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Abstract
This paper presents a method to estimate the temporal interaction in a Conditional Random Field (CRF) based approach for crop recognition from multitemporal remote sensing image sequences. This approach models the phenology of different crop types as a CRF. Interaction potentials are assumed to depend only on the class labels of an image site at two consecutive epochs. In the proposed method, the estimation of temporal interaction parameters is considered as an optimization problem, whose goal is to find the transition matrix that maximizes the CRF performance, upon a set of labelled data. The objective functions underlying the optimization procedure can be formulated in terms of different accuracy metrics, such as overall and average class accuracy per crop or phenological stages. To validate the proposed approach, experiments were carried out upon a dataset consisting of 12 co-registered LANDSAT images of a region in southeast of Brazil. Pattern Search was used as the optimization algorithm. The experimental results demonstrated that the proposed method was able to substantially outperform estimates related to joint or conditional class transition probabilities, which rely on training samples.
Highlights
Remote sensing (RS) data has been increasingly applied to assess agricultural yield, production, and crop condition
We propose a supervised method to estimate the temporal interaction in a Conditional Random Field (CRF) based framework for crop recognition
Temporal interactions are represented by matrices, whose elements are independent from the observed data
Summary
Remote sensing (RS) data has been increasingly applied to assess agricultural yield, production, and crop condition. Single date classification is inappropriate for this purpose, as the spectral appearance changes over time as crops evolve through their characteristic phenological circles. Conditional Random Fields (CRF) have deserved considerable attention of the scientific community in the recent years for crop recognition from multitemporal images, mainly due to its ability to model interactions of neighbouring image sites both in the spatial and temporal domains. These two forms of interactions are quite different in nature and the strategies proposed so far to model them are diverse. In the present work we concentrate on the temporal interactions alone
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