An Accurate Digital Predistortion for Wideband Power Amplifiers Based on Directly Solving the Inverse Model Function

Digital predistortion (DPD) is one of the most effective techniques that can compensate for the distortions caused by the nonlinearities and memory effects of power amplifiers (PAs). In this paper, a new DPD solution which directly solves the inverse function of a PA model is presented for wideband transmitter applications. The major components of the general memory polynomial (GMP) model are selected to effectively characterize the PA’s nonlinearity and memory effects through model identification. In the direct learning algorithm that followed, the DPD function is obtained by constructing and then solving the reverse function of the identified PA model. Due to the high accuracy of the proposed modeling process and the direct learning algorithm, the DPD function is accurately derived, which could significantly compensate for the nonlinear distortions. Simulations and experiments are performed on wideband long-term evolution (LTE) signals to evaluate the effectiveness of the proposed DPD method. It is demonstrated that a 22-dB adjacent channel leakage ratio improvement is achieved for a 100-MHz LTE-advanced signal, which even outperforms the conventional GMP-based DPD method by about 3 dB.

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