PROBABILISTIC DYNAMIC ANALYSIS OF A SINGLE-MASS VIBRATION ISOLATION SYSTEM
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Abstract
The article considers the problem of probabilistic calculation of a single-mass oscillatory system intended for solving problems of force or kinematic vibration isolation. The solution of three problems for the mode of free and forced oscillations is considered depending on the element, the probabilistic characteristics of which are determined. The first problem includes the case of a known probabilistic distribution of the load and constant system parameters. The second problem includes the case of a known probabilistic distribution of the system parameters under a constant external influence. The third problem will combine known probabilistic characteristics for both the external influence and the system parameters. The purpose of solving these problems is to obtain the distribution of the system response under the specified types of influences, as well as to test the methodology for their numerical solution using the Monte Carlo method.
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