David Wisell scite author profile

In this paper a behavioral power amplifier model with substantially lower normalized mean-square error than the well-known and widely used parallel Hammerstein or tapped delay line model is presented. This is significant since the parallel Hammerstein model currently must be considered to be the baseline for behavioral power amplifier modeling efforts. The proposed model does also have at least as low total error as any other model known to the authors for measurements on class-AB LDMOS power amplifiers. Further, the proposed model exhibits an equal or lower out-of-band error than the parallel Hammerstein model. The parameters of the model can be extracted using straightforward system identification techniques. Together this makes the proposed model a strong candidate to replace the parallel Hammerstein model as the model of choice for behavioral power amplifier modeling for many applications.

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Three-Tone Characterization of Nonlinear Memory Effects in Radio-Frequency Power Amplifiers

Rönnow¹,

Wisell

Isaksson

2007

IEEE Trans. Instrum. Meas.

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Nonlinear behavioral modeling of power amplifiers using radial-basis function neural networks

Isaksson

Wisell

Rönnow

2005

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David Wisell

A comparative analysis of behavioral models for RF power amplifiers

Wide-band dynamic modeling of power amplifiers using radial-basis function neural networks

A Technique to Extend the Bandwidth of an RF Power Amplifier Test Bed

Behavioral Power Amplifier Modeling Using the LASSO

A general evaluation criteria for behavioral power amplifier modeling

Derivation of a behavioral RF power amplifier model with low normalized mean-square error

Three-Tone Characterization of Nonlinear Memory Effects in Radio-Frequency Power Amplifiers

Nonlinear behavioral modeling of power amplifiers using radial-basis function neural networks

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