English

Wavefront Sensor for Laser Beams Based on Reweighted Amplitude Flow Algorithm

Optics 2026-02-12 v1

Abstract

We present a reference-free computational wavefront sensor based on binary amplitude modulation and phase retrieval. The method employs Digital Micro-mirror Device as a programmable amplitude modulator and reconstructs the complex optical field from multiple far-field intensity measurements using the Reweighted Amplitude Flow algo-rithm with Optimal Spectral Initialization. Unlike classical pupil-plane wavefront sen-sors, the proposed architecture does not include any wavelength-specific optical elements, enabling straightforward adaptation across a broad spectral range. The achievable spatial resolution of the reconstructed wavefront is scalable with the modulator resolution. We experimentally demonstrate wavefront reconstruction at 650 nm and at 2116 nm, where commercial wavefront sensors are not widely available. The reconstructed wavefront is validated against a commercial lateral shearing interferometer at 650 nm, and the method is further integrated into a closed-loop adaptive optics system using a deformable mirror. The approach is particularly suited for applications requiring high spatial resolution and large dynamic range in slowly varying or quasi-static laser fields, where computational reconstruction speed is not of the primary concern.

Keywords

Cite

@article{arxiv.2602.10998,
  title  = {Wavefront Sensor for Laser Beams Based on Reweighted Amplitude Flow Algorithm},
  author = {Ondrej Denk and Jan Pilar and Martin Divoky and Miroslav Cech and Tomas Mocek},
  journal= {arXiv preprint arXiv:2602.10998},
  year   = {2026}
}

Comments

14 pages, 5 figures

R2 v1 2026-07-01T10:32:07.400Z