LECTURE 1. REDUCTION THEORY 341Theorem 1.2. (Euler-Poincare reduction-part 2.) Hamilton's principle for
L on G is equivalent to the reduced variational principle:86red = 0 J l(~(t))dt = 0
for variations of the form8~ = ( + [~, (]
for some curve ( in g vanishing at the endpoints.Here, 6red is the reduced action, the integral of the reduced Lagrangian l
along curves in g. Now it is easy to work out the corresponding equations as one
does in the calculus of variations and this yields a proof of part 1 of the Euler-
Poincare reduction.History and literature. Looking back with modern notation, it is fair to say
that Lagrange [1788] realized the importance of relating the dynamics on TG to
the dynamics on g and devoted much of Volume II of Mecanique Analytique to it
for the case of the rotation group 80(3). The Euler-Poincare equations for gen-
eral Lie algebras were first written down by Poincare [190lb] who realized that
they were fundamental equations in fluid and solid mechanics, as is apparent from
Poincare [1910]. However, it seems that Poincare did not take a variational point of
view. Arnold [1966a] developed the geometry and mechanics of the Euler-Poincare
equations, including stability theory. In fluid mechanics, the constraints on the
variations appearing in reduced variational principles go under the name "Lin con-
straints" and this subject has a large and complex literature. The general theorem
presented here is due to Marsden and Scheurle [1993b] and, for general Lie groups,
to Bloch, Krishnaprasad, Marsden and Ratiu [1996]. The Euler-Poincare equations
in a general context including advected parameters are developed in Holm, Mars-
den and Ratiu [1998a], linked to semidirect product reduction theory and applied
to continuum mechanics.
Example 1. The first example is the rigid body, free to spin about its center ofmass. Here we take G = 80(3) so that g ~ JR.^3 with Lie algebra bracket given
by the cross product. The Lagrangian L is the total kinetic energy. The reduced
Lagrangian l : JR.^3 _, JR. is a quadratic function of~, which in this case is called the
body angular velocity and is written D. Thus,l(D) = ~ (D, ID)for a symmetric positive definite matrix I , the moment of inertia tensor. The
Euler-Poincare equations (or the rigid body equations) are readily seen to beID= (ID) x D.
The reader may, as an exercise, check directly that these equations come from
the reduced variational principle. Since l is quadratic, L is the kinetic energy of
a Riemannian metric on 80(3), so the Euler-Lagrange equations on 80(3) are the
geodesic equations.
Example 2. For the motion of an ideal fluid, we choose G = Diffv 0 1(B), the
group of volume preserving diffeomorphisms of a given domain B , a Riemannian
manifold in which the fluid moves. The Lagrangian L is the total fluid kinetic