Implementing Deep Learning algorithms for urban tree detection and geolocation with high-resolution aerial, satellite, and ground-level images

IF 7.1 1区 地球科学 Q1 ENVIRONMENTAL STUDIES
Luisa Velasquez-Camacho , Maddi Etxegarai , Sergio de-Miguel
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引用次数: 0

Abstract

Urban forests are becoming increasingly important for human well-being as they provide ecosystem services that contribute to improving well-being of city dwellers and to addressing climate change. However, despite their importance, there is an information gap in most of the world's urban forests due to the high cost and complexity of conducting standard forest inventories in urban environments. New technologies based on artificial intelligence can represent a smart and efficient alternative to costly traditional inventories. In this paper, we present an approach based on deep learning algorithms for the detection, counting, and geopositioning of trees using a combination of ground-level and aerial/satellite imagery. We tested several convolutional networks, exploring different combinations of hyperparameters and adjusting the query distance between ground-level images, detection radius, and various resolutions of satellite and aerial images. Our methodology is able to detect and accurately locate 79% of the urban street tree with a positional accuracy of 60 cm to the center of the canopy. Additionally, this approach allows us to determine the availability of photographs of urban trees, indicating from which Google Street View image each tree is visible. Our research provides a scalable and replicable solution to the scarcity of urban tree data and information worldwide, demonstrating the potential of artificial intelligence to revolutionize the way in which we inventory and monitor urban forests.

利用高分辨率航空、卫星和地面图像实现城市树木检测和地理定位的深度学习算法
城市森林对人类福祉越来越重要,因为它们提供了生态系统服务,有助于改善城市居民的福祉和应对气候变化。然而,尽管它们很重要,但由于在城市环境中进行标准森林清查的成本高且复杂,世界上大多数城市森林都存在信息差距。基于人工智能的新技术可以代表一种智能高效的替代昂贵的传统库存的方法。在本文中,我们提出了一种基于深度学习算法的方法,用于结合地面和航空/卫星图像对树木进行检测、计数和地理定位。我们测试了几个卷积网络,探索了超参数的不同组合,并调整了地面图像之间的查询距离、检测半径以及卫星和航空图像的各种分辨率。我们的方法能够检测并准确定位79%的城市行道树,其位置精度为树冠中心60cm。此外,这种方法使我们能够确定城市树木照片的可用性,表明每棵树都可以从谷歌街景图像中看到。我们的研究为全球城市树木数据和信息的稀缺提供了一个可扩展和可复制的解决方案,展示了人工智能在彻底改变我们清查和监测城市森林的方式方面的潜力。
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来源期刊
CiteScore
13.30
自引率
7.40%
发文量
111
审稿时长
32 days
期刊介绍: Computers, Environment and Urban Systemsis an interdisciplinary journal publishing cutting-edge and innovative computer-based research on environmental and urban systems, that privileges the geospatial perspective. The journal welcomes original high quality scholarship of a theoretical, applied or technological nature, and provides a stimulating presentation of perspectives, research developments, overviews of important new technologies and uses of major computational, information-based, and visualization innovations. Applied and theoretical contributions demonstrate the scope of computer-based analysis fostering a better understanding of environmental and urban systems, their spatial scope and their dynamics.
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