Finding unstable periodic orbits: a hybrid approach with polynomial optimization
Finding unstable periodic orbits: a hybrid approach with polynomial optimization
We present a novel method to compute unstable periodic orbits (UPOs) that optimize the infinite-time average of a given quantity for polynomial ODE systems. The UPO search procedure relies on polynomial optimization to construct nonnegative polynomials whose sublevel sets approximately localize parts of the optimal UPO, and that can be used to implement a simple yet effective control strategy to reduce the UPO’s instability. Precisely, we construct a family of controlled ODE systems, parameterized by a scalar , such that the original ODE system is recovered for and such that the optimal orbit is less unstable, or even stabilized, for . Periodic orbits for the controlled system can often be more easily converged with traditional methods, and numerical continuation in allows one to recover optimal UPOs for the original system. The effectiveness of this approach is illustrated on three low-dimensional ODE systems with chaotic dynamics.
Lakshmi, Mayur V.
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Fantuzzi, Giovanni
42f8bae5-8b01-4cc7-a931-72ade16ffd70
Chernyshenko, Sergei I.
91132b47-9175-43d6-bde4-fc2881005101
Lasagna, Davide
0340a87f-f323-40fb-be9f-6de101486b24
5 September 2021
Lakshmi, Mayur V.
d4e6b8e8-1c6b-4e2a-b82e-af7d4b454db0
Fantuzzi, Giovanni
42f8bae5-8b01-4cc7-a931-72ade16ffd70
Chernyshenko, Sergei I.
91132b47-9175-43d6-bde4-fc2881005101
Lasagna, Davide
0340a87f-f323-40fb-be9f-6de101486b24
Lakshmi, Mayur V., Fantuzzi, Giovanni, Chernyshenko, Sergei I. and Lasagna, Davide
(2021)
Finding unstable periodic orbits: a hybrid approach with polynomial optimization.
Physica D: Nonlinear Phenomena, 427, [133009].
(doi:10.1016/j.physd.2021.133009).
Abstract
We present a novel method to compute unstable periodic orbits (UPOs) that optimize the infinite-time average of a given quantity for polynomial ODE systems. The UPO search procedure relies on polynomial optimization to construct nonnegative polynomials whose sublevel sets approximately localize parts of the optimal UPO, and that can be used to implement a simple yet effective control strategy to reduce the UPO’s instability. Precisely, we construct a family of controlled ODE systems, parameterized by a scalar , such that the original ODE system is recovered for and such that the optimal orbit is less unstable, or even stabilized, for . Periodic orbits for the controlled system can often be more easily converged with traditional methods, and numerical continuation in allows one to recover optimal UPOs for the original system. The effectiveness of this approach is illustrated on three low-dimensional ODE systems with chaotic dynamics.
Text
2101.10285-2
- Accepted Manuscript
More information
Accepted/In Press date: 9 August 2021
e-pub ahead of print date: 28 August 2021
Published date: 5 September 2021
Identifiers
Local EPrints ID: 482978
URI: http://eprints.soton.ac.uk/id/eprint/482978
ISSN: 0167-2789
PURE UUID: dfabc091-0f89-474c-9ee0-aaa1b319e30d
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Date deposited: 18 Oct 2023 16:33
Last modified: 17 Mar 2024 07:22
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Contributors
Author:
Mayur V. Lakshmi
Author:
Giovanni Fantuzzi
Author:
Sergei I. Chernyshenko
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