No, the comparison is fair regards to SNR. All coils rival the good old mono coil with 10 inch diameter.
I haven't taken the near "pin-point" response of the mono coil into account yet as the software didn't search for the maximum response in the former version. This is the edge of the coil but the mono coil response has been taken at the center axis of the coil. Only 1 - 2 inch detection depth is affected.
The mono coil is giving at its edge region at:
@1 inch: 1.83 times more response compared to the center axis
@2 inch: 1.05 times more response compared to the center axis

Divide the calculated ratios by 1.83 for 1" detection depth and by 1.05 for 2" detection depth and you have a comparable result with all coil types regards to pin-pointing performance.

I'll provide the corrected responses later in a very very large excel table (zipped file).

Cheers,
Aziz

Hi Aziz,

The coil I measured from is an old 11"DD before the cancel feature was implemented. Though in saying that, this coil does work well in cancel mode. I do have a later DD coil, though it is not with me at the moment, but from memory the inductance was similar to the old coil. I think the tx coil was closer to 300uh and the rx side measured higher than the tx coil as with the old coil I measured from. Perhaps the rx coil has the same turn count as the tx coil and the inductance is higher due to the higher rx winding resistance.
Yes 300uH~310uH seems to be the standard range for the ML coils. Just measured some mono coils I have with me and they were all 303uH.

Cheers Mick

Thanks Mick

It wouldn't make very much sense regards to EMI noise cancel, if the RX coil would have more loop turns of course. The RX coil bundle is probably more compact (thin wire), which could explain, why it has more inductance value.

I'll take TX=RX=300 µH (same loop turns).
Ok, I've made all three coil models in the right way and have to run the simulation yet.
Expected publishing date: tomorrow (it's late here).

Thanks & cheers,
Aziz

Hi Aziz,

Well while you were sleeping I've been busy(in between eating Christmas dinner leftovers!) Went and got myself a couple of rolls of .25mm enameled copper wire and made myself a form to wind a 14cm dia coil for an 18"tx. Calculated that I would need 144 turns, the tx is 16 turns. Unfortunately only the rolls of copper I could get were enough to do 105 turns. The self resonance of one of my commercial coils is 500kHz fully assembled with shield and coax, but the one I wound up only has a self resonance of 200kHz without shielding or coax. Upon closer inspection the inductance is just a tad high, 3.26mH!!!!! So I would need to run a lot more strands in parallel to lower the inductance, however the .25mm thickness is not ideal either as it should be .2mm or less. Ho hum! Back to the drawing board!

So just to prove that it can be done, I took 2 of my commercial coils, connected one to my detector and the other I put a 680r damping resistor across it. To my delight, the other coil cannot be seen by my detector So there is hope yet I have some litz here harvested from 2 old coils, however I don't think it will be long enough to get the required turns, but I think I will try winding 2 identical coils with it just to see what happens.....

Cheers Mick

ML DD PI Coil vs. Mono Loop PI Coil

Hi all,

this is the long awaited performance comparision between the 10 inch ML DD PI Coil vs. mono loop PI coil, showing each Rx mode (Double D, Monoloop, Cancel). Notice, the comparison (of Double D, Monoloop and Cancel mode) isn't compensated regards to SNR. It is a direct comparison to 300 µH TX, 300 µH RX coil (mono loop 300 µH either). The not compensated DD coil in Double D mode is picking up 1.6 times less EMI noise and therefore 1.6 times less response signal compared to the compensated DD IB coil (I'll show this once more here). The max. response at 1" and 2" for the mono loop coil is corrected now (high sensitivity on its edge).

Notice, that the Cancel mode isn't going deep. Crank up your gain in your detector to compensate for the depth loss.


Cheers,
Aziz

HI Aziz,

Well I had a little bit of a win! Wound up the coils and the resonant frequency was a bit faster than 500khz, and with a damping resistor installed the coils are not seen by the tx coil. However, I am about 100 turns short I was only able to get 40 turns. The inductance was about 360uh. Now if I were to have enough wire to do the 144 turns, the inductance will be too high and the capacitance too high and the resonant frequency too low..... Hmmmm! Damn it, I want this coil to work! I must be missing something, right?

Cheers Mick

Mick,

use thicker insulation wire (teflon if required, but not magnet wire), use more space in the coil bundle, use less loop turns and increase the gain instead, use 0.5 diameter factors (or slightly bigger), use special weave techniqes, ...

I don't have much problems with my low bandwidth detectors (< 50 kHz).
Aziz

New Life for Old Monos

I was idlely thumbing through a 1944 volume of Wireless World when I saw something that looked a bit familiar. It was a schematic for a frame aerial that was balanced, i.e. it had a centre tap and could be connected differentially. One benefit, according to the article was that it did not need to be shielded, unlike a single ended winding. The article pointed out the benefits of a frame aerial, either shielded or balanced, as reducing capacitive noise, or the electric field component. Having a restored and working 1941 RAF Bomber Command radio, I thought I would give a wrap around lead tape shielded single ended 300uH mono a try as a radio aerial. Wow, it works much better than the internal 20ft wire aerial I have in my workshop. It is easily turned for optimum alignment to the transmitting station too. The electric noise, which seems to come from wall plug switched mode power supplies, solder station, fluorescent lighting, central heating controller etc is way down. Clear signals are heard right up to 18MHz, which is surprising. When I get a bifilar wound differential coil of similar diameter it will be interesting to compare - with and without shielding.

Eric.

I add a 470K resistor from either pin 2 or pin 3 of the first amp., depending which one is active, to a test pin on the board. Inject 5Hz sine wave to give 1V pk - pk on preamp output and observe integrator o/p. If properly balanced the differential integrator should show little or no movement even when scope sensitivity set to 5mV. Then put up the frequency to between 10 - 100kHz to check that the gain recovers at preamp output to full closed loop value before the start of sampling. Dual amplifier arrangements should be fine.

Eric.

Not exactly. The tandem or top hat configurations use doubled the area with the same radius, but doubled nevertheless. IMHO all the AI coils should be given the same treatment as they all are using double the geometry this way or another.

Hi Eric, just before a few days I was trying a 11" minelab DD (TX winding), as receiver antenna on the lower part of LW band. Amazing and clear reception.

maybe is trivial to mention it, but using an op-amp for the first stage,actually it's not a "ultra low noise amplifier".
For example, using an opamp with a noise spectral density of 1nV/sqrt(Hz) ,gain 100 and for 100kHz bandwidth, the total "internal" noise (only from the opamp) will be around 32uV.
Not to mention the noise contribution from the resistors on the opamp configuration.
For a quick comparison ,the 1k resistor on the same bandwidth it will give a noise about 1.3uV.

No the comparison is fair as the RX- coil becames a reference EMI pickup coil.
In regards to EMI noise induction:
N(RX)*A(RX) = N(10" TX)*A(10" TX) for normal configurations (not AI),
N(RX-)*A(RX-) = N(RX+)*A(RX+) = N(10" TX)*A(10"TX) for AI configurations.

It is important to show the target response loss in the AI configurations to see the additional gain you would require to compensate for it. There won't be an ideal (full) EMI noise rejection either.

Aziz

You're a bit confused, don't you?
Aziz

That's a good EMI noise pickup configuration Eric. I love it.
Aziz