Polarized protons have never been accelerated to more than about 25 GeV. To achieve polarized proton beams in RHIC (250 GeV), HERA (820 GeV), and the TEVATRON (900 GeV), ideas and techniques new to accelerator physics are needed. In this publication we will stress an important aspect of very high energy polarized proton beams, namely the fact that the equilibrium polarization direction can vary substantially across the beam in the interaction region of a high energy experiment when no countermeasure is taken. Such a divergence of the polarization direction would not only diminish the average polarization available to the particle physics experiment, but it would also make the polarization involved in each collision analyzed in a detector strongly dependent on the phase space position of the interacting particle. In order to analyze and compensate this effect, methods for computing the equilibrium polarization direction are needed. In this paper we introduce the method of stroboscopic averaging, which computes this direction in a very efficient way. Since only tracking data is needed, our method can be implemented easily in existing spin tracking programs. Severla examples demonstrate the importance of the spin divergence and the applicability of stroboscopic avgeraging. (orig.)20 refs.SIGLEAvailable from TIB Hannover: RA 2999(96-078) / FIZ - Fachinformationszzentrum Karlsruhe / TIB - Technische InformationsbibliothekDEGerman