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**Aziz** · 03-20-2025, 10:55 AM

Originally posted by pito View Post

The ADS1220 is useless for direct sampling. 2 k-SPS vs 192 k-SPS (my sound card) = ADS127L11 400-kSPS, Wide-Bandwidth, 24-Bit, Delta-Sigma ADC datasheet (Rev. C)

My sound card is still better regarding snr, enob and noise specs at 192 kHz SR.

And I don't need any soldering iron and micro controller to operate the chip.

**ArchibaldSTM** · 03-20-2025, 10:59 AM

37 pages of empty words, but no result))))

**Aziz** · 03-20-2025, 11:03 AM

Hey guys,

I also want to measure the EMI noise in the field. Lets look at the EMI signal level there. I'm sure there is much less noise compared to at home.
I hope the preamp gain of 100 is enough to see the difference.

Aziz

**moodz** · 03-20-2025, 05:50 PM

Originally posted by Aziz View Post

Hi all,

I have done some real measurements with an RX coil. With preamp (gain 100 or +40 dB) and without pre-amp.
So the EMI noise level is approx. -20 dB below the noise floor level (-120 dB) on quiet regions without the pre-amp.
A gain of +20 dB (x10) is minimum required to rise the residual signals above the noise floor level.

You see, I need this fkn pre-amp.

Aziz

LOL ....must be a real special amp that lifts the signal without lifting the noise.

**moodz** · 03-21-2025, 05:47 AM

Any cancelling scheme would also cancel the target because the interferance you need to worry about is inband of your desired signal ..
Amplification only amplifies the wideband noise and the inband signal for no benefit unless you call making the noise bigger a benefit.
When the signal is under the noise then a preamp is more than useless.

So on my WORKING detector that does use a lockin amplifier ( read up on lockin amplifier reserve ) I have a real reserve of 112 dB ... which means it can pull a signal from 112 dB from below the noise level. Commercial lockin amps can pull a signal from 120 dB below the noise level so I am almost on par.
In the picture below I turn on the LED lighting in the lab for about 10 seconds then off again .... you can see the inband interferance coming from the lighting ... dont need a preamp on the ADC. The target signal ( 10 decimal digits in the upper left corner VA corresponds to 180 db of signal range but only the last digit is changing with low noise )

**Riss** · 03-21-2025, 06:03 AM

Originally posted by moodz View Post

LOL ....must be a real special amp that lifts the signal without lifting the noise.

,,The best amplifier is the antenna!" (I heard this wisdom when I was in kindergarten...

) - it raises the signal level without introducing noise, respectively, it increases the signal/noise ratio. Last year I made and tested a prototype of a directional antenna system for metal detectors. To my surprise, it worked immediately! And in the way it was designed. However, I am like a Woody woodpecker - I experienced countless crashes with my experimental planes

. I will be satisfied with this only if the directional antenna system shows advantages in real field tests. If not - I will laugh at myself like this – https://www.youtube.com/watch?v=iNxujJGnbB4

**Aziz** · 03-21-2025, 10:36 AM

Originally posted by moodz View Post

LOL ....must be a real special amp that lifts the signal without lifting the noise.

Indeed, my old pre-amp seems to produce more (thermal) noise than expected.
I have taken very old tantal caps in my prototype. Guess what? ESR > 1 Ohm.

All measurements are obsolete. I'm preparing a better pre-amp with measured low ESR caps now. No more tantal caps!

Before making real coil measurements, I will measure first resistor noises: for RS = 0 (short input), 1 Ohm, 4.7 Ohm, 10 Ohm and open input (RS=input impedance).
I can then say, what is EMI noise and what is thermal noise.

**Aziz** · 03-21-2025, 11:16 AM

Originally posted by moodz View Post

Any cancelling scheme would also cancel the target because the interferance you need to worry about is inband of your desired signal ..
Amplification only amplifies the wideband noise and the inband signal for no benefit unless you call making the noise bigger a benefit.
When the signal is under the noise then a preamp is more than useless.

So on my WORKING detector that does use a lockin amplifier ( read up on lockin amplifier reserve ) I have a real reserve of 112 dB ... which means it can pull a signal from 112 dB from below the noise level. Commercial lockin amps can pull a signal from 120 dB below the noise level so I am almost on par.
In the picture below I turn on the LED lighting in the lab for about 10 seconds then off again .... you can see the inband interferance coming from the lighting ... dont need a preamp on the ADC. The target signal ( 10 decimal digits in the upper left corner VA corresponds to 180 db of signal range but only the last digit is changing with low noise )

Hi Paul,

well ok, you are obviously using hw demods (hardware implemented lock-in amp).

But this is not the case for me. To make things simple, I use the real digital direct sampling (software) demod. I have no other way as to amplify the signal and noise. That's the reason, why I need the pre-amp to go down the noise floor level of the adc system. It is surely not perfect if I compare it to the hw demod.

I could get similar results with hw demods too. But this would make the detector controller much more complex:
RX demod -> x-ch, y-ch (complex) -> AC modulator -> adc (sound card) -> decode mag and phase.
What about more channels for more frequency demods? Well I'm limitted here or it would make the AC modulator more complex.
But this project wouldn't be a KISS project anymore.

You guys take the hw demods and I take the pre-amp and doing the sw-demods.

Cheers
Aziz

**Aziz** · 03-21-2025, 11:36 AM

Hi all,

I will prepare two pre-amps with gain of 100 for the next measurements:
- simple NE5534 AC pre-amp (producing much more thermal noise)
- discrete ultra low noise AC pre-amp (en approx. 0.25 nV/rtHz)

This should definitely answer the question, whether we need a very low noise pre-amp.
At the same time to see, when the EMI noise is visible on quiet regions to define the gain of the pre-amp.

Back to the black board.

Aziz

**Aziz** · 03-21-2025, 03:51 PM

Hi all,

I will leave the simple NE5534 pre-amp. Too much thermal noise expected due to circuit simulations. I should not try it.

I will leave the discrete solution too. Not versatile use possible.

But 1x ZTX851, NE5534 as control loop and a transistor as driver to get RG1 down to 1 Ohm, it is possible to get 0.25 nV/rtHz at gain 100.
At the expense of high power consumption however (approx. 30 mA at 9V

). But with a stable gain and frequency compensation loop.

Anyway. This is just for clarification.
Cheers

**moodz** · 03-21-2025, 07:12 PM

Originally posted by Aziz View Post

Hi Paul,

well ok, you are obviously using hw demods (hardware implemented lock-in amp).

But this is not the case for me. To make things simple, I use the real digital direct sampling (software) demod. I have no other way as to amplify the signal and noise. That's the reason, why I need the pre-amp to go down the noise floor level of the adc system. It is surely not perfect if I compare it to the hw demod.

I could get similar results with hw demods too. But this would make the detector controller much more complex:
RX demod -> x-ch, y-ch (complex) -> AC modulator -> adc (sound card) -> decode mag and phase.
What about more channels for more frequency demods? Well I'm limitted here or it would make the AC modulator more complex.
But this project wouldn't be a KISS project anymore.

You guys take the hw demods and I take the pre-amp and doing the sw-demods.

Cheers
Aziz

Aziz ... for a smart guy you sure are getting sucked in by fake news ( audophile amplifier schemes )

The RX coil connects directly to the ADC in my scheme except for some passive protection and impedance protections to stop the front end of the ADC being destroyed by EMI spikes.
So I dont use HW demods.

By adding amplification to a high resolution ADC ... its the output noise of the amplifier ... not the input noise that matters more.

1. You increase noise at the input to the ADC.
2. You reduce dynamic range.
3. You lose bit resolution .... reduction in effective number of bits.
4. Have to use differential amps ... single ended amps wont cut the mustard.

For 16 bits you may be able to maintain sensitivity ( ie effective bits ) but your dynamic range will be very small.

PS : you can bet the common mode rejection on your fancy amp will be crap ... so helllo wideband noise.

The main points below ( this assumes an ideal amplifier -- if you amp has any noise the figures will be worse )

**Riss** · 03-22-2025, 04:57 AM

The electromagnetic "smog" is getting thicker - from year to year. The need for super-low noise systems would make sense on the planet Mars, to search for artifacts from the Martians who self-destructed millions of years ago (we will soon turn the earth into a lifeless desert). However, let's see how you will deal with the Telluric currents, which unfortunately are below 2 hertz and are strongest in July-August north of the equator ... gain 120 dB ...

**moodz** · 03-22-2025, 05:37 AM

These are VLF detectors .... Bandwidth is less than 20 hertz at each frequency of interest. The amps Aziz are talking about might work on a PI preamp ...but async noise is almost meaningless in synchronous detection and processing ...this is not PI land.

Interference has to be synchronous, be phase modulated and the phase modulation has to be within the 20 hertz bandwidth at the transmit frequency eg 19.17456 khz.
Security through obscurity ... Not much noise there or on Mars LOL.

**pito** · 03-22-2025, 05:57 AM

https://www.experimentalistsanonymou...eets/NE567.pdf

**Aziz** · 03-25-2025, 09:53 AM

Originally posted by moodz View Post

These are VLF detectors .... Bandwidth is less than 20 hertz at each frequency of interest. The amps Aziz are talking about might work on a PI preamp ...but async noise is almost meaningless in synchronous detection and processing ...this is not PI land.

Interference has to be synchronous, be phase modulated and the phase modulation has to be within the 20 hertz bandwidth at the transmit frequency eg 19.17456 khz.
Security through obscurity ... Not much noise there or on Mars LOL.

Hi Paul,

if you are setting your detection bandwidth < 20 Hz, sure you will get low demodulation noise. I will get it at any case too. As I said, it is only a matter of demod bandwidth. Regardless of using Goertzel, Lock-in or FFT. There is absolutely no difference. Goertzel may produce more numerical errors, if the block size gets (very) large. Whereas the Lock-in amp and FFT are using precalculated internal sin/cos reference in digital demodulations.

I think I won' get much EMI noise. The most dominating noise will be white noise (thermal noise). At least on my sound card rather than on the pre-amp.

Aziz

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