This application is a National Stage of International Application No. PCT/JP2013/051724 filed Jan. 28, 2013, claiming priority based on Japanese Patent Application No. 2012-054398, filed Mar. 12, 2012, the contents of all of which are incorporated herein by reference in their entirety.
The present invention relates to a transmission apparatus and a transmission method, and more particularly to a transmission apparatus and a transmission method that are used for wireless communication and transmit RF (Radio Frequency) signals of a plurality of carrier frequency bands.
In the transmission apparatus used for wireless communication, a power amplifier (PA) that amplifies a RF signal to be transmitted consumes power most among the components of the transmission apparatus. Thus, in the development of the transmission apparatus, improving the power efficiency of the power amplifier (PA) is an important challenge. In recent communication standard, linear modulation is mainstream for spectral efficiency improvement. In the linear modulation, requirements concerning signal distortion are strict.
Thus, in the power amplifier (PA), to maintain linearity, average output power is set so that instantaneous maximum output (peak) power can be equal to or less than saturated output power. In other words, in the power amplifier (PA), as the ratio of the peak power of the signal to be amplified to average power (Peak-to-Average Ratio, hereinafter abbreviated to PAR) takes a larger value, to maintain the linearity, the average output power must be set lower than the saturated output power.
Generally, however, the power amplifier (PA) is characterized in that as the ratio of the average output power to the saturated output power is lower, the ratio (power efficiency) of supply power supplied to the power amplifier (PA) to output power extracted from the power amplifier (PA) is lower. The reduction of the power efficiency runs counter to energy saving.
The PAR of the RF signal has a unique value for each communication standard. In recently used high-speed wireless communication such as CDMA (Code Division Multiple Access), WLAN (Wireless Local Area Network), terrestrial digital broadcasting, or LTE (Long Term Evolution), the PAR takes a large value of several dB to tens of dB. Such a size of the PAR is a cause of great reduction of the power efficiency of the power amplifier (PA).
In the power amplifier (PA), to solve the problem of the reduction of the power efficiency caused by the low average output power, a polar modulation technology has been actively studied in recent years.
According to the ET method, transmission signal data is input to input terminal 401 of polar modulator 411, amplitude component signal 403 of the transmission signal data is output to output terminal 402 of polar modulator 411, and RF modulation signal 408 including the amplitude component and the phase component of the transmission signal data in the carrier wave is output to output terminal 407 of polar modulator 411. Polar modulator 411 has a function of individually setting the output timings of amplitude component signal 403 and RF modulation signal 408 to desired values.
Power supply modulator 404 outputs amplitude component signal 405 obtained by amplifying amplitude component signal 403, and modulates power supply terminal 409 of RF-PA (Radio Frequency Power Amplifier) 406 based on amplitude component signal 405. RF modulation signal 408 output to output terminal 407 of polar modulator 411 is input to RF-PA 406. RF modulation signal 410 that includes the amplitude component and the phase component of the transmission signal data in the carrier wave and that is amplified is output to output terminal 412 of RF-PA 406.
According to the ET method, the voltage of power supply terminal 409 of RF-PA 406 is controlled according to the amplitude of RF modulation signal 410. Particularly, when RF modulation signal 410 is low output power, the voltage of power supply terminal 409 of RF-PA 406 is accordingly reduced. Thus, wasteful power consumption can be suppressed by limiting the amount of supply power from power supply modulator 404 to RF-PA 406 to a necessary minimum during the low output power.
In recent communication standards, to achieve higher-speed wireless communication, as described in Non-patent Literature 1, a Carrier Aggregation (CA) technology collecting a plurality of fragmented bands to utilize has been used. In this CA technology, by bundling the plurality of bands to secure a broadband, a high transmission speed can be achieved.
In an inter-band Non-contiguous CA mode in which carrier frequencies are greatly different from each other (difference Δf between carrier frequencies is sufficiently larger than modulation bandwidth fBB of RF signal of each carrier), communication stability can be improved by simultaneously performing communication at a plurality of carrier frequencies whose propagation characteristics are different. By applying the CA technology, when a plurality of business operators intermittently allocates bands or when the plurality of business operators shares a band, corresponding communication can be performed.
In the wireless communication system using the CA technology, a transmission apparatus and a transmission method that transmit the RF signals of a plurality of bands are necessary. In such a transmission apparatus, similarly, improving of power efficiency is required.
Specifically, in the transmission apparatus illustrated in
The transmission apparatus illustrated in
The transmission apparatus illustrated in
As in the case of the transmission apparatus illustrated in
Non-patent Literature 1: Nobuhiko Mild, et. al., “Carrier Aggregation for achieving Broadband in LTE-Advanced-Advanced”, NTT DoCoMo Technical Journal, Vol. 18, No. 2
Non-patent Literature 2: P. Conlantonio, et. al., “A Design technique for Concurrent Dual-Band Harmonic Tuned Power Amplifier, “IEEE Transactions on Microwave Theory and Techniques, Vol. 56, No. 11, pp. 2545 to 2555, 2008
Non-patent Literature 3: S. Kousai, et. al., “An Octave-Range, Watt-Level, Fully-Integrated CMOSS Switching Power Mixer Array for Linearization and Back-Off-Efficiency Improvement, “IEEE Journal of Solid-State Circuits, Vol. 44, No. 12, pp. 3376 to 3392, 2009
Non-patent Literature 4: P. Saad, et. al., “Design of a Highly Efficient 2-4 GHz Octave Bandwidth GaN-HEMT Power Amplifier, “IEEE Transactions on Microwave Theory and Techniques, Vo. 58, No. 7, pp. 1677 to 1685, 2010
Non-patent Literature 5: E Wang, et. al., “An improved Power-Added Efficiency 19-dBm Hybrid Envelope Elimination and Restoration Power Amplifier for 802.11g WLAN Applications, “IEEE Transactions on Microwave Theory and Techniques, Vol. 54, No. 12, pp. 4086 to 4099, 2006
Non-patent Literature 6: Shigeru Ando, “Electronic Circuit, from basics to system”, Baifukan
However, in the case of technologies described in Patent Literatures 1˜5, the number of power amplifiers equal to that of used bands must be installed. This necessity causes, particularly in a wireless communication system using many bands, the increase of the circuit size and the costs of the transmission apparatus.
It is therefore an object of the present invention to provide a transmission apparatus and a transmission method capable of solving the aforementioned problems.
A transmission apparatus according to the present invention includes:
a polar modulator that generates a power supply modulation signal and RF (Radio Frequency) signals of a plurality of carrier frequency bands to be transmitted;
a power amplifier that amplifies the RF signals from the polar modulator; and
a power supply modulator that modulates the power supply terminal of the power amplifier by a signal obtained by amplifying the power supply modulation signal from the polar modulator,
wherein the power supply modulation signal is set based on a function using, as an argument, the power of the RF signal of each carrier frequency band output from the power amplifier.
A transmission method according to the present invention is a transmission method implemented in a transmission apparatus that generates RF signals of a plurality of carrier frequency bands to transmit the RF signals via a power amplifier,
the transmission method comprising:
the step of detecting the power of the RF signal of each carrier frequency band output from the power amplifier;
the step of setting a power supply modulation signal based on a function using, as an argument, the detected power of the RF signal of each carrier frequency band; and
the step of modulating the power supply terminal of the power amplifier by the power supply modulation signal output from a power supply modulator.
According to the transmission apparatus and the transmission method of the present invention, the RF signals of the plurality of carrier frequency bands are simultaneously amplified by the single power amplifier, and the power supply terminal of the power amplifier is modulated by the single power supply modulator. As a result, the circuit size and the costs of the transmission apparatus can be reduced.
Hereinafter, the preferred exemplary embodiments of a transmission apparatus and a transmission method according to the present invention will be described with reference to the accompanying drawings. In the respective drawings referred to below, similar or equivalent portions will be denoted by similar reference numerals, and description thereof will not be repeated.
(Overview of Invention)
The overview of the present invention will be first given before description of the exemplary embodiments of the invention.
The present invention is mainly characterized by achieving a transmission apparatus that includes a power amplifier compatible with a CA (Carrier Aggregation) technology capable of simultaneously amplifying the signals of a plurality of frequencies generated by a signal generator.
Specifically, the transmission apparatus according to the present invention is mainly characterized by including a polar modulator that generates a power supply modulation signal and RF (Radio Frequency) signals of a plurality of carrier frequency bands to be transmitted, a power amplifier that amplifies the RF signals from the polar modulator, and a power supply modulator that modulates the power supply terminal of the power amplifier by a signal obtained by amplifying the power supply modulation signal from the polar modulator, and in that the power supply modulation signal is set based on a function using, as an argument, the power of the RF signal of each carrier frequency band output from the power amplifier.
Thus, in the transmission apparatus according to the present invention, since the RF signals of the plurality of carrier frequency bands are simultaneously amplified by one power amplifier, the number of power amplifiers can be one, irrespective of the number of RF signals of carrier frequencies to be amplified. In the transmission apparatus according to the present invention, since only one power amplifier is used, only one power supply modulator is necessary. In the transmission apparatus according to the present invention, compared with the transmission apparatuses described in Patent Literatures 1˜5, the transmission apparatus of high power efficiency can be configured by the smaller numbers of power amplifiers and power supply modulators. As a result, a circuit size and costs can be reduced.
In the transmission apparatus according to the present invention, since the RF signals of the plurality of carrier frequency bands are simultaneously amplified by one power amplifier, there is no need to install a switch for switching a used frequency band at the input and the output of the power amplifier. As a result, in the transmission apparatus according to the present invention, the increase of the circuit size and the costs caused by the installation of such a switch and the reduction of the power efficiency of the entire transmission apparatus caused by the insertion loss of a switch can be prevented.
In the transmission apparatus according to the present invention, the RF signals of the plurality of carrier frequency bands can be simultaneously amplified to be output. Thus, the transmission apparatus according to the present invention is compatible with the CA technology.
Polar modulator 601 simultaneously generates RF signals 6211, 6212, . . . , 621n having different carrier frequencies fc1, fc2, . . . , fcn to output them to terminal 605. RF signals 6211, 6212, . . . , 621n are input to power amplifier 603 via terminal 605. Power amplifier 605 amplifies input RF signals 6211, 6212, . . . , 621n to output them as RF signals 6221, 6222, . . . , 622n of carrier frequencies fc1, fc2, . . . , fcn to terminal 606 via coupler 604.
In the exemplary embodiment, as power amplifier 603, a multiband power amplifier designed corresponding to the plurality of carrier frequencies fc1, fc2, . . . , fcn is preferably used. For example, for power amplifier 603, a power amplifier designed for alignment between an input and an output by two or more frequencies, which is similar to that disclosed in Non-patent Literature 2 described in the aforementioned Non-patent Literature Section, can be used.
Alternatively, for power amplifier 603, a broadband power amplifier covering the frequency range of carrier frequencies fc1 to fcn can be used. For the configuration of the broadband power amplifier, for example, a configuration disclosed in Non-patent Literature 3 or 4 described in the aforementioned Non-patent Literature Section can be employed.
Coupler 604 branches RF signals 6221, 6222, . . . , 622n output from power amplifier 603 to output them as RF signals 6251, 6252, . . . , 625n of carrier frequencies fc1, fc2, . . . , fcn to terminal 609. To suppress the losses of RF signals 6221, 6222, . . . , 622n, the powers of RF signals 6251, 6252, . . . , 625n branched by coupler 604 are preferably low. RF signals 6251, 6252, . . . , 625n are input to polar modulator 601 via terminal 609. Polar modulator 601 detects the instantaneous powers POUT1(t), POUT2(t), . . . , POUTn(t) of RF signals 6221, 6222, . . . , 622n based on input RF signals 6251, 6252, . . . , 625n.
Polar modulator 601 outputs power supply modulation signal 623 to terminal 607. Voltage waveform VAM_IN(t) of power supply modulation signal 623 is set based on a function using instantaneous powers POUT1(t), POUT2(t), . . . , POUTn(t) of RF signals 6221, 6222, . . . , 622n detected by polar modulator 601 as arguments.
Power supply modulation signal 623 output to terminal 607 is amplified by power supply modulator 602 to be output as power supply modulation signal 624 to terminal 608. The power supply voltage of power amplifier 603 is modulated by voltage waveform VAM_OUT(t) of power supply modulation signal 624. Voltage waveform VAM_OUT(t) of power supply modulation signal 624 is similarly set based on the function using instantaneous powers POUT1(t), POUT2(t), . . . , POUTn(t) of RF signals 6221, 6222, . . . , 622n detected as the arguments.
Thus, according to the exemplary embodiment, when instantaneous powers POUT1(t), POUT2(t), . . . , POUTn(t) of RF signals 6221, 6222, . . . , 622n output from power amplifier 603 are reduced, voltage waveform VAM_OUT(t) of power supply modulation signal 624 is lowered to suppress a power supply from power supply modulator 602 to power amplifier 603. As a result, the power consumption of power amplifier 603 and the entire transmission apparatus are suppressed, and power efficiency can be improved.
As disclosed in Non-patent Literature 5 described in the aforementioned Non-patent Literature Section, generally, the broader band of the output voltage waveform of the power supply modulator creates problems such as the efficiency reduction of the power supply modulator and the increase of output signal errors. Thus, the operating band of the power supply modulator achievable by a current technology represented by that described in Non-patent Literature 5 is limited to several tens of MHz or lower.
In a current wireless communication system including the LTE-Advanced, the modulation bandwidth fBB of the RF signal of one carrier frequency is 20 MHz at the maximum. On the other hand, for example, in the Inter-band Non-contiguous CA mode used in the LTE-Advanced, a carrier frequency may be set to a band of 800 MHz and 2 GHz. Thus, a difference Δf between carrier frequencies may be 1 GHz or higher.
In the exemplary embodiment, as described above, the output voltage waveform VAM_OUT(t) of power supply modulation signal 624 is set based on the function using instantaneous powers POUT1(t), POUT2(t), . . . , POUTn(t) of RF signals 6221, 6222, . . . , 622n as the arguments. The band of instantaneous powers POUT1(t), POUT2(t), . . . , POUT is approximately equal to the modulation bandwidth fBB of each of RF signals 6221, 6222, . . . , 622n, and set independently of the difference Δf between the carrier frequencies. Accordingly, in the exemplary embodiment, an operating band necessary for power supply modulator 602 is approximately equal to the modulation bandwidth fBB of each of RF signals 6221, 6222, . . . , 622n without any dependence on the difference Δf between the carrier frequencies. By the current technology represented by that described in Non-patent Literature 5, an operating band (several tens of MHz) higher than that (20 MHz at the maximum) necessary for power supply modulator 602 can be achieved. The power supply modulator based on the current technology represented by that described in Non-patent Literature 5 is a desirable form for power supply modulator 602.
In the polar modulation technology, when there is synchronous deviation between the transmission timing of RF signals 6211, 6212, . . . , 621n at input terminal 605 of power amplifier 603 and the transmission timing of power supply modulation signal 624 at power supply terminal 608 of power supply amplifier 603, signal distortion is generated in RF signals 6221, 6222, . . . , 622n at output terminal 606 of power amplifier 603. Thus, the transmission timings of RF signals 6211, 6212, . . . , 621n output from polar modulator 601 and the transmission timings of power supply modulation signal 624 are preferably set so to minimize the signal distortion of RF signals 6221, 6222, . . . , 622n.
Next, a preferable method for setting the output voltage waveform VAM_OUT(t) of power supply modulation signal 624 according to the exemplary embodiment will be described. For simpler description, a case where the number of carrier frequencies is two, namely, fc1 and fc2, will first be described.
The setting method will be described by taking an example where a dual-band power amplifier (PA) corresponding to both carrier frequencies of 800 MHz and 2 GHz is used as power amplifier 603.
The characteristic diagram of
When the ratio of the input power is changed between RF signal 6211 of the carrier frequency fc1 and RF signal 6212 of the carrier frequency fc2 by changing the power difference ΔPin between the input powers, the output powers of RF signal 6221 of the carrier frequency fc1 and RF signal 6222 of the carrier frequency fc2 at the time of saturation also change according to the change of the ratio. Power amplifier 603 in the exemplary embodiment is designed so that the output voltages at the time of saturation of power amplifier 603 can take saturation output powers Psat of approximately equal values both when only RF signal 6211 of the carrier frequency fc1 is used and when only RF signal 6212 of the carrier frequency fc2 is used.
Thus, in the case of the power amplifier configured such that the saturation output powers at the time of the input of a single RF signal take equal values Psat, as illustrated in
This result shows that when the RF signals of a plurality of greatly different carrier frequencies are simultaneously input to the power amplifier (Inter-band Noncontiguous CA mode), the total value of the output powers of the RF signals defines the saturation condition of the power amplifier (PA), irrespective of the input power difference ΔPin between the RF signals of the carrier frequencies. In other words, the result shows that the power amplifier is saturated when the output power total value (Pout1+Pout2) of the RF signals reaches the saturation output power Psat.
According to the characteristic diagrams of
Psat∝(VAM_OUT)2 [Formula 1]
The characteristic diagram of
According to the polar modulation technology, by controlling the power supply voltage so that desired output power can always match the saturation power, the saturated state of high power efficiency is always achieved, irrespective of fluctuation in output power. Thus, in the exemplary embodiment, the output voltage VAM_OUT(t) of power supply modulator 602 is preferably set so that power amplifier 603 can be always set in a saturated state. According to the result in which the saturation output power Psat is determined by the output power total value (Pout1+Pout2) of the RF signals and the result of Formula (1) thus obtained, desirable setting for the output voltage VAM_OUT(t) of power supply modulator 602 is given by following Formula (2) using the instantaneous powers POUT1(t) and POUT2(t) of RF signals 6221 and 6222.
VAM_OUT(t)=C√{square root over (Psat)}=C√{square root over (Pout1(t)+Pout2(t))} [Formula 2]
In Formula 2, C is a proportional constant. When a low proportional constant C is taken to set the power supply voltage VAM_OUT of power amplifier 603 low, power efficiency tends to be improved while a gain is lowered. Conversely, when a large proportional constant C is taken to set the power supply voltage VAM_OUT of power amplifier 603 high, a gain tends to be increased while power efficiency is lowered. The proportional constant C is preferably set according to desired characteristics.
Hereinafter, the effects of the exemplary embodiment will be described based on, as an example, the characteristics of power amplifier 603 when the RF signal of the carrier frequency fc1=800 HMz and the RF signal of the carrier frequency fc2=2 GHz are simultaneously input to power amplifier 603, and the output voltage VAM_OUT(t) of power supply modulator 602 is set by Formula (2).
As a condition for obtaining the characteristics of power amplifier 603, a power difference ΔPin=Pin1−Pin2 (dB) between the input power Pin1 of RF signal 6211 of the carrier frequency fc1=800 MHz and the input power Pin2 of RF signal 6212 of the carrier frequency fc2=2 GHz is set to −6 dB. According to Formula 2, the output voltage VAM_OUT(t) of power supply modulator 602 is set as illustrated in
η=(Pout1+Pout2)/PAM [Formula 3]
As illustrated in
As comparison targets,
The output voltage VAM_OUT(t) of power supply modulator 602 in Formula (2) is desirable setting when two RF signals 6211 and 6212 of carrier frequencies are input to power amplifier 603. Desirable setting of the output voltage VAM_OUT(t) of power supply modulator 602 when two or more RF signals 6211, 6212, . . . , 621n of carrier frequencies are input to power amplifier 603 is expanded by Formula (4) below using the powers Pout1(t), Pout2(t), . . . , Poutn(t) of RF output signals 6221, 6222, . . . , 622n.
VAM_OUT(t)∝√{square root over (Psat)}=√{square root over (Pout1(t)+Pout2(t)+ . . . +Poutn(t))} [Formula 4]
Specifically, the power supply voltage VAM_OUT is set to C √Pout1(t)+Pout2(t) during a period where Pout1(t)+Pout2(t)>(Vth/C)2 is satisfied. The power supply voltage VAM_OUT is set to Vth during a period where Pout1(t)+Pout2(t)<(Vth/C)2 is satisfied.
In the case of C √Pout1(t)+Pout2(t)=Vth, an upper formula and a lower formula take equal values, and thus any of the two can be used.
In the setting of the power supply voltage VAM_OUT illustrated in
A middle formula indicates that C2√Pth2 and C1√Pth2 take equal values.
In the case of Pout1(t)+Pout2(t)=Pth2, an upper formula and the middle formula take equal values, and thus any of the two can be used. In the case of Pout1(t)+Pout2(t)=Pth1, the middle formula and a lower formula take equal values, and thus any of the two can be used.
In the setting of the power supply voltage VAM_OUT illustrated in
In the setting of the power supply voltage VAM_OUT illustrated in
When a relationship between the saturation output power Psat of power amplifier 603 and the power supply voltage VAM_OUT of power supply modulator 602 is given by Formula (1), desirable setting for the power supply voltage VAM_OUT(t) of power supply modulator 602 is given by Formula (4). More generally, when the relationship between the saturation output power Psat of power amplifier 603 and the power supply voltage VAM_OUT of power supply modulator 602 is given by a function f of Formula (7), desirable setting for the power supply voltage VAM_OUT(t) of power supply modulator 602 is given by Formula (8) using the inverse function h(=f−1) of the function f.
Psat∝f(VAM) [Formula 7]
VAM_OUT(t)∝h(Psat)=h[Pout1(t)+Pout2(t)+ . . . +Poutn(t)] [Formula 8]
The function h is defined by measuring the relationship between the saturation output power Psat of power amplifier 603 and the power supply voltage VAM_OUT of power supply modulator 602. Alternatively, as the function h, the function illustrated in
As illustrated in the graph of
Pout1+Pout2=Psat(=const.) [Formula 9]
However, Formula (9) defines only the approximate relationship. The relationship between the output power Pout1 of RF signal 6221 of the carrier frequency fc1 at the time of saturation and the output power Pout2 of RF signal 6222 of the carrier frequency fc2 at the time of saturation based on real characteristics is represented by Formula (10) using an implicit function u as illustrated in the graph of
u(Pout1,Pout2)=Psat(=const.) [Formula 10]
The implicit function u is defined based on the measured data of the output power Pout1 of RF signal 6221 of the carrier frequency fc1 at the time of saturation and the measured data of the output power Pout2 of RF signal 6222 of the carrier frequency fc2 at the time of saturation.
More generally, when two or more RF signals 6211, 6212, . . . , 621n of carrier frequencies are input to power amplifier 603, a relationship among the powers POUT1(t), POUT2(t), . . . , POUTn(t) of RF output signals 6221, 6222, . . . , 622n at the time of saturation is expanded as defined in Formula (11).
u(Pout1,Pout2, . . . , Poutn)=Psat(=const.) [Formula 11]
By combining relational Formula (11) among the powers POUT1(t), POUT2(t), . . . , POUTn(t) of RF output signals 6221, 6222, . . . , 622n at the time of saturation with relational Formula (7) between the saturation output power Psat of power amplifier 603 and the output voltage VAM_OUT of power supply modulator 602, the output voltage VAM_OUT of power supply modulator 602 is set by Formula (12) as shown below.
VAM_OUT(t)∝f−1(Psat)=f−1[u(Pout1(t),Pout2(t), . . . , Poutn(t))]=w[Pout1(t),Pout2(t), . . . , Poutn(t)] [Formula 12]
A function w is a composite function of the function f−1 and the function u. As discussed above, by setting the output voltage VAM_OUT of power supply modulator 602 based on the general function w of the powers POUT1(t), POUT2(t), . . . , POUTn(t) according to Formula (12), power amplifier 603 always operates in a saturated state, and high power efficiency can be obtained as a result.
Next, a transmission apparatus according to the second exemplary embodiment of the present invention will be described with particular attention paid to a polar modulator in the transmission apparatus.
In the transmission apparatus according to the second exemplary embodiment illustrated in
In polar modulator 601, baseband signal generators 8011 8012, . . . , 801n output baseband signals bin1(t), bin2(t), . . . , binn(t) to mixers 8031, 8032, . . . , 803n. Local oscillation (LO) signal generators 8021, 8022, . . . , 802n output the LO signals of carrier frequencies fc1, fc2, . . . , fcn, to mixers 8031, 8032, . . . , 803n. Mixers 8031, 8032, . . . , 803n carries out frequency conversion (up conversion) of baseband signals bin1(t), bin2(t), . . . , binn(t) into carrier frequencies fc1, fc2, . . . , fcn to generate RF signals 6211, 6212, . . . , 621n of carrier frequencies fc1, fc2, . . . , fcn. RF signals 6211, 6212, . . . , 621n are input to RF signal synthesizer 805 via RF signal delay adjusters 8041, 8042, . . . , 804n, and RF signal synthesizer 805 outputs synthesized RF signals 6211, 6212, . . . , 621n to terminal 605. RF signal synthesizer 805 can include, for example, a broadband hybrid coupler usable within the range of carrier frequencies fc1, fc2, . . . , fcn.
RF signal delay adjusters 8041, 8042, . . . , 804n, which are respectively arranged on the output sides of mixers 8031, 8032, . . . , 803n, can be installed on the input sides of mixers 8031, 8032, . . . , 803n instead.
Baseband signal generators 8011 8012, . . . , 801n input the powers Pin1(t), Pin2(t), . . . , Pinn(t) of baseband signals bin1(t), bin2(t), . . . , binn(t) to variable gain amplifiers (VGA) 8061, 8062, . . . , 806n. Variable gain amplifiers (VGA) 8061, 8062, . . . , 806n, which respectively have gains GAM1, GAM2, . . . , GAMn, amplify the input powers Pin1(t), Pin2(t), . . . , Pinn(t) to GAM1Pin1(t), GAM2Pin2(t), . . . , GAMnPinn(t) to output the results to adder 811. Variable gain amplifiers (VGA) 8061, 8062, . . . , 806n, which are not always required to have gains of 0 dB or higher, can be replaced with variable attenuators.
Variable gain amplifiers (VGA) 8061, 8062, . . . , 806n respectively include gain control terminals 8141, 8142, . . . , 814n. The gains GAM1, GAM2, . . . , GAMn of variable gain amplifiers (VGA) 8061, 8062, . . . , 806n are set based on control signals output from controller 807 to gain control terminals 8141, 8142, . . . , 814n.
Adder 811 outputs GAM1Pin1(t)+GAM2Pin2(t)+ . . . +GAMnPinn(t) that are additional values of the input signals to square root extractor 809. Adder 811 can include, for example, an operation amplifier according to a method disclosed in Chapter 5 of Non-patent Literature 6 described in the section of Non-patent Literature.
The power gains of the transmission apparatus in paths from baseband signal generators 8011 8012, . . . , 801n to output terminal 606 of power amplifier 603 via input terminal 605 of power amplifier 603 are defined as GRF1=Pout1/Pin1, GRF2=Pout2/Pin2, . . . , GRFn=Poutn/Pinn. Particularly, in an Inter-band Non-contiguous CA mode in which carrier frequencies are greatly different from each other (difference Δf between carrier frequencies is sufficiently larger than modulation bandwidth fBB of RF signal of each carrier), the influence of the frequency dependency of the power gains is large, and a large difference is generated in value among the power gains GRF1, GRF2, . . . , GRFn.
At this time, the power gains GRF1, GRF2, . . . , GRFn of the transmission apparatus preferably have a relationship defined by Formula (13) below with the gains GAM1, GAM2, . . . , GAMn of variable gain amplifiers (VGA) 8061, 8062, . . . , 806n.
GRF1:GRF2: . . . :GRFn=GAM1:GAM2: . . . :GAMn [Formula 13]
Formula (13) is equivalent to following Formula (14).
Pout1:Pout2: . . . :Poutn=GAM1Pin1:GAM2Pin2: . . . :GAMnPinn [Formula 14]
According to the second exemplary embodiment of the present invention, by controlling the gains of variable gain amplifiers (VGA) 8061, 8062, . . . , 806n via controller 807, the gains GAM1, GAM2, . . . , GAMn are set to satisfy the relationship of Formula 13 or 14. At this time, the signal GAM1Pin1(t)+GAM2Pin2(t)+ . . . +GAMnPinn(t) output from adder 811 to square root extractor 809 is proportional to Pout1(t)+Pout2(t)+ . . . +Poutn(t).
By the aforementioned setting of the gains GAM1, GAM2, . . . , GAMn, even when the power gains GRF1, GRF2, . . . , GRFn of the transmission apparatus are frequency-dependent, the sum total Pout1(t)+Pout2(t)+ . . . +Poutn(t) of the output powers is correctly calculated from input powers Pin1+Pin2(t)+ . . . +Pinn(t). This is particularly effective in the Inter-band Non-contiguous CA mode in which the influence of the frequency dependency of the power gains of the transmission apparatus is large.
Square root extractor 809 outputs sqrt[GAM1Pin1(t)+GAM2Pin2(t)+ . . . +GAMnPinn(t)] that is a square root of the input signal GAM1Pin1(t)+GAM2Pin2(t)+ . . . +GAMnPinn(t) as power supply modulation signal 623 to terminal 607 via power supply modulation signal delay adjuster 810. Square root extractor 809 can include, for example, an IC multiplier according to a method disclosed in Chapter 7 of Non-patent Literature 6 described in the section of Non-patent Literature.
As described above, when the gains GAM1, GAM2, . . . , GAMn are set to satisfy the relationship of Formula 13 or 14, power supply modulation signal 623 output to terminal 607 is a signal proportional to sqrt[Pout(t)+Pout2(t)+ . . . +Poutn(t)]. Power supply modulation signal 623 is amplified by power supply modulator 602 to be output as the output voltage VAM_OUT(t) of power supply modulator 602 to terminal 608. By this operation, in the second exemplary embodiment of the present invention, as in the case of the first exemplary embodiment, the output voltage VAM_OUT(t) of power supply modulator 602 is set as defined in Formula (4).
Hereinafter, the function of controller 807 will be described in detail. The powers Pin1(t), Pin2(t), . . . , Pinn(t) of baseband signals bin1(t), bin2(t), . . . , binn(t) are input to input terminals 8121, 8122, . . . , 812n of controller 807.
RF signals 6251, 6252, . . . , 625n of carrier frequencies fc1, fc2, . . . , fcn, output to terminal 609 via coupler 604 installed on the output side of power amplifier 603, are input to branching filter 808. Branching filter 808 has a function of separately outputting the RF signals of different carrier frequencies to different output terminals. In other words, branching filter 808 separately outputs RF signals 6251, 6252, . . . , 625n to different input terminals 8131, 8132, . . . , 813n. Controller 807 calculates, based on RF signals 6251, 6252, . . . , 625n input to different input terminals 8131, 8132, . . . , 813n, the powers POUT1(t), POUT2(t), . . . , POUTn(t) of RF signals 6221, 6222, . . . , 622n output from power amplifier 603.
By the aforementioned operation, controller 807 detects the input powers Pin1(t), Pin2(t), . . . , Pinn(t) and the output powers POUT1(t), POUT2(t), . . . , POUTn(t) of the transmission apparatus. Controller 807 detects the power gains GRF1=Pout1/Pin1, GRF2=Pout2/Pin2, . . . , GRFn=Poutn/Pinn of the transmission apparatus from the detected input and output powers. Controller 807 calculates desired values of the gains GAM1, GAM2, . . . , GAMn of variable gain amplifiers (VGA) 8061, 8062, . . . , 806n based on the power gains GRF1, GRF2, . . . , GRFn of the transmission apparatus detected in the aforementioned operation and Formula (13) or (14). Controller 807 outputs control signals to gain control terminals 8141, 8142, . . . , 814n so that the gains GAM1, GAM2, . . . , GAMn of variable gain amplifiers (VGA) 8061, 8062, . . . , 806n can be set to the desired values calculated in the aforementioned operation.
In the second exemplary embodiment of the present invention, as in the case of the first exemplary embodiment, the transmission timings of RF signals 6211, 6212, . . . , 621n output from polar modulator 601 and power supply modulation signal 624 are set so to minimize the signal distortion of RF signals 6221, 6222, . . . , 622n. In the second exemplary embodiment, the transmission timings of RF signals 6211, 6212, . . . , 621n and power supply modulation signal 624 are set based on signal delay time at RF signal delay adjusters 8041, 8042, . . . , 804n and power modulation signal delay adjuster 810. Controller 807 detects the signal distortion of RF signals 6221, 6222, . . . , 622n based on RF signals 6251, 6252, . . . , 625n input to terminals 8131, 8132, . . . , 813n. Controller 807 has a function of setting the signal delay time at RF signal delay adjusters 8041, 8042, . . . , 804n and power modulation signal delay adjuster 810 so to minimize the detected signal distortion of RF signals 6221, 6222, . . . , 622n. The signal delay time at RF signal delay adjusters 8041, 8042, . . . , 804n is set based on a control signal output from controller 807 to control terminal 815. The signal delay time at power modulation signal delay adjuster 810 is set based on a control signal output from controller 807 to control terminal 816.
Through the measurement of a given period based on the aforementioned operation, the optimal values of the gains GAM1, GAM2, . . . , GAMn of variable gain amplifiers (VGA) 8061, 8062, . . . , 806n, and the signal delay time at RF signal delay adjusters 8041, 8042, . . . , 804n and power modulation signal delay adjuster 810 are calculated. The gains and the signal delay time can be fixed at the calculated optimal values, or updated again after appropriate time.
In controller 807 illustrated in
In controller 807 illustrated in
MPU 1009 calculates power gains GRF1=Pout1/Pin1, GRF2=Pout2/Pin2, . . . , GRFn=Poutn/Pinn of the transmission apparatus at carrier frequencies fc1, fc2, . . . , fcn from the aforementioned input power data, in other words, the powers Pin1(t), Pin2(t), . . . , Pinn(t) of the baseband signals bin1(t), bin2(t), . . . , binn(t) and the powers POUT1(t), POUT2(t), . . . , POUTn(t) of RF signals 6221, 6222, . . . , 622n. MPU 1009 calculates desired values of the gains GAM1, GAM2, . . . , GAMn of variable gain amplifiers (VGA) 8061, 8062, . . . , 806n based on the calculated power gains GRF1, GRF2, . . . , GRFn and Formula (13).
MPU 1009 outputs control signals to gain control terminals 8141, 8142, . . . , 814n of variable gain amplifiers (VGA) 8061, 8062, . . . , 806n via DACs 10041, 10042, . . . , 1004n so that the gains GAM1, GAM2, . . . , GAMn of variable gain amplifiers (VGA) 8061, 8062, . . . , 806n can be set to the desired values calculated in the aforementioned operation.
In controller 807 illustrated in
In controller 807 illustrated in
In controller 807, MPU 1009 changes the signal delay time at RF signal delay adjusters 8041, 8042, . . . , 804n and power supply modulation signal delay adjuster 810 via control terminals 815 and 816, and simultaneously detects the signal distortion amounts ACPR1, ACPR2, . . . , ACPRn of RF signals 6251, 6252, . . . , 625n. Based on the signal distortion amounts ACPR1, ACPR2, . . . , ACPRn of RF signals 6251, 6252, . . . , 625n, the signal distortion amounts of RF signals 6221, 6222, . . . , 622n output from power amplifier 603 are detected. By this operation, MPU 1009 detects the dependency of the signal distortion amounts ACPR1, ACPR2, . . . , ACPRn of RF signals 6251, 6252, . . . , 625n on the signal delay time at RF signal delay adjusters 8041, 8042, . . . , 804n and power supply modulation signal delay adjuster 810. Then, based on the data of the dependency, MPU 1009 sets the signal delay time at RF signal delay adjusters 8041, 8042, . . . , 804n and power supply modulation signal delay adjuster 810 so as to minimize the signal distortion amounts ACPR1, ACPR2, . . . , ACPRn of RF signals 6251, 6252, . . . , 625n.
In ACPR detector 10061 illustrated in
ACPR detectors 10062, . . . , 1006n are similar in internal configuration and function to ACPR detector 10061.
Based on the circuit configuration and the operation described above, in the second exemplary embodiment of the present invention, as in the case of the first exemplary embodiment, in the transmission apparatus that simultaneously transmits the plurality of RF signals having different carrier frequencies, even when the output power of the RF signal is reduced, power efficiency can be maintained high.
Components other than DC power source 901, switch 902, and control terminal 903 are similar between the second exemplary embodiment of the present invention illustrated in
In the first modified example of the second exemplary embodiment, MPU 1009 in controller 807 calculates the sum total POUT1(t)+POUT2(t)+ . . . +POUTn(t) of the powers based on the detected powers POUT1(t), POUT2(t), . . . , POUTn(t) of RF signals 6221, 6222, . . . , 622n. MPU 1009 outputs a control signal to control terminal 903 so that switch 902 can connect the output of square root extractor 809 to the input of power modulation signal delay adjuster 810 during a period where the power sum total is equal to or higher than a set threshold value. MPU 1009 outputs a control signal to control terminal 903 so that switch 902 can connect the output of DC power source 901 to the input of power modulation signal delay adjuster 810 during a period where the power sum total is equal to or higher than the set threshold value.
By the aforementioned operation, in the first modified example of the second exemplary embodiment of the present invention, the output voltage VAM_OUT(t) of power supply modulator 602 is set to that defined by Formula (15) as shown below.
Specifically, the power supply voltage VAM_OUT is set to C √Pout1(t)+Pout2(t)+ . . . +Poutn(t) during a period where Pout1(t)+Pout2(t)+ . . . +Poutn(t)>(Vth/C)2 is satisfied. The power supply voltage VAM_OUT is set to Vth during a period where Pout1(t)+Pout2(t)+ . . . +Poutn(t)<(Vth/C)2 is satisfied.
In the case of C √Pout1(t)+Pout2(t)+ . . . +Poutn(t)=Vth, an upper formula and a lower formula take equal values, and thus any of the two can be used.
The output voltage VAM_OUT (t) of power supply modulator 602 given by Formula (15) corresponds to that obtained by expanding Formula (5) to a plurality of bands in the first modified example of the first exemplary embodiment.
Thus, in the first modified example of the second exemplary embodiment of the present invention, as in the case of the first modified example of the first exemplary embodiment, in the transmission apparatus that simultaneously transmits the plurality of RF signals having different carrier frequencies, even when the output power of the RF signal is reduced, power efficiency and power gains can be maintained high.
A transmission apparatus according to the second modified example of the second exemplary embodiment of the present invention has, as in the case of the first modified example of the second exemplary embodiment, the block configuration illustrated in
In the second modified example of the second exemplary embodiment of the present invention, the output voltage VAM_OUT(t) of power supply modulator 602 is set to that defined by Formula (16) as shown below.
A middle formula indicates that C2√Pth2 and C1√Pth2 take equal values.
In the case of Pout1(t)+Pout2(t)+ . . . +Poutn(t)=Pth2, an upper formula and the middle formula take equal values, and thus any of the two can be used. In the case of Pout1(t)+Pout2(t)+ . . . +Poutn(t)=Pth1, the middle formula and a lower formula take equal values, and thus any of the two can be used.
The output voltage VAM_OUT(t) of power supply modulator 602 given by Formula (16) corresponds to that obtained by expanding Formula (6) to a plurality of bands in the second modified example of the first exemplary embodiment.
In the second modified example of the second exemplary embodiment, the output voltage VAM_OUT(t) of power supply modulator 602 is set to that defined by Formula (16). Accordingly, the transmission apparatus performs the following operation. During a period where the sum total POUT1(t)+POUT2(t)+ . . . +POUTn(t) of the powers of RF signals 6221, 6222, . . . , 622n is equal to or higher than a first threshold value Pth1, MPU 1009 outputs the control signal of switch 902 to control terminal 903 so that switch 902 can connect the output of square root extractor 809 to the input of power modulation signal delay adjuster 810. During a period where the power sum total is equal to or lower than the first threshold value Pth1 and equal to or higher than a second threshold value Pth2, MPU 1009 outputs the control signal of switch 902 to control terminal 903 so that switch 902 can connect the output of DC power source 910 to the input of power modulation signal delay adjuster 810. During a period where the power sum total is equal to or lower than the second threshold value Pth2, MPU 1009 outputs a control signal to control terminal 903 so that switch 902 can connect the output of square root extractor 809 to the input of power modulation signal delay adjuster 810. By changing the setting values of the gains GAM1, GAM2, . . . , GAMn of variable gain amplifiers (VGA) 8061, 8062, . . . , 806n between the period where the power sum total is equal to or higher than the first threshold value Pth1 and the period where the power sum total is equal to or lower than the second threshold value Pth2, the proportional coefficients C1 and C2 of the output voltage VAM_OUT (t) of power supply modulator 602 are switched.
By the aforementioned operation, in the second modified example of the second exemplary embodiment of the present invention, an operation similar to that in the second modified example of the first exemplary embodiment is achieved. Thus, in the second modified example of the second exemplary embodiment of the present invention, as in the case of the second modified example of the first exemplary embodiment, in the transmission apparatus that simultaneously transmits the plurality of RF signals having different carrier frequencies, even when the output power of the RF signal is reduced, power efficiency and power gains can be maintained high.
In the transmission apparatus according to the third modified example of the second exemplary embodiment illustrated in
In the transmission apparatus according to the third modified example of the second exemplary embodiment illustrated in
The transmission apparatus of the present invention has the following effects as compared with those disclosed in Patent Literatures 1 to 5.
In the case of the transmission apparatuses described in Patent Literatures 1 to 5, the RF signal of one carrier frequency is amplified by one power amplifier (PA). Thus, when the RF signals of n carrier frequencies are amplified, n power amplifiers (PA) are necessary. Since power supply modulation (polar modulation) is individually applied for each PA, n power supply modulators are necessary.
On the other hand, in the case of the transmission apparatuses according to the exemplary embodiments of the present invention, the RF signals of n carrier frequencies are simultaneously amplified by one power amplifier (PA). Thus, the number of PAs is one, irrespective of the number of RF signals of carrier frequencies to be amplified. In the present invention, only one PA is used, and accordingly only one power modulator is necessary. Thus, compared with those disclosed in Patent Literatures 1 to 5, in the transmission apparatuses of the exemplary embodiments, the transmission apparatus of higher power efficiency can be configured by smaller numbers of power amplifiers (PA) and power supply modulators. As a result, a circuit size and costs can be reduced.
In the case of the transmission apparatuses described in Patent Literatures 1 to 5, there is a need to install a switch for changing a used band between the input and the output of the power amplifier. The use of such a switch causes the problem of the reduction of the power efficiency of the entire transmission apparatus due to the insertion loss of the switch in addition to the problem of the increase of the circuit size and the costs caused by the increased number of components.
On the other hand, in the case of the transmission apparatuses according to the exemplary embodiments of the present invention, there is no need to install any switch for changing a used band between the input and the output of the power amplifier. Thus, the problems of the increase of the circuit size and the costs caused by a switch and the reduction of the power efficiency of the entire transmission apparatus due to the insertion loss of a switch can be solved.
In the case of the transmission apparatuses described in Patent Literatures 1 to 5, the method for switching the power amplifiers used in the band changing switch imposes restrictions, namely, inhibition of simultaneous outputting of the RF signals of all bands processable by the transmission apparatus. Because of the restrictions, the transmission apparatuses described in Patent Literatures 1 to 5 have a problem of unsuitability to the CA technology for performing communication by simultaneously using a plurality of bands.
On the other hand, in the case of the transmission apparatuses according to the exemplary embodiments of the present invention, the RF signals of an arbitrary number of bands can be simultaneously output, and the CA technology can be employed.
The configurations of the preferred exemplary embodiments of the present invention have been described. The contents disclosed in Patent Literatures can be incorporated by reference in the invention. Within the framework of the entire disclosure (including the scope of claims) of the present invention, based on the basic technical ideas, changes and adjustments can be made of the exemplary embodiments. Within the framework of the scope of claims of the present invention, a wide variety of combinations of various disclosed elements or selection can be made. In other words, needless to say, the present invention includes various changes and modifications obtainable by those skilled in the art according to the entire disclosure including the scope of claims and the technical ideas.
For example, in the second exemplary embodiment of the present invention, the adjacent channel leakage power (ACPR) is used as a signal distortion index, and the ACPR detector is installed as the signal distortion detector. However, the present invention is not limited to this. The signal distortion detector can use, as a signal distortion index, EVM (Error Vector Magnitude), IMD (Inter-modulation distortion), or MER (Modulation Error Ratio).
Number | Date | Country | Kind |
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2012-054398 | Mar 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/051724 | 1/28/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/136860 | 9/19/2013 | WO | A |
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20070184793 | Drogi et al. | Aug 2007 | A1 |
20090202006 | Ahmed | Aug 2009 | A1 |
20090233644 | McCune, Jr. | Sep 2009 | A1 |
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2004-527956 | Sep 2004 | JP |
2005-244826 | Aug 2005 | JP |
2006-270923 | Oct 2006 | JP |
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