Variable magnification beam expander system based on semiconductor laser

Theoretical and Natural Science Pub Date : 2024-04-02 DOI:10.54254/2753-8818/34/20241186

Ke Zhang, Zhanqiang Ru, Peng Ding, Kunkun Hao, Tengfei Han, Chengao Wang, Yang Xiang

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Abstract

Due to the different divergence angles in two perpendicular directions and the presence of astigmatism in edge-emitting semiconductor lasers, the communication distance and efficiency of underwater communication are seriously affected. Therefore, based on the fact that the semiconductor laser beam belongs to Gaussian beam, satisfying Gaussian characteristics and collimating and expanding characteristics, a system composed of fast-axis collimation mirror and variable magnification beam expander is designed. Simulation is performed, and the final divergence angle is calculated. Experimental results show that the divergence angles of the fast axis and the slow axis have been compressed from 49 and 9, respectively, to 0.315 mrad and 0.180 mrad. Simulation demonstrates that the system can achieve propagation over a distance of 100m underwater and solve the alignment difficulty of APT. The designed structure is compact, easy for processing and adjustment, with high practical value, which helps to solve the problems of optical energy loss and low coupling efficiency in underwater long-distance communication.

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基于半导体激光器的可变倍率扩束系统

由于边缘发射半导体激光器在两个垂直方向上的发散角不同，且存在散光现象，严重影响了水下通信的通信距离和通信效率。因此，根据半导体激光光束属于高斯光束，满足高斯特性和准直扩束特性的特点，设计了一种由快轴准直镜和可变倍率扩束器组成的系统。进行了仿真，并计算了最终的发散角。实验结果表明，快轴和慢轴的发散角分别从 49 和 9 缩小到 0.315 mrad 和 0.180 mrad。仿真表明，该系统可实现水下 100 米的传播距离，并解决了 APT 的对准难题。所设计的结构紧凑，易于加工和调整，具有很高的实用价值，有助于解决水下长距离通信中光能损耗和耦合效率低的问题。

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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Theoretical and Natural Science

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