The first fine-resolution mapping of contour-levee irrigation using deep Bi-Stream convolutional neural networks

•Statewide distribution of contour levee irrigation was mapped for the first time.•A bi-stream encoder-decoder model that copes with gradient vanishing was built.•Superpixel post-processing offers more meticulous field boundary depictions.•The performance of the pre-trained model exceeds the benchma...

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Veröffentlicht in:	International journal of applied earth observation and geoinformation 2021-12, Vol.105, p.102631, Article 102631
Hauptverfasser:	Liang, Lu, Meyarian, Abolfazl, Yuan, Xiaohui, Runkle, Benjamin R.K., Mihaila, George, Qin, Yuchu, Daniels, Jacob, Reba, Michele L., Rigby, James R.
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Sprache:	eng
Schlagworte:	Agriculture water conservation Arkansas Deep learning freshwater irrigated farming irrigation Irrigation practice Remote sensing rice spatial data
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container_title	International journal of applied earth observation and geoinformation
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creator	Liang, Lu Meyarian, Abolfazl Yuan, Xiaohui Runkle, Benjamin R.K. Mihaila, George Qin, Yuchu Daniels, Jacob Reba, Michele L. Rigby, James R.
description	•Statewide distribution of contour levee irrigation was mapped for the first time.•A bi-stream encoder-decoder model that copes with gradient vanishing was built.•Superpixel post-processing offers more meticulous field boundary depictions.•The performance of the pre-trained model exceeds the benchmark methods. Agricultural irrigation accounts for nearly 70% of global freshwater withdrawal. Among irrigation practices, contour-levee cascade irrigation is of particular interest as it is water-intensive and widely used in many rice production regions. Despite its significant environmental implications, no study has quantified the distribution of contour-levee irrigation. One major challenge of remote sensing-based contour-levee field detection is how to accurately identify the thin and curved levee lines whose appearance varies dramatically in different fields. This paper presents a new deep network-based method that jointly optimizes semantically meaningful features to quantify the contour-levee fields. This new method uses a bi-stream encoder-decoder architecture to capture spectral information and gradient features. To maintain image gradient sharpness, a skip connection approach is employed to facilitate gradient propagation across long-range connections. Moreover, the new method uses deep supervision to generate more informative features from the earlier hidden layers and superpixel segmentation to reduce classification noise as a post-processing step. By testing against 41 images across 10 Arkansas counties, the average accuracy was 86.23% and the method achieved 15%-17% improvement over benchmark methods. The results show that IrrNet-Bi-Seg maintains good transferability and is thus promising for larger-scale applications.
doi_str_mv	10.1016/j.jag.2021.102631
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Agricultural irrigation accounts for nearly 70% of global freshwater withdrawal. Among irrigation practices, contour-levee cascade irrigation is of particular interest as it is water-intensive and widely used in many rice production regions. Despite its significant environmental implications, no study has quantified the distribution of contour-levee irrigation. One major challenge of remote sensing-based contour-levee field detection is how to accurately identify the thin and curved levee lines whose appearance varies dramatically in different fields. This paper presents a new deep network-based method that jointly optimizes semantically meaningful features to quantify the contour-levee fields. This new method uses a bi-stream encoder-decoder architecture to capture spectral information and gradient features. To maintain image gradient sharpness, a skip connection approach is employed to facilitate gradient propagation across long-range connections. 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Agricultural irrigation accounts for nearly 70% of global freshwater withdrawal. Among irrigation practices, contour-levee cascade irrigation is of particular interest as it is water-intensive and widely used in many rice production regions. Despite its significant environmental implications, no study has quantified the distribution of contour-levee irrigation. One major challenge of remote sensing-based contour-levee field detection is how to accurately identify the thin and curved levee lines whose appearance varies dramatically in different fields. This paper presents a new deep network-based method that jointly optimizes semantically meaningful features to quantify the contour-levee fields. This new method uses a bi-stream encoder-decoder architecture to capture spectral information and gradient features. To maintain image gradient sharpness, a skip connection approach is employed to facilitate gradient propagation across long-range connections. 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Agricultural irrigation accounts for nearly 70% of global freshwater withdrawal. Among irrigation practices, contour-levee cascade irrigation is of particular interest as it is water-intensive and widely used in many rice production regions. Despite its significant environmental implications, no study has quantified the distribution of contour-levee irrigation. One major challenge of remote sensing-based contour-levee field detection is how to accurately identify the thin and curved levee lines whose appearance varies dramatically in different fields. This paper presents a new deep network-based method that jointly optimizes semantically meaningful features to quantify the contour-levee fields. This new method uses a bi-stream encoder-decoder architecture to capture spectral information and gradient features. To maintain image gradient sharpness, a skip connection approach is employed to facilitate gradient propagation across long-range connections. 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subjects	Agriculture water conservation Arkansas Deep learning freshwater irrigated farming irrigation Irrigation practice Remote sensing rice spatial data
title	The first fine-resolution mapping of contour-levee irrigation using deep Bi-Stream convolutional neural networks
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