Abstract
This paper aims to develop a surrogate model for dynamics analysis of a magnetorheological damper (MRD) in the semi-active seat suspension system. An improved fruit fly optimization algorithm (IFOA) which enhances the global search capability of the original FOA is proposed to optimize the structure of a back propagation neural network (BPNN) in establishing the surrogate model. An MRD platform was fabricated to generate experimental data to feed the IFOA-BPNN model. Intrinsic patterns about the MRD dynamics behind the datasets have been discovered to establish a reliable MRD surrogate model. The outputs of the surrogate model demonstrate satisfactory dynamics characteristics in consistence with the experimental results. Moreover, the performance of the IFOA-BPNN based surrogate model was compared with that produced by the BPNN based, genetic algorithm-BPNN based, and FOA-BPNN based surrogate models. The comparison result shows better tracking capacity of the proposed method on the hysteresis behaviors of the MRD. As a result, the newly developed surrogate model can be used as the basis for advanced controller design of the semi-active seat suspension system.
Highlights
This paper aims to develop a surrogate model for dynamics analysis of a magnetorheological damper (MRD) in the semi-active seat suspension system
The parameters of artificial neural networks such as a back propagation neural network (BPNN) need to be optimized to improve the precision for modeling the hysteretic behavior of MRDs
fly optimization algorithm (FOA) is able to optimize the neural network parameters to establish the MRD surrogate model while very limited work has been done for this purpose
Summary
An accurate dynamic model of the MRD is essential to achieve the desirable vibration control for the suspension system. Recent researches show the capability of artificial intelligence (AI)-based techniques in modeling the MRD dynamics by performing machine learning and data mining [6, 7]. In [8], a new algorithm named establishing neuro-fuzzy system was proposed to identify the dynamic characteristics of smart dampers, and the effectiveness of the proposed algorithm was verified. Prior professional information and exact MRD parameters are not required in establishing the AI-based surrogate model. An improved fruit fly optimization algorithm (IFOA) is developed, and the IFOA optimized BPNN is proposed to improve the modeling capability for the MRD.
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