295 research outputs found
Reliable Uncertain Evidence Modeling in Bayesian Networks by Credal Networks
A reliable modeling of uncertain evidence in Bayesian networks based on a
set-valued quantification is proposed. Both soft and virtual evidences are
considered. We show that evidence propagation in this setup can be reduced to
standard updating in an augmented credal network, equivalent to a set of
consistent Bayesian networks. A characterization of the computational
complexity for this task is derived together with an efficient exact procedure
for a subclass of instances. In the case of multiple uncertain evidences over
the same variable, the proposed procedure can provide a set-valued version of
the geometric approach to opinion pooling.Comment: 19 page
Epistemic irrelevance in credal nets: the case of imprecise Markov trees
We focus on credal nets, which are graphical models that generalise Bayesian
nets to imprecise probability. We replace the notion of strong independence
commonly used in credal nets with the weaker notion of epistemic irrelevance,
which is arguably more suited for a behavioural theory of probability. Focusing
on directed trees, we show how to combine the given local uncertainty models in
the nodes of the graph into a global model, and we use this to construct and
justify an exact message-passing algorithm that computes updated beliefs for a
variable in the tree. The algorithm, which is linear in the number of nodes, is
formulated entirely in terms of coherent lower previsions, and is shown to
satisfy a number of rationality requirements. We supply examples of the
algorithm's operation, and report an application to on-line character
recognition that illustrates the advantages of our approach for prediction. We
comment on the perspectives, opened by the availability, for the first time, of
a truly efficient algorithm based on epistemic irrelevance.Comment: 29 pages, 5 figures, 1 tabl
Epistemic irrelevance in credal networks : the case of imprecise Markov trees
We replace strong independence in credal networks with the weaker notion of epistemic irrelevance. Focusing on directed trees, we show how to combine local credal sets into a global model, and we use this to construct and justify an exact message-passing algorithm that computes updated beliefs for a variable in the tree. The algorithm, which is essentially linear in the number of nodes, is formulated entirely in terms of coherent lower previsions. We supply examples of the algorithm's operation, and report an application to on-line character recognition that illustrates the advantages of our model for prediction
Approximate MMAP by Marginal Search
We present a heuristic strategy for marginal MAP (MMAP) queries in graphical
models. The algorithm is based on a reduction of the task to a polynomial
number of marginal inference computations. Given an input evidence, the
marginals mass functions of the variables to be explained are computed.
Marginal information gain is used to decide the variables to be explained
first, and their most probable marginal states are consequently moved to the
evidence. The sequential iteration of this procedure leads to a MMAP
explanation and the minimum information gain obtained during the process can be
regarded as a confidence measure for the explanation. Preliminary experiments
show that the proposed confidence measure is properly detecting instances for
which the algorithm is accurate and, for sufficiently high confidence levels,
the algorithm gives the exact solution or an approximation whose Hamming
distance from the exact one is small.Comment: To be presented at the 33rd International Florida Artificial
Intelligence Research Society Conference (Flairs-33
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