基于时空数据融合的江汉平原水稻种植信息提取

doi:10.11870/cjlyzyyhj201706010

Abstract

Abstract: Paddy rice is an important crop in China. Extracting rice planting information timely and accurately is of great significance for food policy, food security and agricultural development. However, there are two difficulties in extracting rice planting information based on remote sensing in Southern China. One is the paddy rice growth period is accompanied by abundant precipitation. This makes the remote sensing imagery influenced by serious "cloud contamination". The other one is the cultivated land is not concentrated, making the crop classification result influenced by the phenomenon of "salt and pepper". To solve the problem of lacking available data in extracting paddy rice planting information based on remote sensing, we used Spatial and Temporal Data Fusion Approach (STDFA) to fuse the Landsat 8 and time-series MODIS images and gained the data which had the same temporal resolution with MODIS data and the same spatial resolution with Landsat 8 images. The correlation of reflectance about the red and near-infrared of fused data and true data is 0.84 and 0.81. To address the phenomenon of "salt and pepper", we used the object oriented image analysis method to derive the fusion result into several image objects and then classify and map the rice distribution in the study area. Using multi-temporal data has a higher accuracy relative to use single phase data in crop mapping, and that method has become an important way to crop classification based on remote sensing. Normalized difference vegetation index (NDVI) is widely used in vegetation classification. Based on the above two points, we used the time-series red and near-infrared data to calculate the time-series NDVI of each image object. Mostly, time-series NDVI data obtained by satellite included various noise components. To obtain change characteristics of NDVI before and after harvest of winter wheat, we used the HANTs filtering method for nosie reduction. Then we used the NDVI data to map the paddy rice fields though Support Vector Machine (SVM) method. We built the confusion matrix though the samples which came from field measurements and validated the extraction accuracy of rice. The Kappa index is 0.91 and the total classification accuracy is 93.16%. The result showed that:(1) Spatial and Temporal Data Fusion Approach has the ability to rebuild the time-series data which has had the high temporal resolution and the high spatial resolution in Southern China; (2) The object-orient method shows a high accuracy in mapping the paddy rice, suggesting that the object-orient classification method can also reduce the "salt and pepper" phenomenon in the clutter blocks.

Key words: Jianghan plain, remote sensing, spatial and temporal data fusion, paddy rice

CLC Number:

TP79

LU Jun, HUANG Jin-liang, WANG Li-hui, PEI Yan-yan. PADDY RICE PLANTING INFORMATION EXTRACTION BASED ON SPATIAL AND TEMPORAL DATA FUSION APPROACH IN JIANGHAN PLAIN[J].RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, 2017, 26(06): 874-881.

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PADDY RICE PLANTING INFORMATION EXTRACTION BASED ON SPATIAL AND TEMPORAL DATA FUSION APPROACH IN JIANGHAN PLAIN

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