An Assessment of High-Density UAV Point Clouds for the Measurement of Young Forestry Trials

Robin J L Hartley,Honey Jane Estarija,Michael S Watt,Peter Massam,Nathanael Melia,Ellen Mae Leonardo,Liam Wright,Grant D Pearse

doi:10.3390/rs12244039

Robin J L Hartley, Honey Jane Estarija + Show 6 more

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https://doi.org/10.3390/rs12244039

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Journal: Remote Sensing	Publication Date: Dec 10, 2020
Citations: 29	License type: CC BY 4.0

Affiliation: Scion, Victoria University of Wellington

Abstract

The measurement of forestry trials is a costly and time-consuming process. Over the past few years, unmanned aerial vehicles (UAVs) have provided some significant developments that could improve cost and time efficiencies. However, little research has examined the accuracies of these technologies for measuring young trees. This study compared the data captured by a UAV laser scanning system (ULS), and UAV structure from motion photogrammetry (SfM), with traditional field-measured heights in a series of forestry trials in the central North Island of New Zealand. Data were captured from UAVs, and then processed into point clouds, from which heights were derived and compared to field measurements. The results show that predictions from both ULS and SfM were very strongly correlated to tree heights (R2 = 0.99, RMSE = 5.91%, and R2 = 0.94, RMSE = 18.5%, respectively) but that the height underprediction was markedly lower for ULS than SfM (Mean Bias Error = 0.05 vs. 0.38 m). Integration of a ULS DTM to the SfM made a minor improvement in precision (R2 = 0.95, RMSE = 16.5%). Through plotting error against tree height, we identified a minimum threshold of 1 m, under which the accuracy of height measurements using ULS and SfM significantly declines. Our results show that SfM and ULS data collected from UAV remote sensing can be used to accurately measure height in young forestry trials. It is hoped that this study will give foresters and tree breeders the confidence to start to operationalise this technology for monitoring trials.

Highlights

Forestry trials are established to evaluate and monitor a variety of factors that affect growth
This type of data has been captured and utilised in forestry from manned aircraft since the 1920s, when aerial photography was first used in Canada [2], and satellites since
The results from the UAV laser scanning system (ULS) data show a high level of precision and a low level of bias (Table 3 and Figure 4)

Summary

Introduction

Forestry trials are established to evaluate and monitor a variety of factors that affect growth. The use of remotely sensed data has considerable potential for overcoming difficulties associated with trial measurement. This type of data has been captured and utilised in forestry from manned aircraft since the 1920s, when aerial photography was first used in Canada [2], and satellites since. Airborne laser scanning (ALS), in particular, has emerged as a common tool for forest inventory. This technology has been widely researched for forestry since 1976 and deployed operationally for forest inventory over the past two decades [4,5,6,7]

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