ON NONLINEAR DELAY-DIFFERENTIAL EQUATIONS

We examine qualitative behaviour of delay differential equations of th e form y'(t) = h(y(t), y(qt)), y(0) = y0, where h is a given function and q > 0. We commence by investigating existence of periodic solution s in the case of h(u, v) = f(u) + p(v) , where f is an analytic functi on and p a polynomial. In that case we prove that, unless q is a ratio nal number of a fairly simple form, no nonconstant periodic solutions exist. In particular, in the special case when f is a linear function, we rule out periodicity except for the case when q = 1/deg p. If, in addition, p is a quadratic or a quartic, we show that this result is t he best possible and that a nonconstant periodic solution exists for q = 1/2 or 1/4, respectively. Provided that g is a bivariate polynomial , we investigate solutions of the delay differential equation by expan ding them into Dirichlet series. Coefficients and arguments of these s eries are derived by means of a recurrence relation and their index se t is isomorphic to a subset of planar graphs. Convergence results for these Dirichlet series rely heavily upon the derivation of generating functions of such graphs, counted with respect to certain recursively- defined functionals. We prove existence and convergence of Dirichlet s eries under different general conditions, thereby deducing much useful information about global behaviour of the solution.