Linearization as a Solution for Power Amplifier Imperfections: A Review of Methods

Borel, Andžej; Barzdėnas, Vaidotas; Vasjanov, Aleksandr

doi:10.3390/electronics10091073

Cited by 22 publications

(14 citation statements)

References 87 publications

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“…The prime focus of each contribution is to reduce the PAPR level while evading inherent signal distortion or compromising spectral efficiency (SE). However, such insistence demand additional behavioral baseband optimization for the nonlinearity prediction at the • The linearization and PAPR-reduction techniques are partially discussed in terms of the performance-complexity profile, including their advantages and limitations [42], 2021…”

Section: Introductionmentioning

confidence: 99%

Predistortion-Based Linearization for 5G and Beyond Millimeter-Wave Transceiver Systems: A Comprehensive Survey

Haider

You

et al. 2022

IEEE Commun. Surv. Tutorials

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The next-generation (5G/6G) wireless communication aims to leapfrog the currently occupied sub-6 GHz spectrum to the wideband millimeter-wave (MMW) spectrum. However, MMW spectrums with high-order modulation schemes drive the power amplifier (PA) at significant back-off, causing severe nonlinear distortions, thus deteriorating the transceiver's (TRXs) modulation process. Typically, the TRX efficacy is quantified with standardized linearization matrices, which take advantage of different predistortion (PD) schemes to handle deep compression of the PA. In this regard, TRX baseband signals are mostly linearized in the digital domain, where digitally controlled linearization needs higher sampling rates due to increasing MMW bandwidths to compensate for intermodulation (IMD) products, resulting in increased system cost and power consumption. Alternately, the digitally controlled analog-based linearization, i.e., the hybridization of digital predistortion (DPD) and analog predistortion (APD), is highly productive and cost-effective for fulfilling the linearized energy-efficient design vision of MMW networks. Therefore, this paper puts an extensive spotlight on the progress in PD-based linearization for 5G and beyond communications. It first provides background information on the advancements of PD schemes through recent surveys, then classifies the general roadmap of PD waveform processing across the TRX system models as preliminary. After this, we present three prominent PD architectures and their design approaches with intrinsic performance metrics. Finally, we explore four case studies encompassing PD operation under certain nonlinear constraints of different communication schemes. We examine the suitability of PD-based linearization solutions, both existing and proposed till the first quarter of 2022, and identify the potential prospects in this domain.

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Section: Introductionmentioning

confidence: 99%

Predistortion-Based Linearization for 5G and Beyond Millimeter-Wave Transceiver Systems: A Comprehensive Survey

Haider

You

et al. 2022

IEEE Commun. Surv. Tutorials

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“…Both types can be modeled as a black box based on behavior modeling with memory [ 1 ]. To improve the performance in linearity and power efficiency in data waveforms, crest factor reduction (CFR) in conjunction with digital predistortion (DPD) as linearization technique are used [ 2 ]. In [ 3 ], a novel multi-objective predistortion linearization approach based on a learning procedure constrained algorithm with prescribed linearity levels is able to maximize the RF output power.…”

Section: Introductionmentioning

confidence: 99%

“…In [ 10 ], an interference-aware iterative clipping and filtering PAPR reduction scheme is developed for multiple-input–multiple-output (MIMO)-OFDM systems. Additionally, in [ 2 ], a complete study of existing linearization techniques that shows the aspects to consider into a 5G NR, particularly with W-CDMA and 64–QAM stimulus signals through several methods, such as the feedforward, feedback, and predistortion, is introduced.…”

Section: Introductionmentioning

confidence: 99%

A Crest Factor Reduction Technique for LTE Signals with Target Relaxation in Power Amplifier Linearization

Cárdenas-Valdez

Galaviz-Aguilar

Vargas-Rosales

et al. 2022

Sensors

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The signal conditioning treatment to achieve good relation of power with radio-frequency (RF) conversion in conventional transceiver systems require precise baseband models. A developed framework is built to provide a demonstration of the modeling figures of merit with orthogonal frequency division multiplexing (OFDM) support under signal conditioning and transmission restrictions to waveforms with high peak to average power ratio (PAPR) in practical applications. Therefore, peak and average power levels have to be limited to correct high PAPR for a better suited correction power from the amplifier that can lead to compression or clipping in the signal of interest. This work presents an alternative joint crest factor reduction (CFR) algorithm to correct the performance of PAPR. A real-time field-programmable gate array (FPGA) testbed is developed to characterize and measure the behavior of an amplifier using a single-carrier 64–QAM OFDM based on long-term evolution (LTE) downlink at 2.40 GHz as stimulus, across wide modulation bandwidths. The results demonstrate that the CFR accuracy capabilities for the signal conditioning show a reliable clipping reduction to give a smooth version of the clipping signal and provide a factor of correction for the unwanted out-of-band emission validated according to the adjacent channel power ratio (ACPR), PAPR, peak power, complementary cumulative distribution function (CCDF), and error vector magnitude (EVM) figures of merit.

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“…The deployment of modern wireless communication systems, based on spectrally efficient modulation schemes such as the orthogonal frequency division multiplexing (OFDM), is perhaps the main agent that has pushed the dawn of new ultra-linear and highly efficient power amplifiers (PAs) [1]. Advanced techniques in the discrete-time domain have been employed to quantitatively mitigate the nonlinear impairments generated by the PA and the IQ modulator, mainly through digital predistorters (DPD) in transmitters linearization [2][3][4][5], and also by applying post-compensation in the communications receiver [6,7].…”

Section: Introductionmentioning

confidence: 99%

Upgrading Behavioral Models for the Design of Digital Predistorters

Crespo‐Cadenas

Madero‐Ayora

Becerra

2021

Sensors

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This work presents a strategy to upgrade models for power amplifier (PA) behavioral modeling and digital predistortion (DPD). These incomplete structures are the consequence of nonlinear order and memory depth model truncation with the purpose of reducing the demand of the limited computational resources available in standard processors. On the other hand, the alternative use of model structures pruned a priori does not guarantee that every significant term is included. To improve the limited performance of an incomplete model, a general procedure to augment its structure by incorporating significant terms is demonstrated. The sparse nature of the problem allows a successive search incorporating additional terms with higher nonlinear order and memory depth. This approach is investigated in the modeling and linearization of a commercial class AB PA operating at a compression point of about 6 dB, and a class J PA operating near saturation. Results highlight the capabilities of this upgrading procedure in the improvement of linearization capabilities of DPDs.

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Linearization as a Solution for Power Amplifier Imperfections: A Review of Methods

Cited by 22 publications

References 87 publications

Predistortion-Based Linearization for 5G and Beyond Millimeter-Wave Transceiver Systems: A Comprehensive Survey

Predistortion-Based Linearization for 5G and Beyond Millimeter-Wave Transceiver Systems: A Comprehensive Survey

A Crest Factor Reduction Technique for LTE Signals with Target Relaxation in Power Amplifier Linearization

Upgrading Behavioral Models for the Design of Digital Predistorters

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