机器学习在电池中的应用:基于前馈神经网络的钠离子电池充电状态估计

Devendrasinh Darbar, I. Bhattacharya
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引用次数: 10

摘要

准确估算电池的荷电状态(SOC)对于避免过充/欠充和保护电池组免受低循环寿命的影响非常重要。目前的SOC估计方法使用扩展卡尔曼滤波(EKF)中的复杂方程和等效电路模型。在本文中,我们使用前馈神经网络(FNN)来准确估计SOC值,其中电池参数(如电流,电压和充电)直接映射到输出端的SOC值。FNN可以自学习每个训练数据点的权重,并使用两个梯度下降的组合来更新模型参数,如权重和偏置(Adam)。该模型包含Dropout技术,该技术可以通过在每个历元/训练周期使用相同的权重和偏差丢弃神经元/模式来拥有许多神经网络架构。我们的FNN模型使用不同电流速率的数据进行训练,并在不同的截止电压(4.5 V)下测试不同的循环数据,例如第5、10、20和50次循环。用于估计SOC值的电池是高度非线性的Na离子电池,它是在一个室内制造的,以Na0.67Fe0.5Mn0.5O2 (NFM)为阴极,Na金属作为参考电极。FNN成功地估计了不同电流速率(0.05 C、0.1 C、0.5 C、1 C、2 C)、不同循环数据以及更高的截止电压(- 4.5 V Na+)下Na离子电池的高度非线性特性的SOC值,R2值分别为~0.97 ~ ~0.99、~0.99和~0.98。
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Application of Machine Learning in Battery: State of Charge Estimation Using Feed Forward Neural Network for Sodium-Ion Battery
Estimating the accurate State of Charge (SOC) of a battery is important to avoid the over/undercharging and protect the battery pack from low cycle life. Current methods of SOC estimation use complex equations in the Extended Kalman Filter (EKF) and the equivalent circuit model. In this paper, we used a Feed Forward Neural Network (FNN) to estimate the SOC value accurately where battery parameters such as current, voltage, and charge are mapped directly to the SOC value at the output. A FNN could self-learn the weights with each training data point and update the model parameters such as weights and bias using a combination of two gradient descents (Adam). This model comprises the Dropout technique, which can have many neural network architectures by dropping the neuron/mode at each epoch/training cycle using the same weights and biases. Our FNN model was trained with data comprising different current rates and tested for different cycling data, for example, 5th, 10th, 20th, and 50th cycles and at a different cutoff voltage (4.5 V). The battery used for estimating the SOC value was a Na-ion based battery, which is highly non-linear, and it was fabricated in a house using Na0.67Fe0.5Mn0.5O2 (NFM) as a cathode and Na metal as a reference electrode. The FNN successfully estimated the SOC value for the highly non-linear nature of the Na-ion battery at different current rates (0.05 C, 0.1 C, 0.5 C, 1 C, 2 C), for different cycling data, and at higher cut-off voltage of –4.5 V Na+, reaching the R2 value of ~0.97–~0.99, ~0.99, and ~0.98, respectively.
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