Introduction
The intent of this paper is to illustrate a new interpretation of how gravitation at the quantum scale can be modeled as an electronic circuit. This is done in the hopes that it will benefit engineers who wish to investigate the possibility of designing electro-gravitic devices. In so doing the attempt is made where possible to translate the fluent geometrical language of General Relativity into the less rigorous, but more intuitive language of electrical engineering. A basic understanding of Quantum Mechanics, vectors and the index notation of General Relativity are required. As well as a rudimentary knowledge of electronic circuit analysis.
The equivalent circuit for the transmission of probability waves through space-time is shown to be analogous to the transmission of waves through wave guides in quantum optics, or along transmission lines in electrodynamics. With this interpretation it is shown that the relationships between gravitation and electrodynamics compliment each other in the same fashion that the components of an electronic circuit compliment the sources of electrical energy.
What is presented here shows how the gravitational field can be modeled by variable component values in the equivalent circuit. In a linear circuit the component values do not depend on the strength of the sources. In reality however components such as inductors and capacitors, along with some integrated circuits do have non-linear properties that can also be added to this model in the future.