Application and Evaluation of a Deep Learning Architecture to Urban Tree Canopy Mapping

Urban forest is a dynamic urban ecosystem that provides critical benefits to urban residents and the environment. Accurate mapping of urban forest plays an important role in greenspace management. In this study, we apply a deep learning model, the U-net, to urban tree canopy mapping using high-resol...

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Main Authors: Zhe Wang, Chao Fan, Min Xian
Format: Article
Language:English
Published: MDPI AG 2021-04-01
Series:Remote Sensing
Subjects:
Online Access:https://www.mdpi.com/2072-4292/13/9/1749
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spelling doaj-3d6d24a4442b49c0be2603c9defe9d282021-04-30T23:04:42ZengMDPI AGRemote Sensing2072-42922021-04-01131749174910.3390/rs13091749Application and Evaluation of a Deep Learning Architecture to Urban Tree Canopy MappingZhe Wang0Chao Fan1Min Xian2Department of Geography, University of Idaho, Moscow, ID 83844, USADepartment of Geography, University of Idaho, Moscow, ID 83844, USADepartment of Computer Science, University of Idaho, Idaho Falls, ID 83406, USAUrban forest is a dynamic urban ecosystem that provides critical benefits to urban residents and the environment. Accurate mapping of urban forest plays an important role in greenspace management. In this study, we apply a deep learning model, the U-net, to urban tree canopy mapping using high-resolution aerial photographs. We evaluate the feasibility and effectiveness of the U-net in tree canopy mapping through experiments at four spatial scales—16 cm, 32 cm, 50 cm, and 100 cm. The overall performance of all approaches is validated on the ISPRS Vaihingen 2D Semantic Labeling dataset using four quantitative metrics, Dice, Intersection over Union, Overall Accuracy, and Kappa Coefficient. Two evaluations are performed to assess the model performance. Experimental results show that the U-net with the 32-cm input images perform the best with an overall accuracy of 0.9914 and an Intersection over Union of 0.9638. The U-net achieves the state-of-the-art overall performance in comparison with object-based image analysis approach and other deep learning frameworks. The outstanding performance of the U-net indicates a possibility of applying it to urban tree segmentation at a wide range of spatial scales. The U-net accurately recognizes and delineates tree canopy for different land cover features and has great potential to be adopted as an effective tool for high-resolution land cover mapping.https://www.mdpi.com/2072-4292/13/9/1749urban tree canopyU-netscaleOBIAreceptive field
collection DOAJ
language English
format Article
sources DOAJ
author Zhe Wang
Chao Fan
Min Xian
spellingShingle Zhe Wang
Chao Fan
Min Xian
Application and Evaluation of a Deep Learning Architecture to Urban Tree Canopy Mapping
Remote Sensing
urban tree canopy
U-net
scale
OBIA
receptive field
author_facet Zhe Wang
Chao Fan
Min Xian
author_sort Zhe Wang
title Application and Evaluation of a Deep Learning Architecture to Urban Tree Canopy Mapping
title_short Application and Evaluation of a Deep Learning Architecture to Urban Tree Canopy Mapping
title_full Application and Evaluation of a Deep Learning Architecture to Urban Tree Canopy Mapping
title_fullStr Application and Evaluation of a Deep Learning Architecture to Urban Tree Canopy Mapping
title_full_unstemmed Application and Evaluation of a Deep Learning Architecture to Urban Tree Canopy Mapping
title_sort application and evaluation of a deep learning architecture to urban tree canopy mapping
publisher MDPI AG
series Remote Sensing
issn 2072-4292
publishDate 2021-04-01
description Urban forest is a dynamic urban ecosystem that provides critical benefits to urban residents and the environment. Accurate mapping of urban forest plays an important role in greenspace management. In this study, we apply a deep learning model, the U-net, to urban tree canopy mapping using high-resolution aerial photographs. We evaluate the feasibility and effectiveness of the U-net in tree canopy mapping through experiments at four spatial scales—16 cm, 32 cm, 50 cm, and 100 cm. The overall performance of all approaches is validated on the ISPRS Vaihingen 2D Semantic Labeling dataset using four quantitative metrics, Dice, Intersection over Union, Overall Accuracy, and Kappa Coefficient. Two evaluations are performed to assess the model performance. Experimental results show that the U-net with the 32-cm input images perform the best with an overall accuracy of 0.9914 and an Intersection over Union of 0.9638. The U-net achieves the state-of-the-art overall performance in comparison with object-based image analysis approach and other deep learning frameworks. The outstanding performance of the U-net indicates a possibility of applying it to urban tree segmentation at a wide range of spatial scales. The U-net accurately recognizes and delineates tree canopy for different land cover features and has great potential to be adopted as an effective tool for high-resolution land cover mapping.
topic urban tree canopy
U-net
scale
OBIA
receptive field
url https://www.mdpi.com/2072-4292/13/9/1749
work_keys_str_mv AT zhewang applicationandevaluationofadeeplearningarchitecturetourbantreecanopymapping
AT chaofan applicationandevaluationofadeeplearningarchitecturetourbantreecanopymapping
AT minxian applicationandevaluationofadeeplearningarchitecturetourbantreecanopymapping
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