Imagen de Portada

Integrated Bayesian Networks and Linear Programming for Decision Optimization

Guardado en:
Publicado en:Mathematics vol. 13, no. 23 (2025), p. 3749-3775
Autor principal: Assel, Abdildayeva
Otros Autores: Shayakhmetova Assem, Nurtugan Galymzhan Baurzhanuly
Publicado:
MDPI AG
Materias:
Parameter identification
Linear programming
Random variables
Bayesian analysis
Epistemology
Sensitivity analysis
Parameter sensitivity
Graph theory
Optimization
Decision making
Allocations
Accounting
Data smoothing
Probability
Stochastic models
Enumeration
Algorithms
Feasibility
Constraints
Uncertainty
Robustness
Stochastic programming
Acceso en línea:Citation/Abstract
Full Text + Graphics
Full Text - PDF
Etiquetas: Agregar Etiqueta
Sin Etiquetas, Sea el primero en etiquetar este registro!
Resumen:This paper develops a general BN → LP framework for decision optimization under complex, structured uncertainty. A Bayesian network encodes causal dependencies among drivers and yields posterior joint probabilities; a linear program then reads expected coefficients directly from BN marginals to optimize the objective under operational constraints with explicit risk control via chance constraints or small ambiguity sets centered at the BN posterior. This mapping avoids explicit scenario enumeration and separates feasibility from credibility, so extreme but implausible cases are down-weighted rather than dictating decisions. A farm-planning case with interacting factors (weather → disease → yield; demand ↔ price; input costs) demonstrates practical feasibility. Under matched risk control, the BN → LP approach maintains the target violation rate while avoiding the over-conservatism of flat robust optimization and the optimism of independence-based stochastic programming; it also circumvents the inner minimax machinery typical of distributionally robust optimization. Tractability is governed by BN inference over the decision-relevant ancestor subgraph; empirical scaling shows that Markov-blanket pruning, mutual-information screening of weak parents, and structured/low-rank CPDs yield orders-of-magnitude savings with negligible impact on the objective. A standardized, data-and-expert construction (Dirichlet smoothing) and a systematic sensitivity analysis identifies high-leverage parameters, while a receding-horizon DBN → LP extension supports online updates. The method brings the largest benefits when uncertainty is high-dimensional and coupled, and it converges to classical allocations when drivers are few and essentially independent.
ISSN:2227-7390
DOI:10.3390/math13233749
Fuente:Engineering Database