1. Field of the Invention
The present invention relates to electrical and electronic circuits and systems. More specifically, the present invention relates to power amplifiers for communications systems and predistortion linearizers used in connection therewith.
2. Description of the Related Art
Power amplifiers are used in a variety of communications applications. Power amplifiers not only typically exhibit non-linear distortion but also possess memory effects. While non-linear distortion follows the power amplifier characteristics, the memory effects depend on signal characteristics (e.g., signal bandwidth and also transmit power level.)
Conventional techniques use Lookup Table (LUT) based methods to generate inverse transfer functions in both amplitude and phase to correct for non-linearity in the output of power amplifiers. However these techniques do not effectively handle memory effects and thus provide very moderate linearization improvements.
More importantly, power amplifiers are generally expensive and consume much power. Multiple carrier applications, such as cellular telephone base stations, are particularly problematic inasmuch as a single amplifier is typically used with each carrier signal. Conventional approaches combine separate power amplifiers transmit multiple carrier signals. However, this approach is also expensive and power intensive.
Further, for maximum efficiency, each power amplifier must be driven close to its saturation point. However, as the power level is increased, intermodulation distortion (IMD) levels increase. Hence, the output power level must be ‘backed-off’ to maintain acceptable ACPR (adjacent channel power ratio) levels. Unfortunately, the required power back-off to meet government (e.g. FCC) specified IMD levels limits the efficiency of the power amplifier to relatively low levels and does not offer a solution that is sufficiently cost effective for certain current requirements.
An alternative approach is to use a predistortion linearizer. This technique allows power amplifiers to operate with better power efficiency, while at the same time maintaining acceptable IMD levels. However, conventional digital predistortion linearizers have been shown to reduce the IM levels by only about 10-13 dB for signal bandwidths in excess of 20 MHz.
Hence, a need remains in the art for an efficient, low cost system or method for amplifying multiple carrier signals while maintaining low intermodulation distortion levels.
The need in the art is addressed by the linearizer and method of the present invention. In a most general embodiment, the inventive linearizer includes a characterizer coupled to an input to and an output from said circuit for generating a set of coefficients and a predistortion engine responsive to said coefficients for predistorting a signal input to said circuit such that said circuit generates a linearized output in response thereto.
As a result, in the best mode, the weights used in the predistortion linearization engine can be computed by solving a matrix equation HW=S for W, where W is a vector of the weights, S is a vector of predistortion linearization engine outputs, and H is a matrix of PA return path inputs.
Illustrative embodiments and exemplary applications will now be described with reference to the accompanying drawings to disclose the advantageous teachings of the present invention.
While the present invention is described herein with reference to illustrative embodiments for particular applications, it should be understood that the invention is not limited thereto. Those having ordinary skill in the art and access to the teachings provided herein will recognize additional modifications, applications, and embodiments within the scope thereof and additional fields in which the present invention would be of significant utility.
In accordance with the present teachings, linearization of the performance of the transmitter 12 is effected by a DPD engine 100. The DPD engine performs an inverse filtering of the transmitter 12 using coefficients supplied by a characterizer 30 in a feedback path thereof. As discussed more fully below, the characterizer computes the coefficients of a feedback compensation filter (i.e., using the receive path equalization process) and solves the normal equation during normal operation to compute the weights of the DPD block that are used to provide predistortion. Those skilled in the art will appreciate that the digital processing may be implemented in software using a general purpose microprocessor or other suitable arrangement.
In operation, a complex in-phase and quadrature (I-Q) input signal x(t) is sent to the DPD engine 100 and passes through a set of filters. As discussed more fully below, these filters are non-linear filters with programmable complex weights provided by a characterizer 30. The output of the DPD engine 100 is a predistorted I-Q sample stream.
The transmitter 12 converts the I-Q samples of the DPD output into an RF signal at the desired frequency and power level for transmission. The outputs from the DPD engine 100 are processed by the digital upconverter 14, which converts the I-Q signal into IF digital samples. The IF digital samples are then converted to an analog IF signal by the DAC 16 and are then frequency shifted by the RF upconverter 18 to produce an RF signal. This signal is then amplified using the power amplifier (PA). The linearized output of the transmitter 12 at the desired power level is then sent to the transmit antenna 22.
In accordance with the present teachings, this linearized output is achieved by simultaneously capturing data after the DPD block and at the feedback input in the chraracterizer 30. The data is correlated/shifted, scaled, combined with noise, and then solved for the predistortion coefficients which are averaged with the previously computed weights and then applied on the transmit data in the DPD block. This data capture and weight computation is then repeated continuously. Sampling of the PA output is effected by coupling off a signal from the PA output with attenuation of the signal on the line from the PA output to a feedback circuit 24 that includes a down converter 26 and an analog to digital converter (ADC) 28. The down converter 26 converts the signal to intermediate frequency (IF). The ADC 28 converts the IF signal to digital form and feeds the digital samples to the characterizer 30.
The characterizer 30 computes the coefficients of the inverse filter for the transmitter 12 such that the PA output signal z(t) is linearized with respect to the input signal x(t). As discussed more fully below, the samples from the receive feedback path into the characterizer first pass-through a feedback compensation filter whose coefficients were computed by the characterizer to remove the distortion generated in the feedback section, after which the DPD output and the compensated signal are then time aligned and scaled (scaling is not shown in the invention but is a crucial step although a trivial one since the scaling is fixed). Then a DPD coefficient estimator solves a set of normal equations producing weights. Finally these weights are averaged to produce the coefficients for the DPD engine. The more detailed description of these blocks follows below.
From equation 4 of A Robust Digital Baseband Predistorter Constructed Using Memory Polynomials, by Lei Ding, G. Tong Zhou, Zhengriang Ma, Dennis R. Morgan, J. Stevenson Kenney, Jaehyeong Kim, Charles R. Giardina. C. Manuscript submitted to IEEE Trans. On Communication, Mar. 16, 2002, the PA can be modeled as
where x is the input to the PA, akq=ckqejφkq. Similarly, if we want to predistort the signal, we implement a structure equivalent to the PA model,
where wkq=akqejφkq, and x(t) and y(t) are DPD input and output respectively. A practitioner may use only the odd k terms in the first summation since the even terms correspond to out-of-band harmonics which are not of interest in the illustrative application. However, performance can be enhanced by using these terms. Equation 2 can be realized with a structure based on the following manipulation thereof:
The inner summation in parenthesis can be viewed as a filter for a fixed ‘k’. This feature is exploited in the hardware implementation.
The processing sequence of the data input to the DPD is as follows:
Select the parameters K (K is odd) and Q for the DPD engine.
1. Compute the signal amplitude |x(n)|, and subsequently compute the powers |x(n)|2, |x(n)|3, |x(n)|4, . . . |x(n)|K-1.
2. The signals |x(n)|k, k=1, 2, 3, . . . , K−1 are sent to a tapped delay line to generate |x(n)|k, k=1, 2, 3, . . . , K−1, q=0, 1, . . . , Q.
3. The signals |x(n-q)|k are multiplied with the coefficients wkq and the results are summed to produce the combined weights:
4. The combined weights are then used as coefficients for filtering the signal x(t) to produce the signal:
The coefficients, wkq, used in the data path implementation of the DPD engine are generated by the characterizer 30 as discussed more fully below and illustrated in
As illustrated in
The impulse responses are averaged to improve the signal-to-noise ratio to produce the mean impulse response as:
c(t)=[c1 . . . ck . . . cN] [7]
As illustrated in
C(f)=FFT(c(t))=FFT([c1 c2 c3 . . . cN0 0 0]) [8]
The spectral response of the PA Feedback path filter is then computed as follows:
D(f)=1/C(f) [9]
and the inverse FFT is used to determine the coefficients for the PA Feedback compensation filter d(t):
d(t)=IFFT(D(f)) [10]
It is noted that this process is only performed only during system initialization, or per request.
The feedback compensation filter coefficients output by the estimator 36 are input to a feedback correction filter 38. The feedback correction filter 38 is a finite impulse response filter with N taps. The coefficients of this filter are extracted as set forth above. This filter removes any distortion caused by the RF down converter 26 and ADC 28.
The output of the PA feedback correction filter 38 is an IF signal and it is necessary to convert it into a baseband signal in I-Q form for subsequent signal processing.
The shifters 56 and 58 placed between the up-samplers 52, 54 and down-samplers 60, 62 refine the time t2 during the time synchronization. After the synchronization, this time shift t2 is kept constant.
As mentioned above, the time synchronization is required to align the DPD output signal and the output of the PA Feedback Correction Filter. The time offset error is deterministic and is due to the latency delay in the transmit and receive paths. After synchronization, the time shift will maintain a constant value since the time drift is insignificant.
The correlation process to align the signal is as follows:
Coarse Correlation
a—First, note that there are multiple possible values of n2 in
b—Search for the shift l that yields maximum correlation R(l). n1=lmax is the coarse shift; and
c—Output the time shift nI.
Since the correlation R(l) has the sampling rate of fs, the time correlation is accurate to ±1/(2fs)
Fine Correlation
a—After the coarse time sync, compute correlation between shifted input y(n−n1) and output r(n,n2) signals over n2 {−2, −1, 0, 1, 2} sample in time shift where n2 functions as shown in
b—Search for the shift g that yields maximum correlation R(g). n2=gmax is the fine shift;
d—Output the time shift n2; and
e—Since the correlation R(g) has the sampling rate of Qfs, the time correlation is accurate to ±1/(2Qfs)
DPD Coefficients Estimator
After the signals s(n) and r(n) are aligned in time by a time shift estimator 42 and time shifters 56, 58 and 64, the DPD weights are estimated by a DPD coefficients estimator 70. The objective is to solve the DPD equation as defined in [3]:
where s(n) is derived from the DPD output and r(n) is derived from the PA Feedback output.
High Pass Noise Generation:
Because both the signal s(n) and r(n) have narrow bandwidths relative to the DPD sampling frequency, the estimation of the weights may exhibit undesirable behavior at high frequencies where little signal content exists. To prevent this from happening, either a properly scaled all-pass or high-pass signal (pre-stored in a RAM 72 or generated using a random noise generator such as a pn linear feedback shift register), is added to both signals s(n) and r(n) at steps 74 and 76. This added all-pass or high-pass signal ensures bounded, stable weights and also greatly improves weight averaging.
The new signals with the added signal are expressed as:
S2=S1+N [14]
R2=R1+N [15]
where S1 and R1 are the processed DPD samples and the processed IF to BB converter output, respectively.
Soft Factor:
When operating near saturation of the PA, the peak amplitude of the DPD output s(n) will increase as the DPD loop progresses, but the amplitude of the ADC output will be remain saturated due to PA compression. This is always the case for a PA with an input versus output amplitude profile which curves very flat very quickly, i.e. it becomes highly saturated, and the user has selected a low K and small Q which will not provide an accurate solution for W. A perfect PA has a linear transfer function, output=100*input, i.e., a straight line. A real PA will start to tail off from linear as the input power is increased eventually hitting a maximum output power no matter how much the input power is increased (it becomes a flat line at this time), so the transfer function ends up looking like a hockey stick. The soft factor is used to remove the samples s(n) with very strong amplitude from consideration in solving for the weights in equation [5]. Let
S=[s(0)s(1)s(2)s(3) . . . s(U−1)]T [16]
be the processed DPD signal samples, the soft factor vector is expressed as:
G=[g(0)g(1)g(2)g(3) . . . g(U−1)]T [17]
where
g=1 for |s1|<T2=0 otherwise
T2 is the user chosen threshold that controls how large the samples are that will be processed. This soft factor vector will be used to help solve for the weights with high accuracy.
Sampling Shift n3:
The distribution of the weight W between [0-Q] impacts the accuracy of the DPD engine. In order to maximize the accuracy of the DPD=PAK−1 estimation process, it is necessary to place the weight distribution correctly, by shifting the delay n3 between from 0 to Q and checking for the residue error E as defined in Equation 26. The output of the sample Shift is expressed as:
R3(n)=R2(n−n3) [18]
DPD Weight Estimator
The DPD equation can be expressed as:
Let U be the number of observation samples. The above equation can be expressed in this form:
SU×1=HU×TWT×1 [20]
where
T=½(N+1)(Q+1) [21]
S=[s(0)g(0)s(1)g(1)s(2)·g(2)s(3)·g(3) . . . s(U−1)·g(U−1)]T [22]
H=[h10h30 . . . hK0|h11h31 . . . hK1| . . . |h1Qh3Q . . . hKQ] [23]
hij=[sij(0)·g(0)sij(1)·g(1)sij(2)·g(1)sij(3)·g(3) . . . sij(U−1)·g(U−1)]T [24]
and
W=[w10w30 . . . wK0|w11w31 . . . wK1| . . . |w1Qw3Q . . . wKQ]T [25]
Note that the equation SU×1=HU×TWT×1 was modified to take into account the soft factor G. The normal equation [20] can be solved with QR method or Matrix inversion technique to estimate the coefficient set W.
The residue error for this estimation is:
E=∥SU×1−HU×T·ŴT×1∥2 [26]
where ŴT×1 is the computed weight vector.
Coefficient Averaging
After solving for the coefficients W(t) using samples taken at discrete times t (t=0, 1, 2, . . . ), the coefficient set can be expressed as:
The phase of the fundamental component at DC is expressed as:
It is necessary to maintain this fundamental component phase as zero to ensure that the DPD block does not provide phase rotation of the desired signal. Thus, the new coefficient set W2(t) is expressed as:
Now, since all of the weights have the same fundamental component phase and are also highly correlated, the coefficients can be filtered to improve the signal to noise ratio. The filter coefficient set is expressed as:
W3(t+1)=(1−α)W3(t)+αW2(t+1) [30]
where W2(t) is the coefficient set per data taken and W3(t) is the filtered coefficient set.
As noted above, the transmitter 12 (
Thus, the present invention has been described herein with reference to a particular embodiment for a particular application. Those having ordinary skill in the art and access to the present teachings will recognize additional modifications applications and embodiments within the scope thereof.
It is therefore intended by the appended claims to cover any and all such applications, modifications and embodiments within the scope of the present invention.
Accordingly,
The present application is a continuation of U.S. patent application Ser. No. 11/150,445 filed Jun. 9, 2005, which in turn claims the benefit under 35 USC 119(e) from U.S. Provisional Application No. 60/616,714 filed on Oct. 7, 2007, all of which are incorporated herein by reference.
Number | Date | Country | |
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60616714 | Oct 2004 | US |
Number | Date | Country | |
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Parent | 11150445 | Jun 2005 | US |
Child | 11951238 | Dec 2007 | US |