Abstract
Accurate and timely monitoring of crops can help in better agriculture management. Remote sensing-based crop monitoring helps to track the real-time crop condition. Small farm holding, intercropping, multi-cropping, inadequate irrigation infrastructure, and other challenges are quite common to Indian farms. Satellite-based crop monitoring uses pixel-based analysis poses many challenges as the majority of Indian farms are smallholdings. Hence, to overcome these challenges a novel method has been proposed based on image processing, and machine learning (ML) algorithms in this chapter. In the study, Morbi or Morvi district of Gujarat state, India has been selected, where majority of holdings are small and marginal with cultivation of cotton, cumin, wheat, bajra, sesamum, and groundnut as major crops. In the study, optical satellite data from Sentinel-2 was used to delineate farm boundaries using standard deviation and perform crop classification by using Random Forest (RF) algorithm with approximately 85% accuracy and an F1-score of 0.84. Open-source Geographic Information System (GIS) platform QGIS was used to perform post-processing operations to handle raster, and vector data analysis. The proposed method can be applied to other areas where different farm holding sizes and multiple crops are grown.
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Acknowledgements
The authors would like to thank the Google Earth Engine (GEE) team for providing cloud-computing resources for data visualization and European Space Agency (ESA) for providing open-access data. The authors thank Amnex Infotechnologies Pvt. Ltd. for providing all the needed support and environment to work on this project. Additionally, the authors would like to thank anonymous reviewers for their helpful comments and suggestions.
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Kumar, J.P., Singhania, D., Patel, S.N., Dakwala, M. (2022). Crop Classification for Precision Farming Using Machine Learning Algorithms and Sentinel-2 Data. In: Reddy, G.P.O., Raval, M.S., Adinarayana, J., Chaudhary, S. (eds) Data Science in Agriculture and Natural Resource Management. Studies in Big Data, vol 96. Springer, Singapore. https://doi.org/10.1007/978-981-16-5847-1_7
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