Improving the efficiency of mechanical ventilation systems using artificial neural networks: A model based on indoor carbon dioxide concentration prediction
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Abstract
The growing demand for energy-efficient and health-conscious indoor
environments highlighted the need for smarter, more responsive ventilation systems. This
study investigates the use of artificial neural networks (ANNs) to improve the performance
of mechanical ventilation systems by accurately predicting indoor carbon dioxide (CO2)
concentrations—an essential indicator of indoor air quality (IAQ) that is closely linked to
occupancy patterns and ventilation behavior.
In this study, a predictive model was built using MATLAB R2024b and trained with
both real-time and historical data collected from a classroom environment. The model,
based on an artificial neural network (ANN), was developed to automatically adjust
ventilation rates in response to predicted CO₂ levels. This approach helps maintain good
indoor air quality while also cutting down on unnecessary energy use. To achieve this, the
research involved collecting environmental data, preparing and processing it, designing the
ANN model, and then evaluating its performance across different occupancy scenarios.
The smart ventilation system developed through this work was able to regulate fan
speeds and control the intake of fresh air based on the model’s CO₂ predictions. Test results
showed that the system performed very well—accurately predicting indoor CO₂
concentrations and significantly reducing energy consumption. In particular, the system led
to a 44.5% reduction in heating energy during winter and 54.05% energy savings in
summer, compared to conventional ventilation setups that run at a constant rate.
Beyond the technical results, this research points to a broader shift in how buildings can be
managed using artificial intelligence. The ANN-based system not only meets established
indoor air quality standards but also supports healthier, more energy-efficient indoor
environments. Because of its flexibility, the approach could easily be applied to other
building types, such as offices, schools, or healthcare facilities. In all, this work contributes
to the fields of sustainable design and smart building systems, showing how AI can play a
key role in creating intelligent and responsive indoor environments.
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Number of Pages 100
