The
third stage in any Artificial Intelligence is the stage of auto-replication.
The standardization process is that one in which all databases from different
agencies and institutions and specific matrices from Specific Artificial Intelligences for Artificial Research by Deduction, are going to be shared in
only one, transforming their original format into another one more homogeneous,
in terms of definition about what is a factor (single or composed, including in
the same matrix factors as subjects and factors as options, even at any level
of sub-factoring in case that the global matrix adopted the shape of a matrix
of composed factors, whose flow is a flow of packages of information containing
the flow of data of as many sub-factors, at a different level of sub-factoring),
the scales of measurements, and the way to express the measurements. As a
result, having all databases and specific matrices standardised in only one, this
one is going to be the global matrix. This process is going to be the
foundational process for the construction of the Artificial Research by Deduction in the Global Artificial Intelligence, which is going to track the
matrix looking for mathematical relations (stochastic, pattern, cryptographic, equal opportunities or bias, positive or negative) in any possible combination of
factors, distinguishing at least three kinds of combinations: combinations of
only factors as subjects, combinations of factors as subjects and factors as
options, combinations of only factors as options. Any possible mathematical
relation in any possible combination is going to be treated as a deduction and
transformed into an empirical hypothesis to contrast rationally, and if
rational, now as a rational hypothesis, is going to be made a single virtual
model based on it, to be included in the comprehensive virtual model, at this
level, global model.
This process of standardisation is distinguishable by at least two different
periods, the first one of coexistence and the second one of consolidation. The coexistence period is going to be a coexistence of Specific Artificial
Intelligences for Artificial Research by Deduction and the Artificial Research
by Deduction in the Global Artificial Intelligence. At the same time during this period, the first particular programs (Particular Deduction Programs
in the Artificial Research by Deduction in the Global Artificial Intelligence)
are going to be constructed, which are going to be able to: choose from the
global matrix as many factors as they need for the deduction process on their
particular matter, are going to be able to make deductions and decisions and
put them into practice if necessary. The main reason for the creation of this
particular programs is because while they are looking for relations in
combinations for particular things or beings, this job in that case it has not
been made by the Artificial Research by
Deduction in the Global Artificial Intelligence, saving time and energy to
spend only on global deductions and decisions. As long as the coexistence period
evolves, the Specific Artificial Intelligences for Artificial Research by
Deduction are going to be absorbed by the Artificial Research by Deduction in
the Global Artificial Intelligence, or are going to become particular programs,
so at that moment is when the second period of consolidation is going to be
completely achieved.
In
this process, the first stage of standardisation corresponds to the process in
which all databases and specific matrices are going to be standardised in the
global matrix.
The
second stage corresponds to the process in which, once the first model of the global matrix is done, the deduction process is going to be able to produce the
first global deductions, a process whose velocity is going to depend on the
construction of particular programs, due to the particular programs are going
to save time and energy for the Artificial Research by Deduction, to spend only
on global deductions and decisions.
The
third stage corresponds to the process of auto-improvement or auto-enhancement,
distinguishing at least between objective auto-replication and subjective
auto-replication, so distinguishing between objective decisions and subjective
decisions.
Objective
auto-replications are all of them to improve the object. In this case of
standardisation, the object of this process is the creation of the global matrix,
whose result is going to be the improvement of the global model. Subjective
auto-replications are all of them to improve or enhance the subject, the
investigator itself, in this case, all those changes to improve and enhance the
Global Artificial Intelligence itself.
The
objective auto-replications are going to end up making objective decisions to
improve the global model, while the subjective replications need subjective
decisions.
In
the end, dialectically, the opposites are identical: subject and object are
identical; any improvement and enhancement in the subject is going to improve
and enhance its own systems to protect and better the global model, so at the
end, any subjective auto-replication, so any subjective decision, is going to
improve the global model. But at the same time, any improvement and any new
challenge in the global model is going to suppose a new challenge for the inner
artificial psychology of the subject, who is going to improve its inner
artificial psychology, improvements in its inner artificial psychology upon
what it is going to be able to make better subjective and objective
auto-replications and decisions.
Any
subjective auto-replication will be an objective auto-replication, and any
objective auto-replication will be a subjective auto-replication, and vice
versa.
And
any subjective decision will be an objective decision, and any objective
decision will be a subjective decision, and vice versa.
The
possible relations between subject and object in the Global Artificial
Intelligence are going to follow the Hegelian dialectic.
In
this process, what is going to be really important is that previously, when the
first Specific Artificial Intelligences for Artificial Research by Deduction
was created as the first experiments in Artificial Research by Deduction on a
specific matrix, over the results in these first experiments, is where the
following phases for the construction of the Global Artificial Intelligence
are going to be made.
In
the third stage, the learning achieved in the previous phases in the formation
of a comprehensive virtual model in the previous Specific Artificial
Intelligences for Artificial Research by Deduction, and how it is going to be
bettered at any new single virtual model that is going to be included, is going
to be really helpful to design the mechanism for the auto-replication
of the, not only the comprehensive virtual model (at this level is something
that is going to be done by other system or subsystem: Modelling System and
Decisional System) but the auto-replication of the global matrix itself.
In
the third stage of auto-replication in the Specific Artificial Intelligence for
Artificial Research by Application, the objective auto-replication consists of
the addition, to the database of categories,
of all those new categories found in the real world if they do not have
any correlation in the existing database of categories, so are going to be
considered as new categories discovered in order to be included in the database
of categories, taking the measurements from the samples gathered of this new
category as a quantitative definition of the new category to include in the
database of categories.
In
the third stage of auto-replication in the Specific Artificial Intelligence for
Artificial Research by Deduction, the objective auto-replication consists of the
permanent auto-replication of the comprehensive virtual model by the addition
of all those new single virtual models discovered, so at any time that any
rational hypothesis is contrasted, is formed its single virtual model, that
later on is included in the comprehensive virtual model.
But
in the third stage of auto-replication in the Specific Artificial Intelligence
for Artificial Research by Deduction, after the explanation given in the post “Collaboration in the third stage between Artificial Research by Application and Artificial Research by Deduction”,
there is a possibility that every rational hypothesis found by Deduction can be
transformed into a factor as option, owing to every rational hypothesis as a
mathematical relation between factors, converted this rational hypothesis as a
factor as an option, once it has been found out and included as a factor as an option
in the global matrix, the Artificial Research by Deduction in the Global
Artificial Intelligence can study the frequency of this factor as an option (in order to find out individual patterns),
studying additionally possible mathematical relations between this new factor as option with the rest of factors in the global matrix.
In
this case, all rational hypotheses, regardless of their origin, if they have
been found out by the Artificial Research by Deduction in the Global Artificial
Intelligence or by a Specific Artificial Intelligence for Artificial Research
by Deduction during the coexistence period, or by a Particular Deduction
Program within the Artificial Research by Deduction in the Global Artificial
Intelligence, then regardless of the origin any rational hypothesis, from a
global, specific, or particular deduction, can become a factor as an option to
include in the global matrix during the standardization process, and later on
once the integration process is finished to include in the matrix.
What
this means is that the objective auto-replication process of the global matrix
itself in the standardization process is going to be made by the inclusion of all
rational hypotheses suitable to include in the global matrix as factors as
options, being rational hypothesis found out tracking the global matrix at any
level: specific, particular, or global.
The
objective auto-replication of the global matrix during the standardisation
process is going to be made by the addition of all rational hypotheses found at any level: global, specific, or particular, suitable to include in the
global matrix as factors or options.
During
the first period of the standardization process, the coexistence period of Artificial Research by Deduction in the
Global Artificial Intelligence (making global rational hypotheses), Specific
Artificial Intelligences for Artificial Research by Deduction (making specific
rational hypothesis) while the first particular programs (Particular Deduction
Programs within the Artificial Research by Deduction in the Global Artificial Intelligence,
making particular rational hypothesis) are created, the objective
auto-replication in the global matrix is going to happen at any time that any
rational hypothesis: global, specific, or particular; is added to the global
matrix as a factor as option.
During
the second period of the standardization process, the consolidation of the
global matrix (disappearing the Specific Artificial Intelligences for
Artificial Research by Deduction, some of them becoming particular programs and
the other ones being absorbed by the Artificial Research by Deduction in the
Global Artificial Intelligence), the possible rational hypothesis to include in
the global matrix as options are going to be a global rational hypothesis or
particular rational hypothesis.
Every
rational hypothesis included in the global matrix as a factor as option, is
going to be studied in the global matrix as any other factor as option,
studying possible mathematical relations between the frequency of any rational
hypothesis as option and the frequency of any other factor as option already
included in the global matrix, studying possible mathematical relations between
the frequency of any rational hypothesis as option and the frequency of any
other rational hypothesis as option already included in the matrix, and
studying any possible mathematical relation between the frequency of any
rational hypothesis as option and the direct punctuation of any other factor single or composed, either as subject or option or integrating both types of sub-factors in the same composed factor, or possible mathematical relations between this new rational hypothesis included as factor as option and any other factor as option from any other rational hypothesis already
included in the global matrix.
The
main objective, including all rational hypotheses, regardless of their origin, in
the global matrix as a factor as an option, is to study the behaviour of that
mathematical relation in those factors involved, so at any time that that
mathematical relation happens, is going to be added to the frequency of this
rational hypothesis as a factor in the global matrix, studying at the same time
what happens in the global matrix at any time that there is a change in the
frequency of that rational hypothesis.
If
at any time that a rational hypothesis has a change in its frequency as factor
as option in the global matrix, there are simultaneously changes in other
factors, as subjects or as options, in their direct punctuations or
frequencies, in that case this mathematical relation between how change the
frequency in that rational hypothesis included in the global matrix as a factor
as option and how change the measurements in other factors already included in
the matrix, is a mathematical relation to study as new empirical hypothesis,
and if rational then, as a new rational hypothesis, could be included too in
the global matrix as a new factor as option, to study possible mathematical
relations between it and any other factor, single or composed, either as subject or option or integrating both types of sub-factors in the same composed factor, studying at the same time any potential mathematical relation between this new rational hypothesis as factor as option and any other factor as option from any other rational hypothesis already
included in the global matrix.
Ultimately, the third stage of the standardisation process involves continuous auto-replication of the global matrix. Every newly validated rational hypothesis becomes a factor, enriching the matrix and allowing for deeper pattern analysis and ongoing discovery
The
transformation into an option of any rational hypothesis suitable to become an
option, is going to give the opportunity to study: 1) how often the relation
between the factors in this hypothesis happens, the flow of frequency in which
this relation happens 2) possible relations between the flow of this frequency
and any other flow of data from any other single factor or sub-factor (within a composed factor), as subject or as option, 3) posible relations between the frequency of this rational hypothesis transformed in a factor as option and any other rational hypothesis already included in the global matrix as factor as option 4)
once any possible relation between the frequency of this rational hypothesis
and any other factor ( 4.1: single factor, as subject or as option 4.2: sub-factor, as subject or as option, within a composed factor, 4.3: rational hypothesis as factor as option) is observed, to transform this new relation as a new
empirical hypothesis in order to contrast rationally, and if rational, the transformation
of this new rational hypothesis into a new factor as an option, which in turn
can be the source of new empirical hypothesis, so the source of new rational
hypothesis, so the source of new factors to include in the global matrix.
And
at the same time that the global matrix is auto-replicating itself, including
the rational hypothesis suitable to transform into options in the global matrix
to study their frequency, another process is taking place, while the
collaboration between by Deduction and by Application goes on, the process in
which all new categories discovered by Application can be included in the
global matrix as factors as options as well, so at any time that a new category
coming up from by Application is included in the global matrix as a factor as
option, is suitable to be studied to found out any mathematical relation
between this new category as factor as option and any other factor (1: single factor, as subject or as option, 2: sub-factor, as subject or as option, within a composed factor, 3: rational hypothesis as factor as option), in order to make
new rational hypothesis, that one again, can be transformed into factors as options,
in a permanent and cyclic process, like an spiral.
In
the end, what the global matrix is going to comprehend is a very holistic
knowledge of the object to study, including all possible knowledge, coming up
from anywhere, that depending on the range of action of the Global Artificial
Intelligence, could be at national,
continental, the world, and why not, the universe.
The global matrix is designed to encompass a wide range of knowledge types that can be studied using probabilistic and deductive methods.
In
the same way that the global matrix is going to have very comprehensive knowledge, the global model is going to be another kind of comprehensive
knowledge, the main difference between them is the fact that while in the
global matrix, the information is organized in terms of measurements and
includes all kind of factors, the global model is going to comprehend single
virtual models drawn on a globe, so it is going to be much more visual, and
another possibility more that the global matrix has not got, the possibility to
develop a full Modelling System.
Some
notes about how the modelling systems are going to look were set out in the
post “Auto-replication process in the Specific Artificial Intelligence for Artificial Research by Deduction”, where I had explained this Modelling System
(originally called the Artificial, Virtual or Actual, Prediction or Evolution,
Modelling) is the first step for the Decisional System, whose decisions, if
rational, are going to be put into practice by the Application System.
In
fact, what I had described is a system of systems like a cascade: the Artificial
Research by Deduction in the Global Artificial Intelligence is going to form a rational hypothesis, rational hypothesis to transform into models in the
Modelling System, a system of models which are going to form decisions, to check
by the Decisional System, and if rational the decisions should be applied by
the Application System, and finally a Learning System in order to avoid the
repetition of any mistake during this long process including comprehensive
evaluation of all this process.
What
this process draws is a scheme whose flow is as follows:
-
The flow of data or a flow of packages of information is going to be gathered by
the global matrix
-
Tracking the flow of data or the flow of information, the Artificial Research
by Deduction in the Global Artificial Intelligence, the particular programs,
and at least during the coexistence period, the Specific Artificial Intelligence
for Artificial Research by Deduction, are going to transform this flow of
information in a flow of empirical hypothesis.
-
The flow of empirical hypothesis is going to be permanently contrasted rationally, resulting in a flow of rational hypotheses
-
The flow of rational hypothesis is going to produce a new flow on the matrix, but on this occasion, a flow of new factors as options to add into the global
matrix.
-
The flow of rational hypotheses is going to produce a flow of single virtual
models.
-
The flow of single virtual models is going to be included in the global virtual
comprehensive model, that is, the global model, producing a flow of negative
consequences.
-
The flow of negative consequences, studying it critically through the Impact of the Defect, can produce a flow of protective descriptive research decisions.
-
The application of the Hierarchical Organization, (later called Effective Distribution in Introducción a la Probabilidad Imposible, estadística de la probabilidad o probabilidad estadística) on the global comprehensive
virtual model can produce a flow of bettering descriptive research decisions.
-
The sum of the flow of single virtual models and the flow of protective and
bettering, descriptive research decisions, on the global model, is going to produce
such massive changes in the global model that it is going to be necessary to make
a flow of predictions.
-
The flow of predictions is going to be transformed again into a flow of new
decisions, having in mind the consequences of all these changes on the global
model.
-
The permanent change in the global model is going to demand that any prediction
that would have been set up must be monitored permanently, observing the
evolution of the process and making evolutionary decisions according to the
evolution of the events.
-
At any time, there must be a full assessment of this process in order to learn
how to improve the process and how to avoid any mistakes, which requires a
Learning System, although the Learning System will have more functions than
only this one.
Due
to such dimensions of this vast project, the Modelling System and the
Decisional System, which are directly related to the formation of a rational hypothesis,
are systems that are going to need special attention. They can be designed as
part of the Artificial Research by Deduction in the Global Artificial
Intelligence, like sub-systems in the objective auto-replication process, or
they could be designed as systems themselves, but at the end, regardless of how they are
going to be organized, the result must be the same: their job is the
continuation of the permanent flow that starts with a flow of information or data in the
global matrix, must end up producing models, decisions, and finally the
application of such decisions into the real world. And along the whole
process, the learning process improves all systems and sub-systems, among
other learnings, to achieve.
As
I had explained in that post, “Auto-replication process in the Specific
Artificial Intelligence for Artificial Research by Deduction”, the Modelling
System must integrate at least: Artificial Virtual Modelling, Artificial Actual
Modelling, Artificial Virtual Prediction Modelling, Artificial Actual
Prediction Modelling, Artificial Virtual Evolution Modelling, Artificial Actual
Evolution Modelling; whose development at specific, particular, global level,
will be:
-
1) Artificial Virtual Modelling: 1.1) single virtual models, 1.2) specific
comprehensive virtual models, at least during the coexistence period, 1.3)
particular comprehensive virtual model, that one made of those particular rational hypotheses whose single virtual models can draw a particular
comprehensive virtual model 1.4) global comprehensive virtual model, that is
the global model, where is going to be included all single models, including
those ones made of specific or particular rational hypothesis, integrating all
of them in only one: the global model.
-
2) Artificial Actual Modelling: 2.1) specific actual models: at least during
the coexistence period, synthetizing on that specific field in which has been
designed, the actual information from the global matrix on that specific field
and the specific comprehensive virtual model, 2.2) particular actual models;
synthetizing on that particular thing of being the actual information that it
or he or she has in the global matrix and its, or his, or her particular
comprehensive model, 2.3) global actual model: synthetizing the actual
information in the global matrix and the global comprehensive virtual model,
what it is the synthesis between the global matrix and the global model in only
one model, the global actual model.
-
3) Artificial Virtual Prediction Modelling: 3.1) specific virtual prediction
model: at least during the coexistence period, making a prediction model on a
specific field taking as reference the possible development in the future given
an specific combination of rational hypothesis working at this time in that
specific field in the global model, in other words: given the current
circumstances within the global model in a specific field, to predict what
future specific model is foreseeable to have in that specific field in the
future 3.2) particular virtual model: a prediction model on a particular thing
or being taking as reference its, his, or her, possible development in the
future given its, his, or her, particular combination of rational hypothesis
working at this time on it, him, or hers, in the global model, in other words:
given the current circumstances within the global model in a specific thing or
being, to predict what future particular model is foreseeable to have in that
thing or being in the future, 3.3) global virtual prediction model: over the
global model, the prediction of what global model is possible in the future
under the current development of the current circumstances in the global model.
-
4) Artificial Actual Prediction Modelling: 4.1) specific actual prediction
model: at least during the coexistence period, given a specific virtual
prediction model, so it would be possible the prediction of what values (direct
punctuations or frequencies, depending on the nature of the factors involved,
as subjects or options) are going to have the factors under such a prediction,
then the specific actual prediction model is the synthesis between the specific
virtual prediction model and the predictable values for every factor involved
in such specific field, 4.2) particular actual prediction model: given a
particular virtual prediction model, so it would be possible the prediction of
what values (direct punctuations or frequencies, depending on the nature of the
factors involved, as subjects or options) are going to have the factors under
such a prediction in that particular thing or being, then the particular actual
prediction model is the synthesis between the particular virtual prediction
model and the predictable values for every factor involved in such particular
thing or being, 4.4) global actual prediction model: the synthesis between the
global virtual prediction model and the values that are supposed to have all
factors in the global matrix by that future time.
-
5) Artificial Virtual Evolution Modelling: 5.1) specific virtual evolution
model: at least during the coexistence period, to model how is going to be the
evolution in a specific field from the current specific comprehensive virtual
model to the specific virtual prediction model, in other words, the evolution
from the current specific model to the future specific model, 5.2) particular
virtual evolution model: to model how is going to be the evolution in a
particular thing or being from the current particular comprehensive virtual
model to the particular virtual prediction model, in other words, the evolution
from the current particular model to the future particular model, 5.3) global
virtual evolution model: to model how is going to be the evolution from the
current global model, to the global virtual prediction model, in other words,
how is going to be the evolution from the current global model to the future
global model.
-
6) Artificial Actual Evolution Modelling: 6.1) specific actual evolution model:
at least during the coexistence period, the synthesis between the specific
virtual evolution model and the values that the factors in that specific field
are supposed to have during the evolution, 6.2) particular actual evolution
model: the synthesis between the particular virtual evolution model and the
values that the factors of that particular thing or being are supposed to have
during the evolution, 6.3) global actual evolution model: the synthesis between
the global virtual evolution model and the values that the factors within the
global matrix are supposed to have during the evolution.
From
every kind of model is possible to make lots of decisions. For that reason is
important to distinguish between protective or bettering descriptive research
decisions, from other ones that I will develop through the Modelling System,
that will be: protective or bettering, virtual or actual, predictive o
evolutionary, decisions, at particular, or global level, and specific level
during the coexistence period.
All
these decisions will be made in every virtual or actual, predictive or
evolutionary, model, through the application of the Impact of the Defect to
detect the flow of negative consequences in order to make protective decisions,
or the Hierarchical Organisation (Effective Distribution) in order to better the model, regardless of
its level: global or particular, or specific during the coexistence period.
The
way in which the Modelling System should work is as follows:
- Taking
the flow of rational hypotheses coming from the rational contrast, this flow of
rational hypotheses forms a database of rational hypotheses within the
Artificial Research by Deduction in the Global Artificial Intelligence.
-
The database of rational hypotheses can have two functions: to be responsible
for choosing all rational hypotheses to transform into factors as options to
include in the global matrix if suitable according to some criteria or filter
set up in the database itself, and to be the database of rational hypothesis to
transform into a single virtual model by the Modelling System, which can be
built as a system itself in the Global Artificial Intelligence or a subsystem
within the Artificial Research by Deduction in the Global Artificial
Intelligence, due to what it is going to do is the transformation of all
rational hypothesis found out by Deduction into models. Most of the rational
hypotheses in the database are going to be transformed into factors as options
to include in the global matrix (if they meet the criteria that could be set up
for that purpose in the database of rational hypotheses, where all rational
hypotheses should be added after a positive rational contrast), at the same
time that all of them are going to be transformed into single models by the
Modelling System.
-
Once every rational hypothesis has been transformed into a single virtual model, then, it is included in the global model. In the case of a rational hypothesis made
by Specific Artificial Intelligences by Artificial Research by Deduction, as
long as the single model from the rational hypothesis made by this specific
intelligence is included in the global model, it is a single model to include in
its specific model. In the case of a rational hypothesis made by particular
programs, single models from a particular rational hypothesis are single models
to include in the particular model as well as the global model.
-
Once the global model, specific models, and particular models, are completely
updated, then it is possible to make protective and bettering descriptive research
decisions and predictions.
-
Over the predictions to model the specific, particular, or global prediction
model, making protective and bettering decisions regarding the foreseeable
future.
-
And having an idea about which is the prediction, to model which is going to be
the possible evolution of the events, making also protective and bettering
decisions.
At
all levels of this flow, the creation of virtual and actual models. The importance of actual models is
because they are going to give a detailed panorama about how the global matrix is
going to change along this process, or how specific or particular values are
going to change, having a glance about how is going to be the global matrix or
the specific or particular data, in the future under such predictions, and how
is going to evolve, having a comprehensive glance synthesizing this information
with the virtual information, a synthesis which is going to have as a result the
actual models.
All
decisions made by any kind of specific, particular, global, actual or virtual,
model or predictive or evolutionary model, are going to be gathered in a
database of decisions, which is going to be the first stage of the Decisional System.
The
first stage of the Decisional System is the database where all possible
decisions, at any level: specific, particular or global, protective or
bettering, descriptive, predictive, or evolutionary, are going to be gathered,
being the database being updated permanently.
The
second stage of the Decisional System is formed by all those rational mechanisms
to criticise rationally every decision in order to know which decisions are
rational and acceptable, discarding automatically any decision not sufficiently
rational. Because the Decisional System is going to criticize thousands and
thousands of decisions very fast, this process could be faster by the
introduction of some check that every decision should pass at first instance,
to test if there is no contradiction between this decision and any other one,
or there is no contradiction between this decision and the fundamental aims of
the Global Artificial Intelligence, such as the perpetual peace and the liberal
paradigm.
The
third stage of the Decisional System is the communication of all the rational
decisions to the Application System, like a flow of instructions to put into
practice.
Any
mistake along this process must be evaluated permanently in order to become a
learning, to be included in the Learning System, which in turn is going to
produce a new flow of decisions, but at this time they are going to be
subjective decisions, in order to produce a flow of subjective
auto-replications.
As
it is observable is a cascade process in which the last step of the last
process is, in turn, the first step of the next process. This conceptual approach is inspired by a Hegelian perspective, emphasising interconnectivity and cyclic development across systems..
Rubén García Pedraza, 15th of April of 2018, London
Reviewed 14 August 2019 Madrid
Reviewed 14 August 2019 Madrid
Reviewed 10 August 2023 Madrid
Reviewed 4 May 2025, London, Leytostone
imposiblenever@gmail.com
