2020
DOI: 10.1016/j.isprsjprs.2020.02.001
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Geocoding of trees from street addresses and street-level images

Abstract: We introduce an approach for updating older tree inventories with geographic coordinates using street-level panorama images and a global optimization framework for tree instance matching. Geolocations of trees in inventories until the early 2000s where recorded using street addresses whereas newer inventories use GPS. Our method retrofits older inventories with geographic coordinates to allow connecting them with newer inventories to facilitate long-term studies on tree mortality etc. What makes this problem c… Show more

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Cited by 35 publications
(12 citation statements)
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“…The use of big data methods based on remote sensing and integration with urban ecosystem accounting should be explored (e.g. Laumer et al, 2020;Hanssen et al, 2021 (Campbell et al, 2016). Therefore, future transdisciplinary vulnerability research and assessments on urban forest resilience to climate change will need to take into account more socio-ecological perspectives and approaches (Steenberg et al, 2017).…”
Section: Discussionmentioning
confidence: 99%
“…The use of big data methods based on remote sensing and integration with urban ecosystem accounting should be explored (e.g. Laumer et al, 2020;Hanssen et al, 2021 (Campbell et al, 2016). Therefore, future transdisciplinary vulnerability research and assessments on urban forest resilience to climate change will need to take into account more socio-ecological perspectives and approaches (Steenberg et al, 2017).…”
Section: Discussionmentioning
confidence: 99%
“…Therefore, to complete a vegetation analysis with GLI, the images must be captured along sections that allow for analyzing the whole scene in order to detect and characterize urban trees [109]. Thus, for tree characterization and species identification, shorter section distances between consecutive images, e.g., 10-15 m with DGI [15,45,47,104,105] or 30 m with PPC or MLS are required [102] (Table 5).…”
Section: Ground-level Images and Videosmentioning
confidence: 99%
“…This study highlights the importance of data sources such as GSV and OpenStreetCam for updating information on urban forests and their ability to offer ES. On the other hand, studies, such as the one developed by Laumer et al [105], advanced not only in tree recognition (91% of accuracy), but also in tree positioning, achieving 56% accuracy in the assignment of geographic coordinates' through GSV images and the Geocoding API from Google. Moreover, Branson et al [45] focused on tree species identification, in addition to the detection of individual trees, from GLI and achieved an accuracy of 70% in tree segmentation and an accuracy of 80% in species identification of urban trees of Pasadena, California.…”
Section: Ground-level Images and Videosmentioning
confidence: 99%
“…The feature representations computed by deep networks independently trained for the aerial and ground views were concatenated and fed to a linear SVM for classification of 40 tree species. More recently, Laumer et al (2020) improved the existing street tree inventories where the individual trees were referenced by only street addresses with accurate geographic coordinates that were estimated from multi-view detections in street-view panoramas. The methods proposed in this paper are not specific to tree detection.…”
Section: Related Workmentioning
confidence: 99%