154 D. SALAMON, FLOER HOMOLOGY
Figure 3. A Morse-Smale gradient flow on the 2-torusFigure 4. A Morse-Smale gradient flow on the real projective planeExercise 1.18. Consider the function f : cpn --+JR given by
n
f([zo: z1: · ··:Zn])= Lilzjl^2.
j=lFind the critical points and compute their Morse indices. Compute the homology
groups of cpn. 0
1.4. Symplectic action
Let us now return to Hamiltonian differential equations in the monotone case.
In this section we show how the contractible 1-periodic solutions of (1) can be
interpreted as the critical points of the (circle valued) symplectic action functional
on the space CM of contractible loops in M. Here is how this works.
Throughout we think of a loop in M as a smooth map x : JR --+ M which
satisfies x(t + 1) = x(t) for t E R A tangent vector to .CM at such a loop x is
a vector field ~ along x. Explicitly, we think of ~ as a smooth map ~ : JR --+ TM
which satisfies ~(t) E Tx(t)M and ~(t + 1) = ~(t) fort ER We denote the space of
such vector fields by C^00 (JR/'1L,x*TM) = Tx.CM. For each 1-periodic Hamiltonian
Ht= Ht+l as above the loop space .CM carries a natural 1-form WH: T.CM--+ JR,
defined by
WH(x;~) = fo1
w(i:(t)-Xt(x(t)),~(t))dtfor~ E Tx.CM. The zeros of this 1-form are precisely the 1-periodic solutions of (1).