Multiscale functions, Scale dynamics and Applications to partial differential equations

Abstract

Modeling phenomena from experimental data, always begin with a choice of hypothesis on the observed dynamics such as determinism, randomness, derivability etc. Depending on these choices, different behaviors can be observed. The natural question associated to the modeling problem is the following : "With a finite set of data concerning a phenomenon, can we recover its underlying nature ? From this problem, we introduce in this paper the definition of multi-scale functions, scale calculus and scale dynamics based on the time-scale calculus (see bohn). These definitions will be illustrated on the multi-scale Okamoto's functions. The introduced formalism explains why there exists different continuous models associated to an equation with different scale regimes whereas the equation is scale invariant. A typical example of such an equation, is the Euler-Lagrange equation and particularly the Newton's equation which will be discussed. Notably, we obtain a non-linear diffusion equation via the scale Newton's equation and also the non-linear Schr\"odinger equation via the scale Newton's equation. Under special assumptions, we recover the classical diffusion equation and the Schr\"odinger equation.