I don't think Aziz is disagreeing with this. Yes, it is dB/dt that induces eddy currents in the target. And it is di/dt that produces dB/dt. I think our only disagreement is with the flyback voltage... it is an artifact of the system.

If Aziz is seeing a higher flyback that is settling faster, then I expect it is due to a faster di/dt and the arrangement of the mutually inductive coils. I doubt it is due to the higher voltage burning off the current faster. I think it is this cause & effect where we disagree.

But that's OK. The main thing is, does it Really Work? I will have an answer tomorrow. I am (right now) winding the two coils -- one center-tapped & one not -- to compare this method with the std mono. I have the mono wound and hot-glued into a TDI shell, will have the CT coil done tonight. Then I will put them on my HH board and see.

Stay tuned...

- Carl

Gentlemen, allow me to disagree.
I say it is the expanding magnetic field produced by the coil current, that kicks the target. The Flyback is actually reducing the eddy currents in the target.
The Flyback is too short to "saturate" for want of a better word, the target.
The Flyback induces currents of opposing polarity since the magnetic field of the Flyback expands and then collapses, that is, the field cuts across the target conductor first the one way, the the other way.
The current raising in the coil during TX, generates an expanding magnetic field that cuts across the target \ conductor and induces currents within the target. The first currents are superficial skin effect currents. It takes time for the eddy currents to expand to the core of the target.
How much time? The time needed has been named the TC of the target. High conductive and large size targets have long TC's. Large silver coins can have a TC of hundreds of uS.
If the TX pulse is short, the eddy currents will not have the time to expand to the very core of the target, so they will not reach maximum amplitude.
Now look at the Flyback. It's duration is a matter of nano seconds for the one way and a few micro seconds on the return. Its highest power is at the maximum voltage point that is about even both ways and of a duration of nanoseconds. Just too short to induce much eddy currents. And going both ways, thus canceling the eddy currents induced by the going field, with the field collapsing.
However, the eddy currents induced by the TX coil current persist for some time.
How much time? about the same time it took to generate them The TC of the charge curve equals the TC of the discharge curve.

So, how will I prove my point? I will show you that I can read the eddy currents without having a Flyback.
Better than that, I will show you that, without the Flyback, the amplitude of the eddy currents is much higher.
I will pulse the coil with a usual square wave TX pulse but will modify the circuit to eliminate the Flyback.
Below is the scope picture of the coil current.
The pulse length is about 64us, you can see a slight kink and noise spike where the TX switches OFF. Forgive me for the noise spike, I don't think it can be called a Flyback.
The scope is set at 20us \div and 10mV\div.
Note, this is the coil current, not the TX voltage wave form.

Please allow me some time to setup an RX circuit to read the eddy current. Just the preamp.
I will use US$ 1c, 5c, 10c, 25c as test targets.
Monolith

Aziz in an effort to see where your coming from in regard to the fly back i have a question,
The attatched scope pic is of a target signal taken straight of the receive coil.

Setup
1/2 inch round copper tubing bent into a circle of 18 inches diameter with ends not connected together,used as transmit coil.
Two receive coils residing within transmit coil,approx 30 turns of wire per receive coil,receive coils connected opposite in phase to cancle out flyback signal.
12 volts on transmit,45 amps running through coil,max current reached within 10u/s,pulse width 34u/s


Question
if i understand you correctly you say the flyback kick starts the eddy currents on the target.
on the scope pick,at the start of the transmit,while current is rising very fast i get a very good signal on the target,yet there is no flyback to generate this high target signal,are you able to explain why this is so???

Zed

Physically, it has to be so... induction is only caused by a changing magnetic field, not a static one. What other opinions are there?

I've experimented with switched damping, that is, where the damping resistor is switched in during the flyback. I did this in my security wand, strictly for lower power.

- Carl

This is just what I am talking about. My signal amplitude is about 10 times as high at the beginning of the TX pulse than after TX switch OFF. Using a common IB coil combination.
Not only that, it also DISCRIMINATES between FE and non magnetic targets.

What kind of relation of signal amplitude have you observed between sampling during TX ON time and TX OFF time?

Monolith

Aziz in an effort to see where your coming from in regard to the fly back i have a question,
The attatched scope pic is of a target signal taken straight of the receive coil.

Setup
1/2 inch round copper tubing bent into a circle of 18 inches diameter with ends not connected together,used as transmit coil.
Two receive coils residing within transmit coil,approx 30 turns of wire per receive coil,receive coils connected opposite in phase to cancle out flyback signal.
12 volts on transmit,45 amps running through coil,max current reached within 10u/s,pulse width 34u/s


Question
if i understand you correctly you say the flyback kick starts the eddy currents on the target.
on the scope pick,at the start of the transmit,while current is rising very fast i get a very good signal on the target,yet there is no flyback to generate this high target signal,are you able to explain why this is so???

Zed

It sounds like your circuit is not able to switch off fast for some reason. Can you check that?

Regards,

-SB

The only way to get this sorted out is for several people to post comparable results.
Same amount of power, same amount of amplification, same targets.

Monolith

Hi Monolith,



I have achieved now a true compareable simulation system. I will add now the target response model, which requires a simulation model of 4 independend systems. Otherwise a true comparison is difficult to visualize.

But it shows, that SPICE simulations gives an enourmous potential to understand what is going on in the process. As the physical models are a typical second order functions (R,L,C second order of differential equations), it is quite difficult to solve the equations analytical (beyond my scope). SPICE tools are solving these equations with numerical methods and let show you the complex process.

I am really impressed about the SPICE simulation results, which will help to understand the PI technology better. So I was able to proof the idea in a different way and showed me the faulty of some thoughts.

I recommend all people to play with some SPICE simulations. The better the model is defined, the better will be the result to the real word. Now I will work on the topic to extract some benefits - if any - of the new findings.


Aziz

I was referring to Monolith's ideas that the growing magnetic field, not the collapsing one at turn-off, was causing the target signal that is detected.

Yes, critical damping is the fastest for a fixed RLC system. If it's underdamped, the decay will slew faster but then ring. But what if you switch in the damping R just before the decay crosses zero? You will get the initial fast underdamped decay, then switch to critical damping to avoid ringing. However, it is VERY timing sensitive.

- Carl