Abstract
Remote sensing satellite images in the optical domain often contain missing or misleading data due to overcast conditions or sensor malfunctioning, concealing potentially important information. In this paper, we apply expectation maximization (EM) Tucker to NDVI satellite data from the Iberian Peninsula in order to gap-fill missing information. EM Tucker belongs to a family of tensor decomposition methods that are known to offer a number of interesting properties, including the ability to directly analyze data stored in multidimensional arrays and to explicitly exploit their multiway structure, which is lost when traditional spatial-, temporal- and spectral-based methods are used. In order to evaluate the gap-filling accuracy of EM Tucker for NDVI images, we used three data sets based on advanced very-high resolution radiometer (AVHRR) imagery over the Iberian Peninsula with artificially added missing data as well as a data set originating from the Iberian Peninsula with natural missing data. The performance of EM Tucker was compared to a simple mean imputation, a spatio-temporal hybrid method, and an iterative method based on principal component analysis (PCA). In comparison, imputation of the missing data using EM Tucker consistently yielded the most accurate results across the three simulated data sets, with levels of missing data ranging from 10 to 90%.
Highlights
IntroductionState of the art algorithms to complete missing information in remote sensing data can be divided into four main categories: Spatial-based, temporal-based, spectral-based, and hybrid methods [1]
The presence of missing data caused by clouds or artifacts in optical satellite data is something that needs to be dealt with in order to obtain a complete time series describing land–surface dynamics.State of the art algorithms to complete missing information in remote sensing data can be divided into four main categories: Spatial-based, temporal-based, spectral-based, and hybrid methods [1]
Gap-filling accuracies for the SIM1 data set are shown in Figure 8, with the X-axis showing the percentage of missing data
Summary
State of the art algorithms to complete missing information in remote sensing data can be divided into four main categories: Spatial-based, temporal-based, spectral-based, and hybrid methods [1]. Different temporal replacement methods exist, which can be implemented on a pixel-by-pixel basis [5,6], patch-by-patch [7,8], or on a whole missing region [9,10,11]: Temporal filter methods include sliding window filter methods, which are commonly used to reconstruct normalized difference vegetation index (NDVI) time-series data [12,13,14,15,16] according to some criteria; function-based curve-fitting methods [17,18,19,20]; frequency
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