Research on the Temporal and Spatial Changes and Driving Forces of Rice Fields Based on the NDVI Difference Method

Research on the Temporal and Spatial Changes and Driving Forces of Rice Fields Based on the NDVI Difference Method

Rice is a globally important food crop, and it is crucial to accurately and conveniently obtain information on rice fields, understand their spatial patterns, and grasp their dynamic changes to address food security challenges. In this study, Chongqing’s Yongchuan District was selected as the resear...

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Veröffentlicht in:Agriculture (Basel) 2024-07, Vol.14 (7), p.1165
Hauptverfasser: Tian, Jinglian, Tian, Yongzhong, Wan, Wenhao, Yuan, Chenxi, Liu, Kangning, Wang, Yang
Format: Artikel
Sprache:eng
Schlagworte:
Agricultural production
Altitude
Chongqing
Data analysis
Digital Elevation Models
Digital imaging
driving forces
Food security
Food selection
Harvest
Harvesting
Image resolution
Irrigation
logistic regression model
Machine learning
Multiple regression analysis
NDVI
NDVI difference method
Normalized difference vegetative index
Regional analysis
Regression analysis
Regression models
Remote sensing
Residential areas
Residential location
Rice
Rice fields
Simulation models
Spatial data
Spatial distribution
Statistical analysis
Thresholds
Time series
Unmanned aerial vehicles
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Zusammenfassung:Rice is a globally important food crop, and it is crucial to accurately and conveniently obtain information on rice fields, understand their spatial patterns, and grasp their dynamic changes to address food security challenges. In this study, Chongqing’s Yongchuan District was selected as the research area. By utilizing UAVs (Unmanned Aerial Vehicles) to collect multi-spectral remote sensing data during three seasons, the phenological characteristics of rice fields were analyzed using the NDVI (Normalized Difference Vegetation Index). Based on Sentinel data with a resolution of 10 m, the NDVI difference method was used to extract rice fields between 2019 and 2023. Furthermore, the reasons for changes in rice fields over the five years were also analyzed. First, a simulation model of the rice harvesting period was constructed using data from 32 sampling points through multiple regression analysis. Based on the model, the study area was classified into six categories, and the necessary data for each region were identified. Next, the NDVI values for the pre-harvest and post-harvest periods of rice fields, as well as the differences between them, were calculated for various regions. Additionally, every year, 35 samples of rice fields were chosen from high-resolution images provided by Google. The thresholds for extracting rice fields were determined by statistically analyzing the difference in NDVI values within the sample area. By utilizing these thresholds, rice fields corresponding to six harvesting regions were extracted separately. The rice fields extracted from different regions were merged to obtain the rice fields for the study area from 2019 to 2023, and the accuracy of the extraction results was verified. Then, based on five years of rice fields in the study area, we analyzed them from both temporal and spatial perspectives. In the temporal analysis, a transition matrix of rice field changes and the calculation of the rice fields’ dynamic degree were utilized to examine the temporal changes. The spatial changes were analyzed by incorporating DEM (Digital Elevation Model) data. Finally, a logistic regression model was employed to investigate the causes of both temporal and spatial changes in the rice fields. The study results indicated the following: (1) The simulation model of the rice harvesting period can quickly and accurately determine the best period of remote sensing images needed to extract rice fields. (2) The confusion matrix shows the effec
ISSN:2077-0472
2077-0472
DOI:10.3390/agriculture14071165