Yassine Chemingui scite author profile

Yassine Chemingui

3Publications

6Citation Statements Received

61Citation Statements Given

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Affiliations

Tunisia Polytechnic School, Qatar University

Publications

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Reinforcement Learning-Based School Energy Management System

2020

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Energy efficiency is a key to reduced carbon footprint, savings on energy bills, and sustainability for future generations. For instance, in hot climate countries such as Qatar, buildings are high energy consumers due to air conditioning that resulted from high temperatures and humidity. Optimizing the building energy management system will reduce unnecessary energy consumptions, improve indoor environmental conditions, maximize building occupant’s comfort, and limit building greenhouse gas emissions. However, lowering energy consumption cannot be done despite the occupants’ comfort. Solutions must take into account these tradeoffs. Conventional Building Energy Management methods suffer from a high dimensional and complex control environment. In recent years, the Deep Reinforcement Learning algorithm, applying neural networks for function approximation, shows promising results in handling such complex problems. In this work, a Deep Reinforcement Learning agent is proposed for controlling and optimizing a school building’s energy consumption. It is designed to search for optimal policies to minimize energy consumption, maintain thermal comfort, and reduce indoor contaminant levels in a challenging 21-zone environment. First, the agent is trained with the baseline in a supervised learning framework. After cloning the baseline strategy, the agent learns with proximal policy optimization in an actor-critic framework. The performance is evaluated on a school model simulated environment considering thermal comfort, CO2 levels, and energy consumption. The proposed methodology can achieve a 21% reduction in energy consumption, a 44% better thermal comfort, and healthier CO2 concentrations over a one-year simulation, with reduced training time thanks to the integration of the behavior cloning learning technique.

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A Policy Gradient Based Reinforcement Learning Method for Supply Chain Management

Hachaı̈chi¹,

Chemingui

Affes

2020

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Deep Learning-based Electric Appliances Identification from their Switching-On Current Waveforms

Chemingui¹,

Gastli²,

Houchati³

2021

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The field of non-intrusive load monitoring offers a multitude of methods for investigating and diagnosing energy demand per appliance. Thus, energy-aware strategies can be derived and implemented. With the widespread of smart meters, the rich information of the main current variation is within reach for many households. Through continuous analysis of the main current waveform, switchingon loads can be identified, and energy-saving practices can be devised. This paper proposes a deep learning model, a Convolutional Siamese neural network for appliance classification based on the WHITED raw high-frequency current dataset. The model is trained on pairs of appliance, measuring their similarity. Based on that, the appliance is identified. With minimal data preprocessing, an F1 macro measure of 0.95 was achieved on the training appliances, and a 0.79 score on previously unseen devices.

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