Abstract

Controlling and managing surface source pollution depends on the rapid monitoring of total nitrogen in water. However, the complex factors affecting water quality (plant shading and suspended matter in water) make direct estimation extremely challenging. Considering the spectral response mechanisms of emergent plants, we coupled discrete wavelet transform (DWT) and fractional order discretization (FOD) techniques with three machine learning models (random forest (RF), bagging algorithm (bagging), and eXtreme Gradient Boosting (XGBoost)) to mine this potential spectral information. A total of 567 models were developed, and airborne hyperspectral data processed with various DWT scales and FOD techniques were compared. The effective information in the hyperspectral reflectance data were better emphasized after DWT processing. After DWT processing the original spectrum (OR), its sensitivity to TN in water was maximally improved by 0.22, and the correlation between FOD and TN in water was optimally increased by 0.57. The transformed spectral information enhanced the TN model accuracy, especially for FOD after DWT. For RF, 82% of the model R2 values improved by 0.02~0.72 compared to the model using FOD spectra; 78.8% of the bagging values improved by 0.01~0.53 and 65.0% of the XGBoost values improved by 0.01~0.64. The XGBoost model with DWT coupled with grey relation analysis (GRA) yielded the best estimation accuracy, with the highest precision of R2 = 0.91 for L6. In conclusion, appropriately scaled DWT analysis can substantially improve the accuracy of extracting TN from UAV hyperspectral images. These outcomes may facilitate the further development of accurate water quality monitoring in sophisticated global waters from drone or satellite hyperspectral data.

Highlights

  • To investigate the strengths of discrete wavelet transform (DWT) analysis in extracting the Total nitrogen (TN) concentration in To investigate the strengths of DWT analysis in extracting the TN concentration in water from hyperspectral reflectance data, we summarized and compared the accuracy of water from hyperspectral reflectance data, we summarized and compared the accuracy of 567 models for the original spectrum (OR) hyperspectral reflectance, fractional order discretization (FOD), and wavelet power spectra

  • The results of this study indicate that the combination of DWT and grey relation analysis (GRA) generally enhances the accuracy of TN estimation in water (Table 2)

  • The results of this study in hyperspectral data processing and extraction of water quality parameters once again demonstrated that the application of hyperspectral reflectance to water quality remote sensing is effective and provides a new technological approach for global water environmental protection

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Summary

Introduction

Total nitrogen (TN), as an essential element in water, impacts the water quality of inland waters around the world and has a crucial bearing on the achievement of the United Nations’ sustainable development goals of water conservation and water pollution management [1,2,3]. Water quality issues remain a chronic problem of inland wetland ecosystems [4]. Due to the special characteristics of inland wetland water cycle retardation, environmental pollution caused by unreasonable human production activities and life processes, and the lack of effective monitoring and assessment methods for water bodies, water quality issues such as eutrophication in inland water bodies have arisen, affecting the Remote Sens. TN complicates the water situation through environmental cascades and related effects [8,9], and controlling the TN content of water in a timely and effective manner has become imperative for the government

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