Specialty flat-top beam delivery fibers with controlled beam parameter product

SPIE LASE Pub Date : 2016-04-22 DOI:10.1117/12.2209348

C. Jollivet, K. Farley, M. Conroy, J. Abramczyk, S. Belke, F. Becker, K. Tankala

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引用次数: 2

Abstract

Beam delivery fibers have been used widely for transporting the optical beams from the laser to the subject of irradiation in a variety of markets including industrial, medical and defense applications. Standard beam delivery fibers range from 50 to 1500 μm core diameter and are used to guide CW or pulsed laser light, generated by solid state, fiber or diode lasers. Here, we introduce a novel fiber technology capable of simultaneously controlling the beam profile and the angular divergence of single-mode (SM) and multi-mode (MM) beams using a single-optical fiber. Results of beam transformation from a SM to a MM beam with flat-top intensity profile are presented in the case of a controlled BPP at 3.8 mm*mrad. The scaling capabilities of this flat-top fiber design to achieve a range of BPP values while ensuring a flat-top beam profile are discussed. In addition, we demonstrate, for the first time to the best of our knowledge, the homogenizer capabilities of this novel technology, able to transform random MM beams into uniform flat-top beam profiles with very limited impact on the beam brightness. This study is concluded with a discussion on the scalability of this fiber technology to fit from 50 up to 1500 μm core fibers and its potential for a broader range of applications.

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专用平顶光束输送光纤，光束参数可控产品

光束传输光纤已被广泛用于将光束从激光器传输到各种市场的照射对象，包括工业，医疗和国防应用。标准光束传输光纤的芯径范围为50 ~ 1500 μm，用于引导固体、光纤或二极管激光器产生的连续波或脉冲激光。在这里，我们介绍了一种新的光纤技术，能够同时控制单模(SM)和多模(MM)光束的光束轮廓和角散度。在控制BPP为3.8 MM *mrad的情况下，给出了具有平顶强度分布的SM光束到MM光束的转换结果。讨论了这种平顶光纤设计的缩放能力，以实现一定范围的BPP值，同时确保平顶光束轮廓。此外，据我们所知，我们首次证明了这种新技术的均质器能力，能够将随机的MM光束转换成均匀的平顶光束轮廓，对光束亮度的影响非常有限。本研究最后讨论了该光纤技术的可扩展性，以适应从50到1500 μm芯的光纤，以及它在更广泛应用领域的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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SPIE LASE

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