In mechanical structures, the holes are frequently designed at the isotropic points where the principal stresses are equal. In this paper, a newly developed min-max scanning method is applied to determine the whole field principal stress direction of a photoelastic model by experiment, and the isotropic points on the model are further extracted automatically by a self-designed program. The von-Mises stress distributions around holes: (1) drilled at the determined isotropic point and near-by locations, and (2) having various sizes drilled at the determined isotropic point location are obtained and compared by finite element analysis. The suitability of drilling a hole at the determined isotropic point is investigated. Test results from a three-point loaded disk show that the maximum von-Mises stress around the hole drilled at the determined isotropic point is less than that around the near-by locations. As the size of the hole drilled at the determined isotropic point is decreased, the maximum von-Mises stress around the hole is also decreased. Therefore the isotropic point location determined by using the digital photoelastic approach can be effectively utilized for optimal design of holes in structures.