Exponential stability for nonautonomous functional differential equations with state-dependent delay

Abstract

The properties of stability of compact set K which is positively invariant for a semiflow (× W1,∞([-r,0],Rn),,R+) determined by a family of nonautonomous FDEs with state-dependent delay taking values in [0,r] are analyzed. The solutions of the variational equation through the orbits of K induce linear skew-product semiflows on the bundles K× W1,∞([-r,0],Rn) and K× C([-r,0],Rn). The coincidence of the upper-Lyapunov exponents for both semiflows is checked, and it is a fundamental tool to prove that the strictly negative character of this upper-Lyapunov exponent is equivalent to the exponential stability of K in × W1,∞([-r,0],Rn) and also to the exponential stability of this minimal set when the supremum norm is taken in W1,∞([-r,0],Rn). In particular, the existence of a uniformly exponentially stable solution of a uniformly almost periodic FDE ensures the existence of exponentially stable almost periodic solutions.