The New Virtual: Quantum Emulation: SRMM

Showing posts with label SRMM. Show all posts

Monday, December 26, 2016

Securitization in Qve

In the ordinary world it took years before industry learned about:

Securitization‌ is the financial practice of pooling various types of contractual debt, such as residential mortgages, commercial mortgages, auto loans, or credit card debt obligations, and selling said consolidated debt as pass-through securities, or collateralized mortgage obligation (CMOs) to various investors. The cash collected from the financial instruments underlying the security is paid to the various investors who had advance money for that right. Wikipedia

This practice turns insurance into an Investment Practice rather than an Actuarial Service. In fact, these practices in turn changed banking into a Retail Industry selling digital products. If Technology were to become truly Green, many more industries would merge their services, but create a more functional application of power, energy, capitalization of virtual products and combined subscription services. It would be a truly Virtual Marketplace.

Digital Energy could become a bios package as well allowing people to exceed ordinary standards. So why argue with a new version of Quantum?

We noticed that smaller was better in terms of speed, at least in the Quantum world. Smaller can negotiate curves and hurdles much better, passing through gates faster than anyone can blink.

If everything reached the META State of maximum sustainability, what would insurance companies insure? Well, from the corners that industry has already turned, we can see that they would be underwriting the infrastructure and developing a retail means to insure delivery of a number of utility services.

We keep pointing to finding those mechanics that meet the need within the Gap and learning to manage the field position to gain more leverage.

Who will underwrite Proxy Services and make up the industry requirements in Timing and Timeframes? Typically, a loss of time is actuarially managed and at least for awhile that may still be a consideration. A great number of things were learned after the wars brought about new products, one of them being that the real problems of money were in securing the stability of infrastructure. We have a lot to learn about META Frames and new Quantum Systems. (We also want people to start to recognize branching numbers and their relationships. Just look at the first 2 or 3 digits and use sliding digits to see that the same numbers are at work throughout all of our examples like a map, these branch numbers point to the operations they perform.)

The start of something new has a lot of testing involved. No one expects amazing overnight. But who would insure ordinary material once they see what META Materials can do?

How do you build a Digital Power Plant? Inner Space is waiting to be developed
It could be that power generation in general is ready for the next step in quantum digital production.

Also Read:

We are the Imagine Nation...building in Qve

Vero Ni Nike, Christo

To Our Captain, Nothing We Do Must Fail

Disclaimer: Blog material is presented as the basis of discussion material and is not to be construed as advice, counsel or education, and may at times be misconstrued if read in a context different than the writer's intent. No portion of this blog has been knowingly reproduced. Any resemblance to a specific company or entity is purely coincidental

Sunday, December 25, 2016

Content Management in Qve

In our last Topic about a Qve example of Quantum based production emulation we had shown the idea of moving from the concept of building a design set and moving it out to a production site or the additional concept of moving a virtual machine to a specialized task in the Virtual Universe. But there are several functional aspects of Time and Motion that need to be deployed in the spectrum, and here we want to see how many topic related aspects of this we can use to answer questions about this idea. In our last blog entry we asked this question:

See if you can help us solve this puzzle. When do you apply the Time Bottle, when do you apply Timelines and when do you apply the Manifold? We are going to talk about this next...

The Time Bottle idea is the Gini System that enables all of the parts of the Machine to communicate with one another. In some ways this idea can work with the ship in a bottle idea or the manifold net which can both be deployed from string based elements like plastic space. So this idea can actually be deployed anytime but is distinctly part of any object deployed into a METAframe or as part of the internal METAframe. The time bottle arrangement should also have a watch window that enables a proxy to follow the output, time any changes and deploy new object relations.

The Manifold always controls the overall deployment and operation of any object. Gini objects always communicate with the Manifold. There are some standards that are plainly written such as 144 cubits which are mentioned throughout time, and while may relate to earlier technologies, certainly remain appropriate. ISO standards are what makes development connectable with new technology and existing formats, even as it relates to the inner space of the Virtual Universe. We mention this because this is probably the way things will progress from the beginning.

While we have shown 3 or more timelines used in Development, and we have made calculations of how to develop an agile project using these timelines^, we haven't discussed using the cloning process. It is possible to clone more than one proxy arrangement during development and to use teams to manage various aspects of the project such as more than one Instance to aid in correspondence. Using plastic space and creating your own timing device or Brane, a series of impulses can set up the timings that you are looking for. Also, color coding the impulses can allow you to know the progress or stage of your project.

^may not be published in this series

Additionally, in the production of Virtual Glass, it may be necessary to tie different lattice arrangements in certain sequences. This is the type of utility idea that may make sense.

Because these ideas are just the beginning of building in the Virtual Cube we can offer only a few ideas, but these are here to give some substance to the ideas in emulating strategies for development.

In order to enable the correct rotational speed from our keys to deliver subassemblies to our production we increased our manifold speed.

Most notably we need to correlate this to our maps: using portion below note the call ops process found here: http://quantumve.blogspot.com/2016/12/manifold-delivery-in-qve.html

Now all of our ideas are coming together more closely and we can see that everything is based on spintronics. The way we position subassemblies with our keys is important to the strategic planning of production assembly but we keep using our utility maps as the means to co-ordinate our process. The process is always going to rotate subassemblies according to a random access program and this would enable very good encryption.

The maps we used equated to the area that we required and it also created some topography that we could use to distribute our requirement. We are certain that this would not be the only setup that the operation could use. All of the different analogies of how a Quantum Cube works are found in different media.

The use of a Flag system is also part of the Time and Motion control relative to the Formula ONE theory of the best use of materials and processes to refresh and rebuild in a META State.

Another reason for using the Flagler Rail map is the idea of the Cube and the Progression. We began with a Walk progression and moved to a Run progression when we learned how to move onto the Manifold. Cubes move the process much like a rail system.

This idea is based on the quantum build-out and application of inner space.

Friday, December 23, 2016

Matrix Repackaged

Encryption: Maps, Models and Mirrors

EMS Features

SRQEM: QLD Energy Machine

We are certain that the repackaging of active elements such as nanos loaded with energy spectrometry would change the way everything could operate. But we must stress that in QLD the valence bond is created between quarks that are packaged in Qubit predicated relations.

Spectroscopy and spectrography are terms used to refer to the measurement of radiation intensity as a function of wavelength and are often used to describe experimental spectroscopic methods. ...In quantum mechanical systems, the analogous resonance is a coupling of two quantum mechanical stationary states of one system, such as an atom, via an oscillatory source of energy such as a photon. QED Systems per Wikipedia (Quantum Electro-Dynamics)

QLD is Quantum Lamb Dynamics:

So this is why when we point to the use of Quonics as drivers in the ONE System that a smooth response can be generated to move, motion or motivate many different types of activities. We are also pointing to the lag on the Manifold of our project and how the transitional state can be changed by Interbranching. For example, when the Gap process produced the least squares result of 3508... we can find the Interbranch difference to 3567 as 59 and begin the interbranch transition of 1.67 (which incidentally takes up the lag in our project scope on the last blog entry of 320 days/10/2.5 =12.8-11.2 or 1.6.) here: Asset Capitalization in Projects

We stress the predictability of the results because in QLD everything is directly controlled and ambient energy with tendencies to deliver irratic results are not present in the system. This means that devices can be designed and delivered within a Virtual Spectrum of refinement. This also demonstrates how various composite lens effects can be created with a particle dispersion in a nanotechnology process of QLD. This can also create various field arrangements within conditioned spaces of the environment. With photosynthetic virtualization the ideas of reshaping tomorrow are not so distant.

Now to reiterate the process that we employed in our Qve blog: we have taken a Matrix configuration based on a logical progression of a production and we have repackaged the Matrix to produce that configuration on a CUBE basis of Pascal branching.

Many Technologies are suggested:

By engaging in this type of Emulation we have shown how the interior functionality of a process can be brought into the application relationship of an SAS process. But more importantly we have demonstrated that the Quantum process based on QLD Energy could create Virtual Glass and Virtual Machine components capable of delivering an out of the box composition of functional applications. The smaller the components of the application the more competently CURVE requirements can be compensated at required speeds.

You may also notice that in our use of television and movie related productions that many ideas are emulated by modeling various concepts in story form. We find this to be a very interesting way of suggesting new ideas and proposing models that need to generate further interest on the part of science and technology. We find that thinking through Intelligent Design encourages people to see doors or windows as obstacles they can motivate.

We found the same graphic emulation in every VIEW of Matrix Theory. However, we did note that in QED versus QLD a different outcome is determinant and not visibly distinguished because the packaging theory and the redistribution of attributes do not present themselves readily. This is why we have pursued this emulation and described the nature of Qve.

Also Read:
Asset Capitalization in Projects

Green Technologies

Thursday, December 22, 2016

Tales of the Encryption and Lies of the Lattice

VI. Encryption: Maps, Models and Mirrors

EMS Features

Where is the mirror and how is it used

Best practice idea about encryption

Speed and Matrix definitions

Famous Encryptions

We went to school just in time to find out that Superman lost his powers when he was around kryptonite which acquired his hyper-molecular structure and weakened it, probably by pairing up with it. But if the correct type of encryption had been used he might have danced around kryptonite all day long.

Apparently there are two things to think about with encryption and that is to secure something either permanently or temporary, a transitional or rho based configuration that moves in a random access pattern at the smallest metric level is the most primary key; and the speed of this encryption should exceed the pattern of the image or configured matrix. This by the way, is how we are told RNA is protected.

We are emulating Qve Production:
So we've come into our Gap area and looked into our Pascal Branching to see what we can discover about Encryption while we are detailing the Branch Tables for Conversion of Production. Right now we are working with a hard-wired board and a branch sequence that is untested. So we are still scoping out the theory of what we think the Cube version of Production ought to tell us under certain conditions. And we are building a process that runs on the Pascal Branches of the Cube like a configurator.

We believe that we are right at the point where the subassemblies would be added to the production and the gap is being accessed to input the Key map. There are 66 keys which need to [ sequence to ] match up with our Call Table as we define this process from the last posted Map here: Manifold Delivery in Qve

So here we are in the Gap Sequence of our Transition where we can note a sequence will be returned from the process that establishes that the scale is changing and 96 is returned 3x in a specific consequential formula. Using the same parameters to produce the Object will return the table data we are expecting, and when the sequence comes up we can use it to lock our materials and our field (machine, etc.)

The final number we are looking for is our map. The small numbers between 1 and 9 that appear as differences in figures can often be used to turn or position the product. So our "standards" that we are using to develop this Qve Process are in effect driving the outcome. They don't really become standards until they are proven with certainty within the actual configurator.

Now according to the way our Progression is run on the Cube, the First Run gives us our Transition base. And it is here that there is a Tally and comparison to our "Standard" Model. We haven't yet called up our subassembly and we have not put in any elements that would change the basic glass we are working with; This is the setup stage where the string is applied to the virtual model of the object.

In an untried operation we should simulate this many times before taking the object into production. All of the sequences that lock in the material and apply the subassemblies and any fusion elements should be tested without applying cost or damaging the materials.

We can put in sequencing series that enable all of the parts of a machine to correlate with one another by inputting a time bottle and setting it to run off of the permanent manifold or lie symmetry that will continually process through the operations and indicate the functional status of all the parts. This is called the Gini process.

As we move to the subassembly state, we want to put in our proxy girl to take measures on several (milestones or) progress points and to slow or stop the process if something is out of order. Since the process will be very fast, we can hardly expect to change it without an Intelligent Artiface to argue the task for us. Proxy moves are discussed here: Managing the Adaptive Cycles of Qve

We know that our concept of producing Qve Virtual Machines is futuristic, but that is what makes the process both interesting and pointing to the way we should address Quantum Adaptation in the future.

In the meantime we can learn from following through with the hypothetical process thinking in the same way that computers were emulated from the beginning. We are working on the Quantum Virtual Cube branch production emulation as we learn to encrypt and think through the use of manifolds and lattice arrangements.

We have to be good data miners and minders in order to get the operations out of the box. That's why we are reminded that Lie Groups run like wheels within wheels in keeping track of time even as the machine is being delivered it should be informing the Team of the process. The Lock sequence may be the most important fact regarding tensor structures there is and that needs to be closely encrypted.

How the machine operates with a field can also be important because many machines require platforms.

Some machines may apply sequences from the field. So there are many Lie Group Timeseries to think about And out of the random patterning of the group encryptions can be produced.

We want to study the Strategy for working through this process more in depth, next. We had decided on a Manifold strategy for this Machine and will continue the discussion...

Wednesday, December 21, 2016

PDS Study of Motions in Time Related Conditions

PDS Features described in terms of Dynamic, Dimension, Delivery

Production: 1D, 2D, 3D, 4D, 5D, 6D, 7D, 8D? Yes, 8D

We have been studying the effects of QLD Energy on the Motion related Activities of Production Cycles. QLD is the use of an artificial or flat atom theory of the Quantum Cube. We are measuring the potential effect of massless electrons motivated by the quonic directed activity of nano-packaged energy (also called Green Technology.) We have considered that the QLD String bios could be flat with the persons moving in a Virtual Field in a different form of Quantum Universe called a Cube.

Before we discuss further let's examine some ideas about Motion:

Wikipedia Background and Free Dictionary:

dy·nam·ics‌ (dī-năm′ĭks)
‌n.‌
‌1. ‌
‌a. ‌ ‌(used with a sing. verb)‌ The branch of mechanics that is concerned with the effects of forces on the motion of a body or system of bodies, especially of forces that do not originate within the system itself. Also called ‌ kinetics‌.
‌b. ‌ ‌(used with a pl. verb)‌ The forces and motions that characterize a system: ‌The dynamics of ocean waves are complex.‌
‌2. ‌ ‌(used with a pl. verb)‌ The social, intellectual, or moral forces that produce activity and change in a given sphere: ‌The dynamics of international trade have influenced our business decisions on this matter.‌
‌3. ‌ ‌(used with a pl. verb)‌ Variation in force or intensity, especially in musical sound.
‌4. ‌ ‌(used with a sing. verb)‌ Psychodynamics.

dynamics‌ (dī-năm′ĭks)
ki•net•ics‌ (kɪˈnɛt ɪks, kaɪ-) (NOT QLD)

‌n. ‌ (‌used with a sing. v.‌)
the branch of mechanics that studies the actions of forces in producing or changing the motion of masses.

Kinematics‌

Kinematics applies geometry to the analysis of movement, or motion, of a mechanical system. Rest and motion are very relative terms as far as the frames of reference are concerned. So, while proceeding with any of the problems in kinematics one should be very careful about the frame of reference. ⁽5⁾ The rotation and sliding movement central in a mechanical system is modeled mathematically as Euclidean, or rigid, transformations. The set of rigid transformations in three dimensional space forms a Lie group, denoted as SE(3).

In mathematics, a ‌Lie group‌ /ˈliː/ is a group that is also a differentiable manifold, with the property that the group operations are compatible with the smooth structure. Lie groups are named after Sophus Lie, who laid the foundations of the theory of continuous transformation groups.Lie groups represent the best-developed theory of continuous symmetry of mathematical objects and structures, which makes them indispensable tools for many parts of contemporary mathematics, as well as for modern theoretical physics.

Planar motion‌
While all motion in a mechanical system occurs in three dimensional space, planar motion can be analyzed using plane geometry, if all point trajectories are parallel to a plane. In this case the system is called a ‌planar mechanism‌ (or robot). The kinematic analysis of planar mechanisms uses the subset of SE(3) consisting of planar rotations and translations, denoted SE(2).The group SE(2) is three dimensional, which means that every position of a body in the plane is defined by three parameters. The parameters are often the x and y coordinates of the origin of a coordinate frame in M measured from the origin of a coordinate frame in F, and the angle measured from the x-axis in F to the x-axis in M. This is described saying a body in the plane has three degrees-of-freedom. SE(2) is the configuration space for a planar body, and a planar motion is a curve in this space.

The absence of evidence is not the disregard of Truth. If what we say is conjecture then to the extent that it is backed by the current level of science it is not a difficult leap forward to see the next point in an adaptive context. We have been led to the subject of QLD Energy and have pursued how to Build using particles as the primary basis or starting point of the Qve Virtual Machine Production capability.

The current level of a quantum device is called a Dwave machine. This is far and away from a Dwarf Star machine and so we can't point to our last post as the incredible technology of next year. However, the idea of Virtual Machines operating in a different Quantum design than the current universe based on modern approaches to the problems of Time and Motion are not out of the realm of the Owner's pocket (meaning Owner of this Universe) or his secondary stakeholder's to his processes. And so we have been pointing to what a change in the underlying schema of the Universe may mean to us. We believe that Time and History, storytelling and prophetic content points to the buildout of a different kind of quantum basis. Historically it was the engineering of the GAP (the Cumberland Gap) that ended the Civil War. This is only ONE time related marvel we can point to.

In terms of Power Distribution the theory of Green Technology and other Energy related topics points to a redistribution of power as packaged energy allowing it to have multi-functional capability that is dormant in the present system. We also believe that the tact taken with everything regarding the human dimension is based on a packaging concept that is based on a different string format of the bios system.

The smooth operation of a Quantum based system will rely on the solid state delivery of energy that can scale and be motivated with direct applications. We believe that Photosynthetic Virtualization will give everyone the opportunity to rework problems of making and defining the effect of molecular composition and design, using lens and camera based operations. Sound is also a primary motivator in Quantum and can be used in various formative ways.

Many devices and rearrangements of META based materials will produce objects, machines and scalar based architectural designs previously impossible. This is why machine based learning has been invented, but it doesn't even approximate what Intelligence can become. We don't find these things as ideas to be feared. We have been led to study how production processes could be adapted in quantum and we have documented much of the idea.

Thinking in terms of Green Technology we continue to theorize on this strategy. We see everything differently than it may be presented in MEDIA because we think about gauge and processors that fit and gear quantum to a level of outstanding Intelligences.

Like a circle in a spiral, like a wheel within a wheel
Never ending or beginning on an ever spinning reel
As the images unwind, like the circles that you find
In the windmills of your mind!

Songwriters: ALAN BERGMAN, MARILYN BERGMAN, MICHEL LEGRAND

Next we want to explore STRATEGIES of the web of things.

and rethink: circle in a spiral, wheel within a wheel, a Never ending, beginning, ever spinning reel, images unwind a System we have Mined (raising up the Functional Branching of the Quantum Cube)

Sunday, December 18, 2016

Manifold Delivery in Qve

MDS

Time and Engineering the Manifold: Virtual Delivery Systems

SRGEN: Time and Maps: Scoping Requirements

GAP Qve

MAP 1 PRODUCTION

In order to be certain how many views are correctly required in a Manifold Virtual Delivery System in Qve we have to finish determining the Branch Integration. We are not certain if it works like 6 x 2 x 2 or if it requires 6^2. It is also possible that 60 Views may result from the overall requirement. But we think that by completing our task, the integration of this process will help us to understand it better. So we have more steps here to take, since in our last blog we only extended the Significance Function.

Next we have to take a look at our Board and see if we can wire it. So since this is a lot of work... we'll have to post our results later. Second Map of Production, side 2 of 4 12/20/16

Map2 Production

When we first began working with this type of conversion we didn't realize that Volume is removed from the process because Virtual Machines can be cloned. Space is also removed except for delimited spaces in tiers, etc., but there are still inner branch mechanics to consider.

We have to think about Time many different ways in order to consider both the Timeline and the Manifold Processes.

Measures of Time: (Wikipedia) Position, Spin (Timeline) and Rotation (Work)

transition between two electron spin energy levels of the ground state of the ¹³³Cs atom
the Global Positioning System in coordination with the Network Time Protocol can be used to synchronize timekeeping systems across the globe

Changes: The electron spin state will be based on the Quark composition of QLD and positioned with Quonics.

Progression, Clock (Manifold)

The progression of Time looks something like this in production where 2 x clock time starts the progression at 72 and progressing like a metronome to time the outcome: 0.227272727. If we use three times clock time we represent the clock as 33 related to the production Map (see Top illustration.)

The hourglass uses the flow of sand to measure the flow of time. They were used in navigation. Ferdinand Magellan used 18 glasses on each ship for his circumnavigation of the globe (1522).^[31] Incense sticks and candles were, and are, commonly used to measure time in temples and churches across the globe. Waterclocks, and later, mechanical clocks, were used to mark the events of the abbeys and monasteries of the Middle Ages. Richard of Wallingford (1292–1336), abbot of St. Alban's abbey, famously built a mechanical clock as an astronomical orrery about 1330.^[32]^[33] Great advances in accurate time-keeping were made by Galileo Galilei and especially Christiaan Huygens with the invention of pendulum driven clocks along with the invention of the minute hand by Jost Burgi, Wikipedia

We often demonstrate time like this: A position that denotes the progress made on a Timeline in meeting pre-determined requirements. Motion in terms of Time has these motions: Spin, Rotation, Progression, which includes Work. The determination of the correct level of work is Speed and Distance. The Progression is responsible for creating the Fulcrum or Leverage in the System. The smaller the unit of measure of time the more likely accurate the measure will be, in order to manage the curve.

What we are saying is this: It is not enough to differentiate the Cube. Since the timing of everything has to be measured as a requirement of RUN, determining the requirements of the Manifold is just as important as these two Quantum Cube Performance Mechanics are part of the System. So that while we are defining the Conversion that takes place within the Cube, we also need to study the requirements to generate these Progressions and other norms of the Cube.

If Circumnavigating a sphere was all that was required 18 branch measures may be enough. Taking a developmental View of the manifold, requires us to consider that 18 x 2 is Significance. But there are three more measures that take into account the motion of the progression in and around the cube.

Significance plus motion is 36 + (22 x 2) = 80. We believe these are columns and don't represent Views.

There are both Horizontal columns and Vertical Columns in the Quantum System. The top of the cube and the bottom of the cube don't count as a View. The cost rate applied to String is 44. As we are producing product in the ONE System, string is generated. So the QLD Energy Cube is funding the Production Cube. This is somewhat like our universe but it is a direct refresh rate rather than a translated process of multi-task and formative direction. In order to achieve a high degree of perpetual motion in our universe a lot of push energy has to be invested, and this is an inefficient type of architecture.

PRODUCTION

In the ONE System the turning, tuning and timing of production is immediate and defines the Work. But the entire System will Spin, Rotate and have multi-level Progression within it. So the Manifold has not only Work related functions but Maintenance functions related to System Architecture. We have used Business Conversion as the Production method to enable us to emulate Work. But this production method includes the entire business process.

If you study branch numbers long enough you begin to see more than one pattern here including a mapping pattern which turns a progression. The maps are as important as the numbers they progress.

0.227272727

We have also studied the steps created in the patterns related to Variable Rate Demand. Changes in the patterns of the way production metrics present themselves have a definite effect on the way the system operates. So we have looked at the idea of rotational requirements and time distribution.

This is why one view of the branching is not enough to be certain that the requirements will be met correctly.

While we have emulated Time on the Manifold to develop this idea in our scope, we are working at the manifold idea now from a different point of view. Scale is only one aspect of Time and Motion. This is primarily arranged as speed to the Post:

BACKGROUND: Two concepts of Production include Events and Time-Stamp

Chronology

Main article: Chronology

Another form of time measurement consists of studying the past. Events in the past can be ordered in a sequence (creating a chronology), and can be put into chronological groups (periodization). One of the most important systems of periodization is the geologic time scale, which is a system of periodizing the events that shaped the Earth and its life. Chronology, periodization, and interpretation of the past are together known as the study of history.

Time-like concepts: terminology

The term "time" is generally used for many close but different concepts, including:

instant^[54] as an object—one point on the time axes. Being an object, it has no value;

time interval^[55] as an object—part of the time axes limited by two instants. Being an object, it has no value;

date^[56] as a quantity characterizing an instant. As a quantity, it has a value which may be expressed in a variety of ways, for example "2014-04-26T09:42:36,75" in ISO standard format, or more colloquially such as "today, 9:42 a.m.";

duration^[57] as a quantity characterizing a time interval.^[58] As a quantity, it has a value, such as a number of minutes, or may be described in terms of the quantities (such as times and dates) of its beginning and end.

Production Events must be recorded and they must be time-stamped. As the Object moves through the Production Events in a progression a value is incurred related to both the Cost Activity of being funded and the Benefit Activity of gaining a delivery position. If an object had no benefit it would not be delivered. The only way to recover cost is to generate the leveraged value of delivery to a market position. Measuring the requirements and managing the process requires RECORD KEEPING.

There is also within the same process the requirement to invest funds in an adaptive process that will meet the next level of demand in market position. A platform is maintained in order to produce a value for subscribers and return a leveraged profit to the owner. A fully leveraged system is required and the ONE System has as its primary advantage both the thru-put equation and the cost-efficient elimination of redundancy. In terms of time this is very streamlined. The String based theory of QLD is able to generate META materials as part of a production cycle. There are no gaps in the supply chain (normally, under learning maturity progression.)

PI ANO

The interpretation of this expression is a Power Intelligent measure of a cycle as it runs to completion, or GO. What is the unit of GO?

Formula ONE as we have often pointed to is concerned with making the unit of GO a continuous cycle. It takes a considerable workforce to deliver a quantum in a mega efficient unit of GO.

The one thing we have learned is that if you want to perform something well you need to practice well. And so our work on Formula ONE, the Manifold and "GO" is a learning exercise. It also helps us monitor the thinking or philosophy of Time and Materials that has changed over the years.

Many of the changes which point to Qve and Quantum Formulation started here (1944 plus 72 = 2016+). We believe that the Theory of Everything is wrapped up in the forensic delivery of a quantum based string generation and production delivery system. Green Technologies point us to this delivery system.

To understand in more detail we need to think about MEDIA Delivery or Production in that the elements are arranged around timelines and Server based solutions. Then a more complete picture of how Qve Virtual Glass, Fusion Elements and Design work together with Photosynthetic Virtualization.

Now we have a view as to subassemblies and the manifest delivery of the production meeting together in the manifold design to complete the process; Time and Active dimensions of Motion.

However, this is so mega-plex in design, Game Theory has to be employed.

next, discussion of Game Theory

We will return here with additional analysis of the 3 remaining map views...

We reviewed our Metrics to see if they correspond to the cube and to the gap. All of our Process RUN to Pascal Cube looks good so far, with a better Grover Progression.

Interim Analysis