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Biefeld Brown rotating electric field across plates with a centre plate as a triode.
Strartrek Cyclotron effect at node, tapping the zero of two opposite cancelling vectors.
By swapping over the inductor capacitor in series.
Creates a rippling d.c. Field on top plate. So it is always positive.
See Spiral Lissajous figures.
To boldly go where no "man" has ever gone before.
Initial idea.
After running a few simple resonator circuits you find that a parallel resonator capacitor & inductor combination has max impedance & acts as a near open circuit load at resonance & the voltage source feed appears on the output. No voltage gain or build up of source to output voltage. However, if you build a series resonator resistor, capacitor & inductor at resonance it looks purely resistive as the reactive components L & C cancel like a short but the voltages build and can be orders of magnitude above the excitation voltage but cancel out. The trick is to put the parallel resonator circuit across either of the limbs of the series inductor or capacitor, as the parallel resonator has nearly infinite impedance it doesn’t load the series stage & you’ve got your parallel oscillator at high voltage driven by the series resonator. Connect many parallel resonators from one series source. Resonant frequencies of parallel & series resonators are tuned to the same frequency.
I used small signal model and low frequency, rule of 10x for loading to demonstrate the principal.
A 1V ac sine wave source at resonance 159Hz, gives 10v output across the series inductor then driving the parallel resonator. you can split the single capacitor from a 10µF into 2no. 20µF in series.
You can see the scaling into the kV range and beyond just by driving up the input voltage a few orders & frequency shift. The main problem seems to be generating a dc mid bias point so the driving signal can go from 0v to 2Vin with a Vin offset while still resonating.
Output parallel resonators are alternating 180° out of phase and the d.c. offset at 10v midpoint allows the swing 0v to 2Vs top plate relative to the bottom plate by using another capacitor. Using the small signal model we have 1V a.c input building and scaling to 10v a.c. then 20v to 0v d.c. offset a.c. relative to bottom plate.
Freewheeling mode added by switching off the Vin of 1V a.c. then isolating the outputs of the parallel resonators. These are ideal components and series resistance within the inductors will damp the oscillation before re-exciting.
The whole concept is to be scaled to high frequencies and kV voltage range.
The parallel resonators are arranged alternative pairs and symmetrically around the craft, there is always a high positive voltage on one set of top capacitor plates when there is a zero voltage on the other set of top capacitor plate alternating.
Reference- http://etheric.com/flux-liner-electrogravitic-propulsion-system/
Varying the parameters of input voltage from the small signal demonstration with 1V input and 10V output 10:1 so 100V input gives 1kV output. Probable operation inline with the Foo Fighter Analysis with 300V input giving 3kV output.
Capacitor analysis, stacked capacitor plates forming series capacitors 1/Ct=1/C1+1/C2 etc or for n plates 1/Ct=n.(1/C1) gives Ct=C1/n this improves the breakdown voltage between plate/dielectric/plate.
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