Muhammad Shoaib scite author profile

The present review provides information relevant to issues and challenges in MEMS testing techniques that are implemented to analyze the microelectromechanical systems (MEMS) behavior for specific application and operating conditions. MEMS devices are more complex and extremely diverse due to the immersion of multidomains. Their failure modes are distinctive under different circumstances. Therefore, testing of these systems at device level as well as at mass production level, that is, parallel testing, is becoming very challenging as compared to the IC test, because MEMS respond to electrical, physical, chemical, and optical stimuli. Currently, test systems developed for MEMS devices have to be customized due to their nondeterministic behavior and complexity. The accurate measurement of test systems for MEMS is difficult to quantify in the production phase. The complexity of the device to be tested required maturity in the test technique which increases the cost of test development; this practice is directly imposed on the device cost. This factor causes a delay in time-to-market.

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Temperature dependent Young's modulus and quality factor of CMOS-MEMS resonator: Modelling and experimental approach

Jan

Ahmad

Hamid

et al. 2016

Microelectronics Reliability

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Reliability and Fatigue Analysis in Cantilever-Based MEMS Devices Operating in Harsh Environments

Jan

Hamid

Khir

et al. 2014

Journal of Quality and Reliability Engineering

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The microelectromechanical system (MEMS) is one of the most diversified fields of microelectronics; it is rated to be the most promising technology of modern engineering. MEMS can sense, actuate, and integrate mechanical and electromechanical components of micro-and nano sizes on a single silicon substrate using microfabrication techniques. MEMS industry is at the verge of transforming the semiconductor world into MEMS universe, apart from other hindrances; the reliability of these devices is the focal point of recent research. Commercialization is highly dependent on the reliability of these devices. MEMS requires a high level of reliability. Several technological factors, operating conditions, and environmental effects influencing the performances of MEMS devices must be completely understood. This study reviews some of the major reliability issues and failure mechanisms. Specifically, the fatigue in MEMS is a major material reliability issue resulting in structural damage, crack growth, and lifetime measurements of MEMS devices in the light of statistical distribution and fatigue implementation of Paris' law for fatigue crack accumulation under the influence of undesirable operating and environmental conditions.

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Frequency and displacement analysis of electrostatic cantilever-based MEMS sensor

Shoaib

Hisham

Basheer

et al. 2016

Analog Integr Circ Sig Process

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Experimental investigation of temperature and relative humidity effects on resonance frequency and quality factor of CMOS-MEMS paddle resonator

Jan

Ahmad

Hamid

et al. 2016

Microelectronics Reliability

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Muhammad Shoaib

A Review on Key Issues and Challenges in Devices Level MEMS Testing

Temperature dependent Young's modulus and quality factor of CMOS-MEMS resonator: Modelling and experimental approach

Reliability and Fatigue Analysis in Cantilever-Based MEMS Devices Operating in Harsh Environments

Frequency and displacement analysis of electrostatic cantilever-based MEMS sensor

Experimental investigation of temperature and relative humidity effects on resonance frequency and quality factor of CMOS-MEMS paddle resonator

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