Silicon micro-machined piezoresistive based pressure transducers are often used to make high frequency dynamic pressure measurements. The spectral or frequency response of these microelectromechanical systems (MEMS) is a function of the natural resonance of the sensor structure, sensor size, sensor packaging, signal conditioning and transducer mounting in the desired measurement location. The advancement of MEMS micro-fabrication, which has reduced sensor size dramatically, and the high elastic modulus of silicon have allowed the natural resonance of these devices to range from 100kHz to several MHz [1]. As a result, packaging and mounting at the point of measurement are the major factors that determine the flat (0dB) frequency response envelope of the transducer, which is typically quantified by a transfer function. The transfer function quantifies the difference both in magnitude and phase between an input signal and a measured signal in the frequency domain. The dynamic response of pressure transducers has historically been estimated via a unit step input in pressure created through a shock tube test that excites the high natural resonance of the chip. Unfortunately, these tests are less effective at accurately quantifying the frequency response of the transducer in the domain of greatest interest (DC-20kHz), specifically the bandwidth over which the response is flat (0dB). In this work, we present a test methodology using a speaker-driven dynamic pressure calibration setup for experimentally determining the transfer function of a pressure transducer from 1–50kHz. The test setup is validated using capacitive-based microphones with claimed flat spectral characteristics well beyond 50kHz. Using this test setup, we present experimental spectral response results for low-pressure miniature MEMS piezoresistive pressure transducers over the frequency range of 1–50kHz and qualitatively compare these results to traditional shock tube tests. The transducers characterized have been manufactured with several different standard sizes and front-end configurations.
Skip Nav Destination
ASME Turbo Expo 2014: Turbine Technical Conference and Exposition
June 16–20, 2014
Düsseldorf, Germany
Conference Sponsors:
- International Gas Turbine Institute
ISBN:
978-0-7918-4575-2
PROCEEDINGS PAPER
An Experimental Frequency Response Characterization of MEMS Piezoresistive Pressure Transducers
Adam M. Hurst,
Adam M. Hurst
Kulite® Semiconductor Products Inc., Leonia, NJ
Search for other works by this author on:
Timothy R. Olsen,
Timothy R. Olsen
Kulite® Semiconductor Products Inc., Leonia, NJ
Search for other works by this author on:
Scott Goodman,
Scott Goodman
Kulite® Semiconductor Products Inc., Leonia, NJ
Search for other works by this author on:
Joe VanDeWeert,
Joe VanDeWeert
Kulite® Semiconductor Products Inc., Leonia, NJ
Search for other works by this author on:
Tonghuo Shang
Tonghuo Shang
Kulite® Semiconductor Products Inc., Leonia, NJ
Search for other works by this author on:
Adam M. Hurst
Kulite® Semiconductor Products Inc., Leonia, NJ
Timothy R. Olsen
Kulite® Semiconductor Products Inc., Leonia, NJ
Scott Goodman
Kulite® Semiconductor Products Inc., Leonia, NJ
Joe VanDeWeert
Kulite® Semiconductor Products Inc., Leonia, NJ
Tonghuo Shang
Kulite® Semiconductor Products Inc., Leonia, NJ
Paper No:
GT2014-27159, V006T06A031; 15 pages
Published Online:
September 18, 2014
Citation
Hurst, AM, Olsen, TR, Goodman, S, VanDeWeert, J, & Shang, T. "An Experimental Frequency Response Characterization of MEMS Piezoresistive Pressure Transducers." Proceedings of the ASME Turbo Expo 2014: Turbine Technical Conference and Exposition. Volume 6: Ceramics; Controls, Diagnostics and Instrumentation; Education; Manufacturing Materials and Metallurgy. Düsseldorf, Germany. June 16–20, 2014. V006T06A031. ASME. https://doi.org/10.1115/GT2014-27159
Download citation file:
170
Views
Related Proceedings Papers
Related Articles
Device Process Integration: A New Device Fabrication Approach
J. Med. Devices (June,2010)
Characterization of the Dynamical Response of a Micromachined G-Sensor to Mechanical Shock Loading
J. Dyn. Sys., Meas., Control (July,2008)
Passive Wireless MEMS Microphones for Biomedical Applications
J Biomech Eng (November,2005)
Related Chapters
Experimental Investigation of Ventilated Supercavitation Under Unsteady Conditions
Proceedings of the 10th International Symposium on Cavitation (CAV2018)
Micromachined 1-3 Composite Single Element Transducers
High Frequency Piezo-Composite Micromachined Ultrasound Transducer Array Technology for Biomedical Imaging
Micromachined High Frequency Transducer Arrays
High Frequency Piezo-Composite Micromachined Ultrasound Transducer Array Technology for Biomedical Imaging