Extracting Method of the Cultivation Aera of Rice Based on Sentinel-1/2 and Google Earth Engine (GEE): A Case Study of the Hangjiahu Plain

doi:10.12133/j.smartag.SA202502003

Abstract

Abstract:

[Objective] Accurate monitoring of rice planting areas is vital for ensuring national food security, evaluating greenhouse gas emissions, optimizing water resource allocation, and maintaining agricultural ecosystems. In recent years, the integration of remote sensing technologies—particularly the fusion of optical and synthetic aperture radar (SAR) data—has significantly enhanced the capacity to monitor crop distribution, even under challenging weather conditions. However, many current studies still rely heavily on phenological features captured at specific key stages, such as the transplanting phase, while overlooking the complete temporal dynamics of vegetation and water-related indices throughout the entire rice growth cycle. There is an urgent need for a method that fully leverages the time-series characteristics of remote sensing indices to enable accurate, scalable, and timely rice mapping. [Methods] Focusing on the Hangjiahu Plain, a typical rice-growing region in eastern China, a novel approach—dynamic NDVI-SDWI Fusion method for rice mapping (DNSF-Rice) was proposed in this research to accurately extract rice planting areas by synergistically integrating Sentinel-1 SAR and Sentinel-2 optical imagery on the google earth engine (GEE) platform. The methodological framework included the following three steps: First, using Sentinel-2 imagery, a time series of the normalized difference vegetation index (NDVI) was constructed. By analyzing its temporal dynamics across key rice growth stages, potential rice planting areas were identified through a threshold-based classification method; Second, a time series of the Sentinel-1 dual-polarized water index (SDWI) was generated to analyze its dynamic changes throughout the rice growth cycle. A thresholding algorithm was then applied to extract rice field distribution based on microwave data, considering the significant irrigation involved in rice cultivation; Finally, the spatial intersection of the NDVI-derived and SDWI-derived results was intersected to generate the final rice planting map. This step ensures that only pixels exhibiting both vegetation growth and irrigation signals were classified as rice. The classification datasets spanned five consecutive years from 2019 to 2023, with a spatial resolution of 10 m. [Results and Discussions] The proposed method demonstrated high accuracy and robust performance in mapping rice planting areas. Over the study period, the method achieved an overall accuracy of over 96% and an F₁-Score exceeding 0.96, outperforming several benchmark products in terms of spatial consistency and precision. The integration of NDVI and SDWI time-series features enabled effective identification of rice fields, even under the challenging conditions of frequent cloud cover and variable precipitation typical in the study area. Interannual analysis revealed a consistent increase in rice planting areas across the Hangjiahu Plain from 2019 to 2023. The remote sensing-based rice area estimates were in strong agreement with official agricultural statistics, further validating the reliability of the proposed method. The fusion of optical and SAR data proved to be a valuable strategy, effectively compensating for the limitations inherent in single-source imagery, especially during the cloudy and rainy seasons when optical imagery alone was often insufficient. Furthermore, the use of GEE facilitated the rapid processing of large-scale time-series data, supporting the operational scalability required for regional rice monitoring. This study emphasized the critical importance of capturing the full temporal dynamics of both vegetation and water signals throughout the entire rice growth cycle, rather than relying solely on fixed phenological stages. [Conclusions] By leveraging the complementary advantages of optical and SAR imagery and utilizing the complete time-series behavior of NDVI and SDWI indices, the proposed approach successfully mapped rice planting areas across a complex monsoon climate region over a five-year period. The method has been proven to be stable, reproducible, and adaptable for large-scale agricultural monitoring applications.

Key words: remote sensing, GEE, cultivation aera extraction, Sentinel-1, SAR, NDVI

CLC Number:

TP79

E Hailin, ZHOU Decheng, LI Kun. Extracting Method of the Cultivation Aera of Rice Based on Sentinel-1/2 and Google Earth Engine (GEE): A Case Study of the Hangjiahu Plain[J]. Smart Agriculture, 2025, 7(2): 81-94.

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参数	Sentinel-1 SAR GRD	Sentinel-2 Level-2A
年份	2019—2023年	2019—2023年
时间范围	6月—12月	6月—12月（2020年为次年1月）
含云量	——	<30%
成像模式	IW	——
极化模式/波段	VV、VH	B2、B3、B4、B8

地物类型	采集时间	采集样点数量及说明
水稻	2022年7—11月	大部分间歇性采样，共获取99个样点；其中有20个样点由移栽期开始，持续1次/月监测至收割
水稻	2023年7—11月	大部分间歇性采样，共获取130个样点，其中有20个样点由移栽期开始，持续1次/月监测至收割
森林	2023年4—9月	间歇性采样，共采集84个样点
其他	2023年4—9月	间歇性采样，共采集67个样点

产品简称	年份	空间分辨率/m	遥感数据源	核心方法	数据来源
APRA500^［43］	2000—2021年	500	Terra/Aqua MODIS	物候指数特征法	https：//cstr.cn/15732.11.nesdc.ecodb.rs.2022.029
Rice-TWDTW^［44］	2017—2023年	10	Sentinel-1/2	光谱时序曲线匹配法	https：//cstr.cn/31253.11.sciencedb.06963
EARice10^［45］	2023年	10	Sentinel-1/2	物候指数特征法	https：//doi.org/10.5281/zenodo.13118409

区/县名称	提取面积/km²	统计面积/km²	差值/km²
余杭区	66.44	76.82	-10.38
临平区	13.52	10.73	2.79
德清县	39.99	52.00	-12.01
南浔区	94.41	119.75	-25.34
吴兴区	61.47	76.06	-14.59
海宁市	100.03	117.60	-17.57
桐乡市	98.96	129.40	-30.44
秀洲区	113.05	130.80	-17.75
嘉善县	108.79	134.20	-25.41
平湖市	126.45	155.70	-29.25
南湖区	66.40	83.30	-16.9
海盐县	119.61	120.90	-1.29

产品名称	UA/%	PA/%	Kappa	OA/%	F ₁-Score
APRA500水稻制图（500 m，2021年）	26	77	0.18	59	0.39
Rice-TWDTW水稻制图（10 m，2023年）	51	93	0.48	74	0.66
EARice10水稻制图（10 m，2023年）	93	97	0.90	95	0.95