Abstract: | We carry out the linear stability analysis of a polygonal ring configuration of N point vortices, called an N-ring, along the line of latitude (theta _0) on a torus with the aspect ratio (alpha ). Deriving a criterion for the stability depending on the parameters N, (theta _0) and (alpha ), we reveal how the aspect ratio (alpha ) contributes to the stability of the N-ring. While the N-ring necessarily becomes unstable when N is sufficiently large for fixed (alpha ), the stability is closely associated with the geometric property of the torus for variable (alpha ); for low aspect ratio (alpha sim 1), (N=7) is a critical number determining the stability of the N-ring when it is located along a certain range of latitudes, which is an analogous result to those in a plane and on a sphere. On the other hand, the stability is determined by the sign of curvature for high aspect ratio (alpha gg 1). That is to say, the N-ring is neutrally stable if it is located on the inner side of the toroidal surface with a negative curvature, while the N-ring on its outer side with a positive curvature is unstable. Furthermore, based on the linear stability analysis, we describe nonlinear evolution of the N-ring when it becomes unstable. It is difficult to deal with this problem, since the evolution equation of the N point vortices is formulated as a Hamiltonian system with N degrees of freedom, which is in general non-integrable. Thus, we reduce the Hamiltonian system to a simple integrable system by introducing a cyclic symmetry. Owing to this reduction, we successfully find some periodic orbits in the reduced system, whose local bifurcations and global transitions for variable (alpha ) are characterized in terms of the fundamental group of the torus. |