|
|
|
|
|
|
Geographic Origin Discrimination of Wood Using NIR Spectroscopy
Combined With Machine Learning Techniques |
LUO Li, WANG Jing-yi, XU Zhao-jun, NA Bin* |
College of Materials Science and Engineering,Nanjing Forestry University,Nanjing 210037, China
|
|
|
Abstract The illegal logging of valuable tree species is mainly motivated by the global market that consumes logs, lumber, veneers, and furniture. Rapid and reliable identification of the country of origin of protected timbers is one of the measures for combating illegal logging. There is a global need to create a wood origin identification system to ensure the integrity of wood supply and control the trade, exploitation, and smuggling of these products. Near-infrared spectroscopy (NIRS) is a promising technique for calibration-based and rapid species identification. In the present work, Near-Infrared Spectroscopy combined with machine learning techniques were used to discriminate six wood species (Pinus massoniana, Paulownia fortunei, Zelkova schneideriana, Tectona grandis, Tilia amurensis, Ailanthus altissima) originating from two regions. The initial step was to create a spectral dataset of tree origins by collecting spectral data on these six wood species from two distinct origins, each constituting a dataset. Then, reduce feature dimensionality to two dimensions to investigate the data distribution across datasets. Secondly, the high-dimensional spectral data were dimensionally reduced using principal component analysis and linear discriminant analysis, respectively, to improve the model's generalization and to compare the effects of the two techniques on the model's accuracy. Finally, six different machine learning, namely, Support vector machine, Logistic regression, K-Nearest neighbors, Naïve Bayes, Random Forest, and Artificial neural network, were used to train these wood samples' spectra and assess their discrimination performance. The results showed that the highest accuracies of Pinus massoniana, Paulownia fortunei, Zelkova schneideriana, Tectona grandis, Tilia amurensis, Ailanthus altissimaare 98.3%, 100%, 100%, 100%, 100%, 98.3%, and the fastest operation speed are 0.183, 0.182, 0.181, 0.182, 11.424 and 12.969 s respectively. We evaluated and compared the performance of six models based on different machine learning algorithms to predict the geographic origin of the wood. Compared to the other five models, the best results were obtained by the Artificial neural network approach, but its running time is more than other algorithms, and requires a higher number of tuned and optimized parameters. Moreover, both the linear and non-linear algorithms yielded positive results, but the non-linear models appear slightly better. The study revealed that applying NIRS assisted by machine learning technique is suitable for the rapid identification and discrimination of wood origin and can be an essential tool for tracing the origins of wood, contributing to a safe authentication method in a quick, relatively cheap, and non-destructive way.
|
Received: 2022-05-14
Accepted: 2022-10-08
|
|
Corresponding Authors:
NA Bin
E-mail: nabin8691@126.com
|
|
[1] Feng L, Wu B, Zhu S, et al. Frontiers in Nutrition, 2021, 8: 680357.
[2] Kabir M H, Guindo M L, Chen R, et al. Foods, 2021, 10(11): 2767.
[3] Wang P, Yu Z. Journal of Pharmaceutical Analysis, 2015, 5(5): 277.
[4] Luypaert J, Massart D L, Vander Heyden Y. Talanta, 2007, 72(3): 865.
[5] Manley M. Chemical Society Reviews, 2014, 43(24): 8200.
[6] Wang Y, Xiang J, Tang Y, et al. Applied Spectroscopy Reviews, 2022, 57(4): 300.
[7] Liakos K, Busato P, Moshou D, et al. Sensors, 2018, 18(8): 2674.
[8] Wang Y, Zhang W, Gao R, et al. Wood Science and Technology, 2021, 55(5): 1171.
[9] Li Y, Via B K, Young T, et al. Forests, 2019, 10(12): 1078.
[10] Prades C, Gómez-Sánchez I, García-Olmo J, et al. Journal of Wood Chemistry and Technology, 2012, 32(1): 66.
[11] Yang Z, Liu Y, Pang X, et al. Bioresources, 2015, 10(4): 8505.
[12] Tsuchikawa S, Hayashi K, Tsutsumi S. Applied Spectroscopy, 1996, 50(9): 1117.
[13] Donaldson L. Wood Science and Technology, 2007, 41(5): 443.
[14] Cortes C, Vapnik V. Machine Learning, 1995, 20(3): 273.
[15] Riba Ruiz J R, Canals T, Cantero Gomez R. IEEE Transactions on Instrumentation and Measurement, 2012, 61(4): 1029.
[16] Breiman. Machine Learning, 2001, 45(1): 5.
[17] ZHANG Chi, GUO Yuan, LI Ming(张 驰, 郭 媛, 黎 明). Computer Engineering and Applications(计算机工程与应用), 2021, 57(11): 57.
[18] LUO Li, XU Zhao-jun, WANG Xiao-yu, et al(骆 立, 徐兆军, 王晓羽, 等). Journal of Forestry Engineering(林业工程学报), 2022, 7(104): 122.
|
[1] |
GAO Feng1, 2, XING Ya-ge3, 4, LUO Hua-ping1, 2, ZHANG Yuan-hua3, 4, GUO Ling3, 4*. Nondestructive Identification of Apricot Varieties Based on Visible/Near Infrared Spectroscopy and Chemometrics Methods[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 44-51. |
[2] |
BAO Hao1, 2,ZHANG Yan1, 2*. Research on Spectral Feature Band Selection Model Based on Improved Harris Hawk Optimization Algorithm[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 148-157. |
[3] |
HU Cai-ping1, HE Cheng-yu2, KONG Li-wei3, ZHU You-you3*, WU Bin4, ZHOU Hao-xiang3, SUN Jun2. Identification of Tea Based on Near-Infrared Spectra and Fuzzy Linear Discriminant QR Analysis[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3802-3805. |
[4] |
LIU Xin-peng1, SUN Xiang-hong2, QIN Yu-hua1*, ZHANG Min1, GONG Hui-li3. Research on t-SNE Similarity Measurement Method Based on Wasserstein Divergence[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3806-3812. |
[5] |
HUANG You-ju1, TIAN Yi-chao2, 3*, ZHANG Qiang2, TAO Jin2, ZHANG Ya-li2, YANG Yong-wei2, LIN Jun-liang2. Estimation of Aboveground Biomass of Mangroves in Maowei Sea of Beibu Gulf Based on ZY-1-02D Satellite Hyperspectral Data[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3906-3915. |
[6] |
BAI Xue-bing1, 2, SONG Chang-ze1, ZHANG Qian-wei1, DAI Bin-xiu1, JIN Guo-jie1, 2, LIU Wen-zheng1, TAO Yong-sheng1, 2*. Rapid and Nndestructive Dagnosis Mthod for Posphate Dficiency in “Cabernet Sauvignon” Gape Laves by Vis/NIR Sectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3719-3725. |
[7] |
WANG Qi-biao1, HE Yu-kai1, LUO Yu-shi1, WANG Shu-jun1, XIE Bo2, DENG Chao2*, LIU Yong3, TUO Xian-guo3. Study on Analysis Method of Distiller's Grains Acidity Based on
Convolutional Neural Network and Near Infrared Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3726-3731. |
[8] |
ZHANG Shu-fang1, LEI Lei2, LEI Shun-xin2, TAN Xue-cai1, LIU Shao-gang1, YAN Jun1*. Traceability of Geographical Origin of Jasmine Based on Near
Infrared Diffuse Reflectance Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3389-3395. |
[9] |
YANG Qun1, 2, LING Qi-han1, WEI Yong1, NING Qiang1, 2, KONG Fa-ming1, ZHOU Yi-fan1, 2, ZHANG Hai-lin1, WANG Jie1, 2*. Non-Destructive Monitoring Model of Functional Nitrogen Content in
Citrus Leaves Based on Visible-Near Infrared Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3396-3403. |
[10] |
FANG Zheng, WANG Han-bo. Measurement of Plastic Film Thickness Based on X-Ray Absorption
Spectrometry[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3461-3468. |
[11] |
FU Gen-shen1, LÜ Hai-yan1, YAN Li-peng1, HUANG Qing-feng1, CHENG Hai-feng2, WANG Xin-wen3, QIAN Wen-qi1, GAO Xiang4, TANG Xue-hai1*. A C/N Ratio Estimation Model of Camellia Oleifera Leaves Based on
Canopy Hyperspectral Characteristics[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3404-3411. |
[12] |
HUANG Meng-qiang1, KUANG Wen-jian2, 3*, LIU Xiang1, HE Liang4. Quantitative Analysis of Cotton/Polyester/Wool Blended Fiber Content by Near-Infrared Spectroscopy Based on 1D-CNN[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3565-3570. |
[13] |
HUANG Zhao-di1, CHEN Zai-liang2, WANG Chen3, TIAN Peng2, ZHANG Hai-liang2, XIE Chao-yong2*, LIU Xue-mei4*. Comparing Different Multivariate Calibration Methods Analyses for Measurement of Soil Properties Using Visible and Short Wave-Near
Infrared Spectroscopy Combined With Machine Learning Algorithms[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3535-3540. |
[14] |
KANG Ming-yue1, 3, WANG Cheng1, SUN Hong-yan3, LI Zuo-lin2, LUO Bin1*. Research on Internal Quality Detection Method of Cherry Tomatoes Based on Improved WOA-LSSVM[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3541-3550. |
[15] |
SUN Lin1, BI Wei-hong1, LIU Tong1, WU Jia-qing1, ZHANG Bao-jun1, FU Guang-wei1, JIN Wa1, WANG Bing2, FU Xing-hu1*. Identification Algorithm of Green Algae Using Airborne Hyperspectral and Machine Learning Method[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3637-3643. |
|
|
|
|