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PIER PIER B PIER C PIER M PIER Letters
2015-05-31
A Low-Complexity Dual-Band Model for Dual-Band Power Amplifiers Based on Volterra Series
By
Tianjing Zhang,

    Dr. Tianjing Zhang

    School of Electronic Engineering, Beijing Key Laboratory of Work Safety Intelligent Monitoring

    Beijing University of Posts and Telecommunications

    China

    Homepage

Cuiping Yu,

    Dr. Cuiping Yu

    School of Telecommunication Engineering

    Beijing University of Posts and Telecommunications

    China

    Homepage

Yuan'an Liu,

    Dr. Yuan'an Liu

    School of Telecommunication Engineering,

    Beijing University of Posts and Telecommunications

    China

    Homepage

Shulan Li,

    Dr. Shulan Li

    School of Electronic Engineering

    Beijing University of Posts and Telecommunications

    China

    Homepage

Bihua Tang

    Dr. Bihua Tang

    School of Electronic Engineering

    Beijing University of Posts and Telecommunications

    China

    Homepage

Progress In Electromagnetics Research Letters, Vol. 53, 101-106, 2015
doi:10.2528/PIERL15042704 | Google Scholar

Abstract
A novel low-complexity dual-band digital predistortion (2D-LCMP) model for linearization of dual-band power amplifiers (PAs) is proposed in this paper. The in-band intermodulation (IM) and cross-band modulation (CM) distortion terms in the prior two-dimensional models have different impacts on the model performance. Therefore, they are considered respectively in the proposed model. Some redundant distortion terms are removed away to decrease the model complexity. In addition, the nonlinearity order and memory depth are frequency dependent for each band. Experimental measurements were performed on two types of wideband PAs. The results prove the superiority of the 2D-LCMP model.
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Citation
Tianjing Zhang, Cuiping Yu, Yuan'an Liu, Shulan Li, and Bihua Tang, "A Low-Complexity Dual-Band Model for Dual-Band Power Amplifiers Based on Volterra Series," Progress In Electromagnetics Research Letters, Vol. 53, 101-106, 2015.
doi:10.2528/PIERL15042704
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