what appears to be a complete unified analytical theory of integration

For quite some time now I have been supporting a research development project in Physics and Engineering entirely on my own.  Over time, my findings have accumulated to a point where it may now be considered important enough to warrant the close attention of many knowledgeable researchers in the Physical Sciences.  

As a result of this, my research has now progressed much beyond the level of postdoctoral studies and so this represents for me an excellent opportunity to reach out for some much needed support from within your department.  I would also like to mention that I am currently seeking to apply for some form of funding from various private and public agencies that would tend to favor promoting the development of such a unique type of project in Physics and Engineering. 

The nature of my current research development project involves targeting a very specific type of algorithm that would be constructed from the use of differentials defined in a very unique algebraic configuration.  In accordance with a vast amount of computational experimentation performed over the years, such a unique algorithm has apparently succeeding in exposing what appears to be a complete unified analytical theory of integration in Calculus.  The unique mathematical properties of this algorithm could be exploited much further into the future for establishing the basic fundamental building blocks of what is known today as the theory of everything.  All of this has been well documented in the attachment PDF file entitled  "Main_Proposal.Pdf" followed by a number of supporting PDF reference documents. 

In order to confirm my results, I would like to become part of a research development team within your department so that I can receive the proper resources for providing a complete numerical validation on the existence of such a unified theory of integration for specific applications to Applied Physics and Engineering Science. 

The proposed numerical validation process would consist primarily of using the new universal differential algorithm for arriving at the same exact analytical solutions that were obtained by various authors of several previously published papers in Applied Physics and Engineering Science.  Three of these papers would involve the use of the Navier-Stokesequations in mechanics of fluids, one involving the Navier-Cauchy equations in mechanics of material and finally, the use of the Maxwell-Einstein equation in Applied Physics for a problem in magnetostatic fields. 

I have also included the PDF attachment files  "Seminar_Abstract.Pdf"  and  "Seminar_Abstract_Navier-Stokes.pdf"  each containing a complete abstract for possible presentation at one of your upcoming internal seminars.  This would provide an ideal environment for everyone by which the entire proposal would be discussed in much greater detail. 

Best regards, 
Mike Mikalajunas 
Center for Innovations in Mathematical Equations 
(514) 425-1370