Scope Graceli functions and types of infinitesimal Graceli .

The infinitesimal graceli are divided into five basic types .


The Graceli functions are more geometric , matrix , statistical , infinitesimal , and variables for each proposed item .

Imagine the delay and varied each electron oscillation when dilations . We each point ranging as ocean waves seen from above.

What we have are infinite points with infinite rise and fall , or flow and ripple delay .

That is, an infinitesimal physical represented by an infinitesimal mathematics.


One of the key points of graceli functions are flows relative ac / t present in the quantum and quantum statistics , or uncertainty and negligible interactions between particles and energy systems . Another point is to represent images as if they were alive with varied and tiny wrists , or even movements of varied waves. So we have a new mechanic and living geometry , and matrices representing movements and oscillations and rotations .

Ie , flows are mobile like a sea of ​​waves up and down. And with changes over space and time and intensity. And reach.


The infinitesimal graceli are divided into five basic types .

1 - The series of infinitesimal - part divided by the whole.

2 - X / log x n ...

3 - Endless parties in a moment by c / t [ speed of light by the time ] .

4 - And endless connections and interactions between fgx + fgn ...

5 - FGX + fgn ... + [ X / log x ] n ...



Particularities of Graceli functions .

One of the particularities of Graceli functions is that the same function can have only one result, a negligible result [ x / n lox ... ] two several or infinite results when divided by the speed of light divided by time , as in an explosion or radiation and quantum interaction, and that brings us to the tiny world of infinitesimal uncertainties . Or even odds [ statistics ] results . And for n-dimensional geometries .

Same or be relativistic when much reference or coordinates in many or even n- dimensions .

While the differential and integral calculus has the function of movements by time , since the functions Graceli has the function of coverage being in all the particulars . And be comprehensive in all physical and much of mathematics.





The scope of the universal function Graceli .

The universal function Graceli replace various functions within mathematics . Ie , is a unifying function.


The universal functions Graceli has the scope to address all types of matrices , statistical functions , calculation of interactions and negligible uncertainties Graceli , and quantum statistical mechanics , and also solve problems of calculus of functions [ differential and integral ] . And when divided by the speed of light by the time the function has the tiny quantum world and its phenomena and interactions .


Graceli Function Connections intercalated between concave and convex angles .
And functions for intensity of flows of energy and quantum interactions , and uncertainties and probabilities .

Fgg Fgarâ = [ cc ] + fgbrâ [ cc ] + fgxrâ n ... [ cc ] + [ x / log x ... n ] + r =



Connections interspersed between flows and intensities or power surge or pulses and particles .

Fgg Fgarâf + = + fgbrâf fgxrâf n ... + [ Ief / ief log ... n ] + r =

F = energy flows .
Ief = energy intensity and energy flows .




Graceli function of interlocking chains .

Infinitesimal differential function on each point to infinity within each point .

Fx / fy + [ x / n log x ... ] =


Infinitesimal function connections points between systems in proper motions more spin .
Fgg Fgarâ + = + fgbrâ [ x / log x ... n ] + r =

This can be visualized in a DNA strand with kinking of arms and the connections between the arms of the DNA strands . And with these kinking angle .


Fgg Fgarâ + = + fgbrâ fgxrâ n ... + [ X / log x ... n ] + r =

With several chains of linked DNA and rotational movement .


Fgg Fgarâ + = + fgbrâ fgxrâ n ... [ x / log ... xn ] r + ... + n r = related to various benchmarks , ie relativistic .

This system also has the coordinates movements and deformations , ie , it is not only in relation to time .















Calculation Graceli for minute and multiple results .


Fgx . q . [ adiad ] .

Fgx = graceli function of x .
Quantity . reach. Distance , intensity , acceleration and deceleration .
Imagine the explosion of dynamite in a quarry , or even a balloon when very warm.

The same goes for quantum oscillation streams , or even fluctuating gas or electrons when overheated , or streams of vibrations of electrons . Or even interconnections between quantum interactions , quantum or radiation, or even indeterminism [ uncertainty ] quantum .


Fgx . q . [ adiad ] . [ x / logx ] n ...

For infinitesimal quantum indeterminacy and uncertainty. Or even a geometry and quantum statistics .





Calculation Graceli statistical differential to infinitesimal and quantum and graceli sequential numbers variations .

Fgx [ x / logx ... n ] + FGY [ y / n ... logy ] + fgn ... [ pi + r + â / log ... n ] n ...

Each fg is a function with which interconnect points with other points of other functions .

Integral Calculus Graceli variable statistics .
Fgx [ x / logx ... n ] / [ ct ] + FGY [ y / n ... logy ] / [ ct ] + fgn ... [ pi + r + â / log ... n ] n ... / [ T c ] [ speed of light by the time ] .


. Integral Calculus Graceli variable statistics .
Fgx [ x / logx n ... ] â + / [ ct ] + FGY [ y / n logy ... ] / â + [ ct ] + fgn ... [ pi + r + â / log ... n ] n ... â + / [ t c ] [ speed of light by the time ] .

Taking into account the connection between points, while each system function is represented by motion . With this we have a quantum and statistical variable super system.

With streams and even series of sequences of numbers . where each point on each system in motion represented by exponential functions have flows .
 And that varies in intensity and reach for time and energy, or even c .


Ie we have the ways connections , and we have the exponential flows at each point .


Interconnections of discontinuous points with exponential variable points , points for points, and angular curves between points , and in relation to the speed of light by time.

Fgx + + FGY fgn ... [ â ~ ~ ~ ] * [ ct ] flows and waves and waves of angles relative to the speed of light time.

Where the points of fgx interconnect with every other , and all other among themselves .

Or even for coordinates movements of waves flows in relation to the speed of light time. Where these movements are relative to benchmarks . [ ie , relativistic ] .

Mobile graphics and waveforms kinking .
Graph relativistic in relation to fixed and mobile and reference waveforms .

Imagine the results with respect to the Cartesian coordinate graph , but these graphs with wavy movements , ie , the image in relation to the movement of the plot also involves twisting .

And being that the graph can have more coordinates r , tea acceleration .