.Itshak Gonigman-Scientist and inventor
.Theorist and researcher of the magnetic fields theory
The theory of
magnetic fields deals with planetary movement, waves, light and black holes. It
explains the movement of planets and their location.
The basic claim
of the magnetic fields theory is that every planet in the universe has a
magnetic field.
The planets have
constant contact. This contact is through the planets' magnetic fields, which
repel each-other.
Planets' magnetic fields pervade most of space.
The strength of the planets' magnetic fields is what determines the distance between planets.
The theory of magnetic fields explains the bending of space and light.
The location of
the fields' contact is explained through two rules:
1. Field Equality.
2. Magnetic Field
Equilibrium.
Field Equality
Field equality is the maximum distance between magnetic poles divided by two (for a field in a state of rest).
Magnetic Field
Equilibrium
The magnetic field equilibrium is the
most important basis for understanding and proving the theory of magnetic fields.
Since, according to the magnetic fields
theory, there is contact between the planets, and this contact is through the
planets' magnetic fields, there is crucial importance to the place of contact
between the magnetic fields, so as to maintain constant repulsion between the
fields.
When two or more magnetic fields touch
each-other in the "field equality" area, it is possible to rotate the
fields around themselves or encircle a field around another field without the
poles switching. This way, planets can rotate on their axes and encircle one
another, and the desired polarity will not change.
In this way, the repulsion between the
planets' magnetic fields is maintained.
Electromagnetic Waves
According to the magnetic fields theory, electromagnetic waves are a disturbance in the expanse of a magnetic field, and cannot exist or expand in a void, but only within a magnetic field.
Since there is contact between the
planets' magnetic fields, the disturbance in a magnetic field of one planet can
progress to the magnetic field of another planet, so as the electromagnetic
wave progresses. The disturbance can progress through a great number of fields
and fronts as long as there is contact between the fields.
According to the magnetic fields theory, an appearance in a number of places in
space simultaneously, can only exist through a disturbance in a fields'
expanse, and not through a single wave in a void.
Light
According to the magnetic fields theory,
light is a "phenomenon" of the magnetic field, and cannot exist or
expand in a void, neither as a particle nor as a wave. Light can only exist in
a magnetic field expanse.
Light curve - since, according to the
magnetic field theory, the magnetic field and light "are one", the
general geometry of light is equal to the geometry of the magnetic field, both
in the basic geometry of the magnetic field, as well as the bending of the
magnetic field's expanse by another field, or through different disturbances
(waves) in the magnetic field expanse.
Black Holes
The planets' magnetic fields fill most of
space, but not all of it. Because of the magnetic fields' geometry, the
overlapping between planets' magnetic fields is not perfect, and so there are
areas where there is no magnetic field. Those areas have a void. Since,
according to the magnetic fields theory, light cannot exist in a void, but only
in a magnetic field expanse, these areas are black holes.
Note: The magnetic fields in the figure are illustrated in two dimensions.
In fact, magnetic fields and black holes are three-dimensional.
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Magnetic Fields Theory and Gravitation
The magnetic fields theory divides
gravitation into two groups:
1. Universal gravitation.
2. Local gravitation.
Universal gravitation – relates to and
explains gravitation between planets. According to the magnetic fields theory,
the forces working between these planets are repulsion forces that activate
planetary magnetic fields on each-other, rather than gravitational forces. That
is, if the interplanetary active forces were gravitational, the planets would
gravitate until they would collide with each-other, as there would be no force
to restrict the distance between them.
The repulsion forces that activate the
planets' magnetic fields are those that determine the distance between planets
(dependent on their strength).
Curvature of space – the repulsion forces
of the magnetic fields influenced by the mass of planets causes curving of the
magnetic fields' expanse. Under these circumstances, the "field
equality" position changes in relation to the distance and mass.
Local gravitation – what we know as
gravity. It refers to a single planet, without
interaction with other planets.
interaction with other planets.
Note: The magnetic fields in the figure are illustrated in the "magnetic field equilibrium" plane.
In fact, these areas (field equality) change according to the magnetic fields' bending expanse.
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