混乱的
多模光纤
分光计
Tikhonov正则化
光学
正规化(语言学)
光谱分辨率
迭代重建
物理
干扰(通信)
小型化
光纤
计算机科学
算法
抛光
材料科学
多路复用
反问题
重建算法
电子工程
光谱成像
单模光纤
信号处理
自相关
光谱法
模式(计算机接口)
自适应光学
作者
Huang Zhongming,Junrui Liang,Yanting Guo,Jun Ye,Junhong He,Xiaoya Ma,Yanzhao Ke,Jun Li,Jiangming Xu,冷进勇,Shilong Jin,Pu Zhou
摘要
The development of high-resolution, miniaturized, and cost-effective spectrometers remains a critical technical challenge. In this work, we demonstrate a high-resolution computational spectrometer by exploiting the chaotic effects induced in side-polished multimode fibers (MMFs). The polishing breaks the structural symmetry of the circular fiber, thereby efficiently exciting guided modes and causing chaos. By forming a 5-cm-long polished region, a spectral resolution of ∼0.5 nm is achieved, representing a one-third improvement over an unpolished MMF of the same length. Moreover, we develop a spectral reconstruction algorithm that integrates adaptive regularization and the Savitzky–Golay filter, enabling real-time reconstruction with enhanced accuracy and robustness. Compared to the Tikhonov regularization algorithm alone, the proposed method reduces the reconstruction error by 50%. This scheme, which leverages chaotic effects to enhance spectral resolution, offers an effective design strategy for developing high-resolution spectrometers.
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