Dynamics of singular complex analytic vector fields with essential singularities II

Abstract

The singular complex analytic vector fields X on the Riemann sphere Cz belonging to the family E(r,d)=\ X(z)=1P(z) eE(z)∂ ∂ z\ \ P, E∈C[z]\, where P is monic, deg(P)=r, deg(E)=d, r+d≥ 1, have a finite number of poles on the complex plane and an isolated essential singularity at infinity (for d≥ 1). Our aim is to describe geometrically X, particularly the singularity at infinity. We use the natural one to one correspondence between X, a global singular analytic distinguished parameter X(z)=∫z P(ζ) e-E(ζ)dζ, and the Riemann surface RX of this distinguished parameter. We introduce (r,d)-configuration trees which are weighted directed rooted trees. An (r,d)-configuration tree completely encodes the Riemann surface RX and the singular flat metric associated on RX. The (r,d)-configuration trees provide "parameters" for the complex manifold E(r,d), which give explicit geometrical and dynamical information; a valuable tool for the analytic description of X∈ E(r,d). Furthermore, given X, the phase portrait of the associated real vector field Re(X) on the Riemann sphere is decomposed into Re(X)-invariant components: half planes and finite height strips. The germ of X at infinity is described as a combinatorial word (consisting of hyperbolic, elliptic, parabolic and entire angular sectors having the point at infinity of Cz as center). The structural stability, under perturbation in E(r,d), of the phase portrait of Re(X) is characterized by using the (r,d)-configuration trees. We provide explicit conditions, in terms of r and d, as to when the number of topologically equivalent phase portraits of Re(X) is unbounded.