Updated in
2564 : on
2020 :
6 :
16 : **Eccentric Circles**
;

circle; link; ring; wheel; Radical915;

circle; Radical777;

circuit; circumference; lap; Radical510;

ratio of defined circle's circumference to its diameter (approx. math constant ( π)) is 3.14159 ... ; Radical300;

circumpolar;

Tail Alike Momentum (Origin of Disc, Origin of Fish, Origin of (Oval & Sperm))
__2,3 dimensional__ toward (along with) ... ;
because of lights stretch;
Remark: on ZCS (yellow as
forefront), And Then, yellow disappears naturally IFF ({E3, E3, E3} or silver)
as background; also see:
Schematic
Dimensional;

A basic, prior to a pressure _machine _engine, a gravity machine, ... ; IFF after understanding all eccentric circles, and then try to understand sticks, because hole and stick coexists;

arc; Also see: Monbusho level knowledge enhancement 3, idea ♯ 261, arc defines gravity spot's sizes ... ;

Blue dots are centers, and diff of
2 circles is called
eccentric circles, without
**Time**; IFF __2 circles__ were __2 spin
strings__,
and then
M
Theory's string interactions begin ... ;

IFF (i.e. cluster) ... ;

For basic understanding of potential diff, 1st to understand conductors in diff potential, 2nd to understand eccentric electromagnetic, ... ;

For basic understanding of potential diff, in ACT1 sea
level, __locations of temperature__ variation by using static resistors, __
locations of
temperature__ may vary with environmental conditions such as very cold
environment with dark room condition, normal room condition, pressured, gas vs.
vacuum, ... ;

__ In polar plane__,

__for each__ circle's outward distance along __with
each allocated radius__ can be calculated as:

θ r^{2} = a; Clockwise r = a θ
,
and notice that spiral **1**
H2O
[A drop of water
] resists to
G gravitational waves [graviton and anti-graviton] without square in
ACT 1 stage was, and notice
that G gravitons have been pushed from **3**
planets;
Think that
pairs of sticks, but 1 stick was hidden, logically
similar to: Rejoining interaction, and/or, Splitting interaction,
in strings, in
__M Theory__,

Rejoining interaction, where fuzzy set { ...
of the Turtle Egg may become
__Turtle and Turtle Egg__;

Splitting interaction, where fuzzy set { ...
of the Turtle Egg may become a male turtle, therefore ... ;

If someone asks __spiral__, 1st to think of is that __
pairs of sticks__, 2nd to think of is that 1 stick was hidden, ... ;

For Monbusho
level developers only: Apply A, B,
C,
D, E, F, ... numbers' depth
as power of radius as r^{1}, r^{2},
r^{3},
r^{4}, ... in ACT 2 stage spiral G algorithms, 3, ... ; Also develop:
spiral G waves prediction to be female human beings, male human beings, ... ,
after embryo fertilization stage, ... ;

hoshajono
Radial, diverging lines from center (dot, point, spot)
... ;

hoshajono
Radial, radii of 1 circle ... ;
Also see: Optics;

__ In 2D plane__,
do your own curve algorithm by testing 2 layers
approach such as
StrophoiDAL curve; To do so, point A must be allocated in
ACT 2, point B must be
allocated in ACT 1, ground station must be allocated as
water point, and ... ; For Monbusho level developers
only:
Time.Space.Action
at time t, space of Y axis, do
simulation the actions of

__ In 3D plane__, simulate the 6 parameterized
fuzzy set with distributions ...

IFF polarity calculation with time stamps available, and then do prototype level simulation to deploy 500+ kilo meter per hour fastest train ... ; IFF particle heterodyned indexes are available, and then do prototype level simulation to deploy lightening fast pressure machine engine ... ;

IFF cycloid sticks
, at 1
time line X, characteristic of sticks is similar to
y = ln x; Basically, to create a cycloid, the circle must roll
on 1 straight line i.e. 1 time line X, AND
a marked point must be on the circumference of the circle;
4 sticks are shown because at 1 natural time,
4 planet prediction
outer condition ... ; Develop 2,3 vectors,
cycloid sticks pair .GIF, each stroke and each meaning
somehow represents very meaningful ... ;
__circle to find cycloid sticks .GIF__, non dimensional circle ... ;
A cycloid ,
the circle's rolling direction is in maroon color,
a marked point is in gray color,
the circle's center is in blue color,
resembling circular "a cycloid" is in cyan color, 2 point
distance between __the circle's
center__ and __1 time line X __is parallel to each other; In
M
theory, strings as sticks, determining whether
rejoining interaction OR splitting
interaction can be further studied ... , and then time to develop
2,3
vectors ... ;

IFF cyclotron accelerates, spiral path's vector changes into outward direction as:

+ electrode, - electrode, gap between ... , ion, magnetic field, particle number, vacuum chamber, ...

IFF EPI*, e p i -cycle
is in
maroon colored; __Maroon colored small cycle__
must be a small cycle; The __Maroon colored small
cycle__'s center must move along with circumference of __
Maroon colored big cycle__; While moving, __
Maroon colored big cycle__ must not vary;
Remark: in this image, to ease visualizing, and understanding of e p i -cycle, __
Maroon colored small cycle__ is not small enough,
and its center is not on the the circumference of the __
Maroon colored big cycle__; At@
time t, in X Y plane, above image's __Maroon colored
small cycle__ is in +x, +y coordinate; WHEN generating a curve to
blue colored cycle, e p i cycloid blue curve happens;
WHEN generating a curve to red colored cycle, ... ;
WHEN generating a curve to teal colored cycle, ...
; WHEN generating a curve to green colored cycle,
... ; Epi-cycloid curves are also known as hypocycloid curves;
To draw, or
generate a curve by epi*, x = ( i + j ) cosine θ - j cosine (( i + j )
θ/j); y = ( i + j ) sine θ - j sine (( i + j ) θ/j);
In English language, since 1350, epicycle has been defined; In medical, epidemic
might be derived from epi-cycles of spreading ... ; Also see:
Homological
homotopy
;

**Circle usages**:
22/7,
chord,
circumference,
diameter,
radius, secant, sector,
segment, tangent, ... ;
Circumference of circle;

Sphere, spherical ball, solid geometric round body's (**r**adius
**r**^{2} = x^{2} + y^{2} + z^{2}) dimensions
vary WHEN __displacement of length__ in Time becomes in dimension, also see:
__dimension vs. symmetry__;
Worm hole;

**Curvature usages**: for
calculating curvature's space at any given point, by drawing
circle
at the point, and then Perform
♯ Calculation 285
(area) ;
also see: Pg. 338, Hyperspace, Michio
Kaku, 1994;

^{_ }IFF
Form (curvature
0) AND ACT1,
(
area) = 22/7
(radius *
R)
;

^{_ }IFF
Form (curvature +)
AND ACT1,
(
area) < 22/7
(radius *
R)
;

^{_ }IFF
Form (curvature -)
AND ACT1,
(
area) > 22/7
(radius *
R)
;

^{_ }IFF
Form (curvature
0) AND ACT2,
(
area) = 108
(
* R);

^{_ }IFF
Form (curvature +)
AND ACT2,
(
area)
< 108
(
*
R);

^{_ }IFF
Form (curvature -)
AND ACT2,
(
area) > 108
(
*
R);

^{_ }IFF
Form (curvature
0) AND ACT3,
(
(
area)
= 108
( *
));

^{_ }IFF
Form (curvature +) AND ACT3,
(
(
area)
< 108
( *
));

^{_ }IFF
Form (curvature -) AND ACT3,
(
(
area)
> 108
(
*
));

Remark:
radius might not be the same, in this DOMAIN 's imaginary hyperspace craft ..., in
very very very far away ... , in ACT3 stage ... ; carefully and cleverly notice
that not using neither r^{2} nor radius * radius;

pinoatai Value of Pi ; Also see: Pi;

**
Semicircle**:
Radius should be the same.

Think that naturally we are in egg alike
environment doko WHERE either diameter or radius
are not the same; If you design hyperspace device in 24mm Natural Time, and then
you dispatch the device to ACT3 stage hyperspace, you might not be able to do
Parallel Time SYNC, because you designed in egg alike environment
doko WHERE either diameter or radius are not the same; This might be a
reason (approx.
44+ years of R&D to solve Parallel Time SYNC), this DOMAIN 's
imaginary spacecrafts could not SYNC
Parallel Time; Also see:
1mm Hole By 24mm Natural Time (e.g. ACT1, ACT2, ACT3); Think that if we are static and
then __2,3 dimensional__ must be
dynamic,
vice versa, and
then try again, good luck in your space program ... ;
IFF
electronic,
semicircle look like half (i.e. approx. max)
capacitance concerning
eccentric circles
in
M
Theory ... ;

in
ACT2 imaginary hyper space, IFF 6 of
semicircles are placed within a ring e.g. __2,3 dimensional__ momentum, (360
= 6 * 60) omni
directional may begin;
And Then, using (60) only would be one of the wormhole
(45, 60, 72)
parameters
of this DOMAIN ...
;
Remark: if our earth, pour water to fill stainless steel bowl, then place the
bowl inside a freezer box, then study HOW 60 degree forms naturally; then study
60 degree wormhole length as its parameter naturally; Hint: spiral, spiral, ...
;

**Sphere usages**: Altitude,
Azimuth, North vs. South, Time . Space 1 i.e. planet 1, Time . Space 2 i.e.
planet 2, Zenith vs. Nadir, ... ;
__Either in a hyper plane 1,
or in a hyper plane 2__, if a planet's
North and South have been set, and then Zenith and Nadir can be considered as
East and West alike.

Azimuth has been defined as
__angular distance either from North,
or from South__, therefore this DOMAIN 's imaginary hyperspace
crafts' i.e. Fuzzy S V M
aspect ratio can prompt 2D as:

the distance between point P1 and point P2 in hyperplane 1 can be calculated

for each Time . Space 1, 2D_array_of_azimuth_1[P1, P2], and

the distance between point P3 and point P4 in hyper plane 2 can be calculated

for each Time . Space 2, 2D_array_of_azimuth_2[P3, P4].

Pitfall reminder: if Zenith angle is calculated for altitude, it might be wrong, if Nadir angle is calculated for altitude, it might also be wrong. Above logic can be used in military such as anti-air-to-air missile, anti air-to-ground missile, anti ground-to-air missile, star war tech and gaming, under water anti missile, ... ;

**Sun in eccentric distance**

A part of DEE, approximation of visible Sun in eccentric ... ; Also see: DEE;

Sun's 1D distance by its size may vary, along with location on Earth; If X axis is Earth, and then Y axis should be in 2*6 dimensional ... ; 310x108pixel;

Also see:
artificial eyeballs, and notice that dark energy [also see:
DEE] is in a segment,
and notice that 2,3 dimensional array, ... ; Concerning __artificial eyeball__,
also see:
Eye
seeing system, and its 3 layers as
static eccentric;

**
108
configuration, ACT3 stage**

Before reading 108
configuration, contents of:
Abhidhamma
so that 6 can be understood, Union of Myanmar's 2500+ years old
4 planets prediction so that 4
vectors' relation to gravitational lunar time
2*7 can be understood, __JUN
time 2*5
and Lunar time 2*7__ makes
4PP + JUN = 6 so that __full
moon day and no moon day__ coexistence versus neither __full moon day nor no
moon day__ configuration can be understood, after understanding ACT1 and ACT2,
__3 * 3 * 3 * 3, and 10, 7, 10, can be 108__ ... after understanding
heat vs. light, also see:
c108.GIF; and then develop
108 in ACT3 stage, because ACT1
stage 22 must be shifted by replacing 108 i.e. from 2,3,7,10,22,23,24
to 2,3,7,10,24,108,... ; Remark:
22/7 ACT1 stage information is no longer valid in ACT2 and ACT3 stage ... ;

IFF Cursor,
a.k.a. MOUSE:

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〩〩〩 〩〩〩 〩〩〩〩
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;

IFF epi*
circles become sphere, also see:
Fully_distributed_topology;

IFF Fully_distributed_topology
AND
SYN
Parallel Time,
also see:
numerological dimensional Heavenly Wheel Topology;

IFF variable (heat) electricity ... ;

IFF VVEL engine, Control cam (eccentric cam); Input Cam (eccentric cam);

Gravity Machine ... ; Rectangles are designed for detail locations of gravity spots (e.g. 2 gravity spot, 4 gravity spot, 8 gravity spot, ... ) for space elevating ... ; Circles are designed for detail locations of directional gravity (e.g. contour map, distance, ... ); IFF modulation of DEE, e.g. WHILE kuru kuru ( measure gravity spots) Also see: ..\\MD\Measurement however those circles should not be the same, because Complex Ions vary upon 4PP's spin speeds ... ;

In the early 21st century, Gravity Dimension Computer is designed and developed by Rakhine WHO practice 103 ethical codes for thousands of years ... ;

IFF multi time lines, also see: Meta;

__
Zero Curvature Surface__ :
for
each
ZCS, using :
e.g.
((
c/s (coefficient √FM cycle per second)),
(
Hz (coefficient √FM Hertz))) : e.g. input noise, noise floor, noise on a
surface, ... ;