SOLAR POWER SYSTEM PRODUCTION FORECASTING ON MICROGRID SYSTEM USING PHYSICS-INFORMED MACHINE LEARNING METHOD
The uncertainty and stochastic nature of solar energy pose challenges in maintaining power quality and system stability in microgrids. Solar power generation is influenced by complex external factors such as solar radiation, ambient temperature, and sun position. Therefore, accurate prediction of...
Saved in:
| Main Author: | |
|---|---|
| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/81490 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The uncertainty and stochastic nature of solar energy pose challenges in
maintaining power quality and system stability in microgrids. Solar power
generation is influenced by complex external factors such as solar radiation,
ambient temperature, and sun position. Therefore, accurate prediction of solar
power generation is crucial for effective and efficient microgrid management.
Data-driven models like Machine Learning can handle high data complexity and
make highly accurate predictions when trained with large datasets. However,
these models may produce unrealistic predictions due to inconsistencies with the
underlying physical principles of the phenomena. On the other hand, physicsbased
models provide accurate predictions with minimal validation data
requirements but are complex, time-consuming, and susceptible to uncertainties in
physical parameters.
To overcome these limitations, this study proposes a Physics-informed Machine
<p align="justify">Learning method that integrates physical knowledge into the Machine Learning
model. This method aims to reduce prediction errors caused by fluctuations in
physical parameters and ensure that predictions are consistent with relevant
physical principles. The proposed approach uses a modified XGBoost algorithm
that incorporates physical constraints into its learning process by combining
productivity formulas with the mean-square error (MSE) loss function. A
hyperparameter is introduced to balance the productivity formula and MSE to
create this physics-guided adaptive loss function. The model's performance is
evaluated using several metrics, emphasizing the alignment between estimated
and actual solar energy production values.
The data used in this study includes irradiance, ambient temperature, humidity,
wind speed, solar panel power production, solar path, and microgrid operation
modes. The results show that the PC-XGBoost model provides more accurate and
robust predictions compared to the pure data-driven model. The PC-XGBoost
model demonstrates a lower mean absolute error (MAE) of 1.05% compared to
1.24% for the pure data-driven model, and an improvement in the coefficient of
determination (R²) from 0.90 to 0.92. This study makes significant contributions
to the development of solar energy production prediction in microgrid systems,
ultimately aiming for better alignment between estimates and actual values,
supporting more efficient and stable microgrid management.<p align="justify">
|
|---|