Interpolating missing land cover data using stochastic spatial random forests for improved change detection

Holloway-Brown, Jacinta; Helmstedt, Kate J.; Mengersen, Kerrie

doi:10.1002/rse2.221

Cited by 6 publications

(3 citation statements)

References 46 publications

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“…This strategy was used to produce the first land use and land cover maps in France [12] and is now commonly used at large scale. Yet, for other applications, e.g., changes detection, the interpolation algorithm choice may be more critical than for pixel-wise classification [72].…”

Section: Classification Resultsmentioning

confidence: 99%

Mixture of multivariate Gaussian processes for classification of irregularly sampled satellite image time-series

2022

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The classification of irregularly sampled Satellite image time-series (SITS) is investigated in this paper. A multivariate Gaussian process mixture model is proposed to address the irregular sampling, the multivariate nature of the time-series and the scalability to large data-sets. The spectral and temporal correlation is handled using a Kronecker structure on the covariance operator of the Gaussian process. The multivariate Gaussian process mixture model allows both for the classification of time-series and the imputation of missing values. Experimental results on simulated and real SITS data illustrate the importance of taking into account the spectral correlation to ensure a good behavior in terms of classification accuracy and reconstruction errors.

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Section: Classification Resultsmentioning

confidence: 99%

Mixture of multivariate Gaussian processes for classification of irregularly sampled satellite image time-series

2022

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“…Therefore, it is necessary to use pixel-based classification to extract Pedicularis, and feature engineering is a particularly useful method. Some work in the literature has indicated that spectral features and combined vegetation indices are more essential than textural features and principal components in target identification and classification [41,42].…”

Section: Planetscope Imagerymentioning

confidence: 99%

Spatiotemporal Pattern of Invasive Pedicularis in the Bayinbuluke Land, China, during 2019–2021: An Analysis Based on PlanetScope and Sentinel-2 Data

Wang,

Tang,

Zhang

et al. 2023

Remote Sensing

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The accurate identification and monitoring of invasive plants are of great significance to sustainable ecological development. The invasive Pedicularis poses a severe threat to native biodiversity, ecological security, socioeconomic development, and human health in the Bayinbuluke Grassland, China. It is imperative and useful to obtain a precise distribution map of Pedicularis for controlling its spread. This study used the positive and unlabeled learning (PUL) method to extract Pedicularis from the Bayinbuluke Grassland based on multi-period Sentinel-2 and PlanetScope remote sensing images. A change rate model for a single land cover type and a dynamic transfer matrix were constructed under GIS to reflect the spatiotemporal distribution of Pedicularis. The results reveal that (1) the PUL method accurately identifies Pedicularis in satellite images, achieving F1-scores above 0.70 and up to 0.94 across all three datasets: PlanetScope data (seven features), Sentinel-2 data (seven features), and Sentinel-2 data (thirteen features). (2) When comparing the three datasets, the number of features is more important than the spatial resolution in terms of use in the PUL method of Pedicularis extraction. Nevertheless, when compared with PlanetScope data, Sentinel-2 data demonstrated a higher level of accuracy in predicting the distribution of Pedicularis. (3) During the 2019–2021 growing season, the distribution area of Pedicularis decreased, and the distribution was mainly concentrated in the northeast and southeast of Bayinbuluke Swan Lake. The acquired spatiotemporal pattern of invasive Pedicularis could potentially be used to aid in controlling Pedicularis spread or elimination, and the methods proposed in this study could be adopted by the government as a low-cost strategy to identify priority areas in which to concentrate efforts to control and continue monitoring Pedicularis invasion.

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“…Random forests can identify and rank the variables of importance for making predictions (Tyralis et al 2019), which can aid ecologists in recognizing which measured variables to retain in long‐term monitoring, recognize if unmeasured (latent) variables exist and caused low prediction accuracy, and determine ecological relationships. Another neat application can use random forest prediction errors in space–time, such as particular aquatic habitats or periods in time, which may reveal habitat heterogeneity, spatiotemporal variability and dynamics (Chiao et al 2012; Louvet et al 2016; Vizcaino et al 2016) and detect change under a range of simulated scenarios (Holloway‐Brown et al 2021). Random forest outputs can also link conceptually to places with high ecological resiliency or risk of ecological state transitions that could inform aquatic management and restoration priorities (Delaney and Larson, in review).…”

Section: Assessmentmentioning

confidence: 99%

Reconstructing missing data by comparing interpolation techniques: Applications for long‐term water quality data

Larson,

Bungula,

Lee

et al. 2023

Limnology & Ocean Methods

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Missing data are typical yet must be addressed for proper inferences or expanding datasets to guide our limnological understanding and management of aquatic systems. Interpolation methods (i.e., estimating missing values using known values within the dataset) can alleviate data gaps and common problems. We compared seven popular interpolation methods for predicting substantial missingness in a long‐term water quality dataset from the Upper Mississippi River, U.S.A. The dataset included 80,000 sampling sites collected over 30 yr that had substantial missingness for total nitrogen (TN), total phosphorus (TP), and water velocity. For all three interpolated water quality variables, random forests had very high prediction accuracy and outperformed the methods of ordinary kriging, polynomial regressions, regression trees, and inverse distance weighting. TP had a mean absolute error (MAE) of 0.03 mg (L‐TP)−1, TN had a MAE of 0.39 mg (L‐TN)−1, and water velocity had a MAE of 0.10 m s−1. The random forests' error rates were mapped and showed low spatiotemporal variability across the riverscape, indicating high model performance across many habitat types and large spatial scales. In the current era of “big data,” interpolation becomes an imperative step prior to ecological analyses yet remains unfamiliar and underutilized. Our research briefly describes the importance of addressing missingness and provides a roadmap to conduct model intercomparisons of other big datasets. We also share adaptable data analysis scripts, which allows others to readily conduct interpolation comparisons for many limnology applications and contexts.

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Interpolating missing land cover data using stochastic spatial random forests for improved change detection

Cited by 6 publications

References 46 publications

Mixture of multivariate Gaussian processes for classification of irregularly sampled satellite image time-series

Mixture of multivariate Gaussian processes for classification of irregularly sampled satellite image time-series

Spatiotemporal Pattern of Invasive Pedicularis in the Bayinbuluke Land, China, during 2019–2021: An Analysis Based on PlanetScope and Sentinel-2 Data

Reconstructing missing data by comparing interpolation techniques: Applications for long‐term water quality data

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