基于近红外漫反射测量的便携式土壤有机质测定仪的开发

doi:10.3964/j.issn.1000-0593(2010)04-1146-05

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摘要：开发了一款基于近红外漫反射测量的便携式土壤有机质测定仪。测定仪主要由光学单元和电路单元组成。光学单元包括光源、入射和反射光信号传导光纤、光电转换器件等。电路单元包括光源驱动电路，放大电路、A/D转换电路、液晶显示和U盘存储电路等。工作时探头部分插入土壤形成密闭空间，光源发出的光通过入射光纤传送到探头的顶端，并照射顶端周围的土壤;来自土壤的漫反射光沿反射光纤被传送到光电转换器件，产生的电流再被送至电路单元进行放大、滤波、A/D转换、显示和存储。分别针对自然土样和烘干土样的性能试验结果表明，反射率和SOM含量之间具有很高的相关性，在土壤有机质实际含量大于2%时，平均相对误差率低于5%。开发的仪器能够满足农业生产需要。

关键词：近红外光谱学;漫反射;土壤有机质;测定仪

Abstract：A portable soil organic matter detector based on near infrared diffuse reflectance was developed. The detector uses a microprocessor 89S52 as the micro controller unit (MCU) and consists of an optical system and a control system. The optical system includes an 850 nm near-infrared LED lamp-house, a lamp-house driving-circuit, a Y type optical fiber, a probe, and a photoelectric sensor. The control system includes an amplifying circuit, an A/D circuit, a display circuit with LCD, and a storage circuit with USB interface. Firstly the single waveband optical signal from the near-infrared LED is transferred to the surface of the target soil via the incidence fibers. Then the reflected optical signal is collected and transferred to the photoelectric sensor, where the optical signal is converted to the electrical signal. Subsequently, the obtained electrical signal is processed by 89S52 MCU. Finally, the calculated soil organic matter content is displayed on the LCD and stored in the USB disk. The calibration experiments using the estimation model of the soil organic matter were conducted. Thirteen kinds of natural soil samples were prepared, each divided into five sub-samples. After measurement, the natural samples were dried under the condition of 105 ℃ for 24 h, and then the same measurements were performed. The analysis of the correlation between the detected SOM content and the measured reflectance was carried out. For the natural soil samples, R²=0.907, while R² reached 0.963 for the dried soil samples. The average reflectance of the five sub-samples from the same kind soil was calculated for each kind of soil. And then the same correlation analysis was conducted, for the natural samples R²=0.950, and for the dried samples R²=0.982. The results showed that the developed detector is practical. And the soil moisture has an effect on the accuracy of the detector. It is necessary to correct the real time measurement result of the detector based on soil moisture.

Key words：NIR spectroscopy;Diffuse reflection;Soil organic matter;Detector

收稿日期: 2009-04-08 修订日期: 2009-07-10

中图分类号:	O657.3
	S151.9

通讯作者: 李民赞 E-mail: limz@cau.edu.cn

引用本文:

李民赞，潘娈，郑立华，安晓飞 . 基于近红外漫反射测量的便携式土壤有机质测定仪的开发 [J]. 光谱学与光谱分析, 2010, 30(04): 1146-1150.
LI Min-zan, PAN Luan, ZHENG Li-hua, AN Xiao-fei . Development of a Portable SOM Detector Based on NIR Diffuse Reflection . SPECTROSCOPY AND SPECTRAL ANALYSIS, 2010, 30(04): 1146-1150.

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[1] BAO Shi-dan(鲍士旦). Soil and Agricultural Chemistry Analysis(土壤农化分析). Beijing: China Agriculture Press(北京: 中国农业出版社), 2000.
[2] Bowers S, Hanks R. Soil Sci., 1965, 100: 130.
[3] Al-Abbas A, Swain H, Baumgardner M. Soil Sci., 1972, 114: 477.
[4] Krishnan P, Alexander J, Butler B. Soil Sci. Soc. Am. J, 1980, 44: 1282.
[5] Krishnan P, Butler B J, Hummel J. Transactions of the ASAE, 1981, 24(2): 306.
[6] Dalal R, Henry R. Soil Sci. Soc. Am. J., 1986, 50: 120.
[7] Morra M, Hall M, Freeborn L. Soil Sci. Soc. Am. J., 1991, 55: 288.
[8] Ben-Dor E, Banin A. Soil Sci. Soc. Am. J., 1995, 59: 364.
[9] Sudduth K, Hummel J. Transactions of the ASAE, 1993, 36(1): 185.
[10] Reeves E, McCarty G, Meisinger J. Journal of Near Infrared Spectrosc., 1999, 7: 179.
[11] Reeves E, Van Kessel J. Journal of Near Infrared Spectrosc., 1999, 7: 195.
[12] Hummel J, Sudduth K, Hollinger S. Computers and Electronics in Agriculture, 2001, 32: 149.
[13] PENG Yu-kui, ZHANG Jian-xin, HE Xu-sheng, et al(彭玉魁, 张建新, 何绪生, 等). Acta Pedologica Sinica(土壤学报), 1998, 35(4): 553.
[14] YU Fei-jian, MIN Shun-geng, JU Xiao-tang, et al(于飞健, 闽顺耕, 巨晓棠, 等). Chinese Journal of Analytical Laboratory(分析试验室), 2002, 21(3): 49.
[15] LI Min-zan(李民赞). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报), 2003, 19(5): 36.
[16] ZHU Deng-sheng, WU Di, SONG Hai-yan, et al(朱登胜, 吴迪, 宋海燕, 等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报), 2008, 24(6): 196.
[17] DING Hai-quan, LU Qi-peng, PIAO Ren-guan, et al(丁海泉, 卢启鹏, 朴仁官, 等). Optics and Precision Engineering(光学精密工程), 2007, 15(12): 1946.
[18] CHEN Peng-fei, LIU Liang-yun, WANG Ji-hua, et al(陈鹏飞, 刘良云, 王纪华, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2008, 28(2): 295.
[19] Shonk J, Gaultney L, Schulze D, et al. Transactions of the ASAE, 1991, 34(5): 1978.
[20] Li M, Sasao A, Shibusawa S, et al. Journal of the Japanese Society of Agricultural Machinery, 2000, 62(3): 111.
[21] LI Jin-yang, ZUO Yue-ming, ZHANG Jun(李晋阳, 左月明, 张军). Transactions of the Chinese Society for Agricultural Machinery(农业机械学报), 2007, 38(8): 117.