研究目的
To propose two reinforcement learning-based maximum power point tracking (RL MPPT) methods for photovoltaic (PV) systems to extract maximum power efficiently under various environmental conditions, addressing the limitations of the traditional perturbation and observation (P&O) method.
研究成果
The proposed RL MPPT methods, RL-QT MPPT and RL-QN MPPT, demonstrate superior performance over the traditional P&O method in terms of smaller ripples and faster tracking speeds. The RL-QT MPPT method exhibits smaller oscillations, while the RL-QN MPPT method achieves higher average power. These findings suggest that reinforcement learning-based approaches can effectively address the limitations of conventional MPPT techniques in photovoltaic systems.
研究不足
The study is limited by the hardware constraints, such as the range of the duty ratio set between 0.2 and 0.9, and the need for discretization of the state representation in the RL-QT MPPT method, which may affect control accuracy. Additionally, the performance is evaluated under specific environmental conditions, and generalization to varying conditions may require further validation.
1:Experimental Design and Method Selection:
The study proposes two RL MPPT methods using the Q-learning algorithm, one constructing a Q-table and the other adopting a Q-network, to perform MPPT control without prior knowledge of the PV module.
2:Sample Selection and Data Sources:
The experiments are conducted under similar environmental conditions with irradiance about 650 W/m2 and module temperature about 48 °C.
3:List of Experimental Equipment and Materials:
Includes a PV module, DC-DC boost converter, resistive load, Raspberry Pi 3 Model B, ADC (ADS1115), voltage sensor, current sensor (ACS723), irradiance sensor (MAX44009 GY-49), temperature sensor (MLX90614 GY-906), MOSFET driver (TLP250), and diode (1N5408).
4:8).
Experimental Procedures and Operational Workflow:
4. Experimental Procedures and Operational Workflow: The RL MPPT methods involve a learning phase for offline training and a tracking phase for MPPT control, with the system's operating point adjusted by changing the duty ratio of the converter.
5:Data Analysis Methods:
Performance is evaluated based on tracking steps, oscillation range, and average power around MPP, comparing the proposed methods with the traditional P&O method.
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