Abstract
Time series analysis has gained popularity in forest disturbance monitoring thanks to the availability of satellite and airborne remote sensing images and the development of different time series methods for change detection. Previous research has focused on time series data noise reduction, the magnitude of breakpoints, and accuracy assessment; however, few have looked in detail at how the trend and seasonal model components contribute to disturbance detection in different forest types. Here, we use Landsat time series images spanning 1994–2018 to map forest disturbance in a western Pacific area of Mexico, where both temperate and tropical dry forests have been subject to severe deforestation and forest degradation processes. Since these two forest types have distinct seasonal characteristics, we investigate how trend and seasonal model components, such as the goodness-of-fit (R2), magnitude of change, amplitude, and model length in a stable historical period, affect forest disturbance detection. We applied the Breaks For Additive Season and Trend Monitor (BFAST) algorithm and after accuracy assessment by stratified random sample points, and we obtained 68% and 86% of user accuracy and 75.6% and 86% of producer’s accuracy in disturbance detection, in tropical dry forests and temperate forests, respectively. We extracted the noncorrelated trend and seasonal model components R2, magnitude, amplitude, length of the stable historical period, and percentage of pixels with NA and tested their effects on disturbance detection employing forest-type specific logistic regression. Our results showed that, for all forests combined, the amplitude and stable historical period length contributed to disturbance detection. While for tropical dry forest alone, amplitude was the main predictor, and for the temperate forest alone, the stable historical period length contributed most to the prediction, although it was not statistically significant. These findings provide insights for improving the results of forest disturbance detection in different forest types.
Highlights
Given the importance of the trend and the seasonal model components in time series (TS) model prediction, and the fact that little previous research has been carried out on how these components affect forest disturbance detection in different forest types, we report on a study that focuses on disturbance detection in both tropical dry forests (TDF) and temperate forests (TF), encompassing four research questions: ate forests (TF), encompassing four research questions: (1) Do TDF and TF differ in accuracy in forest disturbance detection by Breaks For Additive Season and Trend Monitor (BFAST) trend and seasonal model?
The disturbance detection in TF obtained a higher accuracy than in TDF. This is in line with the finding from [38] showing that the trend and seasonal model such as BFAST tends to yield higher accuracy in forests with less seasonality, such as those dominated by conifers, because this facilitates the discrimination between phenological changes and disturbances
This study evaluated the contribution of the components of BFAST model and the percentage of NAs in a time series to forest disturbance detection
Summary
Forests play a vital role in ecosystem goods and services to humanity, by providing energy, shelter, and livelihoods [1]. Human-induced land use and management practices, such as deforestation for agriculture, logging, plantation, or transitional subsistence farming, such as shifting cultivation, have led to forest cover loss [2]. Reliable information on forest cover and its changes is crucial for policymakers to design effective plans in forest conservation. Forest disturbances have been detected and quantified using multitemporal spaceborne optical remote sensing, such as Landsat, which has been providing images for Remote Sens.
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