A deep learning framework to map riverbed sand mining budgets in large tropical deltas
Rapid urbanization has dramatically increased the demand for river sand, leading to soaring sand extraction rates that often exceed natural replenishment in many rivers globally. However, our understanding of the geomorphic and social-ecological impacts arising from Sand Mining (SM) remains limited,...
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Earth and Environmental Sciences Deep learning Sand mining Kumar, Sonu Park, Edward Tran, Dung Duc Wang, Jingyu Ho, Huu Loc Feng, Lian Kantoush, Sameh A. Binh, Doan Van Li, Dongfeng Switzer, Adam D. A deep learning framework to map riverbed sand mining budgets in large tropical deltas |
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Rapid urbanization has dramatically increased the demand for river sand, leading to soaring sand extraction rates that often exceed natural replenishment in many rivers globally. However, our understanding of the geomorphic and social-ecological impacts arising from Sand Mining (SM) remains limited, primarily due to insufficient data on sand extraction rates. Conventionally, bathymetry surveys and compilation of declared amounts have been used to quantify SM budgets, but they are often costly and laborious, or result in inaccurate quantification. Here, for the first time, we developed a Remote Sensing (RS)-based Deep Learning (DL) framework to map SM activities and budgets in the Vietnamese Mekong Delta (VMD), a global SM hotspot. We trained a near real-time object detection system to identify three boat classes in Sentinel-1 imagery: Barge with Crane (BC), Sand Transport Boat (STB), and other boats. Our DL model achieved a 96.1% Mean Average Precision (mAP) across all classes and 98.4% for the BC class, used in creating an SM boat density map at an Intersection over Union (IoU) threshold of 0.50. Applying this model to Sentinel-1, 256,647 boats were detected in the VMD between 2014–2022, of which 17.4% were BC. Subsequently, the annual SM budget was estimated by correlating it with a recent riverbed incision map. Our results showed that, between 2015–2022, about 366 Mm3 of sand has been extracted across the VMD. The annual budget has progressively increased from 34.92 Mm3 in 2015 to 53.25 Mm3 in 2022 (by 52%), with an annual increment of around 2.79 Mm3. At the provincial-scale, Dong Thap, An Giang, Vinh Long, Tien Giang, and Can Tho were the locations of intensive mining, accounting for 89.20% of the total extracted volume in the VMD. Finally, our estimated budgets were validated with previous research that yielded a correlation coefficient of 0.99% (with bias of 2.65%). The automatic DL framework developed in this study to quantify SM budgets has a high potential to be applied to other deltas worldwide also facing intensive SM. |
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Asian School of the Environment |
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Asian School of the Environment Kumar, Sonu Park, Edward Tran, Dung Duc Wang, Jingyu Ho, Huu Loc Feng, Lian Kantoush, Sameh A. Binh, Doan Van Li, Dongfeng Switzer, Adam D. |
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Article |
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Kumar, Sonu Park, Edward Tran, Dung Duc Wang, Jingyu Ho, Huu Loc Feng, Lian Kantoush, Sameh A. Binh, Doan Van Li, Dongfeng Switzer, Adam D. |
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Kumar, Sonu |
| title |
A deep learning framework to map riverbed sand mining budgets in large tropical deltas |
| title_short |
A deep learning framework to map riverbed sand mining budgets in large tropical deltas |
| title_full |
A deep learning framework to map riverbed sand mining budgets in large tropical deltas |
| title_fullStr |
A deep learning framework to map riverbed sand mining budgets in large tropical deltas |
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A deep learning framework to map riverbed sand mining budgets in large tropical deltas |
| title_sort |
deep learning framework to map riverbed sand mining budgets in large tropical deltas |
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2024 |
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https://hdl.handle.net/10356/174009 |
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1794549295812182016 |
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sg-ntu-dr.10356-1740092024-03-11T15:30:41Z A deep learning framework to map riverbed sand mining budgets in large tropical deltas Kumar, Sonu Park, Edward Tran, Dung Duc Wang, Jingyu Ho, Huu Loc Feng, Lian Kantoush, Sameh A. Binh, Doan Van Li, Dongfeng Switzer, Adam D. Asian School of the Environment Earth Observatory of Singapore Earth and Environmental Sciences Deep learning Sand mining Rapid urbanization has dramatically increased the demand for river sand, leading to soaring sand extraction rates that often exceed natural replenishment in many rivers globally. However, our understanding of the geomorphic and social-ecological impacts arising from Sand Mining (SM) remains limited, primarily due to insufficient data on sand extraction rates. Conventionally, bathymetry surveys and compilation of declared amounts have been used to quantify SM budgets, but they are often costly and laborious, or result in inaccurate quantification. Here, for the first time, we developed a Remote Sensing (RS)-based Deep Learning (DL) framework to map SM activities and budgets in the Vietnamese Mekong Delta (VMD), a global SM hotspot. We trained a near real-time object detection system to identify three boat classes in Sentinel-1 imagery: Barge with Crane (BC), Sand Transport Boat (STB), and other boats. Our DL model achieved a 96.1% Mean Average Precision (mAP) across all classes and 98.4% for the BC class, used in creating an SM boat density map at an Intersection over Union (IoU) threshold of 0.50. Applying this model to Sentinel-1, 256,647 boats were detected in the VMD between 2014–2022, of which 17.4% were BC. Subsequently, the annual SM budget was estimated by correlating it with a recent riverbed incision map. Our results showed that, between 2015–2022, about 366 Mm3 of sand has been extracted across the VMD. The annual budget has progressively increased from 34.92 Mm3 in 2015 to 53.25 Mm3 in 2022 (by 52%), with an annual increment of around 2.79 Mm3. At the provincial-scale, Dong Thap, An Giang, Vinh Long, Tien Giang, and Can Tho were the locations of intensive mining, accounting for 89.20% of the total extracted volume in the VMD. Finally, our estimated budgets were validated with previous research that yielded a correlation coefficient of 0.99% (with bias of 2.65%). The automatic DL framework developed in this study to quantify SM budgets has a high potential to be applied to other deltas worldwide also facing intensive SM. Ministry of Education (MOE) National Research Foundation (NRF) Published version This research was supported by various grants from the Ministry of Education, Singapore, under its Academic Research #Tier 1 [RG142/22], #Tier 1 [2021-T1-001-056], #Tier 2 [MOE-T2EP402A20-0001], and #Tier 2 [MOE-T2EP50222-0007] and the Earth Observatory of Singapore (EOS) via its funding from the National Research Foundation Singapore and the Singapore Ministry of Education under the Research Centres of Excellence initiative. 2024-03-11T08:53:28Z 2024-03-11T08:53:28Z 2024 Journal Article Kumar, S., Park, E., Tran, D. D., Wang, J., Ho, H. L., Feng, L., Kantoush, S. A., Binh, D. V., Li, D. & Switzer, A. D. (2024). A deep learning framework to map riverbed sand mining budgets in large tropical deltas. GIScience & Remote Sensing, 61(1), 2285178-. https://dx.doi.org/10.1080/15481603.2023.2285178 1943-7226 https://hdl.handle.net/10356/174009 10.1080/15481603.2023.2285178 2-s2.0-85180451341 1 61 2285178 en RG142/22 2021-T1-001-056 MOE- T2EP402A20-0001 MOE-T2EP50222-0007 GIScience & Remote Sensing © 2023 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group. This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial License (http://creativecommons.org/licenses/by-nc/4.0/), which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited. The terms on which this article has been published allow the posting of the Accepted Manuscript in a repository by the author(s) or with their consent. application/pdf |