Title :
A highly simple failure detection method for electrostatic microactuators: application to automatic testing and accelerated lifetime estimation
Author :
Caillard, Benjamin ; Mita, Yoshio ; Fukuta, Yamato ; Shibata, Tadashi ; Fujita, Hiroyuki
Author_Institution :
LIMMS, Univ. of Tokyo, Japan
Abstract :
Reliability and testability are two important factors for the development of batch fabrication of microelectromechanical systems (MEMS) or mixed MEMS/IC applications. In that frame, an easy-to-implement electrical method of detection of failures is presented in this paper, valid for every kind of electrostatic microactuators showing pull-in behavior, with great expectation value in the case of arrayed MEMS. The method relies on the detection of a pull-in current peak at very low frequency. An experimental setup is described and results are shown obtained with prototypes of electrostatic microactuators with parallel capacitances created by deep reactive ion etching on silicon-on-insulator wafers. This method is really suitable for automation and application to on-line testing during mass production and reliability studies. The functional schematic of a test circuitry is proposed for implementation in an industrial tester or for built-in self-test purposes. Then, in order to illustrate the benefits of this method for reliability studies, it is used in conjunction with high voltage testing for accelerated lifetime measurements. A time gain factor of 20 is achieved with above-mentioned test structures.
Keywords :
built-in self test; circuit reliability; electrostatic actuators; failure analysis; micromechanical devices; silicon-on-insulator; sputter etching; accelerated failure analysis; accelerated lifetime estimation; arrayed microelectromechanical systems; automatic testing; built-in self-test purpose; deep reactive ion etching; electrostatic actuator; electrostatic microactuator; electrostatic microactuators; highly simple failure detection method; reliability; silicon-on-insulator wafer; test circuitry; testability; Automatic testing; Circuit testing; Electrostatics; Fabrication; Integrated circuit testing; Life estimation; Lifetime estimation; Microactuators; Micromechanical devices; System testing; Accelerated failure analysis; electrostatic actuator; microelectromechanical systems (MEMS);
Journal_Title :
Semiconductor Manufacturing, IEEE Transactions on
DOI :
10.1109/TSM.2005.863234
