04-08 Aug 2021. Observations: Scaled peaks are the big spikes on 'the schumann'
Thank you for being here. My "day jobs" have been keeping me busy.
I've been working on this particular presentation for over 2 weeks now, as I have been able to. Time seems to be flowing by effortlessly.
Since the last known image of the Tomsk Schumann has gone on sabbatical, it seems fitting to do a video on the last known configuration, which had stalled at 03-05 Aug 2021 while it was down [currently, it's back up again].
(*As a gentle reminder, I am a deep dive into what's happening. It can take a few days to gather data, then make a report on what I've observed. There are those who are looking to link a spike with a physiological symptom, and that is not what my job, nor mission here is. *)
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To this point, I've addressed many of the common issues presented, as part of understanding the spectrogram and graphic information.
The "big spikes" are one of these issues that I've been addressing recently. What are the "big spikes" in reality (the physical realm)?
In order to competently answer this question, we need to understand the process of detecting a signal; where it goes thereafter; then ultimately qualified through the spectrum analyzer of the spectrogram.
"The Schumann", is more than just the image found on the spectrogram; as the spectrogram is an analysis, not a detection of the signal itself. There is a process to get this graphical representation. The spectrogram ('The Schumann') is an analyzer of the signal itself.
Simply looking at the spectrogram, and calling all the notable amplitude spikes as huge spikes is not helping anyone's understanding of what's going on. Eventually, the rhetoric becomes reduced to "click-bait."
There's developing to be a growing tradition to see all the vertical spikes as "big spikes on The Schumann."
I have made the statement in the title that "scaled peaks are the big spikes", but what exactly does this mean?
___ To resume where I started this project :
31-24 July 2021. Big Spikes On 'The Schumann' - response to Wages World
"RESTART- C4 FLARE MORE POSSIBLE COMING AT EARTH" - ( https://youtu.be/GUn7FWSVf0o )
- Building The Lexicon.
This is a discussion of the lexicon , and the belief behind the statement "big spikes on 'The Schumann'" in relation to vertical spiking on the spectrogram.
The language we use, the words we choose, inform our conceptions of the external, phenomenological world. We can not amend our mental formations without words; nor can we convey clear communications without clear images in our heads--generally informed through the logical-word exchange.
The biggest issue we have at odds with our clear understanding of the events, and phenomena at hand, is our mental informations. How clear is the picture in your head of what's happening?
Helping to clear-up some of the misconceptions behind the muddled vocabulary, further obscuring the truth.
Another reason to distinguish the difference between "The Schumann", and the SR spectrogram, is the understanding on how to read the data presented.
- Basic understanding of the hardware.
Spectrogram is an analyser; not the actual antenna-detector hardware.
The antenna hardware detects a signal, then it is amplified, and processed before being sent into the spectrogram to be analyzed.
Spectrogram NEEDS an antennae detector unit, the physical hardware, in order to be able to analyze a signal.
-Spectrogram And Its Dependencies.
The spectrogram is an analysis of a conditioned signal, coming from the detector hardware. Conditioning of the signal includes dynamic filtering, and amplification to a line level strength signal.
Spectrogram is a spectrum analysis of the conditioned signal from 0.3-40 Hertz frequency horizontal; 0.1-1,000 deci-Bels of pico-electron-Volts in vertical conductivity. The spectrogram can not be read by itself, meaning without te reporting dependencies to give the correct, actual number values.
Ampitude is the electric side is the signal, as measured in deci-Bels of pico-electron-Volts. A dipole type antennae is the detector unit for Amplitude; which is properly seen as Intensity, or signal height. This is also called the vertical conductivity channel.
Quality is the magnetic-side of the signal, as measured in pico-Teslas. A pair of induction coils is used to detect the Quality of the signal, which is the process of converting from voltage of the Intensity, into the horizontal channel of the atmospheric resonances.
Frequency is the standard means of measuring radio waves, of Kilometers, from peak-to-peak. White mode signals are small frequency values, because the waves are taller and thinner.
Modes are the representations of the slope of a waveform. This may be one of the most difficult concept for folks to grasp. The modes are what create the color pallet used to plot the patterns seen on the spectrogram. The technical term is "slope"; which is another way to say 'size and shape of a wave'. Mode is a relationship between the height to the width of an incoming rf signal.
Another way of looking at Modes is to see "slope" of the waveform as a function of time, relative to a lightning strike. [SR are the echoes of lightning discharge into the environment. An amplitude burst (lightning strike) is a release of voltage from the upper atmosphere into the local environment/lower atmosphere where we live.] This discharge, in theory, appears as a spike in the vertical conductivity channel; plotted as a vertical spike on the spectrogram. Beginning part of the SR signal starts-out vertical: as tall and thin as it's going to get. In theory, the vertical spikes are expressing lightning discharges; which we might consider to be the "purest" portion of the signal.
Amplitude spikes quickly convert into magnetics, as they travel around the globe. In one second, the original burst of amplitude has travelled around the world 8 times. Each time it propagates thusly, the amplitude burst has met-up with itself; for a total of 8 times, within the second. Each of these meetings creates ripples, and then more ripples, which are the standing waves of the resonances. Eventually, these continued meetings, which create the schumannn resonances, resolve into atmospheric harmonics which silently "hum" in the background, imposing a quite sort of organizing principle for the residents of a planet. In theory, we want those to remain stable.
(* Note: Before going further, let me say thank you for following along the best that you can. i work to be positive in my presentations. I know that there's a few who can grasp this. Yet, despite how simple I can make this in words, the actual technology and science behind this is fairly complex. I have many years experience in electronics, and related pursuits. I am able to grasp this stuff readily enough...yet, it's still complicated.
There is, in all reality, a steep lurning curve to this, for those just coming into this, without much related experiences. If you are not getting what I'm presenting, it could be how I written things. It could be that I'm simply not clear enough. Please ask questions for clarity in the comments section. *)
- Scaling The Results
This is where things start to get complicated.
We have the three dependencies of Amplitude, Quality, Frequency. Each of these three factors is further divided into 4 modes each. This gives us 12 active color channels that we use to plot the signal received from the detecting hardware of the antenna; in addition to the background colour channel of the at rest state of the fair weather baseline; this gives us a total of 13 color channels.
The colour pallet used by the spectrogram is as follows:
A1=White; A2=Yellow; A3=Red; A4=Green
Q1=White; Q2=Yellow; Q3=Red; Q4=Green
F1=White; F2=Yellow; F3=Red; F4=Green
Fair weather, at-rest state=Dark Blue.
Mode ascribes a slope (a size/shape dynamic) of the relationship between height of Amplitude and width of Quality. This can be see as a "cross-section" of the wave, depending on it's time of arrival; or, as the part of the wave that arrives first, middle, and last.
As Amplitude, arriving first as Amplitude Mode 1 (white), it will be the tallest, and thinnest of the waves. The Yellow mode slope follows; then the Red mode slope expectation; then finally the green mode wave slope is the tail end of the section detected by the antennae.
The horizontal constraint is 40 Hertz. The last measurable harmonic is approximately 39.9 Hertz resonance.
Vertical conductivity is not constrained by the Hertz measurement. Hertz is the unit of measure of cycles per second, or 'peak events.' Amplitude is the vertical conductivity channel; which is measured in deci-Bels of pico-electron-Volts.
Vertical conductivity is not operating in the Hertz scale, so the plotting of Amplitude is different from the hoizontal channels, even though the same scope is used.
Amplitude spikes are generally misunderstood by the majority of folks, mainly because they are not observing the spectrogram through the lense of the dependencies. (Above, in this essay, have I explained the dependencies, which correspond to the graphical image included in this presentation.)
The reports of two independent antennae detecting units (the Marconi/dipole type, and the induction coil type) are plotted on one single spectrogram analysis, to approximate a three-dimensional image, based-upon color cues to your visual sense. The principle is essentially that the lightest colors jump forwards, darker colours recede into the background.
When evaluating the patterns of the spectrogram, it's important to have operating principles, through which to process the patterns.
Once we realize that the spectrogram is now showing us 3D/4D/5D, nor timeline shifts, nor ascension energies, nor is it showing gamma bursts, nor any of this mystical fancies which beseige the brain, in attempting to decypher the color code information.
Amplitude spikes are not measured in Hertz. The height of the amplitude spike is not determined by the 40 Hertz horizontal frequency. Amplitude is not measured in Hertz frequency units. Amplitude is in deci-Bels of pico-electron-Volts. The top of the spectrogram represents the momentary peak, as an analyzed signal, for the purposes of representation.
The spectrogram is not a literal measuring device. The dipole antennae is the acual detecting device. The Antennae device is a quantitative device. Spectrogram is a qualitative device, designed to illustrate the radio frequency spectral phenomena which is otherwise invisible to the unaided eyes of a human observer.
Amplitude spikes are scaled to fit into the available space provided by the constraints of the device itself.
- Comparing Peaks
We compare the period of 03 - 05 August 2021 : [A] 18-21 LT, 03 Aug. ; [B] 10-19 LT, 04 Aug.
[A] 3 peaks (roughly 1.5 hrs between each) : 47.6, 78, 62.8 dB-peV.
Each spike registers as a "pegging of the meter" upto the top of the spectrogram.
We compare [B] which features a rolling "peak" over a few hours. The picture the line graph shows is not of a peak, but more of a surge. We look, once again, at the actual number values provided by the line graph dependency.
When we can see this as a real-time updating, scaled to fit the incoming data, we can get a more true, correct picture of what the spectrogram is telling us: it is NOT giving us an actual, real-time, absolute-value reading, as an analog signal. The line graph is the analog, showing the actual, proper number values.
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