Applied Science Unimathematical Test Fundamental Metasciences System

by

© Ph. D. & Dr. Sc. Lev Gelimson

Academic Institute for Creating Fundamental Sciences (Munich, Germany)

Mathematical Journal

of the "Collegium" All World Academy of Sciences

Munich (Germany)

12 (2012), 5

Keywords: Applied science, megascience, revolution, megamathematics, overmathematics, unimathematical test fundamental metasciences system, knowledge, philosophy, strategy, tactic, analysis, synthesis, object, operation, relation, criterion, conclusion, evaluation, measurement, estimation, expression, modeling, processing, symmetry, invariance, bound, level, worst case, defect, mistake, error, reserve, reliability, risk, supplement, improvement, modernization, variation, modification, correction, transformation, generalization, replacement.

Introduction

There are many separate scientific achievements of mankind but they often bring rather unsolvable problems than really improving himan life quality. One of the reasons is that the general level of earth science is clearly insufficient to adequately solve and even consider many urgent himan problems. To provide creating and developing applicable and, moreover, adequate methods, theories, and sciences, we need their testing via universal if possible, at least applicable and, moreover, adequate test metamethods, metatheories, and metasciences whose general level has to be high enough. Mathematics as universal quantitative scientific language naturally has to play here a key role.

But classical mathematics [1] with hardened systems of axioms, intentional search for contradictions and even their purposeful creation cannot (and does not want to) regard very many problems in science, engineering, and life. This generally holds when solving valuation, estimation, discrimination, control, and optimization problems as well as in particular by measuring very inhomogeneous objects and rapidly changeable processes. It is discovered [2] that classical fundamental mathematical theories, methods, and concepts [1] are insufficient for adequately solving and even considering many typical urgent problems.

Mega-overmathematics [2] based on its uninumbers, quantielements, quantisets, and uniquantities with quantioperations and quantirelations provides universally and adequately modeling, expressing, measuring, evaluating, and estimating general objects. This all creates the basis for many further mega-overmathematics fundamental sciences systems developing, extending, and applying overmathematics. Among them are, in particular, science unimathematical test fundamental metasciences systems [3] which are universal.

Applied Science Unimathematical Test Fundamental Metasciences System

Applied science unimathematical test fundamental metasciences system in mega-overmathematics [2] is one of such systems and can efficiently, universally and adequately strategically unimathematically test any pure science. This system includes:

fundamental metascience of applied science test philosophy, strategy, and tactic including applied science test philosophy metatheory, applied science test strategy metatheory, and applied science test tactic metatheory;

fundamental metascience of applied science consideration including applied science fundamentals determination metatheory, applied science approaches determination metatheory, applied science methods determination metatheory, and applied science conclusions determination metatheory;

fundamental metascience of applied science analysis including applied subscience analysis metatheory, applied science fundamentals analysis metatheory, applied science approaches analysis metatheory, applied science methods analysis metatheory, and applied science conclusions analysis metatheory;

fundamental metascience of applied science synthesis including applied science fundamentals synthesis metatheory, applied science approaches synthesis metatheory, applied science methods synthesis metatheory, and applied science conclusions synthesis metatheory;

fundamental metascience of applied science objects, operations, relations, and criteria including applied science object metatheory, applied science operation metatheory, applied science relation metatheory, and applied science criterion metatheory;

fundamental metascience of applied science evaluation, measurement, and estimation including applied science evaluation metatheory, applied science measurement metatheory, and applied science estimation metatheory;

fundamental metascience of applied science expression, modeling, and processing including applied science expression metatheory, applied science modeling metatheory, and applied science processing metatheory;

fundamental metascience of applied science symmetry and invariance including applied science symmetry metatheory and applied science invariance metatheory;

fundamental metascience of applied science bounds and levels including applied science bound metatheory and applied science level metatheory;

fundamental metascience of applied science directed test systems including applied science test direction metatheory and applied science test step metatheory;

fundamental metascience of applied science tolerably simplest limiting, critical, and worst cases analysis and synthesis including applied science tolerably simplest limiting cases analysis and synthesis metatheories, applied science tolerably simplest critical cases analysis and synthesis metatheories, applied science tolerably simplest worst cases analysis and synthesis metatheories, and applied science tolerably simplest limiting, critical, and worst cases counterexamples building metatheories;

fundamental metascience of applied science defects, mistakes, errors, reserves, reliability, and risk including applied science defect metatheory, applied science mistake metatheory, applied science error metatheory, applied science reserve metatheory, applied science reliability metatheory, and applied science risk metatheory;

fundamental metascience of applied science test result evaluation, measurement, estimation, and conclusion including applied science test result evaluation metatheory, applied science test result measurement metatheory, applied science test result estimation metatheory, and applied science test result conclusion metatheory;

fundamental metascience of applied science supplement, improvement, modernization, variation, modification, correction, transformation, generalization, and replacement including applied science supplement metatheory, applied science improvement metatheory, applied science modernization metatheory, applied science variation metatheory, applied science modification metatheory, applied science correction metatheory, applied science transformation metatheory, applied science generalization metatheory, and applied science replacement metatheory.

The applied science unimathematical test fundamental metasciences system in megamathematics [2] is universal and very efficient.

References

[1] Encyclopaedia of Mathematics / Managing editor M. Hazewinkel. Volumes 1 to 10. Kluwer Academic Publ., Dordrecht, 1988-1994

[2] Lev Gelimson. Elastic Mathematics. General Strength Theory. The "Collegium" All World Academy of Sciences Publishers, Munich (Germany), 2004, 496 pp.

[3] Lev Gelimson. Science Unimathematical Test Fundamental Metasciences Systems. Mathematical Journal of the “Collegium” All World Academy of Sciences, Munich (Germany), 12 (2012), 1