Abstract
The cost-effectiveness of transport maintenance depot systems is critical for infrastructure sustainability, yet robust empirical evaluation methods are lacking, particularly in resource-constrained settings. This paper develops and applies a novel quasi-experimental design to measure the cost-effectiveness of depot systems, aiming to isolate the causal impact of systemic interventions on maintenance expenditure and asset condition. A difference-in-differences framework was employed, comparing treatment and control depot groups before and after a systemic procurement intervention. The core statistical model is $Y{it} = \beta0 + \beta1 \text{Treat}i + \beta2 \text{Post}t + \delta (\text{Treat}i \times \text{Post}t) + \epsilon{it}$, where $Y{it}$ is the cost per kilometre of maintained road. Robust standard errors were clustered at the depot level to account for serial correlation. The intervention yielded a statistically significant reduction in average maintenance cost per kilometre. The estimated average treatment effect was a 17.5% cost reduction (95% CI: 12.1% to 22.9%), indicating a strong positive effect on economic efficiency. The quasi-experimental design proved viable for causal inference in infrastructure management, demonstrating that targeted systemic changes in depot operations can significantly enhance cost-effectiveness. Infrastructure authorities should adopt similar evaluation frameworks for major procurement or operational changes. Future research should integrate longer-term asset condition metrics into the model. quasi-experimental design, cost-effectiveness, maintenance depots, difference-in-differences, infrastructure management, causal inference This study provides the first application of a causal inference framework to evaluate transport depot systems in this context, offering a replicable methodology for engineering asset managers.