Robust and automated computational adaptive optics using multiple randomized sub-apertures

Dierck Hillmann; Clara Pfäffle; Hendrik Spahr; Katharina Gercke; Sazan Burhan; Lisa Kutzner; David Melenberg; Felix Hilge; Gereon Hüttmann

doi:10.1117/12.2576890

Robust and automated computational adaptive optics using multiple randomized sub-apertures

Dierck Hillmann, Clara Pfäffle, Hendrik Spahr, Katharina Gercke, Sazan Burhan, Lisa Kutzner, David Melenberg, Felix Hilge, Gereon Hüttmann

Institut für Biomedizinische Optik

Abstract

Computational adaptive optics (CAO) is emerging as an attractive alternative to hardware-based solutions for diffraction-limited optical coherence tomography, e.g., of the human retina. Still, to become a reliable and robust solution, many challenges need to be solved. Here, we present CAO based on multiple randomized sub-apertures in combination with suitable filtering to remove disturbing artifacts. We show that this approach can reliably detect aberrations, and we compare results to other algorithms, such as optimization of imaging quality. We also demonstrate that the filtering of reflecting image structures is essential for a robust determination of aberrations

Originalsprache	Englisch
DOIs	https://doi.org/10.1117/12.2576890
Publikationsstatus	Veröffentlicht - 04.03.2021

UN SDGs

Dieser Output leistet einen Beitrag zu folgendem(n) Ziel(en) für nachhaltige Entwicklung

SDG 9 – Industrie, Innovation und Infrastruktur

DFG-Fachsystematik

3.23-01 Optik, Quantenoptik und Physik der Atome, Moleküle und Plasmen

Dokumente

10.1117/12.2576890

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abstract = "Computational adaptive optics (CAO) is emerging as an attractive alternative to hardware-based solutions for diffraction-limited optical coherence tomography, e.g., of the human retina. Still, to become a reliable and robust solution, many challenges need to be solved. Here, we present CAO based on multiple randomized sub-apertures in combination with suitable filtering to remove disturbing artifacts. We show that this approach can reliably detect aberrations, and we compare results to other algorithms, such as optimization of imaging quality. We also demonstrate that the filtering of reflecting image structures is essential for a robust determination of aberrations",

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AU - Hillmann, Dierck

AU - Pfäffle, Clara

AU - Spahr, Hendrik

AU - Gercke, Katharina

AU - Burhan, Sazan

AU - Kutzner, Lisa

AU - Melenberg, David

AU - Hilge, Felix

AU - Hüttmann, Gereon

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N2 - Computational adaptive optics (CAO) is emerging as an attractive alternative to hardware-based solutions for diffraction-limited optical coherence tomography, e.g., of the human retina. Still, to become a reliable and robust solution, many challenges need to be solved. Here, we present CAO based on multiple randomized sub-apertures in combination with suitable filtering to remove disturbing artifacts. We show that this approach can reliably detect aberrations, and we compare results to other algorithms, such as optimization of imaging quality. We also demonstrate that the filtering of reflecting image structures is essential for a robust determination of aberrations

AB - Computational adaptive optics (CAO) is emerging as an attractive alternative to hardware-based solutions for diffraction-limited optical coherence tomography, e.g., of the human retina. Still, to become a reliable and robust solution, many challenges need to be solved. Here, we present CAO based on multiple randomized sub-apertures in combination with suitable filtering to remove disturbing artifacts. We show that this approach can reliably detect aberrations, and we compare results to other algorithms, such as optimization of imaging quality. We also demonstrate that the filtering of reflecting image structures is essential for a robust determination of aberrations

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