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| A Waste Plastic Classification Method Based on Laser Spectral Fusion
Detection Technology |
| FANG Jia-xuan, DONG Xi-wen, XU Zi-rui, QU Dong-ming, YANG Guang*, SUN Hui-hui* |
College of Instrumentation and Electrical Engineering, Jilin University, Changchun 130026, China
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Abstract Plastic is a commonly used polymer in daily life. With the increasing amount of waste plastic, the resulting environmental pollution has become more severe, making the classification and recycling of waste plastic an urgent issue. Different types of plastics require different recycling methods, so researching plastic classification methods is of great significance. Laser-Induced Breakdown Spectroscopy (LIBS) is an elemental analysis technique based on atomic emission spectroscopy, offering advantages such as rapid analysis, no sample pretreatment required, and in-situ analysis, which provides convenience for plastic classification. Raman Spectroscopy (RS) is a molecular structure characterization technique based on Raman scattering theory, which offers advantages such as simultaneous multi-element analysis, low sample quantity requirements, and minimal sample damage, also facilitating plastic classification. This paper will utilize LIBS and RS technologies to collect spectral information from both atomic and molecular perspectives of plastics, and then merge the two types of spectral information to obtain a fused spectrum. By using LIBS spectra, RS spectra, and fused spectra in conjunction with the Random Forest machine learning algorithm (RF) to build models for plastic classification and identification, a comparison of the classification accuracy of the three models reveals that the fused spectrum can improve classification accuracy. During the model-building process, with the same number of test sets, the number of training sets affects both the model construction time and classification accuracy. Experiments were conducted on the accuracy and model construction time for different ratios of test sets to training sets, concluding that a ratio of 1∶3 is the most suitable, achieving an accuracy of 96%. In addition to the impact of the training set, the preprocessing methods of spectral data also affect the classification accuracy of the plastic fusion spectrum. The experiment-employed a sparsity-based baseline estimation denoising method to process the fusion spectral data and rebuild the model, thereby increasing the classification accuracy of plastics to 100%. The experimental results indicate that when the ratio of the test set to the training set is 1∶3, the fused spectral data has a significant advantage in classification accuracy compared to single spectral data. The classification accuracy of the preprocessed fused spectral data can be improved to 100%.
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Received: 2024-05-08
Accepted: 2025-06-20
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Corresponding Authors:
YANG Guang, SUN Hui-hui
E-mail: yangguang_jlu@163.com;sunhuihui@jlu.edu.cn
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[1] Lin Kunsen, Zhao Youcai, Zhang Meilan, et al. Journal of Industrial Ecology, 2023, 27(1): 170.
[2] Kerdlap P, Purnama A R, Low J S C, et al. Journal of Industrial Ecology, 2023, 27(1): 297.
[3] Wu Xiaoyu, Li Jia, Yao Linpeng, et al. Journal of Cleaner Production, 2020, 246: 118732.
[4] Aidene S, Semenov V, Kirsanov D, et al. Measurement, 2020, 172: 108888.
[5] Harmon R S, Senesi G S. Applied Geochemistry, 2021, 128: 104929.
[6] Chen Chenghan, Shi Qi, Wang Shuai, et al. Journal of Analytical Atomic Spectrometry, 2016, 31(7): 1527.
[7] Liu Ke, Tian Di, Wang Hongxia, et al. Analytical Methods, 2019, 11(9): 1174.
[8] LIU Jun-an, LI Jia-ming, ZHAO Nan, et al(刘俊安, 李嘉铭, 赵 楠, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2021, 41(6): 1955.
[9] Jones R R, Hooper D C, Zhang L, et al. Nanoscale Res. Lett., 2019, 14: 231.
[10] Cowger W, Steinmetz Z, Gray A, et al. Analytical Chemistry, 2021, 93(21): 7543.
[11] Araujo C F, Nolasco M M, Ribeiro A M P, et al. Water Research, 2018, 142: 426.
[12] Yang Y, Zhang W, Wang Zh, et al. Journal of Applied Spectroscopy, 2022, 89(4): 790.
[13] Qin Yazhou, Qiu Jiaxin, Tang Nan, et al. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2024, 309: 123854.
[14] Neo E R K, Yeo Zhi-quan, Low J S C, et al. Resources Conservation and Recycling, 2022, 180: 106217.
[15] Musu W, Tsuchida A, Kawazumi H, et al. Application of PCA-SVM and ANN Techniques for Plastic Identification by Raman Spectroscopy. IEEE 2019 1st International Conference on Cybernetics and Intelligent System (ICORIS), 2019: 114.
[16] Junjuri R, Zhang Chi, Barman I, et al. Polymer Testing, 2019, 76: 101.
[17] Chen Tingting, Zhang Tianlong, Li Hua. Trac-Trends in Analytical Chemistry, 2021, 133: 116113.
[18] XU Ling-ling, CHI Dong-xiang(徐玲玲, 迟冬祥). Computer Engineering and Applications(计算机工程与应用), 2020, 56(24): 12.
[19] Tafintseva V, Lintvedt T A, Solheim J H, et al. Molecules, 2022, 27(3): 873. |
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