Principal fiber bundle description of number scaling for scalars and vectors:  application to gauge theory

Paul Benioff

doi:10.1117/12.2176080

21 May 2015 Principal fiber bundle description of number scaling for scalars and vectors: application to gauge theory

Paul Benioff

Proceedings Volume 9500, Quantum Information and Computation XIII; 95000X (2015) https://doi.org/10.1117/12.2176080
Event: SPIE Sensing Technology + Applications, 2015, Baltimore, MD, United States

Abstract

The purpose of this paper is to put the description of number scaling and its effects on physics and geometry on a firmer foundation, and to make it more understandable. A main point is that two different concepts, number and number value are combined in the usual representations of number structures. This is valid as long as just one structure of each number type is being considered. It is not valid when different structures of each number type are being considered. Elements of base sets of number structures, considered by themselves, have no meaning. They acquire meaning or value as elements of a number structure. Fiber bundles over a space or space time manifold, M, are described. The fiber consists of a collection of many real or complex number structures and vector space structures. The structures are parameterized by a real or complex scaling factor, s. A vector space at a fiber level, s, has, as scalars, real or complex number structures at the same level. Connections are described that relate scalar and vector space structures at both neighbor M locations and at neighbor scaling levels. Scalar and vector structure valued fields are described and covariant derivatives of these fields are obtained. Two complex vector fields, each with one real and one imaginary field, appear, with one complex field associated with positions in M and the other with position dependent scaling factors. A derivation of the covariant derivative for scalar and vector valued fields gives the same vector fields. The derivation shows that the complex vector field associated with scaling fiber levels is the gradient of a complex scalar field. Use of these results in gauge theory shows that the imaginary part of the vector field associated with M positions acts like the electromagnetic field. The physical relevance of the other three fields, if any, is not known.

Citation Download Citation

Paul Benioff "Principal fiber bundle description of number scaling for scalars and vectors: application to gauge theory", Proc. SPIE 9500, Quantum Information and Computation XIII, 95000X (21 May 2015); https://doi.org/10.1117/12.2176080

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