Bloch wall disconnect and reconnect. The final design!

[giantkiller]

@forest & sparks,

I understand what both of you are saying and can apply that with this build. I replaced the core with the 1 turn speaker wire core and a bucking primary/secondary pair on that.

You can see one side inside. The center winding is angled just for the photo shot.
This build is better suited for the next tests. Now I can serially connect the little toroid like the this pic http://www.overunity.com/index.php?action=dlattach;topic=8227.0;attach=42704;image
and then serial connect this config into the sport model build. So I will have a interconnected driver inside another interconnected to achieve multistage interconnection. A pancake within a pancake or ionizer within an ionizer.
The inside windings are 180* of the outside tho not 90* like previously specified. But that can be changed in 30 minutes if it is a problem. So this little gem is a Don Smith pcv tube in a dual bucking pair. Inside and outside.

Condenser, capacitor or electrostatic microphone
Inside the Oktava 319 condenser microphone

In a condenser microphone, also called a capacitor or electrostatic microphone, the diaphragm acts as one plate of a capacitor, and the vibrations produce changes in the distance between the plates. There are two methods of extracting an audio output from the transducer thus formed: DC-biased and radio frequency (RF) or high frequency (HF) condenser microphones. With a DC-biased microphone, the plates are biased with a fixed charge (Q). The voltage maintained across the capacitor plates changes with the vibrations in the air, according to the capacitance equation (C = Q / V), where Q = charge in coulombs, C = capacitance in farads and V = potential difference in volts. The capacitance of the plates is inversely proportional to the distance between them for a parallel-plate capacitor. (See capacitance for details.) The assembly of fixed and movable plates is called an "element" or "capsule."

A nearly constant charge is maintained on the capacitor. As the capacitance changes, the charge across the capacitor does change very slightly, but at audible frequencies it is sensibly constant. The capacitance of the capsule (around 5â€"100 pF) and the value of the bias resistor (100 megohms to tens of gigohms) form a filter which is highpass for the audio signal, and lowpass for the bias voltage. Note that the time constant of an RC circuit equals the product of the resistance and capacitance.

Within the time-frame of the capacitance change (as much as 50 ms at 20 Hz audio signal), the charge is practically constant and the voltage across the capacitor changes instantaneously to reflect the change in capacitance. The voltage across the capacitor varies above and below the bias voltage. The voltage difference between the bias and the capacitor is seen across the series resistor. The voltage across the resistor is amplified for performance or recording.
AKG C451B small-diaphragm condenser microphone

RF condenser microphones use a comparatively low RF voltage, generated by a low-noise oscillator. The oscillator may either be amplitude modulated by the capacitance changes produced by the sound waves moving the capsule diaphragm, or the capsule may be part of a resonant circuit that modulates the frequency of the oscillator signal. Demodulation yields a low-noise audio frequency signal with a very low source impedance. The absence of a high bias voltage permits the use of a diaphragm with looser tension, which may be used to achieve wider frequency response due to higher compliance. The RF biasing process results in a lower electrical impedance capsule, a useful byproduct of which is that RF condenser microphones can be operated in damp weather conditions which could create problems in DC-biased microphones whose insulating surfaces have become contaminated. The Sennheiser "MKH" series of microphones use the RF biasing technique.

Condenser microphones span the range from telephone transmitters through inexpensive karaoke microphones to high-fidelity recording microphones. They generally produce a high-quality audio signal and are now the popular choice in laboratory and studio recording applications. The inherent suitability of this technology is due to the very small mass that must be moved by the incident sound wave, unlike other microphone types which require the sound wave to do more work. They require a power source, provided either via microphone outputs as phantom power or from a small battery. Power is necessary for establishing the capacitor plate voltage, and is also needed to power the microphone electronics (impedance conversion in the case of electret and DC-polarized microphones, demodulation or detection in the case of RF/HF microphones). Condenser microphones are also available with two diaphragms, the signals from which can be electrically connected such as to provide a range of polar patterns (see below), such as cardioid, omnidirectional and figure-eight. It is also possible to vary the pattern smoothly with some microphones, for example the Røde NT2000 or CAD M179.

[giantkiller]

First test on the Sport model.
http://www.youtube.com/watch?v=5nGZNmi4Xdo

Just the wiring diagram. 1khz into the control coils, variable frequency into the ring. Driving with 120vdc.

Have the center toroid  inside with led across outside winding. No lights yet but 4 - 27vac.

[supersam]

@gk

i sure hope nobody is in the bathtub with a blow dryer tonight!

keep up the great work!

lol
sam

[wings]

5khz hiss from fast electrons in the plasmasphere is popping up "hear" and there

http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6V6T-46YCW19-7&_user=10&_coverDate=01%2F31%2F1981&_rdoc=1&_fmt=high&_orig=search&_sort=d&_docanchor=&view=c&_searchStrId=1236086608&_rerunOrigin=google&_acct=C000050221&_version=1&_urlVersion=0&_userid=10&md5=a251dc0ea2a5af4790a4b5a68b95de18

So if you develop a loop receiver and excite it to open up the aperature  (place hearing horn to ear) the probability of converting elf incidence upon an expanded field of interest may be enhanced.  It is theorized that the brain reshapes the cavity influenced by the vibrations of the tympanic membrane to become resonant at the suspected frequency of transmission.  In other words an older person often goes deaf because they hear too much.  The muscles used to tune the ear to specific freqs loose their ability to sweep tune the cavity. The brain is constantly tuning the cavity for those freqs that are of interest such as those a child would make if it were crying or the rustle of leaves a prey would make as it moved through the forest.  A spectrum sweep.  Once the older person is aware that you are speaking to them they hear you fine because by habit their brain tunes the ear cavity for amplification of the human voice signal pattern.  You get the huh or what then they hear you.  Just amplifying the whole deal doesnt work well because the scanner isnt working inside the ear cavity.  There are more intense vibrations but they are not coherent with the cavity.  Newer hearing aids are programmed to output a small instigation vibration and delay the signal.  The person is hearing you not in real time anymore but at least they are hearing you.

http://jlnlabs.online.fr/plasma/html/s_gdp3.htm
http://jlnlabs.online.fr/plasma/html/s_gdp1.htm

[wings]

5khz hiss from fast electrons in the plasmasphere is popping up "hear" and there

http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6V6T-46YCW19-7&_user=10&_coverDate=01%2F31%2F1981&_rdoc=1&_fmt=high&_orig=search&_sort=d&_docanchor=&view=c&_searchStrId=1236086608&_rerunOrigin=google&_acct=C000050221&_version=1&_urlVersion=0&_userid=10&md5=a251dc0ea2a5af4790a4b5a68b95de18

So if you develop a loop receiver and excite it to open up the aperature  (place hearing horn to ear) the probability of converting elf incidence upon an expanded field of interest may be enhanced.  It is theorized that the brain reshapes the cavity influenced by the vibrations of the tympanic membrane to become resonant at the suspected frequency of transmission.  In other words an older person often goes deaf because they hear too much.  The muscles used to tune the ear to specific freqs loose their ability to sweep tune the cavity. The brain is constantly tuning the cavity for those freqs that are of interest such as those a child would make if it were crying or the rustle of leaves a prey would make as it moved through the forest.  A spectrum sweep.  Once the older person is aware that you are speaking to them they hear you fine because by habit their brain tunes the ear cavity for amplification of the human voice signal pattern.  You get the huh or what then they hear you.  Just amplifying the whole deal doesnt work well because the scanner isnt working inside the ear cavity.  There are more intense vibrations but they are not coherent with the cavity.  Newer hearing aids are programmed to output a small instigation vibration and delay the signal.  The person is hearing you not in real time anymore but at least they are hearing you.

"The narrow-band 5 kHz hiss seems to be generated by the cyclotron instabilities of several keV to a few ten keV electrons for the most feasible electron density of 10 cmâˆ'3âˆ'103 cmâˆ'3  in the vicinity of the equatorial plasmapause since the hotter electrons with energy of 10â€"100 keV are dominant just outside the plasmapause. This will be the origin of the narrow-band 5 kHz hiss observed frequently in mid- and low-latitudes."

that can explain :

"An interesting measurement : The current flow is NOT equal in each branch of the GDP wire."

(because the connection to the ground is different)

with 41.54w input .... Voltage and the Current curves measured at the GDP output

"The left bottom scope picture, shows the third channel of the scope, this is the Math channel, ( Math=Ch1xCh2 ) this gives in real time the curve of the power flow. The "M" channel is set to 100W/div, the measured data on the right side "M Mean" is the Mean power =-173.3 W and the "M RMS" is the Root Mean Square power = 219.4 W"

http://jlnlabs.online.fr/plasma/html/s_gdp4.htm