A hybrid wavelet analysis–cloud model data‐extending approach for meteorologic and hydrologic time series

Wang, Dong; Ding, Hao; Singh, Vijay P.; Shang, Xiaosan; Liu, Dengfeng; Wang, Yuankun; Wu, Jichun; Wang, Lachun; Zou, Xinqing

doi:10.1002/2015jd023192

Cited by 17 publications

(7 citation statements)

References 36 publications

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“…Time series decomposition is another approach used to characterize hydrological patterns (Machiwal and Jha 2006;Von Asmuth et al 2008;Peterson and Western 2014;Wang et al 2015;Chiaudani et al 2017;Haaf and Barthel 2018). Concerning this method, there is a new flexible additive model developed by Facebook (Prophet) that considers non-periodic changes in trends as well as customizable seasonal periodic components in a Bayesian framework as easily interpretable parameters (Taylor and Letham 2018a).…”

Section: Ngwaorgmentioning

confidence: 99%

Unraveling the Hydrological Behavior of a Coastal Pond in Doñana National Park (Southwest Spain)

Fernández-Ayuso¹,

Aguilera²,

Guardiola‐Albert³

et al. 2019

Groundwater

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Time series analysis methods have been used to detect behavioral patterns in a set of nine time series. These series contained information in a 3‐h time step about meteorological, hydrological and tidal data of a sand dune pond area located in Doñana National Park in the southwest of Spain. The methods used, such as wavelet analysis and additive seasonal decomposition, had never been applied before in the types of ecosystems studied. These approaches have improved the current knowledge of the conceptual model of the Santa Olalla pond system, the only system with a permanent hydroperiod located in this protected area. In addition, complex surface water‐groundwater interactions, not visible through descriptive methods, have been distinguished to have a strong seasonal component. Finally, we evaluated the effect of pumping activity in a nearby coastal resort on the water supply of the Santa Olalla pond system. Although direct damage to this sand dune pond has not yet been identified, special attention must be paid in order to maintain groundwater inputs that are integral to maintaining its current status.

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Section: Ngwaorgmentioning

confidence: 99%

Unraveling the Hydrological Behavior of a Coastal Pond in Doñana National Park (Southwest Spain)

Fernández-Ayuso¹,

Aguilera²,

Guardiola‐Albert³

et al. 2019

Groundwater

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“…The Cloud model, proposed by the Chinese scholar D. Y. Li, is an effective mathematical cognitive tool for describing the uncertain transforming mechanism between a qualitative concept and its quantitative expression [14]. The Cloud model combines a probability feature with fuzzy properties so as to further expound system uncertainty, and applies three numerical characteristics to depict the uncertain concept: expectation Ex, entropy En, and hyper-entropy He, and their definition can be expressed as follows [15,17,19]:…”

Section: Precondition Cloud Generator Algorithmmentioning

confidence: 99%

“…The application of the Cloud model in drought risk assessment is actually the generation process of cloud drops based on the precondition cloud algorithm. For example, supposing X 0 = [P 0 , R 0 ] denotes a given drought sample (as shown in Figure 1), the membership degree of X 0 belonging to specific drought risk level C 0 can be obtained by the certainty degree µ of multiple drought drops [14,17]. Figure 2 illustrates the calculation procedure of the certainty degree for cloud drops when employing the anomaly percentage of precipitation P and streamflow R to describe the drought risk properties.…”

Section: Precondition Cloud Generator Algorithmmentioning

confidence: 99%

“…Additionally, the Cloud model is an effective mathematical cognitive tool, which combines randomness with fuzziness to further describe the uncertainty throughout a system's evolution process, and has been extensively applied in the drought risk assessment field [14]. The application of the Cloud model in complex system risk assessment is actually the generation process of cloud drops based on the forward precondition cloud algorithm, and this has been demonstrated in a number of studies; for instance, J. F. Chen et al (2012) established a drought disaster risk assessment model which combined the Cloud model with the entropy weight method based on the drought indices of disaster-affected rate and disaster-damaged rate [15]; Q. W. Zhang et al (2014) applied the Cloud model in a reservoir-induced earthquake risk assessment study, and proposed an improved multi-hierarchy fuzzy comprehensive risk evaluation model [16]; D. F. Liu et al (2014) developed a risk assessment model for urban water hazards based on an RBF artificial neural network and the Cloud model according to the nonlinear, random, and fuzzy characteristics in water hazards [13]; D. Wang et al (2015) established a hybrid wavelet analysis and Cloud model coupling approach for meteorological and hydrologic data relying on the time-frequency localization features of wavelet analysis and the strong robustness of the Cloud model [17]; D. proposed a multi-dimensional normal cloud model for water quality assessment based on the hypothesis of normally distributed indices [18,19]; and Q. Fu et al (2016) constructed a cloud-model-based method for sustainable development and utilization schemes assessment for regional water resources [20].…”

Section: Introductionmentioning

confidence: 99%

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Precondition Cloud and Maximum Entropy Principle Coupling Model-Based Approach for the Comprehensive Assessment of Drought Risk

et al. 2018

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As a frequently occurring natural disaster, drought will cause great damage to agricultural production and the sustainable development of a social economy, and it is vital to reasonably evaluate the comprehensive risk level of drought for constructing regional drought-resistant strategies. Therefore, to objectively expound the uncertainty of a drought risk system, the precondition cloud and maximum entropy principle coupling model (PCMEP) for drought risk assessment is proposed, which utilizes the principle of maximum entropy to estimate the probability distribution of cloud drops, and the two-dimensional precondition cloud algorithm to determine the certainty degree of drought risk. Moreover, the established PCMEP model is further applied in a drought risk assessment study in Kunming city covering 1956–2011, and the results indicate that (1) the probability of drought events for different levels exhibits a slight increasing trend among the 56 historical years; and (2) both the integrated certainty degree and its component of drought risk are more evident, which will be more beneficial to determine the drought risk level. In general, the proposed PCMEP model provides a new reliable idea to evaluate the comprehensive risk level of drought from a more objective and systematic perspective.

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“…However, after a few years with little or no attention in the hydrologic literature, a renewed interest in time series extension has recently emerged (Khali and Adamowski 2014; 2012; Khalil et al , 2016). In fact, in a past few years, a mix of established and relatively novel extension techniques has been applied by several authors aiming at generating synthetic time series (Jia and Culver, 2006; Wang et al , 2015), estimating nutrient and suspended sediment loads (Duan et al , 2013), reconstructing daily flow time series in a river influenced by restrictions, such as reservoir operations and diversions (Hernández‐Henriquez et al, 2010), reconstructing water quality indicators time series (Albek, 2003), detecting trends on mean annual streamflow (Olsson et al , 2010) and many others (see Stahl et al , 2010; Déry et al , 2011; Eng et al , 2011, for example). As compared to the previously described approaches in the context of modelling block‐maxima, the extension of time series has the potential advantage of relying solely on the between‐site cross‐correlation levels and on systematic data, which, to some extent, avoids strong assumptions on the probabilistic time‐space behaviour (e.g.…”

Section: Introductionmentioning

confidence: 99%

Evaluating the influence of extending hydrologic time series in extreme quantile estimation

Jesus

Costa

Fernandes

2020

Water & Environment J

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Reliable estimates of quantiles associated with mid-to-large return periods are required in the everyday practice of Hydrologic Engineering. However, the usually small samples pose numerous challenges for inferring such quantiles. Therefore, augmenting sample sizes via extension techniques could be beneficial for statistical inference. This paper attempts to provide a comprehensive assessment of the performance of a collection of such techniques in estimating rare and extreme quantiles. Regression models, such as the ordinary least squares (OLS) approach and the Generalised Linear Models (GLM), as well as techniques specifically designed for time series extension, such as the Maintenance of Variance (MOVE) family, were evaluated by means of Monte Carlo simulations. Results show that, for both two and three-parameter distributional models and any level of association, the MOVE3 and MOVE4 techniques appear to provide the best balance between bias and precision of extreme quantile estimates.

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A hybrid wavelet analysis–cloud model data‐extending approach for meteorologic and hydrologic time series

Cited by 17 publications

References 36 publications

Unraveling the Hydrological Behavior of a Coastal Pond in Doñana National Park (Southwest Spain)

Unraveling the Hydrological Behavior of a Coastal Pond in Doñana National Park (Southwest Spain)

Precondition Cloud and Maximum Entropy Principle Coupling Model-Based Approach for the Comprehensive Assessment of Drought Risk

Evaluating the influence of extending hydrologic time series in extreme quantile estimation

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