In experimental dynamic substructuring two main problems can be defined: addition of substructures (coupling) and subtraction of substructures (decoupling). Decoupling can be important in built-up structures where some components (critical subsystems or joints) cannot be removed or accessed easily. Whilst addition of substructures often leads to satisfactory results even in relatively complex cases, subtraction of substructures is a source of problems even in apparently trivial applications. In the literature, critical issues of decoupling (such as ill-conditioning around a discrete number of frequencies) have been highlighted and verified by using simulated data corrupted by random noise. In this paper, experimental data acquired on a benchmark system are used to check previously obtained results both in coupling and decoupling, and to look for additional issues (systematic errors, inconsistencies, etc.) that can not be observed from simulated data.
Smoothing experimental data in dynamic substructuring of built up systems / Culla, Antonio; W., D'Ambrogio; Fregolent, Annalisa; Schiavone, Alessandro. - STAMPA. - 2:(2011), pp. 89-109. (Intervento presentato al convegno 29th IMAC, a Conference on Structural Dynamics, 2011 tenutosi a Jacksonville, FL nel 31 January 2011 through 3 February 2011) [10.1007/978-1-4419-9305-2_7].
Smoothing experimental data in dynamic substructuring of built up systems
CULLA, Antonio;FREGOLENT, Annalisa;SCHIAVONE, ALESSANDRO
2011
Abstract
In experimental dynamic substructuring two main problems can be defined: addition of substructures (coupling) and subtraction of substructures (decoupling). Decoupling can be important in built-up structures where some components (critical subsystems or joints) cannot be removed or accessed easily. Whilst addition of substructures often leads to satisfactory results even in relatively complex cases, subtraction of substructures is a source of problems even in apparently trivial applications. In the literature, critical issues of decoupling (such as ill-conditioning around a discrete number of frequencies) have been highlighted and verified by using simulated data corrupted by random noise. In this paper, experimental data acquired on a benchmark system are used to check previously obtained results both in coupling and decoupling, and to look for additional issues (systematic errors, inconsistencies, etc.) that can not be observed from simulated data.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
