Abstract
The techniques for conducting forest inventories have been established over centuries of land management and conservation. In recent decades, however, compelling new tools and methodologies in remote sensing, computer vision, and data science have offered innovative pathways for enhancing the effectiveness and comprehension of these sampling designs. Now with the aid of Unmanned Aerial Systems (UAS) and advanced image processing techniques, we have never been closer to mapping forests at field-based inventory scales. Our research, conducted in New Hampshire on complex mixed-species forests, used natural color UAS imagery for estimating individual tree diameters (diameter at breast height (dbh)) as well as stand level estimates of Basal Area per Hectare (BA/ha), Quadratic Mean Diameter (QMD), Trees per Hectare (TPH), and a Stand Density Index (SDI) using digital photogrammetry. To strengthen our understanding of these forests, we also assessed the proficiency of the UAS to map the presence of large trees (i.e., >40 cm in diameter). We assessed the proficiency of UAS digital photogrammetry for identifying large trees in two ways: (1) using the UAS estimated dbh and the 40 cm size threshold and (2) using a random forest supervised classification and a combination of spectral, textural, and geometric features. Our UAS-based estimates of tree diameter reported an average error of 19.7% to 33.7%. At the stand level, BA/ha and QMD were overestimated by 42.18% and 62.09%, respectively, while TPH and SDI were underestimated by 45.58% and 3.34%. When considering only stands larger than 9 ha however, the overestimation of BA/ha at the stand level dropped to 14.629%. The overall classification of large trees, using the random forest supervised classification achieved an overall accuracy of 85%. The efficiency and effectiveness of these methods offer local land managers the opportunity to better understand their forested ecosystems. Future research into individual tree crown detection and delineation, especially for co-dominant or suppressed trees, will further support these efforts.
Highlights
The alteration of forest stand dynamics by mechanisms such as anthropogenic climate change, landscape fragmentation, land cover change, and overutilization have driven the need to revise our conventional forest management tools and procedures with modern technologies without forgetting silvicultural fundamentals
The spatial resolution of the Structure from Motion (SfM)-MVS orthoimagery and canopy height model (CHM) ranged from 2.53 cm to 3.6 cm
Our first objective investigated the ability of Unmanned Aerial Systems (UAS)-SfM photogrammetry to estimate individual tree diameter as well as stand level characterizations of Basal Area per Hectare (BA/ha), Trees per Hectare (TPH), Quadratic Mean Diameter (QMD), and Stand Density Index (SDI)
Summary
The alteration of forest stand dynamics by mechanisms such as anthropogenic climate change, landscape fragmentation, land cover change, and overutilization have driven the need to revise our conventional forest management tools and procedures with modern technologies without forgetting silvicultural fundamentals. The main objective of many forest inventories is to quantify the size, structure, and distribution of observed tree species [1,2]. Numerous plot sampling designs have been established and refined over the centuries based on silvicultural practices and evolving technologies [3,4,5,6,7]. Field-based campaigns are still severely limited in terms of their temporal and spatial scales.
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