Image credit: Mario Livio.

mathematical model Graceli

Graceli theory of the universe floating waves. Curves waves floating like ripples in the tide .

Ie , we have fixed a curved universe , but ripples of waves that fluctuate , so that whenever it is measured curvature will always be different .

Floating Geometry Graceli .

[[Fg1âa + fg2âa +fg3âa +fg4âa ] n... + fgaâfo [cc] n...  . [far] + fgie+ + fgei + fgr + fgmf + fgfccâe] n.... / [c /t] 

+ n...  [ [[Fg1âa + fg2âa +fg3âa +fg4âa ] n... + fgaâfo [cc] n...  . [far] + fgie+ + fgei + fgr + fgmf + fgfccâe] n.... / [c /t]].

[ cc ] = Concave and convex .

Fgâa = Graceli of angles and accelerations of varying flows function.

Synchronous flows between quantum theory and quantum entanglement and quantum radiation and oscillation. And quantum bond between particles.

Theory and synchronic effect of progressivity Graceli .

There is a synchronic between intensity , quantity and scope, and the action of internal and external interactions of quantum flows , radiation, and interconnections between particles and their entanglements .

However , the timing does not follow in the same proportionality , which increases as the intensity of the internal physical and quantum processes by external effects have a larger progressive growth of radiation than the internal quantum flows .

Thus we have a sync related to natural processes of growth equivalent .

And we have a progressive Graceli effect relating to external actions on particles , metals , or even systems dilation.

This variation in timing and progressive Graceli also have the effect of expansion, the particle oscillations and vibrations , which is more visible in plasmas.

The internal entanglement also involves synchrony and Graceli progressivity effect.

Mathematical model Graceli .

Integral Graceli differential function .

It is one function that is both an integral of a set of physical processes , but each physical process has its own role for its functionality .

This we see in the radiation , and the expansion and vibration in the same oscillations of electrons , or even inflating balls and fade continuously .

Where we have the notion of the set of balls in processes and positions , but we also have the notion that each ball has every time their mathematical values ​​according to their physical variations , shapes and placements .

[[Fg1âa + fg2âa +fg3âa +fg4âa ] n... + fgaâfo [cc] n...  . [far] + fgie+ + fgei + fgr + fgmf + fgfccâe] n.... / [c /t] 

+ n...  [ [[Fg1âa + fg2âa +fg3âa +fg4âa ] n... + fgaâfo [cc] n...  . [far] + fgie+ + fgei + fgr + fgmf + fgfccâe] n.... / [c /t]].

[ cc ] = Concave and convex .

Fgâa = Graceli of angles and accelerations of varying flows function.

General mathematical function Graceli involving matrices , differential and integral calculus , geometry [ flat , curved , and discontinuous Graceli and oscillatory vibrations ] , and statistical and mathematical uncertainties 

[[Fg1âa + fg2âa +fg3âa +fg4âa ] n... + fgaâfo [cc] n...  . [far] + fgie+ + fgei + fgr + fgmf + fgfccâe] n.... / [c /t] 

+ n...  [ [[Fg1âa + fg2âa +fg3âa +fg4âa ] n... + fgaâfo [cc] n...  . [far] + fgie+ + fgei + fgr + fgmf + fgfccâe] n.... / [c /t]].

[ cc ] = Concave and convex .

Fgâa = Graceli of angles and accelerations of varying flows function.

Which can be between parts that interlock between dimensions of latitude , longitude , height , [ turns and swings , with movements and deformations ] .

Which can be interconnected by point systems represented by functions that represent points of motion are interconnected with other systems of points, and n ... points.

Per system or even in systems such as curved movements of the astes of DNA that are interconnected in curves.

Or even block parts where each part is in vibratory and curved movements .

Or even concave and convex portions of the balls. Like socks with balls cut parts up and down [ concave and convex ] .

And if interconnected by tiny parts , and infinitesimal variations that occur by the speed of light divided by time .

Thus we have the infinitesimal and infinitesimal , or even quantum statistical uncertainties .

And this function can be used in all individuals , and also biological and DNA variations.

Or even chemical or even interconnections in processes and isotopes decays . Or even the formation of chemical elements .

Graceli discontinuous integral differential geometry . And matrix geometry. And Graceli statistical geometry .

Author : Luiz Ancelmo Graceli .

[[Fg1âa + fg2âa +fg3âa +fg4âa ] n... + fgaâfo [cc] n...  . [far] + fgie+ + fgei + fgr + fgmf + fgfccâe] n.... / [c /t] 

+ n...  [ [[Fg1âa + fg2âa +fg3âa +fg4âa ] n... + fgaâfo [cc] n...  . [far] + fgie+ + fgei + fgr + fgmf + fgfccâe] n.... / [c /t]].

[ cc ] = Concave and convex .

Fgâa = Graceli of angles and accelerations of varying flows function.

Imagine balls up and down , rotating , and moving randomly in all directions .

Imagine many glowing spheres with vibrations of varying flows .

Imagine the photon radiation coming toward an observer. And others elsewhere . So we have a universe of private and relative to each observer forms .

Thus we have the full relativistic quantum geometry [ assembly ] and differential every body or part , or points in changes and vibrations and movements themselves .

With associated points of latitude and longitude and height and angles , and oscillatory flow variables .

As paired spheres or balls cut with alternating concave and convex part or triangles, or even expansion and flow oscillations.

Where an integral sum of the parts , with no repetitive variables in parts form . Thus we have the integral and differential discrete parts and constant changes .

Thus , we do not have a curve , but concave and convex curves , and with own oscillatory flows of each party , as electrons with oscillatory flows .

The integral determines the variation in the sum of differentials. That is, we have the same set of spheres or balls concave and convex , or even at varying flow of electrons have the full set of discrete ways, but each way is discontinuous in motion and acceleration of discontinuous flows , or we thus spread within the whole .

The matrix is formed in the movement of parts of the functions where in each time [ c / t ] we have links with other parts of the system functions and varied movements and accelerations own .

And the statistical geometry is based on the intensity , scope and amount of changes in oscillatory flows in relation to the speed of light by the time [ c / t ] .

Calculation Graceli comprehensive differential, integral , matrix and statistical .

Aims to be a single integral and differential function and matrix and statistics, and solve various problems , such as geometric shapes and oscillatory flows, pulses and oscillations , deformations of the sides , rotations, translations [ quedrimensional and three-dimensional shapes [ the speed of light by the time [ c / t ] , with displacement accelerations in space, where the geometry itself oscillatory graceli has this range. Interconnections and interactions , entanglements and chemical disintegration , discrete spherical shapes juxtaposed as one block parties curves and declines and increases of constant or irregular flows and variational by c / t .

[[Fg1â + fg2â +fg3â +fg4â ] n... + fgaâfo n...  . [far] + fgie+ + fgei + fgr + fgmf + fgfccâe] n.... / [c /t] 

+ n...  [ [[Fg1â + fg2â +fg3â +fg4â ] n... + fgaâfo n...  . [far] + fgie+ + fgei + fgr + fgmf + fgfccâe] n.... / [c /t]].