Lagrangian mechanics of fractional order, Hamilton-Jacobi fractional PDE and Taylor's series of nondifferentiable functions

The paper proposes an extension of the Lagrange analytical mechanics to deal with dynamics of fractal nature. First of all, by using fractional difference, one introduces a slight modification of the Riemann-Liouville derivative definition, which is more consistent with self-similarity by removing the effect of the initial value, and then for the convenience of the reader, one gives a brief background on the Taylor's series of fractional order f(x + h) = E-alpha(h(alpha)E(x)(alpha))f(x) of nondifferentiable function, where E-alpha is the Mittag-Leffler function. The Lagrange characteristics method is extended for solving a class of nonlinear fractional partial differential equations. All this material is necessary to solve the problem of fractional optimal control and mainly to find the characteristics of its fractional Hamilton-Jacobi equation, therefore the canonical equations of optimality. Then fractional Lagrangian mechanics is considered as an application of fractional optimal control. In this framework, the use of complex-valued variables, as Nottale did it, appears as a direct consequence of the irreversibility of time. (c) 2006 Elsevier Ltd. All rights reserved.