Understanding electricity in the TPU.

[wattsup]

@GK

I asked @groundloop to help in a circuit which he did today with thanks man.

The circuit will have three mosfets, 6 transistors, a control IC and caps and resistors, etc. I really did not think it would have been so complicated to make such a simple control but what do I know. I will make the circuit and test it out. It should be good up to 18mhz so this will be such a great tool to test with. Once the circuit proves OK, I will post the schematic since @groundloop prefers I do not post it before it has proven itself, which is a good way to go about this.

[giantkiller]

a 50 nanosecond pulse @ 50% is 25 nanosecond on time with a 10 nanosecond rise and fall should do the trick. You gonna be able to get 5 nanosecond?
I was hoping to have the controller that Jason is building. It does 20megahertz. 50 nanosecond rise and fall time showed promise on the bifilar lamp test we did with his previous controller.

IST has a vid where he puts a magnet next to the core to raise the freq.

[wattsup]

@All

Just to let you guys know that I have been working on a potential control circuit with the great help of @groundloop. The problem of switching as shown in my diagram as shown above on this page by @GK is much more difficult then one would think. lol

It may be an omen, but this ties directly into the question I had asked on Post #1. Pulsing a coil is a dime a dozen. Switching them as shown above is another thing.

SM once said it took him a long time to work out the control circuit for his TPUs and this may be one of the reasons why it is so hard to do.

You can do it with relays but they will stop pulsing at around 100 hertz. So what to do if you want to go up to 20mhz when even a low 5000 hertz is very difficult to do.

Hopefully during the weekend we will see some advancement.

wattsup

PS:

In my Voltage Grabber CIrcuit, I am showing that in order to accomplish something like increasing voltage and amperage, you have to concretely attract, hold, multi-store, multiply, restore, multiply and restore again in order to have the energy "grow" in the circuit.

Anyone doing Free Energy research has to contend with this one fact. If you do JT then you are stepping across one or two of the stages in the VGC but you will still eventually have to use the VGC as a later stage. Whether you shuffle with 2, 3 or more caps then discharge them into a bigger one afterward, the system will still need this way of accumulating the amperage. Or find me another way that can concretely do this.

You can pulse a coil until the cows come home. But just pulsing will not do and finding a miracle pulse method will eventually require that coils be switched around otherwise you will never make a field move. It will just explode and implode over the same space and create a resonance radiant energy.

Now radiant energy is not bad because you can have 100s of smaller circuits catching it all and then do the same thing as the VGC. You can have one circuit catching some of the energy and use it to bias the rings. You can use another one to drive a pulse circuit. Etc. All these can be driven via radiant energy and each circuit would remain totally isolated form the others while working on the same core(s) or laminations.

Anyways, more soon.

[wattsup]

@All

I asked @groundloop if it is OK to put up the following circuit diagram he made which is what he is building for testing as I will be doing also. The diagram is not an end product grade since there will definitely be some changes. he also sent this photo of his circuit. Looks nice. Mine will definitely not look as nice as this. I will put up a photo once I make it for new version.

But this diagram follows pretty well what I had in mind, yes in my Simpletons' mind, lol, was to use not more then three mosfets, but we will see if it works out well enough to move a blotch wall and hence to move a field. The original circuit was not as elaborate and my tests were not showing good results, so hopefully this next diagram will be OK.

The basic function is this.

Pulse off, both coils are connected in series to make one coil all wound the same way. The coils should not be wound in bucking mode. At pulse on, the coils become two coils with their individual positive and negative potentials.

More soon.

[Groundloop]

@All,

Test of two coil switch circuit.

The circuit does not uses any current up
to 5,6 volt with no function generator input.
Above 5,6 volt I start to get a DC bias
to the gate of the transistors and the circuit
will start to use current.

With a low frequency input (12KHz) and with a
function generator signal of 20 volt, the circuit
starts to switch current at Ub 0,2 volt. At 1 volt
the current into the circuit is 1,7 Ampere. This is
with a low frequency.

At high frequency (5MHz), the circuit starts to
use current at 3 volt. At 4 volt the Ub current
is 1,6 Ampere. At 4,2 volt the Ub current
is 2,6 Ampere and the transistors and ultra
fast diodes starts to heat up a little.

The circuit runs at 4.0 volt with a Ub current
at 0,78 Ampere when tuned to the ferrite core coils
resonant frequency (in my case 1,53MHz).

I inserted a Ferrite rod into the coils. I then
added a 40 turn coil to the rod. Connected two
small light bulbs (2,5v / 0,2A) in series to
the extra coil. At no frequency from 25KHz
to 5MHz did I get any light in the bulbs.

The circuit seems to switch both the high
coil, the low coil and also the middle
connection between the coils when the Ub
voltage is lower than 4 volt.

I do not have a o-scope at home right now
so more testing is needed to verify the circuit
operation.

Attached is a image of my Ferrite rod coils and bulbs.

Groundloop.