On the exploitation of mode localization in surface acoustic wave MEMS for sensing applications
Mode localization refers to the spatial trapping of energy in a coupled oscillatory system that occurs when a disorder is introduced into a previously ordered system. This thesis explores the exploitation of this phenomenon in surface acoustic wave (SAW) devices for sensing applications. The sensing...
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ndltd-bl.uk-oai-ethos.bl.uk-7283452018-06-12T03:27:28ZOn the exploitation of mode localization in surface acoustic wave MEMS for sensing applicationsHanley, Thomas Harry2017Mode localization refers to the spatial trapping of energy in a coupled oscillatory system that occurs when a disorder is introduced into a previously ordered system. This thesis explores the exploitation of this phenomenon in surface acoustic wave (SAW) devices for sensing applications. The sensing application of primary focus within this work is a magnetic field sensor, wherein the strength of mode localization changes in proportion to an external magnetic field. In addition, application as a bio-mass sensor is suggested and briefly discussed. Utilisation of mode localization as a sense mechanism involves the use of changes in the normalised mode shape of a weakly-coupled two degree-of-freedom system as the sensor output. This is in contrast to the use of shifts in frequency, phase or amplitude as is commonplace in resonant micro-electromechanical systems (MEMS) sensor technology. The theory and principles of device operation are introduced utilising a discretised model. In particular, the use of a periodic array to couple the sensors’ two degrees-of-freedom is investigated. A generalised geometry of the SAW device is introduced, consisting of a pair of acoustically-coupled cavities. An analytical solution is found for the displacement fields within the cavities. The solution is achieved by coupling the internal cavity solutions using a ray tracing method. The results of the analytical solution are compared to a numerical solution found using commercial finite element analysis (FEA) software; good agreement is observed. The model is subsequently used to analyse and discuss device performance in the presence of noise; expressions are presented describing device operation and performance, and a case study is outlined evaluating use as a MEMS magnetometer. Finally, the design, manufacture and testing of a prototype design is discussed.University of Newcastle upon Tynehttp://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.728345http://hdl.handle.net/10443/3711Electronic Thesis or Dissertation |
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Mode localization refers to the spatial trapping of energy in a coupled oscillatory system that occurs when a disorder is introduced into a previously ordered system. This thesis explores the exploitation of this phenomenon in surface acoustic wave (SAW) devices for sensing applications. The sensing application of primary focus within this work is a magnetic field sensor, wherein the strength of mode localization changes in proportion to an external magnetic field. In addition, application as a bio-mass sensor is suggested and briefly discussed. Utilisation of mode localization as a sense mechanism involves the use of changes in the normalised mode shape of a weakly-coupled two degree-of-freedom system as the sensor output. This is in contrast to the use of shifts in frequency, phase or amplitude as is commonplace in resonant micro-electromechanical systems (MEMS) sensor technology. The theory and principles of device operation are introduced utilising a discretised model. In particular, the use of a periodic array to couple the sensors’ two degrees-of-freedom is investigated. A generalised geometry of the SAW device is introduced, consisting of a pair of acoustically-coupled cavities. An analytical solution is found for the displacement fields within the cavities. The solution is achieved by coupling the internal cavity solutions using a ray tracing method. The results of the analytical solution are compared to a numerical solution found using commercial finite element analysis (FEA) software; good agreement is observed. The model is subsequently used to analyse and discuss device performance in the presence of noise; expressions are presented describing device operation and performance, and a case study is outlined evaluating use as a MEMS magnetometer. Finally, the design, manufacture and testing of a prototype design is discussed. |
author |
Hanley, Thomas Harry |
spellingShingle |
Hanley, Thomas Harry On the exploitation of mode localization in surface acoustic wave MEMS for sensing applications |
author_facet |
Hanley, Thomas Harry |
author_sort |
Hanley, Thomas Harry |
title |
On the exploitation of mode localization in surface acoustic wave MEMS for sensing applications |
title_short |
On the exploitation of mode localization in surface acoustic wave MEMS for sensing applications |
title_full |
On the exploitation of mode localization in surface acoustic wave MEMS for sensing applications |
title_fullStr |
On the exploitation of mode localization in surface acoustic wave MEMS for sensing applications |
title_full_unstemmed |
On the exploitation of mode localization in surface acoustic wave MEMS for sensing applications |
title_sort |
on the exploitation of mode localization in surface acoustic wave mems for sensing applications |
publisher |
University of Newcastle upon Tyne |
publishDate |
2017 |
url |
http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.728345 |
work_keys_str_mv |
AT hanleythomasharry ontheexploitationofmodelocalizationinsurfaceacousticwavememsforsensingapplications |
_version_ |
1718693919658606592 |