JP6405698B2 - Wireless communication apparatus and wireless communication method - Google Patents

Description

  The present invention relates to a wireless communication apparatus and a wireless communication method.

  There is a radio communication apparatus that performs multicarrier transmission in which data is transmitted using a plurality of carriers, such as a radio base station in an LTE (Long Term Evolution) system. In general, such a wireless communication apparatus amplifies and transmits a signal in a radio frequency band with an amplifier (AMP). However, distortion often occurs in the amplified signal of the AMP. Therefore, in the wireless communication apparatus as described above, DPD (Digital PreDistortion) for correcting the input signal of the AMP with the inverse characteristic of the distortion characteristic of the AMP is often performed as the distortion compensation of the amplified signal of the AMP (for example, Patent document 1 (refer Unexamined-Japanese-Patent No. 2010-153937).

JP 2010-153937 A

FIG. 8 is a block diagram illustrating an example of a configuration of a wireless communication apparatus that performs multicarrier transmission.
8 includes a BB (BaseBand) 11, an INTFC (Interface) 12, a DPD 13, a TRX (Transmitter / Receiver) 14, an AMP 15, a SW (Switch) 16, and an ANT (Antenna). 17 and LNA 18 (Low Noise Amplifier). In the following, it is assumed that radio communication apparatus 10 performs multicarrier transmission using two carriers (carriers C1 and C2). In the following description, it is assumed that the wireless communication device 10 performs communication using a TDD (Time Division Duplex) method that switches transmission and reception of signals according to time.
The BB 11 generates a baseband frequency signal in which the signal S1 transmitted by the carrier C1 and the signal S2 transmitted by the carrier C2 are multiplexed, and outputs the generated signal to the INTFC 12.
The INTFC 12 converts the signal output from the BB 11 into a format that can be processed by the TRX 14 and outputs the converted signal to the DPD 13. The INTFC 12 converts the signal output from the TRX 14 into a format that can be processed by the BB 11 and outputs the converted signal to the BB 11.
The DPD 13 receives a part of the output of the AMP 15 via the TRX 14, corrects the signal output from the INTFC 12 (distortion compensation) based on the inverse characteristic of the distortion characteristic of the AMP 15, and outputs the corrected signal to the TRX 14. To do.
The TRX 14 up-converts the signal output from the DPD 13 to a radio frequency, and outputs the up-converted signal to the AMP 15. The TRX 14 downconverts the signal output from the LNA 18 to the baseband frequency, and outputs the downconverted signal to the INTFC 12.
The AMP 15 amplifies the signal output from the TRX 14 and multiplexed with the signal S1 and the signal S2 to a desired output level.
The SW 16 connects the ANT 17 and the AMP 15 when transmitting a signal, and connects the ANT 17 and the LNA 18 when receiving a signal.
The ANT 17 wirelessly transmits the signal S1 output from the AMP 15 using the carrier C1, and wirelessly transmits the signal S2 using the carrier C2. Further, when the ANT 17 receives the signal transmitted wirelessly, the ANT 17 outputs the received signal to the LNA 18.
The LNA 18 amplifies the signal output from the ANT 17 and outputs the amplified signal to the INTFC 12.
In general, in multicarrier transmission, a peak factor, which is a ratio of instantaneous power to average power, becomes high. Therefore, the wireless communication device 10 needs to use the AMP 15 having a high saturation output. However, the use of AMP having a high saturated output causes problems such as high cost, increase in device size, and increase in power consumption.
Further, in the wireless communication device 10, there is a problem that it is difficult to compensate for distortion of the amplified signal of the AMP 15, and communication characteristics in multicarrier transmission are deteriorated.
FIG. 9 is a diagram illustrating an example of an input signal to the AMP 15.
FIG. 9 shows an input signal composed of two carriers C1 and C2 each having a bandwidth of 20 MHz. When this signal is amplified by the AMP 15, distortion (IM (Intermodulation) component) is generated in the amplified signal as shown in FIG. 10. In FIG. 10, IM components are generated on the low frequency side of the carrier C1 and the high frequency side of the carrier C2, and the amplified signal has a wide band.

  In LTE and LTE-Advanced, a non-continuous (non-continuous) signal as shown in FIG. 11 is defined. In FIG. 11, there is a 20 MHz interval between the carrier C1 and the carrier C2. FIG. 12 shows an amplified signal when such a signal is amplified by the APM 15. As shown in FIG. 12, in the amplified signal of the AMP 15, IM components are generated on the low frequency side of the carrier C1 and the high frequency side of the carrier C2, and the bandwidth is widened to about 140 MHz.

  Compensation for distortion of the amplified signal of the AMP 15 having a wide band is extremely difficult due to band limitations of a digital circuit, a D / A (Digital to Analog) converter, an A / D (Analog to Digital) converter, and the like. In general, the signal bandwidth capable of distortion compensation by DPD is about 100 MHz. Therefore, it may be difficult for the wireless communication device 10 to compensate for distortion of the amplified signal of the AMP 15.

  Therefore, in order to solve the above-described problem, it is conceivable to provide an AMP for each carrier in the wireless communication apparatus. FIG. 13 is a block diagram showing a configuration of such a wireless communication device 20. In FIG. 13, the same components as those in FIG. 8 are denoted by the same reference numerals, and description thereof is omitted. In addition, the configuration and operation of the reception system of the wireless communication device 20 are the same as those of the wireless communication device 10, and thus description thereof is omitted.

The wireless communication device 20 includes a BB 11, an INTFC 21, a DPD 22, a TRX 23, AMPs 24 a and 24 b, a hybrid synthesis unit 25, a SW 26, an ANT 17, and an LNA 18.
The INTFC 21 separates the signal output from the BB 11 into a signal S 1 transmitted on the carrier C 1 and a signal S 2 transmitted on the carrier C 2, and outputs the signals S 1 and S 2 to the DPD 22, respectively.
The DPD 22 receives a part of the output of the AMP 24a via the TRX 23, corrects the signal S1 output from the INTFC 21 based on the inverse characteristic of the distortion characteristic of the AMP 24a (distortion compensation), and converts the corrected signal S1 into the TRX 23. Output to. The DPD 22 receives a part of the output of the AMP 24b via the TRX 23, corrects (distorts) the signal S2 output from the INTFC 21 based on the inverse characteristic of the distortion characteristic of the AMP 24b, and corrects the signal S2 after correction. Is output to TRX23.
The TRX 23 up-converts the signal S1 and the signal S2 output from the DPD 22 to radio frequencies, and outputs the up-converted signal S1 to the AMP 24a. The TRX 33 outputs the upconverted signal S2 to the amplifier 24b.
The AMP 24a amplifies the signal S1 output from the TRX 23 to a desired output level. The AMP 24b amplifies the signal S2 output from the TRX 23 to a desired output level.
The hybrid synthesizer (H) 25 synthesizes the amplified signal of the AMP 24a and the amplified signal of the AMP 24b.
The SW 26 connects the ANT 17 and the hybrid synthesizer 25 when transmitting a signal, and connects the ANT 17 and the LNA 18 when receiving a signal. By connecting the hybrid synthesizer 25 and the ANT 17, the amplified signal of the AMP 24 a and the amplified signal of the AMP 24 b synthesized by the hybrid synthesizer 25 are wirelessly transmitted.

  In the wireless communication device 20, the input signal of each AMP 24 is a signal for one carrier. Accordingly, since each AMP 24 amplifies only a signal for one carrier, it is not necessary to use an AMP having a high saturation output. Therefore, it is possible to suppress the cost increase of the device. Further, since each AMP 24 amplifies only the signal for one carrier, the frequency band for compensating distortion of the amplified signal of each AMP 24 is smaller than the frequency band for which the DPD 13 of the wireless communication apparatus 10 compensates for distortion. Therefore, in the wireless communication device 20, it is possible to suppress the occurrence of the problem that distortion compensation becomes difficult due to the wide band of the AMP amplified signal. However, in the wireless communication apparatus 20, the hybrid synthesizer 25 synthesizes the amplified signal of the AMP 24 a and the amplified signal of the AMP 24 b. As described above, when two signals are combined using a hybrid combiner, a loss occurs and power consumption increases.

  An object of the present invention is to provide a wireless communication apparatus and a wireless communication method capable of suppressing a decrease in communication characteristics in multicarrier transmission without causing an increase in apparatus cost and power consumption.

In order to achieve the above object, a wireless communication device of the present invention includes a signal generation unit that generates a first signal , a second signal , a third signal, and a fourth signal ,
A first amplifier for amplifying the first signal;
A second amplifier for amplifying the second signal;
A third amplifier for amplifying the third signal;
A fourth amplifier for amplifying the fourth signal;
The amplified signal of the first amplifier is transmitted on the first carrier with the first polarization, and the amplified signal of the second amplifier is transmitted on the second carrier with the second polarization orthogonal to the first polarization. A first antenna that transmits in polarization ;
The amplified signal of the third amplifier is transmitted on the first carrier with the first polarization, and the amplified signal of the fourth amplifier is transmitted on the second carrier with the second polarization. A second antenna to
A first low noise amplifier that amplifies the first polarization signal and the second polarization signal received by the first antenna;
A second low-noise amplifier that amplifies the signal of the first polarization and the signal of the second polarization received by the second antenna;
The signal generation unit uses the at least one of the amplified signal of the first low noise amplifier and the amplified signal of the second low noise amplifier to use the first polarized signal and the second polarized signal. Is demodulated.
Alternatively, the wireless communication device of the present invention is
A signal generator for generating a first signal, a second signal, a third signal, and a fourth signal;
A first amplifier for amplifying the first signal;
A second amplifier for amplifying the second signal;
A third amplifier for amplifying the third signal;
A fourth amplifier for amplifying the fourth signal;
The amplified signal of the first amplifier is transmitted on the first carrier with the first polarization, and the amplified signal of the third amplifier is transmitted on the second carrier with the second polarization orthogonal to the first polarization. A first antenna that transmits in polarization;
The amplified signal of the second amplifier is transmitted on the first carrier with the first polarization, and the amplified signal of the fourth amplifier is transmitted on the second carrier with the second polarization. A second antenna to
A first low noise amplifier that amplifies the first polarization signal and the second polarization signal received by the first antenna;
A second low-noise amplifier that amplifies the signal of the first polarization and the signal of the second polarization received by the second antenna;
The signal generation unit uses the at least one of the amplified signal of the first low noise amplifier and the amplified signal of the second low noise amplifier to use the first polarized signal and the second polarized signal. Is demodulated.

In order to achieve the above object, a wireless communication method of the present invention includes:
Generating a first signal , a second signal , a third signal and a fourth signal ;
Amplifying the first signal with a first amplifier;
Amplifying the second signal with a second amplifier;
Amplifying the third signal with a third amplifier;
Amplifying the fourth signal with a fourth amplifier;
The amplified signal of the first amplifier is transmitted from the first antenna with the first carrier at the first polarization, and the amplified signal of the second amplifier is transmitted with the first polarization with the second carrier. Transmitting from the first antenna with a second orthogonal polarization ;
The amplified signal of the third amplifier is transmitted from the second antenna on the first carrier at the first polarization, and the amplified signal of the fourth amplifier is transmitted on the second carrier on the second carrier. Transmit from the second antenna in polarization,
Amplifying the first polarization signal and the second polarization signal received by the first antenna with a first low-noise amplifier;
Amplifying the first polarization signal and the second polarization signal received by the second antenna with a second low-noise amplifier;
The first polarization signal and the second polarization signal are demodulated using at least one of the amplified signal of the first low noise amplifier and the amplified signal of the second low noise amplifier. It is a method .
Alternatively, the wireless communication method of the present invention includes:
Generating a first signal, a second signal, a third signal and a fourth signal;
Amplifying the first signal with a first amplifier;
Amplifying the second signal with a second amplifier;
Amplifying the third signal with a third amplifier;
Amplifying the fourth signal with a fourth amplifier;
The amplified signal of the first amplifier is transmitted from the first antenna on the first carrier with the first polarization, and the amplified signal of the third amplifier is transmitted on the second carrier with the first polarization. Transmitting from the first antenna with a second orthogonal polarization;
The amplified signal of the second amplifier is transmitted from the second antenna at the first polarization with the first carrier, and the amplified signal of the fourth amplifier is transmitted with the second carrier on the second carrier. Transmit from the second antenna in polarization,
Amplifying the first polarization signal and the second polarization signal received by the first antenna with a first low-noise amplifier;
Amplifying the first polarization signal and the second polarization signal received by the second antenna with a second low-noise amplifier;
The first polarization signal and the second polarization signal are demodulated using at least one of the amplified signal of the first low noise amplifier and the amplified signal of the second low noise amplifier. It is a method.

  ADVANTAGE OF THE INVENTION According to this invention, the fall of the communication characteristic in multicarrier transmission can be suppressed, without causing the increase in apparatus cost and the increase in power consumption.

It is a block diagram which shows the structure of the radio | wireless communication apparatus of the 1st Embodiment of this invention. It is a block diagram which shows the structure of the radio | wireless communication apparatus of the 2nd Embodiment of this invention. It is a figure which shows an example of the amplified signal of AMP shown in FIG. It is a figure which shows an example of the amplified signal of AMP shown in FIG. It is a figure which shows an example of a structure of ANT shown in FIG. It is a block diagram which shows the other structure of the radio | wireless communication apparatus of the 1st Embodiment of this invention. It is a block diagram which shows the structure of the radio | wireless communication apparatus of the 3rd Embodiment of this invention. It is a block diagram which shows an example of a structure of a related radio | wireless communication apparatus. It is a figure which shows an example of the input signal to AMP shown in FIG. It is a figure which shows an example of the amplified signal of AMP shown in FIG. It is a figure which shows another example of the input signal to AMP shown in FIG. It is a figure which shows another example of the amplified signal of AMP shown in FIG. It is a figure which shows another example of a structure of a related radio | wireless communication signal.

  EMBODIMENT OF THE INVENTION Below, the form for implementing this invention is demonstrated with reference to drawings.

(First embodiment)
FIG. 1 is a block diagram illustrating a configuration of a wireless communication device 100 according to the first embodiment of this invention. Note that the radio communication apparatus according to the present invention is a radio base station in a radio communication system in which multicarrier transmission such as LTE and LTE-Advanced is performed. The radio communication apparatus according to the present invention is suitable for use in a small base station constituting a relatively small cell (small cell), an all-in-one type radio base station having a configuration in which an antenna is integrated, and the like. . In the following, it is assumed that the wireless communication apparatus according to the present invention performs multicarrier transmission using two carriers (carriers C1 and C2).

A wireless communication device 100 illustrated in FIG. 1 includes a signal generation unit 110, AMPs 120a and 120b, and an ANT 130. The AMP 120a is an example of a first amplifier. The AMP 120b is an example of a second amplifier.
The signal generator 110 generates a signal S1 as a first signal and a signal S2 as a second signal. The signal generator 110 outputs the signal S1 to the AMP 120a, and outputs the signal S2 to the AMP 120b. The signals S1 and S2 are radio frequency band signals.
The AMP 120a amplifies the signal S1 output from the signal generation unit 110.
The AMP 120b amplifies the signal S2 output from the signal generation unit 110.
The ANT 130 transmits the amplified signal of the AMP 120a on the carrier C1 (first carrier) with the first polarization, and the amplified signal of the AMP 120b on the carrier C2 (second carrier) with the first polarization. Transmission is performed using the second polarized wave that is orthogonal.

  As described above, the wireless communication apparatus 100 according to the present embodiment includes the AMP 120a that amplifies the signal S1 and the AMP 120b that amplifies the signal S2. In addition, the wireless communication device 100 transmits the amplified signal of the AMP 120a with the first polarization on the carrier C1, and the amplified signal of the AMP 120b with the second polarization orthogonal to the first polarization on the carrier C2. And an antenna 130 for transmitting.

  Since each AMP 120 amplifies only a signal for one carrier, it is not necessary to use an AMP having a high saturation output, and thus the cost of the apparatus can be suppressed. Further, since each AMP 120 amplifies only a signal for one carrier, it is possible to prevent the frequency band for distortion compensation of the amplified signal of each AMP 120 from being widened, and distortion compensation of the amplified signal of each AMP 120 is possible. Therefore, it is possible to suppress a decrease in communication characteristics in multicarrier transmission. Also, by transmitting the amplified signal of the AMP 120a with the first polarization on the carrier C1, and transmitting the amplified signal of the AMP 120b with the second polarization orthogonal to the first polarization by the carrier C2, There is no need to synthesize the amplified signal of each AMP 120 with a hybrid synthesizer or the like. For this reason, it is possible to prevent loss due to signal synthesis and suppress an increase in power consumption.

(Second Embodiment)
In LTE-Advanced, a radio base station is required to support MIMO (Multi-Input Multi-Output) as well as multicarrier transmission. In the present embodiment, a radio communication apparatus suitable for such a radio base station will be described. In the following, it is assumed that the wireless communication apparatus according to the present embodiment performs MIMO communication using two antennas.

FIG. 2 is a block diagram illustrating a configuration of the wireless communication apparatus 200 according to the present embodiment.
2 includes BB 210, INTFCs 220a and 220b, DPDs 230a and 230b, TRXs 240a and 240b, AMPs 250a to 250d, SWs 260a to 260d, ANTs 270a and 270b, and LNAs 280a to 280d. The AMP 250a is an example of a first amplifier. The AMP 250b is an example of a second amplifier. The AMP 250c is an example of a third amplifier. The AMP 250d is an example of a fourth amplifier. The ANT 270a is an example of a first antenna. The ANT 270b is an example of a second antenna. The DPD 230a is an example of a first distortion compensation unit. The DPD 230b is an example of a second distortion compensation unit. The LNA 280a is an example of a first low noise amplifier. The LNA 280b is an example of a second low noise amplifier. The LNA 280c is an example of a third low noise amplifier. The LNA 280d is an example of a fourth low noise amplifier.

  The BB 210 is a digital signal in which a signal S1 transmitted from the ANT 270a by the carrier C1, a signal S2 transmitted from the ANT 270a by the carrier C2, a signal S3 transmitted from the ANT 270b by the carrier C1, and a signal S4 transmitted from the ANT 270a by the carrier C2 are time-division multiplexed. Is generated. The BB 210 outputs the generated signal to the INTFCs 220a and 220b.

  The INTFC 220a separates the signal S1 and the signal S2 from the signal output from the BB 210, and outputs the separated signal S1 and signal S2 to the DPD 230a. The INTFC 220b separates the signal S3 and the signal S4 from the signal output from the BB 210, and outputs the separated signal S3 and the signal S4 to the DPD 230b.

A part of the output of the AMP 250a and a part of the output of the AMP 250b are input to the DPD 230a via the TRX 240a. The DPD 230a corrects the signal S1 output from the INTFC 220a based on the inverse characteristic of the distortion characteristic of the AMP 250a (distortion compensation), and outputs the corrected signal to the TRX 240a. In addition, the DPD 230a corrects (distortion compensation) the signal S2 output from the INTFC 220a based on the inverse characteristic of the distortion characteristic of the AMP 250b, and outputs the corrected signal to the TRX 240a.
A part of the output of the AMP 250c and a part of the output of the AMP 250d are input to the DPD 230b via the TRX 240b. The DPD 230b corrects (distortion compensation) the signal S3 output from the INTFC 220b based on the inverse characteristic of the distortion characteristic of the AMP 250c, and outputs the corrected signal to the TRX 240b. Further, the DPD 230b corrects (distortion compensation) the signal S4 output from the INTFC 220b based on the inverse characteristic of the distortion characteristic of the AMP 250d, and outputs a correction degree signal to the TRX 240b.
The INTFCs 220a and 220b and the DPDs 230a and 230b are digital circuits, and include, for example, an FPGA (Field Programmable Gate Array).

The TRX 240a up-converts the signal S1 and the signal S2 output from the DPD 230a to a radio frequency. The TRX 240a outputs the signal S1 after the up-conversion to the AMP 250a, and outputs the signal S2 after the up-conversion to the AMP 250b. The TRX 240a down-converts the signals output from the LNAs 280a and 280b to the baseband frequency and outputs the down-converted signal to the INTFC 220a.
The TRX 240b up-converts the signal S3 and the signal S4 output from the DPD 230b to a radio frequency. The TRX 240b outputs the upconverted signal S3 to the AMP 250c, and outputs the upconverted signal S4 to the AMP 250d. The TRX 240b down-converts the signals output from the LNAs 280c and 280d to a baseband frequency and outputs the down-converted signal to the INTFC 220b.
The BB 210, the INTFCs 220a and 220b, the DPDs 230a and 230b, and the TRXs 240a and 240b constitute a signal processing unit 290. Note that the signal processing unit 110 in the wireless communication apparatus 200 according to the first embodiment includes, for example, a BB 210, an INTFC 220a, a DPD 230a, and a TRX 240a.

The AMP 250a amplifies the signal S1 output from the TRX 240a to a desired output level. The AMP 250b amplifies the signal S2 output from the TRX 240a to a desired output level. The AMP 250c amplifies the signal S3 output from the TRX 240b to a desired output level. The AMP 250d amplifies the signal S4 output from the TRX 240b to a desired output level.
The signal amplified by each amplifier 250 is a signal for one carrier, and the bandwidth is, for example, 20 MHz and a relatively narrow band. Therefore, since the frequency band in which the DPD 230 performs distortion compensation on the amplified signal of each AMP 250 is also relatively narrow, distortion compensation is possible, and distortion can be prevented from occurring in the amplified signal of the AMP 250.

  FIG. 3 is a diagram illustrating an example of the amplified signals of the AMPs 250a and 250b. Since the band of the signal amplified by the AMPs 250a and 250b is narrow, highly accurate distortion compensation is possible in the DPD 230a. As shown in FIGS. 3 and 4, an amplified signal with suppressed distortion (IM component) can be obtained. Can be obtained. FIG. 4 shows an example of an amplified signal when the input signal of the AMP 250 is a non-continuous signal. Similarly, an amplified signal with suppressed distortion can be obtained for the AMPs 250c and 250d.

  Referring to FIG. 2 again, the SW 260a connects the ANT 270a and the AMP 250a when transmitting a signal, and connects the ANT 270a and the LNA 280a when receiving a signal. The SW 260b connects the ANT 270a and the AMP 250b when transmitting a signal, and connects the ANT 270a and the LNA 280b when receiving a signal. The SW 260c connects the ANT 270b and the AMP 250c when transmitting a signal, and connects the ANT 270b and the LNA 280c when receiving a signal. The SW 260d connects the ANT 270b and the AMP 250d when transmitting a signal, and connects the ANT 270b and the LNA 280d when receiving a signal.

The ANT 270a wirelessly transmits the signal S1 output from the AMP 250a, and wirelessly transmits the signal S2 output from the AMP 250b. Here, the ANT 270a transmits the signal S1 output from the AMP 250a with the carrier C1 in the vertical polarization, and transmits the signal S2 output from the AMP 250b with the carrier C2 in the horizontal polarization.
Further, when the AMT 270a receives a signal wirelessly transmitted by the carrier C1, the AMT 270a outputs a received signal to the LNA 270a, and when receiving a signal wirelessly transmitted by the carrier C2, the AMT 270a outputs the received signal to the LNA 270b.
The ANT 270b wirelessly transmits the signal S3 output from the AMP 250c, and wirelessly transmits the signal S4 output from the AMP 250d. Here, the ANT 270b transmits the signal S3 output from the AMP 250c with the carrier C1 in the vertical polarization, and transmits the signal S4 output from the AMP 250d with the carrier C2 in the horizontal polarization.
In addition, when the AMT 270b receives a signal wirelessly transmitted by the carrier C1, the AMT 270b outputs a reception signal to the LNA 270c, and when receiving a signal wirelessly transmitted by the carrier C2, the AMT 270b outputs the reception signal to the LNA 270d.

FIG. 5 is a diagram showing the configuration of the ANT270.
The ANT 270 is a planar antenna having a configuration in which a patch antenna element 272 is formed on a dielectric substrate 271. The patch antenna element 272 includes two ports, a feed line 273a extending in the X direction and a feed line 273b extending in the Y direction. By connecting different AMPs to the two ports, the amplified signal of one AMP is transmitted by the carrier C1 with vertical polarization, and the amplified signal of the other AMP is transmitted by the carrier C2 with horizontal polarization. Can do.

  Referring to FIG. 2 again, the LNA 280a amplifies the signal output from the ANT 270a and outputs the amplified signal to the TRX 240a. The LNA 280b amplifies the signal output from the ANT 270a and outputs the amplified signal to the TRX 240a. The LNA 280c amplifies the signal output from the ANT 270b and outputs the amplified signal to the TRX 240b. The LNA 280d amplifies the signal output from the ANT 270b and outputs the amplified signal to the TRX 240b. A signal output from each LNA 280 is input to the BB 210 via the TRX 240 and the INTFC 220. The BB 210 can perform diversity reception using signals received by different ANTs 270. The BB 210 demodulates the transmitted signal using at least one of the signal output from the INTFC 220a and the signal output from the INTFC 220b.

  With the configuration described above, radio communication apparatus 200 can perform multicarrier transmission using carriers C1 and C2. Also, the wireless communication apparatus 200 can perform MIMO transmission in which signals of different streams are transmitted from the two antennas (ANTs 270a and 270b).

  As described above, the wireless communication apparatus 200 according to the present embodiment includes the AMP 250a that amplifies the signal S1, the AMP 250b that amplifies the signal S2, the AMP 250c that amplifies the signal S3, and the AMP 250d that amplifies the signal S4. The radio communication apparatus 200 also includes an ANT 270a that transmits the amplified signal of the AMP 250a by the carrier C1 with vertical polarization and transmits the amplified signal of the AMP 250b by the carrier C2 with horizontal polarization. The wireless communication apparatus 200 also includes an ANT 270b that transmits the amplified signal of the AMP 250c with the carrier C1 in the vertical polarization and transmits the amplified signal of the AMP 250d with the carrier C2 with the horizontal polarization.

  Since each AMP 250 only amplifies a signal for one carrier, it is not necessary to use an AMP having a high saturation output, so that the cost of the apparatus can be suppressed. In addition, each AMP 250 amplifies only a signal for one carrier, so that it is possible to prevent the band for distortion compensation of the amplified signal of each AMP 250 from being widened and to perform distortion compensation. Therefore, it is possible to suppress a decrease in communication characteristics in multicarrier transmission. Further, by transmitting the amplified signals of the two AMPs 250 with different carriers and different polarizations, it is not necessary to synthesize the amplified signals of each AMP with a hybrid synthesizer or the like. For this reason, it is possible to prevent loss due to signal synthesis and suppress an increase in power consumption. MIMO transmission is possible by transmitting different stream signals from the ANTs 270a and 270b.

In the wireless communication device 200, the amplified signal of the AMP 250a is transmitted from the ANT 270a with the carrier C1 in the vertical polarization. Further, the amplified signal of the AMP 250b is transmitted from the ANT 270a with the carrier C2 in the horizontally polarized wave. Further, the amplified signal of the AMP 250c is transmitted from the ANT 270b by the carrier C1 with vertical polarization. Further, the amplified signal of the AMP 250d is transmitted from the ANT 270b with the carrier C2 in the horizontally polarized wave. However, the present invention is not limited to this.
As a modification, the wireless communication apparatus of the present embodiment may have the configuration shown in FIG.

FIG. 6 is a block diagram illustrating another configuration of the wireless communication apparatus according to the first embodiment of this invention. In FIG. 6, the same components as those in FIG.
6 is different from the wireless communication device 200 shown in FIG. 1 in the connection relationship between the AMP 250 and the ANT 270. The wireless communication device 200A shown in FIG. Specifically, the AMP 250a is connected to the ANT 270a via the SW 260a. The AMP 250b is connected to the ANT 270b via the SW 260b. The AMP 250c is connected to the ANT 270a via the SW 260c. The AMP 250d is connected to the ANT 270b via the SW 260d.
The ANT 270a transmits the amplified signal of the AMP 250a using the carrier C1 with vertical polarization, and transmits the amplified signal of the AMP 250c using the carrier C2 with horizontal polarization. The ANT 270b transmits the amplified signal of the AMP 250b using the carrier C1 with vertical polarization, and transmits the amplified signal of the AMP 250d using the carrier C2 with horizontal polarization.
Also in the radio communication apparatus 200A shown in FIG. 6, the same effect as that of the radio communication apparatus 200 shown in FIG. 1 can be obtained.

(Third embodiment)
FIG. 7 is a block diagram illustrating a configuration of a wireless communication device 200B according to the third embodiment of this invention. 7, the same components as those in FIG. 2 are denoted by the same reference numerals, and the description thereof is omitted.
The wireless communication device 200B according to the present embodiment is different from the wireless communication device 200 according to the second embodiment in that the SWs 260b, 260d, LNA 280b, and LNA 280d are deleted. Further, with the deletion described above, the AMP 250b is connected to the ANT 270a, and the AMP 250d is connected to the ANT 270a.
That is, in the second embodiment, two reception systems (LNA 280a and 280b) are provided for one ANT 270, whereas in the wireless communication device 200B of the present embodiment, one ANT 270 is provided. On the other hand, one receiving system (LNA 280a) is provided.
In general, the LNA 280 operates at a point where there is a margin in saturation power as compared with the AMP 250, and the bandwidth can be easily increased. Therefore, the LNA 280 can easily amplify signals for two carriers received by the ANT 270. Therefore, as in the first embodiment, it is possible to appropriately process a received signal without providing two reception systems (LNA) for one ANT 270.

As described above, the wireless communication device 200B of the present embodiment has one reception system (LNA 280) for one ANT 270.
Therefore, the number of LNAs can be reduced and the device configuration can be simplified. Further, since the AMPs 250b and 250d are directly connected to the ANT 270, the SW 260 is unnecessary between the AMP 250b and the ANT 270a and between the ANT 250d and the NT 270b. Therefore, transmission loss in the SW 260 can be reduced, and the wireless communication device 200B can be reduced in size and power can be saved.

  In the above-described embodiment, the description has been given using the example in which one of the signals of the carriers C1 and C2 is transmitted by vertical polarization and the other is transmitted by horizontal polarization. However, the present invention is not limited to this. Absent. In short, it is only necessary that the plane of polarization differs between the polarization for transmitting the signal of the carrier C1 and the polarization for transmitting the signal of the carrier C2.

100, 200, 200A, 200B Wireless communication device 110, 290 Signal generation unit 120, 250 AMP
130,270 ANT
210 BB
220 INTFC
230 DPD
240 TRX
260 SW
280 LNA
271 Dielectric substrate 272 Patch antenna element 273 Feed line

Claims (7)

A signal generator for generating a first signal , a second signal , a third signal, and a fourth signal ;
A first amplifier for amplifying the first signal;
A second amplifier for amplifying the second signal;
A third amplifier for amplifying the third signal;
A fourth amplifier for amplifying the fourth signal;
The amplified signal of the first amplifier is transmitted on the first carrier with the first polarization, and the amplified signal of the second amplifier is transmitted on the second carrier with the second polarization orthogonal to the first polarization. A first antenna that transmits in polarization ;
The amplified signal of the third amplifier is transmitted on the first carrier with the first polarization, and the amplified signal of the fourth amplifier is transmitted on the second carrier with the second polarization. A second antenna to
A first low noise amplifier that amplifies the first polarization signal and the second polarization signal received by the first antenna;
A second low-noise amplifier that amplifies the signal of the first polarization and the signal of the second polarization received by the second antenna;
The signal generation unit uses the at least one of the amplified signal of the first low noise amplifier and the amplified signal of the second low noise amplifier to use the first polarized signal and the second polarized signal. A radio communication apparatus for demodulating A signal generator for generating a first signal, a second signal, a third signal, and a fourth signal;
A first amplifier for amplifying the first signal;
A second amplifier for amplifying the second signal;
A third amplifier for amplifying the third signal;
A fourth amplifier for amplifying the fourth signal;
The amplified signal of the first amplifier is transmitted on the first carrier with the first polarization, and the amplified signal of the third amplifier is transmitted on the second carrier with the second polarization orthogonal to the first polarization. A first antenna that transmits in polarization;
The amplified signal of the second amplifier is transmitted on the first carrier with the first polarization, and the amplified signal of the fourth amplifier is transmitted on the second carrier with the second polarization. A second antenna to
A first low noise amplifier that amplifies the first polarization signal and the second polarization signal received by the first antenna;
A second low-noise amplifier that amplifies the signal of the first polarization and the signal of the second polarization received by the second antenna;
The signal generation unit uses the at least one of the amplified signal of the first low noise amplifier and the amplified signal of the second low noise amplifier to use the first polarized signal and the second polarized signal. A radio communication apparatus for demodulating The wireless communication device according to claim 1 or 2 ,
The wireless communication apparatus, wherein the first and second antennas are dual polarization antennas. In the radio | wireless communication apparatus of any one of Claim 1 to 3 ,
The signal generator is
First distortion compensation that corrects the first signal based on an inverse characteristic of the distortion characteristic of the first amplifier and corrects the second signal based on an inverse characteristic of the distortion characteristic of the second amplifier. And
Second distortion compensation that corrects the third signal based on the inverse characteristic of the distortion characteristic of the third amplifier and corrects the fourth signal based on the inverse characteristic of the distortion characteristic of the fourth amplifier. A wireless communication device. In the wireless communication device according to any one of claims 1 to 4,
The wireless communication apparatus, wherein the first antenna and the second antenna are for MIMO (Multi-Input Multi-Output) communication. Generating a first signal , a second signal , a third signal and a fourth signal ;
Amplifying the first signal with a first amplifier;
Amplifying the second signal with a second amplifier;
Amplifying the third signal with a third amplifier;
Amplifying the fourth signal with a fourth amplifier;
The amplified signal of the first amplifier is transmitted from the first antenna with the first carrier at the first polarization, and the amplified signal of the second amplifier is transmitted with the first polarization with the second carrier. Transmitting from the first antenna with a second orthogonal polarization ;
The amplified signal of the third amplifier is transmitted from the second antenna on the first carrier at the first polarization, and the amplified signal of the fourth amplifier is transmitted on the second carrier on the second carrier. Transmit from the second antenna in polarization,
Amplifying the first polarization signal and the second polarization signal received by the first antenna with a first low-noise amplifier;
Amplifying the first polarization signal and the second polarization signal received by the second antenna with a second low-noise amplifier;
The first polarization signal and the second polarization signal are demodulated using at least one of the amplified signal of the first low noise amplifier and the amplified signal of the second low noise amplifier. A wireless communication method. Generating a first signal, a second signal, a third signal and a fourth signal;
Amplifying the first signal with a first amplifier;
Amplifying the second signal with a second amplifier;
Amplifying the third signal with a third amplifier;
Amplifying the fourth signal with a fourth amplifier;
The amplified signal of the first amplifier is transmitted from the first antenna on the first carrier with the first polarization, and the amplified signal of the third amplifier is transmitted on the second carrier with the first polarization. Transmitting from the first antenna with a second orthogonal polarization;
The amplified signal of the second amplifier is transmitted from the second antenna at the first polarization with the first carrier, and the amplified signal of the fourth amplifier is transmitted with the second carrier on the second carrier. Transmit from the second antenna in polarization,
Amplifying the first polarization signal and the second polarization signal received by the first antenna with a first low-noise amplifier;
Amplifying the first polarization signal and the second polarization signal received by the second antenna with a second low-noise amplifier;
The first polarization signal and the second polarization signal are demodulated using at least one of the amplified signal of the first low noise amplifier and the amplified signal of the second low noise amplifier. A wireless communication method.