However, playing with Mr. Thévenin's theorem and the fact that coil/target system works as a (very non-ideal) transformer, that 500ohm would interfere with target taus.
It would not interfere greatly with target signal strength, but will surely screw up any chance of correct discrimination.

No, the most important advantage is coming from early decay (being able to sample the high frequency target response).

But the issue with parasitic (coil) capacitance remains.

Yes, for an ideal step response.

Long-tau eddy responses have a delayed peak whether ferrous or non-ferrous.

Basically.

Depends on the detector design. For tiny fast-tau gold you need a high slew rate TX signal just to induce a decently detectable eddy current. You can potentially "see" this response even if you don't "remove" the energy, which is what VLF gold detectors do.

- Carl

You just calibrate it out in the disc system.

You can't. It is coupling related, hence the effect changes with distance. OK, PI are not famous for accurate discrimination, but this could change with some clever designs such as the Tinkerer's. We'll see.

Aziz,

I hear you but consider the following. If the eddy current response in the coil is taken to be a 1 nanoamp source then yes the 1 ohm does not attenuate relative to a 500 ohm damping resistor. But if there is no damping resistor, then the resistance may be high- say 1 megaohm.

1 nano amp into 500 ohms is 2000 times less of a voltage to measure than into 1 megaohm.

So IF the signal we are trying to detect is nanoamps and comes after flyback then having no damping resistance at that point as Moodz has done should help greatly. I did say IF which comes back to my original question.

Chudster

Hi Chudster,

You say:By the way I found this little reef known as "Lasseter's" not too far from my house http://en.wikipedia.org/wiki/Lasseter's_Reef . I'll share its location if someone can show me the magic eddy current blip If we don't know the signal we are searching for, it is a solution that needs no detector.

I can show you with a simulation what the target response of a 1us target looks like. But, you and another zillion people are going to say: "Ah, simulations are just not like the real thing." And you are right, even if the simulation has been created to show what I have observed on real circuits.

This is why I have posted the full TX and RX circuit that can show you the peak signal of a 1us target. http://www.geotech1.com/forums/showp...&postcount=168

The HEX file that goes with the circuit is not optimized for a 1us target, but I will re-write the timing schedule for you if you build the circuit and want to test and observe specific features.

The circuit is very robust. It will work even on a bread board. The only parts that must be soldered is the TX due to the high voltage combined with the relatively high current.

Don't be fooled by the low power consumption of less than 200mA at 12V. The TX has a peak current of about 4A at several hundred volts.

All the best

Tinkerer

Tinkerer,

Thanks for your reply. I am to start shortly to build a design and I will look at the circuit as it sounds impressive. Before I build a circuit though there are basic engineering steps. These are:
1) What is the characteristic signal that I am to process?
2) What other signal/ noise is it embedded in and how do I extract it?
3) How may it be characterised so that I can build strategies and algorithms capture its salient features in hardware and then to accurately represent that digitally?
4) Model (your model is useful here but steps 1,2 & 3 are best completed first)
5) Design
6) Build and test.
7) Iterate 4-6 and revisit 1,2,3

So I am at stage 1 to 2. Present best understanding is that the signal is an impulse function embedded in the flyback signal seemingly at the end of flyback decay (if flyback was quick enough for the target). If it wasn't quick enough then its info was lost when the signal was clipping at kilovolts or if it was a slow target hopefully I can see it.

That is what I see is likely from Moodz' waveforms posted here which by reputation are pretty much state of the art and from my extensive reading of the forums.

So it appears its not like radar or sonar where we ping, measure delay and then look for the reflected signal using techniques to pull a small signal out of noise but this is basically how I see it being talked about in the forums. I am wondering if its just lore and everyone else can see the Emperor's clothes that I cannot see.

To my knowledge, while it may match the theory, no one has posted a scope trace of the discrete "eddy current collapse" signal that we seek and it does not seem to be leaping out even as flyback time is shortened. I have seen it in simulations but that is step 4. As such no disclosure of Lasseter's reef location yet . Lasseter himself was sure that it was there and lots of people went along with his thinking but its never been found because they all looked in the wrong place out in the desert. Its actually near my house .

To be devil's advocate, existing designs are detecting something and they are successful. Moodz will disclose his breakthrough in due course. It may well be the end of PI improvement as we know it or TINKERERS_SB_MO THE MOTION VERSION might be the last word.

Call me an "old fashioned engineer" but before I build a signal processing circuit I'd like to be sure of the signal I am looking for. Alternatively I will just need to build something and find out for myself (because I am speaking from practical ignorance) and clearly need to suffer multiple soldering burns like the gurus have to attain my enlightenment and right of passage from a junior. I can do that but was hoping to poll (and challenge) the gurus before that was done hence the posts.

Hope this is on topic but it is Moodz' work that has got me thinking.

Chudster

Hi Chudster,

sorry, but you are wrong. Please have a look at Ohms law and voltage dividers.

Aziz

...The Chudster is asking the right questions but not all the questions that need to be asked yet ...I cannot say if the answers he is getting are right or wrong at this point in time.

I have prepared a circuit that pretty much is the production version .... see below shots from the QED front end .... the coil is an 18 inch 0.4 ohm 300u Minelab type.

Below is the damped UN-AMPLIFIED coil signal ...( ie what the first amp sees ). The baseline is ground. The flyback is damped in around 4 us ... 6 us if you are a pessimist LOL. The target responses are excellent IMHO for a PI.

This is the simplest and lowest cost version of the circuit ... the DSP version is much better ..but not off the testbench yet.



Now we zoom up the CRO gain to 500mv / div so we can see a little more detail ....



Now we add a largish non ferrous target .... remember ... this not amplified yet
verrry niiice.



Now we superimpose the non target and target response ..... I was holding the target slightly closer to the coil so the response is a little larger ... LOL.




moodz

Aziz,

Don't be sorry. Every time I am wrong I learn something new.

But I expect that even though I am a Junior, both of us actually know ohm's law really well. If there is a difference then it is in topology or other assumptions .

To that end find an LTSpice model and two simulations. One with a 500 ohm damping resistor and one with none (1 megaohm).

While my target model is perhaps simplistic (a 1nA pulse) I think it demonstrates that not having a damping resistor results in a higher target response, not 2000 times due to the a more realistic coil model but a peak output of 27uV with no damping vs 450nV with a 500 ohm damper so thats about 60 times improvement.

I know its simple, but I have attached plots and the model.

I understand you are the king of target simulation so I would appreciate how we relate this and (a proper target and coil) model to Moodz' latest post and traces which I have just seen and am about to examine right now. Notwithstanding that his circuit is not available to simulate I would have hoped that we could sim a target signal from a coil into no load/ nodamping resistor and end up with something like Moodz has just posted.

Chudster

Thanks a heap for this Moodz. It starts to get to the questions I have been hoping to answer.

So my interpretation:

(1)The initial undershoot is not so much a target feature is a control artifact (no criticism, its a fast circuit and I am amazed it settles that quickly) to get the circuit to a "critical damping" point. I think you said before that you "release" near that point.

(2) In the trace with no target, there is still a tiny bit of current in the coil so from t= +2uS, we see a (small) exponential decay of the type we would expect from an undamped inductive decay. You can see its a little noisy.

OK so now I think I see and can explain the target response (maybe).

(3) With the Fe target in range. We pull out the electrical energy and the "eddy current" response now manifests as a higher and larger decay current starting at t=+2uS. If you could remove more undershoot I could imagine Carl's impulse blip.

What still doesn't jive is that this is a large Fe target. If the theory was right its time coinstant should be large and I would have expected its peak would have bee more to the right.

HOWEVER now we see some use in simulation as if you look at my simulation above you can see that the nice symmetrical current pulse gets skewed to a long trailing tail if there is no damping resistor.

BUT what still does not sit is that this target presumably (by the theory) would have a time constant more than shown or am I wrong?

OPEN is that if we could drop the flyback time more, would we see more of an impulse (t.e^)-t/tau) signal per Carl. It appears that t=0 is the FET turn off point/ start or coil current decay.

Moodz, thanks a heap for taking the time to put this together. Its getting closer to answers (well at least for me- maybe the gurus know this already).

How do others interpret Moodz waveforms vs the theory? Do I have it right?

Chudster

Chudster,

Call me an "old fashioned engineer" but before I build a signal processing circuit I'd like to be sure of the signal I am looking for.

attached is a simulation of the IB version of the signal that you are looking for.

The yellow trace is the TX wave form as seen by the RX coil. No target.

The blue trace is the signal response of a 1us size gold nugget.

The red trace is the target response of a 10us size FE target.

Note 1: the target responses have been scaled vertically to enhance their characteristic, but their horizontal scale is correct.

Note 2: the yellow no target wave form changes with the presence of the ground response as well as all other environmental influences, so we always look at the delta or difference.

These simulations are as close to the real thing as I have come so far. I can also show you the oscilloscope pictures of the same wave forms, but the real wave forms are filtered and changed somewhat by the processing.

Once you understand the simulations, you can easily recognize the target signal on the real wave form.

On the top of the picture, you see the mathematical formula of the processing of each trace.

I do the processing in analog but I would love to do it in digital if I knew how.

Tinkerer

Hi Chudster,

you are still wrong. Change your current source into a voltage source and look at it again. Why is the coil a voltage source and not a current source?

Aziz

Hmmmm what does a constant current source do if you remove the "load" suddenly.
PS ... I know someone who was nearly killed by a cable power system when this happened.