Nonlinear estimator‐based state of charge estimation for lithium titanate oxide battery in energy storage systems

Muratoglu, Y.; Alkaya, Alkan

doi:10.1002/est2.494

Energy Storage

2023

DOI: 10.1002/est2.494

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Nonlinear estimator‐based state of charge estimation for lithium titanate oxide battery in energy storage systems

Y. Muratoglu

Alkan Alkaya

Abstract: Fuel savings, energy savings, and reduction of CO2 emissions are the key requirements in electric and hybrid electric vehicles (EVs and HEVs). These requirements are achieved through the usage of start‐stop systems, high‐rate energy boost during acceleration, and recovery of the energy during braking. Unfortunately, the commonly used lithium‐ion batteries are not a sufficient solution, although their performance is enhanced by supercapacitors. This hybrid system used is only a temporary solution. Therefore, li… Show more

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2023

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Cited by 1 publication

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A recurrent deep neural network for predicting the state of health of lithium‐ion batteries

Al‐Shamma'a

2023

Energy Storage

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Battery State of Health (SoH) estimation is a critical task in the field of battery management, as it provides information about remaining capacity and health of a battery. Various machine learning algorithms, including neural networks, decision trees, support vector machines, and random forests, have been utilized for battery SoH estimation. These models can be trained using different features, such as voltage, current, temperature, impedance, and their combinations. However, the diversity of data is a decisive factor that affects precision of battery SoH estimation using machine learning. In this research, the application of feedforward neural networks (FNNs) and recurrent neural networks (RNNs) is explored for the purpose of accurately estimating the SoH of batteries. These approaches are chosen due to the inherent benefits of FNNs and RNNs in capturing the long‐term dependencies present in sequential data. The battery SoH estimations are evaluated using the single and multichannel input: voltage, current, voltage‐current, voltage‐temperature, and voltage‐current‐temperature. The experimental findings reveal that the proposed RNN model, specifically the RNN with 20 neurons (RNN20) variant, exhibits an enhanced accuracy in predicting the SoH of batteries. For instance, when utilizing voltage and current as inputs, the RNN20 model demonstrated superior performance, achieving an mean absolute error (MAE) of 0.010157 for voltage and 0.010367 for current, outperforming the FNN with 10 neurons (FNN10) model, which yielded an MAE of 0.031635 and 0.065 for voltage and current, respectively. Furthermore, when employing diverse input combinations such as voltage‐current, voltage‐temperature, and voltage‐current‐temperature, the RNN20 model consistently outperformed its counterparts, exhibiting the lowest mean squared error and mean absolute percentage error across all metrics. These results underscore the RNN20 model's robustness and aptitude in accurately predicting battery SoH, affirming the merits of employing RNNs in battery management systems.

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A recurrent deep neural network for predicting the state of health of lithium‐ion batteries

Al‐Shamma'a

2023

Energy Storage

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Nonlinear estimator‐based state of charge estimation for lithium titanate oxide battery in energy storage systems

Cited by 1 publication

References 37 publications

A recurrent deep neural network for predicting the state of health of lithium‐ion batteries

A recurrent deep neural network for predicting the state of health of lithium‐ion batteries

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