[1] K R Redeker, N Wang, JC Low et al. Emissions of Methyl Halides and Methane from rice paddies. Science, 290, 966-969(2000).
[2] J S Lansing, J N Kremer. Rice,fish,and the planet. Proceedings of the National Academy of Sciences, 108, 19841-19842(2011).
[4] Xing WANG, Xin ZHAO, YuQiao WANG et al. Assessment of the carbon footprint of rice production in China. Resources Science, 39, 713-722(2017).
[5] Sengjie YAN, Aixing DENG, Ziyin SHANG et al. Characteristics of carbon emission and approaches of carbon mitigation and sequestration for carbon neutrality in China’s crop production. Acta Agronomica Sinica, 48, 930-941(2022).
[6] Ming ZHAN. Studies on mechanisms of carbon sequestration, carbon emissions and soil organic carbon dynamics in different farming paddy fields(2009).
[7] Qiangsheng WANG. Regulation and mechanism of greenhouse gas emissions of circular agriculture ecosystem of planting and breeding in paddy. Chinese Journal of Eco-Agriculture, 26, 633-642(2018).
[8] G SUN, M SUN, L S DU et al. Ecological rice-cropping systems mitigate global warming - a meta-analysis. Science of the Total Environment, 789(2021).
[9] Mingli NI, Kai DENG, Wenyu ZHANG et al. Effects of rice-crayfish coculture on rice yield and food security. Chinese Journal of Eco-Agriculture, 30, 1293-1300(2022).
[10] Xuyi LI, Mingquan FU, Zhongzhi CHI et al. Cultivation methods in Chengdu basin: effect on growth and development and yield formation of different rice types. Chinese Agricultural Science Bulletin, 34, 1-7(2018).
[11] Jie LI, Hongcheng ZHANG, Yangyang DONG et al. Effects of cultivation methods on yield, growth stage and utilization of temperature and illumination of rice in different ecological regions. Scientia Agricultura Sinica, 44, 2661-2672(2011).
[12] Lang ZHANG, Huaqin XU, Linlin LI et al. Comparative study on CH4 emission from ratoon rice and double-cropping rice fields. Scientia Agricultura Sinica, 52, 2101-2113(2019).
[13] Weiling YUAN, Cougui CAO, Chengfang LI et al. Methane and nitrous oxide emissions from rice-fish and rice-duck complex ecosystems and the evaluation of their economic significance. Scientia Agricultura Sinica, 42, 2052-2060(2009).
[14] L LIN, S YANJU, X YING et al. Comparing rice production systems in China: economic output and carbon footprint. Science of the Total Environment, 791(2021).
[15] Wenchao CUI, Wenjun JIAO, Qingwen MIN. Environmental impact assessment of rice-fish culture with different land management models. Chinese Journal of Eco-Agriculture, 30, 630-640(2022).
[16] N TORBICK, W SALAS, D CHOWDHURY et al. Mapping rice greenhouse gas emissions in the Red River Delta, Vietnam. Carbon Management, 8, 99-108(2017).
[17] V N FIKRIYAH, R DARVISHZADEH, A LABORTE et al. Discriminating transplanted and direct seeded rice using Sentinel-1 intensity data. International Journal of Applied Earth Observation and Geoinformation, 76, 143-153(2019).
[18] S LIU, Y CHEN, Y MA et al. Mapping ratoon rice planting area in central China using Sentinel-2 time stacks and the phenology-based algorithm. Remote Sensing, 12, 3400(2020).
[19] P ZHAN, W ZHU, N LI. An automated rice mapping method based on flooding signals in Synthetic Aperture Radar time series. Remote Sensing of Environment, 252, 112112(2021).
[20] Y WEI, M LU, Q YU et al. Understanding the dynamics of integrated rice-crawfish farming in Qianjiang county,China using Landsat time series images. Agricultural Systems, 191, 103167(2021).
[21] Haodong WEI, Jingya YANG, Zhiwen CAI et al. Phenology windows and multi-sourcemedium-/high-resolution image extraction for rice-crayfish paddy fields mapping. National Remote Sensing Bulletin, 26, 1423-1436(2022).
[22] H WEI, Q HU, Z CAI et al. An object and topology-based analysis (OTBA) method for mapping rice-crayfish fields in south China. Remote Sensing, 13(2021).
[23] Z CAI, H WEI, Q HU et al. Learning spectral-spatial representations from VHR images for fine-scale crop type mapping: a case study of rice-crayfish field extraction in south China. ISPRS Journal of Photogrammetry and Remote Sensing, 199, 28-39(2023).
[25] N GORELICK, M HANCHER, M DIXON et al. Google Earth Engine: planetary-scale geospatial analysis for everyone. Remote Sensing of Environment, 202, 18-27(2017).
[26] H TAMIMINIA, B SALEHI, M MAHDIANPARI et al. Google Earth Engine for geo-big data applications: A meta-analysis and systematic review. ISPRS Journal of Photogrammetry and Remote Sensing, 164, 152-170(2020).
[27] S XU, X ZHU, J CHEN et al. A robust index to extract paddy fields in cloudy regions from SAR time series. Remote Sensing of Environment, 285, 113374(2023).
[28] L MENG, Y LI, R SHEN et al. Large-scale and high-resolution paddy rice intensity mapping using downscaling and phenology-based algorithms on Google Earth Engine. International Journal of Applied Earth Observation and Geoinformation, 128, 103725(2024).
[29] A MULLISSA, A VOLLRATH, C ODONGO-BRAUN et al. Sentinel-1 SAR backscatter analysis ready data preparation in Google Earth Engine. Remote Sensing, 13(2021).
[30] L CHANG, Y CHEN, J WANG et al. Rice-field mapping with Sentinel-1A SAR time-series data. Remote Sensing, 13, 103(2021).
[31] Lisha QIAN, Hao JIANG, Shuisen CHEN et al. Extracting field-scale crop distribution in Lingnan using spatiotemporal filtering of Sentinel-1 time-series data. Transactions of the Chinese Society of Agricultural Engineering, 38, 158-166(2022).
[32] Xinyi ZHAO, Bo TIAN, Ying NIU et al. Classification of coastal salt marsh based on Sentinel-1 time-series backscattering characteristics: the case of the Yangtze River delta. National Remote Sensing Bulletin, 26, 672-682(2022).
[33] Wenxuan ZHANG, Juanle WANG. Flood monitoring of Heilongjiang River basin in China and Russia transboundary region based on SAR backscattering characteristics. Journal of Geo-information Science, 24, 802-813(2022).
[34] Chong HUANG, Zhaoxin XU, Chenchen ZHANG et al. Extraction of rice planting structure in tropical region based on Sentinel-1 temporal features integration. Transactions of the Chinese Society of Agricultural Engineering, 36, 177-184(2020).
[35] D B NGUYEN, A GRUBER, W WAGNER. Mapping rice extent and cropping scheme in the Mekong Delta using Sentinel-1A data. Remote Sensing Letters, 7, 1209-1218(2016).
[36] Hongwei ZHAO, Zhongxin CHEN, Hao JIANG et al. Early growing stage crop species identification in southern China based on sentinel-1A time series imagery and one-dimensional CNN. Transactions of the Chinese Society of Agricultural Engineering, 36, 169-177(2020).
[37] Jianxi HUANG, Yuzhuo HOU, Wei SU et al. Mapping corn and soybean cropped area with GF-1 WFV data. Transactions of the Chinese Society of Agricultural Engineering, 33, 164-170(2017).
[38] Yingpin YANG, Zhifeng WU, Jiancheng LUO et al. Parcel-based crop distribution extraction using the spatiotemporal collaboration of remote sensing data. Transactions of the Chinese Society of Agricultural Engineering, 37, 166-174(2021).
[40] Ze HE, Shihua LI. Research progress on radar remote sensing for rice growth monitoring. National Remote Sensing Bulletin, 27, 2363-2382(2023).
[41] E NDIKUMANA, D HOTONGMINH, N BAGHDAD et al. Deep recurrent neural network for agricultural classification using multitemporal SAR Sentinel-1 for Camargue,France. Remote Sensing, 10, 10081217(2018).
[42] Tan-Hsu Tan et al. Spatial-temporal neural network for rice field classification from SAR Images. Remote Sensing, 14, 1929(2022).
