用于沿海地区数字孪生应用的有监督多区域分割机器学习架构

IF 1.7 4区 环境科学与生态学 Q4 ENVIRONMENTAL SCIENCES
Mohsen Ahmadi, Ahmad Gholizadeh Lonbar, Mohammadsadegh Nouri, Amir Sharifzadeh Javidi, Ali Tarlani Beris, Abbas Sharifi, Ali Salimi-Tarazouj
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引用次数: 0

摘要

本研究的目的是结合数字孪生模型和深度学习技术,在佛罗里达州沿海地区绘制全球地形和海拔地图。利用美国地质调查局(USGS)的数据,我们能够表现多种地貌,同时确保高程变化的准确性。为了减少投影失真,我们对全球范围内的 5000 个地图片段进行了重新缩放,确保包含关键的地理特征。我们将地形划分为七个不同的类别:水域、草原、森林、丘陵、沙漠、山地和苔原。通过中值滤波增强了地图特征,并对每个类别进行了颜色编码。在重叠的图像集中引入了随机参数,以确保多样性并防止冗余。在这七个地形类别中,U-Net 网络用于执行分割任务。为了监测模型的性能,我们进行了交叉验证。稳健的 ROC 曲线分析和较高的 AUC 值证明了模型的有效性,这表明地形分类准确无误。利用深度学习方法和谷歌地球的卫星图像,我们的主要目标是开发佛罗里达州海岸线的数字孪生模型。数字孪生既是物理模型,也是仿真模型,与现实世界中的地点精确相似。除了实现详细的地形测绘外,这种方法还可能在环境监测和城市规划方面有重要应用。就可靠性和性能而言,数字孪生模型有望成为地理信息系统领域的一大进步。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Supervised multi-regional segmentation machine learning architecture for digital twin applications in coastal regions

Supervised multi-regional segmentation machine learning architecture for digital twin applications in coastal regions

The objective of this study is to develop a global terrain and altitude map by combining a digital twin model and deep learning technique on Florida's coastal area. Utilizing USGS data, we are able to represent diverse landforms while ensuring the accuracy of elevation changes. In order to mitigate projection distortions, we rescaled 5000 map segments worldwide, ensuring that key geographical features are included. We segment the terrain into seven distinct classes: Water, Grassland, Forest, Hills, Desert, Mountain, and Tundra. The map features are enhanced by median filtering and each class is color-coded. Random parameters were introduced in overlapping image sets in order to ensure variety and prevent redundancy. On these seven terrain classes, the U-Net network is used to perform segmentation tasks. In order to monitor the performance of the model, we implemented cross-validation. The model's effectiveness is demonstrated by robust ROC curve analysis and high AUC values, which indicate accurate terrain categorization. Using deep learning methods and satellite imagery from Google Earth, the primary objective is to develop a digital twin of Florida's coastline. The digital twin serves as both a physical and simulation model, accurately resembling real-world locations. In addition to the achievement of detailed terrain mapping, this approach is likely to have significant applications in environmental monitoring and urban planning as well. In terms of reliability and performance, the digital twin model is expected to be a significant advancement in the field of geographical information systems.

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来源期刊
Journal of Coastal Conservation
Journal of Coastal Conservation ENVIRONMENTAL SCIENCES-MARINE & FRESHWATER BIOLOGY
CiteScore
3.60
自引率
4.80%
发文量
55
期刊介绍: The Journal of Coastal Conservation is a scientific journal for the dissemination of both theoretical and applied research on integrated and sustainable management of the terrestrial, coastal and marine environmental interface. A thorough understanding of both the physical and the human sciences is important to the study of the spatial patterns and processes observed in terrestrial, coastal and marine systems set in the context of past, present and future social and economic developments. This includes multidisciplinary and integrated knowledge and understanding of: physical geography, coastal geomorphology, sediment dynamics, hydrodynamics, soil science, hydrology, plant and animal ecology, vegetation science, biogeography, landscape ecology, recreation and tourism studies, urban and human ecology, coastal engineering and spatial planning, coastal zone management, and marine resource management.
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