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Prof. Comparing H2 and H∞ Algorithms for Optimum Design of Tuned Mass Dampers under Near-Fault and Far-Fault Earthquake Motions

A. Kaveh, Mazyar Fahimi Fazam, Rasool Maroofiazar

2020Periodica Polytechnica Civil Engineering31 citationsDOIOpen Access PDF

Abstract

In this study, the robust optimum design of Tuned Mass Damper (TMD) is established. The H2 and H∞ norm of roof displacement transfer function are implemented and compared as the objective functions under Near-Fault (NF) and Far-Fault (FF) earthquake motions. Additionally, the consequences of different characteristics of NF ground motions such as forward-directivity and fling-step are investigated on the behavior of a benchmark 10-story controlled structure. The Colliding Bodies Optimization (CBO) is employed as an optimization technique to calculate the optimum parameters of the TMDs. The resulting statistical assessment shows that the H∞ objective function is rather superior to H2 objective function for optimum design of TMDs under NF and FF earthquake excitations. Finally, the robustness of the designed TMDs is evaluated under a large set of natural ground motions.

Topics & Concepts

Tuned mass damperStructural engineeringDirectivityRobustness (evolution)DamperEngineeringComputer scienceAlgorithmTelecommunicationsBiochemistryGeneChemistryAntenna (radio)Vibration Control and Rheological FluidsHydraulic and Pneumatic SystemsFluid Dynamics and Vibration Analysis
Prof. Comparing H2 and H∞ Algorithms for Optimum Design of Tuned Mass Dampers under Near-Fault and Far-Fault Earthquake Motions | Litcius