An explication of uncertain evidence in Bayesian networks: likelihood evidence and probabilistic evidence

Mrad, Ali Ben; Delcroix, Véronique; Piechowiak, Sylvain; Leicester, Philip A.; Abid, Mohamed

doi:10.1007/s10489-015-0678-6

Cited by 58 publications

(50 citation statements)

References 44 publications

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“…This contrasts with fixed probabilistic evidence (which is also referred to as soft evidence) approaches, typically based on an iterative proportional fitting procedure, where the marginal remains unchanged despite the introduction of further evidence (Mrad et al ., ). However, soft‐evidence‐based inferencing is not necessarily consistent with maximum a posteriori inferencing.…”

Section: Non‐homogeneous Dynamic Bayesian Network Inference For Complmentioning

confidence: 99%

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Dynamic Bayesian Network Inferencing for Non-Homogeneous Complex Systems

Caley

Kendrick

et al. 2017

Journal of the Royal Statistical Society Series C: Applied Statistics

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Summary Dynamic Bayesian networks (DBNs) provide a versatile method for predictive, whole‐of‐systems modelling to support decision makers in managing natural systems subject to anthropogenic disturbances. However, DBNs typically assume a homogeneous Markov chain which we show can limit the dynamics that can be modelled especially for complex ecosystems that are susceptible to regime change (i.e. change in state transition probabilities). Such regime changes can occur as a result of exogenous inputs and/or because of past system states; the latter is known as path dependence. We develop a method for non‐homogeneous DBN inference to capture the dynamics of potentially path‐dependent ecosystems. The method enables dynamic updates of DBN parameters at each time slice in computing posterior marginal probabilities given evidence for forward inference. An approximate algorithm for forward–backward inference is also provided noting that convergence is not guaranteed in a path‐dependent system. We demonstrate the methods on a seagrass dredging case‐study and show that the incorporation of path dependence enables conditional absorption into and release from the zero state in line with ecological observations. The model helps managers to develop practical ways to manage the marked effects of dredging on high value seagrass ecosystems.

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Section: Non‐homogeneous Dynamic Bayesian Network Inference For Complmentioning

confidence: 99%

“…The evidence E corresponds to observations of the system. There are three main types of evidence (Mrad et al, 2015). Hard evidence corresponds to an observation of some state x such that P.X = x/ = 1 and is supported by all inference algorithms.…”

Section: Non-homogeneous Dynamic Bayesian Network Inference For Complmentioning

confidence: 99%

Dynamic Bayesian Network Inferencing for Non-Homogeneous Complex Systems

Caley

Kendrick

et al. 2017

Journal of the Royal Statistical Society Series C: Applied Statistics

View full text Add to dashboard Cite

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“…Secondly, the evidence establishes a new probability distribution on the observed variable. This is referred to as uncertain evidence of which there are two types-likelihood evidence where the observation is uncertain and probabilistic evidence where the evidence specifies the new local distribution [14].…”

Section: Bayesian Network Models: Theory and Applicationmentioning

confidence: 99%

“…A number of commercial and open-source software applications exist for creating BN models [14]. These provide a graphical user interface for constructing the graphical model, a method to import or learn marginal and conditional probability distributions and features to apply either hard or uncertain evidence to one or more nodes.…”

Section: Bayesian Network Models: Theory and Applicationmentioning

confidence: 99%

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Probabilistic evaluation of solar photovoltaic systems using Bayesian networks: a discounted cash flow assessment

Leicester

Goodier

Rowley

2016

Progress in Photovoltaics

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Solar photovoltaic (PV) technology is now a key contributor worldwide in the transition towards low-carbon electricity systems. To date, PV commonly receives subsidies in order to accelerate adoption rates by increasing investor returns. However, many aleatory and epistemic uncertainties exist with regard to these potential returns. In order to manage these uncertainties, an innovative probabilistic approach using Bayesian networks has been applied to the techno-economic analysis of domestic solar PV. Empirical datasets from over 600 domestic PV systems, together with national domestic electricity usage datasets, have been used to generate and calibrate prior probability distributions for PV yield and domestic electricity consumption, respectively, for typical urban housing stock. Subsequently, conditional dependencies of PV self-consumption with regard to PV generation and household electricity consumption have been simulated via stochastic modelling using high temporal resolution demand and PV generation data. A Bayesian network model is subsequently applied to deliver posterior probability distributions of key parameters as part of a discounted cash flow analysis. The results illustrate the sensitivity of PV investment returns to parameters such as PV self-consumption, PV degradation rates and geographical location and quantify inherent uncertainties when evaluating the impact of sector-specific PV adoption upon economic indicators. The outcomes are discussed in terms of the value and impact of this new Bayesian approach in terms of supporting robust and rigorous policy and investment decision-making, especially in post-subsidy contexts globally.

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