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DTSTAMP:20171013T020032Z
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DTSTART;TZID=Canada/Pacific:20171013T180000
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DESCRIPTION:By targeting a very specific type of algorithm that would be co
 nstructed from the use of differentials defined in a very unique algebraic
  configuration\, this has succeeding in exposing what appears to be a comp
 lete unified theory of analytical integration in Calculus. The unique math
 ematical properties of this algorithm could be exploited much further for 
 establishing the basic fundamental building blocks of what is known today 
 as the theory of everything. Under such a unified theory of integration\, 
 the analytical solutions of all fundamental PDEs of Physics and Engineerin
 g may now be potentially resolved in their complete original form thereby 
 avoiding the uncertainty of having to apply various types of transformatio
 n processes just for reducing the PDEs to more integrable type.\n\nThe cla
 ssical definition of the theory of everything according to many physicists
  is a hypothetical single\, coherent theoretical framework of physics that
  fully explains and links together all physical aspects of the universe. W
 e ask ourselves "how can such a grandiose physical theory for explaining e
 verything about this universe be possible without the application of an eq
 uivalent grandiose mathematical theory that would explain everything about
  the complete integration of all differential equations (DEs) ". Since DEs
  are universal and not linked to any specific area of the Physical Science
 s there is no evidence to support that Modern Physics is the only subject 
 by which a complete theory of everything may be entirely constructed from.
  Instead\, it is only by consolidating the general analytical solutions of
  all PDEs describing a unique physical system such as the Maxwell equation
 s\, the Einstein Field equations and the Navier-Stokes equations all in te
 rms of fundamental theorems that would lead to the construction of some gi
 gantic theory capable of explaining everything about our physical universe
 . This of course can only be possible under a complete unified theory of a
 nalytical integration such as the one that will be presenting in this talk
 .\n\nCo-sponsored by: IEEE Circuits and Systems Society joint Chapter of t
 he Vancouver/Victoria Sections\n\nSpeaker(s): Mike Mikalajunas\, \, Mike M
 ikalajunas\, \n\nAgenda: \nBy targeting a very specific type of algorithm 
 that would be constructed from the use of differentials defined in a very 
 unique algebraic configuration\, this has succeeding in exposing what appe
 ars to be a complete unified theory of analytical integration in Calculus.
  The unique mathematical properties of this algorithm could be exploited m
 uch further for establishing the basic fundamental building blocks of what
  is known today as the theory of everything. Under such a unified theory o
 f integration\, the analytical solutions of all fundamental PDEs of Physic
 s and Engineering may now be potentially resolved in their complete origin
 al form thereby avoiding the uncertainty of having to apply various types 
 of transformation processes just for reducing the PDEs to more integrable 
 type.\n\nThe classical definition of the theory of everything according to
  many physicists is a hypothetical single\, coherent theoretical framework
  of physics that fully explains and links together all physical aspects of
  the universe. We ask ourselves "how can such a grandiose physical theory 
 for explaining everything about this universe be possible without the appl
 ication of an equivalent grandiose mathematical theory that would explain 
 everything about the complete integration of all differential equations (D
 Es) ". Since DEs are universal and not linked to any specific area of the 
 Physical Sciences there is no evidence to support that Modern Physics is t
 he only subject by which a complete theory of everything may be entirely c
 onstructed from. Instead\, it is only by consolidating the general analyti
 cal solutions of all PDEs describing a unique physical system such as the 
 Maxwell equations\, the Einstein Field equations and the Navier-Stokes equ
 ations all in terms of fundamental theorems that would lead to the constru
 ction of some gigantic theory capable of explaining everything about our p
 hysical universe. This of course can only be possible under a complete uni
 fied theory of analytical integration such as the one that will be present
 ing in this talk.\n\nRoom: 2270 Sauder Industries Policy Room\, Bldg: SFU 
 Harbour Centre \, Simon Fraser University\, 515 West Hastings Street\, Van
 couver\, British Columbia\, Canada\, V6B 5K3
LOCATION:Room: 2270 Sauder Industries Policy Room\, Bldg: SFU Harbour Centr
 e \, Simon Fraser University\, 515 West Hastings Street\, Vancouver\, Brit
 ish Columbia\, Canada\, V6B 5K3
ORGANIZER:ljilja@cs.sfu.ca
SEQUENCE:5
SUMMARY:The fundamental building blocks of a "theory of everything" under a
  unified theory of analytical integration 
URL;VALUE=URI:https://events.vtools.ieee.org/m/47214
X-ALT-DESC:Description: <br /><p>By targeting a very specific type of algor
 ithm that would be constructed from the use of differentials defined in a 
 very unique algebraic configuration\, this has succeeding in exposing what
  appears to be a complete unified theory of analytical integration in Calc
 ulus. The unique mathematical properties of this algorithm could be exploi
 ted much further for establishing the basic fundamental building blocks of
  what is known today as the theory of everything. Under such a unified the
 ory of integration\, the analytical solutions of all fundamental PDEs of P
 hysics and Engineering may now be potentially resolved in their complete o
 riginal form thereby avoiding the uncertainty of having to apply various t
 ypes of transformation processes just for reducing the PDEs to more integr
 able type.</p>\n<p>The classical definition of the theory of everything ac
 cording to many physicists is a hypothetical single\, coherent theoretical
  framework of physics that fully explains and links together all physical 
 aspects of the universe. We ask ourselves "how can such a grandiose physic
 al theory for explaining everything about this universe be possible withou
 t the application of an equivalent grandiose mathematical theory that woul
 d explain everything about the complete integration of all differential eq
 uations (DEs) ". Since DEs are universal and not linked to any specific ar
 ea of the Physical Sciences there is no evidence to support that Modern Ph
 ysics is the only subject by which a complete theory of everything may be 
 entirely constructed from. Instead\, it is only by consolidating the gener
 al analytical solutions of all PDEs describing a unique physical system su
 ch as the Maxwell equations\, the Einstein Field equations and the Navier-
 Stokes equations all in terms of fundamental theorems that would lead to t
 he construction of some gigantic theory capable of explaining everything a
 bout our physical universe. This of course can only be possible under a co
 mplete unified theory of analytical integration such as the one that will 
 be presenting in this talk.</p><br /><br />Agenda: <br /><p>By targeting a
  very specific type of algorithm that would be constructed from the use of
  differentials defined in a very unique algebraic configuration\, this has
  succeeding in exposing what appears to be a complete unified theory of an
 alytical integration in Calculus. The unique mathematical properties of th
 is algorithm could be exploited much further for establishing the basic fu
 ndamental building blocks of what is known today as the theory of everythi
 ng. Under such a unified theory of integration\, the analytical solutions 
 of all fundamental PDEs of Physics and Engineering may now be potentially 
 resolved in their complete original form thereby avoiding the uncertainty 
 of having to apply various types of transformation processes just for redu
 cing the PDEs to more integrable type.</p>\n<p>The classical definition of
  the theory of everything according to many physicists is a hypothetical s
 ingle\, coherent theoretical framework of physics that fully explains and 
 links together all physical aspects of the universe. We ask ourselves "how
  can such a grandiose physical theory for explaining everything about this
  universe be possible without the application of an equivalent grandiose m
 athematical theory that would explain everything about the complete integr
 ation of all differential equations (DEs) ". Since DEs are universal and n
 ot linked to any specific area of the Physical Sciences there is no eviden
 ce to support that Modern Physics is the only subject by which a complete 
 theory of everything may be entirely constructed from. Instead\, it is onl
 y by consolidating the general analytical solutions of all PDEs describing
  a unique physical system such as the Maxwell equations\, the Einstein Fie
 ld equations and the Navier-Stokes equations all in terms of fundamental t
 heorems that would lead to the construction of some gigantic theory capabl
 e of explaining everything about our physical universe. This of course can
  only be possible under a complete unified theory of analytical integratio
 n such as the one that will be presenting in this talk.</p>
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