Forest Delineation Based on Airborne LIDAR Data

Lothar Eysn,Norbert Pfeifer,Klemens Schadauer,Markus Hollaus

doi:10.3390/rs4030762

Lothar Eysn, Norbert Pfeifer + Show 2 more

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https://doi.org/10.3390/rs4030762

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Journal: Remote sensing	Publication Date: Mar 20, 2012
Citations: 69	License type: CC BY 3.0

Affiliation: TU Wien, Austrian Research Centre for Forests

Abstract

The delineation of forested areas is a critical task, because the resulting maps are a fundamental input for a broad field of applications and users. Different national and international forest definitions are available for manual or automatic delineation, but unfortunately most definitions lack precise geometrical descriptions for the different criteria. A mandatory criterion in forest definitions is the criterion of crown coverage (CC), which defines the proportion of the forest floor covered by the vertical projection of the tree crowns. For loosely stocked areas, this criterion is especially critical, because the size and shape of the reference area for calculating CC is not clearly defined in most definitions. Thus current forest delineations differ and tend to be non-comparable because of different settings for checking the criterion of CC in the delineation process. This paper evaluates a new approach for the automatic delineation of forested areas, based on airborne laser scanning (ALS) data with a clearly defined method for calculating CC. The new approach, the ‘tree triples’ method, is based on defining CC as a relation between the sum of the crown areas of three neighboring trees and the area of their convex hull. The approach is applied and analyzed for two study areas in Tyrol, Austria. The selected areas show a loosely stocked forest at the upper timberline and a fragmented forest on the hillside. The fully automatic method presented for delineating forested areas from ALS data shows promising results with an overall accuracy of 96%, and provides a beneficial tool for operational applications.

Highlights

In recent years, the increasing use of forest products derived from airborne laser scanning (ALS)data as well as many ongoing projects related to this topic show the high demand for this research field
The crowns in the derived base products of ALS tend to be overestimated, because the base products are commonly raster-based and the exact size of the modeled crowns depends on the spatial resolution of the models and on the method applied to calculate the digital surface model (DSM)
The results of the approach here presented show the high potential of an automatic delineation of forested areas, based on airborne laser scanning and national forest inventory data

Summary

Introduction

The increasing use of forest products derived from airborne laser scanning (ALS)data as well as many ongoing projects related to this topic show the high demand for this research field. The increasing use of forest products derived from airborne laser scanning (ALS). E.g., estimated tree heights [1,2,3], growing stock estimations [4,5], or forest structure analyses [6,7] are of interest for a broad field of applications and users (e.g., forestry, biologists, risk management for natural hazards). The results determined from these applications are highly dependent on the fundamental input parameters’ size and position of the delineated forest areas. The delineation of these areas is a crucial task. The size of forested areas is of interest for governmental authorities (e.g., taxation, financial support of the European Commission) and, in a broader sense, for politics (e.g., greenhouse gases, Kyoto protocol)

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