2000 MSC: prim. 00A69; sec. 35A35, 39B05, 39B72, 58J70

General Problem Theory (Essential)

by

© Ph. D. & Dr. Sc. Lev Gelimson

Academic Institute for Creating Fundamental Sciences (Munich, Germany)

RUAG Aerospace Services GmbH, Germany

Mathematical Journal

of the "Collegium" All World Academy of Sciences

Munich (Germany)

3 (2003), 1

     For many typical problems, there are no concepts and methods adequate and general enough. The absolute error alone is not sufficient for approximation quality estimation. The relative error is uncertain in principle and has a very restricted applicability domain. The unique known method applicable to overdetermined problems usual in data processing is the least-square method with narrow applicability and adequacy domains and many fundamental defects. No known proposition applies to estimating the quality of approximations to functions and distributions.

A general equation problem generalizes sets of equations of any types including initial and boundary value problems, etc. Consider a quantiset of any equations over indexed functions (dependent variables) f_g of indexed independent variables z_w, all of them belonging to their individual vector spaces. Gather all available functions in the left-hand sides of the equations without further transformations. The unique exception is changing the signs of expressions by moving them to the other sides of the same equations. We receive

_w(l)(K_l[_{g belongs to G} f_g[_{w belongs to W} z_w]] = 0) (l belongs to L)

where K_l is an operator with index l; L, G, W are index sets; [_{w belongs to W} z_w] is a set of indexed elements; w(l) is the quantity as a weight of the lth equation. When replacing all the unknowns (unknown functions) with their possible ”values” (some known functions), the quantiset is transformed into the corresponding quantiset of formal functional equalities. To conserve the quantiset form, for the known functions also use the same designations f_g.

A general relation problem is a quantiset of relations

R_l: _w(l)R_l[_{g belongs to G} f_g[_{w belongs to W} z_w]] (l belongs to L).

A general problem is a quantisystem of relations containing both known elements and unknown ones, which can be regarded as values and variables, respectively.

A pseudosolution to a problem is a quantisystem of such values of all the variables that, after replacing each variable with its value, the problem quantisystem contains no unknown elements, and each of its relations has certain sense and is determinable (i.e., true or false).

A unierror irreproachably corrects the relative error and generalizes it possibly for any conceivable range of applicability. For an equality a =? b (true or not), a unierror can be represented as e_{a =? b} = |a - b|/(|a| + |b|) if |a| + |b| > 0, e_{a =? b} = 0 by a = b = 0, or, by introducing extended division a//b = a/b by nonzero a, a//b = 0 by a = 0 and any (even zero) b, e_{a =? b} = |a - b|//(|a| + |b|). Another possibility is using, instead of the linear estimation fraction, the quadratic one ²e_{a =? b} = |a - b|//[2(|a|² +|b|²)]^1/2 with values in [0, 1], too.

A reserve R with values in [-1, 1] extends the unierror e. For an inexact object I, R(I) = -e(I). For an exact object E, map it at its exactness boundary and take the unierror. For inequalities, negate inequality relations and conserve equality ones, also with natural extending to any functions.

Unierrors and reserves bring reliable estimations of approximation quality and exactness confidence. Using them unlike the least-square method, iteration methods of the least normed powers, of unierror and reserve equalization, and of a direct solution give both quasisolutions and its invariant measure. They all are very effective by setting and solving many urgent general problems in science, engineering, and life, e.g. coding ones.