Development of an Experimental Model for a Magnetorheological Damper Using Artificial Neural Networks (Levenberg-Marquardt Algorithm)

Q2 Physics and Astronomy
Ayush Raizada, P. Singru, V. Krishnakumar, Varun Raj
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引用次数: 10

Abstract

This paper is based on the experimental study for design and control of vibrations in automotive vehicles. The objective of this paper is to develop a model for the highly nonlinear magnetorheological (MR) damper to maximize passenger comfort in an automotive vehicle. The behavior of the MR damper is studied under different loading conditions and current values in the system. The input and output parameters of the system are used as a training data to develop a suitable model using Artificial Neural Networks. To generate the training data, a test rig similar to a quarter car model was fabricated to load the MR damper with a mechanical shaker to excite it externally. With the help of the test rig the input and output parameter data points are acquired by measuring the acceleration and force of the system at different points with the help of an impedance head and accelerometers. The model is validated by measuring the error for the testing and validation data points. The output of the model is the optimum current that is supplied to the MR damper, using a controller, to increase the passenger comfort by minimizing the amplitude of vibrations transmitted to the passenger. Besides using this model for cars, bikes, and other automotive vehicles it can also be modified by retraining the algorithm and used for civil structures to make them earthquake resistant.
利用人工神经网络(Levenberg-Marquardt算法)建立磁流变阻尼器实验模型
本文是基于汽车振动设计与控制的实验研究。本文的目的是建立一个高度非线性磁流变阻尼器的模型,以最大限度地提高汽车乘客的舒适度。研究了磁流变阻尼器在不同加载条件和系统电流值下的性能。将系统的输入输出参数作为训练数据,利用人工神经网络建立合适的模型。为了生成训练数据,制作了一个类似于四分之一汽车模型的试验台,用机械激振器加载磁流变阻尼器,以从外部激励它。在试验台的帮助下,通过阻抗头和加速度计测量系统在不同点的加速度和力,获得输入和输出参数数据点。通过测量测试和验证数据点的误差来验证模型。该模型的输出是提供给磁流变阻尼器的最佳电流,使用控制器,通过最小化传递给乘客的振动幅度来增加乘客的舒适度。除了将该模型用于汽车、自行车和其他汽车之外,还可以通过重新训练算法对其进行修改,并将其用于土木结构,使其具有抗震能力。
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来源期刊
自引率
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期刊介绍: The aim of Advances in Acoustics and Vibration is to act as a platform for dissemination of innovative and original research and development work in the area of acoustics and vibration. The target audience of the journal comprises both researchers and practitioners. Articles with innovative works of theoretical and/or experimental nature with research and/or application focus can be considered for publication in the journal. Articles submitted for publication in Advances in Acoustics and Vibration must neither have been published previously nor be under consideration elsewhere. Subject areas include (but are not limited to): Active, semi-active, passive and combined active-passive noise and vibration control Acoustic signal processing Aero-acoustics and aviation noise Architectural acoustics Audio acoustics, mechanisms of human hearing, musical acoustics Community and environmental acoustics and vibration Computational acoustics, numerical techniques Condition monitoring, health diagnostics, vibration testing, non-destructive testing Human response to sound and vibration, Occupational noise exposure and control Industrial, machinery, transportation noise and vibration Low, mid, and high frequency noise and vibration Materials for noise and vibration control Measurement and actuation techniques, sensors, actuators Modal analysis, statistical energy analysis, wavelet analysis, inverse methods Non-linear acoustics and vibration Sound and vibration sources, source localisation, sound propagation Underwater and ship acoustics Vibro-acoustics and shock.
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