Title :
Modeling reliablity issues in RF MEMS switches
Author :
Schrag, Gabriele ; Kunzig, T. ; Wachutka, G.
Author_Institution :
Inst. for Phys. of Electrotechnol., Munich Univ. of Technol., Munich, Germany
Abstract :
We present a problem-adapted, physics-based 3D finite element (FE) model of an RF-MEMS switch, which is used for investigating the failure scenario of such devices caused by electrically induced stiction, one of the major reliability concerns, which limits their broad commercial application as, e.g., in mobile phones. In particular, a novel embedded active thermal recovery capability is analyzed by coupled electro-thermo-mechanical simulations in order to identify those parameters, which are most significant for the recovery efficiency and, hence, provide the best prospects for optimizing the switch with a view to a reliable design. The derived model was validated and calibrated by optical white-light interferometry and laser Doppler vibrometry to make it reliable and accurate, particularly with regard to predictive simulation.
Keywords :
finite element analysis; microswitches; mobile handsets; semiconductor device reliability; vibration measurement; RF MEMS switches; coupled electro-thermo-mechanical simulations; electrically induced stiction; embedded active thermal recovery capability; failure scenario; laser Doppler vibrometry; mobile phones; modeling reliability; optical white-light interferometry; physics-based 3D finite element model; Force; Heating; Microswitches; Optical switches; Radio frequency; Reliability; 3D FE analysis; RF MEMS switch; problem-adapted modeling; reliability; sticking;
Conference_Titel :
Simulation of Semiconductor Processes and Devices (SISPAD), 2013 International Conference on
Conference_Location :
Glasgow
Print_ISBN :
978-1-4673-5733-3
DOI :
10.1109/SISPAD.2013.6650667
