JP2016208311A - Wireless terminal and wireless communication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wireless terminal and a wireless communication method capable of executing both a function for transmitting/receiving a signal and a diversity reception function by using a plurality of frequency bands.SOLUTION: A duplexer 15 receives a transmission signal of a first frequency band from a wireless processing part 5, and outputs the transmission signal to a first antenna ANT, and receives a signal from the first antenna ANT1, and outputs a reception signal of a third frequency band to a wireless processing part 5. A quadplexer 31 receives a transmission signal of a second frequency band from the wireless processing part 5, and outputs the transmission signal to a second antenna ANT 2, and receives a signal from the second antenna ANT 2, and outputs the reception signal of the third frequency band and a reception signal of a fourth frequency band to a wireless processing part 6. A filter 14 receives a signal from a third antenna ANT 3, and outputs the reception signal of the fourth frequency band to the wireless processing part 5.SELECTED DRAWING: Figure 7

Description

  The present disclosure relates to a wireless terminal and a wireless communication method.

  Conventionally, wireless terminals that transmit and receive signals using a plurality of frequency bands are known. For example, Patent Document 1 is compatible with two wireless communication networks having different uplink frequency bands and downlink frequency bands, and simultaneously transmits a plurality of uplink modulation transmission signals and receives a plurality of downlink modulation receptions. A wireless terminal capable of simultaneously receiving signals is disclosed.

JP 2011-119981 A

  However, Patent Document 1 does not disclose a wireless terminal capable of executing both a function for transmitting and receiving signals using a plurality of frequency bands and a diversity reception function.

  Therefore, an object of the present disclosure is to provide a wireless terminal and a wireless communication method capable of executing both a function of transmitting / receiving a signal using a plurality of frequency bands and a diversity receiving function.

  The wireless terminal according to an embodiment is a wireless terminal capable of transmitting using the first frequency band and the second frequency band and receiving using the third frequency band and the fourth frequency band. The wireless terminal performs frequency conversion on the first antenna, the second antenna, the third antenna, and the two baseband signals of the two systems to transmit the first frequency band transmission signal and the second frequency band. A radio processing unit configured to output a transmission signal; a baseband processing unit that performs baseband processing on a downlink signal received from the radio processing unit and an uplink signal output to the radio processing unit; and a radio A transmission signal in the first frequency band is received from the processing unit and output to the first antenna, and a reception signal in the third frequency band is wirelessly received in response to the signal from the first antenna. A first multiplexer configured to output to the processing unit, a transmission signal in the second frequency band received from the wireless processing unit, configured to output to the second antenna, and the second antenna Or The second multiplexer configured to output the received signal of the third frequency band and the received signal of the fourth frequency band to the wireless processing unit, and the signal from the third antenna And a filter configured to output the received signal in the fourth frequency band to the wireless processing unit. The radio processing unit frequency-converts the received signal in the third frequency band output from the first multiplexer and the received signal in the third frequency band output from the second multiplexer into baseband signals, respectively. The first signal and the second signal are generated, and the received signal in the fourth frequency band outputted from the second multiplexer and the received signal in the fourth frequency band outputted from the filter are respectively baseband signals. The third signal and the fourth signal are generated by performing frequency conversion to. The baseband processing unit performs diversity reception processing on the first signal and the second signal, and diversity reception processing on the third signal and the fourth signal, so as to obtain two types of downlink baseband signals. Configured.

  A wireless terminal according to another embodiment is a wireless terminal capable of transmitting using the first frequency band and the second frequency band and receiving using the third frequency band and the fourth frequency band. The wireless terminal performs frequency conversion on the first antenna, the second antenna, and the two upstream baseband signals, and outputs a transmission signal in the first frequency band and a transmission signal in the second frequency band. A baseband processing unit configured to perform baseband processing on a downstream signal received from the wireless processing unit and an upstream signal output to the wireless processing unit; a first multiplexer; A transmission signal in the second frequency band is received from the processing unit and output to the second antenna. A signal from the second antenna is received and the received signal in the third frequency band is A first state in which a second multiplexer configured to output a received signal in a frequency band of 4 to the wireless processing unit, a filter, a first antenna, and the first multiplexer are connected; of And a switch circuit switching is configured to be in the second state for connecting the antenna and filter. The first multiplexer is configured to receive a transmission signal in the first frequency band from the wireless processing unit and output the transmission signal to the first antenna when the switch circuit is in the first state. Upon reception of the signal from the antenna, the reception signal in the third frequency band is output to the wireless processing unit. The filter is configured to receive a signal from the first antenna and output a received signal in the fourth frequency band to the wireless processing unit when the switch circuit is in the second state.

  When the switch circuit is in the first state, the wireless processing unit receives the third frequency band reception signal output from the first multiplexer and the third frequency band reception signal output from the second multiplexer. Are converted into baseband signals to generate a first signal and a second signal, and a received signal in the fourth frequency band output from the second multiplexer is converted into a baseband signal. 3 signal is generated. When the switch circuit is in the first state, the baseband processing unit has two systems of downlinks including a signal obtained by performing diversity reception processing on the first signal and the second signal, and a third signal. Is configured to obtain a baseband signal. The wireless processing unit receives the fourth frequency band received signal output from the second multiplexer and the fourth frequency band received signal output from the filter, respectively, when the switch circuit is in the second state. Frequency-converted to a baseband signal to generate a fourth signal and a fifth signal, and a received signal in the third frequency band output from the second multiplexer is frequency-converted to a baseband signal to generate a sixth signal Is generated. When the switch circuit is in the second state, the baseband processing unit has two systems of downlinks including a signal obtained by performing diversity reception processing on the fourth signal and the fifth signal, and a sixth signal. Is configured to obtain a baseband signal.

  According to the wireless terminal of one embodiment, both of the function diversity reception functions for transmitting and receiving signals using a plurality of frequency bands can be executed.

It is a figure showing the structure of the radio | wireless terminal of embodiment. It is a figure showing the frequency band of the radio signal transmitted / received in the radio | wireless terminal of 1st Embodiment. It is a figure showing the structure of the antenna part and radio | wireless process part of 1st Embodiment. It is a figure showing the structure of 1st RF transceiver IC (Integrated Circuit) and 2nd RF transceiver IC. It is a figure showing the structure of B2-duplexer. It is a figure showing the structure of BC1-duplexer. It is a figure showing the structure of the antenna part and radio | wireless process part of 2nd Embodiment. It is a figure showing the structure of a quadplexer. It is a figure showing the structure of the antenna part and radio | wireless process part of 3rd Embodiment. It is a figure showing the structure of the antenna part and radio | wireless process part of 4th Embodiment. It is a figure showing the frequency band of the radio signal transmitted / received in the radio | wireless terminal of 5th Embodiment. It is a figure showing the structure of the antenna part and radio | wireless process part of 5th Embodiment. It is a figure showing the structure of the antenna part and radio | wireless process part of 6th Embodiment. It is a figure showing the frequency band of the radio signal transmitted / received in the radio | wireless terminal of 7th Embodiment. It is a figure showing the structure of the antenna part and radio | wireless process part of 7th Embodiment. It is a figure showing the structure of the antenna part and radio | wireless process part of 8th Embodiment. It is a figure showing the frequency band of the radio signal transmitted / received in the radio | wireless terminal of 9th Embodiment. It is a figure showing the structure of the antenna part and radio | wireless process part of 9th Embodiment. It is a figure showing the structure of the antenna part and radio | wireless process part of 10th Embodiment. It is a figure showing the frequency band of the radio signal transmitted / received in the radio | wireless terminal of 11th Embodiment. It is a figure showing the structure of the antenna part and radio | wireless process part of 11th Embodiment.

Hereinafter, embodiments will be described with reference to the drawings.
When transmitting, a wireless terminal according to an embodiment of the present disclosure arranges and transmits CDMA (Code Division Multiple Access) voice in one frequency band and transmits LTE (Long Term Evolution) data in another frequency band. Can be placed and sent. At the time of reception, the wireless terminal can receive CDMA voice arranged in one frequency band and receive LTE data arranged in another frequency band. The wireless terminal can use a diversity reception technique for receiving each of CDMA voice and LTE data with a plurality of antennas at the time of reception. In the present disclosure, the wireless terminal uses maximum ratio combining diversity reception or MIMO reception as diversity reception.

  In MIMO reception, a wireless terminal receives signals multiplexed and spatio-temporally coded in the same frequency band (referred to as band A) transmitted from a plurality of antennas of a radio base station using a plurality of antennas, and receives them. The band A data can be obtained by separating or decoding the processed signals.

  A wireless terminal according to another embodiment of the present disclosure can transmit data using a carrier aggregation technique at the time of transmission, and can receive data using a carrier aggregation technique and a diversity reception technique at the time of reception.

  In the carrier aggregation transmission, the radio terminal can divide and arrange uplink data into a plurality of different frequency bands and simultaneously transmit signals of a plurality of different frequency bands. In the carrier aggregation reception, the wireless terminal can simultaneously receive signals of a plurality of different frequency bands and integrate the received signals to obtain downlink data.

[First Embodiment]
FIG. 1 is a diagram illustrating a configuration of a wireless terminal 1 according to an embodiment.

  With reference to FIG. 1, the wireless terminal 1 includes an antenna unit 2, a wireless processing unit 3, a control unit 440, a speaker 50, a microphone 52, a display 54, a touch panel 56, and a camera 58.

The wireless processing unit 3 can communicate with the wireless base station through the antenna unit 2.
The speaker 50 can output the other party's voice output from the control unit 440.

  The microphone 52 can receive the voice of the user of the wireless terminal 1 and output it to the control unit 440.

The display 54 can display a screen output from the control unit 440.
The touch panel 56 can accept input from the user.

The camera 58 can photograph a subject.
FIG. 2 is a diagram illustrating a frequency band of a radio signal transmitted and received in the radio terminal 1 according to the first embodiment.

  The frequency band of the transmission signal is B4_Tx (1710 to 1755 MHz) and BC1_Tx (1850 to 1910 MHz). The frequency band of the received signal is BC1_Rx (1930 to 1990 MHz) and B4_Rx (2110 to 2155 MHz). In order to receive diversity, the wireless terminal 1 receives a signal in the band BC1_Rx through one antenna (denoted as BC1_Rx0) and receives a signal in the band BC1_Rx through another antenna (denoted as BC1_Rx1). In addition, a B4_Rx band signal can be received through one antenna (denoted as B4_Rx0) and a B4_Rx band signal can be received through another antenna (denoted as B4_Rx1).

  BC1_Tx and BC1_Rx are band names when used in CDMA, and are generally referred to as PCS1900. B4_Tx and B4_Rx are band names when used in LTE, and are referred to as AWS (Advanced Wireless Service) 1700.

FIG. 3 is a diagram illustrating the configuration of the antenna unit 2 and the wireless processing unit 3 according to the first embodiment.
The wireless processing unit 3 includes a demultiplexing unit 4, an RF processing unit 5, and a baseband IC 6.

  The baseband IC 6 performs LTE baseband processing on the data output to the first RF transceiver IC 21 and the data output from the first RF transceiver IC 21, and outputs to the second RF transceiver IC 22. CDMA baseband processing is performed on the audio data to be output and the audio data output from the first RF transceiver IC 21.

  Specifically, the baseband IC 6 performs processing such as channel decoding, discrete Fourier transform (DFT), demapping, Fourier transform (FFT), and data demodulation on downlink data as baseband processing for LTE. And performs processing such as channel coding, data modulation, mapping, and inverse Fourier transform (IFFT) on the uplink data.

  The baseband IC 6 performs processing such as synchronization processing, despreading, and data demodulation on downlink data (voice) as baseband processing for CDMA, and error correction on uplink data (voice). Processing such as encoding, data modulation, and spread modulation is performed.

  The baseband IC 6 performs diversity reception processing on downlink data that is in the same frequency band and received by two antennas. The baseband IC 6 executes a MIMO reception process among the diversity reception processes for a system signal corresponding to the LTE scheme. In the MIMO reception process, the baseband IC 6 can perform a process of separating the spatially multiplexed signal when the radio base station transmits a spatially multiplexed signal, and the radio base station can perform space-time coding. In the case of transmitting the processed signal, a process of decoding the time-coded signal can be performed. The baseband IC 6 executes a maximum ratio combining diversity process in the diversity reception process for a system signal corresponding to the CDMA system.

  The antenna unit 2 includes a first antenna ANT1, a second antenna ANT2, a third antenna ANT3, and a fourth antenna ANT4.

  The first antenna ANT1 has a VSWR (Voltage Standing Wave Ratio) equal to or less than a predetermined value at 1710 MHz to 2155 MHz. The first antenna ANT1 can transmit the B4_Tx signal and can receive the B4_Rx0 signal. The second antenna ANT2 has a VSWR equal to or lower than a predetermined value in 2110 MHz to 2155 MHz. The second antenna ANT2 can receive the signal B4_Rx1. The third antenna ANT3 has a VSWR equal to or less than a predetermined value in the range of 1850 MHz to 1990 Hz. The third antenna ANT3 can transmit a signal of BC1_Tx and can receive a signal of BC1_Rx0. The fourth antenna ANT4 has a VSWR equal to or lower than a predetermined value in 1930 MHz to 1990 MHz. The fourth antenna ANT4 can receive the signal BC1_Rx1.

  The RF processing unit 5 includes a first RF transceiver IC 21 and a second RF transceiver IC 22.

  The demultiplexing unit 4 includes a B4-duplexer 15, a power amplifier (PA) 11, a B4_Rx filter 13, a BC1-duplexer 16, a power amplifier (PA) 12, and a BC1_Rx filter 14.

  The first RF transceiver IC 21 can frequency-convert the baseband signal and output a signal in the B4_Tx band. The first RF transceiver IC21 can frequency-convert two signals (B2_Rx0 and B2_Rx1) in the B4_Rx band to convert them into baseband signals and output them to the baseband IC6.

  The second RF transceiver IC 22 can frequency-convert the baseband signal and output a signal in the BC1_Tx band. The second RF transceiver IC 22 can frequency-convert two signals (BC1_Rx0 and BC1_Rx1) in the BC1_Rx band, convert them into baseband signals, and output them to the baseband IC6.

  FIG. 4 is a diagram illustrating the configuration of the first RF transceiver IC 21 and the second RF transceiver IC 22.

  With reference to FIG. 4, the first RF transceiver IC 21 includes a transmission processing unit 92, a first reception processing unit 93, and a second reception processing unit 94.

  The terminal T4 can receive a digital baseband signal from the baseband IC6. The transmission processing unit 92 can convert the baseband signal received at the terminal T4 into an analog signal, frequency-convert it into a signal in the band of B4_Tx, and output the signal from the terminal T1 to the power amplifier 11.

  The terminal T2 can receive a signal (B4_Rx0) in the band B4_Rx from the B4-duplexer 15. The first reception processing unit 93 can amplify the B4_Rx0 signal received at the terminal T2, frequency-convert it into a baseband signal, further convert it into a digital signal, and output it from the terminal T5_0.

  The terminal T3 can receive a signal (B4_Rx1) in the B4_Rx band from the B4_Rx filter 13. The second reception processing unit 94 can amplify the B4_Rx1 signal received at the terminal T3, frequency-convert it into a baseband signal, further convert it into a digital signal, and output it from the terminal T5_1.

  The second RF transceiver IC 22 includes a transmission processing unit 96, a first reception processing unit 97, and a second reception processing unit 98.

  The terminal T9 can receive a digital baseband signal from the baseband IC6. The transmission processing unit 96 can convert the baseband signal received at the terminal T9 into an analog signal, frequency-convert it into a signal in the band of BC1_Tx, and output the signal from the terminal T6 to the power amplifier 12.

  The terminal T7 can receive a signal (BC1_Rx0) in the band BC1_Rx from the BC1-duplexer 16. The first reception processing unit 97 can amplify the BC1_Rx0 signal received at the terminal T6, frequency-convert it into a baseband signal, further convert it into a digital signal, and output it from the terminal T10_0.

  The terminal T8 can receive a signal (BC1_Rx1) in the BC1_Rx1 band from the BC1_Rx filter 14. The second reception processing unit 98 can amplify the BC1_Rx1 signal received at the terminal T8, frequency-convert it into a baseband signal, further convert it into a digital signal, and output it from the terminal T10_1.

  The power amplifier 11 can amplify the power of the B4_Tx signal output from the first RF transceiver IC 21 and output the amplified signal to the B4-duplexer 15.

  The B4-duplexer 15 extracts the band component of B4_Rx from the signal output from the first antenna ANT1, and outputs it to the first RF transceiver IC21. The B4-duplexer 15 can output the B4_Tx signal to the first antenna ANT1.

  The B4_Rx filter 13 can pass the B4_Rx band component of the signal output from the second antenna ANT2, and output the B4_Rx1 signal to the first RF transceiver IC21.

  The power amplifier 12 can amplify the power of the BC1_Tx signal output from the second RF transceiver IC 21 and output the amplified power to the BC1-duplexer 16.

  The BC1-duplexer 16 extracts the band component of BC1_Rx from the signal output from the third antenna ANT3, and outputs it to the second RF transceiver IC22. The BC1-duplexer 16 can output a BC1_Tx signal to the third antenna ANT3.

  The BC1_Rx filter 14 can pass the BC1_Rx band component of the signal output from the fourth antenna ANT4 and output the BC1_Rx1 signal to the second RF transceiver IC22.

FIG. 5 is a diagram illustrating the configuration of the B4-duplexer 15.
The B4-duplexer 15 is a kind of multiplexer, receives a transmission signal of a specific band from the wireless processing unit 3, outputs it to the first antenna ANT1, and is included in the signal received from the first antenna ANT1. A specific band component can be output to the wireless processing unit 3.

  The B4-duplexer 15 includes terminals T11, T12, T13, a transmission filter 72, and a reception filter 73.

  The transmission filter 72 has a pass characteristic in a band of B4_Tx. The reception filter 73 has a B4_Rx pass characteristic. Therefore, it is possible to secure isolation against the sneak path of the transmission signal in the B4_Tx band to the reception path.

The terminal T12 can receive the B4_Tx signal sent from the power amplifier 11.
The transmission filter 72 can remove band components (noise) other than B4_Tx from the B4_Tx signal received at the terminal T12 and output the result to the terminal T11.

  The terminal T11 can receive a reception signal from the first antenna ANT1 and output it to the reception filter 73. The reception signal from the first antenna ANT1 also flows in the direction of the transmission filter 72. However, since the power of the transmission signal is higher than the power of the reception signal, the reception signal from the first antenna ANT1 becomes the transmission signal. Has no effect. The terminal T11 can receive the B4_Tx signal from the transmission filter 72 and output it to the first antenna ANT1.

  The reception filter 73 can pass the B4_Rx band component from the signal output from the terminal T11 and output the B4_Rx0 signal from the terminal T13 to the first RF transceiver IC21.

FIG. 6 is a diagram illustrating the configuration of the BC1-duplexer 16.
The BC1-duplexer 16 is a kind of multiplexer, receives a transmission signal of a specific band from the wireless processing unit 3, outputs it to the third antenna ANT3, and is included in the signal received from the third antenna ANT3. A specific band component can be output to the wireless processing unit 3.

  The BC1-duplexer 15 includes terminals T14, T15, T16, a transmission filter 75, and a reception filter 76.

  The transmission filter 75 has a pass characteristic of the BC1_Tx band. The reception filter 76 has a pass characteristic of the BC1_Rx band. Therefore, it is possible to secure isolation against the sneak path of the transmission signal in the BC1_Tx band to the reception path.

  The terminal T15 can receive the signal BC1_Tx sent from the power amplifier 12.

  The transmission filter 75 can remove band components (noise) other than BC1_Tx from the signal of BC1_Tx received at the terminal T15, and output the result to the terminal T14.

  The terminal T14 can receive the reception signal from the third antenna ANT3 and output it to the reception filter 76. Although the reception signal from the third antenna ANT3 also flows in the direction of the transmission filter 75, since the power of the transmission signal is higher than the power of the reception signal, the reception signal from the third antenna ANT3 becomes the transmission signal. Has no effect. The terminal T14 can receive the signal BC1_Tx from the transmission filter 75 and output the signal to the third antenna ANT3.

  The reception filter 76 can pass the component of the band BC1_Rx from the signal output from the terminal T14 and output the signal of BC1_Rx0 from the terminal T16 to the second RF transceiver IC22.

Next, the processing procedure at the time of transmission will be described.
(1) LTE transmission processing and CDMA transmission processing The baseband IC 6 generates a baseband signal TxA from uplink data according to the LTE standard, and generates a baseband signal TxB from uplink voice data according to the CDMA standard. The signal TxA can be output to the terminal T4 of the first RF transceiver IC21, and the baseband signal TxB can be output to the terminal T9 of the second RF transceiver IC22.

  The first RF transceiver IC 21 can receive the baseband signal TxA and frequency-convert it into a signal in a band of B4_Tx. The first RF transceiver IC 21 can output a signal in a band of B4_Tx to the power amplifier 11.

  The power amplifier 11 can amplify the power of the signal in the B4_Tx band and output it to the B4-duplexer 15. The B4-duplexer 15 can output a signal in the B4_Tx band to the first antenna ANT1 while preventing a signal from entering the reception path. The first antenna ANT1 capable of transmitting a signal in the B4_Tx band can transmit a signal in the B4_Tx band to the radio base station.

  The second RF transceiver IC 22 can receive the baseband signal TxB and frequency-convert it into a signal in the band BC1_Tx. The second RF transceiver IC 22 can output a signal in a band of BC1_Tx to the power amplifier 12.

  The power amplifier 12 can amplify the power of the signal in the band of BC1_Tx and output it to the BC1-duplexer 16. The BC1-duplexer 16 can output a signal in the band of BC1_Tx to the third antenna ANT3 while preventing a signal from entering the reception path. The third antenna ANT3 capable of transmitting a signal in the BC1_Tx band can transmit a signal in the BC1_Tx band to the radio base station.

  Through the above operation, CDMA voice transmission and LTE data transmission can be performed simultaneously.

(2) LTE MIMO reception processing and CDMA maximum ratio combining diversity reception processing The first antenna ANT1 capable of receiving a signal in the B4_Rx band receives a signal from the radio base station and sends it to the B4-duplexer 15 Can be output. The B4-duplexer 15 can pass the B4_Rx band signal (B4_Rx0) and output it to the first RF transceiver IC21.

  The second antenna ANT2 capable of receiving a signal in the B4_Rx band can receive a signal from the radio base station and output the signal to the B4_Rx filter 13. The B4_Rx filter 13 can pass the B4_Rx band signal (B4_Rx1) and output it to the first RF transceiver IC21.

  The first RF transceiver IC21 can output the baseband signal RxA0 obtained by frequency-converting the B4_Rx band signal (B4_Rx0) output from the B4-duplexer 15 from the terminal T5_0 to the baseband IC6. The first RF transceiver IC21 can output the baseband signal RxA1 obtained by frequency-converting the B4_Rx band signal (B4_Rx1) output from the B4_Rx filter 13 to the baseband IC 6 from the terminal T5_1.

  The third antenna ANT3 capable of receiving a signal in the BC1_Rx band can receive a signal from the radio base station and output the signal to the BC1-duplexer 16. The BC1-duplexer 16 can pass the signal in the band BC1_Rx (BC1_Rx0) and output it to the second RF transceiver IC22.

  The fourth antenna ANT4 capable of receiving a signal in the BC1_Rx band can receive a signal from the radio base station and output the signal to the BC1_Rx filter 14. The BC1_Rx filter 14 can pass the signal (BC1_Rx1) in the band of BC1_Rx and output it to the second RF transceiver IC22.

  The second RF transceiver IC22 can output the baseband signal RxB0 obtained by frequency-converting the signal (BC1_Rx0) in the BC1_Rx band output from the BC1-duplexer 16 from the terminal T10_0 to the baseband IC6. The second RF transceiver IC 22 can output the baseband signal RxB1 obtained by frequency-converting the BC1_Rx band signal (BC1_Rx1) output from the BC1_Rx filter 14 from the terminal T10_1 to the baseband IC6.

  The baseband IC 6 can perform MIMO reception processing on the baseband signal RxA0 and the baseband signal RxA1 sent from the first RF transceiver IC21 to generate a signal RxA. The baseband IC 6 can generate data from the signal RxA according to the LTE standard. The baseband IC 6 can generate a signal RxB by performing a maximum ratio combining diversity reception process on the baseband signal RxB0 and the baseband signal RxB1 sent from the second RF transceiver IC22. The baseband IC 6 can generate audio from the signal RxB according to the CDMA standard.

  With the above operation, it is possible to simultaneously execute the maximum ratio combining diversity reception of the CDMA voice and the MIMO reception of the LTE data.

The transmission process (1) and the reception process (2) described above can be executed simultaneously.
As described above, the wireless terminal according to the first embodiment transmits voice and data in different frequency bands, receives two data in band A with different antennas, and differs between two voices in band B. Receive with antenna. As a result, the wireless terminal can execute both the CDMA and LTE simultaneous communication functions and the diversity reception function.

[Second Embodiment]
The frequency band of the radio signal transmitted and received in the radio terminal 1 of the second embodiment is the same as that of the first embodiment shown in FIG.

FIG. 7 is a diagram illustrating configurations of the antenna unit 2 and the wireless processing unit 3 according to the second embodiment.
The configuration of the second embodiment in FIG. 7 is different from the configuration of the first embodiment in FIG. 3 as follows.

  The antenna unit 2 of the second embodiment includes a first antenna ANT1, a second antenna ANT2, and a third antenna ANT3.

  The first antenna ANT1 has a VSWR equal to or less than a predetermined value at 1710 MHz to 2155 MHz. The first antenna ANT1 can transmit the B4_Tx signal and can receive the B4_Rx0 signal. The second antenna ANT2 has a VSWR equal to or less than a predetermined value in the range of 1850 MHz to 2155 MHz. The second antenna ANT2 can receive the signals B4_Rx1 and BC1_Rx0 and can transmit the signal BC1_Tx. The third antenna ANT3 has a VSWR equal to or lower than a predetermined value in 1930 MHz to 1990 MHz. The third antenna ANT3 can receive the signal of BC1_Rx1.

  The branching unit 4 of the second embodiment includes a quadplexer 31 instead of the B4_Rx filter 13 and the BC1_duplexer 16 included in the branching unit 4 of the first embodiment. The duplexer 15 and the filter 14 of the second embodiment are the same as the B4-duplexer 15 and the BC1_Rx filter 14 of the first embodiment.

FIG. 8 is a diagram illustrating the configuration of the quadplexer 31.
The quadplexer 31 is a kind of multiplexer, receives a transmission signal of a specific band from the radio processing unit 3, outputs it to the second antenna ANT2, and is included in the signal received from the second antenna ANT2. The first specific band component and the second specific band component can be output to the wireless processing unit 3.

  The quadplexer 31 includes terminals T31 to T35, a first transmission filter 42, a first reception filter 43, a second transmission filter 44, and a second reception filter 45.

  The first transmission filter 42 has a pass characteristic in a band of BC1_Tx. The first reception filter 43 has a BC1_Rx pass characteristic.

  The second transmission filter 44 has a pass characteristic of a predetermined band. The second reception filter 45 has a pass characteristic of B4_Rx. Therefore, it is possible to secure isolation against the sneak path of the transmission signal in the B2_Tx band to the reception path.

  The terminal T32 can receive the signal BC1_Tx sent from the power amplifier 11. The first transmission filter 42 can remove band components (noise) other than BC1_Tx from the BC1_Tx signal received at the terminal T32 and output the result to the terminal T31.

  The terminal T34 is terminated with a termination resistor 47. No signal is output from the second transmission filter 44 connected to the terminal T34.

  The terminal T31 can receive a reception signal from the second antenna ANT2 and output it to the first reception filter 43 and the second reception filter 45. The reception signal from the second antenna ANT2 also flows in the direction of the first transmission filter 42 and the second transmission filter 44. However, since the power of the transmission signal is higher than the power of the reception signal, the second antenna The reception signal from ANT2 does not affect the transmission signal. The terminal T31 can receive the signal BC1_Tx from the first transmission filter 42 and output it to the second antenna ANT2.

  The first reception filter 43 can pass the component of the band BC1_Rx from the signal output from the terminal T31 and output the signal of BC1_Rx0 from the terminal T33 to the first RF transceiver IC21. The second reception filter 45 can pass the B4_Rx band component from the signal output from the terminal T31 and output the B4_Rx0 signal from the terminal T35 to the second RF transceiver IC22.

Next, the processing procedure at the time of transmission will be described.
(1) LTE transmission processing and CDMA transmission processing The baseband IC 6 generates a baseband signal TxA from uplink data according to the LTE standard, and generates a baseband signal TxB from uplink voice data according to the CDMA standard. The signal TxA can be output to the first RF transceiver IC21 and the baseband signal TxB can be output to the second RF transceiver IC22.

  The first RF transceiver IC 21 can receive the baseband signal TxA and frequency-convert it into a signal in a band of B4_Tx. The first RF transceiver IC 21 can output a signal in a band of B4_Tx to the power amplifier 11.

  The power amplifier 11 can amplify the power of the signal in the B4_Tx band and output it to the duplexer 15. The duplexer 15 can output the signal in the band of B4_Tx to the first antenna ANT1 while preventing the signal from entering the reception path. The first antenna ANT1 capable of transmitting a signal in the B4_Tx band can transmit a signal in the B4_Tx band to the radio base station.

  The second RF transceiver IC 22 can receive the baseband signal TxB and frequency-convert it into a signal in the band BC1_Tx. The second RF transceiver IC 22 can output a signal in a band of BC1_Tx to the power amplifier 12.

  The power amplifier 12 can amplify the power of the signal in the BC1_Tx band and output the amplified signal power to the quadplexer 31. The quadplexer 31 can output a signal in the BC1_Tx band to the second antenna ANT2 while preventing a signal from entering the reception path. The second antenna ANT2 capable of transmitting signals in the BC1_Tx band can transmit signals in the BC1_Tx band to the radio base station.

  Through the above operation, CDMA voice transmission and LTE data transmission can be performed simultaneously.

(2) LTE MIMO reception processing and CDMA maximum ratio combining diversity reception processing The first antenna ANT1 capable of receiving a signal in the B4_Rx band receives a signal from the radio base station and outputs the signal to the duplexer 15. be able to. The duplexer 15 can pass the B4_Rx band signal (B4_Rx0) and output it to the first RF transceiver IC21.

  The second antenna ANT2 capable of receiving signals in the B4_Rx band and the BC1_Rx band can receive a signal from the radio base station and output the signal to the quadplexer 31. The quadplexer 31 can pass the signal (B4_Rx1) in the B4_Rx band and output it to the first RF transceiver IC21, and can pass the signal (BC1_Rx0) in the BC1_Rx band to pass the second RF It can be output to the transceiver IC 22.

  The first RF transceiver IC 21 can output to the baseband IC 6 a baseband signal RxA0 obtained by frequency-converting the B4_Rx band signal (B4_Rx0) output from the duplexer 15. The first RF transceiver IC 21 can output to the baseband IC 6 a baseband signal RxA1 obtained by frequency-converting the B4_Rx band signal (B4_Rx1) output from the quadplexer 31.

  The third antenna ANT3 capable of receiving a signal in the BC1_Rx band can receive a signal from the radio base station and output the signal to the filter 14. The filter 14 can pass the signal in the band BC1_Rx (BC1_Rx1) and output it to the second RF transceiver IC22.

  The second RF transceiver IC 22 can output to the baseband IC 6 a baseband signal RxB0 obtained by frequency-converting the BC1_Rx band signal (BC1_Rx0) output from the quadplexer 31. The second RF transceiver IC 22 can output the baseband signal RxB1 obtained by frequency-converting the signal (BC1_Rx1) in the BC1_Rx band output from the filter 14 to the baseband IC6.

  The baseband IC 6 can perform MIMO reception processing on the baseband signal RxA0 and the baseband signal RxA1 sent from the first RF transceiver IC21 to generate a signal RxA. The baseband IC 6 can generate data from the signal RxA according to the LTE standard. The baseband IC 6 can generate a signal RxB by performing a maximum ratio combining diversity reception process on the baseband signal RxB0 and the baseband signal RxB1 sent from the second RF transceiver IC22. The baseband IC 6 can generate audio from the signal RxB according to the CDMA standard.

  With the above operation, it is possible to simultaneously execute the maximum ratio combining diversity reception of the CDMA voice and the MIMO reception of the LTE data.

The transmission process (1) and the reception process (2) described above can be executed simultaneously.
As described above, the wireless terminal according to the second embodiment can execute both the simultaneous communication function and the diversity reception function of the CDMA scheme and the LTE scheme, as in the first embodiment. Furthermore, according to the second embodiment, the number of antennas can be reduced by one compared to the first embodiment.

[Third Embodiment]
The frequency band of the radio signal transmitted and received in the radio terminal 1 of the third embodiment is the same as that of the first embodiment shown in FIG.

FIG. 9 is a diagram illustrating the configuration of the antenna unit 2 and the wireless processing unit 3 according to the third embodiment.
The configuration of the third embodiment in FIG. 9 is different from the configuration of the first embodiment in FIG. 3 as follows.

  The antenna unit 2 of the third embodiment includes a first antenna ANT1, a second antenna ANT2, and a third antenna ANT3.

  The first antenna ANT1 has a VSWR equal to or less than a predetermined value at 1710 MHz to 2155 MHz. The first antenna ANT1 can transmit the B4_Tx signal and can receive the B4_Rx0 and BC1_Rx1 signals. The second antenna ANT2 has a VSWR equal to or lower than a predetermined value in 2110 MHz to 2155 MHz. The second antenna ANT2 can receive the signal B4_Rx1. The third antenna ANT3 has a VSWR equal to or less than a predetermined value in the range of 1850 MHz to 1990 Hz. The third antenna ANT3 can transmit a signal of BC1_Tx and can receive a signal of BC1_Rx0.

  The demultiplexing unit 4 of the third embodiment includes a switch circuit 19 in addition to the components included in the demultiplexing unit 4 of the first embodiment.

  The switch circuit 19 includes terminals P1, P2, and P3. When the terminal P1 and the terminal P2 are connected, the first antenna ANT1 and the B4-duplexer 15 are connected. When the terminal P1 and the terminal P3 are connected, the first antenna ANT1 and the BC1_Rx filter 14 are connected.

  The terminal T11 of the B4-duplexer 15 is connected to the first antenna ANT1 in the first embodiment, but is connected to the terminal P2 of the switch circuit 19 in the third embodiment.

(1) LTE transmission processing and CDMA transmission processing During the LTE transmission processing and CDMA transmission processing, the terminal P1 and the terminal P2 of the switch circuit 19 are connected.

  The baseband IC 6 generates a baseband signal TxA from the uplink data according to the LTE standard, generates a baseband signal TxB from the uplink voice data according to the CDMA standard, and transmits the baseband signal TxA to the first RF transceiver IC21. The baseband signal TxB can be output to the second RF transceiver IC 22.

  The first RF transceiver IC 21 can receive the baseband signal TxA and frequency-convert it into a signal in a band of B4_Tx. The first RF transceiver IC 21 can output a signal in a band of B4_Tx to the power amplifier 11.

  The power amplifier 11 can amplify the power of the signal in the B4_Tx band and output it to the B4-duplexer 15. The B4-duplexer 15 can output the B4_Tx band signal to the switch circuit 19 while preventing the signal from flowing into the reception path. Since the terminal P1 and the terminal P2 of the switch circuit 19 are connected, the signal in the B4_Tx band output from the B4-duplexer 15 is sent to the first antenna ANT1. The first antenna ANT1 capable of transmitting a signal in the B4_Tx band can transmit a signal in the B4_Tx band to the radio base station.

  The second RF transceiver IC 22 can receive the baseband signal TxB and frequency-convert it into a signal in the band BC1_Tx. The second RF transceiver IC 22 can output a signal in a band of BC1_Tx to the power amplifier 12.

  The power amplifier 12 can amplify the power of the signal in the band of BC1_Tx and output it to the BC1-duplexer 16. The BC1-duplexer 16 can output a signal in the BC1_Tx band to the third antenna ANT3 while preventing a signal from entering the reception path. The third antenna ANT3 capable of transmitting a signal in the BC1_Tx band can transmit a signal in the BC1_Tx band to the radio base station.

  Through the above operation, CDMA voice transmission and LTE data transmission can be performed simultaneously.

(2) LTE MIMO reception processing and CDMA reception processing During the LTE MIMO reception processing and CDMA reception processing, the terminal P1 and the terminal P2 of the switch circuit 19 are connected.

  The first antenna ANT1 capable of receiving a signal in the B4_Rx band can receive a signal from the radio base station and output the signal to the switch circuit 19. Since the terminal P1 and the terminal P2 of the switch circuit 19 are connected, the signal output from the first antenna ANT1 is sent to the B4-duplexer 15. The B4-duplexer 15 can pass the B4_Rx band signal (B4_Rx0) and output it to the first RF transceiver IC21.

  The second antenna ANT2 capable of receiving a signal in the B4_Rx band can receive a signal from the radio base station and output the signal to the B4_Rx filter 13. The B4_Rx filter 13 can pass the B4_Rx band signal (B4_Rx1) and output it to the first RF transceiver IC21.

  The first RF transceiver IC21 can output to the baseband IC 6 a baseband signal RxA0 obtained by frequency-converting the B4_Rx band signal (B4_Rx0) output from the B4-duplexer 15. The first RF transceiver IC 21 can output a baseband signal RxA1 obtained by frequency-converting the signal (B4_Rx1) in the B4_Rx band output from the B4_Rx filter 13 to the baseband IC6.

  The third antenna ANT3 capable of receiving a signal in the BC1_Rx band can receive a signal from the radio base station and output the signal to the BC1-duplexer 16. The BC1-duplexer 16 can pass the signal in the band BC1_Rx (BC1_Rx0) and output it to the second RF transceiver IC22.

  The second RF transceiver IC 22 can frequency-convert the BC1_Rx band signal (BC1_Rx0) output from the BC1-duplexer 16 into a baseband signal RxB and output the baseband signal to the baseband IC6.

  The baseband IC 6 can perform MIMO reception processing on the baseband signal RxA0 and the baseband signal RxA1 sent from the first RF transceiver IC21 to generate a signal RxA. The baseband IC 6 generates data from the signal RxA according to the LTE standard. The baseband IC 6 can generate voice according to the CDMA standard from the baseband signal RxB sent from the second RF transceiver IC22.

  With the above operation, it is possible to simultaneously execute CDMA voice reception and LTE data MIMO reception.

The transmission process (1) and the reception process (2) described above can be executed simultaneously.
(3) Maximum Ratio Combining Diversity Reception Processing and LTE Reception Processing of CDMA During the maximum ratio combining diversity reception processing and LTE reception processing of CDMA, terminal P1 and terminal P3 of switch circuit 19 are connected.

  The first antenna ANT1 capable of receiving a signal in the BC1_Rx band can receive a signal from the radio base station and output the signal to the switch circuit 19. Since the terminal P1 and the terminal P3 of the switch circuit 19 are connected, the signal output from the first antenna ANT1 is sent to the BC1-Rx filter 14. The BC1-Rx filter 14 can pass a signal (BC1_Rx1) in the band of BC1_Rx and output the signal to the second RF transceiver IC22.

  The second antenna ANT2 capable of receiving a signal in the B4_Rx band can receive a signal from the radio base station and output the signal to the B4_Rx filter 13. The B4_Rx filter 13 can pass the B4_Rx band signal (B4_Rx1) and output it to the first RF transceiver IC21.

  The first RF transceiver IC 21 can frequency-convert the B4_Rx band signal (B4_Rx1) output from the B4_Rx filter 13 into a baseband signal RxA and output the converted signal to the baseband IC 6.

  The third antenna ANT3 capable of receiving a signal in the BC1_Rx band can receive a signal from the radio base station and output the signal to the BC1-duplexer 16. The BC1-duplexer 16 can pass the signal in the band BC1_Rx (BC1_Rx0) and output it to the second RF transceiver IC22.

  The second RF transceiver IC 22 can output to the baseband IC 6 a baseband signal RxB0 obtained by frequency-converting the BC1_Rx band signal (BC1_Rx0) output from the BC1-duplexer 16. The second RF transceiver IC 22 can output the baseband signal RxB1 obtained by frequency-converting the signal (BC1_Rx1) in the BC1_Rx band output from the BC1-Rx filter 14 to the baseband IC6.

  The baseband IC 6 can generate data in accordance with the LTE standard from the baseband signal RxA sent from the first RF transceiver IC21. The baseband IC 6 can generate a signal RxB by performing a maximum ratio combining diversity reception process on the baseband signal RxB0 and the baseband signal RxB1 sent from the second RF transceiver IC22. The baseband IC 6 can generate audio from the signal RxB according to the CDMA standard.

  With the above operation, it is possible to simultaneously execute the maximum ratio combining diversity reception of the CDMA voice and the reception of the LTE data.

  As described above, the wireless terminal according to the third embodiment can execute both the CDMA and LTE simultaneous communication functions and the CDMA or LTE diversity reception function. Furthermore, according to the third embodiment, the number of antennas can be reduced by one compared to the first embodiment.

[Fourth Embodiment]
The frequency band of the radio signal transmitted and received in the radio terminal 1 of the fourth embodiment is the same as that of the first embodiment shown in FIG.

  FIG. 10 is a diagram illustrating the configuration of the antenna unit 2 and the wireless processing unit 3 according to the fourth embodiment.

  The configuration of the fourth embodiment in FIG. 10 is different from the configuration of the second embodiment in FIG. 7 as follows.

  The antenna unit 2 of the fourth embodiment includes a first antenna ANT1 and a second antenna ANT2.

  The first antenna ANT1 has a VSWR equal to or less than a predetermined value at 1710 MHz to 2155 MHz. The first antenna ANT1 can transmit the B4_Tx signal and can receive the B4_Rx0 and BC1_Rx1 signals. The second antenna ANT2 has a VSWR equal to or less than a predetermined value in the range of 1850 MHz to 2155 MHz. The second antenna ANT2 can receive the signals B4_Rx1 and BC1_Rx and can transmit the signal BC1_Tx.

  The demultiplexing unit 4 of the fourth embodiment includes a switch circuit 19 in addition to the components included in the demultiplexing unit 4 of the second embodiment.

  The switch circuit 19 includes terminals P1, P2, and P3. When the terminal P1 and the terminal P2 are connected, the first antenna ANT1 and the duplexer 15 are connected. When the terminal P1 and the terminal P3 are connected, the first antenna ANT1 and the filter 14 are connected.

  The duplexer 15 and the filter 14 of the fourth embodiment are the same as the B4-duplexer 15 and the BC1_Rx filter 14 of the third embodiment.

  In the second embodiment, the terminal T11 of the B4-duplexer 15 is connected to the first antenna ANT1, but in the fourth embodiment, the terminal T11 of the duplexer 15 is connected to the terminal P2 of the switch circuit 19. Is done.

(1) LTE transmission processing and CDMA transmission processing During the LTE transmission processing and CDMA transmission processing, the terminal P1 and the terminal P2 of the switch circuit 19 are connected.

  The baseband IC 6 generates a baseband signal TxA from the uplink data according to the LTE standard, generates a baseband signal TxB from the uplink voice data according to the CDMA standard, and transmits the baseband signal TxA to the first RF transceiver IC21. The baseband signal TxB can be output to the second RF transceiver IC 22.

  The first RF transceiver IC 21 can receive the baseband signal TxA and frequency-convert it into a signal in a band of B4_Tx. The first RF transceiver IC 21 can output a signal in a band of B4_Tx to the power amplifier 11.

  The power amplifier 11 can amplify the power of the signal in the B4_Tx band and output it to the duplexer 15. The duplexer 15 can output the B4_Tx band signal to the switch circuit 19 while preventing the signal from flowing into the reception path. Since the terminal P1 and the terminal P2 of the switch circuit 19 are connected, the signal in the B4_Tx band output from the duplexer 15 is sent to the first antenna ANT1. The first antenna ANT1 capable of transmitting a signal in the B4_Tx band can transmit a signal in the B4_Tx band to the radio base station.

  The second RF transceiver IC 22 can receive the baseband signal TxB and frequency-convert it into a signal in the band BC1_Tx. The second RF transceiver IC 22 can output a signal in a band of BC1_Tx to the power amplifier 12.

  The power amplifier 12 can amplify the power of the signal in the band of BC1_Tx and output it to the quadplexer 31. The quadplexer 31 can output a signal in the BC1_Tx band to the second antenna ANT2 while preventing a signal from entering the reception path. The second antenna ANT2 capable of transmitting signals in the BC1_Tx band can transmit signals in the BC1_Tx band to the radio base station.

  Through the above operation, CDMA voice transmission and LTE data transmission can be performed simultaneously.

(2) LTE MIMO reception processing and CDMA reception processing During the LTE MIMO reception processing and CDMA reception processing, the terminal P1 and the terminal P2 of the switch circuit 19 are connected.

  The first antenna ANT1 capable of receiving a signal in the B4_Rx band can receive a signal from the radio base station and output the signal to the switch circuit 19. Since the terminal P1 and the terminal P2 of the switch circuit 19 are connected, the signal output from the first antenna ANT1 is sent to the duplexer 15. The duplexer 15 can pass the B4_Rx band signal (B4_Rx0) and output it to the first RF transceiver IC21.

  The second antenna ANT2 capable of receiving signals in the B4_Rx band and the BC1_Rx band can receive a signal from the radio base station and output the signal to the quadplexer 31. The quadplexer 31 can pass the signal (B4_Rx1) in the B4_Rx band and output it to the first RF transceiver IC21, and can pass the signal (BC1_Rx0) in the BC1_Rx band to pass the second RF It can be output to the transceiver IC 22.

  The first RF transceiver IC 21 can output to the baseband IC 6 a baseband signal RxA0 obtained by frequency-converting the B4_Rx band signal (B4_Rx0) output from the duplexer 15. The first RF transceiver IC 21 can output to the baseband IC 6 a baseband signal RxA1 obtained by frequency-converting the B4_Rx band signal (B4_Rx1) output from the quadplexer 31.

  The second RF transceiver IC 22 can frequency-convert the BC1_Rx band signal (BC1_Rx0) output from the quadplexer 31 into the baseband signal RxB and output the baseband signal to the baseband IC 6.

  The baseband IC 6 can perform MIMO reception processing on the baseband signal RxA0 and the baseband signal RxA1 sent from the first RF transceiver IC21 to generate a signal RxA. The baseband IC 6 can generate data from the signal RxA according to the LTE standard. The baseband IC 6 can generate a signal RxB by performing a maximum ratio combining diversity reception process on the baseband signal RxB0 and the baseband signal RxB1 sent from the second RF transceiver IC22. The baseband IC 6 can generate audio from the signal RxB according to the CDMA standard.

  With the above operation, it is possible to simultaneously execute CDMA voice reception and LTE data MIMO reception.

The transmission process (1) and the reception process (2) described above can be executed simultaneously.
(3) Maximum Ratio Combining Diversity Reception Processing and LTE Reception Processing of CDMA During the maximum ratio combining diversity reception processing and LTE reception processing of CDMA, terminal P1 and terminal P3 of switch circuit 19 are connected.

  The first antenna ANT1 capable of receiving a signal in the B4_Rx band can receive a signal from the radio base station and output the signal to the switch circuit 19. Since the terminal P1 and the terminal P3 of the switch circuit 19 are connected, the signal output from the first antenna ANT1 is sent to the filter 14. The filter 14 can pass the signal in the band BC1_Rx (BC1_Rx1) and output it to the second RF transceiver IC22.

  The second antenna ANT2 capable of receiving signals in the B4_Rx band and the BC1_Rx band can receive a signal from the radio base station and output the signal to the quadplexer 31. The quadplexer 31 can pass the signal (B4_Rx1) in the B4_Rx band and output it to the first RF transceiver IC21, and can pass the signal (BC1_Rx0) in the BC1_Rx band to pass the second RF It can be output to the transceiver IC 22.

  The first RF transceiver IC 21 can frequency-convert the B4_Rx band signal (B4_Rx1) output from the quadplexer 31 into a baseband signal RxA and output the baseband signal RxA to the baseband IC 6.

  The second RF transceiver IC 22 can output to the baseband IC 6 a baseband signal RxB0 obtained by frequency-converting the BC1_Rx band signal (BC1_Rx0) output from the quadplexer 31. The second RF transceiver IC 22 can output the baseband signal RxB1 obtained by frequency-converting the signal (BC1_Rx1) in the BC1_Rx band output from the filter 14 to the baseband IC6.

  The baseband IC 6 can generate data in accordance with the LTE standard from the baseband signal RxA sent from the first RF transceiver IC21. The baseband IC 6 can generate a signal RxB by performing a maximum ratio combining diversity reception process on the baseband signal RxB0 and the baseband signal RxB1 sent from the second RF transceiver IC22. The baseband IC 6 can generate audio from the signal RxB according to the CDMA standard.

  With the above operation, it is possible to simultaneously execute the maximum ratio combining diversity reception of the CDMA voice and the reception of the LTE data.

  As described above, the wireless terminal according to the fourth embodiment can execute both the CDMA and LTE simultaneous communication functions and the CDMA or LTE diversity reception function. Furthermore, according to the fourth embodiment, the number of antennas can be reduced by one compared to the third embodiment.

[Fifth Embodiment]
FIG. 11 is a diagram illustrating frequency bands of radio signals transmitted and received in the radio terminal 1 according to the fifth embodiment.

  The frequency band of the transmission signal is BC15_Tx (1710 to 1755 MHz) and B2_Tx (1850 to 1910 MHz). The frequency band of the received signal is B2_Rx (1930 to 1990 MHz) and BC15_Rx (2110 to 2155 MHz). In order to receive diversity, the wireless terminal 1 receives a signal in the BC15_Rx band through one antenna (denoted as BC15_Rx0) and receives a signal in the BC15_Rx band through another antenna (denoted as BC15_Rx1). In addition, a B2_Rx band signal can be received through one antenna (denoted as B2_Rx0) and a B2_Rx band signal can be received through another antenna (denoted as B2_Rx1).

  BC15_Tx and BC15_Rx are band names when used in CDMA, and are generally referred to as AWS 1700. B2_Tx and B2_Rx are band names when used in LTE, and are generally referred to as PCS (Personal Communications Service) 1900.

  FIG. 12 is a diagram illustrating the configuration of the antenna unit 2 and the wireless processing unit 3 according to the fifth embodiment.

  The baseband IC 106 performs baseband processing for CDMA on the audio data output to the first RF transceiver IC21 and the audio data output from the first RF transceiver IC21, and to the second RF transceiver IC22. The baseband processing for LTE is performed on the data to be output and the data output from the second RF transceiver IC22.

  The antenna unit 2 of the fifth embodiment is the same as that described in the second embodiment. The wireless processing unit 3 of the fifth embodiment is the same as that described in the second embodiment. The demultiplexing unit 4 of the fifth embodiment is the same as that described in the second embodiment. This is because BC15_Tx and BC15_Rx are the same band as B4_Tx and B4_Rx, and B2_Tx and B2_Rx are the same band as BC1_Tx and BC1_Rx.

  As described above, according to the fifth embodiment, even if the band used in the CDMA scheme and the band used in the LTE scheme in the second embodiment are interchanged, the same effect as in the second embodiment is obtained. It is done.

[Sixth Embodiment]
The frequency band of the radio signal transmitted and received in the radio terminal 1 of the sixth embodiment is the same as that of the fifth embodiment shown in FIG.

  FIG. 13 is a diagram illustrating the configuration of the antenna unit 2 and the wireless processing unit 3 according to the sixth embodiment.

  The baseband IC 106 performs baseband processing for CDMA on the audio data output to the first RF transceiver IC21 and the audio data output from the first RF transceiver IC21, and to the second RF transceiver IC22. The baseband processing for LTE is performed on the data to be output and the data output from the second RF transceiver IC22.

  The antenna unit 2 of the sixth embodiment is the same as that described in the fourth embodiment. The wireless processing unit 3 of the sixth embodiment is the same as that described in the fourth embodiment. The demultiplexing unit 4 of the sixth embodiment is the same as that described in the fourth embodiment. This is because BC15_Tx and BC15_Rx are the same band as B4_Tx and B4_Rx, and B2_Tx and B2_Rx are the same band as BC1_Tx and BC1_Rx.

  As described above, according to the sixth embodiment, even if the band used in the CDMA scheme and the band used in the LTE scheme in the fourth embodiment are interchanged, the same effect as in the fourth embodiment is obtained. It is done.

[Seventh Embodiment]
FIG. 14 is a diagram illustrating frequency bands of radio signals transmitted and received in the radio terminal 1 according to the seventh embodiment.

  The frequency band of the transmission signal is BC8_Tx (1710 to 1785 MHz) and B1_Tx (1920 to 1980 MHz). The frequency band of the received signal is BC8_Rx (1805 to 1880 MHz) and B1_Rx (2110 to 2170 MHz). In order to receive diversity, the wireless terminal 1 receives a signal in the band BC8_Rx through one antenna (denoted as BC8_Rx0) and receives a signal in the band BC8_Rx through another antenna (denoted as BC8_Rx1). The B1_Rx band signal can be received through one antenna (denoted as B1_Rx0), and the B1_Rx band signal can be received through another antenna (denoted as B1_Rx1).

  B1_Tx and B1_Rx are band names when used in LTE, and are generally referred to as IMT (International Mobile Telecommunication) 2100. BC8_Tx and BC8_Rx are band names when used in CDMA, and are referred to as DCS (Digital Cellular Service) 1800.

  FIG. 15 is a diagram illustrating configurations of the antenna unit 2 and the wireless processing unit 3 according to the seventh embodiment.

  The antenna unit 2 of the seventh embodiment includes a first antenna ANT1, a second antenna ANT2, and a third antenna ANT3.

  The first antenna ANT1 has a VSWR equal to or lower than a predetermined value at 1920 MHz to 2170 MHz. The first antenna ANT1 can transmit the signal B1_Tx and can receive the signal B1_Rx0.

  The second antenna ANT2 has a VSWR equal to or lower than a predetermined value in the range of 1710 MHz to 2170 MHz. The second antenna ANT2 can transmit the BC8_Tx signal and can receive the BC8_Rx0 and B1_Rx1 signals.

  The third antenna ANT3 has a VSWR equal to or less than a predetermined value at 1805 MHz to 1880 MHz. The third antenna ANT3 can receive the signal of BC8_Rx1.

The difference between the demultiplexing unit 4 of the seventh embodiment and the demultiplexing unit 4 of the second embodiment is as follows.
The duplexer 15 of the seventh embodiment can process the signals B1_Tx and B1_Rx0 instead of the signals B4_Tx and B4_Rx0.

  The quadplexer 31 of the seventh embodiment can process the signals B1_Rx1, BC8_Tx, and BC8_Rx0 instead of the signals B4_Rx1, BC1_Tx, and BC1_Rx0. The filter 14 of the seventh embodiment can process a BC8_Rx1 signal instead of a BC1_Rx1 signal.

  The first RF transceiver IC 21 of the seventh embodiment can process the signals B1_Tx, B1_Rx0, and B1_Rx1 instead of the signals B4_Tx, B4_Rx0, and B4_Rx1. The second RF transceiver IC 22 of the seventh embodiment can process signals BC8_Tx, BC8_Rx0, and BC8_Rx1 instead of signals BC1_Tx, BC1_Rx0, and BC1_Rx1.

  As described above, according to the seventh embodiment, even if the band used in the CDMA scheme and the band used in the LTE scheme are changed from those different from the second embodiment, the same as the second embodiment. An effect is obtained.

[Eighth Embodiment]
The frequency band of the radio signal transmitted and received in the radio terminal 1 of the eighth embodiment is the same as that of the seventh embodiment shown in FIG.

  FIG. 16 is a diagram illustrating configurations of the antenna unit 2 and the wireless processing unit 3 according to the eighth embodiment.

  The antenna unit 2 of the eighth embodiment includes a first antenna ANT1 and a second antenna ANT2.

  The first antenna ANT1 has a VSWR equal to or less than a predetermined value in the range of 1805 MHz to 2170 MHz. The first antenna ANT1 can transmit the B1_Tx signal and can receive the B1_Rx0 and BC8_Rx1 signals.

  The second antenna ANT2 has a VSWR equal to or lower than a predetermined value in the range of 1710 MHz to 2170 MHz. The second antenna ANT2 can transmit the BC8_Tx signal and can receive the BC8_Rx0 and B1_Rx1 signals.

The difference between the demultiplexing unit 4 of the eighth embodiment and the demultiplexing unit 4 of the fourth embodiment is as follows.
The duplexer 15 of the eighth embodiment can process the signals B1_Tx and B1_Rx0 instead of the signals B4_Tx and B4_Rx0.

  The quadplexer 31 of the eighth embodiment can process the signals B1_Rx1, BC8_Tx, and BC8_Rx0 instead of the signals B4_Rx1, BC1_Tx, and BC1_Rx0. The filter 14 of the eighth embodiment can process the BC8_Rx1 signal instead of the BC1_Rx1 signal.

  The first RF transceiver IC 21 of the eighth embodiment can process the signals B1_Tx, B1_Rx0, and B1_Rx1 instead of the signals B4_Tx, B4_Rx0, and B4_Rx1. The second RF transceiver IC 22 of the eighth embodiment can process signals BC8_Tx, BC8_Rx0, and BC8_Rx1 instead of signals BC1_Tx, BC1_Rx0, and BC1_Rx1.

  As described above, according to the eighth embodiment, the band used in the CDMA scheme and the band used in the LTE scheme are the same as those in the second embodiment even if they are different from those in the fourth embodiment. An effect is obtained.

[Ninth Embodiment]
FIG. 17 is a diagram illustrating frequency bands of radio signals transmitted and received in the radio terminal 1 according to the ninth embodiment.

  The frequency band of the transmission signal is B3_Tx (1710 to 1785 MHz) and BC6_Tx (1920 to 1980 MHz). The frequency band of the received signal is B3_Rx (1805 to 1880 MHz) and BC6_Rx (2110 to 2170 MHz). In order to receive diversity, the wireless terminal 1 receives a signal in the B3_Rx band through one antenna (denoted as B3_Rx0) and receives a signal in the B3_Rx band through another antenna (denoted as B3_Rx1). In addition, a signal in the BC6_Rx band can be received through one antenna (denoted as BC6_Rx0), and a signal in the BC6_Rx band can be received through another antenna (denoted as BC6_Rx1).

  BC6_Tx and BC6_Rx are band names when used in CDMA, and are generally referred to as IMT (International Mobile Telecommunication) 2100. B3_Tx and B3_Rx are band names when used in LTE, and are referred to as DCS (Digital Cellular Service) 1800.

  FIG. 18 is a diagram illustrating the configuration of the antenna unit 2 and the wireless processing unit 3 according to the ninth embodiment.

  The baseband IC 106 performs baseband processing for CDMA on the audio data output to the first RF transceiver IC21 and the audio data output from the first RF transceiver IC21, and to the second RF transceiver IC22. The baseband processing for LTE is performed on the data to be output and the data output from the second RF transceiver IC22.

  The antenna unit 2 of the ninth embodiment is the same as that described in the seventh embodiment. The wireless processing unit 3 of the ninth embodiment is the same as that described in the seventh embodiment. The demultiplexing unit 4 of the ninth embodiment is the same as that described in the seventh embodiment. This is because B3_Tx and B3_Rx are the same band as BC8_Tx and BC9_Rx, and BC6_Tx and BC6_Rx are the same band as B1_Tx and B1_Rx.

  As described above, according to the ninth embodiment, even if the band used in the CDMA scheme and the band used in the LTE scheme in the seventh embodiment are interchanged, the same effect as in the seventh embodiment is obtained. It is done.

[Tenth embodiment]
The frequency band of the radio signal transmitted and received in the radio terminal 1 of the tenth embodiment is the same as that of the ninth embodiment shown in FIG.

  FIG. 19 is a diagram illustrating configurations of the antenna unit 2 and the wireless processing unit 3 according to the tenth embodiment.

  The baseband IC 106 performs baseband processing for CDMA on the audio data output to the first RF transceiver IC21 and the audio data output from the first RF transceiver IC21, and to the second RF transceiver IC22. The baseband processing for LTE is performed on the data to be output and the data output from the second RF transceiver IC22.

  The antenna unit 2 of the tenth embodiment is the same as that described in the eighth embodiment. The wireless processing unit 3 of the tenth embodiment is the same as that described in the eighth embodiment. The demultiplexing unit 4 of the tenth embodiment is the same as that described in the eighth embodiment. This is because B3_Tx and B3_Rx are the same band as BC8_Tx and BC9_Rx, and BC6_Tx and BC6_Rx are the same band as B1_Tx and B1_Rx.

  As described above, according to the tenth embodiment, even if the band used in the CDMA scheme and the band used in the LTE scheme in the eighth embodiment are switched, the same effect as in the eighth embodiment is obtained. It is done.

[Eleventh embodiment]
The wireless terminal according to the eleventh embodiment is assumed to be compatible with LTE. The wireless terminal according to the eleventh embodiment can transmit data using a carrier aggregation technique during transmission. The wireless terminal according to the eleventh embodiment can receive data using a carrier aggregation technique and a diversity reception technique at the time of reception.

  FIG. 20 is a diagram illustrating a frequency band of a radio signal transmitted and received in the radio terminal 1 of the eleventh embodiment. The frequency band of the transmission signal is B4_Tx (1710 to 1755 MHz) and B2_Tx (1850 to 1910 MHz). The frequency band of the received signal is B2_Rx (1930 to 1990 MHz) and B4_Rx (2110 to 2155 MHz). To receive diversity, the wireless terminal 1 receives a signal in the B2_Rx band through one antenna (denoted as B2_Rx0) and receives a signal in the B2_Rx band through another antenna (denoted as B2_Rx1). In addition, a B4_Rx band signal can be received through one antenna (denoted as B4_Rx0) and a B4_Rx band signal can be received through another antenna (denoted as B4_Rx1).

  B2_Tx and B2_Rx are band names when used in LTE, and are generally referred to as PCS (Personal Communications Service) 1900. B4_Tx and B4_Rx are band names when used in LTE, and are referred to as AWS (Advanced Wireless Service) 1700.

  FIG. 21 is a diagram illustrating configurations of the antenna unit 2 and the wireless processing unit 3 according to the eleventh embodiment.

The wireless processing unit 3 includes a demultiplexing unit 4, an RF processing unit 5, and a baseband IC 6.
The baseband IC 206 executes baseband processing for LTE. Specifically, the baseband IC 206 performs processing such as channel decoding, discrete Fourier transform (DFT), demapping, Fourier transform (FFT), and data demodulation on the downlink data. The baseband IC 206 performs processing such as channel coding, data modulation, mapping, and inverse Fourier transform (IFFT) on the uplink data.

  As a carrier aggregation transmission process, the baseband IC 206 can divide the downlink data into two systems for the first RF transceiver IC 21 and the second RF transceiver IC 22 according to a predetermined rule such as a round robin method. . The baseband IC 206 can execute the above-described baseband processing for downlink data on the divided data.

  The baseband IC 206 performs the above-described baseband processing for uplink data on the data output from the first RF transceiver IC 21 and the data output from the second RF transceiver IC 22 as carrier aggregation reception processing, respectively. By doing so, data divided at the time of transmission can be obtained in the radio base station. The baseband IC 206 can reproduce the original data by integrating the obtained divided data.

  The antenna unit 2 includes a first antenna ANT1, a second antenna ANT2, and a third antenna ANT3.

  The first antenna ANT1 has a VSWR equal to or less than a predetermined value at 1710 MHz to 2155 MHz. The first antenna ANT1 can transmit the B4_Tx signal and can receive the B4_Rx0 signal. The second antenna ANT2 has a VSWR equal to or less than a predetermined value in the range of 1850 MHz to 2155 MHz. The second antenna ANT2 can transmit the B2_Tx signal and can receive the B4_Rx1 and B2_Rx0 signals. The third antenna ANT3 has a VSWR equal to or lower than a predetermined value in 1930 MHz to 1990 MHz. The third antenna ANT3 can receive the B2_Rx1 signal.

The difference between the demultiplexing unit 4 of the eleventh embodiment and the demultiplexing unit 4 of the second embodiment is as follows.
The quadplexer 31 of the eleventh embodiment can process the signals B4_Rx1, B2_Tx, and B2_Rx0 instead of the signals B4_Rx1, BC1_Tx, and BC1_Rx0.

  The filter 14 of the eleventh embodiment can process the signal B2_Rx1 instead of the signal BC1_Rx1. The second RF transceiver IC 22 of the eleventh embodiment can process the signals B2_Tx, B2_Rx0, and B2_Rx1 instead of the signals BC1_Tx, BC1_Rx0, and BC1_Rx1.

Next, the processing procedure at the time of transmission will be described.
(1) Carrier aggregation transmission processing The baseband IC 206 divides the uplink data into two systems of the baseband signal TxA and the baseband signal TxB, and outputs the baseband signal TxA to the first RF transceiver IC21. The signal TxB can be output to the second RF transceiver IC22.

  The baseband IC 206 divides uplink data into two systems of a baseband signal TxA and a baseband signal TxB, outputs the baseband signal TxA to the first RF transceiver IC21, and outputs the baseband signal TxB to the second RF It can be output to the transceiver IC 22.

  The first RF transceiver IC 21 can receive the baseband signal TxA and frequency-convert it into a signal in a band of B4_Tx. The first RF transceiver IC 21 can output a signal in a band of B4_Tx to the power amplifier 11.

  The power amplifier 11 can amplify the power of the signal in the B4_Tx band and output it to the duplexer 15. The duplexer 15 can output the signal in the band of B4_Tx to the first antenna ANT1 while preventing the signal from entering the reception path. The first antenna ANT1 capable of transmitting a signal in the B4_Tx band can transmit a signal in the B4_Tx band to the radio base station.

  The second RF transceiver IC 22 can receive the baseband signal TxB and frequency-convert it into a signal in a band of B2_Tx. The second RF transceiver IC 22 can output a signal in the B2_Tx band to the power amplifier 12.

  The power amplifier 12 can amplify the power of the signal in the B2_Tx band and output the amplified signal power to the quadplexer 31. The quadplexer 31 can output the signal in the B2_Tx band to the second antenna ANT2 while preventing the signal from being received in the reception path. The second antenna ANT2 capable of transmitting a signal in the B2_Tx band can transmit a signal in the B2_Tx band to the radio base station.

With the above operation, carrier aggregation transmission can be performed.
(2) MIMO reception processing and carrier aggregation reception processing The first antenna ANT1 capable of receiving a signal in the B4_Rx band can receive a signal from the radio base station and output the signal to the duplexer 15. The duplexer 15 can pass the B4_Rx band signal (B4_Rx0) and output it to the first RF transceiver IC21.

  The second antenna ANT2 capable of receiving signals in the B4_Rx band and the B2_Rx band can receive a signal from the radio base station and output the signal to the quadplexer 31. The quadplexer 31 can pass the B4_Rx band signal (B4_Rx1) and output it to the first RF transceiver IC 21 and pass the B2_Rx band signal (B2_Rx0) to the second RF transceiver IC21. It can be output to the transceiver IC 22.

  The first RF transceiver IC 21 can output to the baseband IC 206 a baseband signal RxA0 obtained by frequency conversion of the B4_Rx band signal (B4_Rx0) output from the duplexer 15. The first RF transceiver IC 21 can output a baseband signal RxA1 obtained by frequency-converting the B4_Rx band signal (B4_Rx1) output from the quadplexer 31 to the baseband IC 206.

  The third antenna ANT3 capable of receiving a signal in the B2_Rx band can receive a signal from the radio base station and output the signal to the filter 14. The filter 14 can pass the B2_Rx band signal (B2_Rx1) and output it to the second RF transceiver IC22.

  The second RF transceiver IC 22 can output, to the baseband IC 206, a baseband signal RxB0 obtained by frequency-converting the B2_Rx band signal (B2_Rx0) output from the quadplexer 31. The second RF transceiver IC 22 can output the baseband signal RxB1 obtained by frequency-converting the signal (B2_Rx1) in the B2_Rx band output from the filter 14 to the baseband IC 206.

  The baseband IC 206 can generate a signal RxA by performing MIMO reception processing on the baseband signal RxA0 and the baseband signal RxA1 sent from the first RF transceiver IC21. The baseband IC 206 can generate a signal RxB by performing MIMO reception processing on the baseband signal RxB0 and the baseband signal RxB1 transmitted from the second RF transceiver IC22. The baseband IC 206 can integrate the signal RxA and the signal RxB to generate downlink data output from the radio base station.

  With the above operation, MIMO reception processing and carrier aggregation reception processing can be performed.

The transmission process (1) and the reception process (2) described above can be executed simultaneously.
As described above, the wireless terminal according to the eleventh embodiment divides data into different frequency bands and transmits the data, receives the two data in the band A by different antennas, and the two data in the band B are different. Receive with antenna. As a result, the wireless terminal can execute both the carrier gregation communication function and the MIMO reception function.

(Modification)
The present disclosure is not limited to the above-described embodiment. The following modifications are also included in the present disclosure.

  (1) In the above embodiment, the wireless communication processing unit is configured by two or three ICs, but is not limited thereto. A plurality of IC functions may be mounted on a single IC.

  (2) In the second and fourth to eleventh embodiments, the quadplexer in which the input of one transmission filter is terminated is used, but the present invention is not limited to this. For example, a triplexer without a terminated filter may be used.

  (3) In the above embodiment, the wireless terminal can transmit two bands and receive two bands, but has been extended to transmit three or more bands and receive three or more bands. May be.

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

  1 wireless terminal, 2 antenna unit, 3 radio processing unit, 4 demultiplexing unit, 5 radio processing unit, 6, 106, 206 baseband IC, 11, 12 power amplifier, 13, 14 filter, 15, 16 duplexer, 19 switch Circuit, 21, 22 RF transceiver IC, 31 Quadplexer, 47, 48 Termination resistor, 440 Control unit, 50 Speaker, 52 Microphone, 54 Display, 56 Touch panel, 58 Camera, 42, 44, 72, 75 Transmit filter, 43 , 45, 73, 76 Reception filter, 92, 96 Transmission processing unit, 93, 94, 97, 98 Reception processing unit, ANT1, ANT2, ANT3, ANT4 antenna, P1-P3, T1-T16, T31-T35 terminals.

Claims (12)

A wireless terminal capable of transmitting using the first frequency band and the second frequency band and receiving using the third frequency band and the fourth frequency band,
A first antenna;
A second antenna;
A third antenna;
A radio processing unit configured to frequency-convert two upstream baseband signals and output the first frequency band transmission signal and the second frequency band transmission signal;
A baseband processing unit that performs baseband processing on a downstream signal received from the wireless processing unit and an upstream signal output to the wireless processing unit;
A transmission signal in the first frequency band is received from the radio processing unit and output to the first antenna, and a signal from the first antenna is received to receive the third frequency. A first multiplexer configured to output a received signal in a band to the wireless processing unit;
It is configured to receive a transmission signal of the second frequency band from the radio processing unit and output it to the second antenna, and to receive a signal from the second antenna to receive the third frequency. A second multiplexer configured to output a received signal in a band and a received signal in the fourth frequency band to the wireless processing unit;
A filter configured to receive a signal from the third antenna and output a reception signal of the fourth frequency band to the wireless processing unit;
The radio processing unit converts the received signal of the third frequency band output from the first multiplexer and the received signal of the third frequency band output from the second multiplexer into baseband signals, respectively. The first frequency signal and the second signal are generated by frequency conversion to the received signal in the fourth frequency band output from the second multiplexer, and the fourth frequency band output from the filter. Each of the received signals is converted into a baseband signal to generate a third signal and a fourth signal,
The baseband processing unit performs diversity reception processing on the first signal and the second signal, and diversity reception processing on the third signal and the fourth signal, thereby performing two systems of downlink bases A wireless terminal configured to obtain a band signal. The first multiplexer includes a first terminal connected to the first antenna;
A second terminal for receiving a transmission signal of the first frequency band;
A third terminal for outputting a reception signal of the third frequency band;
A transmission filter having pass characteristics of the first frequency band, disposed between the first terminal and the second terminal;
The wireless terminal according to claim 1, further comprising: a reception filter having a pass characteristic in the third frequency band and disposed between the first terminal and the third terminal. A wireless terminal capable of transmitting using the first frequency band and the second frequency band and receiving using the third frequency band and the fourth frequency band,
A first antenna;
A second antenna;
A radio processing unit configured to frequency-convert two upstream baseband signals and output the first frequency band transmission signal and the second frequency band transmission signal;
A baseband processing unit that performs baseband processing on a downstream signal received from the wireless processing unit and an upstream signal output to the wireless processing unit;
A first multiplexer;
It is configured to receive a transmission signal of the second frequency band from the radio processing unit and output it to the second antenna, and to receive a signal from the second antenna to receive the third frequency. A second multiplexer configured to output a received signal in a band and a received signal in the fourth frequency band to the wireless processing unit;
Filters,
A switch circuit configured to be switchable between a first state connecting the first antenna and the first multiplexer and a second state connecting the first antenna and the filter; Prepared,
The first multiplexer is configured to receive a transmission signal of the first frequency band from the wireless processing unit and output the transmission signal to the first antenna when the switch circuit is in the first state. And receiving a signal from the first antenna and outputting the received signal in the third frequency band to the wireless processing unit,
The filter is configured to receive a signal from the first antenna and output a received signal in the fourth frequency band to the wireless processing unit when the switch circuit is in the second state. ,
The wireless processing unit receives the received signal of the third frequency band output from the first multiplexer and the second output from the second multiplexer when the switch circuit is in the first state. The first frequency signal and the second frequency signal are converted into baseband signals by frequency conversion of the received frequency band signals of the third frequency band, and the fourth frequency band received signal output from the second multiplexer is Configured to generate a third signal by frequency conversion to a baseband signal;
The baseband processing unit includes a signal obtained by performing diversity reception processing on the first signal and the second signal when the switch circuit is in the first state, and the third signal. Is configured to obtain two downstream baseband signals consisting of
When the switch circuit is in the second state, the wireless processing unit receives the received signal in the fourth frequency band output from the second multiplexer and the fourth frequency output from the filter. The received signal in the band is frequency-converted to a baseband signal to generate a fourth signal and a fifth signal, and the received signal in the third frequency band output from the second multiplexer is a baseband signal. To generate a sixth signal,
The baseband processing unit includes a signal obtained by performing diversity reception processing on the fourth signal and the fifth signal when the switch circuit is in the second state, and the sixth signal. A wireless terminal configured to obtain two systems of downstream baseband signals. The first multiplexer includes a first terminal connected to the switch circuit;
A second terminal for receiving a transmission signal of the first frequency band;
A third terminal for outputting a reception signal of the third frequency band;
A transmission filter having pass characteristics of the first frequency band, disposed between the first terminal and the second terminal;
The wireless terminal according to claim 3, further comprising: a reception filter having pass characteristics in the third frequency band and disposed between the first terminal and the third terminal. The second multiplexer comprises:
A first terminal connected to the second antenna;
A second terminal for receiving a transmission signal of the second frequency band;
A third terminal for outputting a reception signal of the third frequency band;
A fourth terminal terminated with a termination resistor;
A fifth terminal for outputting a reception signal of the fourth frequency band;
A first transmission filter disposed between the first terminal and the second terminal;
A first reception filter having a pass characteristic of the third frequency band and disposed between the first terminal and the third terminal;
A second transmission filter disposed between the first terminal and the fourth terminal;
5. The method according to claim 1, further comprising: a second reception filter having a pass characteristic in the fourth frequency band and disposed between the first terminal and the fifth terminal. The wireless terminal described in 1. The wireless processing unit
The frequency conversion of the first baseband signal is performed to output the transmission signal of the first frequency band, and the reception signal of the third frequency band output from the first multiplexer, A first RF transceiver IC configured to frequency-convert the received signal of the third frequency band output from the second multiplexer into a baseband signal;
The second baseband signal is frequency-converted to output a transmission signal of the second frequency band, and the fourth frequency band reception signal output from the first multiplexer, And a second RF transceiver IC configured to frequency-convert the received signal in the fourth frequency band output from the second multiplexer into a baseband signal, respectively. The wireless terminal according to item 1. The first frequency band and the third frequency band are PCS (Personal Communications Service) 1900,
The wireless terminal according to any one of claims 1 to 4, wherein the second frequency band and the fourth frequency band are an AWS (Advanced Wireless Service) 1700. The first frequency band and the third frequency band are IMT ((International Mobile Telecommunication) 2100,
The wireless terminal according to any one of claims 1 to 4, wherein the second frequency band and the fourth frequency band are DCS (Digital Cellular Service) 1800.   The baseband processing unit is configured to generate a first system upstream baseband signal from the data, and generate a second system upstream baseband signal from the voice and output it to the wireless processing unit, The baseband processing unit configured to generate data from a first downlink baseband signal obtained by the radio processing unit and to generate sound from a second downlink baseband signal. The wireless terminal according to any one of 1 to 4.   The transmission data is divided to generate the two systems of upstream baseband signals and output to the wireless processing unit, and the two systems of downstream baseband signals obtained by the wireless processing unit The radio | wireless terminal of any one of Claims 1-4 further provided with the baseband process part comprised so that it may integrate. A wireless communication method for a wireless terminal capable of transmitting using a first frequency band and a second frequency band and receiving using a third frequency band and a fourth frequency band, the wireless terminal comprising: A first antenna, a second antenna, a third antenna, a radio processing unit, a baseband processing unit, a first multiplexer, a second multiplexer, and a filter,
The wireless communication method includes:
The radio processing unit frequency-converting two systems of upstream baseband signals and outputting the first frequency band transmission signal and the second frequency band transmission signal;
The first multiplexer receives a transmission signal of the first frequency band from the wireless processing unit and outputs the transmission signal to the first antenna, and the second multiplexer is connected to the first processing unit from the wireless processing unit. Receiving a transmission signal of frequency band 2 and outputting to the second antenna;
The first multiplexer receives a signal from the first antenna and outputs a reception signal of the third frequency band to the wireless processing unit, and the second multiplexer receives from the second antenna. And receiving the third frequency band received signal and the fourth frequency band received signal to the radio processing unit, and the filter receiving the signal from the third antenna. Outputting the received signal of the fourth frequency band to the wireless processing unit;
The radio processing unit converts the received signal of the third frequency band output from the first multiplexer and the received signal of the third frequency band output from the second multiplexer to baseband signals, respectively. The first frequency signal and the second signal are generated by frequency conversion to the received signal in the fourth frequency band output from the second multiplexer, and the fourth frequency band output from the filter. Each of the received signals is converted into a baseband signal to generate a third signal and a fourth signal;
The baseband processing unit performs diversity reception processing on the first signal and the second signal, and performs diversity reception processing on the third signal and the fourth signal, so that two downstream signals can be transmitted. A wireless communication method comprising: obtaining a baseband signal. A wireless communication method in a wireless terminal capable of transmitting using a first frequency band and a second frequency band and receiving using a third frequency band and a fourth frequency band, the wireless terminal Includes a first antenna, a second antenna, a radio processing unit, a baseband processing unit, a first multiplexer, a second multiplexer, a filter, the first antenna, and the first antenna. A switch circuit configured to be able to switch between a first state connecting a multiplexer and a second state connecting the first antenna and the filter;
The wireless communication method includes:
The switch circuit is set to a first state connecting the first antenna and the first multiplexer;
The radio processing unit frequency-converting two systems of upstream baseband signals and outputting the first frequency band transmission signal and the second frequency band transmission signal;
The first multiplexer receives a transmission signal of the first frequency band from the radio processing unit when the switch circuit is in the first state, and outputs the transmission signal to the first antenna, and the second antenna Receiving a transmission signal of the second frequency band from the wireless processing unit and outputting the transmission signal to the second antenna;
The first multiplexer receives a signal from the first antenna when the switch circuit is in the first state, and outputs a reception signal of the third frequency band to the wireless processing unit; The second multiplexer receiving a signal from the second antenna and outputting the received signal of the third frequency band and the received signal of the fourth frequency band to the radio processing unit;
When the switch circuit is in the first state, the radio processing unit receives the received signal in the third frequency band output from the first multiplexer and the second output from the second multiplexer. The first frequency signal and the second frequency signal are converted into baseband signals by frequency conversion of the received frequency band signals of the third frequency band, and the fourth frequency band received signal output from the second multiplexer is Generating a third signal by frequency conversion to a baseband signal;
When the baseband processing unit performs diversity reception processing on the first signal and the second signal when the switch circuit is in the first state, the third signal, Obtaining two downstream baseband signals consisting of:
The switch circuit is set to a second state connecting the first antenna and the filter;
The filter receiving a signal from the first antenna when the switch circuit is in the second state, and outputting a received signal in the fourth frequency band to the wireless processing unit;
The wireless processing unit receives the fourth frequency band received signal output from the second multiplexer and the fourth frequency output from the filter when the switch circuit is in the second state. The received signal in the band is frequency-converted to a baseband signal to generate a fourth signal and a fifth signal, and the received signal in the third frequency band output from the second multiplexer is a baseband signal. Generating a sixth signal by frequency conversion to:
When the baseband processing unit performs diversity reception processing on the fourth signal and the fifth signal when the switch circuit is in the second state; and the sixth signal; A wireless communication method comprising: obtaining two downstream downlink baseband signals.

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