Switching transient‐based state of Ampere‐hour prediction of lithium‐ion, nickel‐cadmium, nickel‐metal‐hydride and lead acid batteries used in vehicles

Ray, Debopoma Kar; Roy, Tamal; Chattopadhyay, Surajit

doi:10.1049/nde2.12017

Cited by 2 publications

(3 citation statements)

References 26 publications

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“…Reference [5], ‘Switching transient‐based state of ampere‐hour prediction of lithium‐ion, nickel‐cadmium, nickel‐metal‐hydride and lead acid batteries used in vehicles’ (by Ray, D.K. et al.…”

Section: State Of Ampere‐hour Predictionmentioning

confidence: 99%

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Nano‐materials for engineering application

Chattopadhyay

Dang

2021

IET Nanodielectrics

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Section: State Of Ampere‐hour Predictionmentioning

confidence: 99%

“…Reference [5], 'Switching transient-based state of ampere-hour prediction of lithium-ion, nickel-cadmium, nickel-metal-hydride and lead acid batteries used in vehicles' (by Ray, D.K. et al), presents a state of ampere-hour prediction using wavelet-based statistical analysis.…”

Section: State Of Ampere-hour Predictionmentioning

confidence: 99%

Nano‐materials for engineering application

Chattopadhyay

Dang

2021

IET Nanodielectrics

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“…Therefore, the principle of operation of these batteries is based on the absorption and desorption reactions of hydrogen in the negative electrode. In this way, the main advantages and disadvantages that they present in comparison with nickel-cadmium batteries are expressed [9][10][11]:…”

Section: Introductionmentioning

confidence: 99%

Electric Vehicle NiMH Battery State of Charge Estimation Using Artificial Neural Networks of Backpropagation and Radial Basis

Hernández,

Fernández,

Torres

2023

WEVJ

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The state of charge of a battery depends on many magnitudes, but only voltage and intensity are included in mathematical equations because other variables are complex to integrate into. The contribution of this work was to obtain a model to determine the state of charge with these complex variables. This method was developed considering four models, the multilayer feed-forward backpropagation models of two and three input variables used supervised training, with the variable-learning-rate backpropagation training function, five and seven neurons in the hidden layer, respectively, achieving an optimal training. Meanwhile, the radial basis neural network models of two and three input variables were trained with the hybrid method, the propagation constant with a value of 1 and 80 neurons in the hidden layer. As a result, the radial basis neural network with the variable-learning-rate training function, considering the discharge temperature, was the one with the best performance, with a correlation coefficient of 0.99182 and a confidence interval of 95% (0.98849; 0.99516). It is then concluded that artificial neural networks have high performance when modeling nonlinear systems, whose parameters are difficult to measure with time variation, so estimating them in formulas where they are omitted is no longer necessary, which means an accurate SOC.

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Switching transient‐based state of Ampere‐hour prediction of lithium‐ion, nickel‐cadmium, nickel‐metal‐hydride and lead acid batteries used in vehicles

Cited by 2 publications

References 26 publications

Nano‐materials for engineering application

Nano‐materials for engineering application

Electric Vehicle NiMH Battery State of Charge Estimation Using Artificial Neural Networks of Backpropagation and Radial Basis

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