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Why we wrote this paper

Recently intense research is being conducted on miniaturization and memory
compression algorithms. It is perhaps the notion that we can bypass billions
of years of evolution* by simply computing variables which are favorable and
do resemble natural phenomenon. It has been suggested that perhaps machines
can be built to replace thinkers so that the octogenarians who have been
entrusted with certain old but forgotten knowledge can comfortably age
without enduring the winter years.

Question that we need to be asking is why do we not consider imagination as
part of the evolutionary equation. Is the ability to think freely somehow not
politically correct?
Are we some how going to be sold, on the idea that, a dozen or so computing
Recipes, can replace millions of years of evolution? Should we believe
In making faster and faster processors because they are good fun?

There seems to be very little or no consideration where the real
problem is or what alternatives there might be in telecommunication, the
required circuitry and protocols that govern communication. We are ready to
pat ourselves on the back for coming up with a new formula that will try to
show from the cognitive aspect that natural neural networks can be and do
quantum computation and error correction that takes for granted as
autonomous. It will be clearer as we pursue an approach founded in
philosophy of computation and not in its attributes of the recipes.

INTRODUCTION

This Paper Is divided into
twenty four chapters
each chapter consists of 5 sections
each section contains 7 pages

Abstract

The biological mind 1,2,3,4,5,6,7 encompasses all organisms that existed from
the earliest time, from the first molecule that took organizational order to the nth
symbiotic group that has yet to crystallize in our imagination.
Our apparent imposed compartmentalization of molecular ordering obeys rules
that may be an addition to a more subtle, single universal ordering phenomenon.
The clues to this somewhat elusive order have been emerging in the recent years.
With the advent of ever powerful computational tools and skillful observation of
savant learning process, we have become alerted about the coexistence of biological
structures that share different environments.
Experimental results obtained from cosmological events show findings, suggesting
that evolution may not be a linear process as we once believed.
Is evolution a non-linear symbiotic nonlocal reaction to local phenomenon or
reaction to environment that is primarily driven by the need to consume and replicate?

Biological parts for computers are abundant as they are varied.
Organisms that exist in a single state of revolving motion, only revolving in a positive or a
negative direction.
Organisms depend on the presence or absence of magnetic field, or presence or absence
of light, presence or absence of water, presence or absence of electric field and so on.
All mechanisms that humans create or imagine are essentially exist without being part of a
functioning factory.
What we do is devise schemes that use solids to bring about computation because the
need exists to have something in our hands to touch and feel.
The act of computation can be conducted by symbiotic arrangement of organisms that coexist without
forceful intervention, exactly like baking cookies without having to bake them.
Our bodies are a good example of multi-organizational symbiotic environments.
If we are right then the DNA that we call the building block of all life is not a blue print for all life but
repeater of all life. The DNA does not repeat the same signal over and over since its environment
is constantly changing.

We may yet discover nano-size life forms. The organic assemblies may have very short life
span. Forced by these tiny life forms other surrounding molecules may be forced to move in a
certain direction by the virtue of being applied by extreme amount of kinetic force.
To predict what type of life we may encounter the vastness of quantum or Newtonian space is best
left to the imagination of symbiogenetisist.

A linear evolutionary process effects organisms that are participants in a given time frame.
Non linear evolution of organisms is a spontaneous and homogeneous process where the organism
changes in structure, independently of any constraints in chronology. The later is brought about by
cues that may be an interpreted as an answer to a nonlocal event.
This cue may consist of not one but many mathematical elements that merge as a part of a what
we call the Genesis engine.

Being the case, can one can argue that the present hypothesis of the cosmological expansion
is directly linked to an evolutionary prime?
Evolutionary prime number is a very large number that can only be divided by itself and one.

Are changes in any system agreed upon mutually for each organism undergoing transformation?
in an nth dimensional space in advance, before the formation of the biological structure In accordance
with Bohm-Quantum mechanical model?
The idea is not a violation of objects not permitted to occupy the space.
Does The non-local transformation aid and determine biological events or markers? Can the
"Missing link" be explained by the Bohm-Quantum mechanical model?
Imagination remains an ingredient that human species possess but do not refine.
The only key that enables us to answer the question of if indeed we are or are not part of a much
larger symbiotic process or an ever evolving forms is to understand symbiogenesis.
Ref: Concepts of Symbiogenesis and the Emergence of Life-Forms on Land
http://ecoethics.net/bib/1997/otca-007.htm
A being that is capable of living in three different environments may share characteristics such as
appearance and intellect but differ internally, depending on its position on the morphogenetic tree.
The being could for instance possess the ability to breathe three different types of gases
Physical evidence so far is that a pair of photons, from a down converter source end up merging
as one regardless of their distance. Technically the well-known experiment by Einstein-Podolsky-Rosen,
(EPR) for short, was not possible to conduct due to lack of technical expertise and equipment.
The EPR test has only been made possible recently.
Ref: "http://www.aip.org/enews/physnews/1998/physnews.399.htm#1"
GRS1915+105: The FastestFireball in the Galaxy:

Chapter One Astrogarden® Project R&D Philosophy

Section 1: Archaeoastronomy

Section 2: Nonlinear Communication “Non-locality”

Section 3: Short and long term memory

Section 4: Use of Astronomical events for marking mnemonic events

Section 5: Implementation of Path oriented Learning

Chapter Two Astrogarden Automata

Section 1: Automation and mathematical discoveries

Section 2: Role of automata in path oriented learning

Section 3: Assimilation of data and learning barriers

Section 4: Seeing numbers as objects in a group

Section 5: Adaptation of unconventional numeric system

Chapter Three Astrogarden Mnemonics

Section 1: The role of hippocampus

Section 2: Element of surprise

Section 3: Balance

Section 4: Use of representational and allegorical tools

Section 5: Childhood memories and hard wiring

Chapter Four Astrogarden and Recycling

Section 1: Materials and recycling

Section 2: Recycling and environment

Section 3: Benefits of part standardization of and cost control

Section 4: Survey of materials in building and construction past and future

Section 5: Principles of symbiosis

Chapter Five Astrogarden Power Plant Considerations

Section 1: Power Consideration for large independent structures

Section 2: available energy resources and CO2 emission

Section 3: Cost of energy Availability and ease of access

Section 4: Economy and Use of local power source Versus power delivery with Large generator .

Section 5: Symbiotic use of energy/

Chapter six Astrogarden site considerations

Section 1: Site Locations And Degrees of freedom

Section 2: Exploration of Self Sustained Structures and Magnitude

Section 3: Design and Planning consideration

Section 4: Data management and security

Section 5: Modular approach versus large independent assembly3606

Chapter Seven Astrogarden Data Management

Section 1: Organizational Profiles

Section 2: Scheduling activities

Section 3: Parallel coordination

Section 4: Total visibility and coherence of data

Section 5: Usage statistics and trouble shooting

Chapter Eight Astrogarden Organization

Section 1: Successful organizations

Section 2: Brain storming

Section 3: Collective wealth and happiness

Section 4: Autonomous enterprises and model societies

Section 5: Collective support and individual freedoms

Chapter Nine Exploring Technologies

Section 1: Available building technologies

Section 2: what is at stake

Section 3: biological innovations

Section 4: benefits of Nanotechnology & nanomanufactuing

Section 5: political implications of networked Nanotechnology

Chapter Ten Financial Imputes

Section 1: Securing global safety through common theme parks commerce.

Section 2: Large scale refitting technologies for a global economy.

Section 3: Elimination of hunger and racism via a global safety net.

Section 4: Real-time global power sharing.

Section 5: Enhancement of global monetary system.

Chapter Eleven Role of Industry

Section 1: Integration of technological resources.

Section 2: Establishment of power sharing goals.

Section 3: Self sustaining industrial distribution.

Section 4: Relinquishing compartmentalization.

Section 5: Expanded horizons.

Chapter Twelve Inclusion of all races Not Exclusion

Section 1: Limiting factors in global economy

Section 2: Boundaries of economical growth

Section 3: Distribution of wealth

Section 4: Differentiation of specialization and racial en equity

Section 5: Boundaries of accepted racial philosophy

Chapter Thirteen Geodesic Structures and Purposeful Models

Section 1: History of Geodesic Structures .

Section 2: Natural Geodesic Structures.

Section 3: Suitability of Geodesic forms in offshore construction.

Section 4: Materials used in geodesic structures.

Section 5: Strut stability & geometry.

Chapter Fourteen Role of a Multi national Navy

Section 1: Enforcing Equitable Maritime Law

Section 2: British and American Naval Influence

Section 3: Non Combative Enforcement

Section 4: Perpetual Fear

Section 5: Classified Boundaries

Chapter Fifteen Fundamentals of Harmony

Section 1: Influence of Geometry and Classical music in childhood schooling

Section 2: Perception of space

Section 3: Importance of precision

Section 4: Ordered learning potentiality

Section 5: Template for a new media

Chapter Sixteen Essentials of survival

Section 1: Signatures of mass migration.

Section 2: Geological markers of mass extinctions.

Section 3: Mass survival strategies through just-in-time acquisition of knowledge.

Section 4: Perpetual evolution vs/conservative methodologies.

Section 5: Periodic adjustments.

Chapter Seventeen Modular Thinking

Section 1: Nano Symbiology.(ways to incorporate symbiosis in small ` creations)

Section 2: Cymatics.

Section 3: Flexible Nonlinear Load Bearing Transceivers.

Section 4: Global sensometry. (Data that is transmitted to structures if and when amount of load is about to change on a joist)

Section 5: Monitoring the workflow through internet.

Chapter Eighteen Investigating Architectural Ideas

Section 1: Applied geodesic structures

Section 2: Constants and non-local phenomenology.

Section 3: Floating structures and shore based commerce.

Section 4: Rapid construction and deployment of offshore dwellings.

Section 5: offshore entertainment economics.

Chapter Nineteen Self reliance and sufficiency

Section 1: Astrogarden characters help each other when they are safe to do so.

Section 2: Dissemination of knowledge based on path oriented learning.

Section 3: Just in time action based on non local access to database.

Section 4: Internet protocols & virtual manufacturing.

Section 5: Virtual tools

Chapter Twenty Water Purification

Section 1: Modular approach to water purification.

Section 2: Techniques in desalination.

Section 3: Lessons learned by NASA.

Section 4: Astrogarden theme park water usage and recycling factors.

Section 5: Emergency supply reservoir.

Chapter Twenty one Intelligent Architectural Grids

Section 1: Survey of 20th century structures and their performance under load.

Section 2: Space born structural design and load distribution.

Section 3: Holistic responsive load bearing structures.

Section 4: Definition of integrated load specific structure.

Section 5: hypothetical grids.

Chapter Twenty two : Children's Environment

Section 1: Supervision built in environments.

Section 2: Ergonomics and path specific concepts.

Section 3: Lighting and transparency of environment.

Section 4: Familiarity and form.

Section 5: Plant Vegetation Usage.

Chapter Twenty three : Ergonomics for Unstable structures

Section 1: Our definition of a unstable structure: (Structure that forces one to adjust one's stability in order to remain standing.)

Section 2: Reactive ergonomics for perpetual load distribution.

Section 3: Elastic and super elastic elastomer.

Section 4: Symbiotic ergonomics.

Section 5: Bio-elastomeres

Chapter Twenty four Structural Integrity and Safety

Section 1: Control of failure in large structures.

Section 2: Acceptable failure tolerances.

Section 3: True and false expectations.

Section 4: Definitions of a failure free structure.

Section 5: Auto response to failure.