Multi-parameter persistence in dynamical systems for maximizing effects of control inputs

Abstract

We introduce a new topological method to naturally extend a partial function h X [-∞, ∞] on a ``generalization'' of a metric space X equipped with a dynamical system f X X, to a function hf-p X [-∞,∞] with parameters ,p, which allows us to apply existing topological data analysis techniques to functions defined on the whole space. Moreover, given a function h that evaluates the ``quality'' of points within domh, using this extended function, one can construct a sufficient condition for the existence of an optimal -perturbation path from any point into domh that minimizes the value of h under the condition X = dom f domh = n = 0∞ f-n(domh). In addition, if the domain X is finite, then the function hf-p X [-∞,∞] can be computed recursively. As an application, for a given partial evaluation function on a space equipped with a dynamical system, one can construct a three-parameter filtration associated with its extension, which naturally identifies minimal paths. This clarifies the relationship among three factors: the evaluation of the cost norm, the strength of control, and the resulting value.