Interesting way of using a 555 timer...

As far as I can see, it appears to work like this ->
When the detector is turned on, pin2 (trigger) is below 1/3 of Vcc. This immediately causes the output at pin 3 to go high, which (in the Lobo circuit) drives a CD4024. With the output now high, the cap at pin 2 starts to charge up via the "14k7 res / 2k5 pot" combination until it reaches 2/3 Vcc, which resets the output (pin 3) low and triggers the discharge output (pin 7). Normally this output is used to discharge the capacitor, but in the Lobo circuit it switches on the TX transistor. With pin 3 low, the capacitor can now discharge until it reaches 1/3 Vcc, causing pin 3 to go high and pin 7 to go low (turning off the TX transistor) ... and the cycle repeats.

Ahhh I should mention... (of course everybody know this but I'll say it anyway) one very important requirement for a driven coil is that the driving waveform have very close to 50% duty cycle. The oscillator-divider arrangement scheme as found in the Czech Sabre is probably most notable for meeting that requirement.

Fortunately the 555 can also be made to give a very good symmetrical waveshape, and you eliminate the divider. Of course, quadrature divider outputs could come in very handy if you know what to do with them!

I have always been interested in relaxation or other oscillator as driver too. Of course idea of synchronous detector is that shifts in TX freq don't matter much if you use it for sync pulse, but I'm sure second, third order effects could come in.

With driven coil, if hi-Q circuit, then ground effect could "de-tune" it because change of inductance shifts resonant freq off the driver freq. But probably not practically significant. Maybe even in some cases stabilizes the amplitude.

-SB

Aren't there "pulse" driven designs that are very efficient, like class C amplifiers?

-SB

Limbo

Back to TGSL tuning and troubleshooting. Goal is to get my PCB working similar to dfbowers pcb, using his coil.

Experments go slow. Last test involved:

1. dfbowers mod to my PCB (increased sensitivity threshold range to compensate for out-of-spec parts).

2. Trimming capacitor for C6 (RX capacitor).

3. Box enclosure to protect PCB from light.

4. Direct jumper from speaker ground to battery ground to reduce pulse on buss rails.

5. GB pot adjustment.

Results
-------

Nothing conclusive yet! But my impression is my PCB does not work as well as dfbowers. Sometimes I can get a short beep at 30 cm, but it seems spotty. It seems somehow like it is being squelched too early. A good tone seems to happen in the 20 to 24 cm range.

To get near 30 cm, I have to really tweak the sensitivity pot just to the hairy edge -- doesn't seem like a stable configuration; something still not really right.

The jumper from audio ground to battery ground did not seem to work in the field the way it worked in my "lab". With the jumper, I still was able to get a range of "motorboating" in the field -- RX coil was active. So need to investigate that more.

Note: with my PCB, I'm able to turn sensitivity pot to get constant tone from speaker. With dfbowers, it barely goes chattery at max sens. I believe his PCB has the "dfbowers mod", but doesn't act like mine. I need to open the box and see what is different between our PCBs there.

I tried trimming capacitors for C6, because my C6 is around 13.4 nF. I have a small socket to plug in the trimming capacitor. I have not confirmed how well the socket works. But the trimming cap did not seem to make a world of difference. It actually seemed that a 1 nF trim made it worse, but a 2 nF trim made it a little better, but quite close to no trimmer.

I found that if I turn my GB pot up past mid point, it really hurts my air depth, maybe 5 cm. So for now I'm testing with GB pot at min.

I have a small piece of ferrite -- probably not a really good test slug. When waving it in front of dfbowers coil, it made a sound like crackling across the coil, like a pack of fire crackers. I have not adjusted dfbowers GB pot, but may play with that to see the effect on depth.

I think for next tests I will look more at the effect of audio circuit / speaker on the PCB. Maybe that big pulse cuts off the beep too soon. One thing to try is a resistor in series with the speaker/headphones, to reduce the current draw -- too loud anyway. Also more jumper-to-ground testing.

I know eventually I will make a proper PCB using etching, then will have better confidence in wiring.

If I could comfortably get scope into field would be easier, but can't for now.

I took some video, may post later.

More work to do.


-SB

I sort of meant that for lowest noise in a single frequency LOW POWER IB detector you would probably want the 50:50 drive.

If you don't care about accurate discrimination then use a rectangular drive signal and a car battery. It's done all the time.

Stuck my foot right in my mouth.

IMPROVEMENTS

Porkluvr, your TX circuit in posting #585 was improved (by White's:-)
The improvements shown below are:
1. Both supply voltages -6.5V and +8V are connected in series to obtain 14.5V. (White's obtains 13V because uses 5V instead 6.5V). . This increases the power (ampere-turns) of TX.
2. Tank capacitance C1 is increased 50 times. This also increases ampere-turns and decreases distortion.
3. Coil resistance is decreased 14 times. This also increases ampere-turns and decreases distortion.
Please use these improvements because are made by great designers.

Reason I'm interested is I'm imagining an analog to pushing a pendulum, where a small pulse applied to a high-q tank can build up a healthy mag field with low battery drain. The pulse causes some distortion in oscillation, but not really noise. In fact, the TGSL oscillator has bump because of similar effect I think.

Just interested in various designs.

Cheers,

-SB

Simon,

Despite the last few post about the drawbacks of a high Q Tx coil in the TGSL design, I went ahead with my last experiment anyway. I constructed a Tx coil using 26 gauge wire. It ohms out at just over 10 ohms so in theory it should more than double the Q factor of the coil. I wound it the same way as all my others using Spar Varnish on the same form as all the rest (no binding). It's big! Came out with a nice square cross section. Probably takes up 4x the volume and probably weighs 4 times as much. I did not shield it but should not matter just for a bench test. I did not use a USB cable either.. just 4 jumper wires to my PCB. Maybe had a negative impact.. not sure.

Results: I can't say that I gain any detection range at all. I can still detect a 1e and U.S quarter at 36cm but I have to push the sensitivity to the hairy edge to get a good indication. I have some sensitivity to spare (at 36cm) with my 30 gauge coils using the same test targets.

I did notice however that it seemed to be a little more tedious to null the big coil.. I'm not going to speculate why just because I have not taken any measurements on power.

Anyway, I would probably have to build 2 more 26 gauge coils and test them as well to come to a definite conclusion.. Anywho.. no earth shattering differences with this one. Just to drive this one home, I may shield the Tx coil anyway and use a USB cable and repeat the test.

Don

The circuit diagram below was designed by me and published in the forum.
http://www.geotech1.com/forums/showt...eferrerid=2910
Coil resistance is 1.2 ohm. Capacitance of C5 is formed by two capacitors type MKP connected in parallel. The center tap and diodes connected to C5 are used to supply a low noise preamp placed inside search head.
The controller allows to supply TX and RX preamp direct from battery without stabiliser.

Despite the P-I controller varyes duty cycle from 20% (when coil is high in air) to 45% (when search head is submerged in ocean water), the harmonics contain in radiated field is so small, that can not be noticed any effect on the receiver. The circuit operates also excellent with conventional coil of White's (1.5 ohm), however without center tap, the power (ampere-turns) is reduced.

Those boys sure do work fast because I only posted that circuit yesterday! My head spins.

Ummh, should I also use computer control on my 14.5 kHz Tesoro "clone" (very inaccurate word) so that I can match the fantastic performance of the 6.5kHz (multi frequency) computer controlled Eagle Spectrum? I'm cool with that and will get right on it.

You made a fantastic suggestion, that I should adopt the Whites Spectrum transmitter design. That's like saying that I should grab the motor out of a Mercedes SL450 and shove it into a Honda Civic.

I have to say, "Sure thing, just not right now".

I really want to thank you for informing me that I would get an increase in power if the power supply voltage was made higher because I never would have guessed that.

But it hurts my feelings that you would suggest that Whites' engineers are more competent than I am. Just because I don't have a college degree, you shouldn't rub it in. That's being cruel.

edit:

mikebg, I'm not intending to sound nasty, it's just that I gave up trying to make a rational comparison between the Whites and Tesoro machines. The more I thought about it the more it seemed utterly absurd.

After doing some experimentation I decided that the Tesoro circuit that I posted was vastly more appropriate to hobbyists' needs than what you showed.

If you leave out the drive and frequency controls from a driven tank circuit, you need to have better control over the coil building process than is available to the average hobbyist, otherwise how are you going to optimize the output?

I know that small changes in coil or tank capacitance can have a marked affect on the resonant frequency. That means that a variable control for the drive frequency needs to be available, or else you'll likely be out of tune.

Another thing is that unless you have absolute control over the coil building process so that you have a very consistent product, then you also need to have a drive level control. Without a drive level control you will probably either have low power output or else have high distortion.

This makes me think that for a drive circuit, an RC oscillator may be more adaptable to the hobbyist than a crystal oscillator.

If you do want crystal control, then you probably should have a good supply of different 'tweak' capacitors for the tank, or some other method to match the tank's resonant frequency to the crystal frequency.

I'm sorry if I've insulted anybody's intelligence.

Porkluvr, excuse me for joke, but the following is absolutelly serious.
Experiment showed, that TX circuit diagram of Eagle Spectrum has worst properties than all other circuits we have tested with salty water. When operates at low power mode as marked in posting #529, by lowering search head even to not enough conductive earth, the amplitude of oscillation so diminishes that change can be measured by a conventional AC voltmeter. This is because LC tank is pumped by constant current portions as in your circuit with 555 (posting #585). My circuit in posting #595 simply increases or decreases the current portion stabilysing amplitude across TX coil. That's why in January I proposed modification for TX circuit used in Coinmaster, TM808, Eagle:
http://www.geotech1.com/forums/showt...eferrerid=2910

Very useful test, it's something I've wanted to know about.

Perhaps the law of diminishing returns kicks in. However I still wonder if maybe there is some other adjustment necessary to take advantage of such a coil because of some negative factors that come in.

There are a few things to speculate about. One is the "sixth power" law that someone claims -- I think it states that the received signal strength drops off as the sixth power of the distance beyond a certain point, so that it takes enormous additional power to get meager improvement.

Intuitively, it seems to me that the S/N should improve, if the main noise is EMI. One way to test that would be to measure the noise power at the output of the LM308 chips. It should be the same for both TX coils. If the hi-Q coil has higher noise, then we can suspect some kind of jitter or oscillator noise.

It would be interesting to compare the magnetic field strength of the two coils also. I would make a small "sniffer" loop, maybe a centimeter or two in diameter with twisted pair leads, mounted on a stick. Then sample the magnetic field by putting the loop in the field and observing the signal on an o-scope.

In some ways, if the thinner wire works just as well as thicker, we're happy coil builders. But it is one of those puzzles I don't understand.

I encourage you to make the finished coil and see if you can explore why it does or does not work better.

-SB

Definitely not done with the test yet. .I went too far (AND not far enough) to not come to a conclusion. I have a field strength meter somewhere at work that I will see if I can get my hands on. If just looking for a field strength comparison then the idea of a sniffer loop might fit the bill.. If we don't need to apply an actual number to it.

Over the next few days I will add a shield and USB just so I can say that I compared oranges to oranges.

field test video

This is video from last field test where I tested my pcb with dfbowers coil. My mods include "dfbowers mod" for increased sensitivity range, box enclosure to keep light out, trimming capacitor for RX coil tuning, jumper from audio ground to battery ground to help reduce supply rail pulses.

http://www.youtube.com/watch?v=Z8mVtXH4lKY

Sorry, the video is annoying and not good. I'm just showing it for the record. Traffic and wind noise bad. It's difficult to see where I'm waving the target -- I need a good target holder like dfbowers "merry-go-round" in his basement. The field test is proving difficult to do well. Need better location.

My conclusion is: well, my pcb occasionally can get detection around 30 cm I suppose you can say -- but quite delicate setting of pots. I feel dfbowers gets more consistent, fatter tone in range from 24 to 30 cm. Also, dfbowers has some GB pot setting, my GB pot is at minimum.

It is worth pointing out some differences in my PCB compared to dfbowers PCB, and then pondering which, if any, of these differences matter.

1. dfbowers uses etched PCB as per Ivconic layout. My pcb is hand-wired with 26 gauge buss wire and laid out on a 4.5 by 5.5 board. Possible disadvantages of my board -- higher noise due to spread out; higher buss resistance and coupling of signals such as large audio pulse; more chance of bad solder joints.

Future experiments -- thicker buss wire; change layout to make audio ground next to battery ground; etched board.

2. pot wires - dfbowers has shorter pot/switch wires, particularly disc pot. Possible advantage -- less noise pickup.

3. My pcb has test loops sticking up for probes -- possible disadvantage -- pickup noise.

4. dfbowers has the .1uF bypass capacitors that Ivconic added. I left those off my pcb for simplicity and spacing. Possible disadvantage of my PCB - signal coupling from buss rails to ICs. My feeling is that for the big audio pulse, the small bypass capacitors don't make much difference, but maybe important and maybe reduce motorboating effect.

Future experiments -- add bypass capacitors and assess the difference.

5. dfbowers uses 4.7k resistors, I use 5.1k resistors at front end of LF353. dfbowers may have about 8% higher gain at LF353. Significant? Don't know.

6. dfbowers uses back to back 10uf capacitors for the LM358 filter stage -- I use single non-polar 4.7uF cap. dfbowers has perhaps slightly slower response because of it -- signicant? Hardly seems possible, but...

7. dfbowers uses two transistors for darlington stage of audio amplifier -- I use a single darlington transistor. I don't see a significant difference there, but Ivconic has found the audio stage is very critical to the performance.

8. dfbowers uses two 9 volt batteries in series (18 volts), inside enclosure, for power supply. I use 12 volt AA battery pack external to enclosure, attached by about 9 inch cord. Perhaps my power cord picks up noise? Perhaps resistance of longer cord causes buss coupling? I would think not significant.

9. I have a 22k resistor in the oscillator where dfbowers has a 24k resistor. I could try changing that, but don't expect significant effect.

10. dfbowers I think has resistors to stabilize the unused LM358 op amp as per Ivconic's layout. I chose to stabilize it with a simple wire from the output to inverting input and grounding the non-inverting input, as per some examples I found in a reference. I hope that difference is not significant.

11. I have the "sb mod" (might as well call it that since I'm the only fool who uses it), which is a voltage divider from the oscillator output that feeds a reduced voltage to the discrimination and GB phase shift circuits. The purpose is to get rid of the "jaggie oscillations" in the DISC phase shifter. However, it is possible it introduces a small phase shift of its own (less than 5% probably), and also may reduce the GB phase shift range a little. It also slightly may couple the GB and phase shift pots a little due to the loading effect.

Future experiments -- I can jumper over this voltage divider to assess it's effect.

So some more fool for thought -- I mean food for thought -- to try to find those small critical things that make the TGSL circuit work as well as possible.

Again, as Qiaozhi says, the extra air depth may be of no value. I still want to use it as a basis of comparing PCB construction. Also, it may indicate higher quality of signal at the lower depths also.

-SB