D. Edward Mitchell 16:00, 14 April 2020 (UTC) Hello World!    groupKOS Developer Share —usually UNDER CONSTRUCTION

Amplification of subdominance driving 1/f frequency drift in the local reluctance of desktop space-timing

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edit template Prelude   Theory   Assembly   Resonant Array   Suspension   Power   Sensor Matrix   Processing   The Story

P E N D I N G    E D I T I N G to a more recently realized dreamy place

The following article below the next section was written without yet realizing the simplification of category analsysis of a binary number stream, and a few more dots connected in the project that is organizing itself from skills, lessons, and events lived.

The 'glove for mind' paradigm of dialog with Prueitt, circa 2000, was abstractly defined from a QAT engineering paradigm. When rought-documenting this early system documentation, the design-closure is realized this week to be a completion of a top-overview of how to sensorize a mind and synchronize cognitive augmentation.

When the anticipated mind-entrainment occurs ——after—— Znidarsic coupling floods the phase-timing with proton noise (per se), the anticipated cognitive recognition of extended acuity of mind may or may not be prevalent (yet). Yet, when entrainment does occur, the numbers of QAT analysis will reflect the advent, as a less randomized moment of oscillator history.

Plausibly, then, if the vision orb development sojourn finds closure on a scalar-tether on proximal mind, as experienced decades prior in a brief vision, then the QAT numbers will re-index the pulse-field to a afford a 'recollectable situated awareness.' These are terms of Prueitt's knowledge science.

And this goes way on and on in stuff not very believable unless one had lived my life experience of impossible synchronicites that rocked my soul, woven throughout my life time.

Oh! Additionally! I'm humbled by the over-sight of my live and compulsive nature!

[Drum roll here]

My earlier compulsion with N-average running-window analysis turns our to be (realized while composing system documentation) a digital simulation of a ring-amplifier! That just came to me this morning! 2021.08.30

This is another interwoven layer of self-directed investigation that is exactly what I needed to know to do, but needed for a purpose to come years later, to fulfill construction of a vision orb, seen five decades prior in a vision.

Below here is old text, obsolete in part, to be re-edited.

Below here be dragons

D. Edward Mitchell 20:55, 3 November 2020 (UTC) Developer Msg:    Now dredging old memories... Please excuse the clutter as I figure how to configure the the least Dollar figure to build a device that entrains with regularity within the magnetic environment.
However! Let me share that after living with an over-stuffed brain on all-things-esoteric, the handful of simplistic concepts self-assembled in mind and were there waiting for me to notice —the design concepts of this brain-child in breached-labor for years obtained closure on a complete design. Exclamation point. So... some of the items listed following are now off-concept —mostly in regard to harmonic-operation. But being all this story from a half Kentuckian-alien hybrid is pure fiction by definition, this leaves me designing a science fiction gizmo. It is a chaotic ring amplifier driving a magnetic field revolving on the surface of a torus donut with winding ratios and torus parameters all a power of the golden ratio.

Assuming: Reluctance[1] is a load on ΔB[2], amplification over several cycles of oscillation is by summation of coincident periodicity (N-recent average[3]) of A/D sampling.

Then testing of open-input signal drift of an A/D[4]input on an Arduino provided a chaotic[5] signal source that revealed 1/f frequency drift operating within the noise floor of the signal.

testing magnetic reluctance with a drifty-time-base ring amplifier of inverting self-resonant copper loop elements

The noise in a ring oscillator is timing-drift from the average center. The average center can wander anywhere in the phase cycle.

Essentially, rotating the resonant unit physically should show digital bobble in the resonant time base average, corresponding with rotation of the device in the Earth's magnetic field.

But locking with a local magnetic field means the oscillator can select and co-resonate with the ambient frequencies. That is a phase-coherence, where sympathetic coupling can occur, and where the oscillator accumulates more energy in the oscillating energy envelop. Accumulation is a product of time. The oscillator must add gain to continue a coherence, and the oscillator must be free to wander with the coherent source. I.e., a low-impedance coupling to remain coupled while drifting with the selected source frequencies.

In the premise of a magnetic loop resonator used in this study, a dis-connect with any regularity in the amplifier circuitry is maintained by only driving the resonator with randomly timed pulses.

Coupling loss: A resonant copper loop driven to self-harmony with a randomly pulsed (millions of random pulses per second) prime driver must be over-driven to overcome loss of pulse content which is not selected into the self-harmonic wave-group of the resonating element.

Esoteric free be

Fishing for a submarine

If a submarine is hooked by a fishing real, there is one option to avoid breaking fishing line. Move with the submarine. That is due to the massive variation in inertia between fisher person and a submarine.

Likewise, to build a controller that coupled with a magnetic vortex (toroidally rotating magnetic density variation, a.k.a., Standing patterns of Faraday-induced magnetic flux density variations operating in the moment of the major radius of the toroidal system. This harmonic controller needs to lock-onto with fishing line (harmonic coupling, a.k.a. coheres with) a planetary magnetic moment that may wander. If the planetary magnetic moment wanders, the harmonic controller (fisher man/woman) must also remain coupled while drifting its center of oscillation.

TechnoNaut mind-tuning technique:

Mind-over-coil-field-qualities discovered by Wilbert Brockhouse Smith's team --if-- applicable to a changing variables relating to magnetic field oscillation would therefore be involved in a bio-feedback loop with the Earth's magnetosphere —and those frequencies imprinted into our planetery magnetic field (pending coupling resolution).

This technologically augmented perception is a learned technique afforded by the magic of mind. All this remains in the domain of mystery protected by reality, but may be quite handy to the practicing technoShamaness.

Spirit surfer caution: An autistic giant in the field of aether-quantum-cogno-dowsing teaches that ascension requires balance to avoid kharmic like counter-balance against egocentric cognitive energies. Approach reverently as a child to a deity, as no animalisms of survival are harmonic once ascended beyond mutual consumption as a biological prime determinant of our cognitive reality. If semi-intelligent nothingness (reactive of no intent) besets the magnetic connection, it's already to late to avoid consequences of wandering into the principle's office cluelessly. Reverence and naked self-honesty is exactly the optimal setting for maximal refinement of our soul's mission if that mission is on the slopes of ascension to nature's conservant harmony. Reality inside & out.

Loading of a resonant dipole loop antenna (a simple circle of wire) is a function of the loop physical qualities, but also a function of the ambient magnetic energy.

The 1/f drift of a magnetically self-resonant copper loop may or may not track the local magnetic ambience.

Conjecture of device principles compliant with an oscillator driven to a bifurcation feedback-threshold

To investigate patterns of correlate-meaning buried in the embedded noise of a self-oscillation, an array of resonant loops connected by as an inverting-ring-amplifier would accumulate timing variations, and itself act as a summing amplifier of ambient energies that cohere in the ring oscillator's time dwell.

QAT approach to discovery of causal-linking in a wide array of sensors

The random selection of data for discrimination of the category of that member, can be used to animate a map of categories into abstract pattern-groupings that are correlate with parameters of a wide data mapping of environmental factors at the sensorization event of the data being analyzed.

Exactly what the QAT abstractions of categorical strata means (semantically) is not revealed by the abstraction, but that meaning is inferred by the human operator that selected a parametric conjecture which revealed the human-meaningful abstraction.

QAT implementation can find

Patterns over time in a data-stream. The patterns are structures in relationships of parameters to the source data, as recorded and index-able on the same time-line.

What the QAT event-discrimination is

A dual-category tree binary-testing for time-line coincedence of a data-read category-membership and a coincedent-parameter category-membership.

As a programmer's architecture, it is a binary-tree tagged with a linked-list per node of members (enabling member-count and reverse-lookup between conjecture trees).

Note: by tagging category member count information to a binary tree, that information can be recursively (linked list) retrieved to provide what Prueitt-Mitchell did with emergent-groupings using iterated balanced-random micro-movements.  I.e., whereas the proof used random sampling on time-line data to produce abstracted pattern-emergence, the data-structures supporting algorithmic proof will also support direct harvesting of the same information from along membership time-line links.  Therefore, iterative emergent processing of thousands to hundreds of thousands of cycles of random selection are reduced to a dual big-O fetch (binary tree navigation of a seek-index).  What this entails is that categorical strata can be mapped to an abstraction in real-time based on cross-time data-recursions of coincident-category datum count (cnt * big(O) fetches) populates the time domain without the random-driven mapping-thresholds of the QAT proof.  I am trying to express this: emergent processing using random-pair selection and micro-mapping can be replaced with determinant data-structures found in the binary-tree/linked-list  
Monetarily prudent implementation (workshop made): With Atmel 8-bit 8-pin processors on a bussed time-line as sensor data-loggers enabling a sensor-gridwork assembled as a harness routed for minimal impact on the harmonic system.  Each data-event stores and forwards the data-value until the processor services an interrupt for etching the time-stamped data to memory log.
Vision: Recent N-average-value windows processing recent random averages proportioned between conjectures to profile sub-phase averages (of category frequency found on membership time-line).  The 'data' is a time interval, based on a master quartz clock buss.  The interval data is an accumulation of clock-pulses.  All interval data channels are relative to the clock. Higher or lower clock frequencies will increase or decrease the resolution of an interval.

Conjecture: on categorical drift of durational window member-data categories, phase information will be available at some sampling resolution by the datum's position in its membership chronology.  Such phase is measured against a quartz time base sufficient to ensure 4-bit resolution for 7.5 mid-range of a zero to 15 control-loop.  

About recent average sampling algorithm

Algorithm used to make an Arduino digital comb filter

Technique: with each new data sampling of a floating A/D input (open circuit, unconnected) add the last N sample values, and divide by N for the average.
The new average each data-sample is the new output for the comb filter.
Separate N-averages for X-filter-channels are computed for each individual channel with a different N-value per channel.

As simplistic as it seems, recent-N average cancels oscillations shorter than the length of the windows, as the plus and minus cycles sum to zero, or no effect on the average of N samples. Differently put, signals are averaged-out of the running N-Recent-Averages window —unless the signal is harmonic with the N-samples window. Harmonic data events, sharing a duration with the N-samples, will sum and amplify.

The analog filter equivalent is a capacitor that integrates an average charge with respect to time (dV/dt). The capacitor has a time-base for ΔV, and certain frequencies are harmonic with certain capacitors in A.C. circuits.

By changing the number of samples to be averaged (N) to a larger number, very low frequencies can be filtered. Long averages will take more computing cycles. The Arduino operates in a continuous loop, and large values of N will slow down the cycle-time through the code proportionately, which is of no consequence for very low frequencies.

Instrumenting rotary magnetic self-resonant array

This study, as titled, intends to couple into local desktop space-timing, where a ring-amp is running a toroidal array with timing drift.

  1. Any real, noisy signal will have frequency drifts in the content frequencies of the noise.
  2. Any electromagnetic oscillation will cohere with an external electromagnetic oscillation if the two respective wave-fronts are coincident, or in-phase; coherent.
Conjecture of device performance:

A ring-amplifier of inverting-amplifiers that each output drives the self-inductance of a copper loop will establish the switching-time of each section to exactly the resonant dwell of the ring elements.

A test of an auto-harmonic ring amplifier devised is the Resonant X project. This puts copper loop resonator-halves (semi-circles) as the feedback-crossover "X" of a latching circuit.

Chaos theory -unknown signals need love too

The Resonant X experiment plus the inherent asynchronous operation (self clocked) of the ring sections also conjectured in principle to implement a decoupling of the prime driver (a basic DC power supply) dynamics from the harmonic condition of the copper elements. The time-base of the harmonic loops are their own time-clock.

Conversely, the opposite of decoupled harmonic elements is elements driven by a multi-phase AC signal that matches the natural harmonic time-base of the resonating copper elements. E.g., a digital Johnson ring counter can produce symmetric 3-phase signals from a digital clock. Such could clock the power-switches driving three phase resonators for a very tightly coupled resonance with the digitally-clocked prime driver.

The self-clocked ring-amplifier device approach allows for small purturbances of the magnetic ambience of a desktop environment to be accumulated as micro-timing adjustments on the exact switching time. Those micro-adjustments of phase-timing are summed around the ring, and will average over time to N-average-amplification of those frequencies in the environment that match the summing-time of the ring.

Please note that the ring amplifier signals (a voltage level per ring section, say three signals for 3-phases) are noisy in the time-domain, not the amplitude domain. In the ring of self-resonant magnetic dipole antennas the timing-variations would translate physically to variations around the toroidal ring array of magnetic flux density.

As timing-signals drift in a self-clocking ring of magnetic oscillators, such that phase-to-phase duration varies, the 'absolute' frequency measured against an external 'absolute' time base (quartz clock) will also wander. There will be an frequency-modulation over time.

This test device will be designed to record to a fast log (memory) the real-time variations (as is practical) of...

  1. The phase-signal duration (in quartz cycles) since the last phase, per each phase.
  2. A time-stamp, of the high-res quartz clock counter

With timing-variations data logs, data-driven graphical abstractions of magnetic harmonic trends over time would be attempted.

Further QAT examination may reveal correlations to number of sensorized phenomena about the resonating system.

Development will produce data-driven versions.

Previous μP test

The ten Dollar Arduino microprocessor (μP) ran six simultaneous recent N-averages, and serialized each average to the COM port that magically appears in Windows over the USB cable.

A program was written in Processing Language (A redundant name, eh?) to graphically represent the six data-streams multiplexed on the same serial port.

The results of low-pass filtering on the open-circuit noise (from 3" antenna of hookup wire) were stunning. The immediately obvious determinant in the room was me, the domesticated Codasaurus Hex. When I would move, the noisy signal would seem to jiggle differently. What peak-impact I had on the open-circuit A/D input of the Arduino, was yet just more jitters in the noise. My physical electronic contribution was part of the noise floor. But there were changes when I moved.

This biological explains: The A/D input on the Arduino was reading static charge in the air.

But the results of my motions on the A/D six-channel comb-filter (ish) output from the Arduino COM port was ephemeral. Repetition was difficult.

It was eventually conjectured that a charge-stratification in the small office were physically disturbed by air movements.

This needs testing. This conjecture followed discovering that my absence from the room allowed something to change. When entering the room after the air/static changed to (assumed) steady state -while the Arduino was running with the comb-filter channels running, then a large and continual ramping of the signal was displayed coincident to my person walking through the door toward the computer. This stood out dramatically on the six-channel display in the longer averaging channels.

Digital summation of multiple-readings does invoke digital amplification of regular signals that are recurrent within the same sampling window.

I do not have a formal comp sci knowledge to classify the digital filtering algorithm. For years I've considered this technique a comb filter. Please advise!

Don aght groupKOS doght cφm

defs and refs

  1. Reluctance is obtained by dividing the length of the magnetic path l by the permeability of the path, times the cross-sectional area A; thus r = l/μA, the Greek letter mu, μ, symbolizing the… The reluctance of a magnetic circuit is analogous to the resistance of an electric circuit.Jul 24, 2019 britannica.com
  2. ΔB, or delta-B, referes to a change-in-magnetic-flux-energy-density —positive or negative change.
  3. An average of the most recent N-samples. E.g., The average of the last 6 samples.
  4. A/D means Analog to Digital conversion.
  5. chaotic: signal noise of no apparent correlation to meaning.