Research on Water Spectral Differences Based on Field Object
Spectrometer and Water Spectrometer
CAO Xiao-yi1, CUI Jian-yong1*, DONG Wen2, XU Ming-ming1, WAN Jian-hua1
1. College of Oceanography and Space Informatics, China University of Petroleum (East China), Oingdao 266580, China
2. Academy of Aerospace Information Innovation, Chinese Academy of Sciences, Beijing 100094, China
Abstract:In-site measured water spectral data is the basis of remote sensing inversion. Field object spectrometers are usually used to measure water spectral data. However, the usability of field object spectrometers for water measurements is difficult to evaluate. This article uses the data from the water measurement experiments of the field object spectrometer and the water spectrometer to conduct a difference analysis in terms of noise immunity, measurement results, external environment affecting the two types of instruments, and water quality parameter inversion. Before comparing the differences between the two types of spectrometers for water spectrum measurement, a comparison of the anti-noise capabilities of the two instruments found that the water spectrometer has a stronger anti-noise ability, so the data of the water spectrometer is used as a reference standard for analysis. First of all, regarding the difference in solar irradiance, the correlation coefficient of the solar irradiance measured by the two types of instruments varies in the range of 0.5~0.75, and there is a correlation between the solar irradiance of the two instruments; Secondly, by comparing the changes in skylight radiance at the five wavelengths of 361, 411, 461, 511, and 561 nm, we found that the range of changes in solar radiance obtained by the water spectrometer is smaller. The data acquisition is more stable than the field object spectrometer. By comparing the changes in the total radiance of the sea surface at different times, it is found that there are differences in the radiance obtained by the water spectrometer at different times, and the two change curves are different. The signal-to-noise ratio of the field object spectrometer decreases when the sunlight is weak, resulting in drastic fluctuations in the observed values of each band. The calculated reflectivity difference is obvious before 10 am and after 4 pm. Finally, the comparison shows that the external environment under different wind speed conditions impacts the air-water interface reflectance during the processing of the two instruments. The data needs to be corrected according to the value of the air-water interface reflectance corresponding to the wind speed so that the remote sensing reflectance obtained can be more precise. After the spectrometer obtains the water reflection spectrum curve, it is usually used for quantitative inversion of water quality parameters. To compare and analyze the impact of the observation results of the two spectrometers on the inversion accuracy of water quality parameters, this paper uses the water reflection spectrum curves observed by the two instruments to estimate the suspended matter concentration. The inversion is compared with the experimental test results of water samples collected at the corresponding locations. It is found that the two results are quite different. The accuracy of the water spectrometer is higher than that of the field object spectrometer. In addition, the two instruments could not be mixed, making the result error even greater. Through the processing and analysis of data obtained by two spectrometers and the inversion of water quality parameters, this article provides suggestions for water measurement using field object spectrometers to obtain more accurate and reliable water spectrum curves.
Key words:Spectrometer; Water spectrum measurement; Remote sensing reflectance; Difference analysis
曹晓艺,崔建勇,董 文,许明明,万剑华. 野外地物光谱仪和水体光谱仪测量水体光谱差异研究[J]. 光谱学与光谱分析, 2025, 45(03): 753-760.
CAO Xiao-yi, CUI Jian-yong, DONG Wen, XU Ming-ming, WAN Jian-hua. Research on Water Spectral Differences Based on Field Object
Spectrometer and Water Spectrometer. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(03): 753-760.
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