the RFIC 101 via the terminal 5l. The low noise amplifier 54f amplifies the received signal in the 5 GHz band of WiFi, and outputs the amplified received signal in the 5 GHz band of WiFi to the RFIC 103 via the terminal 5m.

  In the fourth circuit 5 of the first embodiment, the power amplifier 54c is shared by the amplification of the eLAA transmission signal and the WiFi 5 GHz band transmission signal. Therefore, the fourth circuit 5 may not be able to suitably amplify the eLAA transmission signal and the transmission signal in the WiFi 5 GHz region.

  On the other hand, in the fourth circuit 5C of the third modified example, the power amplifier 31l amplifies the eLAA transmission signal, and the power amplifier 54i amplifies the WiFi 5 GHz transmission signal. Accordingly, the fourth circuit 5C can suitably amplify the eLAA transmission signal and the WiFi 5 GHz transmission signal.

  The circuit configuration of the 5 GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 62 in the fifth circuit 6 may be the same as the circuit configuration of the 5 GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53C in the fourth circuit 5C. good. Similarly, the circuit configuration of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63 in the fifth circuit 6 may be the same as that of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54C in the fourth circuit 5C.

  Moreover, you may combine a 1st modification and a 3rd modification. That is, the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54C of the fourth circuit 5C of the third modification are the switches in the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54A of the fourth circuit 5A (see FIG. 9) of the first modification. 54g may be included.

  The fourth circuit 5C of the third modification may not include the GPS signal receiving circuit 51, and the fifth circuit 6 may include the GPS signal receiving circuit 51.

(Fourth modification)
FIG. 13 is a diagram illustrating a configuration of a fourth circuit of the high-frequency signal transmitting and receiving circuit according to the fourth modification example of the first embodiment. The first to third circuits and the fifth to sixth circuits of the high-frequency signal transmitting / receiving circuit of the fourth modification are the same as the first circuit 2 to the third circuit 4 of the high-frequency signal transmitting / receiving circuit 1 of the embodiment. Since it is the same as the 5th circuit 6 to the 6th circuit 7, illustration and description are omitted.

  Referring to FIG. 13, the fourth circuit 5D includes an eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54D instead of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54 (see FIG. 6). The fourth circuit 5D further includes an eLAA transmission signal amplification circuit 56.

  The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54D and the eLAA transmission signal amplification circuit 56 are one module, but the present disclosure is not limited to this. The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54D and the eLAA transmission signal amplification circuit 56 may be separate modules.

  The eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54D includes a power amplifier 54i and a switch 54j instead of the power amplifier 54a, the switch 54b, the power amplifier 54c and the switch 54d, as compared with the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54. .

  The eLAA transmission signal amplification circuit 56 includes a power amplifier 56a.

  When transmitting an eLAA signal, the switch 54j electrically connects the power amplifier 56a and the bandpass filter 54e. The power amplifier 56a receives and amplifies the eLAA transmission signal from the RFIC 101 via the terminal 5j, and outputs the amplified eLAA transmission signal to the bandpass filter 54e via the switch 54j. The band-pass filter 54 e passes the eLAA transmission signal amplified by the power amplifier 56 a through the band and outputs it to the high-pass filter in the multiplexer 55.

  At the time of WiFi signal transmission in the 5 GHz band, the switch 54j electrically connects the power amplifier 54i and the bandpass filter 54e. The power amplifier 54i receives and amplifies the 5 GHz transmission signal of WiFi from the RFIC 103 via the terminal 5k, and outputs the amplified 5 GHz transmission signal of WiFi to the bandpass filter 54e via the switch 54j. The band pass filter 54 e passes the transmission signal in the 5 GHz band of WiFi amplified by the power amplifier 54 i and outputs it to the high pass filter in the multiplexer 55.

  The switch 54j electrically connects the band-pass filter 54e and the low noise amplifier 54f when receiving an eLAA signal or a WiFi signal of 5 GHz. The band-pass filter 54e passes the eLAA reception signal received from the high-pass filter in the multiplexer 55 or the reception signal in the 5 GHz band of WiFi, and outputs it to the low-noise amplifier 54f via the switch 54j. The low noise amplifier 54f amplifies the eLAA reception signal, and outputs the amplified eLAA reception signal to the RFIC 101 via the terminal 5l. The low noise amplifier 54f amplifies the received signal in the 5 GHz band of WiFi, and outputs the amplified received signal in the 5 GHz band of WiFi to the RFIC 103 via the terminal 5m.

  In the fourth circuit 5 of the first embodiment, the power amplifier 54c is shared by the amplification of the eLAA transmission signal and the WiFi 5 GHz band transmission signal. Therefore, the fourth circuit 5 may not be able to suitably amplify the eLAA transmission signal and the transmission signal in the WiFi 5 GHz region.

  On the other hand, in the fourth circuit 5D of the fourth modified example, the power amplifier 56a amplifies the eLAA transmission signal, and the power amplifier 54i amplifies the transmission signal in the WiFi 5 GHz region. Therefore, the fourth circuit 5D can suitably amplify the eLAA transmission signal and the WiFi 5 GHz transmission signal.

  The circuit configuration of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63 in the fifth circuit 6 may be the same as that of the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54D in the fourth circuit 5D. Similarly, the fifth circuit 6 may further include an eLAA transmission signal amplification circuit 56 in the fourth circuit 5D.

  Moreover, you may combine a 1st modification and a 4th modification. That is, the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54D of the fourth circuit 5D of the fourth modification are the switches in the eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 54A of the fourth circuit 5A (see FIG. 9) of the first modification. 54g may be included.

  Further, the fourth circuit 5D of the fourth modification may not include the GPS signal receiving circuit 51, and the fifth circuit 6 may include the GPS signal receiving circuit 51.

  In the present disclosure, the configuration of 4 × 4 MIMO with 5 GNR is described, but in the case of 2 × 2 MIMO with 5 GNR, any two of the four circuit configurations corresponding to 5 GNR may be deleted. Is possible.

(Second Embodiment)
FIG. 14 is a diagram illustrating a configuration of the high-frequency signal transmission / reception circuit according to the second embodiment. In the second embodiment, the same components as those in the first embodiment and the first to fourth modifications are denoted by the same reference numerals, and description thereof is omitted.

  The high-frequency signal transmission / reception circuit 1E includes a first circuit 2E instead of the first circuit 2.

  The first circuit 2E includes an LTE low frequency band signal transmission / reception circuit 21, an LTE middle frequency band signal transmission / reception circuit 22, and a multiplexer 24E. Compared with the first circuit 2, the first circuit 2 </ b> E does not include the LTE high frequency band signal transmission / reception circuit 23.

  The multiplexer 24E is a one-to-two diplexer. The multiplexer 24E electrically connects the first antenna terminal 11a and the LTE low frequency band signal transmission / reception circuit 21 and the LTE middle frequency band signal transmission / reception circuit 22.

  The multiplexer 24E includes a low pass filter and a high pass filter. The low-pass filter passes the LTE low frequency signal. The high-pass filter passes the LTE mid-frequency signal.

  The high-frequency signal transmission / reception circuit 1 </ b> E includes a second circuit 3.

  The high-frequency signal transmission / reception circuit 1E includes a third circuit 4E instead of the third circuit 4.

  The third circuit 4E includes an LTE low frequency band signal receiving circuit 41, an LTE medium / high frequency band signal receiving circuit 42E, and a multiplexer 43.

  The high-frequency signal transmitting / receiving circuit 1E includes a fourth circuit 5E instead of the fourth circuit 5.

  The fourth circuit 5E includes a WiFi 2.4 GHz signal transmission / reception circuit 52E, a 5GNR signal and LTE ultra-high frequency signal transmission / reception circuit 53, and a multiplexer 55E. Compared to the fourth circuit 5, the fourth circuit 5 </ b> E does not include the eLAA signal and the WiFi 5 GHz band signal transmission / reception circuit 54.

  The multiplexer 55E is a one-to-two diplexer. The multiplexer 55E electrically connects the fourth antenna terminal 14a, the WiFi 2.4 GHz band signal transmission / reception circuit 52E, and the 5 GNR signal and LTE ultra-high frequency band signal transmission / reception circuit 53.

  The multiplexer 55E includes a low pass filter and a high pass filter. The low-pass filter passes the WiFi 2.4 GHz band signal. The high pass filter passes the 5GNR signal and the LTE ultra high frequency signal.

  The high-frequency signal transmission / reception circuit 1E includes a fifth circuit 6E instead of the fifth circuit 6.

  The fifth circuit 6E includes a 5GNR signal and LTE ultra high frequency band signal transmission / reception circuit 62, an eLAA signal and WiFi 5 GHz band signal transmission / reception circuit 63, and a multiplexer 64E. Compared with the fifth circuit 6, the fifth circuit 6 </ b> E does not include the LTE medium / high frequency band signal receiving circuit 61.

  The multiplexer 64E is a one-to-two diplexer. The multiplexer 64E electrically connects the fifth antenna terminal 15a, the 5GNR signal and LTE ultra-high frequency band signal transmitting / receiving circuit 62, and the eLAA signal and WiFi 5 GHz band signal transmitting / receiving circuit 63.

  The multiplexer 64E includes a low pass filter and a high pass filter. The low-pass filter passes the 5GNR signal and the LTE ultra-high frequency signal. The high pass filter passes the eLAA signal and the WiFi 5 GHz band signal.

  The high-frequency signal transmission / reception circuit 1 </ b> E includes a sixth circuit 7.

  FIG. 15 is a diagram illustrating a configuration of a third circuit of the high-frequency signal transmitting and receiving circuit according to the second embodiment.

  The LTE mid-high frequency band signal receiving circuit 42E does not include the low-noise amplifier 42j, the switches 42e and 42i, and the power amplifier 42h, compared with the LTE mid-high frequency band signal receiving and WiFi 2.4 GHz band signal transmitting / receiving circuit 42. The low noise amplifier 42f is electrically connected to the multiplexer 42a.

  FIG. 16 is a diagram illustrating a configuration of a fourth circuit of the high-frequency signal transmission / reception circuit according to the second embodiment.

  The WiFi 2.4 GHz signal transmission / reception circuit 52E has a power amplifier 52e, switches 52f, 52h, and 52j, multiplexers 52c and 52i, and a low noise amplifier compared to the LTE high frequency signal and WiFi 2.4GHz signal transmission / reception circuit 52. 52k and the band pass filter 52g are not included. The switch 52b is electrically connected to the multiplexer 55E.

  The high-frequency signal transmission / reception circuit 1E according to the second embodiment has the same effects as the high-frequency signal transmission / reception circuit 1 according to the first embodiment.

  The above-described embodiment is intended to facilitate understanding of the present invention, and is not intended to limit the present invention. The present invention can be changed / improved without departing from the spirit thereof, and the present invention includes equivalents thereof.

DESCRIPTION OF SYMBOLS 1, 1E High frequency signal transmission / reception circuit 2, 2E 1st circuit 3 2nd circuit 4, 4E 3rd circuit 5, 5A, 5B, 5C, 5D, 5E 4th circuit 6, 6A, 6E 5th circuit 7 6th circuit 11 1st antenna 12 2nd antenna 13 3rd antenna 14 4th antenna 15 5th antenna 16 6th antenna 11a 1st antenna terminal 12a 2nd antenna terminal 13a 3rd antenna terminal 14a 4th antenna terminal 15a 5th antenna terminal 16a 1st 6 antenna terminals 21 LTE low frequency signal transmission / reception circuit 22 LTE middle frequency signal transmission / reception circuit 23 LTE high frequency signal transmission / reception circuit 24, 43, 55, 64, 73 Multiplexer 31 5 GNR signal and LTE ultra high frequency signal transmission / reception circuit 41 LTE low frequency signal reception circuit 42 LTE medium and high frequency signal reception and IF 2.4 GHz signal transmission / reception circuit 42E LTE medium / high frequency signal reception circuit 51 GPS signal reception circuit 52 LTE high frequency signal / WiFi 2.4 GHz signal transmission / reception circuit 52E WiFi 2.4 GHz signal transmission / reception circuit 53 5GNR signal and LTE ultra-high frequency Area signal transmission / reception circuit 54, 54A, 54B, 54C, 54D eLAA signal and WiFi 5GHz area signal transmission / reception circuit 56 eLAA transmission signal amplification circuit 61 LTE middle and high frequency area signal reception circuit 62 5GNR signal and LTE ultra high frequency area signal transmission / reception circuit 63 eLAA signal And WiFi 5 GHz signal transmission / reception circuit 71 LTE medium frequency signal reception circuit 72 5 GNR signal and LTE ultra-high frequency signal transmission / reception circuit 101, 102, 103, 104 High frequency integrated circuit

Claims (2)

A high-frequency signal transmission / reception circuit that transmits and receives signals between the first to sixth antenna terminals and a plurality of terminals connected to the high-frequency circuit,
Including first to sixth circuits respectively connected to the first to sixth antenna terminals,
One of the first to sixth circuits performs only transmission / reception of time division multiplex communication signals.
High-frequency signal transmission / reception circuit. Each of the first to sixth circuits amplifies one or a plurality of power amplifiers that amplify signals to be transmitted to the first to sixth antenna terminals, or signals received from the first to sixth antenna terminals. Including one or more low noise amplifiers,
The high frequency signal transmission / reception circuit according to claim 1.

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