another small breakthrough on our NERD technology.

Bubba1 · January 21, 2012, 10:01:36 PM

Quote from: Rosemary Ainslie on January 21, 2012, 02:19:05 PM
... then it will BLOCK the anti-clockwise or negative flow of current from the induced counter electromotive force...

Rosemary:

What "... anti-clockwise or negative flow of current from the induced counter electromotive force."?
Are you saying that current runs clockwise through the circuit and through the inductor, then when the current suddenly stops, it somehow tries to reverse and run counterclockwise due to the collapsing field in the inductance? If you are, then that IS new science.

Bubba1

TinselKoala · January 21, 2012, 11:01:57 PM

Gahh.. I can't believe this. Rosemary, .99......

Has anyone actually done the test, with a FLOATING ground function generator set to produce an "AC" square wave as illustrated in the little FG symbol on the diagram? In other words, if the "ground" lead from the FG is connected only where the diagram says, and the circuit has no other connection to ground..... and the signal from the generator goes from +5 V to -5 V as measured at its output..... then it looks to me like the mosfets do flip-flop. On the other hand, if the FG signal is strictly DC pulses, from 0 to +5, then .99 is right and one never turns on.

Is it possible that the two of you are arguing over a misunderstanding about the FG's output?

Rosemary, now you need to learn what "Q" refers to in an oscillating RLC circuit. The larger the Q the longer the oscillation from a single "strike"; in other words, the lower the losses to resistance (heat) and radiation (RF) and the longer the energy stays sloshing around in the circuit. Remember my TinselKoil? Using a full H-bridge instead of the half-bridge in your circuit, and with a deliberately high Q, I am able to produce power amplification that you only dream about. By your measurement methods the TinselKoil is so far overunity that I expect the Men in Black to arrive with the suppression tools at any moment.

ETA: Here's a simple test. Take 2 LEDS and hook them "back to back", that is, anode of one to cathode of the other and vice versa. Now hook up your FG, ground to one anode-cathode pair and "hot" to the other. Can you make them both flash alternately? Of course you can.

Rosemary Ainslie · January 22, 2012, 12:08:20 AM

Quote from: Bubba1 on January 21, 2012, 10:01:36 PM
Rosemary:

What "... anti-clockwise or negative flow of current from the induced counter electromotive force."?
Are you saying that current runs clockwise through the circuit and through the inductor, then when the current suddenly stops, it somehow tries to reverse and run counterclockwise due to the collapsing field in the inductance? If you are, then that IS new science.

Bubba1

NO Bubba - absolutely NOT. I am saying that the voltage waveform across the shunt indicates a reversing polarity during the oscillation. It is our standard model that tells us that current flows in the direction of the greatest applied potential difference. Therefore RELATIVE to our circuit - IF the applied voltage is positive then the current flow will be greater than zero. And IF, the applied voltage is negative then the current flow will be less than zero. If you are presuming that when the current flow from the battery is interrupted and that CEMF is generating a NEGATIVE voltage potential but YET the current flow does NOT reverse polarity - then this is NOT EVIDENT. This is not the best proof - because a clamp meter can't measure accurate amperage at high frequencies. BUT. IF and when you apply those clamp type ammeters across the source rail - it shows a zero DC current - and only registers an amperage if it is sent on AC.

I have heard that there's a school of thinking that needs that current to flow in the same direction notwithstanding the reversal of the applied voltage. We have NOT found evidence of this. Certainly not on our circuit.

Regards,
Rosemary

Rosemary Ainslie · January 22, 2012, 01:51:33 AM

Actually guys - this may be a better way to explain the anomalies and it may also get to the heart of Bubba's objection. The oscilloscope probes are placed directly across the batteries that ground is at the source rail and the probe is at the drain. Which is standard convention. Then. During the period when the oscillation is greater than zero - in other words - when the battery is DISCHARGING - then it's voltage it falls. And it SERIOUSLY falls. It goes from + 12 volts to + 0.5. Given a 6 battery bank, for example, then it goes from + 72 volts to + 3 volts. At which point the oscillation reaches its peak positive voltage. And this voltage increase is during the period when the applied signal at Q1, is negative. WE KNOW that this FAR EXCEEDS THE BATTERY RATING. In order for that battery to drop its voltage from + 12V to + 0.5V then it must have discharged A SERIOUS AMOUNT OF CURRENT. Effectively it would have had to discharge virtually it's ENTIRE potential as this relates to its watt hour rating. We EXPECT the battery voltage to fall during the discharge cycle. But we CERTAINLY DO NOT expect it to fall to such a ridiculous level in such a small fraction of a moment AND SO REPEATEDLY - WITH EACH OSCILLATION.

Now. If we take in the amount of energy that it has discharged during this moment - bearing in mind that it has virtually discharged ALL its potential - in a single fraction of a second. And then let's assume that we have your average - say 20 watt hour battery. For it to discharge it's entire potential then that means that in that small fraction of second - during this 'discharge' phase of the oscillation it would have to deliver a current measured at 20 amps x 60 seconds x 60 minutes giving a total potential energy delivery capacity - given in AMPS - of 72 000 AMPS. IN A MOMENT? That's hardly likely. And what then must that battery discharge if it's rating is even more than 60 watt hours? As are ours? And we use banks of them - up to and including 6 - at any one time. DO THE MATH. It beggars belief. In fact it's positively ABSURD to even try and argue this.

NOW. You'll recall that Poynty went to some considerable lengths to explain that the battery voltage DID NOT discharge that much voltage. Effectively he was saying 'IGNORE THE FACT THAT THE BATTERY VOLTAGE ALSO MEASURES THAT RATHER EXTREME VOLTAGE COLLAPSE'. JUST ASSUME THAT IT STAYS AT ITS AVERAGE 12 VOLTS. Well. It's CRITICAL - that he asks you all to co-operate on this. And in a way he's right. There is NO WAY that the battery can discharge that much energy. SO? What gives? Our oscilloscope measures that battery voltage collapse. His own simulation software measures it. Yet the actual amount of current that is being DISCHARGED at that moment is PATENTLY - NOT IN SYNCH.

But science is science. And if we're going to ignore measurements - then we're on a hiding to nowhere. So. How to explain it? How does that voltage at the battery DROP to +0.5V from +12.0V? Very obviously the only way that we can COMPUTE a voltage that corresponds to that voltage measured across the battery - is by ASSUMING that there is some voltage at the probe of that oscilloscope - that OPPOSES the voltage measured across the battery supply. Therefore, for example, IF that probe at the drain - was reading a voltage of +12 V from the battery and SIMULTANEOUSLY it was reading a negative or -11.5 volts from a voltage potential measured on the 'other side' of that probe - STILL ON THE DRAIN - then it would compute the available potential difference on that rail +0.5V. Therefore, the only REASONABLE explanation is to assume that while the battery was discharging its energy, then simultaneously it was transposing an opposite potential difference over the circuit material. WHICH IS REASONABLE. Because, essentially, this conforms to the measured waveforms. And it most certainly conforms to the laws of induction.

OR DOES IT? If, under standard applications, I apply a load in series with a battery supply - then I can safely predict that the battery voltage will still apply that opposing potential difference - that opposite voltage across the load. Over time. In fact over the duration. It most certainly will NOT reduce its own measured voltage other than in line with its capacity related to its watt hour rating. It will NOT drop to that 0.5V level EVER. Not even under fully discharged conditions. So? Again. WHAT GIVES? Clearly something else is coming into the equation. Because here, during this phase of the oscillation, during the period when the current is apparently flowing from the battery - then the battery voltage LITERALLY drops to something that FAR exceeds it's limit to discharge anything at all. And we can discount measurement errors because we're ASSURED - actually WE'RE GUARANTEED - that those oscilloscopes are MEASURING CORRECTLY. Well within their capabilities.

SO. BACK TO THE QUESTION? WHAT GIVES? We know that the probe from the oscilloscope is placed ACROSS the battery supply. BUT. By the same token it is ALSO placed across the LOAD and across the switches. It's at the Drain rail. And its ground is on the negative or Source rail. And we've got all those complicated switches and inductive load resistors between IT and its ground. Could it be that the probe is NOT ABLE to read the battery voltage UNLESS IT'S DISCHARGING? UNLESS it's CONNECTED to the circuit? Unless the switch is CLOSED. IF there's a NEGATIVE signal applied to the GATE then it effectively becomes DISCONNECTED? In which case? Would it not then pick up the reading of that potential difference that IS available and connected in series - in that circuit? IF so. Then it would be giving the value of the voltage potential that is still applicable to that circuit. It may not be able to read the voltage potential at the battery because the battery is DISCONNECTED. It would, however, be able to read the DYNAMIC voltage that is available across those circuit components that are STILL CONNECTED to the circuit? In which case? We now have a COMPLETE explanation for that voltage reading during that period of the cycle when the voltage apparently RAMPS UP. What it is actually recording is the measure of a voltage in the process of DISCHARGING its potential difference from those circuit components. Which ONLY makes sense IF that material has now become an energy supply source.

It is this that is argued in the second part of that 2 part paper - as I keep reminding you. Sorry this took so long. It needs all those words to explain this. The worst of it is that there's more to come.

Kindest regards,
Rosemary

Rosemary Ainslie · January 22, 2012, 02:53:53 AM

Hello again TK

Nice to see that you're coming into this discussion.

Quote from: TinselKoala on January 21, 2012, 11:01:57 PM
Gahh.. I can't believe this. Rosemary, .99......

Has anyone actually done the test, with a FLOATING ground function generator set to produce an "AC" square wave as illustrated in the little FG symbol on the diagram? In other words, if the "ground" lead from the FG is connected only where the diagram says, and the circuit has no other connection to ground..... and the signal from the generator goes from +5 V to -5 V as measured at its output..... then it looks to me like the mosfets do flip-flop. On the other hand, if the FG signal is strictly DC pulses, from 0 to +5, then .99 is right and one never turns on.

I see this now. Poynty Point is either right - or? He's right? That's an interesting take. But you see this TK. We get that SAME oscillation with the application of a 555 switch with the supply shared with the same circuit battery supply. There are no differences - except in our range of testing options. THEN. If either one or other MOSFET was conducting current from the battery - how exactly do you EXPLAIN that extraordinary voltage swing that is measured at the batteries? It goes from fully charged to NOTHING - and, on some higher applications of applied energies - TO A NEGATIVE VALUE? Do you, like Poynty, prefer to think that it is capable of discharging its potential - to such EXTRAORDINARY EFFECT? That's an awful lot more energy measured over the circuit than we can reasonably account for.

Quote from: TinselKoala on January 21, 2012, 11:01:57 PMRosemary, now you need to learn what "Q" refers to in an oscillating RLC circuit. The larger the Q the longer the oscillation from a single "strike"; in other words, the lower the losses to resistance (heat) and radiation (RF) and the longer the energy stays sloshing around in the circuit. Remember my TinselKoil? Using a full H-bridge instead of the half-bridge in your circuit, and with a deliberately high Q, I am able to produce power amplification that you only dream about. By your measurement methods the TinselKoil is so far overunity that I expect the Men in Black to arrive with the suppression tools at any moment.

What can I say TK? Except that, as always, your experimental skills are monumental. Unfortunately - my own are more pedantic. And I prefer to stick to the point.

Quote from: TinselKoala on January 21, 2012, 11:01:57 PMETA: Here's a simple test. Take 2 LEDS and hook them "back to back", that is, anode of one to cathode of the other and vice versa. Now hook up your FG, ground to one anode-cathode pair and "hot" to the other. Can you make them both flash alternately? Of course you can.

That's a comfort. If I get around to doing this test - I"ll let you know. We have, indeed, used two banks of LED's to our circuit in place of that element resistor number. And surprisingly, the one bank stays permanently lit - no flashing - while the other stays dark. Also rather puzzling. But also in line with what we predicted in terms of a reversing current flow.

Kindest as ever
Rosie