Hi Med,
remember I was suggesting you induced feed from Tesla coil (from its antenna as I have shown you before)

If you want to drop the frequency to low KHz range, we can connect it directly to TV Flyback or I have 22KHz 10KV Neon transformer. But I think in that case it will need more turnes. To avoid any disfunction the impedences must correspond. On the output probably the HV diode bridge and bank of capacitors.

Hi John,


i think you worry about the E-TBC turns too much, at this point don't worry at all but we need to worry about the resonance, i agree with you a few turns are problematic since the magnetic feedback will be weak, i tested some E-TBC with one turn and less than one turn ! the result is poor even it's not 100% correct to evaluate this device without correct resonance ..

about the induced feed from Tesla coil, i have another point of view even your suggestion maybe correct, we could use another E-TBC oscillating in resonance if CD is open, this is our previous plan! now if we put inside this one another E-TBC with closed CD connection, the first coil will provide a strong induced electric field able to charge our main E-TBC with its rotating field, the objective here is to charge the capacitive side without problems, previously you suggested using a HV diode inside the E-TBC to block the negative oscillation in X point, this will be done in the excitation E-TBC.

Hi Med, My concern about the turns of ETBC is just becouse self resonance With that few turns the measured resonance of my ETBC is exactly 2.78MHz. I have just made a secondary of my new Tesla coil resonating on the same frequency. Than I will connect HV side of the secondary to the ETBC and puls it with just one pulse and gert respond on my scope from the feed back turns (just couple turns on ETBC?? How we can measure E- field?? Any Idea?

i don't understand your setup, please clarify it or you could draw it if you can ?

My setup something like this??

thanks for your drawing! your setup look like focusing in radiant effect only, your Tesla coil will produce such event without problem but unfortunately
energy balance can't be caught very easy there, in other hand we have to think about from where it's better to take the power from the E-TBC, in your setup i guess it's AB point, these point are very important so it's better to keep them as free oscillation END, with this you are sure your E-TBC is free to receive the power from ambient back ground, this device is an open device in both side, in energetic side and regarding the flow of electricity since Lenz's can't be applied and this is the advantage here.

the induced rotating electric field isn't similar to potential voltage, the first is known as no conservative electric field ( even this is not true since the E-TBC is able to catch it ) the second is the common known voltage between any ordinary two points, the E-TBC work in more dimensions so we focus in the energy available in each point not between two different point! now take a look at this drawing and see how the coil is wound the same as the induced rotating field flow, the extension is necessary to keep the power and give another dimension to it :




all the important phenomena start from X point and will END there, the two side give either a current or voltage, if R the resistance is present this will transform the reactive power into active power, this involve closing CD connection and try to achieve the resonance in this condition.

if this is done, just prepare your capacitor banks to harvest the power!

Hi John,


there's another remark about your setup, in reality it's a problem because there's a connection from your Tesla coil passing through the diode into capacitor and finally to the earth, my proposed setup will be very easy and clear in practice, similar to one of DS patent when he used another coil named receiving coil, this coil was used but not connected to the primary side neither to the secondary side, i guess this coil is an E-TBC with closed CD connection. the connection is a slow now i will post the drawing later even i think it's here in some place.

Just to give the proposed setup to charge the E-TBC without problems, please take a look :



the above is simple drawing where we have the excitation E-TBC connected directly to the source of high voltage of course with open CD to achieve the resonance, the same magnetic field produced will pass through the main E-TBC where we have to close the junction CD ( this is necessary at discussed ), this coil don't need any direct connection since it will be charged with the induced rotating electric field which in turn will charge the capacitive side of the main E-TBC and after that the device will oscillate as expected without problem, is there a need for high voltage diode in the excitation E-TBC to avoid the back oscillation ? i don't know but we have to test the setup without diode, i guess we don't need a high voltage diode if we adapt the spark gap distance so it will be very difficult for the negative oscillation to start, even if it did it will be very weak, the excitation E-TBC have to be made with a good number of turn at least to achieve a strong magnetic field able to maintain the oscillation of the main E-TBC as long as possible

NB : L2 coil have to be inside not as shown .

Hi Med. Thank you for your drawing, but I am confused now. I see two ETBC in one? Where are the A,B ? If it is two ETBC - how are they connected? What is the purpose o the open coil L2 in this drawing?

Too many question but it is hard to understand Can you please make a technical- detailed description (drawing) of your setup please? Including source, all inputs (ABCD) and their connections.

Thank you.

Hi John!

you are welcome, the two E-TBC are separated since there's no electrical connection between them ( this is not the mixed E-TBC ) , the excitation E-TBC is connected from AB, the spark gap in CD. when the spark jump a strong magnetic field is produced, the same magnetic field will just enter the main E-TBC ( this is the target coil ) this field will produce another induced rotating electric field because the junction CD is closed in the main E-TBC it will be very easy to charge it statically without the need of resonance! this is the trick here, every adjacent foils will receive a different of voltage due to the rotating electric field, so we need a good magnetic field to start the operation, after that the capacitive side will be just charged as normal even if CD is closed, in reality this is an advantage here since the connection is good for this field to built its elementary voltage.. if the capacitive side is charged the main E-TBC will just oscillate with it resonance frequency, now L2 coil was just drawn for clarity purpose, this is your output coil and you just need to manage the produced power from the oscillating main E-TBC that was charged by the induced rotating electric field.

the excitation coil will give some power but since there's no electric current there, we just need it to start the operation, the good news is the ability of E-TBC to oscillate for a long time if CD is closed is something promising

welcome once again !

@ John

if you have further questions don't hesitate to ask.

Hi John, hello everyone,


i guess the previous proposed setup is good, sometimes i don't like to think about Donald Smith schematics since it may give a wrong destination, sometimes it's good if you have the correct idea so his advices maybe very helpful, in this step i have to be confident because i know what i am talking about, for sure there's some optimal conditions for better results, one of them is the frequency of oscillation for the main E-TBC, higher frequency is better for energy multiplication purpose, to achieve good frequency in the proposed setup we have to think about what's happening inside the E-TBC ? more turns with a relative low capacitance is great choice, this will result in a good magnetic field feedback the low capacitance make it easy for that field to charge it ! so you can achieve higher frequency without real problems.

more suggestion will appear in real practical test, Good night

In reality low capacitance will produce a good oscillation but we have to think twice here, because the same electric charges in the capacitor will transform again into magnetic field and so on... low capacitance may lead to weak magnetic field, the two parameters magnetic field plus the induced rotating field have to be related to the length and width of the E-TBC for optimal conditions, contrary of ordinary coil here the length is the electric current and the width is the voltage!!

Hi John, hello everyone,


i think it's not bad to post other ideas about the new promising technique to feed the E-TBC with appropriate method, i would like to suggest a relatively wider E-TBC, i mean the diameter of the excitation E-TBC have to be large, the same about the main E-TBC, why this is better ?


the strength of induced rotating electric field is related to the surface area where the magnetic field flow, this mean more area lead to stronger induced electric field, it's better to use the excitation coil to be over the main E-TBC so we are sure most magnetic field pass through the main E-TBC.

there's another option maybe someone else will try it, it's the use of the mixed E-TBC as excitation coil! the mixed E-TBC is really a strange coil because it's able to produce a huge magnetic field compared the single E-TBC, it's possible to use it in each side of the main E-TBC as the following drawing :

Hi Med.
I was just about to do it opposite way.

The strength o magnetic field depends on the number of turns. Smaller diameter means more turns, right??