Eur. Phys. J. Plus (2018) 133: 278
https://doi.org/10.1140/epjp/i2018-12094-x

Regular Article

Programming Planck units from a virtual electron: a simulation hypothesis

Christchurch, New Zealand

^* e-mail: maclem@platoscode.com

Received: 22 March 2018
Accepted: 2 June 2018
Published online: 26 July 2018

Abstract

The simulation hypothesis proposes that all of reality is an artificial simulation. In this article I describe a simulation model that derives Planck level units as geometrical forms from a virtual (dimensionless) electron formula that is constructed from 2 unit-less mathematical constants; the fine structure constant and (, ). The mass, space, time, charge units are embedded in according to these ratios; (), giving mass , time , length , ampere . We can thus, for example, create as much mass M as we wish but with the proviso that we create an equivalent space L and time T to balance the above. The 5 SI units kg, m, s, A, K are derived from a single unit that also defines the relationships between the SI units: , , , , . To convert MLTA from the above , geometries to their respective SI Planck unit numerical values (and thus solve the dimensioned physical constants G, h, e, c, m_e, k_B) requires an additional 2-unit-dependent scalars. Results are consistent with CODATA 2014. The rationale for the virtual electron was derived using the sqrt of momentum P and a black-hole electron model as a function of magnetic-monopoles AL (ampere-meters) and time T.