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#26
05-10-2007, 08:53 PM
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what frequebxy and power
Ok what frequency and output power for the signal lines sand how do we detct it.
If we inject a signal into the ground how do the L rods pick them up and how do we know it is picking them up.???????????????????? At this time I can't get any LRL to work or picl up any signal. If we can generte a signal we can detector it. but what signal????????? 
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#27
05-10-2007, 11:34 PM
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 And yes - I would do an air test before testing outside.Quote:
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#28
05-11-2007, 12:15 AM
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NMR, RF Frequency of gold+Gamma Ray
Klondike,
Esteban I feel has it right in detecting a harmonic of the frequency of gold. German Physicist Dr. Paul E. Dobler's test showed to be 1.2mm or around 240GHZ. The NMR frequency of gold is given as 1.729MHZ for the particular strength of the earths magnetic field,but as pointed out with the present state of the art is undetectable. And then there's the gamma signature that Bickel used successfully which after doing a little Google searching found out last night I've got to spend several tens of thousands of dollars to acquire a gamma spectrometer. When I get my Uranium, I will still use it to highlight the gold and see if I can see any differance on an oscilloscope connected to the audio output on my cheap gamma detector (pulse width). So there you have it,take your pick. Randy
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#29
05-11-2007, 02:27 AM
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240ghz
harmonic of the frequency of gold. German Physicist Dr. Paul E. Dobler's test showed to be 1.2mm or around 240GHZ.
---------------------------------------------------------------- AT THAT FREQUENCY LRL ANTENNA would be a very hi Z How would a radio antenna pick up a 240 ghz signal????? also the circuit for that signal. I look at some LRL circuits and well you get the point. I'm lost on the 240 ghz with the LRL circuits i have seen. It must be something else going on.
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#30
05-11-2007, 03:56 AM
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 I've found that if you don't turn the metal detector on, rather amazingly it won't respond to targets. I was out hunting with a Tesoro one time... it runs in a "silent search" mode... at some point in digging a difficult target I turned it off... when I resumed detecting I forgot to turn it back on. It was when I went over a visible target that I realized... errr... duh. OK, now back to the MFD. Do MFDs behave the same way? That is, if I fail to turn it on, will it fail to respond? Once upon a time, I was with some LRLers who were doing some testing with an MFD. At one point, as one person went out to look for the hidden target, I flipped the transmitter off. Still, he got his "hits" and tracked his "signal line" and never once suspected the transmitter was off. Everything was working as he expected. Before he returned, I flipped the transmitter back on. Then a second person went out to look for the hidden target, and I left the transmitter on. He wandered around a while, and finally looked over and asked me if the transmitter was still turned on. Why, yes, it was. Once upon another time, I was with an E-scope user who was "scoping" an area for a suspected cache. He was getting a hit over here, and another hit over there, and was triangulating and whatever else... after 10 or 15 minutes of all this, he looked at his E-scope and realized he forgot to turn the durned thing on. All the while it was operating as he expected it to. So does an MFD really behave differently when it is turned off? Perhaps only if the user is aware of it. If the MFD user knows the device is turned on, he will get the response he expects. If he knows it is turned off (or, perhaps suspects it has been turned off!), he will not get the response he expects. We could do an experiment where the MFD user attempts to locate a signal line while knowing the state of the transmitter. This is a subjective test. MFD users have told me that they can definitely tell whether the transmitter is turned on or off, but my experiences tell me they cannot, unless they already know. If this is the case, then either the so-called signal line does not really exist, or L-rods are an ineffective means of detecting it. Next question... What sort of experiment could we perfom that objectively tests the MFD user's ability to tell whether the transmitter is turned on or off? - Carl
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#31
05-11-2007, 05:37 AM
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Klondike
There are companies that do sell off the shelf detectors,but looking at the picture of their ad in "Microwaves and RF" magazine it looks expensive!
So where does that leave us? For the moment, out of luck I'm afraid. Also the antennas are made from a lithographed PCB for extremely small dipoles. Too bad neon bulb detectors are only good up to 100GHZ,that would of made it easy. Makes me wonder if there is a gas out there that would ionize at that frequency or a way to get the neon bulb to detect higher up. Sure wish I knew a Microwave PHD. There are some books at Amazon on Terahertz systems and the best one is around $90 or so darn it. Randy
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#32
05-11-2007, 09:51 PM
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 I can think of a nasty experiment which might do the trick. Is this what you're looking for? Let's say you have a selection of MFDs, and (to remove any bias) let's say they're all the same make and model. Now, some of these MFDs are working and some are not. One way of achieving this would be to fit a selection with good batteries, and the rest with depleted batteries. These batteries should be fitted by a third party who is not present at the testing. In this way the test organiser cannot unconsciously inform the MFD user which ones are which. The gold can be placed in full view. The purpose of this test then becomes whether an MFD user can say which detector (or detectors) are working, and which ones are not, rather than an objective test related to detecting a gold target. If the detectors are numbered, the results can be recorded and later decoded by the third-party who originally fitted the batteries. In fact, I've just thought of a slight variation. There should be two third-parties (if that makes sense). The first one numbers the batteries and records which ones are dud. The second one takes the numbered batteries and randomly puts these into the MFDs. Neither of these two people are present when the other performs their task, and neither are present at the testing. I suspect the ratio of good to bad batteries should be 50%.
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#33
05-12-2007, 01:56 AM
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The exact method you described has 2 drawbacks. One, it requires more than one person to do the experiment. Two, many MFDs have LEDs and meters that will give away a dead battery. So, what we need is a way to set up an MFD transmitter so that it either outputs a signal, or does not output a signal, in a way that is both random, and not visibly apparent. Preferably in a way that doesn't require extra people to do the experiment. That is what I have built. - Carl
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#34
05-12-2007, 12:19 PM
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MFD transmitter
How do we how if manufacturers of MFD transmitters have a secret the signal that the MFD transmitter put out. Type of AM mix with pulse of FM mixed with signl timing etc.
One test is to have a real gold bar and a fake gold bar that is the same size. THE USER OF THE LRL WILL NOT KNOW REAL FROM FAKE BUT THE LRL WILL KNOW. TAKE A LEAD GIVE IT A GOLD COLOR ETC KEEP THE TESTER MORE THAN 10 FEET FROM THE REAL AND FAKE AND YOU WILL HAVE A GOOD TEST, 
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#35
05-12-2007, 08:34 PM
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Testing for signal lines
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This test could be carried out in a measured area of land that has had all near-surface targets removed using a conventional metal detector. Then let the LRL operator look for any signal lines in the test area before hiding the two targets. An initial search for signal lines in the barren area allows the LRL operator to mark the location of pre-existing signal lines. Then the targets can be hidden (buried 2 inches deep) to see if there is any change in the initial signal lines. If the LRL operator believes he has found one of the two targets, let him recover it (no backhoe needed). The outcome of the test could be any of the following: 1. LRL operator refuses to participate in describing the locations of signal lines because he claims the test is not fair. 2. LRL operator does not find any signal lines in the test area of the targets. 3. LRL operator finds signal lines that lead him to the gold, and (A) identifies the gold, or (B) does not identify the gold before finding it. 4. LRL operator finds signal lines that lead him to the lead, and (A) identifies the lead, or (B) does not identify the lead before finding it. 5. LRL operator locates signal lines that do not lead to either of the two targets, but lead to other locations in the test area. 6. LRL operator locates signal lines that do not lead to either of the two bars or any other location in the test area. After this test is done, then remove one or both or none of the two targets and allow the LRL operator to describe any changes in the signal lines. Measuring this test can be done by recording the distance error the LRL missed the target by, or if repeated trials are conducted, you could have an empty hole count scoring system. The actual test for signal lines could be done by making a sketch of the test area on graph paper and marking the signal lines on the sketch along with the location of the targets. If this test is to be repeated in many distant locations, then the size of the test field and the targets should be made uniform in order that all the tests are done on a comparable field. ie: A 30 meter square section of land marked off with 10 cm grid marks at the perimeter would allow a similar graph paper sketch to be made that accurately indicates the locations of the targets and signal lines. The test for any LRL should be conducted under LRL operating conditions and instructions specified by the manufacturer. This test can be carried out by anyone including LRL manufacturers, LRL training personnel, skeptics, scientists, small children, homeless people, dowsers, space aliens, or anyone else capable of walking and holding a LRL.
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#36
05-12-2007, 10:43 PM
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OK - let me see... the MFD must appear to be powered on, even if it is disabled, and only one person is required to control the experiment.  In that case, if we cannot physically disable the MFD, then we must disable the user. Of course I don't mean calling in Luigi and the boys to give the MFD guy a nuckle sandwich. Nothing so drastic.  I was thinking more in terms of a bit of mind control. Let's say you've built a "mystery" box that is able to remotely disable the MFD. You can either keep the current state of the MFD a secret, or alternatively tell the user whether it's enabled or not. Depends on the experiment. The reality is that the "mystery" box is only another bunch of nonsense electronics, or possibly just full of fresh air. It could have two buttons - one marked "enable" and another marked "disable". The user (being an MFD believer) is convinced that the device can be remotely controlled by initially getting him/her to do a small test with a visible gold bar. Then the real test begins. I guess you get the general idea? As a skeptic, I am unable to think of an actual method of disabling an MFD, since (in my mind) it's already disabled.
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#37
05-13-2007, 03:10 PM
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In the audiophile industry, component testing is difficult to do because audio "quality" is very subjective and easily swayed by personal biases. Does amplifier "A" sound better than amplifier "B"? The way to find out is to have a bunch of people listen to them and give feedback. In such a test, a listener first hears "A", and then hears "B". He gives his opinion. Then he is subjected to a series of tests in which A & B are randomly selected -- blindly -- and each time he gives his opinion. This is to see if there is enough of a performance difference in A & B such that he can consistently tell the difference. The device that is used to select the components is called an "ABX" box. It has a switch that selects "A", or "B", or "X". "X" is a random selection... when the switch is set to X, either A or B is selected, but you have no idea which one. Even the ABX box doesn't tell you, until you press a "reveal" button. This same technique can very easily be applied to any MFD transmitter. The ABX selector is used to control power to the signal generator circuit. The user can turn it "on", or "off", or randomly select between on/off. There are several advantages to this approach. The user can do this anytime, anywhere, all by himself. No extra people, no big setup, no pressure. And it can be used either with planted targets or ordinary field use. This is the kind of testing that MFD manufacturers should be doing, but never do. I suspect they don't even want to do tests like this, because they already know what the results will be. - Carl
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#38
05-13-2007, 05:15 PM
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I was happy to see intelligent viewers exercising their own ability for critical thinking, and it looked like they were headed on the right track, but I see you have swayed the discussion back in the direction to conform to your own prejudice mindset and personal agenda. The puppets were apparently out of line with thinking independently and are back dancing in syncronization to your tune of Scientific pretense. 'THE DOOR TO KNOWLEDGE & UNDERSTANDING IS NEVER OPEN TO A CLOSED, OR PREJUDICE MIND" Dell
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#39
05-13-2007, 05:54 PM
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#40
05-13-2007, 06:03 PM
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I totally agree...ehm...with this too: 'THE DOOR TO KNOWLEDGE & UNDERSTANDING IS NEVER OPEN TO A CLOSED, OR PREJUDICE WALLET" Max Means that one only can say that some stuff doesn't works after buying and testing...but seems too expensive for my taste...this kind of knowledge & understanding...I still prefer the old wood...dowsing-rod...that costs nothing (and works nothing too ???) or the famous telephone wire wounded all around the head...(that maybe works...somehow ...like in Franklin's experiment...you know with the kyte and the key...  ).Best regards, Max
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#41
05-13-2007, 06:24 PM
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Or, maybe you didn't really do those tests, and you'll just continue to complain and blame me. - Carl P.S.--I know as well what the results will be. I'll bet we agree, too.
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#42
05-13-2007, 07:14 PM
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ABX power switch
Actually, an ABX switch to disconnect the power from the active circuitry in a device could be a good idea. If A=on and B=off and X=random selection of on/off, then we will find that any device that uses electricity will stop working when the off condition is selected from B or X.
If this ABX switch was used on a conventional metal detector, the operator would immediately recognize when the power is off during the X position because of the lack of any sound or visible reading on a display. Also, the operator would immediately lose his ability to locate unknown targets when the power was off. There would be no doubt in anyone's mind that the metal detector worked to pick up some kind of signals when power is on, and fails to pick up any signals when the power is off. In the case of a LRL, the difference is that most manufacturers claim the signal lines they are seeking have a varying strength due to physical conditions in the environment. This would suggest that there may be times and places where there are no signal lines even when a treasure is nearby, and other times when signals re-appear. If a meaningful ABX power test is to be conducted with a LRL, then I would suggest the test is started by finding a location where a good signal line is established, then while following the signal, remove the power to see if the signal disappears as it would on a conventional detector. This kind of test satisfies the condition of not needing any other person to conduct the testing, and can be applied to any kind of test field. The ABX switch could also be easily modified for conducting double blind tests if a small transmitter to control the power state was operated by a 3rd party. This could prove to be a valuable test method for determining whether added circuitry enhancements are an improvement or not. It could also be used to eliminate any idea-motor bias for people following signals. ie: A person listening to the signal of a target as he waves the coil over the target is told to "say when you lose the signal". Then we can expect him to identify the times when the power is removed. Or a LRL operator following a strong signal could say when the signal suddenly disappears in the same way.
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#43
05-14-2007, 03:37 AM
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#44
05-14-2007, 12:29 PM
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CARL CIRCUIT
Dell what do you thank of the circuit carl is building.
Will the circuit work or not.Do you have a loner circuit I can test. I will post the results on this forum. Carl is not the only one who can make test circuits DELL WILL YOU MAKE A TEST CIRCUIT FOR TESTING. WE WILL ONLY POST THE FACTS NOW THE SMALL PRINT. we will test all circuits the same way We will not use tricks,scams or deceits or lies
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#45
05-14-2007, 01:40 PM
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TX is ON: there is a signal line. TX is OFF: there is no signal line. TX is ON: there is a signal line. TX is OFF: there is no signal line. Then switch to random mode, and see if he can determine when the TX is ON or OFF. This sort of test won't work for all MFD users. Some people claim that when you switch off the TX power, the signal line remains intact, possibly for hours. Most people who make this claim are those who are most opposed to objective testing*, and use it for an excuse. Many MFD users don't believe this claim to be true at all**. Another way of using this device -- one in which even proponents of residual signal lines can use -- is in planted target testing. There is no question that both manufacturers and users of MFDs run tests (or demonstrations!) using planted targets. With this method, the user could run a daily test:
In either case -- field test or planted target test -- it will not take long to determine whether or not the claim of a detectable signal line is true, or false. - Carl *The same sort of people who claim that buried gold "ages", or that skeptics emit disabling SkepticWaves. **Amazing how something like this could even be debatable. It's so incredibly easy to design a scientific test for signal line "remanence", that it should have been conclusively determined years ago. After, of course, the very existence of signal lines is proven.
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#46
05-14-2007, 02:28 PM
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If you believe the test to be flawed, please state your objections. These generic "blame Carl" arguments are vapid. Let's hear how you would conduct tests that are of scientific quality. Let's hear how you did conduct these tests, if you ever really did. - Carl
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#47
05-15-2007, 04:15 AM
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- Carl
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#48
05-17-2007, 11:57 PM
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An observation..
Given Dell's recent incisive comments, there are only two possibilities that come to mind:
1. Dell doesn't want to know the truth. Which shows that he has a closed mindset. This is something he has accused skeptics of having on several occassions. Somewhat ironic, as it happens. 2. He already knows the sad truth, that dowsing and signal lines are false concepts. In this case the only conclusion is that he must be perpetrating a scam. I sincerely hope that possibility #2 is not the reality. My only concern about believing possibility #1 to be correct, is Dell's refusal to attend the Treasure Hunting event and meet with Carl. If he was 100% convinced of the reality of signal lines, then he would have nothing to fear and everything to gain. Taking a positive view on this, let's say that #2 is incorrect. Then there is only one possible answer. He is simply a deluded person with a pseudoscientific closed mindset, who's head might explode if he learned the truth after so many decades of self-deception. To quote Dell's own words: "It's a fact. Denial is self-deception." Dell Winders and: "The closed minded 'one size fits all' mentality is not going to work when testing LRL. You continue to doom yourself to failure." Dell Many a true word .... etc., etc.....
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