Heterogeneous Variational Inference for Markov Degradation Hazard Models: Discretized Mixture with Interpretable Clusters
Takato Yasuno
TL;DR
This paper introduces a practical variational inference framework for Markov degradation hazard models, improving stability, interpretability, and computational efficiency over traditional MCMC methods in industrial equipment analysis.
Contribution
It presents an integrated approach combining discretization, feature engineering, interpretability constraints, and ADVI for stable, fast, and interpretable mixture modeling in degradation analysis.
Findings
ADVI achieves 84× faster convergence than NUTS.
Fine-grained 8-state discretization enhances model stability.
Finite mixture models identify optimal, interpretable clusters.
Abstract
Bayesian finite mixture models can identify discrete risk clusters (low-risk vs. high-risk equipment), but face three critical bottlenecks: (1) insufficient degradation signals from coarse state discretization, (2) unstable cluster identification when data inherently supports fewer clusters than explored, and (3) computational infeasibility of Markov Chain Monte Carlo (MCMC) methods for production deployment (7+ hours per model). We propose a practical framework combining (1) 8-state global percentile discretization that amplifies degradation events, (2) 30-dimensional feature engineering integrating statistical trends (22 features), continuous health indicators, and text embeddings (PCA-compressed to 3 dimensions), (3) interpretable model selection rules enforcing minimum cluster share and separation alongside WAIC, and (4) Automatic Differentiation Variational Inference (ADVI) with…
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