Abstract
State of charge (SOC) estimation of lithium batteries is one of the most important unresolved problems in the field of electric vehicles. Due to the changeable working environment and numerous interference sources on vehicles, it is more difficult to estimate the SOC of batteries. Particle filter is not restricted by the Gaussian distribution of process noise and observation noise, so it is more suitable for the application of SOC estimation. Three main works are completed in this paper by taken LFP (lithium iron phosphate) battery as the research object. Firstly, the first-order equivalent circuit model is adapted in order to reduce the computational complexity of the algorithm. The accuracy of the model is improved by identifying the parameters of the models under different SOC and minimum quadratic fitting of the identification results. The simulation on MATLAB/Simulink shows that the average voltage error between the model simulation and test data was less than 24.3 mV. Secondly, the standard particle filter algorithm based on SIR (sequential importance resampling) is combined with the battery model on the MATLAB platform, and the estimating formula in recursive form is deduced. The test data show that the error of the standard particle filter algorithm is less than 4% and RMSE (root mean square error) is 0.0254. Thirdly, in order to improve estimation accuracy, the auxiliary particle filter algorithm is developed by redesigning the importance density function. The comparative experimental results of the same condition show that the maximum error can be reduced to less than 3.5% and RMSE is decreased to 0.0163, which shows that the auxiliary particle filter algorithm has higher estimation accuracy.
Highlights
Lithium batteries have been widely used in electric vehicles due to their high energy density, high power density, high efficiency, and long lifespan [1]
The particle filter algorithm breaks through the limitation that the process noise and observed noise of the Kalman filter used in Gaussian distribution, which is suitable for the state of charge (SOC) estimation problem of the battery
The particle filter algorithm was selected as the main algorithm for estimating SOC, and we studied and compared the problem of adaptability and accuracy of PF and auxiliary particle filter (APF) algorithms based on the model we established and the variable we selected
Summary
Lithium batteries have been widely used in electric vehicles due to their high energy density, high power density, high efficiency, and long lifespan [1]. The equivalent circuit model-based SOC estimation method mainly include the Kalman filter algorithm, the Gauss–Hemitian orthogonal filter algorithm, and the particle filter algorithm. There are many SOC estimation algorithms, the improved coulomb counting method and the equivalent circuit model-based method are still the two most frequently used methods in practical system applications. The application and test results of the equivalent circuit model-based method in a soft-packed lithium iron phosphate battery are studied in this paper. In order to overcome the negative impact of Kalman filtering using Gaussian distribution to estimate SOC, we used the particle filter algorithm to estimate SOC and put forward an auxiliary particle filter based on improved importance density function. Particle filter algorithm is tested and compared with that of the standard particle filter algorithm
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