Synergy of (H2, H∞) norms for nonlinear optimal PEMFC dynamic MIMO model reduction using a novel EAO approach

In this paper, a new nature-inspired Artificial Ecosystem Optimization (AEO) methodology is presented for reducing the complexity of nonlinear PEMFC SR-12 500 W system. From the point view of this system, the hydrogen and oxygen pressures P H 2 = 60 atm , P O 2 = 30 atm as two inputs, the cell volta...

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Bibliographic Details
Published in:International journal of system assurance engineering and management 2022-06, Vol.13 (3), p.1396-1409
Main Authors: Touati, Zohra, Saadi, Slami, Kious, Mecheri, Touati, Khaled Omer Mokhtar
Format: Article
Language:English
Subjects:
Algorithms
Energy flow
Engineering
Engineering Economics
H infinity
Logistics
Marketing
Model reduction
Norms
Optimization
Organization
Original Article
Quality Control
Reduced order models
Reliability
Safety and Risk
State space models
Citations: Items that this one cites
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Summary:In this paper, a new nature-inspired Artificial Ecosystem Optimization (AEO) methodology is presented for reducing the complexity of nonlinear PEMFC SR-12 500 W system. From the point view of this system, the hydrogen and oxygen pressures P H 2 = 60 atm , P O 2 = 30 atm as two inputs, the cell voltage and current as two outputs.By implementation of identification technique, the state space model of PEMFC stack is generated using nlarx modelling procedures where the obtained model is reduced their order by AEO method. The AEO mimics the energy flow behaviour between living organisms in a natural ecosystem, including production, consumption, and decomposition.This algorithm minimize the synergy ( H 2 , H ∞ ) norm of error between full PEMFC model and reduced order model. The obtained results are compared with the other optimization algorithms such as MRFO,SSA,ALO and GWO, and they are confirmed that the approximate model obtained by proposed algorithm has faster convergence and better approximation performance in synergy ( H 2 , H ∞ ) norm than those obtained by comparative algorithms in addition, it is proven to be accurate and reliable to investigate the PEMFC optimum global reduced order model which preserved the main behaviour of original PEMFC SR-12 500 W model.
ISSN:0975-6809
0976-4348
DOI:10.1007/s13198-021-01485-1