Processing Chain for Estimation of Tree Diameter from GNSS-IMU-Based Mobile Laser Scanning Data

Juraj Čerňava,Zuzana Slatkovská,Michal Antal,Ján Tuček,Martin Mokroš

doi:10.3390/rs11060615

Juraj Čerňava, Zuzana Slatkovská + Show 3 more

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https://doi.org/10.3390/rs11060615

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Abstract

Mobile laser scanning (MLS) is a progressive technology that has already demonstrated its ability to provide highly accurate measurements of road networks. Mobile innovation of the laser scanning has also found its use in forest mapping over the last decade. In most cases, existing methods for forest data acquisition using MLS result in misaligned scenes of the forest, scanned from different views appearing in one point cloud. These difficulties are caused mainly by forest canopy blocking the global navigation satellite system (GNSS) signal and limited access to the forest. In this study, we propose an approach to the processing of MLS data of forest scanned from different views with two mobile laser scanners under heavy canopy. Data from two scanners, as part of the mobile mapping system (MMS) Riegl VMX-250, were acquired by scanning from five parallel skid trails that are connected to the forest road. Misaligned scenes of the forest acquired from different views were successfully extracted from the raw MLS point cloud using GNSS time based clustering. At first, point clouds with correctly aligned sets of ground points were generated using this method. The loss of points after the clustering amounted to 33.48%. Extracted point clouds were then reduced to 1.15 m thick horizontal slices, and tree stems were detected. Point clusters from individual stems were grouped based on the diameter and mean GNSS time of the cluster acquisition. Horizontal overlap was calculated for the clusters from individual stems, and sufficiently overlapping clusters were aligned using the OPALS ICP module. An average misalignment of 7.2 mm was observed for the aligned point clusters. A 5-cm thick horizontal slice of the aligned point cloud was used for estimation of the stem diameter at breast height (DBH). DBH was estimated using a simple circle-fitting method with a root-mean-square error of 3.06 cm. The methods presented in this study have the potential to process MLS data acquired under heavy forest canopy with any commercial MMS.

Highlights

Mobile laser scanning (MLS) is the latest technology within geospatial data acquisition that enables time-efficient measurements of any ground-based object with high accuracy
We have developed a processing chain for the extraction of forest scenes scanned from different views from misaligned MLS point clouds, and consequent registration of the scenes using iterative closest point (ICP)
This study demonstrates that global navigation satellite system (GNSS) time data can be used both to separate the scenes of forest stands scanned at different time periods from the spatially extracted point cloud, and to match the MLS data from individual trees

Summary

Introduction

Mobile laser scanning (MLS) is the latest technology within geospatial data acquisition that enables time-efficient measurements of any ground-based object with high accuracy. The range accuracy of mobile laser scanners contained in these systems spans from 2 mm (ROADSCANNER) to 50 mm (DYNASCAN) according to Puente et al [6]. Employing one of these systems in forest measurements can be highly beneficial for the extraction of forest structural parameters at the tree level. Measurements of objects using systems from the 2010s with an GNSS outage duration of 1 min were tested in the study of Puente et al [6]. These systems were able to measure the x- and y-positions with an accuracy ranging from 0.1 m (VMX-250/LYNX, ROADSCANNER) to 0.265 m (IP-S2 AG60), while the z-position was measured with an accuracy ranging from 0.07 m (VMX-250/LYNX, ROADSCANNER) to 0.24 m (IP-S2 AG60) [6]

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