Optimization of DMD-based independent amplitude and phase modulation: a spatial resolution and quantization

TL;DR

This study investigates optimizing DMD-based independent amplitude and phase modulation by balancing spatial resolution and quantization, providing a general algorithm for pattern optimization in complex wavefront control.

Contribution

It introduces a comprehensive algorithm for DMD pattern optimization that balances spatial resolution and quantization for complex wavefront manipulation.

Findings

Higher carrier frequency improves spatial resolution.

Higher carrier frequency reduces quantization quality.

Optimal parameters depend on target wavefront type.

Abstract

This paper presents the results of a comprehensive study on the optimization of the optical system for independent amplitude and phase wavefront manipulation, which is based on a digital micromirror device implementation. The parameters of generated binary fringe patterns to reach the optimal quality of target complex-valued wavefront have been found for several examples, and a general algorithm for DMD pattern optimization is described. It was shown that a trade-off between spatial resolution and quantization of the target amplitude and phase distribution should be achieved. The increase of carrier frequency results in higher spatial resolution of the modulated complex wave but decreases its quantization. The dependence of the best DMD-pattern generation parameters on the type of target complex wavefront is discussed in terms of spatial resolution and quantization degree.