Baseband Equivalent Models and Digital Predistortion for Mitigating Dynamic Continuous-Time Perturbations in Phase-Amplitude Modulation-Demodulation Schemes (Expanded version)

TL;DR

This paper develops a novel baseband equivalent model for nonlinear transmission circuits involving phase-amplitude modulation and demodulation, enabling improved digital predistortion techniques to mitigate continuous-time nonlinearities in communication systems.

Contribution

It introduces a new analytical structure for digital pre-compensation of analog nonlinear distortions using baseband equivalent models derived from continuous-time Volterra series.

Findings

The proposed model accurately represents nonlinear transmission circuits.

The new compensation scheme outperforms standard Volterra series methods.

Simulation results confirm the effectiveness of the approach.

Abstract

We consider baseband equivalent representation of transmission circuits, in the form of a nonlinear dynamical system $\mathbf S$ in discrete time (DT) defined by a series interconnection of a phase-amplitude modulator, a nonlinear dynamical system $\mathbf F$ in continuous time (CT), and an ideal demodulator. We show that when $\mathbf F$ is a CT Volterra series model, the resulting $\mathbf S$ is a series interconnection of a DT Volterra series model of same degree and memory depth, and an LTI system with special properties. The result suggests a new, non-obvious, analytically motivated structure of digital pre-compensation of analog nonlinear distortions such as those caused by power amplifiers in digital communication systems. The baseband model and the corresponding digital compensation structure readily extend to OFDM modulation. MATLAB simulation is used to verify proposed baseband equivalent model and demonstrate effectiveness of the new compensation scheme, as compared to the standard Volterra series approach.