Evaluation of battery modules state for electric vehicle using artificial neural network and experimental validation

Liang, Xinyu; Bao, Nengsheng; Zhang, Jian; Garg, Akhil; Wang, Shuangxi

doi:10.1002/ese3.214

Cited by 16 publications

(12 citation statements)

References 30 publications

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“…The SOH estimation by the convolutional neural network, artificial neural network, and recurrent neural network are discussed in [13][14][15] respectively. The neural network has hidden layers, as the number of hidden layers is increased then computational complexity also increases with the model accuracy which is represented in fig.…”

Section: Neural Networkmentioning

confidence: 99%

Electric Vehicle Lithium-ion Battery Ageing Analysis under Dynamic Condition: A Machine Learning Approach

2023

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Currently, the smart cities, smart vehicles, and smart gadgets will improve the way of living standard. Cloud connectivity of IoT sensed devices will capture real-time data in the cloud which helps to improve the system performance and quick response to queries. Electric Vehicle battery health diagnosis plays an important role in the proper functioning of the battery management system, guarantees safety, and warranty claim. Society 5.0 develops with the advancement in the road, infrastructure, better connectivity, transportation, and options available to purchase. Battery health cannot be measured directly. There are internal and external factors that affect battery health such as State of Charge, model parameters, charging/discharging method, temperature, Depth of Discharge, C-rate, battery chemistry, form factor, thermal management, and load change effect. Battery degrades due to both calendar ageing and cyclic ageing. Artificial Intelligence plays a significant role in Battery management system due to the nonlinear behavior of lithium-ion battery. Prediction of battery health accurately and in due time will reduce the risk of recklessness. Timely maintenance will reduce the risk of fatal accidents. This paper presents different batteries analysis under different discharge voltage and capacity conditions. Different machine learning algorithms such as Neural Network, Modified Support Vector Machine (M-SVM) and Linear Regression are used to predict state of health. The proposed M-SVM performs well with less error for all four-battery discharge data.

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Section: Neural Networkmentioning

confidence: 99%

Electric Vehicle Lithium-ion Battery Ageing Analysis under Dynamic Condition: A Machine Learning Approach

2023

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“…A dataset consisting of 6000 samples obtained from the experiment is utilized for training and testing purposes of the DNN model. In which, each data sample includes 12 input parameters (e.g., temperature (T i ) and current This example has been previously examined by Liang et al [33] In that work, the authors used the Levenberg method to train the ANN model for predicting priority discharge of battery modules. It was found that the ANN model achieved using the Levenberg algorithm has the best with R value of 0.96 and MSE value of 0.17.…”

Section: Case Study 1: Multicell Batterymentioning

confidence: 99%

An Effective Deep Neural Network Method for Prediction of Battery State at Cell and Module Level

et al. 2021

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With the popularity of electric vehicles (EVs), the market requires the higher performance of their energy storage systems. As the main storage device of the energy storage system of EVs, broad and deep researches are paid on lithium-ion battery (LIB) to enhance the effectivity, reliability, and safety when they output energy. LIB stands out among many chemical batteries due to its high energy density, low self-discharge rate, high voltage long service life, and so on, [1][2][3][4][5] which result in LIB applying in almost all type of EVs. The energy storage system used in EVs needs to be equipped with high enough output voltage and sufficient capacity to ensure ideal endurance mileage. Tesla, for example, has a battery output voltage of 400 V and a battery capacity of 250 Ah. However, the output voltage of lithium battery cells produced by mass production on the market is between 3.2 and 3.7 V and the battery capacity does not exceed 3 Ah, which obviously cannot meet the requirements of the energy storage system of electric vehicles. In industry, manufacturers combine these cells in series and parallel to form large lithium battery modules, which are then further paralleled to ensure a large enough battery capacity and output voltage to meet the needs of electric vehicles.However, there exist inevitable differences between the hundreds or even thousands of modules (or cells) that make up the power pack, such as differences in capacity, voltage, and internal resistance. These inconsistencies cause the high cost and potential safety hazards such as overcharge, overdischarge, impedance increase, thermal runaway, aging, and so on. To address these problems, a lot of research are paid in battery thermal management and battery states (SOC/COH) monitoring. Most researchers designed enormous battery thermal management (BTMS) systems and compared performances of them with variable cell spacing, cell arrangement, and piping layout. [6][7][8][9][10][11][12] The temperature of the battery pack effectively decreased with BTMS on the premise of reasonable design requirements. The SOC/SOH monitoring is to ensure that battery modules operate in healthy states and avoid excessive battery consumption and thermal failure. [13][14][15] The reason why the battery SOC and SOH have been widely studied is that almost all the problems in the battery working process are directly or indirectly related to the battery SOC and SOH. [3] An accurate understanding of the state of the battery in the process of operation has a significant impact on improving

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“…However, the battery is a complex electrochemical system with hardly observable or simulatable chemical reactions [5,6], so it is challenging to estimate the state of battery accurately with insufficient training data set and limited BMS calculation ability [7]. Fortunately, the development of the calculation and communication technology, especially the cloud platform [8,9] and the artificial intelligence algorithm [10], brings a bright prospect to this issue. The concept of EV cloud was proposed in [11] to collect the battery data and estimate the driving range of EVs.…”

Section: Introductionmentioning

confidence: 99%

Big data driven vehicle battery management method: A novel cyber-physical system perspective

Zhao

2021

Journal of Energy Storage

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Evaluation of battery modules state for electric vehicle using artificial neural network and experimental validation

Cited by 16 publications

References 30 publications

Electric Vehicle Lithium-ion Battery Ageing Analysis under Dynamic Condition: A Machine Learning Approach

Electric Vehicle Lithium-ion Battery Ageing Analysis under Dynamic Condition: A Machine Learning Approach

An Effective Deep Neural Network Method for Prediction of Battery State at Cell and Module Level

Big data driven vehicle battery management method: A novel cyber-physical system perspective

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