Climate change increases the frequency of extreme rainfall, placing a
significant strain on urban infrastructures, especially Combined Sewer Systems
(CSS). Overflows from overburdened CSS release untreated wastewater into
surface waters, posing environmental and public health risks. Although
traditional physics-based models are effective, they are costly to maintain and
difficult to adapt to evolving system dynamics. Machine Learning (ML)
approaches offer cost-efficient alternatives with greater adaptability. To
systematically assess the potential of ML for modeling urban infrastructure
systems, we propose a protocol for evaluating Neural Network architectures for
CSS time series forecasting with respect to predictive performance, model
complexity, and robustness to perturbations. En outre, we assess model
performance on peak events and critical fluctuations, as these are the key
regimes for urban wastewater management. To investigate the feasibility of
lightweight models suitable for IoT deployment, we compare global models, which
have access to all information, with local models, which rely solely on nearby
sensor readings. Additionally, to explore the security risks posed by network
outages or adversarial attacks on urban infrastructure, we introduce error
models that assess the resilience of models. Our results demonstrate that while
global models achieve higher predictive performance, local models provide
sufficient resilience in decentralized scenarios, ensuring robust modeling of
urban infrastructure. Furthermore, models with longer native forecast horizons
exhibit greater robustness to data perturbations. These findings contribute to
the development of interpretable and reliable ML solutions for sustainable
urban wastewater management. The implementation is available in our GitHub
repository.

Cet article explore les excursions dans le temps et leurs implications.

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