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International youth conference "Geometry & Control"
April 14, 2014 15:30, Moscow, Steklov Mathematical Institute of RAS
 


On Conjugate Times of LQ Optimal Control Problems

Pavel Silveira

SISSA, Trieste, Italy
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Flash Video 185.3 Mb
MP4 679.6 Mb
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Adobe PDF 52.8 Kb

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Pavel Silveira



Abstract: We consider an LQ optimal control problem, more generally a dynamical system with a constant quadratic Hamiltonian, and we characterize the number of conjugate times in terms of the spectrum of the Hamiltonian vector field $\vec{H}$. We prove the following dichotomy: the number of conjugate times is identically zero or grows to infinity. The latter case occurs if and only if $\vec{H}$ has at least one Jordan block of odd dimension corresponding to a purely imaginary eigenvalue. As a byproduct, we obtain bounds from below on the number of conjugate times contained in an interval in terms of the spectrum of $\vec{H}$.
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Theorem. The conjugate times of a controllable linear quadratic optimal control problem obey the following dichotomy:
  • If the Hamiltonian field $\vec{H}$ has at least one odd-dimensional Jordan block corresponding to a pure imaginary eigenvalue, the number of conjugate times in the interval $[0,T]$ grows to infinity for $T\to \pm\infty$.
  • If the Hamiltonian field $\vec{H}$ has no odd-dimensional Jordan blocks corresponding to a pure imaginary eigenvalue, there are no conjugate times.


Supplementary materials: abstract.pdf (52.8 Kb)

Language: English

References
  1. A. Agrachev, L. Rizzi, and P. Silveira, On conjugate times of LQ optimal control problems. Preprint arXiv:1311.2009, Nov. 2013 (submitted).
 
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