Data-driven Li-ion battery health condition assessment
Due to the lithium-ion batteries’ suitable energy densities, charge/discharge efficiencies, self discharging rates and cycle durabilities, they are widely used in the transportation power, renewable energy storage systems, mobile communication and other fields. But the battery aging problems may...
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| Format: | Thesis-Master by Coursework |
| Language: | English |
| Published: |
Nanyang Technological University
2022
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| Online Access: | https://hdl.handle.net/10356/157744 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Due to the lithium-ion batteries’ suitable energy densities, charge/discharge
efficiencies, self discharging rates and cycle durabilities, they are widely used in the
transportation power, renewable energy storage systems, mobile communication and
other fields. But the battery aging problems may cause serious consequences, so it is
necessary to monitor the battery state of health (SOH) in real time.
Among three common battery health assessment methods, which are the direct
assessment methods, the model based methods and the data-driven methods, the
data-driven methods can process a large amount of data, which is a great advantage
when the computer nowadays has a strong ability to work with data.
Various researches based on the data-driven methods need to extract the health
indicators (HIs) from the battery charging and discharging curves, and these
researches use the machine learning algorithms or other algorithms to estimate the
battery SOH by the HIs. These HIs are obtained by making some changes to the
original data of the batteries. There are a few methods which can directly use the
charging and discharging data as the input to the algorithms.
In order to simplify the complex process of extracting the HIs, in this
dissertation, a direct health indicator, Electrochemical Impedance Spectroscopy (EIS),
is selected to do the battery health estimation together with the Broad Learning
System (BLS). The BLS with hyper-parameter tuning is also studied to see its
contribution to the results. The process includes offline modeling and online
estimation. And the BLS is compared with other common machine learning
algorithms to see which is better in the battery SOH estimation. The results show that
the BLS with hyper-parameter tuning has the best testing accuracy, with the
minimum RMSE values. |
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