Various exemplary embodiments disclosed herein relate generally to power amplifiers. More specifically, they relate to integrated Chireix out-phasing power amplifiers and methods.
Power amplifiers are widely used in communication systems, for example in cellular communication systems and cellular base stations wherein high frequency communication signals are amplified for transmission.
Bandwidth and efficiency are important considerations in the design of power amplifiers. In the context of cellular base stations, there is a growing need for improved power amplifier (PA) efficiency. There is also need for reconfigurable cellular base station transmitters due to the growing number of standards and the need for backward compatibility without compromising the overall power amplifier efficiency and linearity. A conventional power amplifier, such as a class-B amplifier, generally provides maximum efficiency at or near its maximum saturated power output level. In order to accurately reproduce a signal of varying amplitude, the peak output signal level should be equal to or less than that maximum saturated power level. When the instantaneous signal output level is less than the peak output level, a conventional class-B power amplifier generally operates at less than maximum efficiency.
More recent cellular communication standards, such as UMTS (Universal Mobile Telecommunication Standard) and LTE (Long-Term Evolution) created within 3 GPP (3rd Generation Partnership Project), use complex modulation schemes whose amplitude component creates large variations in the instantaneous carrier output power of a transmitter. The ratio of the peak carrier output power to the average output power (defined as the “crest factor”) when expressed in decibels (dB), may reach values on the order of 10 dB. With crest factors of such magnitude, efficiency of a base-station power amplifier is severely reduced; in order to be able to process large peak carrier powers, a conventional, linear PA operates several dB below its maximum output power capability (e.g., several dB into back-off) for most of its operational time.
Various approaches have been proposed to address the issue noted above. In one approach, a modified out-phasing technique by Chireix (sold under the brand name “Ampliphase” by RCA) has been proposed. The term “out-phasing” relates to a method of obtaining amplitude modulation (AM) by combining several (generally two) phase-modulated constant-amplitude signals as further described below. These signals are produced in a “signal component separator” (SCS) and subsequently, after up-conversion and amplification through RF chains (mixers filters and amplifiers), combined to form an amplified linear signal within an output combiner network. The phases of these constant-amplitude signals are chosen so that the result from their vector-summation yields the desired amplitude, as the amplitude modulation is achieved by the degree of addition or subtraction due to the phase difference between the two signals.
In the Chireix approach, as noted above, a low-level copy of an intended output signal is resolved into two equal-amplitude components with a phase separation determined by the instantaneous amplitude of the intended output signal. These two equal-amplitude components are then amplified by a pair of RF power amplifiers operating in saturation or switched-mode for optimum power efficiency. The outputs of both the power amplifiers are then combined in a low-loss Chireix combiner so as to re-construct a fully-modulated RF carrier. By so doing, effectively, the resistive load impedance that is seen by both PAs becomes a function of the output phase angle and results in an envelope modulation of the output power expressed as:
In the Chireix approach described above, benefits are derived from the use of switched-mode rather than linear-mode power amplifiers.
Conventional Chireix out-phasing PA has drawbacks in terms of bandwidth and efficiency. Frequency limitations are imposed by power combiner (e.g., quarter wavelength transmission lines) and fixed susceptance compensation elements (±jBC, as discussed below). Another drawback in the conventional Chireix PA is that it is usually built from saturated linear PAs (e.g., class AB) or harmonically tuned PAs (e.g., class-F), which ideally fail to provide 100% efficiency without making use of harmonic traps in a matching network.
Other approaches based on class-E and other switch mode (e.g., class DE) based out-phasing have other deficiencies, as they have failed to consider integration, reported to have wide RF bandwidth, and failed to account for reconfigurability aspects. Further, other approaches, like the n-way Doherty PA, in general require more tunable elements due to the use of several quarter-wave transmissions lines.
In light of the present need for communications networks having base stations with enhanced power amplifier efficiency and reconfigurability, a brief summary of various exemplary embodiments is presented. Some simplifications and omissions may be made in the following summary, which is intended to highlight and introduce some aspects of the various exemplary embodiments, but not to limit the scope of the embodiments. Detailed descriptions of a preferred exemplary embodiment adequate to allow those of ordinary skill in the art to make and use the inventive concepts will follow in later sections.
In one aspect, an integrated digital Chireix power amplifier device includes power transistor circuitry having plurality of power transistors and shunt-series circuitry; a broadband combiner having Chireix compensation elements; and an impedance matching filter, wherein the power transistor circuitry, the broadband combiner, and the impedance matching filter are arranged to be integrated in a unified package.
In another aspect, a cellular base station terminal having a digital Chireix power amplifier structure is disclosed.
In a further aspect, a method of driving a Chireix power amplifier structure is disclosed. The method includes providing power transistor circuitry having a plurality of power transistors and shunt-series circuitry, a broadband combiner having Chireix compensation elements, and an impedance matching filter in a unified package. The method may also include tuning a shunt-series network so as to enable reconfiguring of the power amplifier structure. The method may also include driving the power transistor circuitry in a real switch-mode.
In order to better understand various exemplary embodiments, reference is made to the accompanying drawings, wherein:
a) is a diagram illustrating efficiency as a function of normalized output power in dB for the power amplifier shown in
b) is a diagram illustrating efficiency as a function of normalized output power in dB for the power amplifier shown in
Referring now to the drawings, in which like numerals refer to like components or steps, there are disclosed broad aspects of various exemplary embodiments.
where ROPT is the optimum class-E load resistance, B, is the Chireix compensation element, and θC is the Chireix compensation angle where we ideally require 100% efficiency for a specific back-off power level with respect to the peak power.
The transistor circuitry 202 may comprise, for example, a CMOS driver connected to a Gallium Nitride (GaN) power transistor. A person of skill in the art would be knowledgeable of other combinations, such as a CMOS driver with a laterally diffused metal oxide semiconductor (LDMOS) power transistor, or BiCMOS driver with GaN power transistor.
The broadband combiner circuitry 204 may include broadband combiner 214 and high-quality impedance matching filter circuit 216. In some embodiments, the PA 200 may operate with the power transistors 202 operating at a constant duty cycle, e.g., D=0.5 (50%).
Exemplary features in accordance with various embodiments one of which is shown in
Additional features of the PA 200 are the integrated power transistors. The integrated power transistors of the transistor circuit 202, along with the shunt inductors 210, 212 in a unified package may use “inshin” technique, as described U.S. Pat. No. 7,119,623 (assigned to the present assignee), the entire contents of which are incorporated herein by reference. The shunt inductors 210, 212 may facilitate establishing a desired class-E operation mode and also desired Chireix compensation-per-power transistor.
During regular configuration and operation, a reconfigurable Chireix out-phasing power amplifier may be established by means of varying effective shunt inductance, which may require, for example, varactors (i.e., variable-capacitance diodes) or switched capacitor banks. The modulation of the at least one varactor may be used for analog tuning, whereas the switched capacitor banks may be used for digital tuning. In some embodiments, both analog and digital tuning of the Chireix PA may be implemented simultaneously. In some embodiments, the reconfigurable Chireix out-phasing PA may be established with static inductors and capacitors, and a modifiable duty cycle of the switch power transistors.
The broadband combiner 214 of the combiner circuitry 204 may be implemented by a Marchand balun or its low frequency equivalent or a transformer-based combiner.
In some embodiments, the element values of the shunt series networks at the output of both PA branches 211A, 211B can be calculated from the equations below:
where the quality factor q is ideally 1.3 for load modulation, CDS is the output capacitance of the transistor, w is the operational frequency, and the Chireix compensation element Bc is given by (3).
For example, if a complex-modulated signal (e.g. WCDMA or LTE) has a crest factor of 10 dB, it may be preferred that the second efficiency peak of the complex-modulated signal have a magnitude approximately equal to the 10 dB back-off. In this embodiment, L1 and L2 may be fixed, shunt-drain inductors, which may have to fulfill at least equation (8). In order to maintain the optimum class-E operating mode (q≈1.3) and Chireix compensation for frequencies other than the design frequency f0 (aiming at reconfigurable PAs), the values of C1 and C2 in 210, 212 may be changed in accordance with equation (7). The values of C1 and C2 may be modified using analog tuning with varactors, or using digital tuning with switched capacitor banks. The tuning settings for the capacitors C1 and C2 may be stored in a table and may be set by a digital “word” when installing a base station amplifier (not shown).
In another embodiment, fixed L1 and L2 values, with or without series capacitors C1 and C2 in shunt inductors210, 212, may be chosen, while duty cycles D1 and D2 may be modified digitally to effectively change the quality factor q to compensate for a change in frequency co without needing to change the component values calculated in equation (3) and equation (6) at the nominal design frequency.
In an exemplary embodiment, Table 1 lists the optimum element values for the power amplifier 200, when assuming a device output capacitance CDS=1pF and a back-off level of 13 dB.
a) is a diagram illustrating simulated power efficiency, in one example, as a function of normalized output power in dB for the power amplifier 200 shown in
b) is a diagram illustrating simulated power efficiency, in one example, as a function of normalized output power in dB for the power amplifier 200 shown in
In another embodiment, a fixed, rather than a tunable, Chireix combiner network may be used, wherein the power amplifier 200 may be reconfigured for different frequency bands by varying the duty cycle. In such an embodiment, changing the duty cycle has a similar effect in reconfiguring the PA as changing the effective shunt inductance L and output capacitance CDS series in shunt inductors 210, 212. In the example embodiment described in relation to
In an exemplary case, Table 2 shows component values for the power amplifier 200 of
In the embodiment shown in
A feature in accordance with the various embodiments may be the integration of a tunable shunt series networks 210, 212 (
The relation between the coupled-line parameters (electrical length φ1,2, even and odd-mode characteristic impedances Z0e, and Z0o) and the lumped equivalent circuit may viewed according to the equations:
This may result in the effective input admittance at the input terminals S1 and S2 in becoming:
Where the first two terms may be considered the effective shunt admittance of the balun. The third term may be considered the load modulation term and describes how the load impedance is modulated by the out-phasing angle θ.
In one embodiment, when controlling the L1C1 and L2C2 shunt series, it may be desirable to have the effective shunt admittance of the balun
be small enough to have no appreciable influence on the values set by L1C1 and L2C2. This may therefore result in the circuit schematic 700 being similar to the power amplifier 500 as illustrated
In another embodiment, the design of the circuit schematic 700 may be made in a piecemeal manner, separating the class-E and Chireix requirements and fulfilling them independently. In this manner, the Chireix compensation may be made by asymmetry in the balun, while the class-E requirement may be fulfilled by setting =L2C2, which may be similar to power amplifiers 600, 620 of
In another embodiment, when controlling the duty cycles of the power transistors, the use of the L1C1 and L2C2 shunt series networks may be ignored.
Instead, the value of the effective shunt admittance may be
set according to the class-E and Chireix requirements of equations (3) and (6) at the nominal design frequency.
Another alternative embodiment may also involve control of both the L1C1 and L2C2 shunt series networks in addition to the control of the power transistors' duty cycles. A person of ordinary skill in the art would be knowledgeable of methods to combine the above-described design techniques.
In the exemplary plots shown in
The classical Chireix combiner with λ/4 transmission lines (or any derivative thereof) may suffer from highly frequency-dependent behavior of the port impedances at large back-off power levels. This may also be reflected in the PA power efficiency at 10 dB back-off power that is shown in the plot as illustrated in
Applications of the various embodiments include (reconfigurable) transmitters for connectivity and cellular applications, where the modulation standards with high peak-to-average ratio (PAR) require the power amplifier to be efficient over a large dynamic range. These transmitters are desirable for systems in which wide-band complex envelope signals are processed, such as, for example, EDGE, UMTS (WCDMA), HSxPA, WiMAX (OFDM) and 3G-LTE (OFDM).
It should be apparent from the foregoing description that various exemplary embodiments may be implemented in hardware and/or firmware.
Although the various exemplary embodiments have been described in detail with particular reference to certain exemplary aspects thereof, it should be understood that other embodiments and its details are capable of modifications in various obvious respects. As is readily apparent to those skilled in the art, variations and modifications can be affected while remaining within the spirit and scope of the embodiments. Accordingly, the foregoing disclosure, description, and figures are for illustrative purposes only and do not in any way limit the embodiments described, which is defined only by the claims.