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| A Method for Identifying Wood Grades of Chinese Zither Panel Based on Near Infrared Spectroscopy |
| HUANG Ying-lai, MENG Shi-yu, ZHAO Peng, YUE Meng-qiao |
| College of Information and Computer Engineering, Northeast Forestry University, Harbin 150040, China |
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Abstract At present,the wood grades of the national musical instrument Chinese zither panel mainly rely on the personal experience of the musical instrument technician.This method relies on experienced technicians and is susceptible to subjective judgment. In view of this situation, we use the Paulownia wood used to make the Chinese zither panel as an experimental sample. We propose a method of using near-infrared spectroscopy and the improved BP neural network to rapidly identify different grades of Chinese zither panels .Because Near-infrared spectroscopy can characterize a number of material structure and composition information, with the low cost of measuring instruments and many measuring accessories,we conduct an experimental analysis of the near-infrared spectral data of Paulownia panel. In the experiment, spectral denoising is first performed to eliminate system errors and improve spectral resolution, regarding the root mean square error and the square sum of signals as the evaluation criterions of various pretreatment methods.Therefore ,the first derivative is selected as the final pretreatment method, and 15 is the appropriate filter denoising window size.The principal component analysis is then used to compress the data and the Mahalanobis distance is used to eliminate the modeling set’s abnormal samples to create a more representative modeling set. Then, an unsupervised clustering is used to analyze the Paulownia panel grades , which proves the feasibility of grade classification.Since H2O has a large absorption in the near-infrared spectral region, according to experimental spectral analysis results,we do not consider the fundamental frequency vibration band (5 396 to 4 978 cm-1) and the first overtone vibration band (6 800 to 7 000 cm-1),but consider only the remaining near-infrared spectral band. Different spectral bands are combined, and seven bands are used as input to the neural network to carry out the panel grade recognition.We also improve the traditional BP neural network model. The learning rate of BP neural network is set by an adaptive optimization strategy to speed up the traditional neural network’s training rate.At the same time, the cross entropy function is used as the cost function to speed up the updating of the weight.The Relu function is selected as the transfer function between the input layer and the hidden layer, which improves the training speed of the model and effectively prevents over-fitting.The Softmax function is chosen as the transfer function of the last layer to reduce complex calculations. By this way, the final BP neural network is constructed.The amount of spectral information that can be extracted by different principal component variables is different.We adjust the input of the BP neural network model by increasing the number of principal components and adjusting the spectral band interval.When the number of principal components is 11 and the spectral intervals are 10 000 to 7 000 cm-1 and 4 976 to 4 000 cm-1, the unknown sample’s recognition rate reaches 99.7% , and the selected spectral range covers all the characteristis of C—H bond and other bond information.The results show that near-infrared spectroscopy combined with BP neural network can effectively identify different grades of Paulownia panel, thereby reducing manual detection errors, shortening the processing time, and better meeting the needs of the instrument market.
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Received: 2018-07-09
Accepted: 2018-11-04
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[1] ZHOU Li, DENG Xiao-wei, YU Zheng-yu(周 力, 邓小伟, 余征跃). Musical Instrument(乐器), 2017,(9): 20.
[2] FU Ming-jian(傅明鉴). Entertainment Technology(演艺科技), 2016,(5): 11.
[3] Standards for Light Industry of the People’s Republic of China(中华人民共和国轻工业行业标准). QB/T 1207.3—2011 Zheng(筝), 2011.
[4] ZHANG En-yang, XIA Wei-gao, YAN Xiao-jian(张恩阳, 夏维高, 闫晓剑). Information Recording Materials(信息记录材料), 2017, 18(6): 26.
[5] Tsuchikawa S, Kobori H. Journal of Wood Science, 2015, 61(3): 213.
[6] Horikawa Y, Mizuno-Tazuru S, Sugiyama J. J Wood Sci., 2015, 61: 251.
[7] PANG Xiao-yu, YANG Zhong, Lü Bin, et al(庞晓宇, 杨 忠, 吕 斌, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2016, 36(11): 3552.
[8] Hwang S W, Horikawa Y, Lee W H, et al. Journal of Wood Science, 2016, 62(2), 156.
[9] WANG Xue-shun, SUN Yi-dan, HUANG An-min(王学顺, 孙一丹, 黄安民, 等). Journal of Northeast Forestry University(东北林业大学学报), 2015, 43(12): 82.
[10] WANG Xue-shun, SUN Yi-dan, HUANG An-min(王学顺, 孙一丹, 黄安民). Forest Engineering(森林工程), 2015, 31(6): 65.
[11] YANG Zhong, HUANG An-min, JIANG Ze-hui(杨 忠, 黄安民, 江泽慧). Scientia Silvae Sinicae(林业科学), 2012, 48(10): 120.
[12] Alves A, Simoes R, Stackpole D J, et al. J Near Infrared Spectrosc., 2011, 19: 343.
[13] Brigitte Loblon, Oluantosin Adedipe, Guillaume Hans, et al. The Forestry Chronicle, 2013, 89(5): 595..
[14] XU Xiu-qin, CHEN Guo, ZHANG Hao, et al(许秀琴, 陈 国, 章 豪, 等). Anhui Chemical Industry(安徽化工), 2017, 43(4): 7. |
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