Jianwei Zhou’s research while affiliated with China University of Geosciences and other places

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Publications (2)


Location of the study area and footprints of processed satellite data. a The gray area represents the approximate location of the study area, while the red area denotes the extent of the Tibetan Plateau; b the black-bordered area outlines the extent of the study area, the red triangle indicates the location of the Muli mine site, and the gray semi-transparent area is the Landsat data coverage area for the different paths/rows; c the number of three Landsat data types covering the study area
Flowchart of data analysis
Historical Landsat imagery of the area containing the mining disturbance, and schematic of the temporal segmentation for the pixel indicated by the red crosshair. The red hollow circles show the mining disturbance probability, the black solid circles show the vertices fitted by the LandTrendr algorithm, and the fitted segments are represented by straight segments, with different colors corresponding to different processes
Historical Landsat imagery of the area containing the different land use/cover changes, and schematic of the temporal segmentation for the pixel indicated by the red crosshair. The red hollow circles show the mining disturbance probability, the black solid circles show the vertices fitted by the LandTrendr algorithm, and the fitted segments are represented by straight segments. a Urban expansion, b road construction, c glacier melting, and d river change
Definition of the mining area filter by endValincrease and magincrease using the corresponding decision boundary. a, b Boxplots of data statistics with endValincrease and magincrease (the upper and lower limits of the boxes are the 5th and 95th percentiles). c, d ROC curve performances for endValincrease and magincrease, the black circles represent the optimum original decision boundary, and the blue circles represent the adjusted decision boundary

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Mapping annual dynamics of surface mining disturbances in the northeastern Tibetan Plateau using Landsat imagery and LandTrendr algorithm
  • Article
  • Publisher preview available

September 2024

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29 Reads

Hang Xu

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Xu Wang

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Jianwei Zhou

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[...]

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Liyan Yang

The exploitation and utilization of coal resources have significantly contributed to global energy security. However, this mining activity has inflicted considerable damage on the ecological environment, particularly on the Tibetan Plateau, where the impact on ecosystems may be even more detrimental. The implementation of high-intensity mining activities leads to rapid changes in land cover/land use. Consequently, it is essential to accurately and effectively monitor mining disturbances. In this study, we propose an approach to capture surface mining disturbances using spatial–temporal rules and time series stacks of Landsat data. First, a time series of annual mining disturbance probability was generated based on Landsat temporal-spectral metrics and random forest. Second, the Landsat-based detection of Trends in Disturbance and Recovery (LandTrendr) algorithm was employed to segment the time series and detect breakpoints. Finally, mining disturbances were captured by further restricting the output of LandTrendr based on spatial–temporal rules of mining disturbances. This approach was applied and evaluated in the Muli mining area of the northeastern Tibetan Plateau, which experienced large-scale and rapid mining disturbances from 2004 to 2014, and identified a disturbed mining area of 43.62 km². The mining sites have been reclaimed after mining, and all reclamation work was done after 2016, with a total reclaimed area of 22.28 km². The validation results indicated that the overall accuracy of mining disturbance and reclamation mapping ranges from 0.7333 to 0.8667, and the F1 scores for mining disturbances and reclamation range from 0.7551 to 0.8723. This study provides a reliable framework for monitoring mining disturbances and reclamation in surface mines, promising to be useful in realizing disturbance monitoring in surface mines for a wide range of mineral types.

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Analysis of Vegetation Canopy Spectral Features and Species Discrimination in Reclamation Mining Area Using In Situ Hyperspectral Data

June 2024

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24 Reads

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2 Citations

The effective identification of reclaimed vegetation species is important for the subsequent management of ecological restoration projects in mining areas. Hyperspectral remote sensing has been used for identifying vegetation species. However, few studies have focused on mine-reclaimed vegetation. Even if there are studies in this field, the methods used by the researches are mainly traditional discriminant analyses. The environmental conditions of reclaimed mining areas lead to significant intraclass spectral differences in reclaimed vegetation, and there is uncertainty in the identification of reclaimed vegetation species using traditional classification models. In this study, in situ hyperspectral data were used to analyze the spectral variation in the reclaimed vegetation canopy in mine restoration areas and evaluate their potential in the identification of reclaimed vegetation species. We measured the canopy spectral reflectance of five vegetation species in the study area using the ASD FieldSpec 4. The spectral characteristics of vegetation canopy were analyzed by mathematically transforming the original spectra, including Savitzky–Golay smoothing, first derivative, reciprocal logarithm, and continuum removal. In addition, we calculated indicators for identifying vegetation species using mathematically transformed hyperspectral data. The metrics were submitted to a feature selection procedure (recursive feature elimination) to optimize model performance and reduce its complexity. Different classification algorithms (regularized logistic regression, back propagation neural network, support vector machines with radial basis function kernel, and random forest) were constructed to explore optimal procedures for identifying reclaimed vegetation species based on the best feature metrics. The results showed that the separability between the spectra of reclaimed vegetation can be improved by applying different mathematical transformations to the spectra. The most important spectral metrics extracted by the recursive feature elimination (RFE) algorithm were related to the visible and near-infrared spectral regions, mainly in the vegetation pigments and water absorption bands. Among the four identification models, the random forest had the best recognition ability for reclaimed vegetation species, with an overall accuracy of 0.871. Our results provide a quantitative reference for the future exploration of reclaimed vegetation mapping using hyperspectral data.

Citations (1)


... Within the range of visible wavelength (from 500 nm to 600 nm), the reflectance of the six pear varieties showed a notable increase as the wavelength enlarged. The absorption peak at 680 nm was attributed to the presence of chlorophyll in the peel of the pear [30], while the peak variation at 920 nm was associated with water absorption [31]. All the pear varieties maintained high reflectance levels in the near-infrared region, but the extent of the changes exhibited differences. ...

Reference:

Detection of Pear Quality Using Hyperspectral Imaging Technology and Machine Learning Analysis
Analysis of Vegetation Canopy Spectral Features and Species Discrimination in Reclamation Mining Area Using In Situ Hyperspectral Data