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{{headerQuasiAI}}
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<title>Updating QAT to 2023 Standards</title>
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<h1>Updating Quasi Axiomatic Theory to 2023 Standards</h1>
<center>
<p>Author: Don@groupKOS.com</p>
<b><big>
<p>Copyright © 2023 Don@groupKOS.com, All rights reserved under appropriate open-source licenses</p>
A development of 911 era category theory applied as a front-end category engine for machine learning and control &mdash;a plowpoint project, presenting:


<h2>Introduction</h2>
Developing a perceptive envelope of reckoning for an artifactual intelligence —quasiAI: [[the perceptor]]
<p>The Quasi Axiomatic Theory was developed as a big-data tool to significant events in the live-edge of the expanding world-corpus.</p>
</big></b>
</center>


<h2>Abstract and Theoretical Framework</h2>
<font color="green"><b><big>Editors note:  Wow!  The QAT is fascinating to revisit after a couple of decades!  When re-examined and documented, the example concept-soup below will redact in an attempt to reveal the fascinating things from the mind of Dr. Prueitt.</big></b></font>
<p>The QAT is based on a simultaneity of relational events in dual channels of measurement. The simultaneity is registered not at a process thread in an algorithmic moment, but as registered as simultaneous within the entire set of dual measurements.</p>


<h3>Implementation Philosophy</h3>
==Introduction==
<p>In this paradigm of measurement and category-frequency stratification, the data is a recording and remains immutable. A binary tree implementation for node access had no need to balance an immutable log. A delete function for a tree node isn't needed. In the category theory implementation, the data may be sparsely sampled with the same results.</p>
The Quasi Axiomatic Theory (QAT) was developed as a big-data tool to discover significant events in the live-edge of the expanding world-corpus &mdash;Cyberspace: 2000


<h3>The Quasi Axiomatic Theory (QAT) and its Components</h3>
As a category theory, a sampling of the world corpus, would contain a sampling of most of the categories of interest.
<p>The QAT facilitates the display of cross-channel relationships through two key components: Category Abstraction (cA) and Event Chemistry (eC).</p>


<h4>Category Abstraction (cA)</h4>
As an investigatory tool, The QAT could isolate category trends and waves of change in large data samples, planet sized, by taking a sparse sample of the information-routes of the expanding world corpus, recorded in internet router logs.
<p>Once interesting groups of categories within the data-stream are isolated by category abstraction mapping, groupings of interest are selected from the clusters on the cA mapping.</p>


<h4>Event Chemistry (eC)</h4>
The QAT paradigm was implemented as an in-memory data engine of records retrieved by a sparse sampling of the world data, such that when categories of significance were discovered by visual examination.  With discovery of category-frequency-trends in communication IP router logs, the cause of the change-wave may be reverse-searched from category, to data-event, by a category-link explorer, made to step through smaller sets of significant categories &mdash;toward discovery of individual internet routes as the causative determinant.  The butterfly.
<p>Isolation of small groups allows event chemistry abstraction to sleuth the chemistry of categorical interactions as an interactive classical graph of circles connected with lines.</p>


<h2>The Role and Evolution of QAT</h2>
These algorithmic approaches are termed, 'categorical abstraction' (a scatter-gather visual map), and 'eventChemistry' as the category explorer.


<h3>The QAT in the 911 Response Era</h3>
Here we explore the QAT algorithms to expose how machine learning can be afforded a place in the analysis loop <b><big>&mdash;a keen plowpoint</big></b>
<p>With contributions nationally, during the 911 response era, aiding in the global cause were the data structures of the QAT visual abstraction, navigable with event chemistry, providing access back to the source-moment of any categorical trend, and as such was the purpose of domestic surveillance.</p>


<h3>The Creation of Ontological Access</h3>
=== Visual Abstraction &mdash;mapping cross-category coincidence-frequency dynamics ===
<p>Data access methods to access the values of a data stream by value-category by natural order in a linking-sequence visiting the data-solution at Big(O) efficiency.</p>
<div style="float:left; margin-right:2em;">


<h3>Visual Abstraction of Relationships</h3>
__TOC__
<p>Two measurement channels provide one QAT dimension of analysis providing visual abstraction of relationships in the cross-comparison. This occurs by randomly scattering onto a visual map the set of points representing all existing pairs within dual channels of measurement in the data ontology widget. The gather process accesses the proportionality map to animate the category-mapping- wherein this is a visual abstraction of dynamic relationships translated to a stratification of motions within the category-scatter-map.</p>
</div>
<br/>
<div style="float:left; width:auto; margin-right:2em;">
[[File:SLIP browser spook-ware ontologystream.com image070.jpg|frame|The Quasi Axiomatic Theory SLIP browser showing the structures of coincedence within an internet router log file.]]
</div>


<h2>Applications and Future Directions of QAT</h2>
The visual abstraction of the [[random-scatter mapping]] appears as points (representing value categories) that move on a mapping, which map the category-points were randomly scattered upon.


<h3>Existing and Potential Applications</h3>
The 'magic' ingredient of the QAT algorithms that afford [[visual abstraction]] (vA) of relational events is the Cartesian product of the value categories found in the data stream sample for analysis.  The magic is conjured by a tight iteration (programmatic loop) that moves two points slightly closer together upon the map.
<p>The outcome of the paradigm rendered to notation is a binary-tree/linked-list data widget where all members of a category value are linked as a chain, as category-member-chains attached to each binary tree node.</p>


<h3>Conclusion</h3>
Moving random point-pairs in the vA by micro-movements toward each the other, produces a clustering of categories upon the vA mapping. The coincedent-proportionality subset of a,b permutations of the Cartesian product is established by the occurrence-frequency of members in a category as sampled from the data stream.
<p>The binary-tree nodes each have a chain of equivalent values indexed in natural order as a linked list. The fully structured data widget affords any data by relational-path-access, including lower_category, higher_category, next_member, previous_member, with all index values anywhere within the structure also indicating relative age by natural order.</p>


<h3>Future Work</h3>
With an animated spectrum of motion-activated groups of map-points moving, an operator of this technology, typically an NSA analyst, could partition the categorical-dynamics with a sub-selection of the time-windows sampled for analysis.
<p>With structured historical data access of a measured channel, a second structure is referenced holding a second channel of measurements.  These two structures provide the prismatic affordance of the proportionality map of their implicit relational dynamics across a sampling of events within a time line.</p>


</body>
This describes the '''Category Abstraction''' (cA) portion of the ''Quasi Axiomatic Theory and Paradigm'' (QAT).
</html>
 
 
===Event Chemistry===
 
[[File:QAT event chemistry browser ontologystream.com image030.jpg|right|frame|The QAT eventChemistry browser, as a navigable classic graph (mouse click navigation), through the 'compounds' of categories of coincidence.]]
 
A further affordance of the QAT is an inference technique availed by the displayed cross-channel emergent-relationships, termed '''Event Chemistry''' (eC).
 
Once interesting groups of categories within the data-stream are isolated by category abstraction mapping, groupings of interest are selected from the clusters on the cA mapping.
 
==== Browsing an isolation of small groups from a world of information ====
Event chemistry abstraction, as a interactive classical graph of circles connected with lines, allowed inference techniques to sleuth the chemistry of categorical interactions. Prueitt's formal QAT applied Mill's logic of inferences with an overlaid knowledge-management framework of annotation and reporting. 
 
<span style=" width:0px; float:left;"><center>{{Template:Img data butterfly white|44px}}</center></span>
Along with all of the contributions nationally, during the 911 response era, aiding in the global cause, were also the data structures of the QAT visual abstraction, navigable with event chemistry, providing access back to the source-moment of any categorical trend. A basic butterfly hunter.
 
<br style="clear:both;"/>
 
== QAT Theory in principle of emergent processing of determinants within chaos ==
<b><big><font color="blue"><b><big> in severe edit</big></b></font></big></b> [[User:XenoEngineer|XenoEngineer]] ([[User talk:XenoEngineer|talk]]) 12:51, 21 July 2023 (UTC)
 
Allow an attempt to express the feature of a deep category theory learned from a very deep mind that influenced the beginning of the domestic spy agency over two decades ago.
 
<div style="float:left; width:auto;">
{{Template:Img_data_scatter-gather_122x124}}</div>
The QAT is a map maker. 
 
If pure random data is mapped to a circle in random radial distribution, then purely random operation on pairs of these distributed map points would continue to randomize the points in radial positions.
 
AI-s like maps, BTW.
 
 
=== Emergency lexicon (footnotes?) ===
'''''a stratification of category-frequency density of inter-relational coincedence 'tween two channels of measurement'''''
[fuzzy circle illustration goes here | hang right]
 
== What's a tween? ==
A categorical stratification process over time as a random-pair selection in a tight-loop. Tweening is the act of emergent computing, in a general sense. Usage of the term:  ''The spikes on the circle illustrated were 'tweened' from the fuzzy halo of the other fuzzy circle illustration.
 
== Implementation of QAT Data Structures ==
'''Term:''' [[QAT.SLIP]] affords cross-column  category-frequency stratification.
 
In this paradigm of measurement and category-frequency stratification, the data is a recording 'mapped' into memory in ordered sequence addressable by numeric index.
 
This is a simple array data structure.
 
The minimum pointer-set to implement a binary-tree combined with a linked list of tree-node members is stored as an array of integers, explained by their monikers:
 
 
A delete function for a tree node isn't needed. In the category theory implementation, the data may be sparsely sampled with the same results.
 
By structuring the data-sample stream, or some sparse selection of samples over time, into a structure including all members in an accessible structure, the tree-list composite becomes a rudimentary ontology of the data-stream structured by value-comparisons against a data-relationship, and time-reversible (or re-build-able to any certain event on the time line).
 
Additionally, as a time-series log, there is implicitly a time-line addressable ontology.
 
Two measurement channels provide one QAT dimension of analysis<sup>[[QAT.I-RIB]]</sup> providing visual abstraction of relationships in the cross-comparison. This occurs by randomly scattering onto a visual map the set of points representing all existing pairs within dual channels of measurement in the data ontology widget. The gather process accesses the proportionality map to animate the category-mapping- wherein this is a visual abstraction of dynamic relationships translated to a stratification of motions within the category-scatter-map.
 
 
<small>
* '''I-RIB:''' In-memory Referential Information Base.  A term coined by P. S. Prueitt. ''Foundational Paper on Referential Bases'', Paul S Prueitt Ph.D, October 31, 2006
* http://www.bcngroup.org/beadgames/TaosDiscussion/referentialBases.htm
* http://www.bcngroup.org/area1/2005beads/GIF/RoadMap.htm  and
* ''[[File:Event Detection and categorical Abstraction|Event Detection and categorical Abstraction]]'' 2002, Paul S. Prueitt PhD, OntologyStream '''URL:''' <small>http://www.ontologystream.com/cA/papers/EventDetection.htm</small>'''
* [[File:Foundational Paper on Referential Bases]] 2006, Paul S. Prueitt, Ph.D
 
October 31, 2006
</small>
 
===A question on nomenclature===
Is a data structure of a tree-of-categories sharing indices with a linked-list headed with each category node, with the list comprising as pointers to all members of a value category &mdash;then may the pointer matrix be properly termed an ontology?  An ontological primitive?   
 
=== Rigorous loose thoughts ===
 
In this notational paradigm of measurement and category frequency trending, the data is a recording and remains immutable.
 
A binary tree implementation for data access has no need to balance an immutable log. 
 
A delete function for a tree node isn't needed, moreover, the data element tree/list nodes are each a demarcation of their category membership, in order on the time-line.
 
In the category theory implementation, the data may be sparsely sampled with the same results, within limits.
 
Should a data-access excursion on the tree-list structure get lengthy (as an unbalanced binary-tree) in any certain data sample, it is simply rejected as part of the un-sampled, dis-obviating any need for binary tree balancing.
 
The outcome of the paradigm rendered to notation is a binary-tree/linked-list data widget where all members of a category value are linked as a chain, as category-member-chains attached to each binary tree node. 
 
The binary-tree nodes each have a chain of equivalent values indexed in natural order as a linked list. The fully structured data widget affords any data by relational-path-access, including lower_category, higher_category, next_member, previous_member, with all index values anywhere within the structure also indicating relative age by natural order, i.e., the magntitude of the access-index is a relative age value in a time-line sampling.
 
With structured historical data access of a measured channel, a second structure is referenced holding a second channel of measurements.  These two structures provide the prismatic affordance of the proportionality map of their implicit relational dynamics across a sampling of events within a time line.
 
==Future Development ==
;* Hyper-accelerating quasiAI category-perception with the Cartesian product sub-set on high-speed data-streams as a running-recent-average analysis window (or any previous history of the data-stream)
;* Implement a video-frame-rate capability of gather processes on a random-scatter map, providing a gather-process that stratifies category-frequency-dynamics of a data-stream sample AS compared to an unknown data-stream.  I.e., dual-channel-expansion of how category-frequency dynamics of unknown data.
:: Known </> Unknown ==> meaningful results to a domain expert, where '</>' represents a cluster-process based on a determinant.
:: Known </> Known ==> machine intelligence training scenario
:: Unknown </> Unknown ==> interesting patterns which can be traced back to the causal instances of a value-category-occurrence in the sampled data stream/log.
:: Trace-back to root causality of existing unknown category dynamics is available to adjust sampling resolution.
:::* This affords in principles of an applicable domain a domestication of Maxwell's demon over events of chaotic environment, capable of isolating causal-determinants in ongoing apparent chaos.
;*  Massive parallel circuits on FPGA configurations customized for UI customized/calibrated to units and measures of the data stream for analysis.
:* Implement N-Dimensional QAT analysis, with an N-quasiAI
 
</div>

Revision as of 12:40, 22 July 2023

quasiArtifactualIntelligence —a perception from the edge

  About White paper QuasiMatrix Code QAT Code Data Examples Scatter-Gather Explained The Plow Share

A development of 911 era category theory applied as a front-end category engine for machine learning and control —a plowpoint project, presenting:

Developing a perceptive envelope of reckoning for an artifactual intelligence —quasiAI: the perceptor 

Editors note:  Wow!  The QAT is fascinating to revisit after a couple of decades!  When re-examined and documented, the example concept-soup below will redact in an attempt to reveal the fascinating things from the mind of Dr. Prueitt.

Introduction

The Quasi Axiomatic Theory (QAT) was developed as a big-data tool to discover significant events in the live-edge of the expanding world-corpus —Cyberspace: 2000

As a category theory, a sampling of the world corpus, would contain a sampling of most of the categories of interest.  

As an investigatory tool, The QAT could isolate category trends and waves of change in large data samples, planet sized, by taking a sparse sample of the information-routes of the expanding world corpus, recorded in internet router logs.  

The QAT paradigm was implemented as an in-memory data engine of records retrieved by a sparse sampling of the world data, such that when categories of significance were discovered by visual examination.  With discovery of category-frequency-trends in communication IP router logs, the cause of the change-wave may be reverse-searched from category, to data-event, by a category-link explorer, made to step through smaller sets of significant categories —toward discovery of individual internet routes as the causative determinant.  The butterfly.  

These algorithmic approaches are termed, 'categorical abstraction' (a scatter-gather visual map), and 'eventChemistry' as the category explorer.

Here we explore the QAT algorithms to expose how machine learning can be afforded a place in the analysis loop —a keen plowpoint

Visual Abstraction —mapping cross-category coincidence-frequency dynamics


The Quasi Axiomatic Theory SLIP browser showing the structures of coincedence within an internet router log file.

The visual abstraction of the random-scatter mapping appears as points (representing value categories) that move on a mapping, which map the category-points were randomly scattered upon.

The 'magic' ingredient of the QAT algorithms that afford visual abstraction (vA) of relational events is the Cartesian product of the value categories found in the data stream sample for analysis. The magic is conjured by a tight iteration (programmatic loop) that moves two points slightly closer together upon the map. 

Moving random point-pairs in the vA by micro-movements toward each the other, produces a clustering of categories upon the vA mapping.  The coincedent-proportionality subset of a,b permutations of the Cartesian product is established by the occurrence-frequency of members in a category as sampled from the data stream.

With an animated spectrum of motion-activated groups of map-points moving, an operator of this technology, typically an NSA analyst, could partition the categorical-dynamics with a sub-selection of the time-windows sampled for analysis.

This describes the Category Abstraction (cA) portion of the Quasi Axiomatic Theory and Paradigm (QAT).


Event Chemistry

The QAT eventChemistry browser, as a navigable classic graph (mouse click navigation), through the 'compounds' of categories of coincidence.

A further affordance of the QAT is an inference technique availed by the displayed cross-channel emergent-relationships, termed Event Chemistry (eC).

Once interesting groups of categories within the data-stream are isolated by category abstraction mapping, groupings of interest are selected from the clusters on the cA mapping.

Browsing an isolation of small groups from a world of information

Event chemistry abstraction, as a interactive classical graph of circles connected with lines, allowed inference techniques to sleuth the chemistry of categorical interactions. Prueitt's formal QAT applied Mill's logic of inferences with an overlaid knowledge-management framework of annotation and reporting.

Along with all of the contributions nationally, during the 911 response era, aiding in the global cause, were also the data structures of the QAT visual abstraction, navigable with event chemistry, providing access back to the source-moment of any categorical trend. A basic butterfly hunter.


QAT Theory in principle of emergent processing of determinants within chaos

in severe edit XenoEngineer (talk) 12:51, 21 July 2023 (UTC) 

Allow an attempt to express the feature of a deep category theory learned from a very deep mind that influenced the beginning of the domestic spy agency over two decades ago.

The QAT is a map maker.  

If pure random data is mapped to a circle in random radial distribution, then purely random operation on pairs of these distributed map points would continue to randomize the points in radial positions.

AI-s like maps, BTW.


Emergency lexicon (footnotes?)

a stratification of category-frequency density of inter-relational coincedence 'tween two channels of measurement [fuzzy circle illustration goes here | hang right]

What's a tween?

A categorical stratification process over time as a random-pair selection in a tight-loop. Tweening is the act of emergent computing, in a general sense. Usage of the term: The spikes on the circle illustrated were 'tweened' from the fuzzy halo of the other fuzzy circle illustration.

Implementation of QAT Data Structures

Term: QAT.SLIP affords cross-column  category-frequency stratification.

In this paradigm of measurement and category-frequency stratification, the data is a recording 'mapped' into memory in ordered sequence addressable by numeric index.

This is a simple array data structure.

The minimum pointer-set to implement a binary-tree combined with a linked list of tree-node members is stored as an array of integers, explained by their monikers:


A delete function for a tree node isn't needed. In the category theory implementation, the data may be sparsely sampled with the same results.

By structuring the data-sample stream, or some sparse selection of samples over time, into a structure including all members in an accessible structure, the tree-list composite becomes a rudimentary ontology of the data-stream structured by value-comparisons against a data-relationship, and time-reversible (or re-build-able to any certain event on the time line).

Additionally, as a time-series log, there is implicitly a time-line addressable ontology.

Two measurement channels provide one QAT dimension of analysisQAT.I-RIB providing visual abstraction of relationships in the cross-comparison. This occurs by randomly scattering onto a visual map the set of points representing all existing pairs within dual channels of measurement in the data ontology widget. The gather process accesses the proportionality map to animate the category-mapping- wherein this is a visual abstraction of dynamic relationships translated to a stratification of motions within the category-scatter-map.


October 31, 2006

A question on nomenclature

Is a data structure of a tree-of-categories sharing indices with a linked-list headed with each category node, with the list comprising as pointers to all members of a value category —then may the pointer matrix be properly termed an ontology?  An ontological primitive?

Rigorous loose thoughts

In this notational paradigm of measurement and category frequency trending, the data is a recording and remains immutable.

A binary tree implementation for data access has no need to balance an immutable log.

A delete function for a tree node isn't needed, moreover, the data element tree/list nodes are each a demarcation of their category membership, in order on the time-line.

In the category theory implementation, the data may be sparsely sampled with the same results, within limits.

Should a data-access excursion on the tree-list structure get lengthy (as an unbalanced binary-tree) in any certain data sample, it is simply rejected as part of the un-sampled, dis-obviating any need for binary tree balancing.

The outcome of the paradigm rendered to notation is a binary-tree/linked-list data widget where all members of a category value are linked as a chain, as category-member-chains attached to each binary tree node.

The binary-tree nodes each have a chain of equivalent values indexed in natural order as a linked list. The fully structured data widget affords any data by relational-path-access, including lower_category, higher_category, next_member, previous_member, with all index values anywhere within the structure also indicating relative age by natural order, i.e., the magntitude of the access-index is a relative age value in a time-line sampling. 

With structured historical data access of a measured channel, a second structure is referenced holding a second channel of measurements.  These two structures provide the prismatic affordance of the proportionality map of their implicit relational dynamics across a sampling of events within a time line.

Future Development

  • Hyper-accelerating quasiAI category-perception with the Cartesian product sub-set on high-speed data-streams as a running-recent-average analysis window (or any previous history of the data-stream)
  • Implement a video-frame-rate capability of gather processes on a random-scatter map, providing a gather-process that stratifies category-frequency-dynamics of a data-stream sample AS compared to an unknown data-stream. I.e., dual-channel-expansion of how category-frequency dynamics of unknown data.
Known </> Unknown ==> meaningful results to a domain expert, where '</>' represents a cluster-process based on a determinant.
Known </> Known ==> machine intelligence training scenario
Unknown </> Unknown ==> interesting patterns which can be traced back to the causal instances of a value-category-occurrence in the sampled data stream/log.
Trace-back to root causality of existing unknown category dynamics is available to adjust sampling resolution.
  • This affords in principles of an applicable domain a domestication of Maxwell's demon over events of chaotic environment, capable of isolating causal-determinants in ongoing apparent chaos.
  • Massive parallel circuits on FPGA configurations customized for UI customized/calibrated to units and measures of the data stream for analysis.
  • Implement N-Dimensional QAT analysis, with an N-quasiAI
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