CALCULATION GRACELI INFINITESIMAL ANGLE .


Author . Ancelmo Luiz Graceli .

Brazilian, professor , researcher, theorist, graduate in philosophy .

Address - street Itabira , n 5 , Rosa da Penha - Cariacica - Espírito Santo , Brazil .

ancelmoluizgraceli@hotmail.com

Work registered in the National Library - Brazil - Copyright .

PRESENTED THE SECT - ES - BRAZIL .

Sesbram - Society Espírito Santo - Brazil Mathematics - submission.


THE ALMOST NOTHING EVERYTHING CAN APPEAR - EXCEPT GOD . BECAUSE IT IS THE ONLY ABSOLUTE .



MATHEMATICS .

The objective of this work is to develop mathematical model of a new way to see the calculation , though simple and can suffer several reforms over time.

Theory graceliana limit .

'' Least a part of a whole, the result divided by the whole'' . Continuing the equation infinitely .

x - y / x = g . The result [g] will always be between zero and one.
Here we have the beginning of a new calculus .
x -y / x = g . where g never be more than one and will never be less than zero . And decrease infinitely .

+ G L .
g -g .
/ g . g * g / x .
g / g
n ... infinitesimal progression .

[k ]
g / x .


g * g = a g .
n ...
x -y / x = g ... X * y / x = g ... X + y / x = g = n ...


g * to g .... Progression limit.

The boundary between zero and one can be infinite, because it may decrease indefinitely, but will always be less than the number one.

gx / x infinitesimal limit .
n ...

x - y / x / x ...

Found the boundary between zero and one with the whole of a part subtracted , and back to share with the whole, is found just a number that never goes beyond a .


Calculation Graceliano Angle .

Graphics from points and boundaries between zero and one .

1 - Variation of points by varying the distance to the angle , and the angle variation .

The point is marked by the angle and the distance to the angle . Where the points will vary .

And the distance will vary according to the equation relative to determine the angle .

Example .

20 * x = 40 . Where x = 2 , ie the distance is equal to 40 . That is, we have a point angle 20:01 distance 40, that is, 2 times larger than the angle. This will build a format in space or graph predetermined .

That is, both the angle can vary as x , determining that within a chart from angle will point to various distances to the center . Where we have multiple formats of lines , curves , and shapes from these points .

With x being equations , progressions , limits , fractions , etc. .

Example .
x -y
X = x .

X = y / x -1. And several other ways to find the points of angles [ â ] and distance .


2 - Variation of points also from varying angles variables , and away from these variations coupled with the variations of the equations of distances .

Examples .
1 - = â progressions , fractions , and other variables .

2 - a = y / 2 +3 / 2 = angle . The angle sought is found the distance of each point to the center of the graph from a different formula to find the distance from that angle ever encountered.


1 - x + y = ã. The angle [ â ] determine the distance from a new formula .

And determine the angle and distance to the point where several points will be built straight , curves and graphs . Finding multiple angles , will be found various distances , and for each angle and distance will be scored a point . And these infinite points will format the lines , curves and graphs .

Example .
X = y / 3 = a a = x * [g / 2] = d = distance .

Variables will be found the angle , the angle + variables will be found the distance to the center of the angle , and angle and distance to the center is where the point will be marked for that equation .

X +2 = 3 +2 = 5 ã ã = 5 .
D = ã + 4 . For x = 3 we â 5 5 +4 = 9 = 9 = d . so we have a point angle 5 with distance 9 .

As the variables are changing the points are changing the place where will be built straight or curved and irregular figures and irregular variables .


The angle can also be found from the predetermined distance . And so the point will be marked .

The figure , straight or curve can be measured from any angle above 10 degrees .

However if you start from the 90 degree figure developed by the calculation will have a better view .

â = d . In this equation will always have a straight line parallel to the center point as the graph above .

CALCULATION AND GRAPHIC GRACELIANO .


Infinitesimal limit .

A = [ - x ] / a n ... = g

The whole least part divided by the whole, infinitely so .

Where x is always less than that .
And the threshold is infinitesimal , and always greater than 0 and less than 1.

T - P / T ...

Calculation and graphic graceliano .

The graph is always determined by the angle and distance from the center to the edge , and the angles vary by distance or equation to be developed .

It is divided into several types .

FIRST CONDITION .

For d = distance equal to â equals angle.

The distance determines the angle where the points are marked with the distance and angle , and the succession of points form a graph , straight or curve .

Where x ranges from one to ten , or between two other values ​​.

Example .

1 - For d = x +5 = â for x = 3
d = 3 +5 = â
d = 8
â = 8

2 - for d = ã = x +5 for x = 4

d = 4 +5 = ã
d = 9
â = 9




SECOND CONDITION .

A DIFFERENT Â DISTANCE OF DIFFERENT ANGLE .

The distance and angle can be different , where the results will be different , and that the result of the equation can give any graph.

A different .

For d = x + y / 2 +3 , we have â = y / 3-5 .

For x from 1 to 9 and y 1 to 9 .

Thus we have 9 points marked with a distance varying the angle.

For the first point x = 1 and y = 1.
For the second point x = 2 and y = 2. So forth.


THIRD CONDITION .

WHERE THE VALUE OF X AND Y CAN BE DIFFERENT IN RELATION TO THE POINT TO BE MARKED .

Where the first point x can be 1 , y 3 * x . or any other variation equation .

The distance and angle are variable .
And x and y are also variable , or a third or fourth variable.


Hence points that will form straight lines , curves and graphs .



With the results infinitesimal can be added or multiplied by real numbers to mark the points on the graph .

Forming a full result .



FOURTH CONDITION .

ADDITION UP POINTS OF AN EQUATION WITH ANOTHER , FORMING A GRAPHIC CIRCULAR .

Where the result differs from the angle distance , which is different from x and y.

2 2
1 - d = x +2 / 5 + y = x +3 â x.y / 2


2 - x d = 2 * 5 * y + a = x / 2 * y / 2


For x 1 to 10 .

For y 1 to 10 .

Equation 1 will add up all the points , and also equation 2 , and the sum of the curve of equation 1 with 2 form a pie chart .

We will see the graphics front .

FIFTH CONDITION -

POINTS WILL ALSO BE MARKED WITH DIFFERENT ANGLES OF DISTANCE AND VALUES OF X Y DIFFERENT , AND SUM OF RESULTS WILL MAKE A TYPE OF GRAPHIC CURVO .

D different from â , different x and y .

1 - d = 3 / x - [ y * 2] . â = 4 / * y [ x * y + 6] .
With the values ​​of x and y =

1.1 = 1 to 10.

= 1.2 x = 2 and y = 3
= 1.3 x = 4 y = 7
X = 1.4 y = 8 = 9 .


2 - for d = 4/3 +5-2 * [ y / 2 ] , with â 2/y-4 * = x * [ 3 / x + y ] .

2.1. X - y 1 to 10 and 1 to 10 .

2.2. x = 4 y = 3.
2.3. y = 3 x = 4 .

As outlined the graph follow the result of the equation , where for each result found from x and y , we will have an angle with a distance from the center to the edge where the point will be marked .

Even if the result is different from the angle distance for this condition.


LIMIT INFINITESIMAL .

The subtracted from every part divided by the total, the result divided by the back around so infinitely thus have a new form of more boundary between zero and one, and decreasing infinitely , but only between greater than 0 and less than 1 .

[x y = g . g / x = k / m = x .
5 - 20 = 15 15/ 20 = 0.75 , 0.75 / 20 . 0.375 = so indefinitely.


[ y = g x / x ] n ....

More boundary between 0 and minus 1, and can decrease indefinitely.


FRIDAY CONDITION .

THE EQUATION OF DISTANCE EQUAL ANGLE added [ + ] minus [ - ] , multiply [ * ] OR DIVIDED [ / ] The A VALUE X , X OR PROGRESSION OR POWER X

D = â * x ..
D = a / x squared . And there continues .

or
D = â + x / 3 = r +2 . ie d suffers little variation while â is variable in the extreme.



SEVENTH CONDITION .

DISTANCE IS THE VALUE OF A QUALQUÉR EQUATION WITH VARIABLE X OR any other variables . Â ANGLE AND DISTANCE WILL BE EQUAL TO OR THE RESULT OF THE EQUATION OF DISTANCE added , OR DIVIDED , MULTIPLIED or subtracted OTHER EQUATION .


Example .
D = x .
X = â * y / 2 +4 .

The distance is from the center of the graph is marked by the point where the result of the equation, and the angle of the result of the equation depend on the distance to the result of the equation and the angle of its variables .

Example 2.

D = x / y for x = +3 from 1 to 9 and y = 2.

X = â + 5 - y + g . = 0.5 g

That is, the angle will vary depending on its first variable is distance.

YEG can be more fixed values ​​, as in the case of x with infinite values ​​of a thousandth of the nine values ​​or only nine natural numbers .

However, for each variable x should be an equation for each variable y and g .


Eighth condition .

For progression .

For d = x , x = â â = y and angle value varies - in one direction increases and decreases in another in a progression .

g = y + â , â = y - g .

The distance increases in arithmetic progression as the angle increases in a geometric progression .

And it can start with the angle variable to find the distance in ascending and descending progression .

à = y + g y = x and y = x -g . g = variable.




NINTH CONDITION .

LIMIT ANGLE POINT , THAT THE SUM DETERMINE A BOW OR GRAPHIC .

L = limit = 9-3 / 9 ... Displaying n = 9 n =

Or g threshold = 9 = - s / 9 = ks = greater than 2 and less than 8 .
And multiplying the sum of the limit 1-9 .
* K 1 to 9.



TENTH CONDITION .


G CAN BE potentiation , potentiation PROGRESSION FROM 1 TO 9 AND BASIS OF 1 TO 9 OR MORE , AND SUM OF LIMITS , fractions, NATURAL NUMBERS , AND IN THE SAME EQUATION potentiation , FRACTION , NATURAL AND NUMBERS OF LIMITS summations .

The graph can vary from a straight line to a curve , a cone , or any other graph.

1 - d = A result of the equation will be the same angle for a distance.

à = x / y + g + k

X = 1 to 9. y 1 to 9. g = potentiation progression from 1 to 9 .

k = summation limit 1-9 ..

For every natural number of 1 to 9 x has an equation for y worth a unit and the same will happen with the progression of potentiation and the sum of threshold 1 to 9.

Example .

For x = 1/ 1 + 1 power of 2 over - limit 8 + S / 8 to s = 1 through 7 .

Thus for each unit of x , y , 1 to 9 of power and base 1-9 , and with the variable limit [ s ] will have an equation with points and values ​​that increase or decrease according to equation order .

Since the signals may also change addition , for subtraction , division and multiplication .




ELEVENTH CONDITION .

A different angle. D = x .
â equal to x / y * g - k .

In case the distance d ranges will vary with x .

The distance may also be y or g or k . or addition of x and y , and the result of equation x and y.

The result will be different to the angle for distance. For the variables are more angles .






TWELFTH CONDITION .

For the variable distance d , where x / y * k .
And the angle variable , unlike d.
â = d + k * g ..

As the result of the distance to the variables k and g .

Multiplicatória infinitesimal limit .

T - p / t = L * n . n is operating in the equation to infinity.
G = L *
To g greater than L.


Example .

10 - 2 / 10 = 0.8
To 0.8 * g = g = 1 to 9 .

The angle a is the limit and the distance of the result with multiplicatória . Or vice - versa .

The multiplicatória can be any variable. Or continue with more variables .

As , L * g = r / c = s output . = Radian , area charts , etc. .

With this calculation can be created any condition .


NOTICE .

The chart can start with the angle that is determined by the equation or already be being quoted that he will get the 90 degree angle , which will be formed straight , curve or any other graphic as the sum of points represented by Eq .

Also, the distance from the center point to the 90 degree angle according to equation may be reduced by bringing the graph of the equation being developed also in the graph of angle, or having the same outside and inside of the angle.

With these equations can also be found forms of graphs and their respective areas .

Ie , you can find results for these calculations both present in plane geometry , as in differential and integral calculus .

It may also be a game of logical and mathematical possibilities in one equation, where it can be found in one equation results as thousands of variables to be displayed .

Can replace other calculations requiring many variables.

To calculate the areas of triangles , rectangles , circles , cubes just relate values ​​as are needed after being found by the equation graph format .

Calculating graceliano for graphic angle is possible to produce various graphs of infinite forms , with several equations .

In the same equation you can use real numbers , progression, potentiation , potentiation progression , percentage , fraction , differential and integral calculus , summation limits , plane geometry and complex numbers .





ON FORMS OF GRAPHICS .

1 - In an equation in which the results are the same for the angle , and with various results to have a straight away toward the center of the chart angle .

2 - and if the angle is variable so that a curve will follow the circumference of the graph , ie a curve perpendicular to the center.

3 - And if both are variables , then yes we have several ways for a single equation, which will be determined according to the variables of the equation .

4 - or various forms depending on the variables.

5 - The graph should be measured from the angle of 90 degrees. For the 90 degree angle provides the best format built by the graph points.

6 - Distance can start from the center , or at the end .

7 - In equation should be mentioned that the opposite side of the same graphic form on the other side . If the right is equivalent to left and vice versa. That is, symmetrical shapes .


8 - To rectangular areas should be considered symbols for the type of area to be measured to the same areas of circles , cones and bolts, or even graphs with rectangular and the other circular parts .

9 - The equation can ask interleaved values ​​, and for even numbers or odd , as in the construction of graphics format screw.

That only certain values ​​entered into the equation when even or odd , or even from a predetermined value .

10 - A simple equation can be progressive and progressive enhancement based on a numerical started , exponent and numerical starting at one or any other number .

Example . A screw cone equation should be interleaved and progression of increasing exponent , and be represented by the symbol of the area of circles .

And said representation being symmetrical on the other side .


To calculate the area consider the distance and angle , the result of the sum of points or areas to raise squared , cubed for volume , and volumes of circles to radians .




DIMENSIONAL ANGULAR CALCULATION .

THIRTEENTH CONDITION -

GRAPHIC DIMENSIONAL ANGLE .

TO CALCULATE THE POINTS AND FORM A THREE-DIMENSIONAL GRAPHIC , MUST TAKE INTO ACCOUNT OTHER THAN DISTANCE AND ANGLE FOR EACH ANOTHER POINT VALUE , WHAT IS THE POINT OF LATITUDE MARKED WITH RESPECT TO ANGLE , WHICH WILL BE THREE DIMENSIONAL .

Example .
To sum ​​of the angle plus the distance a different point will be marked in relation to the latitude angle .

D than or equal to the angle â and â latitude L different . But in the same direction over the distance d .

Point first . d = x + [y / 2] .
For each value of x in the equation has the value 1 to the unit 9 .

For each value of y with equation has the value 1 to the unit 9 .


â = x + [y / 3 ] .
For each value of x in the equation has the value 1 to the unit 9 .
For each value of y with equation has the value 1 to the unit 9 .

L = x + [y / 4 ] .
Follow the same values ​​for x and y expressed above .

NOTICE . YOU CAN ALSO USE THE THIRD DIMENSION TO INCLUDE AREAS WITHIN THE GRAPHICS OR PARTS THEREOF .
Using symmetry.



FOURTEENTH CONDITION - ANGLE CHART FOR FOUR DIMENSIONS .

FOR DIMENSION OF ROTATION , OR TRAVELING .

TO CALCULATE THE FOURTH DIMENSION SHOULD BE TAKEN INTO ACCOUNT FOR EACH ANOTHER POINT VALUE , VALUE THE ROOM .

THAT IS, ONE BEDROOM VALUE TO SCORE A POINT WHICH IS THE ROTATION OR WHETHER , BEYOND THE GRAPH TO HAVE A WAY HE WILL TURN rotationally SPEED IN SECONDS WITH RESPECT TO , OR ANY OTHER UNIT AS A REFERENCE FOR A SPIN , And CW OR CCW .

D THAN OR EQUAL TO Ã, WHICH ARE DIFFERENT OR EQUAL AL LATITUDE , AND THAN OR EQUAL TO [ r ] ROTATION .

And for every point scored will be worth the value end of the equation.
Example .

D = x + y for point 1 . Where x is 5 and y is worth 4/3 .
ã = x - y for point 1 . Where x and y worth worth 4 3/2 .
L = x / y for point 1 . Where x and y worth worth 6 2 .
r = x / [ y / 2 ] for point 1 . where x and y worth worth 8 4 .

You can mark several points to form the object or graphic.

There will be a point marked by distance and angle , a different point parallel to determine latitude L , and another point responsible for the rotation of the object graph or equation that will determine .





FIFTEENTH CONDITION -

FOR DEFORMATION OF CHARTS AND AREAS .
ANGLE CHART FOR FIVE DIMENSIONS .

TO CALCULATE THE FIFTH DIMENSION MUST TAKE INTO ACCOUNT THAT FOR EVERY POINT VALUE ADDITION OF ANOTHER FOUR sized ALREADY , THAT IS, ONE POINT FIVE HAVE VALUES WHICH IS THE TIME , AND THAT IS A VARIABLE deform DEVELOPED AS THE GRAPH ACTION TIME AND HE WILL SUFFER. THIS CAN BE DISPLAYED IN A BALLOON AND FILLS wilt , wilt OR SIDE AND FILL IN THE OTHER, OR MAY EVEN PULSAR .

THAT IS, HE HAS AN ADDITION TO SPIN IT WILL MORE THAN ONE VARIABLE deform YOUR GRAPHIC , AREA AND VOLUME . AS ACTION AND TIME .


A different or equal to A , which may be the same or different latitude L , which may be different or equal to [ r] rotation , which may be the same or different variable v .

The same situation is repeated , and the four points one or two input variables in the equation are deforming the graph.

Ie a graph with several different situations form a balloon , which besides having rotating as it wither and fill values ​​that equation gives you , which is the variable v deformativa . variables or deforming action and time [ aet ] .

V = x / [y +1 ] , the values ​​of x and y are variables.
Most points scored by other situations .

Note spatial geometry integral calculus , differential and complex numbers will be developed to calculate angle in another phase .


Graceliana DYNAMIC GEOMETRY .


With the fourth dimension which deals with the rotation and the fifth dimension that deals with the variation of the shape of the graph and the object , such as a balloon that can be suffered by the action of wind deforming the side of its format or deflating or inflating the lower or higher , the geometry becomes dynamic and variable. Or the object can pulsate with some intensity per second . And you can also pulsate .

Considering also that the object can move sideways on the chart that marks the angles .

For the rotation must be added to the equation the variable R , rotation per second .

For the deformation must add the equation of variable deformativa V , and direction and intensity per second on the angles or distances , where the graphics will suffer changes .

We have these equations in the fourth and fifth dimension .

A DYNAMIC GEOMETRY graceliana is different from flat space to be subject to three or more dynamic variables that deform the geometric object .

A variable displacement ,
Variable speed R,
Variable strain V.
Variable pulse .
Variable translation.


That is, a pulse balloon can have rotation , translation and removal from a point of origin. This applies in astronomy graceliana .


Example 1.

For different distance d â angle. The difference in the latitude L , D, R and L different rotation , and all different V by the time varying deformation .

And for each subsequent point will be added to the value of a unit , subsequent to all dimensional requirements , which determine the shape of the object variable and its dynamics .

Different equations for all conditions .
For the first point .
1 - x + y = d * [g / 2] = where x = 5 , y = 4 , g = 3.
1 - a * x y = - [ g / 3] = where x = 7 , y = 2, g = 4 .
1 - L = x / y - [b +1 ] = x = 4 and y = 3 , g = 5 .
1 - R = x / y - [ G - 3] = where x = 3 , y = 2, g = 7 .
1 - V = x * y + [ G - 2] = x = 4 and y = 3 , g = 5 .
Aw = x * y


2 - with the same equation for each dimension or mathematical condition , the variables x , YEG be increased by one unit for each point ,

To d x = 6 , y = 5, g = 4 .
To ã, x = 8 , y = 3 , g = 5 .
For L x = 5 , y = 4 , g = 6 .
For R , the value of R will be repeated , because the rotation has only one value .
To V , x = 5 , y = 4 , g = 5 .

Thus , the other points are marked progressively until complete graph , or object with their variation and rotation .


The variables will be increased by one unit for each point .

Ai is the construction of the first point for all conditions , the other points are marked by keeping the equations and changing the values ​​of variables .

The values ​​of the variables x , YEG are increasing, for each condition in each equation , the equation is repeated for each point by changing a drive with increasing values ​​for each variable of x , y and g .

It must be related to what point the variable V deformativa begin its action wither , swell or throb.

And in one rotation R value to rotate the object , the first equation is that worth .

The latitude L is related in that direction and meaning , and in relation to points â angle.

Direction , direction, and speed may be new dimensions .


Example 2.

May be a single equation for all dimensional requirements .

1. D, L , R, V = x * y + g - 2 = where x = 5 , y = 4 , g = 3.
2 . d , ã, G , R , V = x * y + g - 2 = where x = 6 y = 5 , g = 4 .
3 . D, L , R, V = x * y + g - 2 = 7 where x = y = g = 6 5

Namely , the variables are increased by one unit.







Thus, one can calculate a balloon wither one side or pulses , is in rotation, translation , ellipse, and isolation.


This work is incomplete .
Posted by ancelmo at 08:53 0 comments
ANGLE CALCULATION INFINITESIMAL GRACELIANO .


Author . Ancelmo Luiz Graceli .

Brazilian, professor , researcher, theorist, graduate in philosophy .

Address - street Itabira , n 5 , Rosa da Penha - Cariacica - Espírito Santo , Brazil .

ancelmoluizgraceli@hotmail.com

Work registered in the National Library - Brazil - Copyright .

PRESENTED THE SECT - ES - BRAZIL .

Sesbram - Society Espírito Santo - Brazil Mathematics - submission.


THE ALMOST NOTHING EVERYTHING CAN APPEAR - EXCEPT GOD . BECAUSE IT IS THE ONLY ABSOLUTE .



MATHEMATICS .

The objective of this work is to develop mathematical model of a new way to see the calculation , though simple and can suffer several reforms over time.

Theory graceliana limit .

'' Least a part of a whole, the result divided by the whole'' . Continuing the equation infinitely .

x - y / x = g . The result [g] will always be between zero and one.
Here we have the beginning of a new calculus .
x -y / x = g . where g never be more than one and will never be less than zero . And decrease infinitely .

+ G L .
g -g .
/ g . g * g / x .
g / g
n ... infinitesimal progression .

[k ]
g / x .


g * g = a g .
n ...
x -y / x = g ... X * y / x = g ... X + y / x = g = n ...


g * to g .... Progression limit.

The boundary between zero and one can be infinite, because it may decrease indefinitely, but will always be less than the number one.

gx / x infinitesimal limit .
n ...

x - y / x / x ...

Found the boundary between zero and one with the whole of a part subtracted , and back to share with the whole, is found just a number that never goes beyond a .


Calculation Graceliano Angle .

Graphics from points and boundaries between zero and one .

1 - Variation of points by varying the distance to the angle , and the angle variation .

The point is marked by the angle and the distance to the angle . Where the points will vary .

And the distance will vary according to the equation relative to determine the angle .

Example .

20 * x = 40 . Where x = 2 , ie the distance is equal to 40 . That is, we have a point angle 20:01 distance 40, that is, 2 times larger than the angle. This will build a format in space or graph predetermined .

That is, both the angle can vary as x , determining that within a chart from angle will point to various distances to the center . Where we have multiple formats of lines , curves , and shapes from these points .

With x being equations , progressions , limits , fractions , etc. .

Example .
x -y
X = x .

X = y / x -1. And several other ways to find the points of angles [ â ] and distance .


2 - Variation of points also from varying angles variables , and away from these variations coupled with the variations of the equations of distances .

Examples .
1 - = â progressions , fractions , and other variables .

2 - a = y / 2 +3 / 2 = angle . The angle sought is found the distance of each point to the center of the graph from a different formula to find the distance from that angle ever encountered.


1 - x + y = ã. The angle [ â ] determine the distance from a new formula .

And determine the angle and distance to the point where several points will be built straight , curves and graphs . Finding multiple angles , will be found various distances , and for each angle and distance will be scored a point . And these infinite points will format the lines , curves and graphs .

Example .
X = y / 3 = a a = x * [g / 2] = d = distance .

Variables will be found the angle , the angle + variables will be found the distance to the center of the angle , and angle and distance to the center is where the point will be marked for that equation .

X +2 = 3 +2 = 5 ã ã = 5 .
D = ã + 4 . For x = 3 we â 5 5 +4 = 9 = 9 = d . so we have a point angle 5 with distance 9 .
As the variables are changing the points are changing the place where will be built straight or curved and irregular irregular figures
Posted by ancelmo at 08:51 0 comments
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Posted by ancelmo at 09:07 0 comments
Friday, July 30, 2010

CALCULATION INFINITESIMAL DIMENSIONAL SPACE GRACELIANO .
Author - Ancelmo Luiz graceli .

Brazilian, professor , researcher, theorist, graduate in philosophy .

Rose of the rock, Cariacica , Espírito Santo , Brazil .

ancelmoluizgraceli@hotmail.com

Contributor . Marcio Rangel Piter .

Work registered in the National Library - Brazil - Copyright .

Thanks to some colleges that are including my work on their resumes .


This calculation does not use the Cartesian graph or angular graceliano . Points are scored in the space as the function result in an order of time or longitude , latitude , and transverse [ or ] acceleration and velocity , or rotation , etc. . with respect to time .

For that is one dimensional spatial calculation .

And with infinite dimensions .

And why is infinitesimal calculus can use force or graceliano .




The stitches are not tagged in relation to a chart but in space.

And the values ​​that determine whether the reference is a straight line, a curve , a curve with rotation , or rotation and gradual removal at one end and have translation.

An initial value of x to another value of x the final , which will be among the initial x ex end .

And for each value of x is infinitesimal variation - which may be exponential , progressive fractional , or other mathematical functions . Including the current calculation .


The variation for each infinitesimal variation of x can represent algebraic functions , integral calculus , or mainly with functions and dimensional values ​​.


The dimensional values ​​can represent infinite dimensions . But mostly for rotation, translation , laterality , remoteness, progressive expansion .


Space is in space, without reference , but the values ​​of x may form a graph - straight , curved , spiral, etc. . fixed or dynamic range so as to determine the function .

Temporal - may vary in time, so the value of x as the function result .

And you can gradually increase or decrease.


That is, the initial value of x to x end may be from 5 to 9 . or other initial values ​​for x and x end .

Examples .

1] x = a + b * 2 * 4 + [ C / 2] .

2 ] That is, for each point between 5:09 and variations will determine points compared
each value of 5:09 and its intermediates .


3 ] The calculations may be for algebraic functions , mathematical calculations , and especially dimensional .


4] Using dimensions.
Between the initial value of x ex end or infinite being that initial x is 7 . And using x as the spatial reference , and the other point is the result from the value used in algebraic function , calculation , or valore dimensional .


the ] initial x where x = 7 can start with 7 and have one end or continue .

For each value of x = rotation * translation + clearance + movement laterality .

And for each value of each dimension will be different variables with respect to time .


B] and each dimension may have a very variable , and each variable itself a variable for each value of x.

C ] and each value of x vary according to a predetermined function .

That is, x being 7 to 14 rotation , translation and removal increased to 10 and decreasing from 10.01 to 14 or more .

And for each variation of x will be a proportional variation [ or ] equal to a higher value y at all , some or none of r , t, a.


X may represent points of spacing forming a straight or curved , or curved rotating etc. . points to the results of the function.


The dimensional variables may be more than one for each dimension.

Example .

R1, r2 , r3 , ... rn All variables with different coefficients .