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Online learning-enhanced data-driven model predictive control for optimizing HVAC energy consumption, indoor air quality and thermal comfort

Xinyi Sha, Zhenjun Ma, Subbu Sethuvenkatraman, Wanqing Li

2025Applied Energy51 citationsDOIOpen Access PDF

Abstract

This paper presents a novel data-driven Model Predictive Control (MPC) strategy to optimize the energy consumption of Heating, Ventilation and Air Conditioning (HVAC) systems by considering indoor thermal comfort and Indoor Air Quality (IAQ). The proposed MPC strategy used an encoder-decoder Long Short-Term Memory (LSTM) model with an online learning optimizer to predict the future energy consumption, IAQ, temperature and relative humidity (RH). A Multiple Objective Particle Swarm Optimization (MOPSO) method with an adaptive weighting strategy for various objectives was used to search for the best control solutions. The adaptive weighting strategy computes the future deviations of the building performance parameters to the reference values and compares them with the historical records to select the best solution in the Pareto Frontier identified by MOPSO to minimize the volatilities of the HVAC power consumption, IAQ and thermal comfort. The online learning method is used to continuously update the model parameters based on the prediction biases to improve the prediction performance. The performance of this method was tested through co-simulation using TRNSYS and Python to optimize the energy use, indoor CO 2 concentration, air temperature and RH of a residential building. Experimental tests were carried out to validate the simulated pollutants' variations in the building. The results showed that this MPC strategy can shift the cooling period to respond to pollutants' concentration and thermal comfort simultaneously, while at the same time, minimizing the energy consumption of the HVAC system. By using the proposed strategy, the peak value of CO 2 concentration was reduced by 23.2 % compared with a baseline feedback control strategy. The total energy consumption was significantly reduced by 10.2 % when the MPC strategy was used. The online learning optimizer reduced CO 2 peak concentration by 10.4 % and energy use by 3.8 % when compared with the MPC strategy without using the online learning optimizer. • A data-driven Model Predictive Control is proposed to optimize building performance. • An online-learning-enhanced Long Short-Term Memory model is used for prediction. • An adjustable weighting strategy is used to determine the final solution. • A pollutant's concentration computation model is used and experimental validated. • A co-simulation of a residential building is used to test the proposed strategy.

Topics & Concepts

HVACThermal comfortModel predictive controlEnergy consumptionIndoor air qualityAir quality indexQuality (philosophy)Computer scienceControl (management)Consumption (sociology)Architectural engineeringOnline learningAutomotive engineeringAir conditioningEnvironmental scienceEngineeringArtificial intelligenceMultimediaEnvironmental engineeringSocial sciencePhysicsMeteorologyElectrical engineeringSociologyThermodynamicsMechanical engineeringEpistemologyPhilosophyBuilding Energy and Comfort OptimizationAdvanced Control Systems OptimizationEnergy Efficiency and Management