| Popis: |
We introduce a natural, mathematically consistent definition of the essential (highest possible) regularity of an affine connection -- a geometric property independent of atlas -- together with a checkable necessary and sufficient condition for determining whether connections are at their essential regularity. This condition is based on the relative regularity between the connection and its Riemann curvature. Based on this, we prove that authors' theory of the RT-equations provides a computable procedure for constructing coordinate transformations which simultaneously lift connection and curvature components to essential regularity, and lift the atlas of coordinate charts to the regularity required to preserve the essential regularity of the connection. This provides a definitive theory for determining whether or not singularities in a geometry are essential or removable by coordinate transformation, together with an explicit procedure for lifting removable singularities to their essential regularity, both locally and globally. The theory applies to general affine connections with components in $L^p$, $p>n$, which naturally includes shock wave singularities in General Relativity as well as continuous metrics with infinite gradients, (both obstacles to numerical simulation), but not yet singularities at the lower regularity $p\leq n$ associated with discontinuous metric components, for example, the event horizon of a black hole. |
