A Near Real-Time Method for Forest Change Detection Based on a Structural Time Series Model and the Kalman Filter

A Near Real-Time Method for Forest Change Detection Based on a Structural Time Series Model and the Kalman Filter

The increasing availability of dense time series of earth observation data has incited a growing interest in time series analysis for vegetation monitoring and change detection. Vegetation monitoring algorithms need to deal with several time series characteristics such as seasonality, irregular samp...

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Main Authors: Martin Puhm, Janik Deutscher, Manuela Hirschmugl, Andreas Wimmer, Ursula Schmitt, Mathias Schardt
Format: Article
Language:English
Published: MDPI AG 2020-09-01
Series:Remote Sensing
Subjects:
state space models
forest disturbance mapping
near real-time monitoring
Sentinel-2
CUSUM
Online Access:https://www.mdpi.com/2072-4292/12/19/3135
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spelling doaj-12947837710145a4a41ee7d1a69570df2020-11-25T03:41:47ZengMDPI AGRemote Sensing2072-42922020-09-01123135313510.3390/rs12193135A Near Real-Time Method for Forest Change Detection Based on a Structural Time Series Model and the Kalman FilterMartin Puhm0Janik Deutscher1Manuela Hirschmugl2Andreas Wimmer3Ursula Schmitt4Mathias Schardt5JOANNEUM RESEARCH, Institute for Information and Communication Technologies, Steyrergasse 17, 8010 Graz, AustriaJOANNEUM RESEARCH, Institute for Information and Communication Technologies, Steyrergasse 17, 8010 Graz, AustriaJOANNEUM RESEARCH, Institute for Information and Communication Technologies, Steyrergasse 17, 8010 Graz, AustriaJOANNEUM RESEARCH, Institute for Information and Communication Technologies, Steyrergasse 17, 8010 Graz, AustriaJOANNEUM RESEARCH, Institute for Information and Communication Technologies, Steyrergasse 17, 8010 Graz, AustriaJOANNEUM RESEARCH, Institute for Information and Communication Technologies, Steyrergasse 17, 8010 Graz, AustriaThe increasing availability of dense time series of earth observation data has incited a growing interest in time series analysis for vegetation monitoring and change detection. Vegetation monitoring algorithms need to deal with several time series characteristics such as seasonality, irregular sampling intervals, and signal artefacts. While common algorithms based on deterministic harmonic regression models account for intra-annual seasonality, inter-annual variations of the seasonal pattern related to shifts in vegetation phenology due to different temperature and rainfall are usually not accounted for. We propose a transition to stochastic modelling and present a near real-time change detection method that combines a structural time series model with the Kalman filter. The model continuously adapts to new observations and allows to better separate phenology-related deviations from vegetation anomalies or land cover changes. The method is tested in a forest change detection application aiming at the assessment of damages caused by storm events and insect calamities. Forest changes are detected based on the cumulative sum control chart (CUSUM) which is used to decide if new observations deviate from model-based forecasts. The performance is evaluated in two test sites, one in Malawi (dry tropical forest) and one in Austria (temperate deciduous, coniferous and mixed forests) based on Sentinel-2 time series. Both forest areas are characterized by a distinct, but temporally varying leaf-off season. The presented change detection method shows overall accuracies above 99%, users’ accuracies of 76.8% to 88.6%, and producers’ accuracies of 68.2% to 80.4% for the forest change stratum (minimum mapping unit: 0.1 ha). Results are based on visually interpreted points derived by stratified random sampling. A further analysis revealed that increasing the time series density by merging data from two Sentinel-2 orbits yields better forest change detection accuracies in comparison to using data from one orbit only. The resulting increase in users’ accuracy amounts to 7.6%. The presented method is capable of near real-time processing and could be used for a variety of automated forest monitoring applications.https://www.mdpi.com/2072-4292/12/19/3135state space modelsforest disturbance mappingnear real-time monitoringSentinel-2CUSUM
collection DOAJ
language English
format Article
sources DOAJ
author Martin Puhm
Janik Deutscher
Manuela Hirschmugl
Andreas Wimmer
Ursula Schmitt
Mathias Schardt
spellingShingle Martin Puhm
Janik Deutscher
Manuela Hirschmugl
Andreas Wimmer
Ursula Schmitt
Mathias Schardt
A Near Real-Time Method for Forest Change Detection Based on a Structural Time Series Model and the Kalman Filter
Remote Sensing
state space models
forest disturbance mapping
near real-time monitoring
Sentinel-2
CUSUM
author_facet Martin Puhm
Janik Deutscher
Manuela Hirschmugl
Andreas Wimmer
Ursula Schmitt
Mathias Schardt
author_sort Martin Puhm
title A Near Real-Time Method for Forest Change Detection Based on a Structural Time Series Model and the Kalman Filter
title_short A Near Real-Time Method for Forest Change Detection Based on a Structural Time Series Model and the Kalman Filter
title_full A Near Real-Time Method for Forest Change Detection Based on a Structural Time Series Model and the Kalman Filter
title_fullStr A Near Real-Time Method for Forest Change Detection Based on a Structural Time Series Model and the Kalman Filter
title_full_unstemmed A Near Real-Time Method for Forest Change Detection Based on a Structural Time Series Model and the Kalman Filter
title_sort near real-time method for forest change detection based on a structural time series model and the kalman filter
publisher MDPI AG
series Remote Sensing
issn 2072-4292
publishDate 2020-09-01
description The increasing availability of dense time series of earth observation data has incited a growing interest in time series analysis for vegetation monitoring and change detection. Vegetation monitoring algorithms need to deal with several time series characteristics such as seasonality, irregular sampling intervals, and signal artefacts. While common algorithms based on deterministic harmonic regression models account for intra-annual seasonality, inter-annual variations of the seasonal pattern related to shifts in vegetation phenology due to different temperature and rainfall are usually not accounted for. We propose a transition to stochastic modelling and present a near real-time change detection method that combines a structural time series model with the Kalman filter. The model continuously adapts to new observations and allows to better separate phenology-related deviations from vegetation anomalies or land cover changes. The method is tested in a forest change detection application aiming at the assessment of damages caused by storm events and insect calamities. Forest changes are detected based on the cumulative sum control chart (CUSUM) which is used to decide if new observations deviate from model-based forecasts. The performance is evaluated in two test sites, one in Malawi (dry tropical forest) and one in Austria (temperate deciduous, coniferous and mixed forests) based on Sentinel-2 time series. Both forest areas are characterized by a distinct, but temporally varying leaf-off season. The presented change detection method shows overall accuracies above 99%, users’ accuracies of 76.8% to 88.6%, and producers’ accuracies of 68.2% to 80.4% for the forest change stratum (minimum mapping unit: 0.1 ha). Results are based on visually interpreted points derived by stratified random sampling. A further analysis revealed that increasing the time series density by merging data from two Sentinel-2 orbits yields better forest change detection accuracies in comparison to using data from one orbit only. The resulting increase in users’ accuracy amounts to 7.6%. The presented method is capable of near real-time processing and could be used for a variety of automated forest monitoring applications.
topic state space models
forest disturbance mapping
near real-time monitoring
Sentinel-2
CUSUM
url https://www.mdpi.com/2072-4292/12/19/3135
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