A Methodology to Characterize Vertical Accuracies in Lidar-Derived Products at Landscape Scales

Wade T. Tinkham; Chad M. Hoffman; Michael J. Falkowski; Alistair M. S. Smith; Hans-Peter Marshall; Timothy E. Link

doi:10.14358/PERS.79.8.709

A Methodology to Characterize Vertical Accuracies in Lidar-Derived Products at Landscape Scales

Wade T. Tinkham, Chad M. Hoffman, Michael J. Falkowski, Alistair M. S. Smith, Hans-Peter Marshall, Timothy E. Link

Geosciences Department

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

Light detection and ranging (lidar) is the premier technology for high-resolution elevation measurements in complex landscapes. Lidar error assessments allow for objective interpretation of Digital Elevation Models (DEMs) and products reliant on these layers. The purpose of this study is to spatially estimate the vertical error of a lidar-derived DEM across seven cover types through modeling of field survey data. We use thirty-four variables and ground-based field survey data in a Random Forest regression to predict elevation error. Four variables captured the variability within the lidar errors, with three variables relevant to the distribution of returns within the vegetation and one relating to the terrain form. Good agreement was observed when comparing the survey against the model predictions (μ = -0.02 m, s = 0.13 m, and RMSE = 0.14 m). With most lidar products reliant upon accurate production of DEMs, providing spatially explicit assessments of uncertainty at the landscape level will increase user confidence in lidar products.

Original language	American English
Pages (from-to)	709-716
Number of pages	8
Journal	Photogrammetric Engineering & Remote Sensing
Volume	79
Issue number	8
DOIs	https://doi.org/10.14358/PERS.79.8.709
State	Published - Aug 2013

Keywords

depth
digital elevation models; airborne lidar; classification
ecology
environments
field
forests
trees
vegetation

EGS Disciplines

Earth Sciences
Geophysics and Seismology

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10.14358/PERS.79.8.709

Cite this

@article{56c0cc05ba8549b6abd33e6f35a67362,

title = "A Methodology to Characterize Vertical Accuracies in Lidar-Derived Products at Landscape Scales",

abstract = "Light detection and ranging (lidar) is the premier technology for high-resolution elevation measurements in complex landscapes. Lidar error assessments allow for objective interpretation of Digital Elevation Models (DEMs) and products reliant on these layers. The purpose of this study is to spatially estimate the vertical error of a lidar-derived DEM across seven cover types through modeling of field survey data. We use thirty-four variables and ground-based field survey data in a Random Forest regression to predict elevation error. Four variables captured the variability within the lidar errors, with three variables relevant to the distribution of returns within the vegetation and one relating to the terrain form. Good agreement was observed when comparing the survey against the model predictions (μ = -0.02 m, s = 0.13 m, and RMSE = 0.14 m). With most lidar products reliant upon accurate production of DEMs, providing spatially explicit assessments of uncertainty at the landscape level will increase user confidence in lidar products.",

keywords = "depth, digital elevation models; airborne lidar; classification, ecology, environments, field, forests, trees, vegetation",

author = "Tinkham, {Wade T.} and Hoffman, {Chad M.} and Falkowski, {Michael J.} and Smith, {Alistair M. S.} and Hans-Peter Marshall and Link, {Timothy E.}",

year = "2013",

month = aug,

doi = "10.14358/PERS.79.8.709",

language = "American English",

volume = "79",

pages = "709--716",

number = "8",

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T1 - A Methodology to Characterize Vertical Accuracies in Lidar-Derived Products at Landscape Scales

AU - Tinkham, Wade T.

AU - Hoffman, Chad M.

AU - Falkowski, Michael J.

AU - Smith, Alistair M. S.

AU - Marshall, Hans-Peter

AU - Link, Timothy E.

PY - 2013/8

Y1 - 2013/8

N2 - Light detection and ranging (lidar) is the premier technology for high-resolution elevation measurements in complex landscapes. Lidar error assessments allow for objective interpretation of Digital Elevation Models (DEMs) and products reliant on these layers. The purpose of this study is to spatially estimate the vertical error of a lidar-derived DEM across seven cover types through modeling of field survey data. We use thirty-four variables and ground-based field survey data in a Random Forest regression to predict elevation error. Four variables captured the variability within the lidar errors, with three variables relevant to the distribution of returns within the vegetation and one relating to the terrain form. Good agreement was observed when comparing the survey against the model predictions (μ = -0.02 m, s = 0.13 m, and RMSE = 0.14 m). With most lidar products reliant upon accurate production of DEMs, providing spatially explicit assessments of uncertainty at the landscape level will increase user confidence in lidar products.

AB - Light detection and ranging (lidar) is the premier technology for high-resolution elevation measurements in complex landscapes. Lidar error assessments allow for objective interpretation of Digital Elevation Models (DEMs) and products reliant on these layers. The purpose of this study is to spatially estimate the vertical error of a lidar-derived DEM across seven cover types through modeling of field survey data. We use thirty-four variables and ground-based field survey data in a Random Forest regression to predict elevation error. Four variables captured the variability within the lidar errors, with three variables relevant to the distribution of returns within the vegetation and one relating to the terrain form. Good agreement was observed when comparing the survey against the model predictions (μ = -0.02 m, s = 0.13 m, and RMSE = 0.14 m). With most lidar products reliant upon accurate production of DEMs, providing spatially explicit assessments of uncertainty at the landscape level will increase user confidence in lidar products.

KW - depth

KW - digital elevation models; airborne lidar; classification

KW - ecology

KW - environments

KW - field

KW - forests

KW - trees

KW - vegetation

UR - http://www.scopus.com/inward/record.url?scp=84881138918&partnerID=8YFLogxK

UR - https://scholarworks.boisestate.edu/geo_facpubs/188

U2 - 10.14358/PERS.79.8.709

DO - 10.14358/PERS.79.8.709

M3 - Article

SN - 0099-1112

VL - 79

SP - 709

EP - 716

JO - Photogrammetric Engineering & Remote Sensing

JF - Photogrammetric Engineering & Remote Sensing

IS - 8

ER -

A Methodology to Characterize Vertical Accuracies in Lidar-Derived Products at Landscape Scales

Abstract

Keywords

EGS Disciplines

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