Accounting for laser beam characteristics in the design of freeform optics for laser material processing-Reference-Cited by-同舟云学术

Accounting for laser beam characteristics in the design of freeform optics for laser material processing

Published:2019-05-27 Issue:3-4 Volume:8 Page:279-287
ISSN:2192-8584
Container-title:Advanced Optical Technologies
language:en
Short-container-title:

Author:

Völl Annika¹,Wester Rolf²,Berens Michael¹,Buske Paul¹,Stollenwerk Jochen¹²,Loosen Peter¹²

Affiliation:

1. Chair for Technology of Optical Systems , RWTH Aachen University , Steinbachstraße 15 , 52072 Aachen , Germany

2. Fraunhofer Institute for Laser Technology , Steinbachstraße 15 , 52072 Aachen , Germany

Abstract

Abstract Recently, freeform optics have been introduced for application adapted beam shaping in laser heat treatment. There, intensity distributions are generated that induce previously defined temporal and spatial temperature profiles. To this end, a two-step simulation strategy is necessary, where in the first step the intensity distribution must be derived for which in the second step the freeform optics is calculated. To provide a design that can successfully be integrated in an experimental setup, the incoming laser beam’s characteristics must be accounted for in the derivation of the adapted intensity distribution as well as in the freeform optics design. Here, the two most relevant quantities are the beam’s maximum output power as well as the divergence angle. In this work, strategies are presented that account for the beam’s maximum output power in the derivation of the adapted intensity distribution. Furthermore, stabilizing methods are introduced to enhance the performance of a previously introduced freeform optics design algorithm that takes into account the laser beam’s finite divergence angle but suffers from numerical noise and oscillation problems. A simulation example that uses both techniques is given for (nano)ceramic thin-film laser processing.

Funder

German Federal Ministry of Education and Research

Publisher

Walter de Gruyter GmbH

Subject

Instrumentation,Atomic and Molecular Physics, and Optics,Electronic, Optical and Magnetic Materials

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