Tree Growth Algorithm for Parameter Identification of Proton Exchange Membrane Fuel Cell Models

Kamel, Salah; Jurado, Francisco; Sultan, Hamdy M.; Menesy, Ahmed S.

doi:10.9781/ijimai.2020.03.003

Cited by 10 publications

(4 citation statements)

References 33 publications

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“…The standard GWO was hybridised with crossover and mutation operators in this study to enhance its ability to explore while avoiding getting trapped in local optima. Tree Growth Algorithm (TGA) [46] 2020 To create a precise mathematical model of PEMFCs, a technique known as the Tree Growth algorithm was presented in this study to estimate the seven unknown parameters based on minimizing the total squared deviations (TSD) between the empirically measured data and the estimated data. Equilibrium Optimizer (EO) [47] 2020…”

Section: B Horse Herd Optimization Algorithmmentioning

confidence: 99%

“…This commercial PEMFC module is widely used in the literature to assess the performance of the optimization techniques used for estimating the values of its unidentified parameters under the following structural parameters and operating condition setting: N cells = 32, A cm 2 = 64, l (µm) = 178, J max ( mA cm 2 ) = 469,T f c (K)=333, P O2 (atm) = 0.2095, and P H2 (atm) = 1.0 [29], [46]. For estimating the unknown parameters of this test case, all algorithms have been independently executed 40 times and the best, average (Avg), and worst SSE values, in addition to their standard deviation (SD) to show the stability for each algorithm have been calculated and presented in Table 1, which shows that HSOA, HHOA, and HGBO could be competitive with each other and superior to the other compared optimizers in terms of the best SSE; however, for the Avg SSE value, the best MAE and MAPE values, both HSOA and HGBO could come true the same outcomes that are the best in comparison to those obtained by the others algorithms.…”

Section: B Test Case 1: Bcs 500w Stackmentioning

confidence: 99%

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Improved Metaheuristic Algorithms for Optimal Parameters Selection of Proton Exchange Membrane Fuel Cells: A Comparative Study

et al. 2023

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As a new attempt to design a precise mathematical model for the proton exchange membrane fuel cell (PEMFC), in this paper, three recently-proposed well-established optimizers: horse herding optimization algorithm (HOA), seagull optimization algorithm (SOA) and gradient-based optimizer (GBO) integrated with two newly-proposed effective strategies, namely self-adaptive strategy, and ranking-based updating strategy, have been extensively investigated to accurately estimate the unknown parameters of this model for accomplishing a better output voltage of the simulated PEMFC stacks. Those hybridized algorithms were briefly named HHOA, HSOA, and HGBO. To assess the performance of those proposed algorithms, six common PEMFC stacks were used and their outcomes were extensively compared with the standard algorithms and some of the state-of-the-arts under various performance metrics and the Wilcoxon rank-sum test. The experimental findings show the effectiveness of both HGBO and HSOA in terms of convergence speed and final accuracy; However, HSOA could be more stable. The source code of this study is publicly available at https://drive.matlab.com/sharing/d9263036-9f80-4a40-bad9-ad476ed19c69.

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Section: B Horse Herd Optimization Algorithmmentioning

confidence: 99%

Section: B Test Case 1: Bcs 500w Stackmentioning

confidence: 99%

Improved Metaheuristic Algorithms for Optimal Parameters Selection of Proton Exchange Membrane Fuel Cells: A Comparative Study

et al. 2023

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“…In addition to that, artificially ecosystem optimization 27 , tree-seed algorithm (TSA) and neural network algorithm 28 have been applied for the same issue. Also, the researchers utilized the similar context of tree-growth algorithm 29 , flower pollination method 30 , political optimization algorithm, marine predator technique 31 and slime mould optimization algorithm 32 for parameter identification of PEMFCs. In 33 , a combination between teaching learning based optimizer and DE approach has been developed while a modified salp swarm optimizer has been presented to identify the optimal PEMFCs stack parameters in 34 .…”

Section: Introductionmentioning

confidence: 99%

Fuel-cell parameter estimation based on improved gorilla troops technique

Shaheen

El‐Sehiemy

El‐Fergany

et al. 2023

Sci Rep

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The parameter extraction of the proton exchange membrane fuel cells (PEMFCs) is an active study area over the past few years to achieve accurate current/voltage (I/V) curves. This work proposes an advanced version of an improved gorilla troops technique (IGTT) to precisely estimate the PEMFC’s model parameters. The GTT's dual implementation of the migration approach enables boosting the exploitation phase and preventing becoming trapped in the local minima. Besides, a Tangent Flight Strategy (TFS) is incorporated with the exploitation stage for efficiently searching the search space. Using two common PEMFCs stacks of BCS 500W, and Modular SR-12, the developed IGTT is effectively applied. Furthermore, the two models are evaluated under varied partial temperature and pressure. In addition to this, different new recently inspired optimizers are employed for comparative validations namely supply demand optimization (SDO), flying foxes optimizer (FFO) and red fox optimizer (RFO). Also, a comparative assessment of the developed IGTT and the original GTT are tested to ten unconstrained benchmark functions following to the Congress on Evolutionary Computation (CEC) 2017. The proposed IGTT outperforms the standard GTT, grey wolf algorithm (GWA) and Particle swarm optimizer (PSO) in 92.5%, 87.5% and 92.5% of the statistical indices. Moreover, the viability of the IGTT is proved in comparison to various previously published frameworks-based parameter's identification of PEMFCs stacks. The obtained sum of squared errors (SSE) and the standard deviations (STD) are among the difficult approaches in this context and are quite competitive. For the PEMFCs stacks being studied, the developed IGTT achieves exceedingly small SSE values of 0.0117 and 0.000142 for BCS 500 and SR-12, respectively. Added to that, the IGTT gives superior performance compared to GTT, SDO, FFO and RFO obtaining the smallest SSE objective with the least STD ever.

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“…The great advantages of using metaheuristic algorithms are the simplicity, ease of implementation, and robustness [15]. The broad applications of metaheuristic algorithms in solving the parameter identification problems of PEMFC models, such as the genetic algorithm (GA) [16], particle swarm optimization (PSO) [17], firefly optimization (FFO) [18], grey wolf optimization (GWO) [19], simulated annealing (SA) [20], harmony search (HS) [21], artificial bee swarm (ABS) optimization [22], flower pollination algorithm (FPA) [23], artificial bee colony (ABC) algorithm [24], big bang-big crunch (BBBC) algorithm [25], salp swarm optimizer (SSA) [26], shark smell optimizer (SSO) [27], multiverse optimizer (MVO) [28], teaching learning-based algorithm (TLBO) [29], backtracking search algorithm (BSA) [30], differential evolution algorithm (DEA) [31], biogeographybased optimization (BBO) [32], imperialist competitive algorithm (ICA) [33], grasshopper optimization algorithm (GOA) [34], bird mating optimizer (BMO) [35], flower pollination algorithm (FPA) [23], whale optimization algorithm (WOA) [36], satin bowerbird optimizer (SBO) [37], seagull optimization algorithm (SOA) [38], shuffled frog-leaping algorithm (SFLA) [33], vortex search algorithm (VSA) [39], bat algorithm (BA) [40], owl search algorithm (OSA) [18], tree growth algorithm (TGA) [41], Harris hawks optimization (HHO) [42], atom search optimizer (ASO) [43], dragonfly algorithm (DA) [44], ant lion optimizer (ALO) [44], cuckoo search algorithm (CS) [45], artificial ...…”

Section: Introductionmentioning

confidence: 99%

Proton Exchange Membrane Fuel Cell Parameter Extraction Using a Supply–Demand-Based Optimization Algorithm

et al. 2021

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For proton exchange membrane fuel cells (PEMFCs), the parameter extraction issue is among the most widely studied problems in the field of energy storage systems, since the precise identification of such parameters plays an important role in increasing the PEMFC performance and life span. The optimization process is intended to adjust the performance of PEMFCs by appraising the optimal parameters that produce a good estimation of the current–voltage (I–V) curve. In order to build an accurate equivalent circuit model for PEMFCs, a reliable and effective parameter extraction algorithm, termed a supply–demand-based optimization (SDO) algorithm, is proposed in this paper. Nine parameters (ξ1, ξ2, ξ3, ξ4, Rc, β, λ, l, and Jmax) are evaluated, to minimize the sum squared deviation (SSE) between the experimental and simulated I–V curves. To validate the feasibility and effectiveness of the SDO algorithm, four sets of experimental data with diverse characteristics and two well-known PEMFC stacks (BSC500W and 500W Horizon) are employed. Comparison of the simulated and experimental results clearly demonstrates the superiority/competitiveness of the SDO algorithm over five well-established parameter extraction algorithms, i.e., the whale optimization algorithm (WOA), grey wolf optimization (GWO), Harris hawks optimization (HHO), and genetic algorithm (GA). Several evaluation criteria, including best SSE, worst SSE, mean SSE, and standard deviation, show that the SDO algorithm has merits in terms of PEMFC modeling.

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Tree Growth Algorithm for Parameter Identification of Proton Exchange Membrane Fuel Cell Models

Cited by 10 publications

References 33 publications

Improved Metaheuristic Algorithms for Optimal Parameters Selection of Proton Exchange Membrane Fuel Cells: A Comparative Study

Improved Metaheuristic Algorithms for Optimal Parameters Selection of Proton Exchange Membrane Fuel Cells: A Comparative Study

Fuel-cell parameter estimation based on improved gorilla troops technique

Proton Exchange Membrane Fuel Cell Parameter Extraction Using a Supply–Demand-Based Optimization Algorithm

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