Amplifiers – With plural amplifier channels – Redundant amplifier circuits
Reexamination Certificate
2003-01-06
2004-08-10
Nguyen, Patricia (Department: 2817)
Amplifiers
With plural amplifier channels
Redundant amplifier circuits
C330S144000
Reexamination Certificate
active
06774717
ABSTRACT:
TECHNICAL FIELD
The present invention relates to a composite amplifier of the type that includes a main power amplifier and an auxiliary power amplifier, which are connected to a load over a Doherty output network. The invention also relates to a transmitter including such an amplifier and methods for operating such an amplifier and transmitter, respectively.
BACKGROUND
In cellular base stations, satellite communications and other communications and broadcast systems, many radio frequency (RF) carriers, spread over a large bandwidth, are amplified simultaneously in the same power amplifier. For the power amplifier this has the effect that the instantaneous transmit power will vary very widely and very rapidly. This is because the sum of many independent RF carriers (i.e. a multi-carrier signal) tends to have a large peak-to-average power ratio. It also tends to have a similar amplitude distribution as bandpass filtered Gaussian noise, which has a Rayleigh distribution.
A main difficulty in a power amplifier is efficiency. A conventional class B power amplifier exhibits maximum DC to RF power conversion efficiency when it delivers its peak power to the load. Since the quasi-Rayleigh distribution of amplitudes in the summed transmit signal implies a large difference between the average power and the peak power, the overall efficiency when amplifying such a signal in a conventional class B amplifier is very low. For a quasi-Rayleigh distributed signal with a 10 dB peak-to-average power ratio, the efficiency of an ideal class B amplifier is only 28%, see [1].
One way of increasing the efficiently of an RF power amplifier is to use the Doherty principle [1, 2, 3]. The Doherty amplifier uses in its basic form two amplifier stages, a main and an auxiliary amplifier (also called carrier and peaking amplifier, respectively). The load is connected to the auxiliary amplifier, and the main amplifier is connected to the load through an impedance-inverter, usually a quarter wavelength transmission line or an equivalent lumped network.
At low output levels only the main amplifier is active, and the auxiliary amplifier is shut off. In this region, the main amplifier sees a higher (transformed) load impedance than the impedance at peak power, which increases its efficiency in this region. When the output level climbs over the so-called transition point (usually at half the maximum output voltage), the auxiliary amplifier becomes active, driving current into the load. Through the impedance-inverting action of the quarter wavelength transmission line, this decreases the effective impedance at the output of the main amplifier, such that the main amplifier is kept at a constant (peak) voltage above the transition point. Th result is a substantially linear output to input power relationship, with a significantly higher efficiently than a traditional amplifier.
The transition point can be shifted, so that the auxiliary amplifier kicks in a a lower or higher power level. This can be used for increasing efficiency for a specific type of signal or a specific amplitude distribution. When the transition point is shifted, the power division between the amplifier at peak power is shifted accordingly, and the average power loss in each amplifier also changes. The latter effect also depends on the specific amplitude distribution.
An important feature of Doherty amplifiers is that they are inherently band-limited, since the impedance inverting network only provides 90 degrees of phase shift at a single frequency. This has the effect that the Doherty principle, i.e. the suppression of RF voltage rise at the main amplifier above a certain transition point, works poorly (inefficiently) outside a limited frequency band. This is because the suppression requires the voltages from the main amplifier and the auxiliary amplifier to be in perfect anti-phase at the output of the main amplifier. Since the quarter-wave network is really only a quarter wave (90 degrees) phase shift at the center frequency, and shorter or longer at frequencies below and above the center frequency, respectively, this requirement gets more and more violated the further one gets from the center frequency of the impedance inverter.
SUMMARY
An object of the present invention is to enhance efficiency of a composite amplifier provided with a Doherty output network. Preferably the efficiency is increased over a broader frequency band.
The stated object is achieved in accordance with the attached claims.
Briefly, the present invention enhances efficiency by separately pre-filtering the input signals to the power amplifiers in such a way that the signals meeting at the output of the main amplifier have the same frequency dependence. Preferably this is done by using filters representing the inverses of the frequency dependent power amplifier impedance and transimpedance, thereby flattening the frequency response of the composite amplifier over a broader frequency band.
REFERENCES:
patent: 5880633 (1999-03-01), Leizerovich et al.
patent: 6008694 (1999-12-01), El-Sharawy
patent: 6085074 (2000-07-01), Cygan
patent: 6097252 (2000-08-01), Sigmon et al.
patent: 6128478 (2000-10-01), Kim
patent: 6396341 (2002-05-01), Pehlke
patent: 6639464 (2003-10-01), Hellberg
Nguyen Patricia
Nixon & Vanderhye P.C.
Telefonaktiebolaget LM Ericsson (publ)
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