Kapanadze and other FE discussion

[Hoppy]

Read the section entitled: 'ON THE LIGHT PHENOMENA PRODUCED BY HIGH-FREQUENCY CURRENTS OF HIGH POTENTIAL AND GENERAL REMARKS RELATING TO THE SUBJECT.' in the following link:

https://teslauniverse.com/nikola-tesla/articles/light-and-other-high-frequency-phenomena
Is Kapanadze using a Tesla plasma lighting effect using high frequency and high potential on regular light bulbs to achieve high illumination from a conversion of a low power, low frequency input??

[Void]

Hi Wesley. In my opinion, unless a person can at least show a video reasonably demonstrating that a
particular configuration produces 'over unity', or at least shows an interesting or unusual effect,
then any 'theories' and schematics, etc. that someone presents are likely not going to get too
much traction. It will likely just be seen as more unproven speculation to be added to the mountain
that can already be found here. This should really be a given at this point.

[stivep]

7. look at video  https://www.youtube.com/watch?v=zg8V9XCgIqs ( no sound)
Fabrication of a KNO3 capacitor
_{Explanation of the video is in point below Note2a}
==============================================================================

<sub>Ferroelectric  Capacitor
The construction of a KNO3 capacitor, and the hysteresis loop it displays.
The circuit used is the standard Sawyer-Tower circuit.
From TLP: Ferroelectric materials, http://www.msm.cam.ac.uk/doitpoms/tlp...
the link is not working but: there is copy  here explaining what video is about  https://www.doitpoms.ac.uk/tlplib/ferroelectrics/printall.php
For these who want to know more  https://www.doitpoms.ac.uk/tlplib/ferroelectrics/index.php


It will help also  to look  at:
https://www.youtube.com/watch?v=X0WnddW5gZI
https://www.youtube.com/watch?v=p7SkE5pERtA
Ferroelectric capacitor</sub>
https://en.wikipedia.org/wiki/Ferroelectric_capacitor



Wesley

[stivep]

Note#3
from video https://www.youtube.com/watch?v=zg8V9XCgIqs

Square hysteresis:

What the square S-curve hysteresis loop means is that, in one region of operation, with only a very tiny voltage change,
you can get a rather enormous current change from that capacitor. 
In another region of operation, you can get a very large voltage change from the capacitor for a very small current change. 
In other words, biased into one region, you have essentially a voltage device. 
In the other region, you have essentially a current device.  Neither device will "cost" you very much energy to operate it in its region. 
However, if you then nonlinearly mix the two outputs just right, as we filed on methods of doing, then bingo!
You had a mixer device whose output now had both large current and large power, but you "paid for" and input not nearly so much "energy dissipation"
(remember, engineers calculate energy dissipation flow, never energy transport flow!)
to the mixer as what would be output by the mixer.
The whole question is this. 
We all know about ordinary nonlinear mixing and mixers.   
We know that two signals can indeed be mixed nonlinearly.
Can we build a nonlinear mixer and a dual circuit, where we feed a voltage-like signal in and also a current-like signal in
to the mixer, get the two combined into a high voltage, high current signal output, and do that without back-field coupling onto the two input "signals"
to force equal energy dissipation in the input

_3a
Fabrication of a KNO3 ferroelectric capacitor
<sub>A capacitor can be made from potassium nitrate (KNO3), which is ferroelectric below 120°C.
(The temperature dependence of ferroelectrics will be explained later.)
The following video clip shows the construction of a KNO3 capacitor, and the hysteresis loop it displays.
The circuit used is the standard Sawyer-Tower circuit.
The result is a hysteresis loop.
This arises from the fact that a system does not respond immediately to a given set of external conditions.
Rather, there is a history dependence and this is the basis for memory (two states are possible in E=0).
doitpoms@msm.cam.ac.uk, © University of Cambridge DoITPoMS, Department of Materials Science and Metallurgy, University of Cambridge

3b.
Tom Bearden:</sub>

<sub>Ferroelectric Capacitors and the Magnetic Resonance Amplifier
In a nonlinear ferroelectric capacitor there are three major nonlinear processes involved, so it is possible to carefully choose and arrange
conditions so that the current through the capacitor moves against the voltage across its terminals.


With adroit switching and timing, and some consideration for resonance effects, it is in theory possible to use such highly nonlinear effects in a circuit to allow
(1) an overpotential at the terminals of the battery as a reaction from the ferroelectric capacitor,
(2) consequent recharging of the battery via that back potential on the battery side, while the load is also being powered,
(3) consequent driving of the load on the load side of the terminals, and
(4) having a bypass ferroelectric capacitor across the terminals of the battery, where the capacitor is in the "current against the voltage" condition.

McLain and Wooten patented a great little MRA (magnetic Resonance Amplifier) system, based on that application.
Dr. Robert Bass, a very fine electrodynamicist of exceptional knowledge, experience, and ability wrote the patent for them, and assisted in their work.
For that he was persecuted, unjustly attacked, and suffered financial difficulties.
The "system" does not forgive highly qualified scientists who take a serious interest in "perpetual motion machines" — as permissible Maxwellian
open dissipative systems are erroneously and derogatorily labeled by the orthodox scientific community.
Any scientist violating that inquisition suffers the consequences.
After technical discussions back and forth, the Patent Office even notified
Wooten and McLain that the patent had been accepted and the patent would be issued. 
Within days, to their consternation the patent was rejected and that was the end of that.</sub>

_Wesley

[magpwr]

Note#3
from video https://www.youtube.com/watch?v=zg8V9XCgIqs

Square hysteresis:

_3a
Fabrication of a KNO3 ferroelectric capacitor
<sub>A capacitor can be made from potassium nitrate (KNO3), which is ferroelectric below 120°C.
(The temperature dependence of ferroelectrics will be explained later.)
The following video clip shows the construction of a KNO3 capacitor, and the hysteresis loop it displays.
The circuit used is the standard Sawyer-Tower circuit.
The result is a hysteresis loop.
This arises from the fact that a system does not respond immediately to a given set of external conditions.
Rather, there is a history dependence and this is the basis for memory (two states are possible in E=0).
doitpoms@msm.cam.ac.uk, © University of Cambridge DoITPoMS, Department of Materials Science and Metallurgy, University of Cambridge

3b.
Tom Bearden:


Wesley</sub>

hi stivep,
I recall there was mentioned of S-curve hysteresis capacitor as one of the important requirement in one of the free-energy device i can't recall if it was Don smith or someone else.This was way before i even stumble upon Kapanadze discussion.
I can only recall fragmented information from my memory (Only Human)-There was mentioned of one of the American base company that manufacture this type of S-curve hysteresis capacitor for the Navy or military.The last thing i can recall from my head that this type of capacitor was not available to public.Around 10years have past from my last research related to this cap.