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Claims  |
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What is claimed:
1. For use with an RF power amplifier having an RF carrier input port to
which an RF input signal is coupled, an RF output port from which an
amplified RF output signal is derived, and an RF carrier cancellation
combiner having a first input coupled to said RF input port and a second
input coupled to said RF output port, and being operative to produce an RF
error signal through said RF amplifier between said RF input port and said
RF output port, an arrangement for reducing a DC component of a
correlation signal used for control of RF signal alignment to effect RF
carrier cancellation by said RF carrier cancellation combiner comprising:
an RF carrier modification circuit coupled between said RF input port and
an input to said RF power amplifier, and being operative to modify said RF
carrier input signal to said RF power amplifier;
a signal combiner which combines said RF carrier input signal with said RF
error signal, producing a control signal, which is used to control said RF
carrier modification circuit and thereby modify said signal flow path
through said RF power amplifier so as to align RF signals prior to
cancellation; and
a signal processor which measures DC distortion associated with said signal
combiner, and controllably removes said DC distortion from said control
signal, so that control of said RF carrier modification circuit and
thereby modification of said signal flow path through said RF amplifier is
performed exclusive of said DC distortion associated with said signal
combiner.
2. An arrangement according to claim 1, wherein said signal processor is
operative to measure said DC distortion by controllably decoupling said RF
carrier input signal and said RF error signal from said signal combiner.
3. An arrangement according to claim 1, wherein said signal combiner
comprises a correlator circuit, which correlates said RF carrier input
signal with said RF error signal to produce said control signal, and
wherein said signal processor is operative to measure said DC distortion
associated with the operation of said correlator circuit and to
controllably remove said DC distortion from said control signal.
4. An arrangement according to claim 3, wherein said correlator circuit
comprises a wideband multiplier having an operational bandwidth that
contains the variation bandwidth of said RF carrier input signal.
5. An arrangement according to claim 3, wherein said RF carrier
modification circuit comprises a vector modulator coupled in an RF carrier
signal flow path between said RF carrier input port and said RF power
amplifier, and being responsive to said control signal to modify said RF
input signal so as to align RF signals prior to cancellation thereof.
6. An arrangement according to claim 5, wherein said correlator circuit
comprises wideband multiplier circuitry having an operational bandwidth
that contains the variation bandwidth of said RF carried input signal.
7. An arrangement according to claim 6, wherein said wideband multiplier
circuitry is operative to generate a first product signal representative
of the product of in-phase versions of said RF carrier input signal and
said RF error signal, and a second product signal representative of the
product of quadrature versions of said RF carrier input signal and said RF
error signal, and an integrator which is operative to integrate said first
and second product signals, producing respective gain and phase adjustment
signals for controlling the operation of said vector modulator, and
wherein said signal processor comprises a DC offset compensator coupled
with said wideband multiplier circuitry and being operative to remove DC
offsets introduced into said first and second product signals by said
wideband multiplier circuitry.
8. An arrangement according to claim 3, wherein said signal processor is
operative to measure said DC distortion associated with said correlator
circuit, while controllably decoupling said RF error signal and said RF
carrier input signal from said correlator circuit, and also applying a
previous value of said control signal to said RF carrier modification
circuit.
9. An arrangement according to claim 1, further including a feedforward
error correction circuit which is coupled in an RF signal flow path
downstream of said RF amplifier and is operative to cancel distortion of
amplified RF output signal by an equal said amplitude, anti-phase RF error
signal.
10. For use with an RF power amplifier having an RF input port to which an
RF carrier input signal is coupled, an RF output port from which an
amplified RF output signal is derived, a vector modulator coupled between
said RF input port and an input to said RF power amplifier, and an RF
carrier cancellation combiner having a first input coupled to said RF
input port and a second input coupled to said RF output port, and being
operative to produce an RF error signal representative of RF distortion of
a signal flow path through said RF amplifier between said RF input port
and said RF output port, and wherein said RF carrier input signal is
combined in a signal processing circuit with said RF error signal
producing a control signal which adjusts the operation of said vector
modulator, so as to minimize said RF carrier input signal in said RF error
signal produced by said RF carrier cancellation combiner, a method of
minimizing a DC component of said RF error signal comprising the steps of:
(a) measuring DC distortion associated with said signal processing circuit;
and
(b) removing said DC distortion from said control signal, so that
adjustment of said vector modulator is carried out exclusive of error
associated with said signal processing circuit.
11. A method according to claim 10, wherein said signal processing circuit
comprises a correlator circuit which correlates said RF carrier input
signal with said RF error signal to produce said control signal, and
wherein step (a) comprises measuring DC distortion associated with the
operation of said correlator circuit.
12. A method according to claim 11, wherein step (a) comprises measuring
said DC distortion associated with said correlator circuit, while
controllably decoupling said RF carrier input signal and said RF error
signal from said correlator circuit, and also applying a previous value of
said control signal to said vector modulator.
13. A method according to claim 12, wherein said correlator circuit
comprises a wideband multiplier having an operational bandwidth that
contains the variation bandwidth of said RF carrier input signal.
14. A method according to claim 13, wherein said wideband multiplier
circuitry is operative to generate a first product signal representative
of the product of in-phase versions of said RF carrier input signal and
said RF error signal, and a second product signal representative of the
product of quadrature versions of said RF carrier input signal and said RF
error signal, and an integrator which is operative to integrate said first
and second product signals, producing respective gain and phase adjustment
signals for controlling the operation of said vector modulator, and
wherein said signal processing circuit comprises a DC voltage offset
compensator coupled with said wideband multiplier and is operative to
remove DC voltage offsets introduced into said first and second product
signals by said wideband multiplier.
15. A method according to claim 11, further including a feedforward error
correction circuit which is coupled in an RF signal flow path downstream
of said RF amplifier and is operative to cancel distortion of said
amplified RF output signal by an equal amplitude, anti-phase RF error
signal. |
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Claims |
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Description |
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FIELD OF THE INVENTION
The present invention relates in general to communication systems, and is
particularly directed to the use of an auto-calibrating RF correlator to
control an RF distortion extractor, so that the RF carrier is canceled,
leaving only the RF error at the output, which can be used to cancel the
distortion of a microwave/RF power amplifier. The RF correlator is
operative to derive a control signal for a vector modulator used to align
the RF signals prior to being canceled; also an unwanted DC voltage
associated with the operation of the correlator is measured and removed
from the control signal.
BACKGROUND OF THE INVENTION
Communication service providers are subject to very strict bandwidth usage
spectrum constraints, such as technically mandated specifications and
regulations imposed by the Federal Communications Commission (FCC), which
currently requires that sideband spillage, namely the amount of energy
spillover outside a licensed band of interest, be sharply attenuated
(e.g., on the order of 60 dB). While such specifications are readily
achievable for traditional forms of modulation such as single-carrier
frequency modulation (FM), they are difficult to achieve using more
contemporary, digitally based modulation formats, such as QPSK modulation.
Keeping the sidebands attenuated sufficiently to meet industry or
regulatory-based requirements using such modulation techniques mandates
the use of very linear signal processing systems and components. Although
linear components can be implemented at a reasonable cost at relatively
low bandwidths (baseband) used in telephone networks, linearizing such
components, especially RF power amplifiers, becomes a very costly
exercise.
RF power amplifiers are inherently non-linear devices, and generate
unwanted intermodulation products (or `intermods`), which manifest
themselves as spurious signals in the amplified RF output signal, separate
and distinct from the RF input signal. This intermodulation distortion is
also referred to as spectral regrowth, or spreading of a compact spectrum
into spectral regions that do not appear in the RF input signal. The
distortion introduced by an RF amplifier causes the phase and amplitude of
its amplified output signal to depart from the respective phase and
amplitude of the input signal, and may be considered as an incidental (and
undesired) AM-to-AM and/or AM-to-PM of the input signal.
One brute force technique for linearizing an RF power amplifier is to build
the amplifier as large, high power device and then operate the amplifier
at a low power level that is only a small percentage of its rated output
power, where the RF amplifier's transfer function is relatively linear.
The obvious drawback to this approach is the inefficiency, as well as the
high cost and large size. Other prior art attempts to account for RF
amplifier degradation have included coupling a `pre-processing` correction
loop in the path of the amplifier's input signal, and/or coupling a
`post-processing`, feed-forward correction loop with the amplifier's
output signal.
The purpose of a preprocessing correction loop is modify the RF amplifier's
input signal path. Ideally the control signal causes the signal path
adjustment mechanism to produce a signal control characteristic that has
been predetermined to be the inverse of the distortion expected at the
output of the RF amplifier. As a consequence, when subjected to the
transfer function of the RF amplifier, it will optimally effectively
cancel the amplifier's anticipated distortion behavior. The mechanism may
be made adaptive by extracting the RF error signal component in the output
of the RF amplifier and adjusting the control signal in accordance with
the such extracted error behavior of the RF amplifier during real time
operation, so as to effectively continuously minimize distortion in the
amplifier's output.
A post-processing, feed-forward correction loop, on the other hand, serves
to extract the amount of RF error (distortion) present in the RF
amplifier's output signal, amplify that extracted distortion signal to the
proper level, and then reinject the amplified RF error signal at equal
amplitude and opposite phase back into a downstream output path of the RF
amplifier, such that (ideally) the amplifier distortion is effectively
canceled. To extract this error, the output of the RF amplifier is
combined in an RF cancellation combiner with the RF input signal (which is
used as a reference), so that, ideally, all carrier components (which give
rise to the baseband intermods referenced above) are effectively canceled,
leaving only the RF error.
In the past, mechanisms to minimize such RF carrier components have
involved the use of analog phase and amplitude adjustment circuits, which
attempt to align the phase and amplitude of the two RF signals, using
differential amplifier and phase detector circuitry to control phase
shifter and attenuator elements installed in one or both RF signal paths.
A major shortcoming of this conventional approach is the fact that DC
offsets of the detector circuits tend to dominate when the energy in the
RF signals becomes relatively low, causing the carriers to become
misaligned. While this misalignment is not of practical significance for
low energy signals, it becomes a major problem when a large RF pulse is
received, and the loop does not have sufficient time to respond. When
misaligned high energy content RF carriers are applied to the combiner,
unwanted RF carrier energy will contribute substantially to the content of
the RF error signal, and introduce distortion in the feed-forward loop by
overdriving the error amplifier. Also, if the amount of RF carrier energy
resulting from misalignment of the two signals is large, the resulting RF
error signal can actually damage the error amplifier feeding the
downstream feed-forward injection loop.
SUMMARY OF THE INVENTION
In accordance with the present invention, this problem is effectively
eliminated by an RF signal-canceling, auto-calibrated correlator that
correlates the RF reference and output signal of the RF cancellation
combiner and produces phase and gain control signals for a vector
modulator installed in the path of the non-linear RF power amplifier. The
vector modulator has respective gain and phase control ports, to which
correlator-based amplitude and phase control signals generated by a
digital signal processor are supplied. These control signals cause the
vector modulator to maximize cancellation of RF carrier signals at the
output of the RF carrier cancellation combiner, so as to leave only RF
error.
More particularly, in order to extract the RF error signal, the RF
amplifier output is coupled to a carrier cancellation combiner, which is
also coupled to receive a delayed version of the RF input signal as a
reference signal. The output of the carrier cancellation combiner is
coupled to an RF error signal path to a downstream correlator. The
reference signal is coupled to a reference signal path of the correlator.
The reference and RF error signals are downconverted to an IF frequency
range that falls within the bandwidth of a pair of four-quadrant
multipliers.
The downconverted outputs of the mixers are filtered in bandpass filters
and coupled through respective amplifiers to in-phase and quadrature-phase
signal splitters. The in-phase signal splitter has in-phase outputs, which
are coupled to first inputs of respective amplitude and phase multipliers.
The quadrature-phase signal splitter has a first in-phase output coupled
to a second input of the amplitude multiplier and a second
quadrature-phase output coupled to a second input of the phase multiplier.
The products of the amplitude and phase multipliers are low pass-filtered,
digitized and coupled to a digital signal processor, where they are
integrated into respective amplitude and phase correlation values. These
respective amplitude and phase correlation values are then mapped via a
look-up table into amplitude and phase correction codes, which are
converted into analog amplitude and phase signals, for controlling the
operation of the vector modulator.
In addition to performing integration of each of the amplitude and phase
signal paths from the amplitude and phase multipliers, the correlator's
digital signal processor controllably measures and then removes any DC
offsets that are introduced by the analog signal processing components of
respective upstream multiplier circuitry paths. To measure DC offset, the
processor is programmed to periodically supply a control signal, which
decouples (turns off) the supply voltage to the local oscillator driving
the IF downconversion circuit, and thereby eliminates IF signals from the
reference and RF error integration signal paths. Prior to removing the
supply voltage for the local oscillator, the processor stores the most
recent integration codes, which are then used to freeze the amplitude and
phase control signals to the vector modulator during the autocalibration
mode.
During autocalibration (DC offset measurement) mode, the processor measures
any DC offset voltages that are introduced by the analog components of the
correlation circuitry. Since these DC offset voltages are measured
independently of the RF signals being amplified by the RF amplifier, they
represent only unwanted error contributions of the correlation processing
components, which must be removed, in order that they will not contribute
to amplitude and phase control inputs to the vector modulator. For this
purpose, the digital signal processor stores the measured DC offset
voltage codes, which are then subtracted from the amplitude and phase
product signals during the RF signal processing mode of operation.
BRIEF DESCRIPTION OF THE DRAWINGS
The FIG. 1 diagrammatically illustrates an embodiment of the wideband,
auto-calibrating RF correlator in accordance with the invention, as
installed in an RF power amplifier vector modulator loop and coupled with
an RF error extraction loop for feedforward error correction.
DETAILED DESCRIPTION
Before describing in detail the new and improved wideband, auto-calibrating
correlator that may be employed in an RF power amplifier vector modulator
control loop in accordance with the present invention, it should be
observed that the invention resides primarily in what is effectively a
prescribed arrangement of conventional communication circuits and
associated digital signal processing components and attendant supervisory
control circuitry, that controls the operations of such circuits and
components. Consequently, the configuration of such circuits components
and the manner in which they are interfaced with other communication
system equipment have, for the most part, been illustrated in the drawings
by readily understandable block diagrams, which show only those specific
details that are pertinent to the present invention, so as not to obscure
the disclosure with details which will be readily apparent to those
skilled in the art having the benefit of the description herein. Thus, the
block diagram illustrations are primarily intended to show the major
components of the system in a convenient functional grouping, whereby the
present invention may be more readily understood.
The FIG. 1 diagrammatically illustrates a non-linear RF power amplifier 10
employing a vector modulator control loop 20 and an RF error extraction
loop 30 for a downstream feedforward error correction mechanism including
a reinjection error amplifier 40, which employs the wideband,
auto-calibrating RF correlator of the present invention. As shown therein
the RF amplifier 10 has an input port 11, to which an RF input signal to
be amplified is applied. RF input port 11 is coupled to a vector modulator
12, the output of which is coupled to the non-linear RF amplifier 10.
Vector modulator has gain and phase control input ports 14 and 16, to
which amplitude and phase control signals conveyed over links 13 and 15,
respectively, generated by a digital signal processor 100, are supplied.
Under the control of signals applied to ports 14 and 16, vector modulator
12 modifies the RF input signal in a manner that effectively maximizes
cancellation of RF carriers by an RF carrier cancellation combiner 23, and
thereby leaving only RF error.
In order to extract the RF error signal component in the output of the RF
amplifier 10 for adjusting the amplitude and phase control signals on
links 13 and 15, and for the downstream feed-forward correction mechanism
40, the output of the RF amplifier 10 is coupled via a directional coupler
17 to a first input 21 of an RF carrier cancellation combiner 23, a second
input 22 of which is coupled via a delay line 25 and a directional coupler
26 to the RF input port 11. As a non-limiting example, RF carrier
cancellation combiner 23 may be implemented as a Wilkinson
splitter/combiner. The output 24 of the (Wilkinson) carrier cancellation
combiner 23 provides an RF error signal as the equal amplitude,
out-of-phase summation of an RF reference signal, corresponding to a
delayed version of the RF input signal at input port 11 (using delay
circuit 25 for signal alignment), and the extracted amplified RF output
signal via directional coupler 17, containing whatever uncorrected RF
error has been introduced by the non-linear RF amplifier 10.
The RF reference signal component at the input 22 of the Wilkinson carrier
cancellation combiner 23 is extracted via a directional coupler 31 and is
coupled thereby to a first, reference signal path 32. The RF error signal
component at the output 24 of the Wilkinson carrier cancellation combiner
23 is extracted via a directional coupler 41 and coupled thereby to a
second, error signal path 42. The error signal in path 42 is amplified by
amplifier 43 and coupled to a first input port 71 of mixer 70. The
reference signal is amplified by an amplifier 33 and coupled to a first
input port 51 of a mixer 50. A local oscillator is coupled to the second
input port 52 of mixer 50 via a phase adjustment circuit 54 from a first
output port 62 of a Wilkinson splitter 60. The local oscillator is also
coupled via second output port 63 of splitter 60 to a second input port 72
of mixer 70.
The phase adjustment circuit 54 is used to ensure that inputs 52, 72 to
respective mixers 50 and 70 are aligned, so as to provide amplitude and
phase detection in multipliers 80 and 90. Wilkinson splitter 60 has its
input port 61 coupled via an amplifier 65 to the output of a voltage
controlled oscillator (VCO) 67, the supply voltage for which is provided
via a switch 78 from a bias voltage supply 68. As will be described,
during autocalibration (DC offset measurement) mode, switch 78 is operated
so as to effectively decouple the RF signals in paths 32 and 42 from
downstream correlation circuitry, so that parasitic DC offsets introduced
by the correlation circuitry may be measured independently of the DC
offsets generated by the RF signals being processed, so as not to
introduce inaccuracies in the measurement of RF correlation between paths
32 and 42.
Mixers 50 and 70 serve to downconvert the RF signals in paths 32 and 42 to
a frequency range (IF bandwidth) that falls within the bandwidth (e.g., on
the order of 450 MHz, as a non-limiting example) of a pair of
four-quadrant multipliers 80 and 90 of downstream correlator circuitry.
(If the multipliers are capable of operation at the bandwidth of the
carrier of the RF input signal, downconversion circuitry is unnecessary.)
The outputs of the mixers 50 and 70 are filtered in bandpass filters 56
and 76, respectively, and coupled through respective IF amplifiers 82 and
84 to in-phase and quadrature-phase signal splitters 86 and 88.
In-phase signal splitter 86 may comprise a Wilkinson splitter having first
and second in-phase outputs 92 and 94, which are coupled to first inputs
81 and 91 of respective multipliers 80 and 90. Quadrature-phase signal
splitter 88 may comprise a quadrature hybrid having a first in-phase input
96 coupled between a zero degree port of the coupler and a second input 83
of multiplier 80. A second quadrature-phase input 98 is coupled to a
second input 93 of multiplier 90. With these in-phase connections at 81
and 83, multiplier 80 effectively functions as an amplitude detector,
whereas with the quadrature connections at 91 and 93, multiplier 90
functions as a phase detector.
The product output of amplitude multiplier 80 is filtered in a low pass
filter 120 and then digitized via an analog-to-digital converter (ADC)
130. Similarly, the product output of phase multiplier 90 is filtered in a
low pass filter 140 and then digitized via an ADC 150. The digital outputs
of ADCs 130 and 150 are supplied to the digital signal processor (DSP)
100, wherein they are integrated into respective amplitude and phase
correlation values, as diagrammatically illustrated by respective
integration signal processing routines 101 and 102 executed within DSP
100.
These respective amplitude and phase integration values are then mapped by
means of a look-up table 103 into amplitude and phase correction codes.
Digital-to-analog converters (DACs) 160 and 170 convert these codes into
amplitude and phase control signals, which are filtered in low pass
filters 165 and 175, and coupled over lines 13 and 15 to respective
amplitude and phase control ports 14 and 16 of vector modulator 12, for
controlling its operation, as described above.
In addition to performing the integration of the phase and amplitude
detector outputs produced from multipliers 80 and 90, the DSP 100 is
operative to controllably measure and then remove any DC offsets that are
introduced by the analog signal processing components of respective
upstream multiplier circuitry paths 32 and 42. For this purpose, the DSP
100 is programmed to periodically supply a control signal over switch
control link 77, which decouples (turns off) the supply voltage to VCO 67,
and thus decouples the IF signals from paths 32 and 42. Prior to supplying
this control signal over switch control link 77 to remove the
downconversion supply voltage for VCO 67, the DSP 100 stores the most
recent integration codes, so that they may continue to be supplied to
look-up table 103 for providing amplitude and phase control signals for
vector modulator 12, during autocalibration.
In the autocalibration (DC offset measurement) mode of operation, what is
measured by DSP 100 at the outputs of ADCs 130 and 150 are any parasitic
DC offset voltages introduced by non-ideal characteristics of analog
components of the correlation circuitry. These DC offset voltages do not
correspond to a correlation between the RF signals in paths 32 and 42,
they represent only unwanted error contributions of the correlation
processing components. They must be removed, in order that such components
will not erroneously influence the RF alignment output of carriers at the
cancellation combiner 23. For this purpose, the DSP 100 stores the
measured DC offset voltage codes in respective buffers, so that they be
subtracted from the amplitude and phase product signals as digitized by
ADCs 130 and 150 during the RF signal processing mode of operation (as
diagrammatically represented by subtraction operators 135 and 155 to which
the DC voltage offset codes 176 are supplied.
As will be appreciated from the foregoing description, the problem of
unwanted DC offsets in IF error detection/correction components used in
the error extraction circuitry, which results in residual carrier power in
the RF error signal, are effectively obviated in accordance with the
present invention, by means of an offset-canceling, auto-calibrated
correlator. The correlator is coupled to receive the RF reference and
error signals of an RF carrier cancellation combiner and produces DC
offset-compensated phase and gain control signals for a vector modulator
installed in the RF power amplifier's input signal path.
It should be noted by that the RF signal-canceling, auto-calibrated
correlator of the invention may be employed in any application where a
reference signal is to be removed from a signal composed of that reference
signal plus an additional signal (typically referred to as an error
signal). A non-limiting example may involve deriving an RF error signal
for use in polar envelope correction, such as described in co-pending U.S.
patent application Ser. No. 08/594,089, filed Jan. 30, 1997, entitled
"Polar Envelope Correction Mechanism for Enhancing Linearity of
RF/Microwave Power Amplifier," by J. Eisenberg et al, now U.S. Pat. No.
5,742,201, assigned to the assignee of the present application and the
disclosure of which is incorporated herein. Another non-limiting example
involves an adaptive predistortion scheme, such as a table-based complex
gain predistorter or work function-based predistorter, which may be of the
type described in co-pending U.S. patent application Ser. No. 08/626,239,
filed Mar. 29, 1996, entitled "Adaptive Compensation of RF Amplifier
Distortion by Injecting Predistortion Signal Derived from Respectively
Different Functions of Input Signal Amplitude," by D. Belcher et al,
assigned to the assignee of the present application and the disclosure of
which is incorporated herein. These schemes may benefit from the present
invention, in the course of adapting the parameters of the modulation
input to the RF amplifier, so as to minimize the error measured at the
output of the error extractor/digital correlator.
While we have shown and described an embodiment in accordance with the
present invention, it is to be understood that the same is not limited
thereto but is susceptible to numerous changes and modifications as are
known to a person skilled in the art, and we therefore do not wish to be
limited to the details shown and described herein, but intend to cover all
such changes and modifications as are obvious to one of ordinary skill in
the art.
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