been playing with the L2 tuning and blocking cap.
I reversed them.
Now the tuning cap is near V+
And the large DC blocking cap is near L1.
This also works, giving interesting results.
Still the impulse duration is too fast, need a capacitor parallel over L1 to tune it down
when reversing the L2 caps, I also reversed the connections of the coil.
So the inside rim of L2 is always connected to the tuning cap, and the large DC blocking cap is connected to L2 outside rim.
If I would not do that, I would have to flip the L2 coil over at TEM resonance.

maybe of interest - ever seen these little grounding straps for shoes (this one's called 'PRJ20')? Conductive carbon-silicone electrode with adhesive backing. Supposedly has general anti-inflammatory and other subtle health benefits, and I like to think it helps ground me slightly if I forget to wear ESD bracelet. Perhaps something to test and writeup, I like the suggestion to start a little play-bench here, stay tuned brethrens :emperor:

Quote from coldelectric on March 31st, 2021, 07:55 PM

maybe of interest - ever seen these little grounding straps for shoes (this one's called 'PRJ20')? Conductive carbon-silicone electrode with adhesive backing. Supposedly has general anti-inflammatory and other subtle health benefits, and I like to think it helps ground me slightly if I forget to wear ESD bracelet. Perhaps something to test and writeup, I like the suggestion to start a little play-bench here, stay tuned brethrens :emperor:

Nice!
But I am only grounded when the circuit runs. This is because of the high voltage impulses, and the electric fields. I just put up a new E field meter, and around 20cm from the coil is 1000V/m which isn't healthy at all.
So I keep my distance, and I stay grounded when it is running.

E field meter:
https://www.aliexpress.com/item/4001064780386.html?spm=a2g0s.9042311.0.0.6b774c4dyg7gKu

But when the circuit is turned off, I disconnect from ground. I do this, because the DC charged caps that give L2 (or L3) the dc offset, can be lethal.  I always discharge these caps before working on the circuit (modifying)

So the ground is on  and off. not very practical with shoes. But I do like the idea to ground via feet

I made the new coils smaller, and this has brought the resonant frequency up to above 100kcps.
and thats only the tem the lmd is even higger.

So I need bigger caps in my tuning board.
also need a bit larger coils
or larger buckets and coils.

I bought 5 liter buckets, and the coil could become slightly bigger.
But they also sell 10L buckets. Probably will go for those. and make some bigger coils. with lower resonant frequencies.

did more testing with the small coils, in semi LMD mode.
L2 is on the LMD mode, but if L@ is tuned to the lower TEM mode, then L3 is an octave higher resonant. this should not be.
Both L2 and L3 should be resonant at TEM and LMD.
L2 is flipped over. so compared to L3 its counter rotating.

 L3 close coupled to L1, L2 loose coupled to L3, 15mm
tuned L3 with 61nF
tuned L2 with 49nF
L2 should be smaller and L3 bigger.


Still could see a nice current wave on L3, while close coupled to L1. current of L3 is amplified, by the impulse.
impulse enters via large cap of L2, no the resonant tuning cap (tuning cap is on the V+ side)

SCR04: green is L3 current
yellow is L2 voltage (DC coupled showing DC offset)
orange=L3 voltage
Note L2 and L3 are out of phase, because L2 is flipped over, they should be in phase. This is probably because L3 is in TEM mode.

SCR05:
Same, but orange now is between L2 and the big cap, showing impulse.
I didn't use a cap over L1

If I loaded L2 with L4 and a 12V 5W bulb, the current sine of L3 wasn't tune able anymore, so I used no load.

If L2 and L3 are correctly tuned (whereby L3 is much larger in capacity) Then L2 probably will have large voltage, While L3 has large current.
voltages of L2 and L3 are then in phase, if L2 is flipped over, or out of phase, when L2 is not flipped over.
I flipped over L2, to get the current feedback of L3 into L1 in the right polarity, in LMD mode.

this was at 122,6 kcps
input power: 20V 0.4A=8W

I added 60nF to my L3 parallel tuning board.

I still have L2 and L3 out of phase. I wonder if L3 is able to phase shift when it is close  coupled to L1.
I don't fully grasp the logic.
What I know is with LMD resonance, the voltage of L3 is 180 degrees phase shifted compared to L2.
But... that is not the problem. What if L2 also is phase shifted in voltage, compared between TEM and LMD resonance?
HMM...
The Idea is the L3 current should be constructive, both from magnetic induction of L1 and LMD resonance with L2.

I assumed, L3 being close coupled would not phase shift. Therefor, I flipped L2 over. to correct the phase.
I need more information on the phase relation ships of L2 and L3 in TEM and LMD resonance.
Or... compare this test, with L2 not flipped over. see if it draws more or less current.
From the looks of it, I still am at TEM resonance since L2 is flipped, and L2 and L3 are out of phase. So at least I should tune higher, and look for the LMD resonance.


20V 0.57A input power
6:
orange is L2 ground (big cap) showing impulse of -400V (300nS)
yellow=L2 resonant 222Vpp  tuned with 41nF
green = L3 current 10App  tuned with 111nF
Res freq= 99.55kcps (TEM)

7:
same, but orange is L3 voltage 136.2V pp

NOTE: L3 current (green) is amplified!

edit:
I tuned up, and could not find another resonant sine wave. So I tuned down, and indeed! I found another resonant sine wave at 60.65kcps. Which drew a lot more current! 1.26A at 9,4V  I tuned the voltage down, because I like to keep the impulses low for now.
8 shows that L3 (orange) and L2 now are in phase. Phase shifted, so this is the TEM resonance.
OK, back to LMD resonance.

flipped L2 over in LMD resonant mode. input current went up, so I was right.

So cool to have this basic setup working. So whats next?
check L2 for current amplification.
check higher voltages
check L4 output

pfew...
The E field probe, went above 1000V/m again. Going to take a brake and sit on the E chair

Quote from evostars on March 29th, 2021, 11:47 AM

I will use the biggest inside ring of the pentagram

The second lesson was the knowledge of THE PENTAGRAM. That is the ability to distinguish the five bodies of man one from another. When someone says: physical body, etheric body, astral body, Kama-Manas body, causal body, [higher Manas or spirit self] these are mere words, or at best, abstract ideas. Nothing, however, is achieved by that. A person living today as a rule hardly knows the physical body; only one who knows THE PENTAGRAM learns to know the five bodies. One does not know a body by living in it, but by having it as an object. That is what distinguishes an average person from one who has gone through such a schooling that the five bodies have become objects.

https://wn.rsarchive.org/Lectures/GA093/English/RSP1985/19041216p01.html

HOW TO BUILD WITH ATOMS THROUGH THE POWER OF THINKING
https://www.facebook.com/permalink.php?story_fbid=876790522727673&id=100011901996265

The pentagram, is completely PHI ratio! Note that the frequency differnce between TEM and LMD resonance in this video, is almost phi ratio.
LMD=106kcps
TEM=65kcps

back to research.
I have a feedback loop, that works. L1 and L3 is close coupled, L2 is loose coupled to L3, and L2 is flipped over.
When tuned to the higher LMD resonant mode it should feedback the energy in a loop.

I analised the  phase shift of current and voltage of L1 L2 and L3.
And I came to the conclusion that current wise L1 shows the same phase of L3.
L3 current is shifting phase, and so does L1! How can that be?
As L1 still produces negative impulses. Very weird. need to take a close look at this.

I wondered if L2 shifted phase, as it is loose coupled, but it doesn't. L2 stays the same.
Only L3 phase shifts between TEM and LMD resonant modes.

This unlisted video shows the experiment (only sscope shots).
I used the 2019 radiant power circuit for this.

https://youtu.be/IExeR-PGuV4

radiant power circuit 2019, with coils stacked like this:
L1-L3----L2 (flipped)
is a feedback loop! the energy runs 2 ways!
When L2 is flipped over, and tuned to LMD resonance the following happens:

L1 is pulsed by the mosfet. It generates a magnetic field.
L3 is close coupled to L1 and is magnetically induced to be parallel resonant, by L1's magnetic field.
L3 is the secondary, and L1 is the (first) primary coil.

L2 is series resonant, by the opening and closing of the mosfet.
L1 produces a impulse when the mosfet opens the circuit. Its built up magnetic field collapses, and transforms into a dielectric high voltage short duration impulse.
The impulse of L1, is injected into L2, as L2 is a low impedance path to ground for the L1 coil energy to discharge to.
L2 is amplified in current by the L1 impulse.

L2 is the (second!) primary coil for L3, which is the secondary (so it has 2 primaries, one magnetic induction by L1 and one dielectric induction by L2).
L2 induces LMD resonance in L3 by dielectric induction.
because LMD resonance causes a phase shift in L3, I need to flip L2 over, to get the right phase in L3.
This way, L3 can couple back its LMD magnetic field back into L1, which reduces power from the power supply.

L2 is in series with L1, when the mosfet has opened the circuit,  L2 also charges L1.

So the energy is looping around in 2 directions.
from L1 into L3(magnetic induction) into L2(dielectric induction) into L1

And L1 is feeding into L2 (impulse energy), L2 into L3 (dielectric induction) and L3 into L1 (LMD magnetic induction).

You could call this counter rotation magnetic fields, but that's not completely accurate.

Further more, to complete this picture, The impulses of L1 create a positive DC offset in L2.
This charges up the L2 L3 coil capacitor, where by the L2 and L3 pancake coils, acts as the plates of a capacitor.

The impulses on L2 temporarily discharge the L2 L3 coil capacitor. Which creates longitudinal waves from L3 into L1.
 In theory, this discharge of the high voltage L2/L3 coil capacitor is an implosion of the dielectric field. This implosion creates a vacuum to be filled by the ambient medium, the Aether.  This inflow of ambient Aether current, is free, and used for magnification.

This feedback loop already works. now I need to get the current amplified again, as I have seen it do before.

what if I flipped L1 instead of L2?
that would make L2 and L3 in phase at LMD resonance, while L3 still couples current back to L1.

in phase L2 and L3 is better for the impulse voltage discharge of the L2 L3 coil capacitor

tested with flipping L1 over instead of L2 (not flipped over anymore). this also works, but no real difference. L2 and L3 still .... of phase. I cant remember if it was in or out phase between l2 and l3. they should be in phase so I assume they were out. :-/

So then I reversed L2 again, but not by flipping over. I reversed its connections (including blocking cap and tuning cap that are in series.
This gave an even lower current draw from the power supply.  And L2 and L3 are now .... I need to do the test again and write it down

what I did notice with reversing the L2 and its caps, it now could produce a proper impulse again on L2, which is needed to discharge the capacitor. this is because the impulse now enters from the tuning cap side, instead of the large blocking dc cap.
So I will keep it like this for now. Low current from supply, high current(slightly amplified) and impulse in L2.

I found a really nice application for voice to speech which I am now using it's called LilySpeech.com

I had a lot of troubles getting the right phase of the the resident coils and I decided to use the arrow on the current probe to 2 direct away from the resonant coil measured on the inner Rim.
The l1 coil is also measured on the inner Rim with the arrow pointing away from the coil.
 this way I know that the currents in the coils will have the same phase or are out of phase

so the arrow of the current probe points to the inside of the coil

edit: ****SOLVED*******
something is wrong and I found out while making a video.

I was about to test the current of a single high switched coil.
I expected it to resonate at it's resonant frequency, when the mosfets were turned off but it didn't, it gave a single spike, and right befor the mosfet turned on again, a small bump.
I have seen that bump for a while now, and it has been bugging me. Should not be there.

I use 2 mosfets that are switched simultaneously on and of with a 50% duty cycle 70kcps pulse.

video shows all:

https://youtu.be/rUDlZwByw6o

ok, positive cycle of the L1 resonant ring, opens up the body diodes of the mosfets, and passes it, into the capacitor bank, the diode between the power supply and the cap bank is closed, as now the cap bank is charged to a higher voltage than the power supply voltage. this explains the low current of 40mA at 20V. after the first negative impulse, the energy is recycled back into the caps, and reused.
I could fix this, by placing the diode between the cap bank and the drain of the first mosfet.

did several test today, to make sure what the direction of the currents in the coils are.
L3 in LMD mode definitly is 180 phase shifted. I made several video recording of it for future reference, need to edit them down.

This  means for a consructive feedback loop, one coil needs to be flipped.
But... there is another option.
I can also reverse connect the L2 and its capacitor.
This means, the tuning cap will be on the positive supply/ drain. and again connected to the inside rim of L2. This reverse the phase.

This way I can make a feedback loop, without flipping any coil over, all will be clockwise. My intuition says this works best, if you want an aether field flow that runs flawlessly.

this means, the impulse of L1, will enter L2 on the non resonant outside rim, passing the large capacitor.
I have played a little with this, but not enough yet. to know of all the quirks

Another issue, are the ripples that keep occuring on the positive maximum, right before the mosfet turns on again. I cant pinpoint the cause of it, but it is a problem. it seems to come out of the L1 coil, or, from the isolated gate driver.
I have had this problem for a while now. and I need to fix it. Badly.
So maybe I will try connecting the batteries again, instead of the isolated DC DC to see if that will fix it. but I doubt its that...

if I will need to use a battery again for the gaye driver IC, to get rid of the distortions, then I will use Li ion in combination with a boost converter.

That should work stable,
and the isolated dc dc converter could be used to charge the li ion again, but probably that would cause problems again.

still need to locate the cause of those ripples on the positive voltage max. suspect it is related to the isolated dc dc converter

I need to check what the frequency is of the problem ripples, then compare it ti the frequency of the isolated dc dc converter.
if they match...

here you can see the impulse (orange) on the left, at turn off (purple low)
and the ripple before turn on (purple high).

the ripple is around 1Mcps (1uS per period)
the impulse is faster.

The r12p22005D isolated dc dc converter of this circuit, is much slower. between the 20 kcps and 50 kcps
https://www.mouser.in/datasheet/2/468/RxxP2xxyy-1709962.pdf

the ripple is faster, meaning, its not the coil by itself, faster, means less capacity. So the ripple is slower, it has more capacity.
it could even be response from L2 into L1.

but not the series capacity of the gate driver circuit. this would not increase the capacity, and make the frequency slower

just did a test for feedback loop again.
none of the coils were flipped.
instead L2 was reverse connected, with it tuning capacitor on the drain side.
This should have brought l3 and L2 currents in the same direction.

but it didn't.
Maybe the LMD resonance wasn't complete, I need to check for the TEM resonance again, see if it is also a sinewave for both L2 and L3.

maybe... L3 LMD current, is reversed because its negative?

did another test with the reverse connected L2 and tuning cap
as expected, L2 now as reversed current, and when coupled to L1 the input supply has very large current 3,5A dc at 20v 70kcps, 41nF L2 tuning cap.

This means, with LMD resonance L3 should be phase reversed, and in phase with L1.

BUT it isn't.
I looked at the video of the 3 coil test again, and noticed, L2 is phase reversing again when tuning.
This is the cause of the phase reversal.

Now why is L2 reversing phase?
I think, it is, because L3 is pushing L2 out of phase.
I still need to do one more test. I need to see if I can tune in TEM and LMD into the looping system.  Both TEM and LMD should have a single sine wave on L2 and L3. If not, then one of the coils isn't properly tuned.

I checked for TEM and indeed, couldn't dial it in. L2 has a higher octave resonance. no sine wave.

L3 is 121nF and L2 is 41nF so this needs to be corrected.

L2 needs to be bigger, or L3 smaller

getting very tired quickly, So I will stop testing, and sit on the chair to rebalance.

I'm really excited about the feedback setup I'm now working on.

all the coils ar now wound in the same direction, none are flipped over.

tuning is tricky but also fun as I have a strong intuitive drive to achieve this.

and I'm still working without the dc offset which makes it safer. I will use it once it is better tuned.

with L2's tuning capacitor on the drain side, it is out of phase with L1 which is on the other side of the 3 coil stack (will be 4 in the future)
L2 will be LMD resonant with L3 and this makes L3 in phase with L1 again.

I also will change the power supply capacitors. right now its a series parallel stack of 4x 680nF, but I will put them all in parallel.

from the previous tests (which I recorded) I learned L1 gives a positive impulse that travels trough the mosfets body diodes, in  to the capacitor bank. but although they are high voltage impulses, the cap bank stays low in voltage, So I better replace them with 100V dc rated caps.

maybe... it will make the ripples disappear

anyway. I feel really good about this direction.
still many steps to take but it feels go to know where I am going.

 :bliss:

played a bot with tuning.
noticed both L2 and L3 phase shift when tuning into LMD resonance.

must show it on video cant type it out

as L3 is close coupled to L1,
and L2 is only loose coupled to L3

L2 will naturally have a lower resonant frequency than L3.

This is because the close coupling of L1 to l3 introduces mutual inductive and capacitive coupling, which raises the resonant frequency of L3

this means to tune L2 and L3 to the same resonant frequency, L3 always needs to have a little bigger capacity than L2.