DCDC converter unit, power amplifier, and base station using the same

A DCDC converter includes a signal splitting unit that splits an input signal into N signal components; N DCDC converter elements that process individually the N split signals; and an adder that adds outputs from the plural DCDC converter elements to generate output signals. Each of the DCDC converter elements has an operation band narrower than an applicable frequency band of the input signal, and selects a design parameter that allows a conversion efficiency of the DCDC converter elements to be optimized for any band of the applicable frequency bands. For example, the parameter of a PMOS transistor and a NMOS transistor, which configure an inverter is designed to optimize the efficiency at any of frequency bands. The frequency band of the input signal is split, and each of the split outputs is input to a DCDC converter element that has a corresponding frequency and high efficiency characteristic.

CLAIM OF PRIORITY

The present invention claims priority from Japanese patent application JP 2007-174015 filed on Jul. 2, 2007, the content of which is hereby incorporated by reference into this application.

FIELD OF THE INVENTION

The present invention relates to a DCDC converter unit, a power amplifier, and a base station, and in particular, to a base station that performs wireless communication using a broadband high-frequency signal, and a DCDC converter and a power amplifier suitable for the base station apparatus.

BACKGROUND OF THE INVENTION

A power amplifier that is used in a base station that performs wireless communication is required to have a small size and high efficiency in consideration of cost. Further, high speed and broadband communication is progressing in the wireless communication field such as mobile phones and a broadband and high efficiency power amplifier is required for a base station. Envelop elimination and restoration (EER), which is one of the methods used for addressing the above demands, is disclosed in U.S. Pat. No. 6,256,482B1.

Further, in JP-A-2006-211112, a broadband D/A converter that uses an EER method and a broadband power amplifier using the same are disclosed. According to JP-A-2006-211112, the broadband D/A converter splits an input digital envelope signal for every frequency band, and n D/A converters individually convert digital envelope signals into analog signals. Furthermore, the converted analog signals are up-converted at predetermined frequency bands by individual up-converters and then added by an adder to be transmitted as an analog envelope signal corresponding to the original digital envelope signal.

In JP-A-2005-277559, a broadband and high efficiency EER transmitter is disclosed. According to the configuration of the transmitter disclosed in JP-A-2005-277559, an amplitude component of a modulation signal is input to a power supply terminal of a high-frequency power amplifier and a phase component thereof is input to a high frequency wave input terminal of the high-frequency power amplifier. Further, a modulated wave that is modulated from the original modulation signal is obtained through an output of the high-frequency power amplifier. An output of any of plural DC-DC converters is selected according to the level of the amplitude component as a power supply voltage of the transmitter.

In JP-A-Hei 11(1999)-127573, a parallel operating apparatus of a DC/DC converter is disclosed. The parallel operating apparatus of a DC/DC converter includes plural DC/DC converters that can be operated simultaneously and connected in parallel to each other, a current detecting circuit that detects the total current output from an output terminal, and a DC/DC converter on/off control circuit that controls the number of DC/DC converters to be operated according to the amount of total current.

In “High-Linearity RF Amplifier Design” (written by Peter B. Kenington, Artech house, 2000, PP 124-126), an example of s configuration of a class-S amplifier is disclosed. With this configuration, a PMW signal is generated by comparing an input waveform with a triangular wave, and the PMW signal is amplified by an amplifier including a pair of transistors in which a diode is inserted between a collector and an emitter. Further, a desired output is obtained by a low pass filter.

SUMMARY OF THE INVENTION

An example of the EER amplifier disclosed in U.S. Pat. No. 6,256,482B1 is shown inFIG. 17. Amplitude information (AM signal) is extracted from a high frequency input signal by an envelope detector15. Further, phase information of the input signal is extracted by a limiter16. The amplitude information is amplified by a class-S amplifier25and then supplied to a power supply terminal of a carrier amplifier17. Further, the phase information is supplied to an input terminal of the carrier amplifier17. Even though the amplitude information of the input signal is temporarily absorbed by the limiter16, since the amplitude information is supplied to the power supply terminal of the carrier amplifier17, the absorbed amplitude information is recovered by the carrier amplifier17. Further, because the carrier amplifier17of the EER amplifier26shown inFIG. 17is designed to always be saturated regardless of the input power, this results in the EER amplifier having a high efficiency. However, in order to make the entire EER amplifier26highly effective, the DCDC converter that amplifies the amplitude information needs to have high efficiency, in addition to the carrier amplifier17. In U.S. Pat. No. 6,256,482B1, the class-S amplifier25serves as a DCDC converter.

Even though the amplitude information has a frequency lower than the phase information, in a broadband system such as a worldwide interoperability for microwave access (WiMAX), the applicable frequency band reaches several tens of MHz and the maximum transmission rate reaches 75 Mbps. In case of the class-S amplifier that amplifies the amplitude information, as the operating frequency becomes higher, the power efficiency becomes lowered. Further, the operating frequency band that is capable of obtaining efficiency applicable to the EER amplifier suitable for the base station is several hundreds of kHz to several MHz. Therefore, it is difficult to use the class-S amplifier for the high speed and broadband system such as WiMAX. That is, if the frequency of the input signal becomes higher, W/L of a MOS transistor needs to be large in order to allow a PMOS transistor and an NMOS transistor, which configure an inverter of the class-S amplifier to correspondingly comply with the frequency. Further, a large-sized MOS transistor is required. However, if the W/L of the transistor becomes larger, a peak value of a pass-through current that flows in the inverter becomes larger, which lowers the efficiency of the class-S amplifier.

Further, if the W/L becomes larger, even though an on-state resistance of the MOS transistor becomes smaller, the gate capacity becomes larger. Therefore, when a frequency band signal that is lowered by the gate capacity is output from a comparator, the efficiency of the class-S amplifier becomes lowered. As a result, even though the W/L of the PMOS transistor and the NMOS transistor, which configure the inverter, is sufficiently high, if the frequency of the input signal is high as compared with the W/L, the inverter cannot be driven with the output signal of the comparator with the square wave, which lowers the efficiency of the class-S amplifier.

On the other hand, if the frequency of the input signal is low, when a PMOS transistor and an NMOS transistor having a large W/L are used for the inverter, the pass-through current becomes larger, which lowers the efficiency.

As described above, when the class-S amplifier is used as a DCDC converter, the class-S amplifier is not suitable for amplifying the amplitude information of a wireless communication system having a high transmission rate and a wide applicable frequency band, such as WiMAX. That is, in case of a broadband wireless communication system, the class-S amplifier that is a DCDC converter needs to operate with a low efficiency but at a high frequency band.

The broadband D/A converter disclosed in JP-A-2006-211112 converts individually digital envelope signals that are divided for every frequency band by a band divider into analog signals. The D/A converter includes a frequency converter that multiplies the individual analog signals by a sine wave to be up-converted. Further, the D/A converter D/A-converts the broadband envelope signals. However, during the up-converting to the IP frequency band, when the sine wave is multiplied with the analog signals, the operation in a non-saturated area, that is, the overlapping of the current component and the voltage component cannot be avoided, which causes a large power loss. Therefore, it is difficult to ensure high efficiency in the power amplifying apparatus that uses the D/A converter. Further, the band divider shifts the frequency so as not to include frequency signals of 5000 Hz or larger such that the divided output signals has the same low frequency band, for example, an operating rate of 5000 Hz. However, when using this process, it is difficult to efficiently amplify the amplitude information of a wireless communication system with high speed and wide applicable frequency band such as WiMAX.

Furthermore, the apparatus disclosed in JP-A-2005-277559 or JP-A-Hei 11(1999)-127573 includes plural DC-DC converters connected in parallel to each other. However, since the input signal is processed by any of the DC-DC converters, the amplifier for a signal having a high speed and wide frequency band decreases in efficiency.

An object of the present invention is to provide a DCDC converter unit that has a high efficiency for a high speed and broadband input signal, a power amplifier applicable to a wireless communication system using the same, and a base band using the same.

Further, another object of the present invention is to provide a broadband and high efficiency DCDC converter unit that is capable of applying to a terminal, and etc. and an amplifier using the same.

An exemplary embodiment of the invention will be described. A DCDC converter unit according to the exemplary embodiment includes a signal splitting unit that splits an input signal into plural signal components; plural DCDC converter elements each of that has different characteristics for frequency bands; and an adder that adds outputs from the plural DCDC converter elements to generate an output signal. Each of the plural signal components may be input to any of the DCDC converter elements that has a characteristic corresponding to a frequency of the corresponding signal component.

According to the present invention, it is possible to provide a highly efficient and broadband DCDC converter unit (Hereafter, it is written as a DCDC converter) and a power amplifier that is capable of being applied to a high speed and broadband wireless communication system.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Due to the demand for a high speed and broadband communication, the present invention uses an idea that a DCDC converter unit whose input signal has a lower frequency is more efficient and there is a design parameter that optimizes the efficiency of the DCDC converter according to the band of the input signal.

According to an exemplary embodiment of the present invention, a DCDC converter includes a signal splitting unit that splits an input signal into plural signal components; plural DCDC converter elements that have different characteristics for frequency bands; and an adder that adds outputs from the plural DCDC converter elements to generate output signals. Each of the plural DCDC comparator elements has an operation band narrower than an applicable frequency band of the input signal, and selects a design parameter that allows a conversion efficiency of the DCDC converter elements to be optimized for any band of the applicable frequency bands. That is, the components of each of the DCDC converter elements, for example, a triangle wave generated by a triangle wave generating unit and the input signal component are compared by a comparator. Therefore, according to the comparison result, at least one of parameters of a PMOS transistor and a NMOS transistor which configure an inverter that inversely amplifies and outputs a square wave output from the comparator and a parameter of a filter that extracts and outputs an output waveform passing through a predetermined frequency band within an applicable frequency band from the output waveform from the inverter is set to allow the efficiency to be optimized for any of the frequency bands of the input signal and to control the total applicable frequency band for the entire DCDC converter.

Specifically, the inverter and the filter have a parameter that the efficiency of each of the DCDC converter elements at a predetermined frequency band is better than the efficiency at the other frequency band within the applicable frequency band. The frequency band of the input signal is split, and each of the split outputs is input to a DCDC converter element that has a corresponding frequency and high conversion efficiency characteristic.

Therefore, by increasing the efficiency of the DCDC converter elements, it is possible to improve the efficiency of the entire DCDC converter, and realize the DCDC converter having improved efficiency as compared with the related art that processes the broadband input signal by a single DCDC converter element.

First Embodiment

A DCDC converter according to a first embodiment of the present invention will be described with reference toFIGS. 1 to 5.FIG. 1is a block diagram showing a DCDC converter according to the first embodiment of the invention andFIG. 2is a circuit diagram showing a DCDC converter element shown inFIG. 1.

A DCDC converter1includes a signal splitting unit2that splits an input signal into N signal components Sd (Sd1to Sdn), N DCDC converter elements31to3N that process N signal components that are split by the signal splitting unit2and have different characteristics for frequency bands, and an adder4that adds outputs Sc (Sc1to Scn) of the N DCDC converter elements.

Class-S amplifiers shown inFIG. 2serve as each of the DCDC converter elements31to3N. Each of the plural DCDC converter elements has high efficiency at a predetermined frequency band. Further, the entire DCDC converter elements31to3N are configured so as to control the entire applicable frequency bands. Each of the operating band of the DCDC converter elements is narrower than the applicable frequency bands, and a design parameter is selected so as to optimize the efficiency of each of the DCDC converter elements at any of the applicable frequency bands.

Referring toFIG. 2, each of the class-S amplifiers that configures each of the DCDC converter elements31to31N includes a triangle wave generating unit5that generates a low frequency band triangle wave signal having a frequency component that is predetermined times a frequency of the input signal component Sd, a comparator6that compares an input signal component with the triangle wave to output a square wave, a PMOS transistor7and a NMOS transistor8, which configure an inverter, and a coil9and a capacitor10, which configure a filter having a predetermined pass band set for every DCDC converter element. A signal Sc obtained by amplifying a pass band input signal component of the filter is output from each of the DCDC converter elements.

Since the MOS transistor, which configures the inverter, is completely turned on/off, not saturated, the DCDC converter elements can amplify the input signal with high efficiency.

As described above, the PMOS transistor7and the NMOS transistor8, which configure the inverter, need to satisfactorily comply with a frequency of the triangular wave. Therefore, the W/L of the MOS transistor has to be large. However, if the W/L is larger, the peak value of the pass-through current that flows in the inverter becomes larger, which lowers the efficiency of the DCDC converter elements. Further, as a gate capacitance becomes larger, the efficiency of the DCDC converter elements is lowered. Therefore, the above needs to be taken into consideration. When the frequency of the input signal Sd is low, the W/L becomes smaller so as to make the pass-through current of the inverter small, which prevents the lowering of the efficiency.

As such, the efficiency of the DCDC converter elements is lowered as the frequency of the input signal becomes lower. However, a parameter that optimizes the efficiency according to the frequency band of the input signal, that is, a size of the PMOS transistor7and NMOS transistor8already exists.

According to the first embodiment, a broadband input signal is split into plural frequency band signal components. The DCDC converter elements31to3N to which the frequency band signal components are input are designed to allow a parameter of components thereof, that is, the PMOS transistor and the NMOS transistor, which configure the inverter, to optimize the efficiency at the frequency band of the input signal components.

Referring toFIG. 1again, output signals Sc of the DCDC converter elements31to3N are added by the adder4so that a broadband signal obtained by amplifying the input signal is generated as an output signal.

FIG. 3shows a first configuration example of the signal splitting unit2shown inFIG. 1. The signal splitting unit2includes a low pass filter11and a high pass filter12. The input signal is input to the low pass filter11and the high pass filter12and output signals Sd1and Sd2of the filters serve as output signals of the signal splitting unit2.

Next, an operation when the signal splitting unit2shown inFIG. 3is applied to the DCDC converter according to the embodiment of the invention shown inFIG. 1will be described.

As described above, in order to make the efficiency of the entire EER amplifier high, both the carrier amplifier and the DCDC converter that amplifies amplitude information need to have high efficiency. Even though the amplitude information has a lower frequency than the phase information, the upper limit of the applicable frequency band in the broadband wireless communication system such as worldwide interoperability for microwave access (WiMAX) reaches several tens of KMz. In the meantime, as shown inFIG. 4A, the DCDC converter has a characteristic that the power efficiency is rapidly lowered as the operating frequency (at the same interval) becomes higher.

In this embodiment, a frequency component of the input signal is split, and class-S amplifiers that correspond to the frequencies of the split signals respectively are used as DCDC converter elements, and the group of DCDC converter elements configures the DCDC converter. Therefore, the lowering of the power efficiency accompanied by the broadening of the operational frequency band can be prevented.

FIG. 4Bis a diagram showing that the band of the input signal is split by the signal splitting unit2shown inFIG. 3. The input signal having a predetermined band is input to the signal splitting unit2and then split into a low band component Sd1that is lower than a frequency Fa and a high band component Sd2that is higher than the frequency Fa and lower than a frequency Fb, by a low pass filter11and a high pass filter12. The split signals are input to the DCDC converter elements31to32. That is, an output signal Sd1of the low pass filter11is input to the DCDC converter element31and an output signal Sd2of the high pass filter12is input to the DCDC converter element32.

As a result, an operating speed of the DCDC converter element31is low, and an operating speed of the DCDC converter32is high. Therefore, a parameter of each of the DCDC converter elements needs to be previously set so as to optimize the efficiency at each of the operating speeds.

Specifically, in case of the DCDC converter element31to which the low band component Sd1is input, since the frequency band of the input signal is low, the triangle wave output from the triangle wave generating unit5of the DCDC converter element shown inFIG. 2is a signal having a frequency component, which is predetermined times a frequency of the input signal. Therefore, the triangle wave is a low frequency band signal. The frequency component of the triangle wave is about fifty times the frequency component of the input signal, even though it may be varied depending on the wireless specification. The triangle wave and the input signal are compared by the comparator6to output the square wave. The inverter is required to process the square wave as a square wave.

In the DCDC converter element31, the frequency band of the input signal Sd1, that is, the frequency band of the square wave is in the low range. Therefore, the size of the PMOS transistor7and the NMOS transistor8, which configure the inverter of the DCDC converter element31, is designed to have the minimum W/L that is capable of processing the square wave as the square wave. Therefore, the W/L is small. The low pass filter that is configured by the coil9and the capacitor10is designed to have a band that passes the input signal component and intercepts the triangle wave component. Accordingly, the DCDC converter element31is designed to process the low band input signal and optimize the efficiency.

Further, in case of the DCDC converter element32to which the high band component Sd2is input, since the frequency band of the input signal Sd2is high, the triangle wave output from the triangle wave generating unit of the DCDC converter element shown inFIG. 2is a signal having a frequency component that is predetermined times a frequency of the input signal. Therefore, the triangle wave is a high frequency band signal. Similarly the DCDC converter element31, in case of the DCDC converter element32, the frequency component of the triangle wave is about fifty times the frequency component of the input signal, even though it may be varied depending on the wireless specification. The triangle wave and the input signal are compared by the comparator6to output the square wave. The inverter is required to process the square wave as a square wave. In the DCDC converter element32, the frequency band of the square wave is high. Therefore, the size of the PMOS transistor7and the NMOS transistor8, which configure the inverter, is designed to have the minimum W/L that is capable of processing the square wave as the square wave. Therefore, the W/L is large as compared with the inverter of the DCDC converter element31. Further, the low pass filter that is configured by the coil9and the capacitor10is designed to have a band that passes the input signal component and intercepts the triangle wave component.

The output signals Sc1and Sc2of the DCDC converter elements31and32are added by the adder4so that a signal obtained by amplifying the input signal is generated as an output signal.

Accordingly, the efficiency of the DCDC converter element32that processes the high band component Sd2of the input signal is the same as the related art, and the efficiency of the DCDC converter element31that processes the low band component Sd1of the input signal becomes higher. As a result, the efficiency of the entire DCDC converter1is improved.

FIG. 5is a diagram showing a relationship between a frequency of an input signal when using a transistor and the efficiency of the DCDC converter (the horizontal axis is represented by an exponential scale). In contrast, if the efficiency of the DCDC converter element31is 90%, the efficiency of the DCDC converter element32is 50%, the power density of a signal component Sd1that is input to the DCDC converter element31is 50%, the power density of a signal component Sd2that is input to the DCDC converter element32is 50%, and the efficiency of the adder is 95%, the total efficiency of the DCDC converter1according to the first embodiment is represented by the following equation.
Power efficiency=(efficiency of DCDC converter element 31*power density of signal component that is input to DCDC converter element 31+efficiency of DCDC converter element 32*power density of signal component that is input to DCDC converter element 32)*efficiency of adder=(90%*50%+50%*50%)*95%=66.5%   (1)

That is, the efficiency of the DCDC converter1according to the first embodiment is 66.5%.

In the meantime, according to the related art that does not split a frequency of an input signal, a single DCDC converter needs to process the entire applicable frequency band component of an input signal. Therefore, the DCDC converter corresponding to the DCDC converter element32is used. However, since the efficiency of the DCDC converter element32is 50%, the efficiency of the DCDC converter according to the related art is 50%. As a result, according to the embodiment of the invention, the efficiency of the DCDC converter is improved by 16.5%.

Further, if the signal splitting unit2performs the same operation, the signal splitting unit does not need to have the configuration shown inFIG. 3. The DCDC converter elements also may use a configuration other than the class-S amplifier. Furthermore, the DCDC converter element32does not need to have the same characteristic as the DCDC converter element that processes the entire applicable frequency component according to the related art, and may set a parameter having a high conversion efficiency for the high band component Sd2.

The signal splitting unit may include a predetermined number of band pass filters in addition to the low pass filter and the high pass filter, and split a broadband frequency into three or more frequency bands. Even in this case, the components of the DCDC converter that correspond to the respective band filters, for example, the PMOS transistor and the NMOS transistor, that configure the inverter, have a parameter that is set to optimize the efficiency at the respective frequency bands. Therefore, it is possible to increase the efficiency of each of the DCDC converter elements and thus improve the efficiency of the DCDC converter.

According to the first embodiment, it is possible to provide a high efficiency DCDC converter in a high speed and broadband wireless system.

Second Embodiment

Next, a second embodiment according to the invention will be described with reference toFIGS. 6 to 8. The second embodiment relates to another configuration example of the signal splitting unit2of the DCDC converter shown inFIG. 1. The configuration of the signal splitting unit2is shown inFIG. 6. The signal splitting unit2according to the second embodiment is configured by N comparator elements131to13N and N threshold generating units141to14N. Signal components Sd1to SdN obtained by comparing an input signal with threshold values by the N comparator elements131to13N are output. Therefore, an amplitude component of the input signal is split into N components.

FIGS. 7A and 7Bshow operation examples when the signal splitting unit2according to the second embodiment includes three comparator elements. As shown inFIG. 7A, the input signal is split into amplitude components on the basis of three threshold values V1, V2, and V3. The three comparator elements output square waves shown inFIG. 7Bby comparing the input signal with the threshold values V1, V2, and V3. In this case, since the threshold value V1has a lower level than the input signal, a DC component is output as a signal component Sd1. Further, the signal components Sd2and Sd3are not DC components, but signals that shift to predetermined frequencies.

The signal components Sd1, Sd2, and Sd3are input to the DCDC converter elements31to33, and the output signals Sc1, Sc2, and Sc3are added by an adder4to serve as an output signal. The output signal is obtained by amplifying the input signal.

In this case, since the signal components Sd1is a DC component, the efficiency of the DCDC converter element31to which the signal component Sd1is input is almost 100%. Even though the DCDC converter elements32and33to which the signal components Sd2and Sd3are input have poor efficiencies, since the efficiency of the DCDC converter element31is significantly good, the entire efficiency of the DCDC converter1according to the second embodiment is improved as compared with the configuration configured by the single DCDC converter element according to the related art.

That is, referring toFIG. 8, if the efficiency of the DCDC converter element31is 100%, the efficiency of the DCDC converter element32is 60%, the efficiency of the DCDC converter element33is 20%, the power density of an input signal component is ⅓, and the efficiency of the adder is 95%, the total efficiency of the DCDC converter1according to the second embodiment is represented by the following equation (2).
Power efficiency=(100%*⅓+60%*⅓+20%*⅓)*95%=57%   (2)

Therefore, since the efficiency of the DCDC converter element33is 20%, the efficiency of the DCDC converter according to the related art is also 20%. As a result, according to the second embodiment of the invention, the efficiency of the DCDC converter is improved by 37%.

The signal splitting unit2is not limited to the configuration shown inFIG. 6, if it is possible to realize the same operation.

According to the second embodiment, it is possible to provide a high efficiency DCDC converter in the high speed broadband wireless system.

Third Embodiment

Next, a third embodiment according to the invention will be described with reference toFIGS. 9 to 11. The third embodiment relates to still another configuration example of the signal splitting unit2of the DCDC converter shown inFIG. 1. Referring toFIG. 9, the signal splitting unit2is configured by a timing generating unit28, a set flipflop30, N-1 set-reset flipflops27, and N-1 subtractors29. A phase of an input signal is split into N signal components Sd1to SdN.

FIG. 10shows an operation example of the signal splitting unit2that splits the input signal into four signal components according to the third embodiment shown inFIG. 9. Amplitude information of the input signal is extracted by the set flipflop30at a timing of C1. The amplitude information Sd1extracted by the set flipflop30is maintained by a timing of a rising edge of the subsequent C1.

Next, amplitude information Sd2of the input signal is extracted by the set-reset flipflop27at a timing of C2, and is maintained by a timing of a rising edge of the subsequent C1. The amplitude information Sd1and Sd2are subtracted by the subtractor29to be output as a difference signal Sd2−Sd1. Similarly, amplitude information Sd3and Sd4of the input signal are extracted at timings of C3and C4, and difference signals Sd3−Sd2, and Sd4−Sd3are generated and output.

The signals components Sd1, Sd2−Sd1, Sd3−Sd2, and Sd4−Sd3that are output using the amplitude information by the signal splitting unit2shown inFIG. 9are then input to first to fourth DCDC converter elements, respectively, and then added by the adder to be output as output signals.

As is seen fromFIG. 10, it is possible to decrease frequencies of the signal components Sd1and Sd3−Sd2. Further, even though the signal components Sd2−Sd1and Sd4−Sd3may also have fast frequency component, since the amount of shift in the amplitude direction is small, the load for the DCDC converter is small, which improves the efficiency.

That is, referring toFIG. 11, if the efficiencies of the first and third DCDC converter elements are 60%, the efficiencies of the second and fourth DCDC converter elements are 20%, the power densities of input signal components are ¼, and the efficiency of the adder is 95%, the total efficiency of the DCDC converter1according to the third embodiment is represented by the following equation (3).
Power efficiency=(60%*¼+60%*¼+20%*¼+20%*¼)*95%=41%   (3)

Therefore, since the efficiencies of the second and fourth DCDC converter elements are 20%, the efficiency of the DCDC converter according to the related art is also 20%. As a result, according to the third embodiment of the invention, the efficiency of the DCDC converter is improved by 21%.

Further, the signal splitting unit2is not limited to the configuration shown inFIG. 9, if it is possible to realize the same operation. Further, the filter may split the broadband frequency into three or more frequency bands.

According to the third embodiment, it is possible to provide a high efficiency DCDC converter in the high speed broadband wireless system.

Fourth Embodiment

Next, a fourth embodiment according to the invention will be described with reference toFIGS. 12 and 13. The fourth embodiment relates to still another configuration example of the signal splitting unit2of the DCDC converter shown inFIG. 1. A signal splitting unit2according to the fourth embodiment is a combined use of the signal splitting unit for frequency splitting shown inFIG. 3and the signal splitting unit for amplitude splitting shown inFIG. 6.

The signal splitting unit2shown inFIG. 12includes a low pass filter11, a high pass filter12, comparators131to13N, and threshold generating units141to14N.

As shown inFIGS. 12 and 13, a frequency of an input signal is split by the low pass filter11and the high pass filter12. Thereafter, an amplitude of a low frequency component are split by the comparators131to13M, and an amplitude of a high frequency component are split by the comparators13M+1 to13N. The generated signal components Sd1to SdM and SdM+1 to SdN are input to corresponding DCDC converter elements that are designed to have a parameter to make the efficiency good at a predetermined frequency and amplified. Thereafter, the outputs are added by an adder4to be output as an output signal of the DCDC converter1.

Further, the signal splitting unit2is not limited to the configuration shown inFIG. 12, if it is possible to realize the same operation. Further, the filter may split the broadband frequency into three or more frequency bands.

According to the fourth embodiment, it is possible to provide a high efficiency DCDC converter in the high speed broadband wireless system.

Fifth Embodiment

Next,FIG. 14shows a fifth configuration example of the signal splitting unit2shown inFIG. 1. A signal splitting unit2according to the fifth embodiment is a combined use of the signal splitting unit for frequency splitting shown inFIG. 3and the signal splitting unit for amplitude and phase splitting shown inFIG. 9. The signal splitting unit2includes a low pass filter11, a high pass filter12, a timing generating unit28, set flipflops30, N-1 set-reset flipflops27, and N-1 subtractors29. A frequency of an input signal is split by the low pass filter11and the high pass filter12. Thereafter, amplitudes and phases of low frequency components are split by the set flipflop30, the M set-reset flipflops27, and the M subtractors. Further, amplitudes and phases of high frequency components are split by the set flipflop30, the M set-reset flipflops27, and the M subtractors. The output signal components are input to corresponding DCDC converter elements that are configured to have a good efficiency at a predetermined frequency, and amplified. Thereafter, the outputs are added by the adder4to be output as an output signal of the DCDC converter1.

Further, the signal splitting unit2is not limited to the configuration shown inFIG. 14, if it is possible to realize the same operation. Further, the filter may split the broadband frequency into three or more frequency bands.

According to the fifth embodiment, it is possible to provide a high efficiency DCDC converter in the high speed and broadband wireless system.

Sixth Embodiment

An EER amplifier according to a sixth embodiment of the invention will be described with reference toFIG. 15.

The EER amplifier shown inFIG. 15is an EER amplifier that uses the DCDC converter1according to the above embodiments. The EER amplifier18includes an envelope detector15, a limiter16, a DCDC converter1, and a carrier amplifier17. The DCDC converter1is configured by the DCDC converter elements according to the above embodiments.

Next, the operation of the EER amplifier will be described.

Amplitude information AM of an input signal that is a high frequency signal is extracted by the envelope detector15. Further, phase information PM of the input signal is extracted by the limiter16. The amplitude information is amplified by the DCDC converter1and then supplied to a power supply terminal of the carrier amplifier17. Further, the phase information is supplied to an input terminal of the carrier amplifier17.

Even though the amplitude information of the input signal is temporarily absorbed by the limiter16, the amplitude information is supplied to the power supply terminal of the carrier amplifier17. Accordingly, the absorbed amplitude information is recovered by the carrier amplifier17. Since the EER amplifier18is designed to allow the carrier amplifier17to be saturated without using the input power and the DCDC converter1that amplifies the amplitude information has a high efficiency, the entire system has a high efficiency.

That is, even though in a communication system such as WiMAX, the used frequency reaches several tens MHz and a broadband signal is input, the DCDC converter1that amplifies the amplitude information splits the frequency band of the input signal into plural components. Then, each of the signals is input to corresponding DCDC converter elements that have a good efficiency at a predetermined frequency band. Accordingly, even though the operating frequency is high, it is possible to prevent the lowering of the power efficiency. Therefore, it is further possible to obtain an EER amplifier having high conversion efficiency sufficient to be applied to a base station at a broad operation frequency band of several hundreds of kHz to 100 MHz.

As described above, the EER amplifier according to the sixth embodiment uses a DCDC converter1according to the above embodiments. Therefore, even though a broadband amplitude modulated signal such as WiMAX that cannot be processed by the class-S amplifier according to the related art is input, it is possible to realize the high efficiency operation.

Further, in order to correct the AM-PM distortion or AM-AM distortion, the feedback operation that compares the output signal and the input signal of the carrier amplifier17may be performed. Furthermore, predistortion may be performed.

According to the sixth embodiment, it is possible to provide a highly efficient power amplifier in the high speed broadband wireless system.

Seventh Embodiment

Next, a base station according to a seventh embodiment of the invention will be described with reference toFIG. 16. The base station21shown inFIG. 16is a base station that uses an EER amplifier according to the sixth embodiment. The base station21includes a base band unit19, a modem20, and an EER amplifier18.

Transmission information is processed in the base band unit19, and then modulated by the modem20. Therefore, the information is amplified by the EER amplifier18to be transmitted to an antenna23. Since the EER amplifier18is an EER amplifier that uses a DCDC converter1according to any of the above embodiments, it is possible to realize the highly efficient operation even in a broadband wireless system such as WiMAX that can not processed by the EER amplifier according to the related art.

Further, predistortion that inputs an output signal of the EER amplifier18to the base band unit19to correct the distortion may be performed.

According to the seventh embodiment, it is possible to provide a highly efficient base station in the high speed broadband wireless system.

Further, the broadband and highly efficient DCDC converter and the amplifier using the same may be broadly applied to a portable terminal, a terminal built in a vehicle, a terminal mounted in a digital household electrical appliance, and other wireless communication systems that process broadband and high speed signals, in addition to the base band.