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Controlling Chaos!

Controlling Chaos!. Dylan Thomas and Alex Yang. Why control chaos?. One may want a system to be used for different purposes at different times Chaos offers flexibility (ability to switch between behaviors as circumstances change) Small changes produce large effects. How is it done?.

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Controlling Chaos!

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  1. Controlling Chaos! Dylan Thomas and Alex Yang

  2. Why control chaos? • One may want a system to be used for different purposes at different times • Chaos offers flexibility (ability to switch between behaviors as circumstances change) • Small changes produce large effects

  3. How is it done? • Chaotic systems can be controlled by using the underlying non-linear deterministic structure. • Exploit extreme sensitivity to initial conditions • Use small, appropriately timed changes to bring the system onto the stable manifold of an unstable orbit

  4. Famous examples Chaotic ribbon Lorentz equations

  5. ISEE-3/ICE and the n body problem

  6. Two methods • Ott, Grebogi, Yorke: modify parameters of the system to move the stable manifold to the current system state • Garfinkel et. al. (Proportional perturbation feedback): force the system onto the stable manifold by a small perturbation

  7. The logistic map

  8. The Hénon map

  9. Variation of a parameter in the Hénon map Legend: Green =stable manifold Red = unstable manifold

  10. Matlab experimental results

  11. Controlling chaos when the equations determining the system are not known • Let Z1, Z2,…,Zn be a trajectory, or a series of piercing of a Poincare surface-of-section • If two successive Zs are close, then there will be a period one orbit Z* nearby • Find other such close successive pairs of points, which will exist because orbits on a strange attractor are ergodic. • Perform a regression to estimate A, an approximation of the Jacobian matrix, and C, a constant vector. • For period 2 points, proceed the same way, for pairs (Zn, Zn+2)

  12. Altering the dynamics of arrythmia

  13. Cardiac tissue

  14. Neurons Schiff et al. removed and sectioned the hippocampus of rats (where sensory inputs and distributed to the forebrain) and perfused it with artificial cerebrospinal fluid.

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