Method for modeling electrorheological dampers using its dynamic characteristics

Carlos A. Vivas-Lopez; Diana Hernández-Alcantara; Ruben Morales-Menendez; Ricardo A. Ramírez-Mendoza; Horacio Ahuett-Garza

doi:10.1155/2015/905731

Method for modeling electrorheological dampers using its dynamic characteristics

Carlos A. Vivas-Lopez, Diana Hernández-Alcantara, Ruben Morales-Menendez, Ricardo A. Ramírez-Mendoza, Horacio Ahuett-Garza

Producción científica › revisión exhaustiva

8 Citas (Scopus)

Resumen

A method for modeling an Electrorheological (ER) damper is proposed. The modeling method comprehends two simple steps: characterization and model customization. These steps are based on the experimental data of the damper behavior. Experiments were designed to explore the nonlinear behavior of the damper at different frequencies and actuation signals (i.e., automotive domain). The resulting model has low computational complexity. The method was experimentally validated with a commercial damper. The error-to-signal Ratio (ESR) performance index was used to evaluate the model accuracy. The results were quantitatively compared with two well-known ER damper models: the Choi parametric model and the Eyring-plastic model. The new proposed model has a 44% better ESR index than the Choi parametric model and 28% for the Eyring-plastic model. A qualitative comparison based on density plots highlights the advantages of this proposal.

Idioma original	English
Número de artículo	905731
Publicación	Mathematical Problems in Engineering
Volumen	2015
DOI	https://doi.org/10.1155/2015/905731
Estado	Published - 1 ene 2015
Publicado de forma externa	Sí

All Science Journal Classification (ASJC) codes

Matemáticas (todo)
Ingeniería (todo)

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10.1155/2015/905731

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abstract = "A method for modeling an Electrorheological (ER) damper is proposed. The modeling method comprehends two simple steps: characterization and model customization. These steps are based on the experimental data of the damper behavior. Experiments were designed to explore the nonlinear behavior of the damper at different frequencies and actuation signals (i.e., automotive domain). The resulting model has low computational complexity. The method was experimentally validated with a commercial damper. The error-to-signal Ratio (ESR) performance index was used to evaluate the model accuracy. The results were quantitatively compared with two well-known ER damper models: the Choi parametric model and the Eyring-plastic model. The new proposed model has a 44% better ESR index than the Choi parametric model and 28% for the Eyring-plastic model. A qualitative comparison based on density plots highlights the advantages of this proposal.",

author = "Vivas-Lopez, {Carlos A.} and Diana Hern{\'a}ndez-Alcantara and Ruben Morales-Menendez and Ram{\'i}rez-Mendoza, {Ricardo A.} and Horacio Ahuett-Garza",

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AU - Vivas-Lopez, Carlos A.

AU - Hernández-Alcantara, Diana

AU - Morales-Menendez, Ruben

AU - Ramírez-Mendoza, Ricardo A.

AU - Ahuett-Garza, Horacio

PY - 2015/1/1

Y1 - 2015/1/1

N2 - A method for modeling an Electrorheological (ER) damper is proposed. The modeling method comprehends two simple steps: characterization and model customization. These steps are based on the experimental data of the damper behavior. Experiments were designed to explore the nonlinear behavior of the damper at different frequencies and actuation signals (i.e., automotive domain). The resulting model has low computational complexity. The method was experimentally validated with a commercial damper. The error-to-signal Ratio (ESR) performance index was used to evaluate the model accuracy. The results were quantitatively compared with two well-known ER damper models: the Choi parametric model and the Eyring-plastic model. The new proposed model has a 44% better ESR index than the Choi parametric model and 28% for the Eyring-plastic model. A qualitative comparison based on density plots highlights the advantages of this proposal.

AB - A method for modeling an Electrorheological (ER) damper is proposed. The modeling method comprehends two simple steps: characterization and model customization. These steps are based on the experimental data of the damper behavior. Experiments were designed to explore the nonlinear behavior of the damper at different frequencies and actuation signals (i.e., automotive domain). The resulting model has low computational complexity. The method was experimentally validated with a commercial damper. The error-to-signal Ratio (ESR) performance index was used to evaluate the model accuracy. The results were quantitatively compared with two well-known ER damper models: the Choi parametric model and the Eyring-plastic model. The new proposed model has a 44% better ESR index than the Choi parametric model and 28% for the Eyring-plastic model. A qualitative comparison based on density plots highlights the advantages of this proposal.

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Method for modeling electrorheological dampers using its dynamic characteristics

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