Set inversion


In mathematics, set inversion is the problem of characterizing the preimage X of a set Y by a function f, i.e., X = f−1 =. It can also be viewed as the problem of describing the solution set of the quantified constraint "Y", where Y is a constraint, for example, an inequality, describing the set Y.
In most applications, f is a function from Rn to Rp and the set Y is a box of Rp.
When f is nonlinear the set inversion problem can be solved
using interval analysis combined with a branch-and-bound algorithm.
The main idea consists in building a paving of Rp made with non-overlapping boxes. For each box , we perform the following tests:
  1. if fY we conclude that ⊂ X;
  2. if fY = we conclude that ∩ X = ∅;
  3. Otherwise, the box the box is bisected except if its width is smaller than a given precision.
To check the two first tests, we need an interval extension for f. Classified boxes are stored into subpavings, i.e., union of non overlapping boxes.
The algorithm can be made more efficient by replacing the inclusion tests by contractors.

Example

The set X = f−1 where f = x + x is represented on the figure.
For instance, since 2 + 2 = + = does not intersect the interval , we conclude that the box × is outside X. Since 2 + 2 = + = is inside , we conclude that the whole box × is inside X.

Application

Set inversion is mainly used for path planning, for nonlinear parameter set estimation
, for localization
or for the characterization of stability domains of linear dynamical systems.