Analysis and Prediction of Gap Dynamics in a Secondary Deciduous Broadleaf Forest of Central Japan Using Airborne Multi-LiDAR Observations

Analysis and Prediction of Gap Dynamics in a Secondary Deciduous Broadleaf Forest of Central Japan Using Airborne Multi-LiDAR Observations

Gaps are important for growth of vegetation on the forest floor. However, monitoring of gaps in large areas is difficult. Airborne light detection and ranging (LiDAR) data make precise gap mapping possible. We formulated a method to describe changes in gaps by time-series tracking of gap area change...

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Bibliographic Details
Main Authors: Kazuho Araki, Yoshio Awaya
Format: Article
Language:English
Published: MDPI AG 2021-12-01
Series:Remote Sensing
Subjects:
gap area
spatiotemporal change
gap lifespan prediction
Online Access:https://www.mdpi.com/2072-4292/13/1/100
id doaj-0b157a4b124f40bfb071207ffeee826a
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spelling doaj-0b157a4b124f40bfb071207ffeee826a2020-12-31T00:03:16ZengMDPI AGRemote Sensing2072-42922021-12-011310010010.3390/rs13010100Analysis and Prediction of Gap Dynamics in a Secondary Deciduous Broadleaf Forest of Central Japan Using Airborne Multi-LiDAR ObservationsKazuho Araki0Yoshio Awaya1Graduate School of Natural Science and Technology, Gifu University, 1-1, Yanagido, Gifu 501-1193, JapanRiver Basin Research Center, Gifu University, 1-1, Yanagido, Gifu 501-1193, JapanGaps are important for growth of vegetation on the forest floor. However, monitoring of gaps in large areas is difficult. Airborne light detection and ranging (LiDAR) data make precise gap mapping possible. We formulated a method to describe changes in gaps by time-series tracking of gap area changes using three digital canopy height models (DCHMs) based on LiDAR data collected in 2005, 2011, and 2016 over secondary deciduous broadleaf forest. We generated a mask that covered merging or splitting of gaps in the three DCHMs and allowed us to identify their spatiotemporal relationships. One-fifth of gaps merged with adjacent gaps or split into several gaps between 2005 and 2016. Gap shrinkage showed a strong linear correlation with gap area in 2005, via lateral growth of gap-edge trees between 2005 and 2016, as modeled by a linear regression analysis. New gaps that emerged between 2005 and 2011 shrank faster than gaps present in 2005. A statistical model to predict gap lifespan was developed and gap lifespan was mapped using data from 2005 and 2016. Predicted gap lifespan decreased greatly due to shrinkage and splitting of gaps between 2005 and 2016.https://www.mdpi.com/2072-4292/13/1/100gap areaspatiotemporal changegap lifespan prediction
collection DOAJ
language English
format Article
sources DOAJ
author Kazuho Araki
Yoshio Awaya
spellingShingle Kazuho Araki
Yoshio Awaya
Analysis and Prediction of Gap Dynamics in a Secondary Deciduous Broadleaf Forest of Central Japan Using Airborne Multi-LiDAR Observations
Remote Sensing
gap area
spatiotemporal change
gap lifespan prediction
author_facet Kazuho Araki
Yoshio Awaya
author_sort Kazuho Araki
title Analysis and Prediction of Gap Dynamics in a Secondary Deciduous Broadleaf Forest of Central Japan Using Airborne Multi-LiDAR Observations
title_short Analysis and Prediction of Gap Dynamics in a Secondary Deciduous Broadleaf Forest of Central Japan Using Airborne Multi-LiDAR Observations
title_full Analysis and Prediction of Gap Dynamics in a Secondary Deciduous Broadleaf Forest of Central Japan Using Airborne Multi-LiDAR Observations
title_fullStr Analysis and Prediction of Gap Dynamics in a Secondary Deciduous Broadleaf Forest of Central Japan Using Airborne Multi-LiDAR Observations
title_full_unstemmed Analysis and Prediction of Gap Dynamics in a Secondary Deciduous Broadleaf Forest of Central Japan Using Airborne Multi-LiDAR Observations
title_sort analysis and prediction of gap dynamics in a secondary deciduous broadleaf forest of central japan using airborne multi-lidar observations
publisher MDPI AG
series Remote Sensing
issn 2072-4292
publishDate 2021-12-01
description Gaps are important for growth of vegetation on the forest floor. However, monitoring of gaps in large areas is difficult. Airborne light detection and ranging (LiDAR) data make precise gap mapping possible. We formulated a method to describe changes in gaps by time-series tracking of gap area changes using three digital canopy height models (DCHMs) based on LiDAR data collected in 2005, 2011, and 2016 over secondary deciduous broadleaf forest. We generated a mask that covered merging or splitting of gaps in the three DCHMs and allowed us to identify their spatiotemporal relationships. One-fifth of gaps merged with adjacent gaps or split into several gaps between 2005 and 2016. Gap shrinkage showed a strong linear correlation with gap area in 2005, via lateral growth of gap-edge trees between 2005 and 2016, as modeled by a linear regression analysis. New gaps that emerged between 2005 and 2011 shrank faster than gaps present in 2005. A statistical model to predict gap lifespan was developed and gap lifespan was mapped using data from 2005 and 2016. Predicted gap lifespan decreased greatly due to shrinkage and splitting of gaps between 2005 and 2016.
topic gap area
spatiotemporal change
gap lifespan prediction
url https://www.mdpi.com/2072-4292/13/1/100
work_keys_str_mv AT kazuhoaraki analysisandpredictionofgapdynamicsinasecondarydeciduousbroadleafforestofcentraljapanusingairbornemultilidarobservations
AT yoshioawaya analysisandpredictionofgapdynamicsinasecondarydeciduousbroadleafforestofcentraljapanusingairbornemultilidarobservations
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