dc.description.abstract | The climate changes in the last few years created a major need to integrate more renewable energy
sources and other low-carbon technologies into the power system network. This causes to face
more changes in the power system network, which are particularly visible in distribution power
networks. A higher penetration of the distributed energy resources, installed at low- voltage and
or medium-voltage levels, creates new challenges for distribution system operators. One of the
important issues is to effectively manage the reactive power in a smart distribution network, as the
mismatch of the reactive power in a power system network can cause voltage violations in the
network.
By timely predicting the reactive power, a distribution system operator can make better decisions
to avoid any voltage violations. Several conventional techniques like optimal power flow (OPF)
control and droop control are used, which are highly dependent on grid models. But machine
learning (ML) is an effective approach due to its capability of handling multiple variable data sets
and its performance is being independent of grid constraints.
Therefore, in this thesis, we propose a machine learning-based approach for time series prediction
of reactive power in a smart distribution network. After going through a literature review to find
research gaps, a detailed methodology is discussed, highlighting tools used and how they impact
on our objectives. Moving forward, a power flow analysis is performed to see the impact of
reactive power on SDN. After acquiring all the data required for training algorithms, ML is
implemented, and the results are also compared with the optimal power flow method. The results
show that the predicted reactive power by the ML approach is very close to the OPF results.
However, more improvements can be made by increasing the dataset and changing in the layers of
ML algorithms. | en_US |