改进团队进步算法的近红外光谱波长筛选

doi:10.3964/j.issn.1000-0593(2021)10-3032-07

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摘要：针对近红外光谱波长选择问题，在团队进步算法(TPA)的基础上，提出一种改进团队进步算法(iTPA)的波长变量选择方法，将分子光谱的波段按照与其相应的理化值建模得到的评价值函数大小降序排列，顺序分为精英组、普通组和垃圾回收组。当新生波段选择学习行为时，若其产生于普通组，则需要向精英组样板的方向调节；若其产生于精英组，则需要改进其更新方向，向垃圾回收组样板的反方向调节。垃圾回收组成员的评价值不像精英组和普通组随着更新的过程一直上升，而是一直处于极低的状态，为产生于精英组的新生波段在学习时提供一个准确的更新方向，从而提升算法的全局寻优能力。通过不断的迭代更新，逐步提升整体评价值，最终选取评价值最高的波段作为筛选波段。该算法对玉米的淀粉和蛋白质含量数据集进行了实验测试，并与TPA、遗传算法(GA)、主成分分析(PCA)以及全谱方法进行了对比。实验结果表明，所提算法能够找出全谱范围内波长的最优组合，并且可以解释各含量的化学特性。玉米淀粉数据集运行的效果相比于全光谱，变量个数从700个减少到17.55个左右（50次试验求平均），模型的RMSEC从0.335 7降到0.260 9，校正集预测精度提升了22.3%，模型的RMSEP从0.391 4下降到0.334 4左右，预测集预测精度提升了14.6%；在玉米蛋白质数据集运行的效果相比于全光谱，变量个数从700个减少到19.6个左右（50次试验求平均），模型的RMSEC从0.147 4降到0.101 9，校正集预测精度提升了30.1%，模型的RMSEP从0.178 9下降到0.117 7，预测集预测精度提升了34.2%。

关键词：近红外光谱；波长选择；改进的团队进步算法；智能组合优化；特征波长

Abstract：Aiming at the problem of near-infrared spectroscopy wavelength selection, an improved team progress algorithm (iTPA) is proposed based on the team progress algorithm (TPA). The bands of molecular spectrum are arranged in descending order according to the evaluation value function obtained by modeling corresponding physical and chemical values and are divided into elite group, plain group and garbage collection group. When the new wave band selects learning behavior, if it is generated in the plain group, it needs to adjust to the direction of the elite group template; if it is generated in the elite group, its updating direction needs to be improved to adjust to the reverse direction of garbage collection group template. Unlike the elite group and the plain group, members’ evaluation value of the garbage collection group is always in a deficient state, which provides an accurate update direction for the new band generated from the elite group during the learning procedure to improve the global optimization ability of the algorithm. Through continuous iterative updating, the overall evaluation value is gradually improved, and finally, the band with the highest evaluation value is selected as the screening band. The algorithm is tested on the data set of corn starch and protein content and compared with TPA, genetic algorithm (GA), principal component analysis (PCA) and complete spectrum method. The experimental results show that the proposed algorithm can find the optimal combination of wavelengths in the whole spectrum range and explain each component’s chemical characteristics. Compared with the full spectrum, for the corn starch data set, the number of variables of iTAP was decreased from 700 to 17.55 (averaged by 50 tests), RMSEC of the model was reduced from 0.335 7 to 0.260 9, and the prediction accuracy of the correction set was improved by 22.3%. The RMSEP of the model decreased from 0.391 4 to 0.334 4, and the prediction accuracy of the prediction set increased by 14.6%; For the corn protein dataset, the number of variables decreased from 700 to 19.6 (averaged by 50 tests), RMSEC of the model was reduced from 0.147 4 to 0.101 9, and the prediction accuracy of correction set was improved by 30.1%. The RMSEP of the model decreased from 0.178 9 to 0.117 7, and the prediction accuracy of the prediction set increased by 34.2%.

Key words：Near infrared spectrum; Wavelength selection; Improved team progress algorithm; Intelligent combination optimization; Characteristic wavelength

收稿日期: 2020-08-28 修订日期: 2020-12-12

中图分类号:

Q657.3

基金资助: 国家自然科学基金项目（61833007）资助

作者简介: 高美凤，1963年生，江南大学物联网工程学院副教授 e-mail：mfgao@jiangnan.edu.cn

引用本文:

高美凤，陶焕明. 改进团队进步算法的近红外光谱波长筛选[J]. 光谱学与光谱分析, 2021, 41(10): 3032-3038.
GAO Mei-feng, TAO Huan-ming. Near Infrared Spectral Wavelength Selection Based on Improved Team Progress Algorithm. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(10): 3032-3038.

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