Kaplan–Yorke conjecture

In applied mathematics, the Kaplan–Yorke conjecture concerns the dimension of an attractor, using Lyapunov exponents.^[1]^[2] By arranging the Lyapunov exponents in order from largest to smallest $\lambda _{1}\geq \lambda _{2}\geq \dots \geq \lambda _{n}$ , let j be the largest index for which

\sum _{i=1}^{j}\lambda _{i}\geqslant 0

and

\sum _{i=1}^{j+1}\lambda _{i}<0.

Then the conjecture is that the dimension of the attractor is

D=j+{\frac {\sum _{i=1}^{j}\lambda _{i}}{|\lambda _{j+1}|}}.

This idea is used for the definition of the Lyapunov dimension.^[3]

Examples edit

Especially for chaotic systems, the Kaplan–Yorke conjecture is a useful tool in order to estimate the fractal dimension and the Hausdorff dimension of the corresponding attractor.^[4]^[3]

The Hénon map with parameters a = 1.4 and b = 0.3 has the ordered Lyapunov exponents $\lambda _{1}=0.603$ and $\lambda _{2}=-2.34$ . In this case, we find j = 1 and the dimension formula reduces to

D=j+{\frac {\lambda _{1}}{|\lambda _{2}|}}=1+{\frac {0.603}{|{-2.34}|}}=1.26.

The Lorenz system shows chaotic behavior at the parameter values $\sigma =16$ , $\rho =45.92$ and $\beta =4.0$ . The resulting Lyapunov exponents are {2.16, 0.00, −32.4}. Noting that j = 2, we find