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Saturday, March 14, 2015

Pi Day

Waking up on the couch this morning, even after sleeping through the entire night, how frigging long has it been since that happened, I thought what a waste it all was.  Why am I sleeping on a couch?
So here's a life hack.  The easiest way to make oatmeal or grits is in a microwave.  But there are two problems using a properly sized bowl.  The water boiling over and getting the amount of water right.  And there is like this great easy solution to both problems.  The first one is putting the wide end of a wooden chopstick over the top of the bowl which somehow magically keeps the water from boiling over (This is quantum mechanics, not cooking science) and the other is to boil a kettle of water which can be added after the approximate amount recommended in the directions turns out not to be enough.
But it's pi day and you don't care about making oatmeal or where I sleep at night:  This started many years ago with the Einstein Hologram universe where the discussion first surfaces about time "uncoiling."

STEPPED TRANSITIONS

One question of linearity is why don't forces cancel out the corresponding dimensional aspects and take everything back to a non-linear state?  The best answer is that we exist in a non linear state, but we have linear states at quantum “points”, even if they are largely illusory.  This proposition assumes that at any point in time, we exist with a prepackaged past and future, and that all of these points in time (quantum points, of course) exist at once.

A longer discussion will follow where we see this type of stepped transition in irrational (or non-linear) numbers such as pi which can only be calculated by way of example.  4/1-4/3+4/4/5-4/7.  Nothing this transition is also a function of 2 (4/2^0-4/2^1*2+4/2^1*3 where the transition from 0 to 1 represents a phase transition.  Phase transitions are reflected in time dilation as will be discussed further.  Using the idea of phase transitions, you can arrive at pi being the sum from n=zero to infinity of 4/(2^n’)*n noting that there may also be a summation of n’ associated with certain changes in n, in this case n=0 to n=1.  There is no reason why there cannot be other phase changes before or after the n’0 to n’1.

One answer suggested by the math is that Forces (F) are from a lower dimensional state.  That is gravity, which effects CT1 dimensional characteristics is a CT0 force, Photonic energy which is a feature of CT2 is a CT1 force characteristic.  Following the model of Non linear numbers (irrational numbers) like pi this would yield an equation for any Point (P)=ct(0)-ct1+ct2-ct3 etc where each clock time represents a number which approaches, but never reaches a solution which is consistent with the approach previously derived by compression also using a factor of 2.  Instead of 4/(2^n’)*n; the equation is loosely seen at x^2^n as n increases from 0 to infinity.
Expanding the equation to take into account non-linear (or irrataional) numbers:
(x/n)*10^2^n-x/n*10^2^n+x/n*10^2^n.   If you wanted the equation to be closer to that of pi, n may be replaced by 2 times n, but that is merely the changing of a constant.  Likewise, you can have a phase change which would alter the equation.  One place where this could happen is where n=0 in the first part of the equation (x/0)*10^2^0.  In this case, there are two possible solutions present.  The first is that there is, for example, a reverse phase change (from 1 then to match the second n)  An alternative would use the alternate values for zero derived for non-linear time which are discussed below in the discussion of zero in a linear and non-linear universe..

The other method would mimic the pi equation:
((x/2^n’)*n)*10^2^n-(x/2^n’)*10^2^n+etc where x is some constant and n’ goes through a phase change at n’=0.  The same type of phase change in such a case is expected at the ct4-ct5 interface based on an analysis of time dilation as will be discussed in more detail below.

There are a dozen permutations.  Ct1+ct2+ct3-ct4+ct5 for example (only one of several perceived compression states being negative). 
Or the negative could be the intermediary stages, again, visiting the pi equation:
[((x/2^n)*n)*10^2*n]-[(x/(2^n+1)*10^2*n]+[x/2^n)*n)*10^2*n where n increases sequentially only at the point where the [transition] goes positive so that the negative is a function only of the transition state between 1 and 3, 3 and 5, etc)  While this might seem mildly inconsistent since it gradually goes to a point near infinity, it can make sense in a NLC universe where zero and infinity achieve a duality as set forth below.

It also has to be kept in mind that compression is a function of coordinate “change”.  When we use an equation like this to define a point, we are really talking about the change in a point since all points remain constant and we are only seeing changes in the point.

For lack of a better math model, understanding NLC requires reliance on non-dimensional math, and the possibility of alternating positive and negative time states.  This would envision an uneven transition into non-linearity, time states don’t just split into their component parts, they split into a dimensional character and force characteristic lags behind pulling on the dimensional characteristic, but not strongly enough to pull it back to non-linearity, instead gradually moving towards the non-solution of an infinite series.  The discussion in later chapters will cover how these infinite series are solved using non-dimensional math using quantum concepts.

This vibration model assumes an infinite or very long series which is discussed in the reflection of this model in the irrational or non-linear numbers such as pi.

 It should be noted that with CT5 (black holes), gravity seems to be winning over most of the other forces in terms of concentration but the model indicated would suggest something more than a steady movement to an end place, but is instead a gradual migration to a point.

This would be, in terms of our three dimensional world, a little like saying we are affected by another dimension; but the truth is that NLT doesn't have dimensions.  We are an illusion, a projection of NLT and hence limitations on what happens in our universe would not apply any more than the light passing through the film projector affects the film that breaks it into its component wavelengths.
In a very rough sense, the equation NLT=T+(-T) might look like this: NLT=T1-(-T0); T2-(-T1), etc. or it might look like NLC=t1-t2+t3-t4, etc.  In the later equation T2 may be –T1 but in such an event, the negative time state –t1 plus the positive time state t1 are not equal to zero.

 NEGATIVE TIME FOR FORCE EQUATIONS

The idea of vibrating time, pi and a universe of converging series suggests that there are positive and negative features of time.
     If the negative time of a preceding clock time is force, then the force equation can be eliminated completely in favor of a negative time.  In terms of equation: P=((t-y)/t)DA-(t-y/t)FA)dt=((t-y)/t)DA+((t-x)D(A-1).  This simplified equation recognizes that the Dimensional function and the Force function for state "A" Could be equal to the Dimensional function for A and the negative dimensional function for the preceding dimensional coordinates.
This suggests an absence of convergence (a converging infinite series like pi) but such result is counter-intuitive.
 THE IMPORTANCE OF PI
Pi represents the smallest point at which change is relevant.  While we think of this converging infinite series as having no conclusion, in a NLC universe it likely has a solution where quantum changes no longer are relevant.  This point is the NLC-Planck length.  This would hold that it is possible to have a perfect circle which is impossible in a linear universe.
A “Planck length circle” would be based on pi=c/PL (from the equation c(circumference)=2pir.  Both the size of Planck length (PL) and the corresponding approximate relationship of R to PL would dictate the point at which further derivation of pi would become irrelevant due to quantum limitations in linearity.  It would not, however, change the relationship of pi to a non-linear environment where pi ceases to exist as such because there is no dimension, hence in the equation above, PL would go to zero along with the circumference and pi would lose its meaning.

Solving pi with finality is something that needed doing.  Impossible with linearity, but what is a circle without dimension, how can you travel round and round if there is no time in which to do it.  Pi proves that.  If there is no perfect circle, that requires the smallest point cannot exist, and pi cannot be solved because it is, by nature, a non linear number because you constantly approach the solution but cannot arrive at it without running out of "twos" to add.  Irrational?  They should be called non-linear numbers, but then no one knew of non-linearity.
The many faces of irrational numbers should resolve themselves with non linearity.
The irrational number pi can only be determined using an infinite series.  NLC assumes some amount of finitude, because if everything has happened there is the suggestion of both a beginning and an end, a sum total of all information necessary to define the universe.
Pi alleges that you cannot have a perfect circle, even though by definition if you had a perfect circle there is an easy definition, the circumference of a perfect circle divided by the diameter.  The problem with pi will be easily understood by the methods of approximation, but in the end, a perfect circle would have to provide for a finite definition of pi which is alleged not to exist and well it might not except in NLT or NLC.
When we look at NLC we come up with some unusual formula for the universe which are a function of information and not actual locations.  When we look at pi (and there are many different ways to look at pi) we find ourselves, for example, looking at a convergent infinite series of the type:
pi=4/1-4/3+4/5-4/7+4/9-4/11 etc
There are other ways of showing this through equations which converge quicker and integration of change e.g.
pi=2xint(from -1 to 1) or (1-x2)^1/2dx
This is not considered coincidentally similar to the equations of clock times going positive and negative and just as we have multiple orbit types and phase changes in NLT, so we find an equation for pi that reflects a phase change.
In this example, pi is represented by the same type of “informational” bit transformation: 4/2^n transitioning to 4/2*n from 0 to infinity.  There are several places for this phase changes, the most suggested by non-linearity is when you go from n=0 to n=1, although it could be at n=3.  Either way you would have 4/1-4/2+4/4-4/6,etc.  The transition, however, can be viewed differently if you want to accept orbits as pointed out below.
One question of linearity is why don't forces cancel out the corresponding dimensional aspects and take everything back to a non-linear state?  The best answer is that we exist in a non linear state, but we have linear states at quantum “points”, even if they are largely illusory.  This proposition assumes that at any point in time, we exist with a prepackaged past and future, and that all of these points in time (quantum points, of course) exist at once.
 A longer discussion will follow where we see this type of stepped transition in irrational (or non-linear) numbers such as pi which can only be calculated by way of example.  4/1-4/3+4/4/5-4/7.  Nothing this transition is also a function of 2, and if there are “orbits” associated with the calculation of pi, which would provide a vehicle for a fixed solution, that “orbital” change occurs at the point here 2^n transitions from n=0 to n=1, the 0 element being the first orbit, the n=1 being the second so that the solution in terms of orbits looks like this: 4/2^0-4/2^1*2+4/2^1*3-4/2^1*4, etc where the transition from 0 to 1 represents a phase transition.  Phase transitions are reflected in time dilation as will be discussed further. 
Using the idea of phase transitions, you can arrive at pi being the sum from n=zero to infinity of 4/(2^n’)*n noting that there may also be a summation of n’ associated with certain changes in n, in this case n=0 to n=1.  There is no reason why there cannot be other phase changes before or after the n’0 to n’1, the next one looking something like this: 4/2^2*x where x may start over as 1 or x may be some other function.  At what point in the solution this phase change would occur is important in solving pi and it represents the transition from an irrational number with no solution in ct4 to an irrational number with a solution, presumably in CT3 or lower, perhaps only present in ct1 where there is, after all, no true clock time because there is only one coordinate change at once and the most likely place, based on time dilation and gravity where you would expect to find these types of transitions.

When we connect pi to nonlinearity we can do more than just look at very small applications of pi.  We can compare the infinite series of pi to what may be the infinite series tied to the compression equation 2^n which applies as 10^x where x=2^n in the matter to energy conversion.  It has been envisioned that compression might dictate this equation as 10^(1/x) due to the compression concept.

This involves treating pi as a reflection of a vibrating singularity.  If pi is a vibration than the suggestion is that the positive and negative nature of linearity reflected in spatial and force characteristics would be of the same family of phenomena.

 In this case, the nature of the universal change we experience is seen as a series of vibrations, circles reflect these with pi being 4/1-4/3+4/5, etc and all space follows a similar pattern being reflected in a NLC universe where CT=CT1-ct2+ct3-ct4 and where each clock time is a function f(2^n) so that all of clock time approaches a point of non-linearity just as pi approaches a point between 4 and 4/3, neither necessarily arriving. 
The only problem with this analysis is that in NLC, the apparent designation appears more like this CT=CT1-CT0+CT2-CT1, etc.  However, the math allows that either formula is possible since you have in the analysis that CT1 has both dimensional and force characteristics built into it.
When one applies the Clock time universe to pi, you can find versions of pi that would be relevant in CT3, CT2, etc.  Solving the pi equation for n in CT3, for example, you find 3/1-3/3 as an alternative to 4/0-4/2+4/4.  The former corresponding nicely to the NLC concept of compression where 3/1 would be the part associated with ct3, 2/1-2/3 for ct2 and, of course 0/1-0/3+0/5 for non-linear time.   It makes for a mental exercise to try to find where non-linearity is spiraling to.  

The equations for arriving at pi can be seen as a circle spiraling in to 3.142...
The equations for force and time seem to be spiraling outward.  If you assume that NLT never arrives at the endpoint (assumed to be from non-linearity to linearity and then back to non-linearity in an infinite set of sets) and if you accept the very theoretical concept, even for NLC, that the forces we experience (such as gravity) are the next earlier time (or coordinate) state going negative, then you arrive at this interesting equation (which you can even find in the second edition (NLT is actually the second edition of the Einstein Hologram Universe):
P(any quantum point)=ct1-ct0+ct2-ct1+ct3-ct2+ct4-ct3 etc.  This equation says that any point is a set of coordinates plus the negative state of the next earlier coordinate state as if there was a vibration where linearity is the result of a positive state change immediately offset, but incompletely, by the next earlier state change.  Pi appears to follow this.  Indeed the ct states have a compression factor of 2^n while pi has a "compression" factor of 1/n where n increases by 2 starting at 1.

There are two ways to approach this.  One is to improperly assume that it is a coincidence.  The better approach is that pi results from the non-linearity of space going to a three dimensional volume (at least in ct4)  The exponential compression, as shown by the earlier set of posts, is built around the time dilation equation.  Both can be shown to be related with relative ease suggesting pi would have a solution in a Non-linear environment (when you couldn't have spatial circles anyway because of the lack of dimension.

We can solve for 3/0 in a non-linear universe.  In such a case zero is not nothing, as previously discussed, at least for these purposes, but includes all of linearity, all of the information in the universe.  It is a 10 with so many zeros behind it as to be essentially uncountable, just what we would expect, infinity because all the information in the universe is the location of every quantum point, including the quantum points of space for all time embodied within the universe.
However, it is a number that a god-being in the sense of all knowing and all powerful should be able to comprehend even though we could not do so even if we could calculate what it is (if we give the universe a given term and size, we could calculate an approximate rendition of it just as we were able with relative simplicity to calculate the amount of intelligence in the known universe, past present and future in the Einstein Hologram Universe.
In such an event, 3/0 achieves a value and we can determine at what point the remainder of the equation becomes relevant (at the point where we reach this infinitely small point and it gives us a point of reference other than the speed of light to determine Planck length or some linearity Planck length.
The reason that a solution to pi is so important is because it is required to have an infinitely small circumference, quantum space: C=2pi(r) or the change in pi=c/2r as r approaches zero or infinity. The reason that a solution to pi is so important is because it is required to have an infinitely small circumference, quantum space: C=2pi(r) or
pi=c/2r as r approaches zero.
The places where quantum mechanics finds a foothold are where r goes to zero or infinity.  Somewhere in the former (zero) pi would achieve a finite size.  At the same time, under a linear universe, the equation to solve for pi renders this impossible.  You would, to get a finite answer, have to "stop" the solution at some point.
In a strictly quantum universe, this is possible and not possible.  You merely say the smallest quantum of space is x and you solve till you reach this very small point and say, beyond that there is no splitting, it is the minimum size of a circle, a quantum point circle.
However, the very nature of the equation for determining pi renders this impossible as it requires that you gradually arrive at a point without ever arriving, the definition of an infinite series.  It is the essence of NLC that time is non-linear and that linearity is a solution for the minimum amount of linearity and the point where the maximum amount of linearity arrives back, it arrives back to non-linearity.
There is also every indication that forces are negative indicia offsetting the positive indicia but incompletely, providing that non-linearity remains but that the offset is imperfect allowing for non-linearity and linearity never to be completely triumphant one over the other or the universe would go wildly non-linear or would cease linearity altogether.
The remnant of this process is pi=4/1-4/3+4/5-4/7+4/9-4/11 etc
An alternate version of pi in CT3, which is not a solution to CT4 pi is 3/0-3/2+3/4-3/6 etc.  We rail against the alternative because it starts with infinity, that is non-linearity, and then seeks to achieve a point which is infinity less some finite amount. If we started with 3/2 we would be very comfortable and we then we could say that this second point is the "pi" of ct3, perhaps increasing our comfort level further if we started with 3/1-3/3+3/5-3/7 etc, but there are reasons why a result that is logical in our universe might make less sense in a non-linear universe where there is an infinity, an absolute singularity.

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