应用遗传算法拟合偏振X射线荧光重叠谱

doi:10.3964/j.issn.1000-0593.2008.03.054

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摘要： X射线荧光光谱分析由于受能量探测器分辨率的限制，谱线重叠干扰严重。不采用合适的重叠谱峰分解或曲线拟合技术，很难进行成分定性和定量分析。样品中的元素及谱线未知、背景基线不确定和模型初始参数不准确是曲线拟合中的最大困难。有多种算法可应用于光谱分析中的曲线拟合。文章将遗传算法应用于永磁材料偏振X射线荧光中的重叠谱分解，研究了进化策略对谱峰分解质量的影响，比较了遗传算法与传统算法的拟合结果。研究表明遗传算法在谱线严重重叠情况下仍具有较强的谱峰分解能力；群体初始化和进化策略的正确选择是该算法成功应用的关键；遗传算法具有全局搜索能力，对重叠谱峰的分辨能力优于标准Marquardt-Levenberg算法。

关键词：遗传算法;偏振X射线荧光;重叠谱分解;永磁材料

Abstract：Overlapped spectra occur often in energy dispersive X-ray fluorescence spectrometry. Without a suitable curve fitting process,no correct qualitative and quantitative results can be obtained. The most difficult problems in curve fitting include that elements and their lines are unknown,background is uncertain sometimes,and initial model parameters may be in correct. In order to solve these problems,several available algorithms may be used. Among them are genetic algorithms. In the present work,polarization energy dispersive X-ray spectrometry was used in the determination of raw materials for permanent magnet. A genetic algorithm was successfully applied to the deconvolution of the overlapped spectra in magnetic materials. With its global searching capability,the genetic algorithm beatures higher resolution than the standard Marquardt-Levenberg method in resolving the overlapped X-ray spectra. Because of the powerful capability of genetic algorithms to deconvolute overlapped spectra,the algorithms are useful especially in energy dispersive X-ray spectrometry and complex material analysis.

Key words：Genetic algorithm;Polarization X-ray fluorescence spectrometry;Deconvolution of overlapped spectra;Permanent magnetic materials

收稿日期: 2006-04-10 修订日期: 2006-08-25

中图分类号:

O657.3

通讯作者: 罗立强 E-mail: luoliqiang@ccsd.org.cn

引用本文:

罗立强,詹秀春. 应用遗传算法拟合偏振X射线荧光重叠谱[J]. 光谱学与光谱分析, 2008, 28(03): 704-706.
LUO Li-qiang,ZHAN Xiu-chun. Resolution of Overlapped Spectra in Polarization X-Ray Fluorescence Spectrometry by Genetic Algorithm. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2008, 28(03): 704-706.

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