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(C) Copyright 6/24/2009 Justin Coslor in regard to Ohm_Law_in_SSG.jpg
When the diameter gets bigger from an increase in resistance, the
periods get closer together from a decrease in voltage, and likewise
when the voltage increases from a smaller (perpendicular) exponent of
representation of Pi (Inductance, Amperage, the ratio of the distance
around to the distance across in terms of periods and radians (curved
diameters)) remains constant. Even exponents spiral loop in a closed
circuit, and when that circle torroidal spiral is broken then the
exponent becomes odd and a rather more complex helix-like spiral is
formed that whose timeline axis actually eventually curves around to
make a higher even exponent as a more complex torroidal spiral like a
complex higher dimensional spiral.
The unit circle is the front view and the sine waveform around
the timeline the is a perpendicular exponent top view (The of the XYZ
spiral), and the cosine of the waveform around the timeline is a
perpendicular side view of the X axis, and put X, Y, Z (where Z is
the timeline) coordinates together and you have an orthogonal three
dimensional version of a helix-like spiral. It can be simplified by
just calling it time^3 or T^3 as it is a three dimensional spiral
(Time, X, and Y) so it has an odd exponent because the number three
(in the exponent slot) is an odd number. This is scalable to T^N from
torroidal spiral to helix-like spiral as spirals around spirals
around spirals, and so on as exponents represent the number of
perpendicular dimensions. Fractional exponents represent prime and
composite fractions of one rotation at T^N such as Circumference^(1/3) =
the cube root of the circumference, such as an arc curve that is equal
to one third of one rotation at T^N.
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