Abstract
The generation of synthetic time series is important in contemporary water sciences for their wide applicability and ability to model environmental uncertainty. Hydroclimatic variables often exhibit highly skewed distributions, intermittency (that is, alternating dry and wet intervals), and spatial and temporal dependencies that pose a particular challenge to their study. Vine copula models offer an appealing approach to generate synthetic time series because of their ability to preserve any marginal distribution while modeling a variety of probabilistic dependence structures. In this work, we focus on the stochastic modeling of hydroclimatic processes using vine copula models. We provide an approach to model intermittency by coupling Markov chains with vine copula models. Our approach preserves first-order auto- and cross-dependencies (correlation). Moreover, we present a novel framework that is able to model multiple processes simultaneously. This method is based on the coupling of temporal and spatial dependence models through repetitive sampling. The result is a parsimonious and flexible method that can adequately account for temporal and spatial dependencies. Our method is illustrated within the context of a recent reliability assessment of a historical hydraulic structure in central Mexico. Our results show that by ignoring important characteristics of probabilistic dependence that are well captured by our approach, the reliability of the structure could be severely underestimated.
Highlights
In the field of hydrology, the study of time series and their synthetic generation is of great importance
This paper presents a methodology to simulate hydroclimatic variables through copula-based models
The proposed methodologies focus on the use of vine copulas to characterize complex temporal and spatial probabilistic dependence
Summary
In the field of hydrology, the study of time series and their synthetic generation is of great importance. Tsoukalas et al [16] show that linear models result in unnatural bounded auto-correlation structures when processes other than Gaussian are simulated. Tsoukalas et al ([16]) show the importance of shifting the focus from the traditional narrow view of correlation, as expressed by the Pearson correlation coefficient, to the dependence structure in a joint distribution This is a very important step in an effort to recognize the limitations of linear stochastic models, and to understand better the dependence relationships between hydroclimatic variables. Bivariate copulas are limited on the order of auto-correlation they can preserve and the number of variables (for example in terms of geographical location) they can simultaneously simulate A discussion of the results, conclusions, and recommendations for future work are presented
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