Do we have test results?

The detection distance is now about 33cm, but the tone is still faint and short.

I disconnected the emitter of TR7 from the + rail. Then I soldered 6V battery pack between anode of D6 and ground (battery minus on anode).

The detection distance is now about 33cm, but the tone is still faint and short.

All voltage rails are now quite clean: the 14.5 kHz ripple is below 2mVpp while it was 40mV before modifications.

When you talk about the tone being faint and short, do you mean that it is that way at all depths or it gets fainter and shorter as the depth increases?

It's long and loud up to 15cm, after that it gets gradually shorter and weaker. It is normal, right? I need to check some videos in the Youtube to compare.

It might be good idea to change all bypass electrolytic capacitors to low ESR ones to lower the ripple.

The rescue blanket I got has plastic on both sidesso I can't make a connection to the aluminium inside.

hello 2 any 1
I want to understand the meaning of this shortcut ( V.C.O )
I found V.C.O in another metal detector
Greetings

I think a little different. I try give you an example and explain how i imagine this when no target applied.

On Tr gates comes signal 14.5khz from Tx coil.
On Tr drain comes signal 14.5khz received by Rx coil, shifted and modulated by Tx signal from Tr gate. Because of it we don't see nice sinus on Tr drains as wee see on LF353 pin 7 - it is modulated here. Depending on phase shift between Rx/Tx on Tr drain signal will be positive or negative, also it influence Tr source voltages.

When disc pot are turned, shift also changes, this changes voltage on Tr 4 source.
If we have wrong phase shift at min disc pot position, then we will no be able achieve correct disc at all pot positions.
As you know disc pot changes cut off point for target metal.

Example again (if we have wrong phase shift tx/rx) then imagine:

disc pot min (phase shift between Rx/Tx disc sampling pulse -40) then voltage on Tr s = -V.
disc pot middle (phase shift between Rx/tx disc sampling pulse 0) then voltage on Tr s = --V (more negative).
disc pot middle (phase shift between Rx/tx disc sampling pulse 40) then voltage on Tr s = -V.

Tr s voltage when disc pot min and max will be equall so disc at min and max will act the same. Only from Min to middle and from middle to max different.
Disc can't act the same on min and max. Also this applies to geb.

There is how i think

Also depending on this, some TGSL made projects has iron rejection at min pot, some not.
Mine has iron rejection when disc pot turned at 1.
Depending on phase shift i can make that iron will be rejected when disc pot turned at 0 or at 3.

That is a good test and it showed some very promising results!

When you talk about the tone being faint and short, do you mean that it is that way at all depths or it gets fainter and shorter as the depth increases?

Ivconic did experiment with a threshold control on U107 and he adopted that in the IGSL for U8a & b. I have not done this one yet but I think it could help the short tones in particular. Right now it may be just the peaks getting above the threshold and so they are shorter.

My ideal is to have the get fainter as it goes deeper but not shorter, so you can get a sense for the depth by listening to the target.

Thanks for posting your test results.

Jerry

I am interested in seeing what it will do for a TGSL that is already getting good depth.

Winter weather is about here so I hope to be back to experimenting with this soon.

Jerry

The important point is that the target phase is not affected by your null signal phase -- the two can be considered separately.


Regards,

-SB

That is an interesting point, depending on how much high-ferrite ground could affect the TX frequency. However, I assume ferrite will always reduce the TX frequency, which might reduce the gain/sensitivity of the TGSL by moving away from the RX resonant freq, but wouldn't cause a problem with phase shifts.



That may be desired for certain TGSL constructed a particular way. I personally suspect however it is not necessary in general, and some MDs will naturally need a different phase shift. I'm working on finding a way to explain why and how to predict the correct phase shift for each TGLS.



I would be interested in seeing an actual comparison test with real chips and oscilloscope pics.



Don't forget -- the null signal phase (20 deg or whatever) has nothing to do with the target signal phase. The phase between the drain and gate of TR4, TR5 that you observe is only for the null signal, not the target signal. The null signal only makes a DC voltage at the source of TR4, TR5 -- which is ignored by the next op amp filter!

So the null signal phase is not really important in the way you think (I think).

What matters is the relationship between the sync pulse phase (gate of TR4, TR5) and the target signal, which you cannot see normally, it is so small. You can change the null signal phase all you want and it does not change the phase of target signals. So don't worry too much about the null signal phase as a way to null your coils -- use other criteria. Except this warning -- make sure the DC voltage on the source of TR4, TR5 does not go too far less than ground, or you will forward bias the JFET and make a mess. In other words, shift your coils to pick a different null signal phase.

I have not completely made my mind up on the effect of the null signal phase on ground balancing. Qiaozhi and I had a long confused discussion on this and I accepted the idea that ground/ferrite would amplitude-modulate the null signal without changing its phase. Since then I have been considering that this is only partially true -- that the null signal may be composed of a "magnetic" component and also a "non-magnetic" component, in which case ground/ferrite would only modulate the "magnetic" component. I also have been thinking that ferrite truly may be a "zero phase" target, which really is different from simply modulating any null phase.

Sorry, getting too complicated. I need to do much more thinking about it. But my final advice is don't get too concerned about your null signal phase for the purpose of nulling your coils. And don't worry that the wrong null signal phase will hurt your DISC control -- it should not. Do make sure your JFet gate-source voltage is not forward biasing the JFet junction.

-SB

This message is for me?
Tgsl works good with separate power supply and not so good when only some capacitors are connected. I wonder if 7660 could work with less spikes and rails than chopper stage power supply.

How about capacitor selection in you project. Since it works better on a separate P.S. maybe look at what you are using for polarized caps?? Can you post what you are using and maybe we can compare the ripple specs?