Supplement to Chaos
One way to get a handle on global Lyapunov exponents is to see how
they arise out of linear stability analysis of the trajectories of
evolution equations. Consider the first-order, ordinary differential
equation system
dx ⁄ dt = Fx
and suppose that
x* is a steady point, i.e. a point at which
F(x*) = 0. We
can study the behavior of trajectories
near x* by
considering x(t) = x*
+ ε(t), where ε(t) is an
infinitesimal perturbation to every component
of x. Substituting back
into F and expanding to first order in
ε(t) (considering only the perturbations at t = 0 and dropping the explicit dependence on t from ε) yields
| (A1) |
F(x*+ ε) = F(x*) + J(x*)ε + O(ε), |
where the matrix
J(x) is the
n×n Jacobian matrix of partial derivatives of
F evaluated at the point
x. We then obtain an equation for the time dependence
of the perturbation of x, namely
A linear stability analysis results if we neglect terms of
ε2 or higher powers in (A2). If
ε is a real-valued vector and
J a real-valued matrix (i.e., having no
complex values), and we assume a solution of the form
ε = λest, (A2) reduces to
the eigenvalue equation
Linear stability analysis can be used to characterize Lyapunov
exponents for nonlinear systems of equations. Consider the initial
condition x(0) for our first-order system of
differential equations and an infinitesimal displacement from
x(0) in the direction of some tangent vector,
y(0). Then the evolution of
y according to (A2) is given by
valid for only an infinitesimal neighborhood about
x(0). So the value of the vector
y changes in time according to the values
J takes on over time. Here
y ⁄ |y| gives the
direction of the infinitesimal displacement from
x, where the bars indicate absolute
magnitude. Additionally, |y| ⁄ |y(0)| gives
the factor by which the infinitesimal displacement grows
(|y|>|y(0)|) or
shrinks
(|y|<|y(0)|).
The Lyapunov exponent is now defined with respect to initial condition
x(0) and initial orientation of the
infinitesimal
displacement y(0) ⁄ |y(0)|
as
| (A5) |
λ(x(0)), |
|
)
|
= |
limt→∞
t−1 ln( |
|
) |
|
|
|
|
= |
limt→∞
t−1 ln( |
|
) . |
For an n-dimensional system, there will be at most
n distinct Lyapunov exponents for a given
x(0), and the relevant exponent is picked out
by the initial orientation y
(0) ⁄ |y(0)|. The infinite time limit plays an
important role in this analysis as it indicates that the Lyapunov
exponents represent time-averaged quantities (meaning that transient
behavior has decayed). The existence of this limit is guaranteed by
Oseledec's (1969) multiplicative ergodic theorem, which holds
under mild conditions. In addition, J is a
constant in space in this limit (otherwise its value varies in space),
and the Lyapunov exponents obtained from (A5) are then the same for
almost every value of x(0). Hence, one often
drops the dependence on the initial condition in (A5). Such exponents
are usually called global Lyapunov exponents.
