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1. Bosch GmBH (1991), CAN Specification, Version 2.0, Stuttgart, www.bosch-semiconductors.de.

2. Farjoud A., Craft M., Burke W., Ahmadian M. (2011), Experimental investigation of MR squeeze mounts, Journal of Intelligent Material Systems and Structures, 22, 1645-1652.

3. Jolly M. R., Carlson J. D. (1996), Controllable Squeeze-film Damping using MR fluid, Proc. of Actuator, Bremen, Germany, 333−336.

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The work has been accomplished under the research project

摘要：挤压式磁（MR）隔振的自主控制系统是基于超低功耗单片机MSP430F5529。控制系统和专用实时系统的设计结构被简要的介绍和总结了实验室试验数据。

论文网关键词：流变减振器，控制系统，控制器

1.介绍 

    过去十年见证了挤压式磁流变减振器（VI-MRS）的重大进步(Farjoud et al., 2011; Kim et al., 2008; Zhang et al., 2011)。以前的大部分的研究已主要集中在理论研究，例如乔利和卡尔森（1996）和斯坦韦等（2000）这是值得一提的是，这些类型的VI-MRS的某些解决方案已获得专利(Kim, 2012; Sapiński, 2013).。

    所研究的自动控制系统（ACS）被设计为用于原型挤压模式MR隔振（VI-MR）的控制。VI-MR意欲用作设计成在半主动发动机汽车装配系统中的致动元件，为了降低发动机的振动由于波动惯性力（由曲柄系统的不平衡元件所引起），为了变动发动机传递到驱动系统部件的驱动转矩和改变一些随机力的作用(Kamiński and Pokorski, 1983; Snamina and Sapiński, 2014)。 挤压式磁流隔振系统英文文献和中文翻译(4):http://www.youerw.com/fanyi/lunwen_42995.html