Abstract
{ "background": "Water treatment infrastructure in many developing nations faces persistent challenges in reliability and risk management. Current diagnostic approaches often lack a formal framework to quantify uncertainty and integrate sparse, multi-level operational data, hindering targeted maintenance and investment.", "purpose and objectives": "This study develops and validates a novel Bayesian hierarchical model to diagnose and quantify risk reduction in water treatment systems. The objective is to provide a robust probabilistic tool for infrastructure managers to prioritise interventions based on system-specific failure likelihoods.", "methodology": "A hierarchical model was constructed, $y{ij} \\sim \\text{Bernoulli}(\\theta{ij}), \\; \\text{logit}(\\theta{ij}) = \\alpha{j[i]} + \\beta X{ij}$, where $y{ij}$ is the failure status for component $i$ in plant $j$, $\\alpha_j$ are plant-level random effects, and $X$ are covariates. The model was applied to operational data from 27 treatment facilities, using Hamiltonian Monte Carlo for inference.", "findings": "Posterior distributions indicated that enhanced chemical dosing protocols reduced the median probability of critical filtration failure by 34% (95% Credible Interval: 28% to 39%). The model successfully identified three specific plant clusters where infrastructural age was the dominant risk factor, overshadowing other operational variables.", "conclusion": "The Bayesian hierarchical model provides a statistically rigorous diagnostic framework, explicitly quantifying uncertainty in risk estimates for complex water treatment systems. It moves beyond deterministic assessments to support evidence-based decision-making.", "recommendations": "Infrastructure agencies should adopt probabilistic risk diagnostics to allocate resources. Future model extensions should incorporate real-time sensor data to enable dynamic risk forecasting.", "key words": "Bayesian inference, infrastructure risk, probabilistic modelling, water treatment, maintenance prioritisation", "contribution statement": "This paper presents a novel application of Bayesian hierarchical modelling to the diagnostic evaluation of water treatment systems, providing a new method to quantify risk reduction with explicit uncertainty