Abstract
The power amplifier (PA) is the most critical subsystem in terms of linearity and power efficiency. Digital predistortion (DPD) is commonly used to mitigate nonlinearities while the PA operates at levels close to saturation, where the device presents its highest power efficiency. Since the DPD is generally based on Volterra series models, its number of coefficients is high, producing ill-conditioned and over-fitted estimations. Recently, a plethora of techniques have been independently proposed for reducing their dimensionality. This paper is devoted to presenting a fair benchmark of the most relevant order reduction techniques present in the literature categorized by the following: (i) greedy pursuits, including Orthogonal Matching Pursuit (OMP), Doubly Orthogonal Matching Pursuit (DOMP), Subspace Pursuit (SP) and Random Forest (RF); (ii) regularization techniques, including ridge regression and least absolute shrinkage and selection operator (LASSO); (iii) heuristic local search methods, including hill climbing (HC) and dynamic model sizing (DMS); and (iv) global probabilistic optimization algorithms, including simulated annealing (SA), genetic algorithms (GA) and adaptive Lipschitz optimization (adaLIPO). The comparison is carried out with modeling and linearization performance and in terms of runtime. The results show that greedy pursuits, particularly the DOMP, provide the best trade-off between execution time and linearization robustness against dimensionality reduction.
Highlights
The power amplifier is an active and power-hungry device present in every transmitter, being the cause of the main sources of nonlinear distortion
Despite the specific particularities of each of the previously-described algorithms it was possible to compare their performance in terms of normalized mean square error (NMSE) and adjacent channel error power ratio (ACEPR) versus the number of coefficients
In this paper we have compared several dimensionality reduction methods that have been used in the field of power amplifier (PA) behavioral modeling or DPD linearization, focusing on greedy pursuits, heuristic local search methods, regularization techniques and global probabilistic search algorithms
Summary
The power amplifier is an active and power-hungry device present in every transmitter, being the cause of the main sources of nonlinear distortion. Many efforts have been devoted at characterizing its behavior at both circuit and system level. Blackboxes or behavioral models are used to characterize its nonlinear behavior from simple input-output data observations. In order to overcome the low power efficiency figures of linear class AB PAs when handling current orthogonal frequency division multiplexing (OFDM)-based signals with high peak-to-average power ratio (PAPR), highly efficient amplification architectures based on dynamic load or dynamic supply modulation have been proposed in the literature. Other dynamic load modulation approaches such as load modulated balanced amplifiers (LMBA) [2], LINC or outphasing PAs [3] have been proposed. A different approach based on dynamic supply modulation, such envelope tracking PAs [4], has been adopted by the industry but mainly for mobile terminals
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