Hello.
I would like to address my question to those members of the forum who have prior experience in developing electronics professionally.
I had recently found an article (in Russian) that seems to summarize all my theories of how Free Energy devices that involve some sort of transformer may work.
https://translate.google.com/translate?sl=auto&tl=en&js=y&prev=_t&hl=en&ie=UTF-8&u=http%3A%2F%2Fhalerman.narod.ru%2FTTCG%2FKapanadze.htm&edit-text=http://halerman.narod.ru/TTCG/Kapanadze.htmThis article talks about efficient ways of exciting a Tesla Transformer using an oscillator that is Phase Lock Looped to the self-frequency of the Tesla Transformer SECONDARY and that applies an occasional impulse to maintain the oscillations.
The timing of this impulse is very critical and it compared to the automobile ignition timing.
If, indeed, transformers that work in the impulse mode can create Free Energy from Aether entering the device as the magnetic field collapses, than it makes a perfect sense to excite them at their resonant self-frequency and to measure the voltages and currents that exist inside the transformer after a square impulse was applied.
I would like to test different ferrite-core transformers and air-core transformers using this experimental rig.
1) Is occasional impulse method of driving a transformer more efficient than just using a transistor that is connected to the secondary for feedback and excites the primary?
2) Is this method better than the traditional Tesla Coil method of adding a pulse from a capacitor bank as voltage on the secondary decays?
My hypothesis is that Mother Nature tends to generate harmonic oscillations and in doing so, additional energy may be drawn from the aether to add to the energy that was brought to the transformer by the input impulse.
I want to test all the possible "Free Energy" transformer devices using this jig.
(http://s2.postimg.org/r78trpk85/Scan_140612_0005.jpg)http://s2.postimg.org/blri7r8a1/Scan_140612_0005.jpg-----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
There are two ways to construct this device.
A traditional PLL synthesizer that uses the coil resonance as a clock source and a digital approach.
(http://s9.postimg.org/fgmcu79d7/Scan_140612_0006.jpg)http://s9.postimg.org/p15zh2ypb/Scan_140612_0006.jpgOR
A Microcontroller - DDS impulse generator that uses a frequency divider to measure the oscillator frequency and some kind of DDS to generate an impulse.
(http://s28.postimg.org/tjuty7pux/Scan_140612_0003.jpg)http://s28.postimg.org/u9dmakqel/Scan_140612_0003.jpgSince my experiment will run in the 10KHz to 1MHz frequency, using a microcontroller directly would not be possible.
I would need some kind of ripple counter for this purpose.
Timing of the input impulse would be rather difficult. In case with traditional PLL, I would need a voltage-controlled oscillator that outputs a pulse every N number of oscillations.
In case with a microcontroller I would need to use an algorithm and circuity to time the pulse perfectly at very high frequencies.
So I will need to consider the time it takes to make a decision that the pulse has to occur and subtract it from the timing of the pulse.
I bought a
http://www.analog.com/static/imported-files/data_sheets/AD9833.pdfI am not sure how many steps are offered to shift the output phase.
I see this in the datasheet:
The analog output from the AD9833 is
fMCLK/228 × FREQREG
where FREQREG is the value loaded into the selected frequency
register. This signal is phase shifted by
2π/4096 × PHASEREG
where PHASEREG is the value contained in the selected phase
register
But Pi is an irrational number...
Maybe I should buy a different Analog Devices IC to generate the pulse.
A triangle output of AD 9833 makes it suitable, however there are very few examples of how to interface it to Arduino.
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I am designing a circuit that would be able to excite any RCL resonator at the 10KHz to 1MHz frequency range.
I would need to connect the circuit to Arduino anyways because I would like to see the output frequency on a text LCD and I would like some rotary encoder inputs to tweak some variables.
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Help me design a circuit, please.