Local Availability of mathematics and number scaling: Effects on quantum physics

Abstract

Local availability of mathematics and number scaling provide an approach to a coherent theory of physics and mathematics. Local availability of mathematics assigns separate mathematical universes, Ux, to each space time point, x. The mathematics available to an observer, Ox, at x is contained in Ux. Number scaling is based on extending the choice freedom of vector space bases in gauge theories to choice freedom of underlying number systems. Scaling arises in the description, in Ux, of mathematical systems in Uy. If ay or y is a number or a quantum state in Uy, then the corresponding number or state in Ux is ry,xax or ry,xx. Here ax and x are the same number and state in Ux as ay and y are in Uy. If y=x+μdx is a neighbor point of x, then the scaling factor is ry,x=(A(x)·μdx) where A is a vector field, assumed here to be the gradient of a scalar field. The effects of scaling and local availability of mathematics on quantum theory show that scaling has two components, external and internal. External scaling is shown above for ay and y. Internal scaling occurs in expressions with integrals or derivatives over space or space time. An example is the replacement of the position expectation value, ∫*(y)y(y)dy, by ∫xry,x*x(yx)yxx(yx)dyx. This is an integral in Ux. The good agreement between quantum theory and experiment shows that scaling is negligible in a space region, L, in which experiments and calculations can be done, and results compared. L includes the solar system, but the speed of light limits the size of L to a few light years. Outside of L, at cosmological distances, the limits on scaling are not present.