Plausibility: Control of the effect of Gravity in two sentences (theory and method)

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Golden Orthogonal Torus Knots

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Investigations in solid geometry

3-Phase, orthogonal, Fibonacci (13-8) torus knots (Full resolution, with POVRay code) available. Significance of the knot's orthogonality between inner and outer conductor loops is that orthogonal conductors do not magnetically interact. This allows the inner loops to have harmonics not associated, magnetically, with the outer torus knot conductor loops. In this way, the coil, as a load on an oscillator, can host resonant structures that contain a base frequency, and chirp frequencies. The oscillator is operating in the low impedance current domain, like an induction furnace driver-coil by similarity.


It was found in the Summer of 2013 that —
The relative angle between the inner and outer torus knot loops is orthogonal for a Fibonacci torus knot WHEN
  1. The ratio of the torus hole radius is four powers of the Golden Ratio (Phi 4) smaller than the torus major radius, and
  2. The knot ratio of the torus knot, the ratio of the loops to twists of the knot entanglement, is the quotient of neighboring numbers in the Fibonacci Sequence.
Note: the ratio of Phi4 is the torus major radius over the radius of the hole, NOT the torus minor radius. Major / hole radii ratio of Phi4.
Due to this geometry with orthogonality between conductors at the torus plane, the torus loop crossing the torus plane at the outer diameter engaged in magnetic resonance will not be able to experience the magnetic field of a loop crossing the torus plane at the torus hole, as inductive coupling requires some parallel component between conductors to support some degree of inductive coupling. [Except for usual and customary eddy currents.]
This creates a gradient of electromagnetic reactance within the cross-section volume of the torus ring, forming a topology of the inductance qualities divided into hemispheres above and below the torus plane. The contributed reactive component of the torus plane is resistive, for the golden orthogonal knot.
By the way —The RF resonant condition of Eugene Podkletnov's rotating superconducting ceramic disk created a dipolar EM oscillation, alternating above and below the plane of the disk.[Citation needed]
See category Gravitation.
The moving grey bars are the shadows of the center knot. The light source is at the center-point of the torus-form of the torus knot, on the axis in the middle. The larger gray bars are shadows of the inner torus knot loops, while the thinner, orthogonal gray bars are shadows of the knot's outer loops. The wide bars appear larger because they are closer to the light sourced on center point. This image is created with POVRay raytracing program, and represents mathematically correct parameters.