Addressing the complexity in non-linear evolution of vegetation phenological change with time-series of remote sensing images

► The phenological fluctuation of ecosystems is addressed by a robust change indicator. ► Consistency of spatial pattern and sensitivity against pre-processing are analyzed. ► Linear regression limits the possibilities of assessing fluctuating ecosystem changes. ► “Steadiness” instead of linear regr...

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Published in	Ecological indicators Vol. 26; pp. 49 - 60
Main Authors	Ivits, E., Cherlet, M., Sommer, S., Mehl, W.
Format	Journal Article
Language	English
Published	Amsterdam Elsevier Ltd 01.03.2013 Elsevier
Subjects	algorithms Animal and plant ecology Animal, plant and microbial ecology Biological and medical sciences climate confidence interval Demecology ecosystems evolution Fundamental and applied biological sciences. Psychology General aspects. Techniques humans land cover linear models Linear regression monitoring Non-linear phenology fluctuations phenology Plants and fungi regression analysis remote sensing Stationarity Teledetection and vegetation maps temporal variation vegetation Europe Non-linear phenology fluctuations Linear regression Stationarity Fluctuations Phenology Time series Vegetation dynamics Image Remote sensing
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Abstract	► The phenological fluctuation of ecosystems is addressed by a robust change indicator. ► Consistency of spatial pattern and sensitivity against pre-processing are analyzed. ► Linear regression limits the possibilities of assessing fluctuating ecosystem changes. ► “Steadiness” instead of linear regression is suggested for assessing ecosystem change. ► This non-parametric index confirms spatially consistent fluctuating change patterns. Earth observation based monitoring of change in vegetation phenology and productivity is an important and widely used approach to quantify degradation of ecosystems due to climatic or human influences. Most satellite based studies apply linear or polynomial regression methods for trend detections. In this paper it is argued that natural systems hardly react to human or natural influences in a linear or a polynomial manner. At shorter time-scales of few decades natural systems fluctuate to a certain extent in a non-systematic manner without necessarily changing equilibrium. Finding a systematic model that describes this behavior on large spatial scales is certainly a difficult challenge. Furthermore, the manner vegetation phenology reacts to climate and to socio-economic changes is also dependent on the land cover type and on the bioclimatic region. In addition to this, traditional parametric methods require the fulfillment of several statistical criteria. In case these criteria are violated confidence intervals and significance tests of the models may be biased, even misleading. This paper proposes an alternative approach termed the Steadiness to traditional trend analysis methods. Steadiness combines the direction or tendency of the change and the net change of the time-series over a selected time period. It is a non-parametric approach which can be used without violation of statistical criteria, it can be applied on short time-series as well and results are not dependent on the significance test or on thresholds. To demonstrate differences, a time-series of satellite derived Season Length images for 24 years is analyzed for the entire European continent using linear regression and the Steadiness approach. Spatial and temporal change patterns and sensitivity to pre-processing algorithms are compared between the two methods. We show that linear regression limits the possibilities of assessing fluctuating ecosystem changes whereas the non-parametric Steadiness index more consistently confirms the fluctuating phenological change patterns.
AbstractList	Earth observation based monitoring of change in vegetation phenology and productivity is an important and widely used approach to quantify degradation of ecosystems due to climatic or human influences. Most satellite based studies apply linear or polynomial regression methods for trend detections. In this paper it is argued that natural systems hardly react to human or natural influences in a linear or a polynomial manner. At shorter time-scales of few decades natural systems fluctuate to a certain extent in a non-systematic manner without necessarily changing equilibrium. Finding a systematic model that describes this behavior on large spatial scales is certainly a difficult challenge. Furthermore, the manner vegetation phenology reacts to climate and to socio-economic changes is also dependent on the land cover type and on the bioclimatic region. In addition to this, traditional parametric methods require the fulfillment of several statistical criteria. In case these criteria are violated confidence intervals and significance tests of the models may be biased, even misleading. This paper proposes an alternative approach termed the Steadiness to traditional trend analysis methods. Steadiness combines the direction or tendency of the change and the net change of the time-series over a selected time period. It is a non-parametric approach which can be used without violation of statistical criteria, it can be applied on short time-series as well and results are not dependent on the significance test or on thresholds. To demonstrate differences, a time-series of satellite derived Season Length images for 24 years is analyzed for the entire European continent using linear regression and the Steadiness approach. Spatial and temporal change patterns and sensitivity to pre-processing algorithms are compared between the two methods. We show that linear regression limits the possibilities of assessing fluctuating ecosystem changes whereas the non-parametric Steadiness index more consistently confirms the fluctuating phenological change patterns. ► The phenological fluctuation of ecosystems is addressed by a robust change indicator. ► Consistency of spatial pattern and sensitivity against pre-processing are analyzed. ► Linear regression limits the possibilities of assessing fluctuating ecosystem changes. ► “Steadiness” instead of linear regression is suggested for assessing ecosystem change. ► This non-parametric index confirms spatially consistent fluctuating change patterns. Earth observation based monitoring of change in vegetation phenology and productivity is an important and widely used approach to quantify degradation of ecosystems due to climatic or human influences. Most satellite based studies apply linear or polynomial regression methods for trend detections. In this paper it is argued that natural systems hardly react to human or natural influences in a linear or a polynomial manner. At shorter time-scales of few decades natural systems fluctuate to a certain extent in a non-systematic manner without necessarily changing equilibrium. Finding a systematic model that describes this behavior on large spatial scales is certainly a difficult challenge. Furthermore, the manner vegetation phenology reacts to climate and to socio-economic changes is also dependent on the land cover type and on the bioclimatic region. In addition to this, traditional parametric methods require the fulfillment of several statistical criteria. In case these criteria are violated confidence intervals and significance tests of the models may be biased, even misleading. This paper proposes an alternative approach termed the Steadiness to traditional trend analysis methods. Steadiness combines the direction or tendency of the change and the net change of the time-series over a selected time period. It is a non-parametric approach which can be used without violation of statistical criteria, it can be applied on short time-series as well and results are not dependent on the significance test or on thresholds. To demonstrate differences, a time-series of satellite derived Season Length images for 24 years is analyzed for the entire European continent using linear regression and the Steadiness approach. Spatial and temporal change patterns and sensitivity to pre-processing algorithms are compared between the two methods. We show that linear regression limits the possibilities of assessing fluctuating ecosystem changes whereas the non-parametric Steadiness index more consistently confirms the fluctuating phenological change patterns.
Author	Mehl, W. Cherlet, M. Ivits, E. Sommer, S.
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Snippet	► The phenological fluctuation of ecosystems is addressed by a robust change indicator. ► Consistency of spatial pattern and sensitivity against pre-processing... Earth observation based monitoring of change in vegetation phenology and productivity is an important and widely used approach to quantify degradation of...
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SubjectTerms	algorithms Animal and plant ecology Animal, plant and microbial ecology Biological and medical sciences climate confidence interval Demecology ecosystems evolution Fundamental and applied biological sciences. Psychology General aspects. Techniques humans land cover linear models Linear regression monitoring Non-linear phenology fluctuations phenology Plants and fungi regression analysis remote sensing Stationarity Teledetection and vegetation maps temporal variation vegetation
Title	Addressing the complexity in non-linear evolution of vegetation phenological change with time-series of remote sensing images
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