Difference between revisions of "Michael Meylan"

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plate (which can be computed in exact form, at least up to solving an equation involving
 
plate (which can be computed in exact form, at least up to solving an equation involving
 
Bessel functions. The solution method has been superseeded by [[Peter_Meylan_Chung_2004a | Peter, Meylan and Chung 2004]].
 
Bessel functions. The solution method has been superseeded by [[Peter_Meylan_Chung_2004a | Peter, Meylan and Chung 2004]].
 +
Mike also developed a method to solve for plates of arbitrary geometry, initially using
 +
a variational method ([[Meylan_2001a|Meylan 2001]]) and later using the [[Finite Element Method]]
 +
([[Meylan_2001b|Meylan 2001]].
  
 
Mike then worked on using the solution for a circular elastic plate to try and construct a model
 
Mike then worked on using the solution for a circular elastic plate to try and construct a model
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Mike then began to work on a very abstract (and difficult problems) of an eigenfunction
 
Mike then began to work on a very abstract (and difficult problems) of an eigenfunction
 
expansion method for the non-selfadjoint operator which arises in the scattering model
 
expansion method for the non-selfadjoint operator which arises in the scattering model
of [[Meylan_Squire_Fox_1997a| Meylan, Squire and Fox 1997]]
+
of [[Meylan_Squire_Fox_1997a| Meylan, Squire and Fox 1997]]. This work is still
 +
unpublished although a paper has been submitted. It is not a problem in water wave theory.
  
 
= Publications =
 
= Publications =

Revision as of 04:53, 5 May 2006

Micheal Meylan is a lecturer at the University of Auckland. He complete his Ph.D. under Vernon Squire in 1993 which was concerned with modelling ice floes using linear wave theory.

He has worked on various problem connected with linear wave theory in the subsequent time. The idea for a website devoted to water waves was his idea.

Photo taken in 1999

Research

Mike's Phd thesis concerned a two-dimensional floating elastic plate which was solved using a Green function method. The motivation for the solution was to model ice floe and at the time he was ignorant of the engineering applications (e.g. VLFS). Mike independently derived the Green function which was well known in water waves and goes back to John 1950. The derivation method was copied by Squire and Dixon 2000 (based on a close reading of his Phd thesis) for the case, not of a free surface, but for a free surface covered by a plate The results of this research were publised in the Journal of Geophysical Research were largely ignored by later researchers. His Phd thesis probably had a much greater influence on the researchers who followed at Otago and it is continuing to appear in journal citations. The solution method using a Green function coupled with a Green function for the plate (the later Green function does not extend to three dimensions because of the much more complicated boundary conditions which exist). The solution method has been superseeded by more efficient methods, most notably the Wiener-Hopf method developed by Tim Williams and the eigenfunction matching method (which applied to multiple plates) developed by Kohout et. al. 2006.

Mike then extended the two-dimensional solution to a three-dimensional circular elastic plate (Meylan and Squire 1996). This solution again used a Green function method coupled with the eigenfunctions for a circular plate (which can be computed in exact form, at least up to solving an equation involving Bessel functions. The solution method has been superseeded by Peter, Meylan and Chung 2004. Mike also developed a method to solve for plates of arbitrary geometry, initially using a variational method (Meylan 2001) and later using the Finite Element Method (Meylan 2001.

Mike then worked on using the solution for a circular elastic plate to try and construct a model for wave scattering in the Marginal Ice Zone ( Meylan, Squire and Fox 1997). This model was developed independently of the model of Masson and LeBlond 1989 but shares many similarities with it.

Mike then began to work on a very abstract (and difficult problems) of an eigenfunction expansion method for the non-selfadjoint operator which arises in the scattering model of Meylan, Squire and Fox 1997. This work is still unpublished although a paper has been submitted. It is not a problem in water wave theory.

Publications

Meylan 2002

Mike's Pages

Scattering Frequencies