CHAPTER 11. A
META-LANGUAGE AND METAPHYSICS
FOR [HX] ASSEMBLER.
This chapter will
present working definitions and models for both simple and complex transactions
in the cosmos.
1. Process
descriptions for [T] essential numbers.
2. A
syllogistic association model.
3. Synthetic
Biology and Field Theory in Natural Systems.
4. Universal
Process Model.
5. Scalar
Relativity Model.
These models are
tools within the language [HX] and are the foundations of a universal systems
theory. They allow a framework for the mechanical and chemical engineering of
self-conscious synthetic organisms.
PART 1. Process
descriptions for [T] numbers.
There follows eight
process descriptions for the eight tripartite atoms of the language [T].
1. MACRO = 0, MESO = 0, MICRO = 0.
In the system, all is
in flux and there is no relativity or congruence between the context, the
object and its activities.
There is currently no
contextual environment for the development, redevelopment or continuation of
any system and the qualitative aspects of evolution within this dissonance have
no emergent aspect that can be measured at this time according to current
empirical process.
2. MACRO = 0, MESO = 0, MICRO = 1.
The limited integrity
of the past has had the qualitative capacity to emerge an asset, the Micro, but
at this time now, (presently at timeX), the system has no systemic integrity.
The emerged asset, though, having persisted from a previous time interlude is
currently of high quality and integrity.
3. MACRO = 0, MESO = 1, MICRO = 0.
The lack of supply of
systemic precursors caused by the discontinuity within the context has had no
detrimental effect at this time, timeX, on the integrity of the persistent
systems' mechanics. The facilitation of systemic growth, though, by the Meso,
has ceased because of this lapse in the supply of precursors to the systemic
mechanism and therefore no new assets and tools have been produced for the
evolution of the system.
4. MACRO = 0, MESO =1, MICRO = 1.
The lack of systemic
equilibrium and integrity due to the collapse of the precursor supply to the
equilibrium from the aggregates of the context has not interrupted the
integrity or persistence of the mechanical attributes within the system at
timeX as it continues to emerge asset.
5. MACRO = 1, MESO = 0, MICRO = 0.
At timeX, the
present, an integrated supply of systemic precursors has emerged as an event,
the Macro, but has no telic properties at timeX such that any new mechanical
attributes have organised or have had such time that would have produced a qualitative
asset as per conditions of observation.
6. MACRO = 1, MESO = 0, MICRO = 1.
At timeX, the
present, an integrated supply of systemic precursors [Macro], have emerged a
qualitative event [Micro] - though the
mechanics that supplied it were transparent to observation.
7. MACRO = 1, MESO = 1, MICRO = 0.
At timeX, the
present, the contextual supply of systemic precursors to the emergent mechanics
of the Meso and its self-regulating equilibrium is of insufficient gradient,
velocity and content to produce a measurable qualitative asset of any integrity
under the assumed contextual conditions.
8. MACRO = 1, MESO = 1, MICRO = 1.
At timeX, the
present, a fully emergent, self-regulating system, producing assets of
measurable qualities through viable mechanical integrity is observed to conform
to the criteria of judgements imposed by the observations and criteria of
systemic success.
The eight
descriptors, the eight tripartite atoms of the language [T] at time1, describe
an event deltaT at time2, producing a set of 64 logically real essential
numbers that are unique state descriptions fully describing every change of
systemic integrity at time1 and time2.
The one rule of
assumption that drives this set of rules of derivation is that in all
(universal) cases, a larger system of aggregates, universally and autonomically
contributes to a smaller system through a common medium with also the
intercession of at least a common other.
PART 2. A syllogistic
association model.
The [HX] Tautological
Syllogism.
In syllogistic form,
the propositional variables or industrial conjecture can also state a true
'tautology' as regards the continuity of systemic functions within the
perceived empirical associations and labels, attached to the functions being
observed.
The Systemic backbone
of Macro M components, that drive the Meso comprised of M and also in
regulatory equilibrium with S introduce an equilibrium component, P to the Meso
such that the Meso MS drives the emergence of a qualitative asset SP.
The [HX] Syllogism.
MACRO MP
MESO MS
MICRO SP
This singular
tautology is non-arbitrary and is not one of the many styles and forms of
tautology derived by Leibnitz. This is because the ordering and precedence of
the lettering is deemed irrational in terms of [T]. As a language of function,
[T] does not attend to e.g. banana or orange, or, orange and banana, both being
fruiting bodies of biological systems within the botanical class of
angiospermae. [Vines and Rees, 'Plant and Animal Biology, vol. 1.', edn.4, pub.
Pitman, 1972, ISBN 0-273-25222-4]
The underlying common
process is both are fruit, one of a tree, the other of a herb (banana). The
process description is the same in both cases however. [see chapter 12]
The fruit content is
divergent also, as neither generic oranges, nor generic bananas, are actually
absolutely identical in any logical way.
M in this simplified
analogy is the predominantly Carbon backbone of the plant systems Macro, where
P is contextual Oxygen, and S is systemic Meso Water. The evolved asset driven
by metabolic oxygen is the predominantly water based asset of the plant
metabolic system.
i.e. Major
Premis MP, Minor Premis MS, Outcome SP.
The order of
precedence for lettering and other arbitrary labels is entirely unimportant in
[T] descriptions.
PART 3. Synthetic
Biology and Field Theory in Natural Systems.
In [T] and its
transaction model, the properties of electrovalence - the movement of energy by
Fajan's Rules extends across the electromagnetic spectrum from approximately 10
to the 21 hertz to 0 hertz - including in order of decreasing frequency; gamma
rays, X rays, ultraviolet, visible, infrared radiation, microwaves and
radio-waves.
The interaction or
inter-conversion of electric and chemical phenomena produces an effect called
electromotive force, or EMF. This energy can be converted reversibly from;
chemical, mechanical or other forms of energy into electrical energy in some
mechanism or Meso.
There are two
transaction types in any given context that has a system under observation.
These common and relative transactions can be modeled using the [HX] syllogism.
Z = Water, M =
Specific Ions, S = Plant System, Q = Physical Context,
P = System Product
and Emerged Asset of Scaling Exploitation.
In the aggregate
context where: [Z, M, S, P] % Q + [t1 ... tn.]
[HXmicro]
[HXmeso] [HXmacro]]
SYSTEM PRODUCT OBJECT SYSTEM CONTEXT
(Q~3S = t0)
~2"MS
~3"MZ, t3
~1Z ~2M ~1Q ~1Z
~2"MS
~3"MP ~2!3Z ~2+?#¬S, t1 ~2Q ~2M
~3"ZP
+ (?~3S), ~3"!3MS, tn ~3M~1S,
t2 ~3M ~3Z, t2
The common process
being exploited by piggy-back between the object system S (plant) and the
context is the fact that in the evaporation of massive ground waters Z
percolating through the geochemistry, from relatively large scales within the
geophysical context there is a set of necessary ionic ingredients M, making
progress from greater to lesser scales of magnitude. This is driven by osmosis within the soil and atmospheric
conditions for evaporation.
i.e. ~2M >> ~3M
at time 2
The niche for plant
growth can be described in terms of the [HX] syllogistic forms as; ~1Z
+ (~2Z + ~2MS >> ~3MS) >> ~3Z
The evolutionary
assets of the context system, e.g. its; soils, physical chemistry, geology,
seasons, temperature, pressure, light levels, altitude, solar activity,
ecological global dependence, sunspot activity, relative ocean currents,
orbital irregularities, planetary tilt, albedo, tectonics etc.
In the context of relative
scales of interactivity within and between the object system and the context
system, the object system is always embedded and nested within the scales of
transaction in the context.
Persistent
over-supply (t1 ... tn) of the aggregates Q, necessary to emerge and replicate
complexity within the system S, will produce the emergent product e.g.
seed, at t3. (t3 = ?¬S) to be regrown
at context time Q = t4. (where t4 =
t0).
The object system
must attenuate and defend itself from the greater scales of similar aggregate
and their activities within the context.
It must pay a
systemic toll to do this whilst converting meso quantities of context into
structural assets such that the system becomes viable and macro.
The
molecular version of [TREES] - 'Tripartite Relativity Expert System',
can use processes
such as electro-kinetics. These are the electro-dynamics of heating effects and
of current distribution in; electric network electrolysis, chemical change and
decomposition produced in an electrolyte by an electric current.
Also,
electro-kinetics come from electromagnetic interaction - a form of interaction
between particles and or fields.
Analogical reading of
the emissions at the CPU by e.g. a photonic array and, or, the crystal can be
interpreted to produce a tautological outcome in whatever context.
The benefit is that
if the context of the industrial crystalline environment changes such that
higher stresses on the atomic elemental integrity is induced, i.e. the
participation of certain elements is taken out of the running by chaos, then
depending on the damage and or context;
If the change of
context is relevant and desirable then the aggregates may output a different
ontological result:
a) Aggregate Ontology
1 Oi
b) Aggregate Ontology
2 Oii
e.g. certain changes
of state and molecular stress may cause the relationships in Ontology (i) to
cease.
Under these
conditions they may seek to relate to other aggregates for discharge of
potential difference, and thereby select other routes through the crystal.
Simulate O1 with O2
relationships, or move onto O2 agenda.
The UPA model when
instantiated in [H] Logic is comprised of a structured set of nested IPO boxes
labeled as letters of the alphabet to which; corresponding elemental
aggregates, objects, compounds etc with their corresponding voltage or energy
activity scales and ranges within any given context are added.
This will enable any
and every process to be modeled.
e.g. OBJECTS, ACTIVITIES AND QUALITIES HAVE THE
SAME ROOT.
ATOMIC MACRO NEUTRONS NOUNS OBJECT
ATOMIC MESO PROTONS VERBS PROCESS
ATOMIC MICRO ELECTRONS ADJECTIVES ACTIVITY
From a set of atomic
rules of interactivity it becomes possible to design a physical description
whose processes can tie directly into the assignation of natural language.
From [Brown GI,
'Introduction to Physical Chemistry', Pub. Longman, 1972, ISBN 0-582-32131X.]
Observed chemical
aggregate behaviour has discovered and measured various types of interactivity.
1. the energy input required to create, atomise
and disassociate free elements. [Brown, pps. 172.]
2. 'ad hoc' intermediate bonds that are
unassigned. [Brown, pps. 185.]
3. Chains of electrical association between
atoms in this agglomeration can be set up using expectations of properties such
as: [Brown, p.171-172.]
(i) paramagnetic
substance - forces of attraction and repulsion:
e.g. north pole] ››››››› [southpole
(ii) diamagnetic
substance - forces of attraction and repulsion:
›
e.g. north pole] ›
[south pole
›
(iii) changes in electron affinity.
Using Fajan's Rules
[1924 CE] of ionic transmission i.e. that larger elements donate electrons to
smaller elements [Brown, p.165].
Molecular chaos in
atomic bonding may be used successfully as part of an industrial process by
exploiting latencies and other conditions of change and energy stress in
industrial contexts.
There follows an
ontological model of chemical changes between two pre-scripted chemical
ontologies within designed chemical aggregates of known properties.
The
Input-Process-Output box or IPObox A containing the two prescripted ontologies
1 and 2 - then transmits and inputs to, a second chemically prescripted
receptor - IPObox B.
The molecules used in
the process description for IPObox A using design ontology 1 either augment or
supercede the encoded process by becoming active as ontology 2 under industrial
stress either as chaotic wear and tear on internal structures and or, whilst
doing industrial work. The chemical aggregate designs do industrial work by
making use of the energies supplied by the change in industrial context to put
these usually chaotic and not dependably assigned molecules and their molecular
bonding capacity into a more stable and contributive state.
When exposed to
certain energy levels of known values, they become resonance hybrids through a
context supplied and driven by change of state.
These changes in
circuit tautologies, connectivity and relativity can be exploited by empirical
discrimination within the industrial process.
The output of the
industrial mechanism e.g. a sensor designed and comprised of these custom made
chemical aggregates of known properties, then reaches a second unit that
receives it physically as part of a circuit whose conditions of connection have
a threshold of expected and or recognizable potential difference.
The second sensory unit has been constructed
to a previously pre-determined design that allows several processes to be
activated dependent on the incorporated thresh-holds of chemical activity
utilising e.g. : intensity, frequency and consistency of signals from the
output of IPO box A.
Other kinds of
measurable biomagnetic responses in more complex biological aggregates have
been scientifically and industrially measured:
from Watson L, 'Supernature', pub. 1974, Coronet, ISBN 0-340-188332.
e.g's:
Barber TZ et al. eds.
'Biofeedback and Self-Control', Aldine Annuals, Chicago: Aldine-Atherton, 1971.
A collection of thirty-eight scientific articles drawn mainly from medical
journals dealing with psychosomatic and psychophysiological research.
Burr HS, 'Blueprint
for Immortality', London: Neville Spearman, 1972. Burr's personal record of his
discovery and exploration of the Electro-dynamic, or Life Field. Including full
bibliography.
Brown, FA,
'Persistent Activity Rhythms in the Oyster', American J. Physiology 178: 510,
1954.
Brown, FA, 'Response
of a Living Organism, under constant conditions including pressure, to a
barometric-pressure-correlated cyclic external variable.', Biological Bulletin
112: 285, 1957.
Brown FA, Park YH
& Zeno JR. 'Diurnal variation in organismic response to very weak gamma
radiation.' Nature 211: 830, 1966.
Bradley D, Woodbury M
& Brier G, 'Lunar Synodical Period and Widespread Precipitation', Science
137: 748, 1962.
Adderley EE &
Bowden EG, 'Lunar Component in Precipitation Data', Science 137: 749, 1962.
Chertok L, 'The
Evolution of Research into Hypnosis', In 'Psychophysiological Mechanisms of
Hypnosis', New York: Springer-Verlag, 1969.
Hartland-Rowe R, 'The
biology of a tropical mayfly 'povilla adusta' with special reference to the
Lunar Rhythm of Emergence', Rev. Zool, et Botan, Afric. 58: 185, 1958.
Kruegar A & Smith
R, 'The physiological significance of positive and negative ionisation of the
atmosphere.' In 'Man's dependence on the Earthly atmosphere.', New York:
MacMillan, 1962.
Burr HS &
Northrop FSC, 'The electro-dynamic theory of life', Quarterly review of Biology
10: 322, 1935.
Burr HS, 'electric
correlates of pure and hybrid strains of corn'. Proceedings of the national
academy of Sciences 29: 163, 1943.
Burr HS, Harvey SC
and Taffel M, 'Bioelectric correlates of Wound Healing', Yale Journal of
Biology and Medicine 12: 483, 1940.
Palmer JD,
'Organismic spatial orientation in very weak magnetic fields', Nature 198:
1061, 1963.
The second unit, IPO
box B, is a physical and chemical binary generator in that it will generate
testable responses that infer the presence of previously agreed qualities
within existing aggregates of known ratios and relativity in each industrially
designated physical section or partition.
This evidence of
continuity or discontinuity with time in known ratios and known relativities
and previously understood aggregates outputs at a higher than experimental
level of semantic modeling. This information about the experimental attributes
of IPO box A. has relevance to current state-of-the art conjecture about
current industrial empiricism and aggregate performances.
These empirical
observations of different adaptations of chemical performance within and
between the relativity of; chemical performance, scales, ratios and quality of
IPO box A and IPO box B aid in the translation of new chemical processes and
performance from one set of semantics to one that previously existed.
This effectively uses
older data and models of chemical ratios and aggregates to create and model new
materials and industrial processes.
New and old molecular
arrangements and assemblies can be designed to communicate with one another,
but in terms of what is known, rather than what is unknown.
This communication is
valid, therefore, in terms of how the known performs rather than what the
unknown unknowably does.
The android modeling
therefore does not produce new chemistry as such but makes use of known
chemical performance to deductively and declaratively assert tautology and
relativity within any circuits and switches.
In the android 2 design,
for example, layers of communicating interactivity are wrapped around a
skeletal structure - in a series of successive IPO box collectors, each
collecting the sum products of successive layers of specialised interactivity,
rather like a chemical onion.
As each successive
skin of IPO boxes collect the proceeds accrued at any given time from the more
external shells, they progressively sort their inputs into more and more
specialist activities and reactivities with which to inform the performance of
the skeletal mechanism and central processor.
In terms of the
viability, logic and description of chemical communication between different
internal layers under various kinds of chemical and ergonomic stress - the
presence or absence of 1's or zero's in any IPO box will reflect on the
magnitude of the contextual processes experienced by the mechanism and, also,
the internal chemical tolerances and ratios within the design of the mechanism
itself.
Using the rules of:
bio-magnetic resonance, field theory and resonance, Fajan's rules, ionic and
hybrid resonance etc various aspects of physically simple and complex
interaction can be accounted for.
e.g. circuit boards
using some Boolean expression: commutation, association and distribution.
Organic and
bio-magnetic adaptation.
The IPO box B is
absolutely configured to have 3 zones of energy receipt though within each
zone, an arbitrary number of sub-divisions could be incorporated.
These zones comprised
of designed chemical ratios and aggregates have 'a priori' known thresh-hold
levels of activity responses to stimulii.
The conditions for
the activation of the physical chemistry of IPO box B have been constructed
along the lines of the expected greatest output of IPO box A in terms of the
ergonomic stresses and contextual flux that it was allocated to measure.
IPO box B must also
be constructed such that the minimum operational threshold required would
constitute a representative minimum tolerance of the physical stresses within
the operational remit and tolerances of its destination technology and its
socially constructed consequences. This would keep it in an operational and appropriate
continuity. i.e. safe product design.
e.g. in extreme cold,
space, etc. e.g. Kelvin scale - some molecular activity would become redundant.
In terms of [T] or
[G] or [H], IPO Box constructs and components are directly relative to and
derived from the known context and its known ingredients with time. :
IPO box B with three
zones in some Industrial Context at time1.
OBJECT MACRO ZONE
1 = [ Z1.1, Z1.2, Z1.3, ... Z1.X .. etc]
PROCESS MESO ZONE
2 = [ Z2.1, Z2.2, Z2.3, ... Z2.X .. etc]
QUALITY MICRO ZONE 3 = [ Z3.1, Z3.2, Z3.3, ... Z3.X .. etc]
At input frequency X,
zone set Z.A.A in context C at time1 may be different in morphology,
distribution, enumeration and activity from the zone set Z.B.B at time 2, input
frequency Y in context C, due to contextually induced changes in chemical
states.
Zone set Z.A.A
contains in its ratios a process of interactivity belonging to a technology
that requires augmentation by a performance enhancement in its operational
consequences in a new industrial context.
It must collect data
from the physical consequences of the frequency ranges designed to be collected
in this new aggregate IPO box A by the allocation of various elements to three
zones in unique proportions.
The maximum
efficiency of the excitation state is represented by the essential number 64
from the language [T].
This number
represents the physical continuity of the operational integrity within the
physical process of both the technology and its industrial context. This
logical tautology will also measure the performance of the new aggregate design
in context C.
In terms of the
design and meaning of the industrial process, the numbers that are agreed to be
relevant must be socially defined for an industrial context such that the
frequency sets in Zone's 1-3 are representative of the operational context of
the industrial augmentation under test. This is represented in the process
model called IPO box B.
This will be
described by the language [T] - a closed set of state descriptions that define
a rational and logical and tautological, field of relativity between 2 objects
across a common medium. e.g. A to B through some common C. In natural
chaos, however, a further intercession of at least a common D is required to
model the modal and transitory states of complex systems. This produces the
finite language [A] - a complete set of transaction descriptions in 729 natural
numbers.
An industrial process
N is using IPO box A and IPO box B to measure a process called F. The
technology, its molecular and mechanical properties and constructs and their
relative, qualitative attributes are described by the 'a priori' linguistic
significators that consciousness and society attaches to the observed
activities.
e.g. The empirical
ability to observe and discriminate between enormous simplicity within enormous
complexity.
Thus it becomes
possible to derive a workable and reproducible process description for the
manufacture of tools; tools, artifacts and information.
The IPO box B, has an
output that is defined as a higher degree of molecular performance in terms of
relationships and outcomes in a previously undiscovered 3rd party relativity.
Use of the language
[A] is required to model these transactions such that values of empirical and
chronological uncertainty can be introduced to more easily calibrate transitory
and evolutionary fluctuations of; entropy and emergence within the performance
of the aggregates.
The language [A] of
729 deltaT states incorporates the logically definite deltaT 64 essential
number descriptions of the language [T].
Conventional 20th
Century 'Logic' had it that there is no mechanical way of sorting sequential
expressions into true or false without reference to the Universe of arbitrary
infinite labels. [i.e. Turing's recursion paradox, W V Quine's 'language
problem' etc].
This is false.
Without recourse to
the arbitrary, and resorting to basic 'a priori' physical laws and limited
closed sets of chemical atoms from the periodic table of chemistry, and using
the number-crunching capacity of today's large computers, massively enumerated
modalities with thousands of bits representing sophisticated interactions in
each of the; macro, meso and micro within the closed, generic systems of [T]
can be finitely modeled.
Modeling of
biological emergence and self-regulation by Biologist Goodwin B, using the
species 'Acetabularia acetabulum' spp.,
can be further interpreted by overlaying an atomic and chemical schematic on
the components of the process using such a closed system.
Goodwin B,
'Development as a robust natural process' in 'Thinking about Biology', ed.
Varela F and Stein W, pub. 1992, Addison-Wesley.
Modeling a strategy
for the creation of semantics and the [HX] Assembly Language from the material
behaviour of designer aggregates.
agg.x ZONE 1 80 70 89 macro
A1 A2 A3
agg.y ZONE 2 50 30 45 meso
A4 A5 A6
agg.z ZONE 3 20 12 07 micro
A7 A8 A9
Aggregate X in zone 1
is comprised of components that significantly perform at greater than or equal
to [70 - 100]. Within the tolerances within the macro aggregate, however, there
are other material relationships and dependencies that become empirically
obvious in the order of; [A2, A1, A3].
The masses, and
scales, ratios and morphology of the materials present in aggregate x have been
pre-selected and morphologically designed as tools to exploit a particular
user-function.
The empirical and
social agreements that allocate the relativity and number of partitions within
and between the chemical and structural and morphological components of the
macro of this mechanism and its industrial context will convey information
pertinent to structural performance, integrity and dis-integrity with time
according to the social expectations of the materials used.
Similarly with the
meso and micro.
Thus according to
Fajan's Rules and the industrial 'functional and structural material premise'
modeled in terms of the [HX] tautological syllogism as stated above the
efficiency and structural performance of all aspects of any material aggregate
can be empirically monitored and described.
In this way,
structured complex systems built because of the accountability and regulation
of massive simplicity can be designed.
In the following
examples, Android 'state descriptions' model materials that illustrate
conductivity between and within various layers, or skins, of materials.
There are, however,
different ways to approach Android 'skin design' as the receptor strategies
within the layering could pose different problems of accountancy of sensitivities
in differing industrial contexts e.g. in conditions of socially extreme
challenges at the limits of material tolerance within unknown levels of entropy
- the robot sensory configuration will fail.
It becomes a matter
of strategy, therefore, to select the most persistent aggregates that can
supply the most persistent and relevant information over the greatest length of
time.
Most likely to fail
first, therefore are the Micro Aggregates, the qualitative information most
useful for semantic exploration of the unusual and new. These are facilitated
by the Meso which is comprised more of the Macro components. The direct line of
transference between observer industry and the empirical activity within the
industrial context at the Micro is represented in the [HX] syllogism by the
component 'P'.
A more complex
version of the [HX] syllogism is presented hereafter. It is called the
Universal Process Model or [UPM].
The syntax or
'lettering' within it can be endlessly substituted by IPO boxes or other
[UPM]'s within the whole [UPM] to
represent increasing layers and levels of complexity within any system being
modeled. Instantiation of increasing complexity reflects the levels of
observation and understanding of desirable energy transference gradients and
other industrial bridging activities into the new context that is under
exploration.
PART 4. The [UPM], the universal process model.
The process of
systemic interactivity and its transactions - its scales and relationships,
within the universal process model [UPM] - is denoted in the language [H] - as
defined above. It can model complexity by nesting and re-nesting etc the whole
model itself within any atom of syntax within the boundaries of the primary
whole description. These 'object' boundaries are socially agreed on as the
object or system within any given context.
The level of detail
in this systemic model as regards the energy gradients (potential differences
etc) and quantities, and frequency of transactions etc within the various
scales of nesting within and between the components and processes adjudged to
be part of this system - can be furnished from previously established
industrial and empirical data.
The [SRM], the
inter-scalar model.
Furthermore, between
zones of known demarcation within the scales of energy transaction within the
object model and between the object model and its context there will be a
regulatory intermediate mechanism or boundary. e.g. conductor, membrane,
buffer, epidermis, cache etc
This second process
mechanism is essential for all systemic modeling, as it allows for intercourse
between the two scales of common process.
The mechanism, the
Scaling Relativity Model or, [SRM] is also an Input Process Output box, or IPO
box, that can be replicated and embedded to furnish analogies for levels and
degrees of process activity previously measured.
The Universal Process
Model [UPM].
The [UPM] will use
plant biology to label the generic organic systems model.
The physical context
enables the most reactive aggregates within the physical system to bridge the
physical obstacles to create the highest velocity transaction and gradient
available from and within the interactions of the context.
These gradients
between organism and context are maintained in equilibrium by the systemic
description within the plant DNA, the [UPM], but also attenuated within the
[UPM] description such that the [SRM] deals with the energy tolls inflicted by
the concentrated aggregates within the context.
In any context, a
plant enables its evolution, survival and growth by maintaining and energizing
both the [SRM] and the [UPM] in equilibrium.
If the DNA cannot
master the changing aggregates of a changing context by randomly and
successfully including some extra new macro ingredient, then the DNA script
will become selected against and become redundant.
The DNA script,
scripts for the inclusion and incorporation of
undifferentiated atomic and molecular simples such that the efficiency
of bridging activities will produce constant over-sufficiency over time.
The bridging
components assimilated for these transactions will be the primary atomic and
molecular simples of the context within which are other more unusual reactions
from some of the rarer elements from within the context. These reactions, from
the more interactive elements are attenuated and mediated by the most freely
available transference medium for complex molecular interaction within the
context. [e.g. H2O]
There are two
synergistic components of organic systemic structure that reflect the two-way
object and context exchange within the organism. These interactions create
electromagnetic fields and flux.
Internal physical
field theories within both natural and synthetic systems can thus be modeled,
given empirical agreements, technology and industrial data.
Field Theory
Priorities in Natural Systems.
1. the feeding
gradient [@f] for systemic growth. [@g]
i.e. [@f] $ [@g] - a directly related field.
2. the systemic toll
gradient. [@t] for context self-defence. [@d]
i.e. [@t] $ [@d]
3. the feeding gradient
[@f] and the toll gradient [@t], however, are inversely proportional and
directly competitive to the point of mutual exclusion. i.e. [@f] $$ [@t]
These properties
inversely relate as a power law, but are influenced by the upper and lower
tolerances of structural activity and interactivity within the atoms,
molecules, simples and complexes of the systemic structure in the context of
the modeling processes.
The DNA therefore has
to script for and supply its own internal processes [@f] faster than it can
lose its interphase of macro ingredients to the more massively competing macro
ingredients [@t] within the context.
i.e. [@f] $$ [@t] -
[Hennessey's 1976 CE, "Cost-Benefit Law", 'Ecce Homo - diary of a
victim', pub.1981, Solan GF.]
These energy losses
and gains are present at all levels of aggregate scale and interactivity within
both the [UPM] and the [SRM].
If the [UPM] feeding
gradient slows because of contextual disruptions in the [SRM] that cannot be
quickly re-supplied to maintain overall systemic integrity, then the organism
will fail.
[UPM] Context
Alternatives - using plant biology model.
Scripting in [H] can
here either begin the model 'outside-in' or 'inside-out' - as for these
demonstration purposes this matter is arbitrary.
i.e. context aggregates
versus DNA scripted aggregates, or,
DNA scripted asset
aggregates versus context aggregates.
The model is built
around the use of atmospheric pressure to deliver water to the plant biology
using the transpiration stream up the xylem caused by leaf metabolism and the
osmotic uptake of (biologically) necessary ion aggregates from the soil by
centripetal ion activity in shoots and roots.
01. If the context
aggregates Q and their changing attributes with time &Q are available as Q
to the DNA script propagating to exploit them, then the evolutionary driver
from Q that is Z will arrive in the plant system S at time1.
With systemic
structures, macro aggregate defences and enforced adaptive tolerances against
usual macrotic chaos, and bridging activities with which to exploit the macro
intact, the water transport system conveys the ionic packets to the plant
envelope and its metabolism.
where (?¬S) is the
plant seed system and Q = environment aggregates
1a. @ Q >> #Q = ~1S, t1
1d. &t, t2 >> (~1Z = (=:=Z)
+ ("3Z + !3Z))
1c. t2 = Q[@t]Z
$ Q[@d]Z
1d. &t, t3 >> ((?¬S) + (+?¬S) = (=:=S)
02. The plant system S uses and mutates
transport system Z and has
successfully incorporated and exploited
?Z in this environmental
context. Successful self-assembling
aggregate S has enfolded and
maintained a Z supply vacuum that
exploits the process of evaporation
from the tolerances within the soil and
vegetation types and the
changes in air temperature and pressure.
S has embedded itself in a persistent
opportunity between massive
scalar differences in the macro
aggregates.
Low S in the macro aggregates is
feeding the assembly and emergence
of high S within the plant because it
is being pulled and transported by
the greater and more physically
abundant and reactive high Z in the
macro aggregates across a massive
scalar divide to massively
low Z (atmosphere) in Q.
2a. &t, t4 =
((~1Z + ? + &Z) % (Q + &Q)) >>
2b. >> ( Z
>> (+?S(&Z)) + (+?S(-?Z)))
2c.
~1QZ = (~1!3QZ* + ~1SZ*!2) = (+?SZ)
2d.
[@f] $ [@g]
03. IF context C (atmosphere activity
prevalent), where C % Q, and is greater than or equal to biological and
physical plant tolerances - Optimum O, then some water Z plus other ion
attributes M will be moved into the plant cytoplasm L in the plant system S at
time1.
3a. S % (C % Q), t4,
3b. Q = !3Z = ?Z
3c. ((C>= O*) >> ~1+?Z + (~3*!2ZM = L)
~2S* + !3ZS ) >>
3d. >> (+?(#Z + #~2M) >> ~2L)
>> ~2S*)
3e. >> (&~1Z % !~3SQ, t4)
04. Piggy-backed on the massive scalar
processes (e.g. physics and physical energies) interchanging in the
groundwater, hydrosphere and aeolosphere, ionic components essential for plant
growth and over-sufficiency create the possibility of evolutionary asset or
fruit.
e.g. Plant metabolism: ~1S >> ~3S, where ¬S in ~3S is the process replication
description called biological DNA, M = migrating ions, L = cytoplasmic envelope
at time n.
i.e. the central systemic
manufacturing process of S that creates the subset (s1 .. s3) in order of;
macro, meso, micro and also of scale is:
S = (s1, s2, s3).
In plants, these
processes have primary components of operational capacity that is predicated
upon structures utilizing: s1 = protein base, s2 = sugars, s3 = phosphate
predicated.
4a. Q =
=:=MZ, t1
4b. S = (s1, s2, s3)
4c. S + t2 +
+?Q~2M = (L = (#~3M + ¬S) +
Z) =
~3S = (?¬S)
4d. (?¬S) = [@f] $ [@g]
05. In the ground G, in good conditions, the
seeds start to sprout. The emergence of the external structure of the plant, E,
where E % S, and includes the superstructure of the foliage F, and xylem X: -
is driven by aeolian A, and phototrophic P, dictates.
Persistence of
temperature and light and moisture and low air pressure and low turbulence will
produce an over-sufficiency O, (=:=), of growth and therefore fruit. (?¬S).
5a. IF ~1S
+ (?¬S) % G + (+?~1Z^) + (+?P^) + (+?A^), t1 >>
5b. >> (?¬S) + ~2S + ~2Z + (+?S) +
("1S) = t2.
5c. t2 = ((L =
(#M + #¬S) + ~2Z)) $$
5d. $$ = (E = (#A + #P + ~2Z^ + F + #M) + ~3Z)))
= t2.
5e. t2, IF (+?~1Z) >> ( ((L = [@f]) $$ (E
= [@t])) = t3)
5f. t3
>> (+?S = (+?~2Z) +
(+?~3Z)) =
5g. = (#~2MFs* + #~2MXs* + (#¬S(#s1, #s2, #s2),
t2) + #"2S) + ~3Z.
5h. membranes roots and leaves and relative
seasonal velocity
5h. t4 = +?S (¬s1 >> s2 + #s3) + (#"1SFX + #"2SFX) +
//#
5i. t5 =
+?S(¬s1 + ¬s2 >> s3) + (#"2SFX + #"3SFX) + //#
5j. t6 =
+?S(¬s1 + ¬s2 + ¬s3) >> ("3SFX >> (?¬3S) + IF£ //#)
5k. t7 =
-?S( £=:=(s1 .. s3)) +V (//#)
PART 5. THE
SCALING RELATIVITY MODEL [SRM]
06. At the boundaries of various membranes and
other transitional zones used in 'osmosis' by aggregates, there is a relatively
normative systemic toll to be paid falling within the usual tolerances of the
self-regulating and self-replicating physical system.
e.g. A to B through
some common C with the intercession of at least some common D.
However, migratory
aspects of adjacent chaos can introduce other modalities and scaling conflicts
into the object - context relationship.
i.e. A to B through
some common C with the intercession of some D that causes destructive
distortion in the systemic structure, t1.
Although the systemic
resistance exists, depending on the degree of physical impact on the systemic
defences and tolerances there will be a gradual shutdown until cessation and
de-contextualisation ensues, t3.
e.g. drought.
(S = Plant System, Z = Pluvial and Fluvial Water)
6a. t1 = (+?~3//#~2S) + (-?!1~1Z)
6b. t2 = (?~2//#~1S) + (-?!1~1Z)
6c. t3 = (~1//#£S) + (-?!1~1Z)
07. The Plant System suffers context disruption
in its feeding gradient and its metabolic bridging activities and transference
gradient are compromised.
Where S = (f1 .. f5),
and f1;XXX and Q = (t1 .. t6) and
t1;XXX are numeric values; 001 - 999. for the purposes of empirically measuring
relative wavelength and frequency for the construction of social information
and artifacts.
7a. +?QS, t1
7b. t1 = S([@f] $ [@p]) $$
Q([@t] $ [@d]) = [@f] $$ [@t]
7c. t2 = ~2//#S >> S(f1;075, f2;153, f3;125, f4;092, f5;085) + (£f2;153)
7d. t3 = (?~2//#~1S) + (-?!2~3Z)
7e. t2 = S(f;)(075,
000, 125, 092, 085)
7f. t4 = ?Q[@t] >> Q(t;)(t1; 150, t2;112, t3; 000, t4; 000, t5; 017, t6; 443)
7g. t5 = IF "3~3S >> (~3//#S V ~2//#S)
= (-?~3S)
7h. t5 = IF "1!1~1S >> (~1//#£S)
7i. t5 = "3~3S >> (f1 + f2 +
f3) £$$ (t1 + t2 + t3 + t6) =
(&t£=:=)
7j. t5 =
f;(075 + 000 + 125) = f;200, $$t;1:2 = (//#~1!S) = (f;red)
7k. t6 =
~1S(f;red) >> (f; tripartite biology domain, massive heating)
7l. t6 =
//#~1S(f; geo-drought, dehydration rupture, red distortion)
7l. t0 =
f;(075 + 153 + 125) = f;353, $$t;1:3 = (+?~3"3!3S) = (f;blue)
7m. t0 = f;(blue, UV)
>>
7m. t0 >> (f;
tripartite physics domain, diffuse atmospherics, less plant red into
photosynthesis, more blue/yellow and less red/green, greater xanthophyll and
less chlorophyll).
7n. t7 = IF (+?~3"3!1S) = t1 = (£f2;000) >>
7o. t7 >>
//#S = //#f(~1f + ~2f + ~3f) =
% Q
7p. t8 = ("2~2f2;000) + //#f >> (~1"1f2;160) = ?S
7n. The scale of f2
needed by S is nested in the larger ecosystem Q, which feeds (+?) the metabolic
meso (~2S) through various layers of filtration and transportation mechanisms
("3 V "2). These eventually substantiate (=:=) the emergence of fruit
or other replications, (~3S).
e.g. [HX] syllogism.
7q. t9 =
//#-?£f2[@d] + //#f(~1f + ~2f + ~3f) + (//#"2!1Q)
>> £S V £#S
7r. t9, IF //#f;XXX = t;XXX + ~3"3!1S + £f2 >> ?S V +?S
08. The system having
been breached by migratory chaos if sufficiently sturdy, complex, well stored
and developed may be able to cope with variable distresses within the new
orientations of the context.
If it does or does
not, however, is entirely unpredictable and arbitrary, as physical conditions
accrue and emerge and de-merge with time and with the influence of more global
activities. Some examples of systemic states for S are given below at time13
and intimations for what may or may not be possible. t13, (8g. - 8x.) for example massive scale velocity
transference on massively complex, massively storing systems versus relative
damage on similar systems in low scale velocity transference on simple and
relatively unfortified systems. A few examples iterate the possibility of
complexity and detail within the [HX] ASSEMBLER.
8a. SQ = S([@f] $ [@p]) $$
Q([@t] $ [@d]) = [@f] $$ [@t]
8b. t9 =
~2//#S >> S(f1;075,
f2;153, f3;125, f4;092, f5;085) + (£f2;153)
8c. t9
= (?~2//#~1S) + (- !3~3Z) +
(~3//#+?~1!"3Q)
8d. t10 = S(f;)(075,
000, 125, 092, 085)
8e. t11 = //#-?£f2[@d] + //#f(~1f + ~2f + ~3f) >> (£#S) + (?S) + (+?S)
8f. t12 = #S % ~1[@t]"3!3~1S +
(~3//#+?~1!"3Q) + //#f(~1f + ~2f +
~3f)
8g. t13 = #S + //#f;(~1f) >>
~1!1"1-?£S + (?S) = S at timeN
8h. t13 = #S + //#f;(~1f) >>
~1!1"2-?£S + (?S) = S at timeN
8i. t13 = #S + //#f;(~1f) >>
~1!1"3-?£S + (?S) = S at timeN
8j. t13 = #S + //#f;(~1f) >>
~1!2"1-?£S + (?S) = S at timeN
8k. t13 = #S + //#f;(~1f) >> ~1!2"2S
+ (?S) V (+?S) V (£S) = S at timeN
8l. t13 = #S + //#f;(~1f) >>
~1!2"3S + (?S) V (+?S) V (£S) = S at timeN
8m. t13 = #S + //#f;(~1f) >> ~1!3"1S
+ (?S) V (+?S) V (£S) = S at timeN
8n. t13 = #S + //#f;(~1f) >> ~1!3"2S
+ (?S) V (+?S) V (£S) = S at timeN
8o. t13 = #S + //#f;(~1f) >> ~1!3"3S
+ (?S) V (+?S) V (£S) = S at timeN
8p. t13 = #S + //#f;(~1f) >> ~2!1"1S
+ (?S) V (+?S) V (£S) = S at timeN
8q. t13 = #S + //#f;(~1f) >> ~2!1"2S
+ (?S) V (+?S) V (£S) = S at timeN
8r. t13 = #S + //#f;(~1f) >>
~2!1"3S + (?S) V (+?S) V (£S) = S at timeN
8s. t13 = #S + //#f;(~1f) >> ~2!2"1S
+ (?S) V (+?S) V (£S) = S at timeN
8t. t13 = #S + //#f;(~1f) >>
~2!2"2S + (?S) V (+?S) V (£S) = S at timeN
8u. t13 = #S + //#f;(~1f) >> ~2!2"3S
+ (?S) V (+?S) V (£S) = S at timeN
8v. t13 = #S + //#f;(~1f) >> ~2!3"1S
+ (?S) V (+?S) V (£S) = S at timeN
8w. t13 = #S + //#f;(~1f) >> ~2!3"2S
+ (?S) V (+?S) V (£S) = S at timeN
8x. t13 = #S + //#f;(~1f) >> ~2!3"3S
+ (?S) V (+?S) V (£S) = S at timeN
8y. t13 = #S + //#f;(~1f) >> ~3S = (?S) V
(+?S) V (£S) = S at timeN
8z. t13 = #S + ~1//#f(~1f) >> #S((-?S) V
(?S) V (+?S) V (£S)) = S at timeN
8aa. t13 = #S +
//#f(~2f) >> #S((-?S) V (?S) V (+?S) V (£S)) = S at timeN
8ab. t13 = #S +
//#f(~3f) >> #S((-?S) V (?S) V (+?S) V (£S)) = S at timeN
8ac. t14 = #S +
//#f(~2f) >> #~2S = S at timeN
09. Macro Toll
Gradient [@t] is an energy toll of previously established physical and social
parameters measured in and pertaining to the observed context between time1 and
time2.
When contextual
disaster strikes though, tolerances within the system break down and release
numerous breakdown products from aspects of the system and new environmental
context that interfere and mix with and disrupt (or augment) previously working
and stable physical relationships. e.g. ~1//#S, t1.
In normative
circumstances: Context Q $ S >> S([@d] $ [@t])
In abnormative disruption :
9a. t15 = //#Q $
//#S, #S >> = ?S(f2;153) at timeN
9b. t15 = £S +
(//#(S[@d])) = ?S(f2;153) at timeN
Within the damaged
system, possibilities for recombination of simples (n) represent at the damage
interphase until the unique physical tolerances of the damaged zone are either
superceded and disintegrated or useful recombination and structural attenuation
can present enough bridging material to repair the systemic defence [@d] such
that the feeding gradient from the
systemic metabolism can support [@t] the abnormative structural distress.
Two similar but
differently scaled systems may fare differently in a chaotic context disruption
of similar magnitude. No modeling assertion could be absolutely true in a
chaotic universe though.
examples s1 and s2,
where s1(mature) + s2(young) % S
s1 =
!3ZS(~1X"3~1F"2) mature plant
in emergent growing season
s2 =
!3ZS(~3X"1~3F"1) young plant
in emergent growing season
9a. t14 =
//#-?£f2[@d] + //#f(~1f + ~2f + ~3f) >>
(£#S) + (?S) + (+?S)
9b. t14 = #S % ~1[@t]"3!3~1S
+ (~3//#+?~1!"3Q) + //#f(~1f + ~2f +
~3f)
In this system S,
values for fn at; macro (~1fn) =
500 - 1000
meso (~2fn)
= 50 - 100
micro (~3fn) = 1
- 10
In the context //#Q,
however, disruption at (~1fn) has caused systemic failure such that the
velocity of the normative rate of supply is now insufficient to supply enough
systemic defences to slow down the rate of systemic disintegration.
Some complex systems
can still function and retain some damage within their structure.
In the context Q,
normatively, the upper and lower tolerances of competition on [@d], lie within
the range of [800 - 1200] where [<1000] is prevalent. e.g. 1:10 aggregates
in context lie in the range [1001 - 1200]
This 1:10 entropy
ratio ~3!S would define normative existence within context Q for S.
Also 1:10 aggregates
in Q, used by S to make ~1S lie within the range
[1 - 499].
In the context //#Q,
however, this ratio has changed; e.g.1
Contextual disruption
of Q has led from a normative ~3!S; (1:10), to a systemically damaging, ~1!S;
(1:100 - 1:1000), tn.
9c. t15 = //#S + fn
=<~2f2 + +?[@f] + (#S + ?S) - S(~1//#!1"1fn)
9d. t16 = //#S + fn +
fn =<~2f2 + +?[@f] + (#S + ?S) -
S(~1//#!1"1fn)
9e. t17 = //#S + fn +
fn + fn =<~2f2 + +?[@f] + (#S + ?S)
- S(~1//#!1"1fn)
9f. t18 = //#S + fn +
fn + fn + fn =<~2f2 + +?[@f] + (#S +
?S) -
9f. t18 = - S(~1//#!1"1fn).
9g. t19 = //#S + fn +
fn + fn + fn + fn =<~2f2 + +?[@f] +
(#S + ?S) -
9g. t19 - S(~1//#!1"1fn).
9h. (t14 - tn) =
//#SQ +?[@f] >> #S + //#Q = (#fn=<~2f2,tn) + (#S + ?S) V 9h. (+?S).
9h. t20 =
//#S+6(fn),@tn(t+1) >> @fn(+1fn)tn. =< ~2f2.
9h. t20 ~2f2 + (+?[@f] + (#S + ?S) -
S(~1//#!1"1fn))
9i. t21 = //#S + 7(fn) + =< (#fn=<~2f2,tn)
+ (#S + ?S) - S(~1//#!1"1fn)
9j. tn = //#S + 8(fn) + =< (#fn=<~2f2,tn)
+ (#S + ?S) - S(~1//#!1"1fn)
10. Disruptions in
the context //#Q may allow the survival of system S or not - dependent on the
nature and magnitude and duration of the systemic de-contextualisation and the
durability and complexity of the system.
e.g. X = xylem
transport system and F = foliage. s1 = mature, s2 = young.
s1 =
!3ZS(~1X"3~1F"2) mature plant
in emergent growing season, tn.
s2 =
!3ZS(~3X"1~3F"1) young plant
in emergent growing season, tn.
10a. tn = (@//#Q
>> £S) V (#//#Q >> #S(s1.x));(S,phenotypes, properties.x)
10b. t23 =
!1ZS(~1X"3~1F"1), xs1.1;(deluge, mature root and xylem,
10b. t23 = bad
foliage).
10b. t23 =
!1ZS(~1X"2~1F"3), xs1.2;(deluge, mature root and xylem,
10b. t23 = excellent
foliage).
10b. t23 =
!1ZS(~1X"1~1F"1), xs1.3;(deluge, mature/decayed root
10b. t23 = and xylem,
bad foliage).
10c. t24 = @//#Q = (-?s(1.1 + 1.2)) V (?s(1.1 + 1.2)) +
£(s1.3)
10d. t25 = @//#Q!1Z >> S = (£X)x;(deluge, root
dislocation, £[@f])
10e. t25 = IF @//#Q = t26 >> (s1.2 > s1.1) +
(!1~1Z) + #(?s(1.2>1.1))
10f. t25 =
IF @//#Q = t27 >> (s1.2 < s1.1) + (!1~1Z) + #(?s(1.1>1.2))
10e. t26 = !1Z@//#QSs
>> #~3Q,x;(optimum temperature and light, £[@f])
10f. t27 = !1Z@//#QSs >> #~1Q,x;(extreme
temperature and light, £[@f])
10g. t27 = f2
% &Q = (q1, q2, q3, q4, Q(1-n), ~1Z) > @(~2S +
~3S)
10h. t27 = #(~1S) =
f2 % (q1, q4)
10i. t27 =
@Q % &W = (W1, W2, w1, w2, w3, w4 ...wn)
10i. t27 =
W;(tectonics, volcanism, tsunami) = &Q(~1!1{G} + ~1!1{L})
10i. t27 =
W;(Richter, Geochemistry, Salinity + Temp) >> $$[@t]s
10j. t28 =
W1 $$ W2 >> @//Q (q1 $$ q4) >> f2 + (&~1!1"1Q) +
(#QSs)
10k. t28 = (!1W1 $$ !1W2 >> =:= {G}@w + #¬{L}
>> (q1 $$ q4)
10l. t29 =
#¬~3{L} >> #¬~3(f2) >> #{L}Ss = (=:= + ?Ss)