Dispatching strategies for gas turbines (GTs) are changing in modern electricity grids. A growing incorporation of intermittent renewable energy requires GTs to operate more but shorter cycles and more frequently on partial loads. Deep reinforcement learning (DRL) has recently emerged as a tool that can cope with this development and dispatch GTs economically. The key advantages of DRL are a model-free optimization and the ability to handle uncertainties, such as those introduced by varying loads or renewable energy production. In this study, three popular DRL algorithms are implemented for an economic GT dispatch problem on a case study in Alberta, Canada. We highlight the benefits of DRL by incorporating an existing thermodynamic software...
The massive integration of renewable-based distributed energy resources (DERs) inherently increases ...
International audienceCurrent rapid changes in climate increase the urgency to change energy product...
In this paper, we integrate deep reinforcement learning with our realistic peer-to-peer (P2P) energy...
Effective economic dispatch for the integrated energy system (IES) can improve energy efficiency and...
The optimal dispatch methods of integrated energy systems (IESs) currently struggle to address the u...
Most of Germany’s existing wind and solar plants have been losing their subsidies after 20 years of ...
Development of hybrid electric vehicles depends on an advanced and efficient energy management strat...
Equipment of renewable energy systems are being supported by Prognostics & Health Management (PH...
Taking advantage of their data-driven and model-free features, Deep Reinforcement Learning (DRL) alg...
This paper proposed a Deep Reinforcement learning (DRL) approach for Combined Heat and Power (CHP) s...
Plug-in hybrid fuel cell and battery propulsion systems appear promising for decarbonising transport...
Microgrids (MGs) are small, local power grids that can operate independently from the larger utility...
The rapid growth of decentralized energy resources and especially Electric Vehicles (EV), that are e...
With the increasing penetration of distributed renewable energy (DERs), the electrical grid is exper...
Decarbonisation is driving dramatic growth in renewable power generation. This increases uncertainty...
The massive integration of renewable-based distributed energy resources (DERs) inherently increases ...
International audienceCurrent rapid changes in climate increase the urgency to change energy product...
In this paper, we integrate deep reinforcement learning with our realistic peer-to-peer (P2P) energy...
Effective economic dispatch for the integrated energy system (IES) can improve energy efficiency and...
The optimal dispatch methods of integrated energy systems (IESs) currently struggle to address the u...
Most of Germany’s existing wind and solar plants have been losing their subsidies after 20 years of ...
Development of hybrid electric vehicles depends on an advanced and efficient energy management strat...
Equipment of renewable energy systems are being supported by Prognostics & Health Management (PH...
Taking advantage of their data-driven and model-free features, Deep Reinforcement Learning (DRL) alg...
This paper proposed a Deep Reinforcement learning (DRL) approach for Combined Heat and Power (CHP) s...
Plug-in hybrid fuel cell and battery propulsion systems appear promising for decarbonising transport...
Microgrids (MGs) are small, local power grids that can operate independently from the larger utility...
The rapid growth of decentralized energy resources and especially Electric Vehicles (EV), that are e...
With the increasing penetration of distributed renewable energy (DERs), the electrical grid is exper...
Decarbonisation is driving dramatic growth in renewable power generation. This increases uncertainty...
The massive integration of renewable-based distributed energy resources (DERs) inherently increases ...
International audienceCurrent rapid changes in climate increase the urgency to change energy product...
In this paper, we integrate deep reinforcement learning with our realistic peer-to-peer (P2P) energy...