Consider a large, wide, dark, deep, fast flowing river. We wish to find the rock that is just bigger than the others and will snag the bottom of our boat.

We could take numerous measurements of the rivers current at points above and below and all across the stream and hope to find the infintesimal change in Kilo litres/per min caused by the obstruction of the rock.

Or... we could sprinkle lots of tiny leaves on the surface upstream and look for the one that stops or circles in the "eddy" caused by the Rock.


Dont let the big stuff cloud your view of the small stuff
Aurificus

STOP PRESS NEW NEWS



AURIFICUS

This is precisely the problem with the theory you presented. The big stuff is clouding the view of the small stuff that the detector is looking for.

In the analogy you presented, the large rock would represent the degree of variations in the thermal energy supplied by the sun (due to shadows and surface moisture). And what we are looking for is not a large rock, but a very small pebble which is buried amongst the large rocks. ie: The shadows and damp spots in the soil cause large deviations and gradients in the solar energy supplied. The buried metal object represents only a very small fraction of a percent of the thermal gradients seen at the surface above it. In fact, any thermal gradient derived from the presence of the buried metal receives it's energy from the same non-uniform larger gradients above at the surface, after it is conducted downwards as heat. So we are basically starting with a non-uniform energy input to energize the buried metal before trying to locate it.

Since we are looking to sense a very small thermal anomaly where the buried metal object is, the problem becomes one of signal to noise ratio. In other words, what is to stop the large energy anomalies caused from shadows cast on the surface from absorbing the pulsed IR LED energy instead of the faint anomaly from a metal coin buried 10 cm below the surface? After all, the variation of thermal energy caused by the surface shadows and moisture is at least several hundreds of times stronger than the variations in thermal energy caused by a buried metal object.

Then there is still the problem of the divergence of the beam of an IR LED. Esteban did not use a collimator to focus into a narrow beam. He used a plain IR LED with the attached factory lens, which typically has a 40 degree cone of illumination. This suggests that at 10 meters, the IR LED is illuminating a spot of 6 meters diameter. A deviation in the power pulsed to the LED could be caused by absorption anywhere within that 6 meter diameter circle. If the theory presented is correct (an anomaly of thermal gradient is causing the small variation in pulsed IR LED power), then the shaded side of stones, plants, or footprints within this 6-meter circle the ground would have an influence on the LED which is hundreds of times larger than a tiny gradient from a metal object buried below the surface.

Perhaps it is time to look for a different secondary effect of buried metal object phenomenon to explain why the IR LED power would change when pointed at the treasure location?

Best wishes,
J_P

25 meters. But is associated with a magnetic loop, seems the "phenomenon" "travel" into this light and secondary system is capable to detect. But was a wire, yes a quality galvanized special wire. A beam of light acts as an antenna.

Regards

Don't know if the power would change when the beam is pointed at the item location, but maybe change the voltage in the secondary detector (the receiver or monitor). But this system need the adjustment of receiver very sensitive.

Regards

Exactly as I described some years, but my example was a brick. Alonso tell me: "In the rain you see the water flow normally by the terrain, but when collide with a brick, the original flow changes, is similar to the detection with LRL pistols". So, is a distortion of natural flow. The natural flow is magnetic field of Earth, and here is produced a distortion in site of the target and around it.

Regards

Hi Esteban,
I have a few questions about the IR LED detectors you built:

1. Can you tell us if the IR LED detectors you built work with long-time buried coins, or do they work equally well with fresh buried coins?

2. What hours of the day or night did you find your best detection using the IR LED detectors you built?
Were there times of the day or night that the IR LED detector does not work adequately?

3. Do you think the IR LED detector is sensing the difference in temperature from a buried metal object, or do you think it is sensing something different, such as might be caused by an anomaly of the magnetic field, or electric field, or maybe disturbances in other energies?

Best wishes,
J_P

Well,Well .. A varying magnetic field interacting with a changing electromagnetic energy potential.....sounds like something???

SOMETHING... THAT MIGHT PRODUCE A DETECTABLE RESPONSE

1. Never I test with fresh items. I have a big patio in when supossed through the years things has been lost. The first time I found a 5.5 compressed air rifle bullet at 2 m. I'm with a friend. We walk and obtain another persistent signal. Was a bronze coin. And similar items. As I start investigating other type of pistols I abandon it. Later I rebuild other and found round copper object and small things, as a 1.5 mm copper wire. All these detection was very good, no random here. The IR and loop was another experiment.

2. I use only at day, never I test at night. But Alonso build with IR and lenses for to use at night, because some kind of pistols has poblem at night, so the problem was "solved" using IR.

3. I think is a mixing of various of all it. I think we can't separate. There are magnetic and electric fields and difference of temperature too.

Regards

Before start searching you adjust the pistol with all gradients of energy around, in the air, magnetic fields, etc. This gradient of energy is all the voltage, include the possible interferences (but no strong). So, pistol detects the difference, this is, the metal buried for long time, wich causes the distortion. But here pistol need to work in the limit of sensibility for to catch the difference. Is not important if this add of substract energy of the pistol. If energy ups in the system, OK, no problem. If energy down, when return at preadjusted point, this "nock" the system and beeps occurs.

Regards

Mr. Alonso is the inventor

Mr. Alonso is the inventor. To him my GREAT gratefulness and recognition.

See Seebeck effect

Google: Seebeck effect

Aurificus

Hi,
Congratulations! For the big pile of BS.

I think it doesn't work, and will never work in the real world, maybe yours is different.

Have any idea of what percentage of IR radiation arrives to a deep buried target ???

ZERO. The soil will dump anything your ridiculos 10mW from the led!

The LED you'll not read any measurable variation.

Follow this thought: suppose you have a 23mm diameter/4.15cm^2 area coin buried at half a meter underground... and you're 10meters far from target on the horizontal plane...

OK the half-meter means 50cm of soil above the coin...

The soil will swamp any reading... or you're talking here that a target like a coin cause if the thermal gradient is what you're looking for you must know that heath transfers are related to the MASS of objects ...so considering a deep buried small target (50cm and a coin) you're trying to let people here think that the coin retains or delivers heath to/from the soil in a way that's detectable by a simple IR LED + amplifier ! Isn't it ?

Now... the heath radiation happens from/to coin isotropically, so in all direction from/to coin vs soil , right ?

So... a coin placed at 50cm will radiate or receive heath equally from a volume of 1m^3 soil if we consider soil temperature about flat constant in the 1st meter (a good approximation in most cases during the day).

1m^3=10,000,000 cm^3

Now look at the coin that is e.g. a 23mm diameter one, 1mm thick: you'll get a volume of around 4.15 cm^3 means something 4*10^-7 order to be clear... so the coin's volume is about 4/10,000,000 the volume of soil we are talking about...

About mass... soil mass for 1m^3 vary due to soil composition/density but in organic soil (farm soil in most places) is about roughly 1200kg/m^3 so 1200Kg mass for 1m^3 and for coin, say it's silver... with density of 10490Kg/m^3 , so 10490*0.000000415= 0.00435Kg or 4.35grams

Now look at energy transfer (heath) in ideal conditions between these 2 mass... in the case the silver coin is hotter than soil around it... with a temperature difference of 20°C = 20°K....with wide approximations it's something like this:

The energy release from silver coin is due to Qc= volume_of_coin*volumetric_heat_capacity_for_silver *delta_T(°K)...

so Qc= 4.15*2.44*20= 202.52 joules

... then we suppose the soil that's 20°K lower in temperature will get that heath by conduction mostly (an approximation close to reality) and so the temperature in soil will increase , but what's that increase in °K considering all energy will be transferred with no losses and no dispersions ?

here the energy Qs=volume_of_soil*volumetric_heat_capacity_soil(si lica,water)*delta_T_soil(°K)

Qs=Qc (perfect transfer)

delta_T_soil(°K) = Qs/(volume_of_soil_volumetric_heat_capacity_soil(sili ca,water)) = 202.52/(10,000,000*2.9)= 6.98*10^-6 °K

In other words... if your soil is humid, organic and hi content silica... say it's at 30°C and the 23mm silver coin buried at 50cm reach 50°C, so with gradient of +20°C at coin, and we approximate full heat transfer between coin and soil, you'll get just about 7u°K or 7*10^6 °C variation in the considered 1m^3 soil.

GUYS !? We consider having 20°C gradient at coin soil interface and end up with 7 MICRO CELSIUS variation at soil volume... so at surface.

Can you detect 7*10^-6 °C variations with a LED diode ???

From 10meters away ???

Consider also S/N... 7uCelsius variations will be swamped out by any e.g. wind movement... that will cause the soil to cool down at really faster rate than 7uCelsius!

Consider the evaporation of trapped water in soil... will that cool the surface or not ???

It's a themodynamic-hell for you PYROMETER OR LED... OR WHATEVER!

Is that the new LRL-science-fiction!

I'm sure you didn't realize any of these fairy-tales devices... otherwise YOU MUST KNOW that's impossible detecting something this way.

On the air... of course, things are quite different... but soil it's a well known dumping filler... that's cause e.g. an atomic bomb shelter is usually underground... (not only... there are other reasons too ) the heath is dispersed by soil/water volume... will not work at ground zero just under the bomb maybe... but at few distance the soil will shield from excess heath... not like painting white your room and wear your preferite sunglasses!

Kind regards,
Max

This is not problem regarding the beam is a kind of antenna. If you can transmit voice, music, etc., through an IR beam, then, you can receive the "phenomenon" or halo or "field".

Regards

Aurificus and Esteban are putting forward two separate theories.

Aurificus' "hypothesis" (as he calls it) is unworkable in practice, and has already been detroyed by Max.

Esteban has a different idea whereby the beam acts as an antenna that transports the "phenomenon" to the detector

Neither of these theories is scientifically plausible, but Esteban insists that his method works. Perhaps this approach needs further investigation to prove/disprove the idea.