Deformation principle as foundation of physical geometry and its application to space - time geometry

Deformation principle as foundation of physical geometry and its application to space-time geometry. Abstract Physical geometry studies mutual disposition of geometrical objects and points in space, or space-time, which is described by the distance function d, or by the world function σ = d 2 /2. One suggests a new general method of the physical geometry construction. The proper Euclidean geometry is described in terms of its world function σ E. Any physical geometry G is obtained from the Euclidean geometry as a result of replacement of the Euclidean world function σ E by the world function σ of G. This method is very simple and effective. It introduces a new geometric property: nondegeneracy of geometry. Using this method, one can construct deterministic space-time geometries with primordially stochastic motion of free particles and geometrized particle mass. Such a space-time geometry defined properly (with quantum constant as an attribute of geometry) allows one to explain quantum effects as a result of the statistical description of the stochastic particle motion (without a use of quantum principles).