1
01:00:01,040 --> 01:00:05,040
So I'm going to move on now to the next section and that's going to be how what the frequencies
00:10.520 --> 00:14.480
were that Reif used that Hoyland wrote down.
00:14.480 --> 00:21.800
Once again I'm going to say that Hoyland hid these by doing this sideband method that
00:21.800 --> 00:24.240
we talked about earlier.
00:24.240 --> 00:31.480
And then of course you saw in the earlier segment how the sidebands show up on the spectrum
00:31.480 --> 00:32.480
analyzer.
00:32.480 --> 00:37.600
Okay so these were the known frequencies in hertz.
00:37.600 --> 00:46.000
So you can see the lowest frequency here is 191.803 hertz.
00:46.000 --> 00:50.880
And that's in the radio band so that would be at the very very, in fact that's below
00:50.880 --> 00:53.080
the radio band.
00:53.080 --> 00:58.000
Alright and then we move up to the next one which is anthrax.
00:58.000 --> 01:05.760
The bacteria is getting bigger so this frequency is getting lower.
01:05.760 --> 01:11.720
So the lowest one is anthrax at 139.200.
01:11.720 --> 01:18.960
And then we go to B or E coli rod at 416.510.
01:18.960 --> 01:25.960
Now this is after you multiply this frequency out this is what you get that you're going
01:25.960 --> 01:33.920
to subtract from the fundamental frequency.
01:33.920 --> 01:38.160
And then you're going to get this different frequency here and then every how many times
01:38.160 --> 01:40.760
you divide it you're going to get this audio frequency.
01:40.760 --> 01:44.480
So I think I've covered that earlier.
01:44.480 --> 01:53.560
So as you can see the highest known frequency that Hyland knew about along with Reif after
01:53.560 --> 02:01.620
he re-measured it was the cancer frequency which is 1607.450.
02:01.620 --> 02:06.320
And again it's showing you that if you do this.
02:06.720 --> 02:10.760
Now one thing that I have to point out.
02:10.760 --> 02:19.000
The carrier frequency here is at 31, 3.1 megahertz and so the max audio frequency that I'm going
02:19.000 --> 02:23.560
to run to is between 10,000 and 70,000.
02:23.560 --> 02:32.960
So when you put 70,000 into the sideband calculator which is going to print out a paper and it's
02:32.960 --> 02:39.400
going to tell me exactly what these frequencies are that I need to do my sweep in.
02:39.400 --> 02:45.120
So that's all part of in the little paper.
02:45.120 --> 02:46.120
Which paper?
02:46.120 --> 02:51.280
Well it's in the little paper that's in the booklet.
02:51.280 --> 03:00.160
And the thing is that what we want to do here is as I pointed out earlier see I am not a
03:00.160 --> 03:10.200
firm believer that I absolutely have to have the frequency exactly like this.
03:10.200 --> 03:15.000
Because I'm going to sweep it and I'm going to find it and I've got a spectrum analyzer
03:15.000 --> 03:16.880
and I can see it.
03:16.880 --> 03:21.480
So I can see where this frequency is going to end up.
03:21.480 --> 03:26.260
Exactly and I can put a dot there and I can sweep and I can see how many times it hits
03:26.260 --> 03:30.040
that maybe we should revisit that in a minute.
03:30.120 --> 03:34.360
So that they can see what I'm talking about.
03:34.360 --> 03:38.680
But see these audio frequencies over here in the chart?
03:38.680 --> 03:42.640
These are all the audio frequencies that I need to do.
03:42.640 --> 03:45.760
In other words in my sweep.
03:45.760 --> 03:51.200
That's why I'm sweeping the sine wave generator or the square wave generator between this
03:51.200 --> 03:53.400
frequency and the highest frequency.
03:53.400 --> 03:57.360
So 31 is the lowest one and 69 is the highest?
03:57.400 --> 04:01.720
Yeah, that's what it looks like right in here.
04:01.720 --> 04:07.000
And see that's typhoid and see these little blue indicators?
04:07.000 --> 04:10.520
That's indicating it's a virus to me.
04:10.520 --> 04:15.320
So the two most important are the two most dangerous.
04:15.320 --> 04:21.440
The most dangerous is tuberculosis because you not only have to kill the rod, you have
04:21.440 --> 04:23.280
to kill the virus.
04:23.280 --> 04:25.360
There's a rod and there's a virus.
04:25.360 --> 04:27.200
Reif called it a rod.
04:27.200 --> 04:28.800
It's like a rod in the microscope.
04:28.800 --> 04:31.680
Yeah, in the microscope.
04:31.680 --> 04:37.120
So it's mandatory that you do both of these frequencies at the same time or one right
04:37.120 --> 04:38.120
after the other.
04:38.120 --> 04:39.120
That's why the sweep.
04:39.120 --> 04:47.320
All right, because you can see there's not much difference here between them.
04:47.320 --> 04:52.600
The virus is here.
04:52.600 --> 04:53.640
This is where we're going to end.
04:53.640 --> 04:59.600
This is what Reif determined or Hoyland determined was the frequency in the lab.
04:59.600 --> 05:04.960
And the other thing that I'm going to point out is Hoyland, when he made the sideband
05:04.960 --> 05:09.640
machine, it was tested in the laboratory.
05:09.640 --> 05:14.120
And then it was given to the doctors and it was tested so that they know that this method
05:14.120 --> 05:16.160
works.
05:16.160 --> 05:20.880
So here's all your different frequencies in the chart.
05:20.880 --> 05:21.880
One quick question.
05:21.880 --> 05:25.960
I see under typhoid rod, you've got two numbers.
05:25.960 --> 05:31.720
Yes, I got the two numbers because you got to do these two numbers.
05:31.720 --> 05:32.720
You have to do this.
05:32.720 --> 05:37.400
This is the only known virus.
05:37.400 --> 05:39.600
Tuberculosis is the only known thing.
05:39.600 --> 05:46.800
If you kill the rod, what's going to happen is the patient's going to die because then
05:46.800 --> 05:50.320
the virus is going to take over and it's going to eat you.
05:51.000 --> 05:55.400
So you know there's two frequencies there from Reif's original lab work?
05:55.400 --> 05:56.400
Yes.
05:56.400 --> 05:57.400
Yes.
05:57.400 --> 06:05.120
And Reif stated in the movies and the films and the talks that you must kill the rod and
06:05.120 --> 06:06.400
you must kill the virus.
06:06.400 --> 06:10.960
So he developed a machine that did those two frequencies at one time.
06:10.960 --> 06:14.680
There's the two numbers.
06:14.680 --> 06:15.680
See that Tony?
06:15.680 --> 06:16.680
Yeah.
06:16.680 --> 06:17.680
There's the two numbers.
06:17.680 --> 06:20.240
That's the rod and the virus.
06:20.240 --> 06:21.960
Yeah, that's why I got the blue there.
06:21.960 --> 06:22.960
Yeah, yeah, yeah.
06:22.960 --> 06:24.960
So I see what happened.
06:24.960 --> 06:28.480
As I went down the chart, I just transposed a number.
06:28.480 --> 06:29.480
Okay.
06:29.480 --> 06:35.480
Anyway, this is what was known.
06:35.480 --> 06:36.480
Okay.
06:36.480 --> 06:37.480
Period.
06:37.480 --> 06:39.440
This is all they knew about.
06:39.440 --> 06:44.400
There were probably 15 more.
06:44.400 --> 06:46.120
Who knows where that went.
06:46.120 --> 06:47.120
Right.
06:48.120 --> 06:51.120
So anyway, I'm going to go back to this.
06:51.120 --> 06:54.120
I'm going to go through this one more time.
06:54.120 --> 07:05.800
These are the only known frequencies for these viruses that we have today.
07:05.800 --> 07:09.080
The rest of the notes have been lost.
07:09.080 --> 07:10.080
Okay.
07:10.080 --> 07:12.600
Nobody knows where they're at, so we don't know.
07:12.600 --> 07:13.720
Okay.
07:13.720 --> 07:20.880
Because the machines are gone and nobody can find the other machine.
07:20.880 --> 07:30.560
The only machine that was found was the one that I suspect was in LA that Jeff Garf got
07:30.560 --> 07:32.560
from Dr. Lowe.
07:32.560 --> 07:33.560
Okay.
07:33.560 --> 07:37.680
And I've never seen anything.
07:37.680 --> 07:42.680
I've heard about it and I see some spectrum analysis.
07:42.680 --> 07:52.160
What my interest would be with that machine would be to run it and have the real spectrum
07:52.160 --> 07:55.960
analyzer and see if you're absolutely going to end up.
07:55.960 --> 07:58.440
Who was Jeff Garf again?
07:58.440 --> 08:04.560
Jeff Garf was very interested in RIFE in the beginning.
08:04.560 --> 08:12.320
And he's the one that wrote the history of RIFE in the PDF file on the Internet.
08:12.960 --> 08:17.920
And when I was talking to him, he explained that he finally found a machine and he was
08:17.920 --> 08:21.880
able to figure out what was going on with it.
08:21.880 --> 08:31.400
But through my research, well first of all, Jeff Garf, let's just say what he does.
08:31.400 --> 08:36.280
He produces the GB4000 and the Mopi amplifier.
08:36.280 --> 08:40.040
Those are two things that you can buy right now on the Internet.
08:40.760 --> 08:47.000
Right, but there's no guarantees or anything because remember we're not medical doctors.
08:47.000 --> 08:52.080
We're only reproducing this guy's work and if you want to do experiments with it, then
08:52.080 --> 08:54.160
that's what you're going to do.
08:54.160 --> 09:06.360
Now the thing about it is this work requires, I would really recommend the person doing
09:06.480 --> 09:10.160
this kind of work to have a spectrum analyzer.
09:10.160 --> 09:12.640
And they're not going to be able to see.
09:12.640 --> 09:13.640
You're just second guessing.
09:13.640 --> 09:17.600
You're saying, yeah, we have the wave shape on the scope.
09:17.600 --> 09:23.160
The scope is not telling you what bands it's generating.
09:23.160 --> 09:28.480
So I think what we'll do is we'll cut away from here for a minute and we'll go back
09:28.480 --> 09:30.600
to the analyzer.
09:30.600 --> 09:40.480
All right, so anyway, we're here at the analyzer and what we want the machine to do right
09:40.480 --> 09:47.200
at this point in time, and I'll point out some parts in the machine here and I'll...
09:47.200 --> 09:51.160
This is very important because this is your fundamental oscillator.
09:51.160 --> 09:53.800
This is your replication of your version?
09:53.800 --> 09:55.880
Well, this is programmed to do the...
09:55.880 --> 09:57.840
No, but this is a rife machine.
09:57.840 --> 09:59.640
Yes, this is a rife...
09:59.680 --> 10:00.680
By Vadini.
10:00.680 --> 10:05.760
Yes, along with this entails the pump wave in it.
10:05.760 --> 10:12.080
So if I turn this on, right away, you can see this appear.
10:12.080 --> 10:13.520
That's your fundamental frequency.
10:13.520 --> 10:20.480
Now, if you look at this, we know that this is the cancer frequency because we've determined
10:20.480 --> 10:23.840
that by over there on the other chart.
10:23.840 --> 10:29.120
So now if we hit the marker, well, let's auto it and hit the marker.
10:29.120 --> 10:33.360
Okay, so there's our fundamental frequency and see all this?
10:33.360 --> 10:35.440
We're not modulating at all.
10:35.440 --> 10:41.120
So now if we hit the marker button, it appears there and it's telling us...
10:41.120 --> 10:45.120
Okay, we're sitting at...
10:45.120 --> 10:53.400
See right at the peak of this wave, we're sitting at 3.09999999, which is 3.1 megahertz.
10:53.960 --> 11:02.120
All right, now, when the frequencies are put into the machine, it's going to modulate
11:02.120 --> 11:07.120
these against the RF amplifier, which is going to create sidebands here.
11:10.320 --> 11:12.520
So this is that little $100...
11:12.520 --> 11:13.720
What do you call that thing?
11:13.720 --> 11:18.560
Generator, and see, you can see that the sidebands appeared for a second, watch, they'll pop
11:18.560 --> 11:22.240
in there when the oscillator comes down a little bit.
11:23.440 --> 11:24.440
See them?
11:24.440 --> 11:28.440
Okay, now, so what we're going to do with this is we're going to...
11:32.440 --> 11:37.440
Actually, we want to zoom out because we want to see what all of them that it's generating.
11:37.440 --> 11:44.440
Okay, so see all the sidebands that it's generating?
11:44.480 --> 11:49.480
So, what we can do is we can take this marker...
11:54.480 --> 11:59.480
And we know what the cancer frequency, we know it's 3.14.
12:00.480 --> 12:05.480
Let me have that chart just for a minute there, Michael, and I'll just point it out here.
12:05.520 --> 12:16.520
So, what we're looking for is we're looking for the BX sarcoma virus, and that's 3214900.
12:16.520 --> 12:19.520
So all we have to do is move this marker.
12:21.520 --> 12:24.520
Okay, so we want 3214.
12:27.520 --> 12:32.520
832, we're within one tenth of one meter right there.
12:32.560 --> 12:37.560
And see that now this spectrum analyzer shows you this dot.
12:39.560 --> 12:43.560
And see it's hitting those peaks as it goes towards the fundamental.
12:43.560 --> 12:48.560
And each time it hits that peak, you're actually hitting the cancer virus.
12:48.560 --> 12:51.560
So, we'll bring this down.
12:55.560 --> 12:59.560
Sometimes hard to adjust this, but we'll get it.
12:59.600 --> 13:02.600
We don't need that much attenuation.
13:04.600 --> 13:09.600
Or I want you to get a good picture of this, so you can see where they're going.
13:12.600 --> 13:15.600
And I'll zoom this in a little bit.
13:19.600 --> 13:22.600
Maybe I can get this where I want it.
13:22.640 --> 13:27.640
See all the bands that are showing up in there, Tony?
13:27.640 --> 13:28.640
Mm-hmm.
13:29.640 --> 13:32.640
So, let's get it out here.
13:35.640 --> 13:39.640
My electrodes are goofing me up here, so I'm gonna get this right here.
13:40.640 --> 13:43.640
I'm gonna hold them together so you can see.
13:43.680 --> 13:48.680
As it generates those bands, as it moves, see that dot moving up and down?
13:48.680 --> 13:53.680
It's hitting the cancer frequency at those, every time that dot appears.
13:55.680 --> 13:58.680
But it's also hitting all these others.
14:00.680 --> 14:05.680
So, if we chose another frequency, like,
14:05.720 --> 14:08.720
let's see if we can go down here.
14:08.720 --> 14:10.720
Marker.
14:16.720 --> 14:19.720
29.
14:21.720 --> 14:24.720
15.
14:24.760 --> 14:27.760
29.
14:30.760 --> 14:33.760
15.
14:37.760 --> 14:40.760
So, we're at 29.15.
14:40.760 --> 14:47.760
So, we're at B or E coli rod, every time that dot hits on top of one of those peaks.
14:47.800 --> 14:49.800
See it?
14:50.800 --> 14:53.800
So, it's sweeping the whole band.
14:53.800 --> 14:55.800
Yeah.
14:56.800 --> 14:59.800
So, we could move this in.
15:03.800 --> 15:06.800
We have a little better picture of this.
15:06.800 --> 15:09.800
As these sweep out, there you go.
15:09.840 --> 15:14.840
And this really machine wants to be in resonance, so it wants you to be on the machine.
15:14.840 --> 15:15.840
See it?
15:15.840 --> 15:18.840
So, it's already hit it there, it's hit it there.
15:18.840 --> 15:22.840
It's hit B, B and E, E coli there.
15:22.840 --> 15:26.840
So, now if we just take another one to show you that it's hitting, well,
15:26.840 --> 15:31.840
30594.
15:31.840 --> 15:34.840
So, we just take the marker.
15:34.880 --> 15:37.880
And go to 30.
15:45.880 --> 15:50.880
Now we are hitting, every time that dot hits this peak,
15:54.880 --> 15:59.880
we are hitting BY sarcoma, which would be skin cancer.
15:59.920 --> 16:02.920
If you could put it right on there.
16:02.920 --> 16:03.920
You follow me?
16:03.920 --> 16:06.920
So, let's pick another one and see where we are.
16:06.920 --> 16:08.920
Okay, two.
16:08.920 --> 16:13.920
So, just to, you said you've kind of shorted out the electrodes here or the...
16:13.920 --> 16:15.920
Well, I want the electrodes.
16:15.920 --> 16:18.920
See, they want to be hooked to something that you're seeing the pump wave
16:18.920 --> 16:20.920
and you're seeing noise enter.
16:20.920 --> 16:22.920
They want to be hooked.
16:22.920 --> 16:27.920
So, we're hitting BY sarcoma, which would be skin cancer.
16:27.960 --> 16:29.960
And then you see the noise enter.
16:29.960 --> 16:31.960
They want to be hooked to you.
16:31.960 --> 16:35.960
See, so you get a perfect wave watch as it comes out.
16:35.960 --> 16:36.960
To complete the circuit.
16:36.960 --> 16:37.960
Yeah, see it?
16:37.960 --> 16:41.960
Now you're seeing the real sideband waves.
16:41.960 --> 16:44.960
And it doesn't make any difference.
16:44.960 --> 16:48.960
What I found out with this is that if I put these together like that,
16:48.960 --> 16:50.960
it shows you a pretty good picture.
16:50.960 --> 16:51.960
See?
16:51.960 --> 16:52.960
Yeah.
16:52.960 --> 16:54.960
And that's why I have detuned the circuit.
16:55.000 --> 16:58.000
I can't make the circuit in this machine for the simple fact
16:58.000 --> 17:00.000
that once it's on you, it tunes.
17:00.000 --> 17:01.000
Right.
17:03.000 --> 17:06.000
And I can make this as small or as wide as I want right now.
17:06.000 --> 17:09.000
I'm in the noise, but let's see if I can get this...
17:09.000 --> 17:10.000
Yeah.
17:14.000 --> 17:15.000
There you go.
17:15.000 --> 17:20.000
That's a pretty good picture of how they go out.
17:20.000 --> 17:21.000
See?
17:21.000 --> 17:22.000
Uh-huh.
17:22.040 --> 17:24.040
You're starting at a real low frequency
17:24.040 --> 17:27.040
and you're ending up at a real high frequency.
17:27.040 --> 17:31.040
So what I want to do is I'll put this under here for a second
17:31.040 --> 17:33.040
so it stays there.
17:33.040 --> 17:36.040
And I'll pick another one.
17:36.040 --> 17:41.040
I'll pick pneumonia or spinal meningitis.
17:41.040 --> 17:47.040
That would be at 2988.034.
17:47.040 --> 17:49.040
So I'll hit the marker.
17:49.080 --> 17:54.040
298.
17:59.040 --> 18:01.040
8.
18:07.040 --> 18:09.040
107, but see, since I'm sweeping,
18:09.040 --> 18:12.040
see, I'm hitting it all the time there.
18:12.040 --> 18:14.040
I hit it twice here.
18:14.040 --> 18:16.040
Once there...
18:17.040 --> 18:19.040
And once when it moves there,
18:19.040 --> 18:21.040
I actually hit it a couple of times.
18:21.040 --> 18:22.040
See it?
18:22.040 --> 18:24.040
They're down lower here.
18:26.040 --> 18:29.040
So now what we should do is probably...
18:32.040 --> 18:35.040
span it in there so you can see it hit it
18:35.040 --> 18:37.040
right at the top of the peak
18:37.040 --> 18:39.040
when it gets right at the right frequency.
18:39.040 --> 18:40.040
See?
18:40.040 --> 18:42.040
When it's at the top of the peak of the...
18:42.040 --> 18:43.040
Yeah, see?
18:43.040 --> 18:44.040
...when it hits it?
18:44.040 --> 18:45.040
See it hit it?
18:45.040 --> 18:47.040
Now watch as it grows.
18:47.040 --> 18:50.040
See it hit it there, it hit it there.
18:50.040 --> 18:52.040
It's gonna hit it there.
18:52.040 --> 18:55.040
And then it's gonna go down here and collapse.
18:55.040 --> 18:57.040
And then it's gonna come back and sweep again
18:57.040 --> 18:59.040
and hit it and hit it.
18:59.040 --> 19:01.040
And that would be your pneumonia
19:01.040 --> 19:05.040
according to Hoylan.
19:05.040 --> 19:08.040
Now, let's go down and see if we can get...
19:09.040 --> 19:11.040
syphilis,
19:11.040 --> 19:16.040
which is at 3.154.
19:16.040 --> 19:19.040
So we'll go to the marker...
19:19.040 --> 19:21.040
4 there.
19:21.040 --> 19:23.040
We're within 1 tenth.
19:23.040 --> 19:25.040
Now you can see that it's coming along
19:25.040 --> 19:28.040
and it's hitting it right there.
19:28.040 --> 19:30.040
See it?
19:32.040 --> 19:34.040
Then it's gonna grow again,
19:34.040 --> 19:36.040
so it's hitting it every time it hits.
19:36.040 --> 19:38.040
See how it sweeps by?
19:38.040 --> 19:41.040
So it's sweeping the range,
19:41.040 --> 19:43.040
and that's what Reif said,
19:43.040 --> 19:47.040
or the doctor said that they had to sweep the machine
19:47.040 --> 19:50.040
back and forth, and then they got great results.
19:50.040 --> 19:54.040
So we're just doing it to show you
19:54.040 --> 19:58.040
that the sweep is hitting these frequencies.
20:00.040 --> 20:03.040
I think we can close this down.
20:06.040 --> 20:08.040
Now...
20:09.040 --> 20:11.040
this, of course, you can see the sweep here
20:11.040 --> 20:14.040
and the gating effect.
20:14.040 --> 20:18.040
And this little wiggle that you're seeing here,
20:18.040 --> 20:21.040
see the gating effect in there?
20:21.040 --> 20:25.040
That little wiggle you're seeing is this pump wave.
20:25.040 --> 20:29.040
Okay, so if we took the scope...
20:29.040 --> 20:32.040
and we'll go over to the pump wave.
20:35.040 --> 20:38.040
That's your pump wave.
20:38.040 --> 20:41.040
Now let's go over here.
20:49.040 --> 20:53.040
And you see how the pump wave is making it.
20:53.040 --> 20:56.040
It's making it...
20:56.040 --> 20:59.040
the pump wave is making it...
21:01.040 --> 21:04.040
move up and down.
21:04.040 --> 21:07.040
It might be really hard to see that on there,
21:07.040 --> 21:10.040
but it's that wiggle that's in there.
21:10.040 --> 21:13.040
Can you get that to me?
21:17.040 --> 21:21.040
So let's come out of the oscillator and look at it.
21:21.040 --> 21:24.040
Okay, there's the pump.
21:26.040 --> 21:29.040
So you can see the wave.
21:29.040 --> 21:32.040
So it's just on and off, on and off, on and off.
21:32.040 --> 21:38.040
And that pump wave is then being sent out to the electrodes.
21:38.040 --> 21:45.040
And you can see that in the pump wave are the frequencies.
21:45.040 --> 21:48.040
The whole band of frequencies.
21:48.040 --> 21:51.040
That's what would be going into your body.
21:51.040 --> 21:55.040
And it's using that little bit of DC current to push it through your body.
21:55.040 --> 21:58.040
Wouldn't you say gating effect?
21:58.040 --> 22:01.040
Does that mean where it goes into the body?
22:01.040 --> 22:04.040
Yeah.
22:04.040 --> 22:09.040
And the most important part is, are you generating these sidebands?
22:09.040 --> 22:13.040
And this is why it's important to see the spectrum analyzer
22:13.040 --> 22:16.040
so that you know the frequency.
22:16.040 --> 22:20.040
And this is why it's important to see the spectrum analyzer
22:20.040 --> 22:23.040
so that you know that it's actually hitting it.
22:23.040 --> 22:28.040
And every time you see this jump, that's the pump wave.
22:28.040 --> 22:31.040
That's this ripple effect.
22:36.040 --> 22:38.040
It's there.
22:38.040 --> 22:40.040
You see it moving up and down?
22:40.040 --> 22:43.040
Okay, that's very important.
22:43.040 --> 22:46.040
I just changed the resonance of it.
22:46.040 --> 22:50.040
And I changed the resonance down here because I'm holding the electrodes.
22:50.040 --> 22:52.040
So now I've got clean waves.
22:52.040 --> 22:55.040
See it? When it pops up, watch.
23:03.040 --> 23:06.040
If I let go of it and I separate the electrodes,
23:06.040 --> 23:08.040
then I'm just going to get what I get.
23:08.040 --> 23:10.040
It's going to bounce around.
23:10.040 --> 23:14.040
Because there's a pump wave involved and it's pumping it.
23:16.040 --> 23:18.040
That's a DC current.
23:18.040 --> 23:24.040
And then if I take the electrodes and I put them together like this,
23:24.040 --> 23:28.040
you can see my waves are cleaner.
23:30.040 --> 23:32.040
It shows you more.
23:32.040 --> 23:34.040
Yeah, more regular.
23:34.040 --> 23:36.040
Yeah.
23:36.040 --> 23:41.040
Every time that dot is going to the peak of this, right?
23:41.040 --> 23:45.040
Then I'm hitting that exact frequency.
23:45.040 --> 23:47.040
That's the hit on the peak.
23:47.040 --> 23:55.040
Yeah, now I think the lowest one is 139.
23:55.040 --> 23:59.040
So that would be 3062.
24:01.040 --> 24:03.040
There, 465.
24:03.040 --> 24:10.040
Every time that hits on the peak, like right there,
24:10.040 --> 24:14.040
remember this is the lowest one.
24:14.040 --> 24:17.040
So it's going to hit it one time.
24:17.040 --> 24:20.040
Actually two times, three times.
24:20.040 --> 24:23.040
Yeah, it's moving a lot slower.
24:23.040 --> 24:26.040
Yeah, and that would be anthrax.
24:26.040 --> 24:28.040
Wow.
24:28.040 --> 24:32.040
So I'm hitting the whole spectrum of what I have here.
24:33.040 --> 24:36.040
And I can change that by changing the generator.
24:36.040 --> 24:41.040
In other words, if I change it from 70,000 Hz to something else,
24:41.040 --> 24:45.040
then my sideband calculator is going to change.
24:45.040 --> 24:49.040
And what I'd like to do, if possible,
24:49.040 --> 24:53.040
Tony, is it possible to do the computer screen so I can show you the sideband calculator?
24:53.040 --> 24:55.040
Sure.
24:57.040 --> 24:59.040
Okay, what are we doing now, John?
24:59.040 --> 25:02.040
We're going to, I'm going to run the sideband calculator.
25:02.040 --> 25:08.040
Now what I want to tell everybody is you can only get this calculator off the right group.
25:08.040 --> 25:11.040
You have to join the group to get it.
25:11.040 --> 25:15.040
So here I'm going to run the calculator and show you.
25:15.040 --> 25:19.040
Here's the carrier frequency, which I had over on the other chart.
25:19.040 --> 25:23.040
So I'm going to put 31.
25:23.040 --> 25:26.040
Right there, that gives me 3.1 MHz.
25:26.040 --> 25:32.040
And see, my max audio frequency is going to be 70,000.
25:32.040 --> 25:35.040
So I'm just going to make that 7.
25:35.040 --> 25:40.040
And then I'm going to tell it to calculate, and these numbers are going to change.
25:42.040 --> 25:52.040
So now you can see that the BX frequency still maintains 3.214900.
25:52.040 --> 25:57.040
And the difference frequency is 114, which I showed you in the calculation.
25:57.040 --> 26:05.040
Audio 1 is 57, but if I put this back to 40, it's going to be where I told you it was on the chart over there.
26:05.040 --> 26:11.040
Now, if we choose the sarcoma frequency, right?
26:11.040 --> 26:14.040
And we tell it, give us the graph.
26:14.040 --> 26:24.040
You can see this is what the wave looks like, gated, which you saw there.
26:24.040 --> 26:29.040
And then it's going to be 1, 2 here, over.
26:29.040 --> 26:34.040
So if I divide it by 3, it's going to be here.
26:34.040 --> 26:36.040
If I divide it by 4, it's going to be there.
26:36.040 --> 26:39.040
So who put all this stuff in the right group then?
26:40.040 --> 26:47.040
There was a computer programmer that made this program after they figured out how the machine actually worked.
26:47.040 --> 26:56.040
And so it actually works out pretty good because if I get out of here, and I put this back to 40,
26:56.040 --> 27:07.040
so I only want to run my generator to 40,000, and I recalculate for this same cancer frequency, and I go to the graph.
27:07.040 --> 27:11.040
I'm exactly where I want to be when I divide by 3.
27:14.040 --> 27:17.040
1, 2, 3.
27:17.040 --> 27:24.040
So if I change the generator, as long as I get this number,
27:24.040 --> 27:35.040
as long as I get this number, which is 3214.900,
27:35.040 --> 27:40.040
you see here? It's saying it's divided by 3 here.
27:44.040 --> 27:51.040
So my spectrum analyzer is showing me those numbers and what's being.
27:52.040 --> 27:56.040
Once again, here's the fundamental frequency. We'll mark it.
27:59.040 --> 28:02.040
We'll auto this first, and then we'll bring it in.
28:03.040 --> 28:06.040
So we know that's it, right?
28:07.040 --> 28:14.040
And then we'll span this in so that we can see there's nothing being generated.
28:15.040 --> 28:18.040
In other words, we're not generating anything here.
28:19.040 --> 28:21.040
All right, then we mark this.
28:21.040 --> 28:26.040
It's telling me, according to my span, where my generator is, see?
28:28.040 --> 28:30.040
So there's my fundamental frequency.
28:32.040 --> 28:33.040
All right?
28:35.040 --> 28:42.040
And then I say to it, start generating the sidebands.
28:45.040 --> 28:47.040
There you go.
28:48.040 --> 28:51.040
See, my fundamental frequency is not changing.
28:52.040 --> 28:54.040
What's changing are the sidebands.
28:54.040 --> 28:56.040
So now if I just say marker,
28:57.040 --> 29:01.040
and I know that the cancer frequency is going to be over at the third band,
29:01.040 --> 29:07.040
so that's going to be 3214,
29:08.040 --> 29:10.040
which is going to be here.
29:11.040 --> 29:17.040
3214.
29:18.040 --> 29:21.040
I'm within still one tenth of one meter.
29:21.040 --> 29:24.040
You can see the dot, how many times it hits the actual frequency.
29:24.040 --> 29:25.040
See it?
29:26.040 --> 29:28.040
So then we can just span this in,
29:29.040 --> 29:34.040
telling me so we can get a tighter view of how many times this is going to happen.
29:37.040 --> 29:38.040
See?
29:39.040 --> 29:40.040
So I know it's right.
29:40.040 --> 29:41.040
Hitting it regular.
29:41.040 --> 29:42.040
Yep.
29:43.040 --> 29:45.040
And that's all I have to do.
29:46.040 --> 29:51.040
And then, of course, this is going to change.
29:51.040 --> 29:54.040
If I take these off and I put one here,
29:57.040 --> 30:01.040
and one here, then you're going to see a much more detailed wave.
30:01.040 --> 30:02.040
See it?
30:02.040 --> 30:03.040
And more regular.
30:03.040 --> 30:04.040
Yeah.
30:04.040 --> 30:06.040
Because it's down tuned with me.
30:06.040 --> 30:07.040
Right.
30:15.040 --> 30:18.040
Yeah, it's performing nicely.
30:18.040 --> 30:19.040
Yes.
30:20.040 --> 30:23.040
And the jumping up and down is this pump wave here.
30:26.040 --> 30:28.040
So I think everybody gets the idea.
30:28.040 --> 30:30.040
And just to reiterate,
30:30.040 --> 30:39.040
this here is your solid state version of the Reif machine.
30:39.040 --> 30:41.040
Of the Reif machine.
30:41.040 --> 30:43.040
Which we'll get into later on.
30:43.040 --> 30:44.040
Yeah.
30:44.040 --> 30:45.040
Well, it's in the booklet.
30:45.040 --> 30:50.040
But like I said, the important part was programming this for a fundamental frequency
30:50.040 --> 30:57.040
and then getting the audio circuit to end the pump wave to put the DC current through you.
30:57.040 --> 30:58.040
It's beautiful.
30:58.040 --> 31:03.040
So if you take the generator off, you should come back to the fundamental frequency.
31:07.040 --> 31:10.040
And then you can see the difference.
31:10.040 --> 31:13.040
And in the pump wave is a square wave.
31:13.040 --> 31:14.040
See.
31:16.040 --> 31:19.040
Now by changing this, right?
31:20.040 --> 31:26.040
By changing the span, I mean they're going to come down 1.66 or I'm going to go up.
31:26.040 --> 31:27.040
See?
31:27.040 --> 31:30.040
So the thing is to auto it.
31:30.040 --> 31:33.040
And let's find out where the marker says it is.
31:33.040 --> 31:35.040
And there it is.
31:36.040 --> 31:39.040
3.1000000.
31:39.040 --> 31:40.040
So it's right on.
31:40.040 --> 31:42.040
And there's the wave.
31:42.040 --> 31:43.040
Beautiful.
31:43.040 --> 31:46.040
And you can see the pump now because you can see it going up and down.
31:46.040 --> 31:47.040
Right.
31:47.040 --> 31:49.040
That's the DC pump.
31:49.040 --> 31:51.040
And that's the sweep.
31:51.040 --> 31:52.040
No, it's not sweep.
31:52.040 --> 31:54.040
It's the DC pump.
31:54.040 --> 31:56.040
And that's the sweep.
31:56.040 --> 31:58.040
And that's the sweep.
31:58.040 --> 32:00.040
That's the DC pump.
32:00.040 --> 32:02.040
And that's the sweep.
32:02.040 --> 32:03.040
No, it's not sweeping.
32:03.040 --> 32:05.040
It's just a one steady frequency.
32:05.040 --> 32:06.040
The fundamental.
32:06.040 --> 32:07.040
Because it's up at the top.
32:07.040 --> 32:10.040
Yeah, what you're seeing there is the pump wave pumping.
32:10.040 --> 32:11.040
I see.
32:14.040 --> 32:17.040
So the minute you add the generator to it, watch what's going to happen.
32:17.040 --> 32:18.040
Then it sweeps.
32:18.040 --> 32:21.040
Well, watch as soon as it comes on.
32:21.040 --> 32:22.040
Yeah.
32:22.040 --> 32:25.040
You see and then you can see what it's doing here.
32:25.040 --> 32:26.040
Right.
32:28.040 --> 32:33.040
As it moves to the CL, as many bands it's generating.
32:33.040 --> 32:34.040
Yeah.
32:34.040 --> 32:41.040
And so that's saying that please zoom out so you get more.
32:41.040 --> 32:46.040
The machine can actually tell you, OK, zoom out a little bit more.
32:46.040 --> 32:51.040
Now there it goes.
32:51.040 --> 32:53.040
See, it's going.
32:53.040 --> 32:56.040
So zoom in.
32:56.040 --> 33:03.040
And we'll get these so that we get a nice wave, see.
33:03.040 --> 33:08.040
And it says it spans at 200 kilohertz.
33:08.040 --> 33:10.040
The market.
33:10.040 --> 33:15.040
Notice the fundamental frequency is not changing at all.
33:15.040 --> 33:17.040
Even though it's being pumped.
33:17.040 --> 33:18.040
Right.
33:18.040 --> 33:22.040
So I think everybody's got a pretty good idea of how this is working.
33:22.040 --> 33:23.040
Right.
33:23.040 --> 33:29.040
So we'll go back and I'll explain it one more time over here.
33:29.040 --> 33:34.040
And then we'll move on to the circuits.
33:34.040 --> 33:35.040
OK.
33:35.040 --> 33:38.040
So now we're going to move on to the circuit.
33:38.040 --> 33:41.040
So we're going to go back to the circuit.
33:41.040 --> 33:45.040
And then we'll move on to the circuits.
33:45.040 --> 33:46.040
OK.
33:46.040 --> 33:54.040
So now we're going to move on to more technical in the Rife machine, the building blocks for the Rife machine.
33:54.040 --> 34:01.040
So the first building block is the fundamental oscillator.
34:01.040 --> 34:07.040
Now this is a programmable oscillator that you have to buy and you have to program it.
34:07.040 --> 34:10.040
So you need a programmer to program it.
34:10.040 --> 34:18.040
And it's programmed and it's a CCPC4, which you can get at Digi-Key.
34:18.040 --> 34:24.040
And I think you give them a little bit and they'll program that frequency for you.
34:24.040 --> 34:25.040
Who? Digi-Key?
34:25.040 --> 34:26.040
Digi-Key.
34:26.040 --> 34:27.040
Electronics.
34:27.040 --> 34:30.040
They're on the Internet.
34:30.040 --> 34:38.040
And it's very important to remember with this type of CMOS oscillator, I think it does CMOS and TTL.
34:38.040 --> 34:41.040
And that you regulate it to 5 volts.
34:41.040 --> 34:43.040
So you need a regulator in the circuit.
34:43.040 --> 34:46.040
And you can see that right here.
34:46.040 --> 34:49.040
And you need these filter.
34:49.040 --> 34:57.040
You need the filter capacitor here, 1000 mics on the input from the 12 volt source.
34:57.040 --> 35:03.040
You want to keep this as stable as you can from the 12 volt lithium cells.
35:03.040 --> 35:11.040
And this is giving you your fundamental frequency in a square wave.
35:11.040 --> 35:18.040
Now whether we're using square waves or we're using sine waves, we're still going to get the same thing.
35:18.040 --> 35:22.040
We're just going to get more of them with a square wave.
35:22.040 --> 35:25.040
Because it's odd harmonics.
35:25.040 --> 35:31.040
And to protect this guy, this oscillator,
35:31.040 --> 35:41.040
we built a buffer circuit for it, which takes the RF and buffers it so that there's a safety factor.
35:41.040 --> 35:45.040
So that it comes out of the emitter at low impedance.
35:45.040 --> 35:51.040
So it's going to drive the RF circuit from this point here.
35:51.040 --> 35:55.040
And these are just common variety transistors.
35:55.040 --> 36:10.040
This can be a 2N2222, a 2N4401, or anything that's got a high HFE, which is high frequency gain bandwidth.
36:10.040 --> 36:13.040
And so this becomes your buffer circuit.
36:13.040 --> 36:17.040
And this is going to drive your RF amplifier.
36:17.040 --> 36:26.040
Now, the RF amplifier is just done really simple.
36:26.040 --> 36:29.040
It's biased with a 10K resistor.
36:29.040 --> 36:32.040
It's got an inductor where it belongs.
36:32.040 --> 36:34.040
It's got a resistor and an emitter.
36:34.040 --> 36:37.040
And it's got a Pi network so it's tunable.
36:37.040 --> 36:41.040
In my case, I detuned it.
36:41.040 --> 36:46.040
I detuned it for the simple reason is when you touch it, it goes into tune.
36:46.040 --> 36:53.040
So it's set to go into tune the minute you touch the electrodes to give you the best results.
36:53.040 --> 37:02.040
And so this transistor here is very important because this is a regular RF transistor.
37:02.040 --> 37:10.040
And it needs to have a heat sink on it, which I'll show you when I bring out the machine in a few minutes.
37:10.040 --> 37:14.040
And I'll point out all the components are.
37:14.040 --> 37:19.040
These are tremble capacitors that adjust this Pi network.
37:19.040 --> 37:25.040
Now, normally this network would be higher than 22 microhenries.
37:25.040 --> 37:32.040
But since I wanted it detuned because I want you to make up part of the resonant circuit,
37:32.040 --> 37:36.040
I made this as small as I could get away with.
37:36.040 --> 37:43.040
But I made this as big as I could get away with for current through here.
37:43.040 --> 37:55.040
So the thing about this RF amplifier is this RF amplifier must include the pump wave and the modulating wave.
37:55.040 --> 38:01.040
And you can see right down here at the base, there's a 2.5 millihenry choke.
38:01.040 --> 38:09.040
And that choke then connects over here to the audio amplifier like this.
38:10.040 --> 38:16.040
So when you put the audio frequency in here, this gates this transistor,
38:16.040 --> 38:24.040
which puts a space in between what the oscillator is putting out from the buffer in here.
38:24.040 --> 38:28.040
So it's like it shorts it to ground for a minute and comes back.
38:28.040 --> 38:36.040
So this allows you to generate the side bands, this circuit here and this.
38:37.040 --> 38:43.040
This is how you generate the side bands, by putting the audio frequency in here.
38:43.040 --> 38:49.040
But it's not what I would call an audio frequency from 20 to 20 kilohertz,
38:49.040 --> 38:57.040
because it's 10 kilohertz to 70 kilohertz is how you're going to get right frequencies.
38:57.040 --> 39:02.040
So this amplifier has to be capable of doing 70 kilohertz.
39:03.040 --> 39:09.040
In other words, there can't be anything where it's not the same as if it's doing 10 kilohertz.
39:09.040 --> 39:11.040
It has to be flat.
39:12.040 --> 39:19.040
The next part of the circuit that's very important is the pump wave oscillator.
39:19.040 --> 39:28.040
And if you look at this very closely, the 555 timer sends out a pulse.
39:28.040 --> 39:33.040
It's about 14 hertz. So it's a square wave at 14 hertz.
39:33.040 --> 39:38.040
And turns this transistor on, lets the current go through it.
39:38.040 --> 39:43.040
And of course this piece ends up being connected right here.
39:43.040 --> 39:51.040
Now the limit to not have any of the RF come back through the circuit to the oscillator,
39:51.040 --> 39:55.040
there's a choke here. That's also selected for minimum.
39:55.040 --> 40:01.040
So that when you touch it, you're in resonance.
40:01.040 --> 40:08.040
The 47k resistor limits the current that can go through your body.
40:08.040 --> 40:13.040
Because you only want 2 milliamps or 3 milliamps. You don't want anything more than that.
40:13.040 --> 40:19.040
Because the DC is what allows the frequency to get in.
40:19.040 --> 40:26.040
And this is why this is really not like a Rife machine, it's more like a Peori machine.
40:26.040 --> 40:31.040
And so I call it the Beedini-Rife Peori or whatever you want to call it.
40:31.040 --> 40:38.040
But this is what allows you to get the signal through your body, is this pump wave.
40:38.040 --> 40:48.040
And without this pump wave, then you're at the limit of however far the RF can penetrate in your body.
40:48.040 --> 40:55.040
And that's not going to be very far. Because maybe about 2 inches.
40:55.040 --> 41:02.040
I mean you can change this around and make it more powerful to where it will light a light bulb.
41:02.040 --> 41:10.040
But I'm not into burning anybody, I don't want anybody to get hurt or anything like that by getting an RF burn.
41:10.040 --> 41:15.040
RF burns aren't funny, they're blotches that never go away in your skin.
41:15.040 --> 41:20.040
So that's exactly why I've done the circuit like this.
41:20.040 --> 41:28.040
It's limiting this thing to maybe 1 watt or 2 watts maximum under resonance.
41:28.040 --> 41:35.040
It's 20 volts peak to peak, so I mean it's got plenty of RF.
41:35.040 --> 41:41.040
And the only other thing you could do with this is if you wanted to boost this,
41:41.040 --> 41:46.040
then you'd build an RF amplifier and put it here.
41:46.040 --> 41:51.040
And you would burn yourself up.
41:51.040 --> 41:56.040
You know sooner or later you're going to put too much RF and you're going to feel that.
41:56.040 --> 41:58.040
What is a millihenry?
41:58.040 --> 41:59.040
Millihenry.
41:59.040 --> 42:00.040
Yes.
42:00.040 --> 42:02.040
Millihenrys, they're chokes.
42:02.040 --> 42:07.040
They're in millihenries and microhenries and it would be a choke that being what it is,
42:07.040 --> 42:13.040
is it's wound wire around a ceramic and it becomes an inductor.
42:13.040 --> 42:18.040
And so that inductor is basically sitting right here in the circuit.
42:18.040 --> 42:19.040
Okay.
42:19.040 --> 42:26.040
And then the resistor is sitting right here and then there's another inductor that's sitting right here.
42:26.040 --> 42:32.040
And trimmable capacitors are, you know, they're a little bit different.
42:32.040 --> 42:36.040
They're...
42:36.040 --> 42:42.040
Well, just backing up, an ohm is like a measurement of resistance and a henry is a measurement of capacitance.
42:42.040 --> 42:43.040
Of inductance.
42:43.040 --> 42:44.040
Inductance, bargain.
42:44.040 --> 42:45.040
Yeah.
42:45.040 --> 42:49.040
Anyway, a trimmable capacitor, see, has a...
42:49.040 --> 42:50.040
Tiny, yeah.
42:50.040 --> 42:54.040
Yeah, it's a very tiny thing in the circuit.
42:54.040 --> 43:03.040
And it allows you to adjust the capacitance and that's why you see, you know, these arrows through these capacitors.
43:03.040 --> 43:10.040
And these are actually sitting in the circuit like this.
43:10.040 --> 43:13.040
Mm-hmm. Yeah.
43:13.040 --> 43:19.040
So see, usually when I draw things, it's the circuit the way I'm going to lay it out.
43:19.040 --> 43:20.040
Yeah.
43:20.040 --> 43:22.040
Exactly the way I'm going to lay it out.
43:22.040 --> 43:23.040
Okay.
43:23.040 --> 43:26.040
So basically your pump wave looks like this.
43:26.040 --> 43:31.040
It comes on at zero, goes up to its 12 or 11.5 volts.
43:31.040 --> 43:42.040
And then this, the RF oscillator, you know, this pump wave, when it starts to pump this, it ends up here with a DC pulse.
43:42.040 --> 43:52.040
And what ends up on the DC pulse is...
43:52.040 --> 43:57.040
This.
43:57.040 --> 43:59.040
Which are the side bands.
43:59.040 --> 44:00.040
Okay.
44:00.040 --> 44:03.040
And so now it's on the DC.
44:03.040 --> 44:09.040
And that's how you get it in there. That's how you get it into the body.
44:09.040 --> 44:15.040
John, could you just read off the values on the pump wave circuit? One of them is a little bit small.
44:15.040 --> 44:17.040
Okay.
44:17.040 --> 44:24.040
The 12-volt line, okay, this capacitor right here is .47.
44:24.040 --> 44:25.040
.47, is it?
44:25.040 --> 44:26.040
Yeah.
44:26.040 --> 44:27.040
Okay.
44:27.040 --> 44:32.040
And then there's 100 ohms, 10k, and 4.7 microfarads.
44:32.040 --> 44:33.040
Right. Yeah, got it.
44:33.040 --> 44:37.040
And that sets you at about 14 hertz.
44:37.040 --> 44:45.040
And then the transistor, just a garden variety, 2N4401 or 2N2222,
44:45.040 --> 44:51.040
where the current's coming out of the emitter and then going up to the 47k and through the 22...
44:51.040 --> 44:52.040
Yeah.
44:52.040 --> 45:02.040
...microhenry choke. And a 22-microhenry choke, you can get them on the Internet, and you can see that they're not very big.
45:02.040 --> 45:04.040
Uh-huh, yeah.
45:04.040 --> 45:08.040
And that's actually sitting right here, across here.
45:08.040 --> 45:10.040
Okay.
45:10.040 --> 45:13.040
Of course, this being the bigger one, and then another 22 here.
45:13.040 --> 45:14.040
Right.
45:14.040 --> 45:17.040
These two are kept the same.
45:17.040 --> 45:32.040
Now, this 2.5 millihenries blocks the RF, because the RF amplifier is getting RF from the buffer circuit, see?
45:32.040 --> 45:42.040
So it blocks the RF going back into the audio circuit, so you only push forward.
45:42.040 --> 45:45.040
That's a good way to say that.
45:45.040 --> 45:50.040
And that 22 is sort of a big part.
45:50.040 --> 45:52.040
Right.
45:52.040 --> 45:54.040
And that would go right there.
45:54.040 --> 45:57.040
Yeah, okay.
45:57.040 --> 46:06.040
So that's pretty big for the circuit, and that's what's blocking the RF, allowing the audio to get gated.
46:06.040 --> 46:15.040
And so what's happening is the audio is gating this RF transistor off and on, to produce the sidebands.
46:15.040 --> 46:17.040
It's actually distorting the wave.
46:17.040 --> 46:19.040
Okay.
46:19.040 --> 46:25.040
You know, which, if you were to watch it, it wouldn't look perfect. It would be distorted.
46:25.040 --> 46:26.040
Yeah.
46:26.040 --> 46:31.040
So that's the basic functioning of the whole circuit.
46:31.040 --> 46:43.040
I mean, if you put this together, and you have a spectrum analyzer, and you have a sweep generator, and you program it, you're going to get exactly what we just showed you.
46:43.040 --> 46:44.040
Yeah.
46:44.040 --> 47:13.040
First of all, I'm going to explain to everybody that I'm not a medical doctor, and that you build this machine, or you, from my research work, which I'm presenting on this film, and that I make no guarantee at all for anything that you do or you do to anybody else.
47:13.040 --> 47:14.040
If you build this.
47:14.040 --> 47:16.040
So you make no claims on this machine?
47:16.040 --> 47:18.040
I make no claims whatsoever.
47:18.040 --> 47:28.040
But I want to also explain to everybody that this is not your normal rife machine.
47:28.040 --> 47:30.040
This is a mixture.
47:30.040 --> 47:57.040
This is a machine from my research work, which indicates that it works far better with a pump wave involved in it, and that's a small DC current that's pumped that allows the frequencies to actually get into your body, where rife's machine, you had to be within so many inches of your body with a tube.
47:57.040 --> 48:05.040
And for the RF then to penetrate you, you have to have power in wattage.
48:05.040 --> 48:17.040
So rife's machine was 50 watts max, until he hired the new engineer, and they started to bring it up.
48:17.040 --> 48:18.040
That was Hoyland, was it?
48:18.040 --> 48:27.040
Yeah, Hoyland, and I think the highest I would, you know, 400 watts is a lot to be putting into a ray tube.
48:27.040 --> 48:33.040
Now, the other thing is that you don't need the ray tube.
48:33.040 --> 48:38.040
It doesn't make any difference how you get the RF into you.
48:38.040 --> 48:44.040
So I'm in disagreement with a lot of things, like power and everything else.
48:44.040 --> 48:58.040
For the simple fact is I always worked in milliamps and microampers with my machines and got results by using electrodes.
48:58.040 --> 49:07.040
So it's not that John Crane's, I want to make it known, that it's not that John's Crane machine wouldn't have worked.
49:07.040 --> 49:14.040
It would have worked if he would have had that fundamental frequency and he could have gotten the sidebands.
49:14.040 --> 49:15.040
In your opinion?
49:15.040 --> 49:33.040
No, in true reality you need the sidebands, because as you will see in this DVD, if you're watching it now,
49:33.040 --> 49:42.040
you will see how the sidebands appear on the spectrum analyzer and exactly what's happening.
49:42.040 --> 50:00.040
And the other thing that I'm going to point out is nobody really knows, because there really isn't a record of who got cured and how long that cure lasted with a rifle or anything.
50:00.040 --> 50:06.040
Nobody's, you know, with a Peore machine, there are records.
50:06.040 --> 50:13.040
You know, you can research those records and it was documented very well because it was done by the French.
50:13.040 --> 50:14.040
Right.
50:14.040 --> 50:16.040
Yeah, and they're on Tom Bearden's website.
50:16.040 --> 50:17.040
Yes.
50:17.040 --> 50:22.040
They're on Tom Bearden's website, all those papers.
50:22.040 --> 50:37.040
And my discussion on this machine is basically my research in how I combine the two machines together to form a new machine.
50:37.040 --> 50:50.040
And the other thing is that I'm not so common, you know, when it comes to complicated stuff.
50:50.040 --> 50:52.040
I don't like complicated stuff.
50:52.040 --> 51:01.040
So I like to simplify the circuit as much as possible because you only, all you need is the effect.
51:01.040 --> 51:12.040
And that effect you will see as you get into this DVD is it will produce the sidebands that it needs to produce.
51:12.040 --> 51:14.040
And that's all you need.
51:14.040 --> 51:25.040
Now, the next thing you need is you need to get this into the cells because I have to agree with Tom Bearden on this.
51:26.040 --> 51:31.040
Let me give you an explanation of me.
51:31.040 --> 51:32.040
Okay.
51:32.040 --> 51:36.040
When it comes to electronic circuits.
51:36.040 --> 51:44.040
I'm not one that likes complicated circuits.
51:44.040 --> 51:49.040
I feel that you can reduce everything to simplicity.
51:49.040 --> 52:01.040
In other words, as long as you achieve the results, as long as the scope showing you the results, as long as the analyzer showing you the results.
52:01.040 --> 52:12.040
And mysteriously, if the results work, then why do you need something that's so complicated?
52:12.040 --> 52:18.040
There are machines out there that are so difficult to build that nobody could build them.
52:18.040 --> 52:27.040
And if we really think about it today, we can do things with oscillators that we can program ourselves.
52:27.040 --> 52:31.040
We can do things with the transistors that we got.
52:31.040 --> 52:37.040
And so I'm not one that's going to make a very complicated circuit.
52:37.040 --> 52:41.040
And I want everybody to understand that I'm going to reduce it to its simplest form.
52:41.040 --> 52:47.040
So that it becomes to where anybody can make it.
52:47.040 --> 52:56.040
In other words, I would prefer that you had skills, and I would prefer that you had the equipment to check it.
52:56.040 --> 53:01.040
Otherwise, you're just stabbing in the dark.
53:01.040 --> 53:07.040
Or buy it from somebody that's going to make it, that has tested it.
53:07.040 --> 53:14.040
So the final thing here is the batteries for this unit.
53:14.040 --> 53:28.040
And I'm going to say this, that I would prefer that where the battery is concerned, that you use a lithium iron phosphate.
53:28.040 --> 53:38.040
A lithium iron phosphate battery, you can buy it at Home Depot or any garden center that sells solar lights.
53:38.040 --> 53:41.040
Now these have to be one amp hour each.
53:41.040 --> 53:47.040
I would prefer that you use four of these batteries.
53:47.040 --> 53:50.040
They're 3.2 volts each.
53:50.040 --> 53:57.040
And then you're going to get up to the 12 volts that you need to operate this machine, and it's going to run for a long time.
53:57.040 --> 54:04.040
Because, as I said, I'm not one that uses massive currents.
54:04.040 --> 54:08.040
I'm looking for the results on the analyzers.
54:08.040 --> 54:16.040
So with that said, I'm going to get into the charger for it, which is an LM317.
54:16.040 --> 54:22.040
Now these are adjustable voltage regulators.
54:22.040 --> 54:28.040
And I've fixed this one where I want these batteries to be.
54:28.040 --> 54:33.040
So if you look here very closely, there's a diode right here.
54:33.040 --> 54:35.040
This is very important.
54:35.040 --> 54:43.040
If you do not put this in, thinking you can just run the regulator to charge the batteries.
54:43.040 --> 54:48.040
And you disconnect the transformer that's charging them.
54:48.040 --> 54:52.040
When you come back tomorrow, the batteries are going to be dead.
54:52.040 --> 54:57.040
And then you're going to be replacing these. You don't want to run these to zero.
54:57.040 --> 55:03.040
When you run this type battery to zero, you run the risk.
55:03.040 --> 55:06.040
In other words, you run it right down to zero.
55:06.040 --> 55:15.040
You run the risk of this cell will not operate after that.
55:15.040 --> 55:24.040
Now the reason that you don't really run it to zero in a solar light when they put them in there is because the LED is at 2.8 volts.
55:24.040 --> 55:32.040
So the minute there isn't enough voltage to run the LED, you're not drawing anything from the battery.
55:32.040 --> 55:35.040
So that's the little trick there.
55:35.040 --> 55:41.040
So you absolutely need this diode in the circuit if you're going to make this charging circuit.
55:41.040 --> 55:50.040
And you absolutely need 18 volts DC so that this regulator can operate.
55:50.040 --> 55:57.040
And the max charge that you want to put on this battery is 14.80.
55:57.040 --> 56:03.040
So I've chosen some resistors here that will get you exactly in the ballpark.
56:03.040 --> 56:06.040
So you've got a 20 ohm here and a 3.1 K here.
56:06.040 --> 56:09.040
Now this is sort of an oddball resistor.
56:09.040 --> 56:16.040
You just don't go to Radio Shack and buy a 3.1 K resistor unless they have them in percentages.
56:16.040 --> 56:19.040
You're going to need to order that resistor.
56:19.040 --> 56:23.040
And you're going to need to find a heat sink for this.
56:23.040 --> 56:27.040
Because when you put the 18 volts, it's going to heat up.
56:27.040 --> 56:30.040
It's thermal protected and it's current protected.
56:30.040 --> 56:37.040
So if a short happens here in the battery, this will protect itself.
56:37.040 --> 56:40.040
But it's mandatory for the diode.
56:40.040 --> 56:44.040
Or you're just not going to be able to charge this machine.
56:44.040 --> 56:48.040
And that's what I want to say on the charger.
56:50.040 --> 56:56.040
Okay, so what I want to bring up here, Pat, is Peori.
56:56.040 --> 56:58.040
Okay.
56:58.040 --> 57:02.040
As I said, he is the most documented.
57:02.040 --> 57:05.040
It's on the Tom Bearden website.
57:05.040 --> 57:07.040
Anybody can read this information.
57:07.040 --> 57:17.040
I mean, when the military gets involved in healing devices,
57:17.040 --> 57:20.040
then you know that something's working.
57:20.040 --> 57:23.040
Yeah, well the U.S. Office of Naval Intelligence went over there
57:23.040 --> 57:26.040
and wrote a report on it, which is on the Tom Bearden website.
57:26.040 --> 57:27.040
Right, exactly.
57:27.040 --> 57:31.040
In 1978, I believe it was, wasn't it? Thereabouts.
57:31.040 --> 57:35.040
And the French Academy of Sciences were behind it.
57:35.040 --> 57:41.040
The mayor of Bordeaux laid the cornerstone for the facility.
57:41.040 --> 57:44.040
And then he got to be Premier of France, Jacques-Chalbon Desmas,
57:44.040 --> 57:47.040
and he opened up the Peori facility.
57:47.040 --> 57:49.040
The Premier of France opened up the facility.
57:49.040 --> 57:52.040
So this was not inconsequential.
57:52.040 --> 57:57.040
And France's, the permanent secretary of the Academy of Sciences
57:57.040 --> 58:02.040
sponsored it, and France's leading immunologist did the tests
58:02.040 --> 58:05.040
on the rats and rabbits and whatever.
58:05.040 --> 58:16.040
Exactly. Now, see, technically, this really is not a right machine.
58:16.040 --> 58:26.040
It's using Reif's, Hoylan's sideband frequencies,
58:26.040 --> 58:28.040
but think about this just for a second.
58:28.040 --> 58:35.040
Peori was mixing all these different microwaves together in this gas tube,
58:35.040 --> 58:44.040
which did the exact same thing that Hoylan was doing with the sidebands.
58:44.040 --> 58:53.040
And the thing about Peori is he could penetrate the cells perfectly
58:53.040 --> 58:56.040
because of the rippling magnetic field,
58:56.040 --> 59:02.040
which that magnetic field gathered those frequencies and sent it through your body.
59:02.040 --> 59:05.040
And this was my discussion with Tom Bearden,
59:05.040 --> 59:14.040
that the pump wave is a very important piece of this whole thing.
59:14.040 --> 59:20.040
And as I was saying in the beginning, I like to simplify things.
59:20.040 --> 59:26.040
I like to have a simple oscillator that's doing just what it needs to do.
59:26.040 --> 59:30.040
I like to have a simple buffer that's doing just what it needs to do.
59:30.040 --> 59:32.040
I like to have a simple audio circuit,
59:32.040 --> 59:37.040
which is in Class A that's just doing what it needs to do.
59:37.040 --> 59:41.040
And I like to have a simple RF amplifier and a simple pump wave oscillator.
59:41.040 --> 59:46.040
And it's very important that before we get into our discussion
59:46.040 --> 59:52.040
that everybody understands this, that we need to simplify this.
59:52.040 --> 59:57.040
This has to be something that you can have, you know, that you can make.
59:57.040 --> 01:00:01.040
And if you need to charge it with a solar, then you charge it with solar.
01:00:01.040 --> 01:00:05.040
If you need to charge it by the wall, you charge it by the wall.
01:00:05.040 --> 01:00:15.040
But what you do not want to have to do is try to adjust things like in Reif's machine,
01:00:15.040 --> 01:00:20.040
where nobody knew exactly what the frequency was.
01:00:20.040 --> 01:00:22.040
They had to sweep the frequency back and forth.
01:00:22.040 --> 01:00:25.040
And that's the other thing.
01:00:25.040 --> 01:00:27.040
It's the sweep generator.
01:00:27.040 --> 01:00:33.040
And, Michael, can you hand me that blue generator that's on the bench there?
01:00:33.040 --> 01:00:39.040
This is a very important piece of equipment, and it's only like $127.
01:00:39.040 --> 01:00:48.040
And you set this thing to sweep, you know, from 10 kilohertz to 70 kilohertz,
01:00:48.040 --> 01:00:56.040
then you know that you are hitting all these sidebands that hit the viruses and the bacteria.
01:00:56.040 --> 01:01:01.040
Anyway, now that we understand, you know, what this thing is going to be,
01:01:01.040 --> 01:01:06.040
that not only was the rippling magnetic field very important,
01:01:06.040 --> 01:01:15.040
but Peori discovered aboard ship that there was some fruit laying next to a microwave dish.
01:01:15.040 --> 01:01:20.040
And when they were running the microwave, that fruit never rotted aboard the ship.
01:01:21.040 --> 01:01:28.040
So it must have killed all the bacteria, and I can understand where he took it from there.
01:01:28.040 --> 01:01:31.040
And, Tony, do you have anything to add to that?
01:01:31.040 --> 01:01:36.040
Not really. I think he was a radar operator in World War II,
01:01:36.040 --> 01:01:42.040
and they stored the vegetables up behind all the electronic electrical equipment.
01:01:42.040 --> 01:01:45.040
And as you said, that's where it came from.
01:01:45.040 --> 01:01:48.040
And he was also a member of the French Resistance,
01:01:48.040 --> 01:01:53.040
as was the future of Mayor Bordeaux, who got to be Premier of France.
01:01:53.040 --> 01:01:55.040
So they were kind of buddies.
01:01:55.040 --> 01:02:00.040
And because of that, he got a lot of backing from the government
01:02:00.040 --> 01:02:05.040
when Jacques-Charles Bondemar was voted into either, first of all, Mayor of Bordeaux,
01:02:05.040 --> 01:02:08.040
and then Premier of France.
01:02:08.040 --> 01:02:11.040
And it's worth noting that Peori wrote a PhD on this.
01:02:11.040 --> 01:02:15.040
It's on Tom Bearden's website, and he also had two U.S. patents on it.
01:02:15.040 --> 01:02:17.040
So this is not a big secret.
01:02:17.040 --> 01:02:18.040
Oh, no.
01:02:18.040 --> 01:02:22.040
We got slaughtered when we got on the Peori thing.
01:02:22.040 --> 01:02:25.040
We really got slaughtered.
01:02:25.040 --> 01:02:29.040
And that's how that all got broken up.
01:02:29.040 --> 01:02:32.040
They ran Bob right out of the country to save his life.
01:02:32.040 --> 01:02:36.040
He fled to keep his life, and tore everything we were doing up.
01:02:36.040 --> 01:02:40.040
And obviously they didn't want that Peori thing gone at all.
01:02:40.040 --> 01:02:42.040
They called these doctors that were going to fund it.
01:02:42.040 --> 01:02:47.040
We had $16 million funding already pledged by some very wealthy doctors
01:02:47.040 --> 01:02:51.040
that knew this was real because he had cured cancer,
01:02:51.040 --> 01:02:55.040
and put it in the hard French literature,
01:02:55.040 --> 01:02:59.040
and replicated by other scientists working with him.
01:02:59.040 --> 01:03:03.040
So strange people called all these doctors up and said,
01:03:03.040 --> 01:03:07.040
you know, if you put one penny in this,
01:03:07.040 --> 01:03:10.040
you and every member of your family will be killed, you know,
01:03:10.040 --> 01:03:11.040
and includes the children.
01:03:11.040 --> 01:03:15.040
If you think we're kidding, tell us which child you want to kill first.
01:03:15.040 --> 01:03:19.040
So in the space of two weeks, we didn't have any backing.
01:03:19.040 --> 01:03:23.040
We already had reached an agreement with Peori.
01:03:23.040 --> 01:03:26.040
So we didn't get to do it.
01:03:26.040 --> 01:03:29.040
Peori later had a stroke.
01:03:29.040 --> 01:03:32.040
He spent the last two years of his life, you know,
01:03:32.040 --> 01:03:35.040
basically out of it and helpless and then died.
01:03:35.040 --> 01:03:41.040
See, most people can't do this unless they have some kind of research funds.
01:03:41.040 --> 01:03:47.040
In other words, it's very important, even if you're a garage mechanic,
01:03:47.040 --> 01:03:49.040
and you think you're going to do some kind of invention,
01:03:49.040 --> 01:03:51.040
what's the first thing you always run out of?
01:03:51.040 --> 01:03:53.040
Money.
01:03:53.040 --> 01:03:56.040
So you just have to stop your project.
01:03:56.040 --> 01:04:00.040
But I've been pretty fortunate in all this, you know,
01:04:00.040 --> 01:04:07.040
to receive grants and different funds to do all this.
01:04:07.040 --> 01:04:11.040
And so I accomplished it.
01:04:11.040 --> 01:04:15.040
You know, otherwise I wouldn't have been able to do it.
01:04:15.040 --> 01:04:22.040
And so I just want everybody to remember that if they build this,
01:04:22.040 --> 01:04:26.040
that it just takes a little bit of money to do the research.
01:04:26.040 --> 01:04:31.040
Yeah, and Peori was fortunate because the World Health Organization provided money for this,
01:04:31.040 --> 01:04:33.040
as did the French military.
01:04:33.040 --> 01:04:36.040
Right. Where Reif...
01:04:36.040 --> 01:04:37.040
He didn't have anything like that.
01:04:37.040 --> 01:04:38.040
Well, he had bridges.
01:04:38.040 --> 01:04:39.040
Yeah, okay.
01:04:39.040 --> 01:04:42.040
He had Timken Roller bearing in the beginning.
01:04:42.040 --> 01:04:47.040
But as the people infiltrated into his lab,
01:04:47.040 --> 01:04:50.040
things started to change around and change around and change around.
01:04:50.040 --> 01:04:53.040
And I don't think Reif said a couple...
01:04:53.040 --> 01:04:56.040
I don't think Reif was really into, you know,
01:04:56.040 --> 01:05:02.040
wanting to build a machine unless every one of these machines was tested by him in his laboratory.
01:05:02.040 --> 01:05:03.040
Yeah.
01:05:03.040 --> 01:05:05.040
Under his microscope.
01:05:05.040 --> 01:05:07.040
Now think about this.
01:05:07.040 --> 01:05:10.040
How many microscopes did he build? About three.
01:05:10.040 --> 01:05:13.040
You know, some worked.
01:05:13.040 --> 01:05:15.040
Some people had trouble with them.
01:05:15.040 --> 01:05:18.040
There's one in the Smithonian Institute.
01:05:18.040 --> 01:05:22.040
Why isn't that up and operating and we can view it?
01:05:22.040 --> 01:05:25.040
So what's actually missing?
01:05:25.040 --> 01:05:28.040
You know, now I do know...
01:05:28.040 --> 01:05:30.040
I'm not allowed to give the name,
01:05:30.040 --> 01:05:34.040
but I do know of a person that reconstructed the microscope and it does work.
01:05:34.040 --> 01:05:36.040
So I can say that here.
01:05:36.040 --> 01:05:37.040
Yeah.
01:05:37.040 --> 01:05:40.040
This is important to do the lab trials.
01:05:40.040 --> 01:05:41.040
Yes.
01:05:41.040 --> 01:05:44.040
Of which I can't do because I'm not a medical doctor
01:05:44.040 --> 01:05:49.040
and I don't, you know, attend some university where they have all this stuff.
01:05:49.040 --> 01:05:54.040
And I think even if I did, the work would be buried.
01:05:54.040 --> 01:05:57.040
But Strecker did it, didn't he?
01:05:57.040 --> 01:06:00.040
Yeah, Dr. Strecker...
01:06:00.040 --> 01:06:04.040
Dr. Strecker was very interested in the microscope
01:06:04.040 --> 01:06:09.040
and, you know, being able to kill viruses with frequencies.
01:06:09.040 --> 01:06:11.040
And as I...
01:06:11.040 --> 01:06:13.040
And as I...
01:06:13.040 --> 01:06:20.040
You'll find out later in this movie or this film
01:06:20.040 --> 01:06:26.040
that Dr. Strecker had to put up with a lot like I did with John Crane
01:06:26.040 --> 01:06:32.040
because John Crane really did not have all the answers.
01:06:32.040 --> 01:06:35.040
You know, and it was more or less...
01:06:35.040 --> 01:06:41.040
Reif said things to him, but if John Crane would have had the answers,
01:06:41.040 --> 01:06:44.040
then he would have never...
01:06:44.040 --> 01:06:47.040
Reif would have never allowed him
01:06:47.040 --> 01:06:52.040
to just sell a frequency generator that you bought off the shelf.
01:06:52.040 --> 01:06:54.040
That wouldn't have been...
01:06:54.040 --> 01:06:56.040
What do you mean, if he had the answers?
01:06:56.040 --> 01:06:58.040
If Reif would have known...
01:06:58.040 --> 01:06:59.040
Yeah.
01:06:59.040 --> 01:07:03.040
Exactly what the secret to the machine was
01:07:03.040 --> 01:07:05.040
and understood it,
01:07:05.040 --> 01:07:08.040
then John Crane would have never been able to.
01:07:08.040 --> 01:07:09.040
Okay.
01:07:09.040 --> 01:07:12.040
Reif would have just walked away from the deal.
01:07:12.040 --> 01:07:18.040
Because to sell frequency generators off the shelf
01:07:18.040 --> 01:07:22.040
is nutty, in a way.
01:07:22.040 --> 01:07:25.040
So I think that's what I have to say, Tony.
01:07:25.040 --> 01:07:28.040
And they can view the DVD.
01:07:28.040 --> 01:07:30.040
We've decided to move over
01:07:30.040 --> 01:07:34.040
because we're going to be looking at what the original wave looked like
01:07:34.040 --> 01:07:36.040
that Reif used,
01:07:36.040 --> 01:07:40.040
and then we're going to be looking at the sideband...
01:07:40.040 --> 01:07:41.040
Oh, this should be...
01:07:41.040 --> 01:07:45.040
Yeah, on the spectrum analyzer so we can see all this.
01:07:45.040 --> 01:07:49.040
So anyway, if you look at this wave,
01:07:49.040 --> 01:07:52.040
it sort of looks like a square wave, you notice that?
01:07:52.040 --> 01:07:53.040
Yes.
01:07:53.040 --> 01:07:55.040
But it's not a square wave.
01:07:55.040 --> 01:07:58.040
You know, this was actually made up from sine waves.
01:07:58.040 --> 01:08:02.040
All right, so let's go up here and look at what it was.
01:08:02.040 --> 01:08:07.040
This is actually the sine wave that's coming from this oscillator,
01:08:07.040 --> 01:08:10.040
and this is what it's producing with the gating.
01:08:10.040 --> 01:08:11.040
Okay.
01:08:11.040 --> 01:08:13.040
It's automatic when you modulate this.
01:08:13.040 --> 01:08:15.040
Whose oscillator is this? Is this Reif's?
01:08:15.040 --> 01:08:17.040
This is Reif. This is a...
01:08:17.040 --> 01:08:21.040
It's a coil, and basically this is the schoon machine,
01:08:21.040 --> 01:08:24.040
the Auburn schoon machine,
01:08:24.040 --> 01:08:27.040
that is a copy of the Reif machine.
01:08:27.040 --> 01:08:31.040
This is not the original, but it's doing the same thing,
01:08:31.040 --> 01:08:33.040
and it had the correct frequency.
01:08:33.040 --> 01:08:38.040
All right, now, one thing that I want to explain that...
01:08:40.040 --> 01:08:45.040
Richard Hoylen used three different frequencies.
01:08:45.040 --> 01:08:51.040
He used, see, 3.8 megahertz, and then he used 3.3,
01:08:51.040 --> 01:08:56.040
and I think he used 3.1-something on a later version.
01:08:56.040 --> 01:09:02.040
And, of course, Crane changed all that to 4.8 or 4.6.
01:09:02.040 --> 01:09:03.040
Why did he do that?
01:09:03.040 --> 01:09:10.040
Well, he did it for the simple fact that he didn't want to interfere
01:09:10.040 --> 01:09:12.040
in the 3 megahertz band.
01:09:12.040 --> 01:09:13.040
Okay.
01:09:13.040 --> 01:09:17.040
You know, so anyway, here's the original oscillator
01:09:17.040 --> 01:09:19.040
and the way that it looked.
01:09:19.040 --> 01:09:22.040
So you can see here...
01:09:22.040 --> 01:09:23.040
Yeah?
01:09:23.040 --> 01:09:25.040
That it's not an absolute clean wave.
01:09:25.040 --> 01:09:26.040
Right.
01:09:26.040 --> 01:09:27.040
Right.
01:09:27.040 --> 01:09:29.040
Today we can do far better than that,
01:09:29.040 --> 01:09:32.040
and the bands are much cleaner and everything,
01:09:32.040 --> 01:09:35.040
but this is a working machine.
01:09:35.040 --> 01:09:37.040
This machine actually worked.
01:09:37.040 --> 01:09:40.040
And see, when they did the sideband,
01:09:40.040 --> 01:09:42.040
these are your sidebands.
01:09:42.040 --> 01:09:43.040
Oh, yeah.
01:09:43.040 --> 01:09:45.040
Okay.
01:09:45.040 --> 01:09:48.040
But with the piece of equipment that I have over there,
01:09:48.040 --> 01:09:52.040
the DS-8, 815, we're going to see it much clearer.
01:09:52.040 --> 01:09:53.040
Okay.
01:09:53.040 --> 01:09:54.040
Okay.
01:09:54.040 --> 01:09:58.040
So I'm hoping that I've answered that,
01:09:58.040 --> 01:10:01.040
but let's go to the sideband calculator now.
01:10:05.040 --> 01:10:12.040
This can only be gotten online at the Rife group.
01:10:12.040 --> 01:10:13.040
Okay.
01:10:13.040 --> 01:10:16.040
So you're going to have to search through a lot of stuff to get it,
01:10:16.040 --> 01:10:19.040
but it's actually downloadable once you join the group.
01:10:19.040 --> 01:10:21.040
Anyway, you can see down here it says,
01:10:21.040 --> 01:10:25.040
input your carrier frequency.
01:10:25.040 --> 01:10:29.040
And see, it's got everything that's known to date
01:10:29.040 --> 01:10:34.040
that we have a number on in our system.
01:10:34.040 --> 01:10:36.040
So I'm going to change this carrier frequency
01:10:36.040 --> 01:10:40.040
to where my fundamental is, which is 31,
01:10:40.040 --> 01:10:44.040
and to where the end of my sweep generator is going to go out,
01:10:44.040 --> 01:10:47.040
which is 70,000.
01:10:47.040 --> 01:10:49.040
Because I want to cover a lot.
01:10:49.040 --> 01:10:50.040
Okay.
01:10:50.040 --> 01:10:52.040
I want to make sure that I can cover everything.
01:10:52.040 --> 01:10:53.040
Okay.
01:10:53.040 --> 01:10:55.040
And then I'm going to tell it to calculate,
01:10:55.040 --> 01:10:56.040
and these numbers change.
01:10:56.040 --> 01:10:57.040
Oh, yeah, I see that.
01:10:57.040 --> 01:10:58.040
You saw that change.
01:10:58.040 --> 01:11:03.040
So now if I go look at cancer right here, the BX virus,
01:11:03.040 --> 01:11:05.040
it's saying that Rife's,
01:11:05.040 --> 01:11:10.040
Rife's original frequency was 1,607.450.
01:11:10.040 --> 01:11:12.040
All right?
01:11:12.040 --> 01:11:17.040
And it says that the frequency that I'm going to be looking for
01:11:17.040 --> 01:11:23.040
on the analyzer is going to be 321,400,
01:11:23.040 --> 01:11:26.040
plus or minus, you know, one meter.
01:11:26.040 --> 01:11:28.040
Right.
01:11:28.040 --> 01:11:29.040
Which is cycles.
01:11:29.040 --> 01:11:31.040
So maybe a couple hundred cycles.
01:11:31.040 --> 01:11:33.040
Right?
01:11:33.040 --> 01:11:36.040
So now if we click on this,
01:11:36.040 --> 01:11:39.040
and we go to the graph
01:11:39.040 --> 01:11:41.040
for the audio signal that we're going to input,
01:11:41.040 --> 01:11:44.040
which is, by the way, Nadi, you couldn't hear this.
01:11:44.040 --> 01:11:49.040
It's at 57,450, see?
01:11:49.040 --> 01:11:51.040
That's way above the hearing range.
01:11:51.040 --> 01:11:53.040
But the machine can hear it.
01:11:53.040 --> 01:11:57.040
So now we open this up.
01:11:57.040 --> 01:12:00.040
We can see where we're generating our waves.
01:12:00.040 --> 01:12:02.040
This is what the oscillator's actually doing,
01:12:02.040 --> 01:12:04.040
although we're going to use a square wave,
01:12:04.040 --> 01:12:06.040
which is going to come out like this anyway.
01:12:06.040 --> 01:12:10.040
And it says that what I've chosen,
01:12:10.040 --> 01:12:12.040
I'm going to be at the second band.
01:12:12.040 --> 01:12:14.040
Okay.
01:12:14.040 --> 01:12:17.040
And when I hit the second band is when I hit that cancer virus.
01:12:17.040 --> 01:12:19.040
Okay.
01:12:19.040 --> 01:12:21.040
Now watch.
01:12:21.040 --> 01:12:23.040
If I go back,
01:12:23.040 --> 01:12:26.040
X that out, and I choose something different like anthrax.
01:12:26.040 --> 01:12:30.040
See, it's still this carrier frequency remains the same,
01:12:30.040 --> 01:12:34.040
and still the sweep generator remains going from 10,000 to 70,000.
01:12:34.040 --> 01:12:37.040
Okay.
01:12:37.040 --> 01:12:41.040
And then I just hit that, hit the graph.
01:12:41.040 --> 01:12:43.040
You can see.
01:12:43.040 --> 01:12:45.040
Oh, it goes on the other side.
01:12:45.040 --> 01:12:47.040
It's on the other side.
01:12:47.040 --> 01:12:49.040
See, it doesn't make any difference.
01:12:49.040 --> 01:12:53.040
When we talk about generating these harmonics, right,
01:12:53.040 --> 01:12:56.040
you don't want to have your machine
01:12:56.040 --> 01:12:58.040
putting the correct frequency way out here,
01:12:58.040 --> 01:13:00.040
because see, there's no power.
01:13:00.040 --> 01:13:02.040
Okay.
01:13:02.040 --> 01:13:06.040
The power goes up on sort of a linear scale, not quite.
01:13:06.040 --> 01:13:08.040
Mm-hmm.
01:13:08.040 --> 01:13:11.040
But you want to get it...
01:13:11.040 --> 01:13:13.040
So you want to make it on the outside or maybe the both at the outside.
01:13:13.040 --> 01:13:17.040
Yes, you want to get it as close to the fundamental as you can,
01:13:17.040 --> 01:13:19.040
because that's the most power.
01:13:19.040 --> 01:13:21.040
Yeah.
01:13:21.040 --> 01:13:23.040
All right, so let's look at a couple more,
01:13:23.040 --> 01:13:27.040
and then we'll turn around and spin at the analyzer and work with it.
01:13:27.040 --> 01:13:30.040
Okay, so let's go down to tetanus,
01:13:30.040 --> 01:13:33.040
and I always make it calculate over.
01:13:33.040 --> 01:13:37.040
So, okay, so now see, tetanus is up here, too.
01:13:37.040 --> 01:13:39.040
Mm-hmm.
01:13:39.040 --> 01:13:42.040
You see, and it says that...
01:13:42.040 --> 01:13:44.040
So the...
01:13:44.040 --> 01:13:49.040
Why everybody chose 3100 is it gives you the most power in this band.
01:13:49.040 --> 01:13:51.040
Okay, okay.
01:13:51.040 --> 01:13:53.040
Yeah, you see what I'm saying?
01:13:53.040 --> 01:13:55.040
Fundamental is rock solid. It's not going to move.
01:13:55.040 --> 01:13:57.040
Yeah.
01:13:57.040 --> 01:14:00.040
So we don't...you don't care about that.
01:14:00.040 --> 01:14:04.040
So let's go look at something else like typhoid, the rod.
01:14:04.040 --> 01:14:06.040
Mm-hmm.
01:14:10.040 --> 01:14:14.040
See? It's also showing it's up high.
01:14:14.040 --> 01:14:16.040
Okay.
01:14:16.040 --> 01:14:18.040
And it says rod.
01:14:18.040 --> 01:14:21.040
And it says, if we look on the spectrum analyzer,
01:14:21.040 --> 01:14:26.040
this is the frequency we're looking for, 3037.800.
01:14:26.040 --> 01:14:28.040
And that's still one meter on that.
01:14:28.040 --> 01:14:31.040
Yeah, yeah. I mean, we can be...
01:14:31.040 --> 01:14:35.040
Since we're sweeping, these are not going to be stationary like this.
01:14:35.040 --> 01:14:37.040
They're going to be changing.
01:14:37.040 --> 01:14:39.040
Yeah.
01:14:39.040 --> 01:14:41.040
So eventually we're going to hit that.
01:14:41.040 --> 01:14:44.040
All right, so let's get one that sort of changes for them.
01:14:44.040 --> 01:14:47.040
See, it says it's in the first place here.
01:14:47.040 --> 01:14:50.040
Let's go on and show you a little bit less power,
01:14:50.040 --> 01:14:52.040
which is the tuberculosis rod.
01:14:52.040 --> 01:14:54.040
Now, these are the only two.
01:14:54.040 --> 01:14:56.040
Mm-hmm.
01:14:56.040 --> 01:14:59.040
Tuberculosis rod and tuberculosis virus.
01:14:59.040 --> 01:15:03.040
Reif said that once you kill the rod...
01:15:03.040 --> 01:15:05.040
Mm-hmm.
01:15:05.040 --> 01:15:09.040
If you do not kill the virus, the patient will go into toxemia.
01:15:09.040 --> 01:15:11.040
Okay.
01:15:11.040 --> 01:15:15.040
Because the virus will use the rod as food.
01:15:15.040 --> 01:15:17.040
Okay.
01:15:17.040 --> 01:15:19.040
Its waste material is going to kill you.
01:15:19.040 --> 01:15:21.040
Yeah.
01:15:21.040 --> 01:15:24.040
All right, so let's look at it, where it is.
01:15:24.040 --> 01:15:28.040
Now, see, it's down in the power band.
01:15:28.040 --> 01:15:32.040
So, by the way, by changing this fundamental frequency pattern...
01:15:32.040 --> 01:15:34.040
Mm-hmm.
01:15:34.040 --> 01:15:37.040
You can actually move this up or move it down.
01:15:37.040 --> 01:15:39.040
Okay.
01:15:39.040 --> 01:15:42.040
But we're not looking for one specific thing.
01:15:42.040 --> 01:15:44.040
Because we're sweeping.
01:15:44.040 --> 01:15:47.040
We can get this whole range...
01:15:47.040 --> 01:15:49.040
Right.
01:15:49.040 --> 01:15:51.040
Of viruses and bacteria.
01:15:51.040 --> 01:15:55.040
And see, some of this is bacteria like the B.E. coli rod.
01:15:55.040 --> 01:15:57.040
Why does it say five on that?
01:15:57.040 --> 01:15:59.040
Where?
01:15:57.040 --> 01:15:59.040
Sideband number five.
01:15:59.040 --> 01:16:01.040
Yeah, sideband number five.
01:16:01.040 --> 01:16:03.040
It's going to be in the fifth position.
01:16:05.040 --> 01:16:07.040
For sure, that's what it means.
01:16:07.040 --> 01:16:09.040
Oh, yeah. Okay.
01:16:09.040 --> 01:16:11.040
See? One, two, three, four, five.
01:16:11.040 --> 01:16:13.040
Yeah.
01:16:11.040 --> 01:16:13.040
And so...
01:16:13.040 --> 01:16:15.040
Remember what I said on our chart?
01:16:13.040 --> 01:16:15.040
Yeah.
01:16:15.040 --> 01:16:17.040
That if I divide it by this,
01:16:17.040 --> 01:16:21.040
I can just count three over or two over or one over.
01:16:21.040 --> 01:16:23.040
So when you're sweeping...
01:16:23.040 --> 01:16:25.040
Then it's different.
01:16:25.040 --> 01:16:27.040
It doesn't lose power when it goes down like that.
01:16:27.040 --> 01:16:32.040
No, as you sweep, you're going to run a frequency that's closer up...
01:16:32.040 --> 01:16:34.040
Okay. Yeah, yeah.
01:16:34.040 --> 01:16:36.040
...you know, bigger to the fundamental.
01:16:36.040 --> 01:16:38.040
And let's look at that first, all right?
01:16:38.040 --> 01:16:40.040
Let's look at that now.
01:16:40.040 --> 01:16:43.040
We'll come back to this if we need more explanation
01:16:43.040 --> 01:16:45.040
on this fundamental frequency.
01:16:45.040 --> 01:16:47.040
Okay.
01:16:54.040 --> 01:16:56.040
So by gating...
01:16:56.040 --> 01:16:59.040
By gating, that means that the audio comes in
01:16:59.040 --> 01:17:02.040
and sort of kicks down the oscillator to the ground.
01:17:02.040 --> 01:17:04.040
Right.
01:17:02.040 --> 01:17:04.040
And it goes off, and then it comes back on.
01:17:04.040 --> 01:17:06.040
And so after...
01:17:04.040 --> 01:17:06.040
And it causes these peaks.
01:17:06.040 --> 01:17:08.040
After each packet, there's a gate.
01:17:08.040 --> 01:17:10.040
Yeah, see it here? See it?
01:17:10.040 --> 01:17:12.040
Right, right.
01:17:14.040 --> 01:17:16.040
Let me get...
01:17:18.040 --> 01:17:21.040
Let me get it to where I want it to be.
01:17:21.040 --> 01:17:23.040
I don't want to see it.
01:17:23.040 --> 01:17:25.040
So you're not sweeping here?
01:17:25.040 --> 01:17:27.040
Yes, we are sweeping. See it?
01:17:27.040 --> 01:17:29.040
So everything is running through that...
01:17:29.040 --> 01:17:31.040
What we're seeing on that scope is everything?
01:17:31.040 --> 01:17:33.040
Everything that's being transmitted right now.
01:17:33.040 --> 01:17:35.040
Okay.
01:17:33.040 --> 01:17:35.040
Coming out of the machine.
01:17:35.040 --> 01:17:38.040
So you're actually looking at the packets there.
01:17:38.040 --> 01:17:40.040
Okay, that's the combined...
01:17:40.040 --> 01:17:42.040
Yeah, this looks a little bit different,
01:17:42.040 --> 01:17:45.040
but actually does the same thing,
01:17:45.040 --> 01:17:49.040
and a little bit more precise than what Rice equipment did.
01:17:49.040 --> 01:17:51.040
Right.
01:17:49.040 --> 01:17:53.040
His was tube, this was digital, more solid state.
01:17:53.040 --> 01:17:55.040
This is what's going into the patient?
01:17:55.040 --> 01:17:58.040
Yes, that signal right there with these sharp spikes in.
01:17:58.040 --> 01:18:00.040
Okay.
01:18:00.040 --> 01:18:02.040
But he doesn't feel that.
01:18:02.040 --> 01:18:09.040
Anyway, yeah, we're going to use the VNK Precision 4140V
01:18:09.040 --> 01:18:15.040
12 MHz generator in the sweep function in the linear mode.
01:18:15.040 --> 01:18:17.040
So that's providing...
01:18:17.040 --> 01:18:19.040
It's the laboratory. It has stopped.
01:18:19.040 --> 01:18:22.040
It's just showing you that it's going to sweep here, see?
01:18:22.040 --> 01:18:25.040
And it's showing you that it's in the linear sweep, see it?
01:18:25.040 --> 01:18:27.040
Okay.
01:18:25.040 --> 01:18:27.040
See that line?
01:18:27.040 --> 01:18:29.040
Yeah.
01:18:29.040 --> 01:18:32.040
It's sweeping from here to here in the linear range.
01:18:32.040 --> 01:18:34.040
And then it comes back and sweeps to you.
01:18:34.040 --> 01:18:40.040
Right, because if we stop this for a moment, right, we just say stop.
01:18:40.040 --> 01:18:43.040
You see we're at a locked frequency there.
01:18:43.040 --> 01:18:48.040
And this may be better to see where it comes back down, see it's ringing.
01:18:48.040 --> 01:18:50.040
Well, it's at a frequency where...
01:18:50.040 --> 01:18:52.040
This is actually your packet.
01:18:52.040 --> 01:18:54.040
Right.
01:18:54.040 --> 01:18:56.040
That I was showing you.
01:18:56.040 --> 01:18:58.040
See these squares? They look like squares.
01:18:58.040 --> 01:19:01.040
But out here, there's sine waves.
01:19:01.040 --> 01:19:03.040
Yeah, yeah.
01:19:03.040 --> 01:19:05.040
See?
01:19:06.040 --> 01:19:08.040
All right?
01:19:08.040 --> 01:19:15.040
And what that sine wave is actually doing that we're inputting from this linear generator,
01:19:15.040 --> 01:19:17.040
right, the sweep generator,
01:19:17.040 --> 01:19:25.040
is modulating the RF circuitry to distort the wave and cause sidebands.
01:19:25.040 --> 01:19:29.040
So, if we go back to linear...
01:19:29.040 --> 01:19:31.040
And that's a blank spot.
01:19:31.040 --> 01:19:33.040
Yeah, let's see if we can get this...
01:19:33.040 --> 01:19:35.040
There you go.
01:19:35.040 --> 01:19:38.040
I want to get it so you can see it good.
01:19:38.040 --> 01:19:41.040
That's good. Can you see that?
01:19:41.040 --> 01:19:45.040
Yeah, I'm going to go down to the lower frequencies, see the gates.
01:19:45.040 --> 01:19:48.040
It's kind of hard for the scope to trigger on it.
01:19:48.040 --> 01:19:53.040
It doesn't know, you know, we can force it, but it's not going to...
01:19:53.040 --> 01:19:56.040
It's not going to do it. And see, once we have our trigger line down here,
01:19:56.040 --> 01:20:02.040
we're not going to be able to see it until we get it to where it can catch a peak.
01:20:02.040 --> 01:20:04.040
You can see it in there.
01:20:04.040 --> 01:20:06.040
Yeah.
01:20:06.040 --> 01:20:08.040
So there's our packets, see?
01:20:08.040 --> 01:20:09.040
Yep.
01:20:09.040 --> 01:20:11.040
And the gates in between.
01:20:11.040 --> 01:20:17.040
So, technically, it's identical to what RIFE was doing.
01:20:17.040 --> 01:20:20.040
How many times a minute were you sweeping it?
01:20:20.040 --> 01:20:23.040
I'm going from 10,000...
01:20:25.040 --> 01:20:28.040
Well, we're left here, sorry.
01:20:28.040 --> 01:20:30.040
We have to stop that.
01:20:30.040 --> 01:20:34.040
Okay, we've stopped at 60,000.
01:20:34.040 --> 01:20:39.040
So our stop is 60,000, our start is 15,000 here.
01:20:39.040 --> 01:20:44.040
And our rate is 11.8 seconds.
01:20:44.040 --> 01:20:49.040
Okay. So every 11.8 seconds is one sweep.
01:20:49.040 --> 01:20:51.040
Yeah, it's going to go through the whole thing.
01:20:51.040 --> 01:20:53.040
So that's about 60 times...
01:20:53.040 --> 01:20:54.040
Yeah.
01:20:54.040 --> 01:20:55.040
Six times a minute.
01:20:55.040 --> 01:20:56.040
Yeah.
01:20:56.040 --> 01:20:59.040
So now we go back to sweep.
01:20:59.040 --> 01:21:04.040
And you can see that, well, we didn't stop the sweep, so it's still sweeping.
01:21:04.040 --> 01:21:06.040
But if we stop the sweep...
01:21:08.040 --> 01:21:14.040
And we bring this out, you can see that it's all in here in packets.
01:21:14.040 --> 01:21:15.040
See?
01:21:15.040 --> 01:21:22.040
There's one complete set of cycles that it's modulating on this thing.
01:21:22.040 --> 01:21:23.040
Right.
01:21:23.040 --> 01:21:29.040
And these sharp spikes are what actually get in there and kill the virus.
01:21:29.040 --> 01:21:32.040
Now we go back to linear sweep.
01:21:32.040 --> 01:21:33.040
I have a question.
01:21:33.040 --> 01:21:34.040
Mm-hmm.
01:21:34.040 --> 01:21:40.040
If it sweeps every 11.8 seconds, so that's about five times a minute.
01:21:40.040 --> 01:21:41.040
Yeah.
01:21:41.040 --> 01:21:46.040
And your blood flow through your body takes a minute for your blood flow.
01:21:46.040 --> 01:21:47.040
Right.
01:21:47.040 --> 01:21:52.040
If you did a three-minute treatment, then you have three times 11.
01:21:52.040 --> 01:21:53.040
Yeah.
01:21:53.040 --> 01:21:54.040
Or 11.
01:21:54.040 --> 01:21:56.040
Yeah, it's going to hit it over and over.
01:21:56.040 --> 01:21:59.040
Yeah, it's going to hit it over and over faster.
01:21:59.040 --> 01:22:06.040
Now, let's go down here to this spectrum analyzer, because I've froze this screen here,
01:22:06.040 --> 01:22:09.040
so that you could see what it's generating.
01:22:09.040 --> 01:22:15.040
And if I mark it, it's going to tell me right where this marker is.
01:22:15.040 --> 01:22:17.040
Can you see that there, Tony?
01:22:17.040 --> 01:22:18.040
Yeah.
01:22:18.040 --> 01:22:19.040
Okay.
01:22:19.040 --> 01:22:24.040
And if I say, did I want to look at the cancer frequency?
01:22:24.040 --> 01:22:35.040
We both know that we want to be at 3214.
01:22:35.040 --> 01:22:38.040
So see, I'm already past it.
01:22:38.040 --> 01:22:44.040
See, 3, 2.
01:22:44.040 --> 01:22:52.040
So I can dial it in here, see?
01:22:52.040 --> 01:22:53.040
Okay.
01:22:53.040 --> 01:22:59.040
Now, see, I'm at 3214666 because of the span.
01:22:59.040 --> 01:23:04.040
In other words, if I change the span, this number will get lower or higher.
01:23:04.040 --> 01:23:05.040
Do you understand what I'm saying?
01:23:05.040 --> 01:23:07.040
If I make the span go out.
01:23:07.040 --> 01:23:11.040
So I'm within one tenth of one meter because I'm going to hit it when I sweep.
01:23:11.040 --> 01:23:20.040
So now let's look at what it's doing on the spectrum analyzer by unfreezing it.
01:23:20.040 --> 01:23:25.040
And see, I'm leaving the trace up there so you can see where we dialed in.
01:23:25.040 --> 01:23:29.040
But now see, on the second trace is in blue.
01:23:29.040 --> 01:23:36.040
See it hitting the cancer frequency each time coming up to the resonant point.
01:23:36.040 --> 01:23:39.040
So you're combining an actual sweep with...
01:23:39.040 --> 01:23:40.040
I'm leaving...
01:23:40.040 --> 01:23:42.040
Where do you set the original?
01:23:42.040 --> 01:23:48.040
Right. I'm showing you how it sweeps out, right?
01:23:48.040 --> 01:23:52.040
How it's going and hitting that in the third place or the second place.
01:23:52.040 --> 01:23:53.040
See it?
01:23:53.040 --> 01:23:57.040
One, two, one.
01:23:57.040 --> 01:24:03.040
The biggest one will be number two coming up right now.
01:24:03.040 --> 01:24:04.040
Right there.
01:24:04.040 --> 01:24:05.040
Okay.
01:24:05.040 --> 01:24:09.040
So now if we go back...
01:24:09.040 --> 01:24:14.040
Okay, so now we're on a blue screen instead of a yellow screen.
01:24:14.040 --> 01:24:17.040
Because that's the one we set to do the sweeping.
01:24:17.040 --> 01:24:22.040
So now, Tony, let's pick a frequency.
01:24:22.040 --> 01:24:26.040
Let's freeze this when it's up here.
01:24:26.040 --> 01:24:32.040
So we'll wait a second here.
01:24:32.040 --> 01:24:43.040
All right.
01:24:43.040 --> 01:24:45.040
Let's just say right there.
01:24:45.040 --> 01:24:47.040
See, now we've frozen.
01:24:47.040 --> 01:24:49.040
The yellow shows up as being there.
01:24:49.040 --> 01:24:53.040
So let's just clear all.
01:24:53.040 --> 01:24:55.040
Okay. So we're there.
01:24:55.040 --> 01:24:56.040
All right.
01:24:56.040 --> 01:24:58.040
Now there's your fundamental frequency.
01:24:58.040 --> 01:25:02.040
Three, one, see?
01:25:02.040 --> 01:25:06.040
And now what we want to do is we want to take that span.
01:25:06.040 --> 01:25:11.040
And we want to zoom out so we can get as many of these bands as we can in there.
01:25:11.040 --> 01:25:14.040
See?
01:25:14.040 --> 01:25:25.040
And then what we're going to do is we're going to amplify this up so we can see we don't need this much attenuation.
01:25:25.040 --> 01:25:31.040
We'll change the scale division.
01:25:31.040 --> 01:25:36.040
And we're in the log scale, so it's going to go...
01:25:36.040 --> 01:25:40.040
Okay, so let's freeze it and calculate some things here.
01:25:40.040 --> 01:25:46.040
So we've frozen the screen, and we've marked our fundamental.
01:25:46.040 --> 01:25:54.040
As soon as I move this around a little bit, I can show right where I'm at with the fundamental frequency.
01:25:54.040 --> 01:25:57.040
You know, which I'm close enough.
01:25:57.040 --> 01:26:06.040
So now if we go to the chart, and you pick one out like you talked about, pneumonia.
01:26:06.040 --> 01:26:08.040
Remember?
01:26:08.040 --> 01:26:14.040
So you can see what we're looking for is 2988034.
01:26:14.040 --> 01:26:15.040
Okay.
01:26:15.040 --> 01:26:27.040
All right, so now if we take the analyzer, and since we marked 29888...
01:26:27.040 --> 01:26:32.040
We'll just go 298889499.
01:26:32.040 --> 01:26:35.040
We'll be within the range when we sweep.
01:26:35.040 --> 01:26:37.040
So now we'll clear this.
01:26:37.040 --> 01:26:39.040
The dot's right here. See it?
01:26:39.040 --> 01:26:42.040
We'll go with it and we'll unfreeze this.
01:26:42.040 --> 01:26:49.040
Now, watch as the dot comes up as the side bands get bigger and bigger and bigger.
01:26:49.040 --> 01:26:54.040
And you see it's going to end up exactly what the chart's showing you.
01:26:54.040 --> 01:26:57.040
And it's going to hit it right when it needs to hit it.
01:26:57.040 --> 01:27:04.040
The freeze is a disaster rescan.
01:27:04.040 --> 01:27:08.040
Listen, we can get this in a little bit better here.
01:27:08.040 --> 01:27:11.040
And that we would have to do by spanning it.
01:27:11.040 --> 01:27:14.040
There we go.
01:27:14.040 --> 01:27:17.040
Is that a little bit better on the camera?
01:27:17.040 --> 01:27:24.040
And you can see how many times it's actually hitting that pneumonia frequency.
01:27:24.040 --> 01:27:27.040
It's done it three times already.
01:27:27.040 --> 01:27:34.040
It's hitting it first at the low, and then it's building...
01:27:34.040 --> 01:27:38.040
And building.
01:27:38.040 --> 01:27:40.040
And so you can choose any one you want there.
01:27:40.040 --> 01:27:43.040
When it drops it, that's the gate, is it?
01:27:43.040 --> 01:27:46.040
No, the gating's done up here.
01:27:46.040 --> 01:27:55.040
But the spectrum analyzer, since you're sweeping, it's changing its frequency, modulating this.
01:27:55.040 --> 01:27:58.040
You can see it's getting narrower or bigger.
01:27:58.040 --> 01:28:00.040
Okay, I guess I was just confused.
01:28:00.040 --> 01:28:03.040
It goes to the top, and it goes to the bottom.
01:28:03.040 --> 01:28:07.040
Well, each time it goes to the top, you've hit the frequency.
01:28:07.040 --> 01:28:10.040
But it doesn't always come right down to the bottom, it seems.
01:28:10.040 --> 01:28:12.040
Well, it does.
01:28:12.040 --> 01:28:13.040
It does?
01:28:13.040 --> 01:28:17.040
Well, yeah, you can't see it, it seems like it's going all the way to the bottom.
01:28:17.040 --> 01:28:23.040
So pick another frequency, and I'll freeze this out, and we'll see if it hits it.
01:28:23.040 --> 01:28:26.040
Gloria!
01:28:26.040 --> 01:28:29.040
Let me stop it.
01:28:29.040 --> 01:28:31.040
It's 3.029.
01:28:31.040 --> 01:28:34.040
Okay, 3.029.
01:28:34.040 --> 01:28:43.040
Okay, 3.029.
01:28:43.040 --> 01:28:44.040
Right.
01:28:44.040 --> 01:28:48.040
Yeah, that's fine, because see where it is on there, Tony?
01:28:48.040 --> 01:28:51.040
It's going to sweep it and hit it.
01:28:51.040 --> 01:28:55.040
So now we go back and unfreeze that.
01:28:59.040 --> 01:29:08.040
See, it hit it there, it hit it there, it's going to hit it there, but it's going to hit it with the most power here.
01:29:08.040 --> 01:29:10.040
Yeah, okay.
01:29:10.040 --> 01:29:13.040
Because it's just going to be short of this one, watch, see?
01:29:13.040 --> 01:29:15.040
Yeah, yeah.
01:29:15.040 --> 01:29:17.040
Unless we change the span.
01:29:17.040 --> 01:29:24.040
But that's probably, it's going to hit it right where the chart says, so let's look at where the chart says it's going to hit it.
01:29:24.040 --> 01:29:27.040
Okay, so second band.
01:29:27.040 --> 01:29:29.040
Right, that's what it was.
01:29:29.040 --> 01:29:35.040
That's what it's, the second band that's going to hit it the highest here, Tony, if we watch.
01:29:35.040 --> 01:29:39.040
It's not going to hit it on the first band, it's going to start over.
01:29:39.040 --> 01:29:42.040
We're going to wait until it builds, see?
01:29:42.040 --> 01:29:44.040
Well, it's hitting it all that time.
01:29:44.040 --> 01:29:50.040
So it's going to hit this in the second band, which is right here.
01:29:50.040 --> 01:29:52.040
Watch.
01:29:54.040 --> 01:29:57.040
See, it's at the second band.
01:29:57.040 --> 01:29:59.040
Then it's got the most power.
01:29:59.040 --> 01:30:01.040
It won't hit it here.
01:30:01.040 --> 01:30:03.040
Yeah.
01:30:03.040 --> 01:30:07.040
Now, we might be able to tighten this in.
01:30:13.040 --> 01:30:18.040
But it's going to show you all these generations.
01:30:18.040 --> 01:30:21.040
So we'll go back to the marker.
01:30:25.040 --> 01:30:30.040
Okay, so we were looking for the second band, which is the highest.
01:30:30.040 --> 01:30:33.040
Which is right there.
01:30:33.040 --> 01:30:36.040
Because it's not going to hit it there.
01:30:36.040 --> 01:30:41.040
And that's basically how it works.
01:30:41.040 --> 01:30:45.040
So now just pick another random one, Pat.
01:30:45.040 --> 01:30:47.040
These are tough ones.
01:30:47.040 --> 01:30:49.040
Tuberculosis, virus, the...
01:30:49.040 --> 01:30:52.040
Well, that's going to come in the first band.
01:30:52.040 --> 01:30:55.040
Well, we should show them this come up in the first band.
01:30:55.040 --> 01:30:58.040
Right, we should, you're right.
01:31:00.040 --> 01:31:01.040
Yeah.
01:31:01.040 --> 01:31:02.040
Yeah.
01:31:02.040 --> 01:31:06.040
Okay, and so the frequency we're looking for is this one, 3076.
01:31:06.040 --> 01:31:08.040
Right.
01:31:08.040 --> 01:31:09.040
I think we did that.
01:31:09.040 --> 01:31:11.040
We did the rod. We didn't do the virus.
01:31:11.040 --> 01:31:12.040
All right.
01:31:12.040 --> 01:31:14.040
The rod is a hit number three.
01:31:14.040 --> 01:31:16.040
Well, that's going to look kind of weird.
01:31:16.040 --> 01:31:18.040
No, because he said you have to do both.
01:31:18.040 --> 01:31:20.040
Yeah, you have to do both.
01:31:20.040 --> 01:31:23.040
Because one will kill you.
01:31:23.040 --> 01:31:28.040
Okay, so what I'm going to do is freeze this again.
01:31:28.040 --> 01:31:33.040
All right, now what frequency are we looking for, Pat?
01:31:33.040 --> 01:31:36.040
3076.
01:31:36.040 --> 01:31:37.040
Pat.
01:31:37.040 --> 01:31:38.040
Wait, what is this?
01:31:38.040 --> 01:31:45.040
Well, this is the tuberculosis virus we're looking for here with a marker.
01:31:45.040 --> 01:31:46.040
Okay.
01:31:46.040 --> 01:31:48.040
So we're going to start the sweep.
01:31:48.040 --> 01:31:51.040
We're going to go back and unfreeze this.
01:31:51.040 --> 01:31:55.040
All right, we've hit it there on the first band, Pat.
01:31:58.040 --> 01:32:02.040
And so we hit it right away, see?
01:32:02.040 --> 01:32:08.040
We hit it there and notice that as they spread out, we've already hit it.
01:32:08.040 --> 01:32:12.040
And see, it's right there where the fundamental is.
01:32:12.040 --> 01:32:16.040
So let's change the span a little bit.
01:32:17.040 --> 01:32:26.040
So let's change the span a little bit while this is running so we can actually get it better.
01:32:26.040 --> 01:32:28.040
There's the fundamental.
01:32:32.040 --> 01:32:33.040
See it hit it?
01:32:33.040 --> 01:32:35.040
Yeah.
01:32:35.040 --> 01:32:41.040
And so we don't have to be right on here because it sweeps it.
01:32:41.040 --> 01:32:43.040
It's going to hit it no matter what.
01:32:43.040 --> 01:32:45.040
Yeah, yeah.
01:32:46.040 --> 01:32:49.040
And it's going to hit it six times every minute.
01:32:49.040 --> 01:32:50.040
Yeah.
01:32:50.040 --> 01:32:51.040
Or is it 12?
01:32:51.040 --> 01:32:53.040
Well, every 11 seconds.
01:32:53.040 --> 01:32:54.040
Yeah, every 11 seconds.
01:32:54.040 --> 01:32:56.040
About five times every minute.
01:32:56.040 --> 01:32:57.040
Yeah, see?
01:32:57.040 --> 01:33:00.040
So it's already hit it two times.
01:33:00.040 --> 01:33:02.040
Okay.
01:33:06.040 --> 01:33:08.040
There it hits it there.
01:33:08.040 --> 01:33:11.040
And it grows.
01:33:11.040 --> 01:33:13.040
Remember, it's sweeping by.
01:33:13.040 --> 01:33:15.040
It hits it right there, see?
01:33:15.040 --> 01:33:16.040
And it's furthest.
01:33:16.040 --> 01:33:17.040
Yeah, yeah.
01:33:17.040 --> 01:33:22.040
And then you see them go out from there because of the sweep.
01:33:22.040 --> 01:33:30.040
But actually what's happening here is that this, we might be able to get this.
01:33:30.040 --> 01:33:34.040
I want to get it in a clearer view.
01:33:34.040 --> 01:33:37.040
Now notice this is on the antenna.
01:33:37.040 --> 01:33:40.040
And when I touch it, see the power go up?
01:33:40.040 --> 01:33:41.040
Yeah, yeah.
01:33:41.040 --> 01:33:48.040
Because the signal's actually transmitting into me right now.
01:33:48.040 --> 01:33:51.040
So it's pretty powerful right there.
01:33:51.040 --> 01:33:52.040
Yeah.
01:33:52.040 --> 01:34:01.040
And then the other thing that I want to say is this is mandatory.
01:34:01.040 --> 01:34:04.040
This is a mandatory item to have.
01:34:05.040 --> 01:34:11.040
So that you know that when you make this unit from the little booklet in the video,
01:34:11.040 --> 01:34:16.040
that you can actually see all this.
01:34:16.040 --> 01:34:18.040
So you're saying that you should really have the...
01:34:18.040 --> 01:34:20.040
You should have the equipment to do it.
01:34:20.040 --> 01:34:21.040
Yeah, just to analyze it here.
01:34:21.040 --> 01:34:27.040
Yeah, now this, you asked what this was.
01:34:27.040 --> 01:34:29.040
This is the pump wave.
01:34:29.040 --> 01:34:34.040
And this is at 7.4 hertz.
01:34:34.040 --> 01:34:40.040
And that's generating a magnetic field right now in the antenna, in the box.
01:34:40.040 --> 01:34:43.040
So the whole unit's actually in the box.
01:34:43.040 --> 01:34:46.040
Or you can run electrodes on it. Doesn't make any difference.
01:34:46.040 --> 01:34:48.040
Well, that box is a little different than from the other one.
01:34:48.040 --> 01:34:52.040
Yes, we'll cover that later on.
01:34:52.040 --> 01:34:54.040
What, in another DVD?
01:34:54.040 --> 01:34:55.040
Absolutely.
01:34:55.040 --> 01:34:56.040
Okay.
01:34:56.040 --> 01:35:02.040
Because there's, since we've, you know, you keep thinking of things to do to this.
01:35:02.040 --> 01:35:03.040
Yeah, yeah.
01:35:03.040 --> 01:35:11.040
And it's never ending because it just doesn't, you know, it's not that it has to be done this way.
01:35:11.040 --> 01:35:14.040
Here's what's going on.
01:35:14.040 --> 01:35:19.040
Now you really must think about what I'm going to say to you here.
01:35:19.040 --> 01:35:28.040
That nature, if we just disconnect, turn this off, and we bring this up.
01:35:28.040 --> 01:35:30.040
You see these frequencies?
01:35:30.040 --> 01:35:31.040
Mm-hmm.
01:35:31.040 --> 01:35:32.040
This is in the air.
01:35:32.040 --> 01:35:33.040
Yeah.
01:35:33.040 --> 01:35:37.040
See, it's hitting the cancer and it's hitting the type.
01:35:37.040 --> 01:35:44.040
But what's happening is it's being masked by everything that we're using today.
01:35:44.040 --> 01:35:49.040
The computer, the digital switching supplies, these lights.
01:35:49.040 --> 01:36:11.040
If we really look at this, if we, say we plug in that frequency that cancer is, which is 107.455.
01:36:11.040 --> 01:36:26.040
But we have to tell it frequency, so we've got to go to a frequency of 107.455 and tell it megahertz.
01:36:26.040 --> 01:36:38.040
Now what it's going to do is it's just going to look for that frequency.
01:36:38.040 --> 01:36:41.040
And so what we want to do is 107.
01:36:41.040 --> 01:36:44.040
Well, it's way down here at this end.
01:36:44.040 --> 01:36:49.040
So that means we have to bring in this span.
01:36:49.040 --> 01:36:56.040
So if we go here to the cancer virus, they want 1607, see?
01:36:56.040 --> 01:37:03.040
Yeah, so they want 16.
01:37:03.040 --> 01:37:07.040
And it's going to be out here somewhere.
01:37:07.040 --> 01:37:21.040
Now the funny thing about the spectrum analyzer is I think we can tell it center frequency.
01:37:21.040 --> 01:37:25.040
So if we push that, so what is it exactly, Pat?
01:37:25.040 --> 01:37:35.040
1607.450.
01:37:35.040 --> 01:37:38.040
4.
01:37:38.040 --> 01:37:41.040
5, yeah.
01:37:41.040 --> 01:37:44.040
Killerhertz, or megahertz, yeah.
01:37:44.040 --> 01:37:45.040
Good, good.
01:37:45.040 --> 01:37:47.040
Okay, so now see, Tony?
01:37:47.040 --> 01:37:48.040
Yeah.
01:37:48.040 --> 01:37:54.040
You can see that it's detecting that frequency right here when it goes up.
01:37:54.040 --> 01:37:59.040
Because I think if we mark that, actually it's not telling us here.
01:37:59.040 --> 01:38:05.040
So let's just go back and set this again.
01:38:05.040 --> 01:38:07.040
Okay, there's our fundamental.
01:38:07.040 --> 01:38:17.040
Okay.
01:38:17.040 --> 01:38:22.040
Let's see what we're doing here.
01:38:22.040 --> 01:38:26.040
But I think, you see this fundamental right here?
01:38:26.040 --> 01:38:31.040
Pat, there's something here that the antenna is picking up.
01:38:31.040 --> 01:38:38.040
So if we mark that, what it is is 518.2.
01:38:38.040 --> 01:38:41.040
That's in the natural background.
01:38:41.040 --> 01:38:43.040
Well, that's not the natural background.
01:38:43.040 --> 01:38:46.040
That's in the natural background right there.
01:38:46.040 --> 01:38:49.040
518.2 megahertz.
01:38:49.040 --> 01:38:52.040
Something's transmitting, see?
01:38:52.040 --> 01:38:57.040
So if we take this, right, and let's say...
01:38:57.040 --> 01:38:59.040
That's the camera sound.
01:38:59.040 --> 01:39:00.040
Well, it could be.
01:39:00.040 --> 01:39:01.040
No, it is.
01:39:01.040 --> 01:39:03.040
That's that frequency, 518.2.
01:39:03.040 --> 01:39:04.040
Okay.
01:39:04.040 --> 01:39:06.040
Sorry.
01:39:06.040 --> 01:39:07.040
Fine.
01:39:07.040 --> 01:39:08.040
Well, that's there, see?
01:39:08.040 --> 01:39:10.040
Yeah, it's actually picking it up.
01:39:10.040 --> 01:39:11.040
Yeah.
01:39:11.040 --> 01:39:18.040
Okay, now, say that a radio station, right?
01:39:18.040 --> 01:39:22.040
Say we wanted a radio station, just to give you an idea of what you could do with it.
01:39:22.040 --> 01:39:25.040
I mean, I can cut the sound and do it off the other mic, but...
01:39:25.040 --> 01:39:28.040
Yeah, but you're picking this up.
01:39:28.040 --> 01:39:31.040
Yeah, that's the take that demonstrates that...
01:39:31.040 --> 01:39:32.040
Yeah, that's what I'm trying to do.
01:39:32.040 --> 01:39:36.040
I'm trying to demonstrate to you how it does, you know, what it can do here.
01:39:36.040 --> 01:39:44.040
Yeah, but I think what you're trying to also demonstrate is the fact that all the healing frequencies are in the natural background...
01:39:44.040 --> 01:39:45.040
Noise.
01:39:45.040 --> 01:39:46.040
Noise.
01:39:46.040 --> 01:39:48.040
But we have polluted them so bad.
01:39:48.040 --> 01:39:51.040
Yeah, we've polluted them, because, see, they're all in this noise.
01:39:51.040 --> 01:39:57.040
And that's why there is so much more cancer these days than there was 200 years ago.
01:39:57.040 --> 01:39:59.040
Now, here's a radio station, see?
01:39:59.040 --> 01:40:00.040
Okay.
01:40:00.040 --> 01:40:04.040
That's at fit 150, see, it's at 1.5 megahertz.
01:40:04.040 --> 01:40:05.040
Yeah.
01:40:05.040 --> 01:40:07.040
That's an AM station here.
01:40:07.040 --> 01:40:11.040
So, let's see if we can get...these are all radio stations.
01:40:11.040 --> 01:40:13.040
Okay.
01:40:13.040 --> 01:40:25.040
So, this is what I'm trying to show you, that we've actually polluted ourselves out from anything that...which naturally would have healed us before.
01:40:25.040 --> 01:40:26.040
Right.
01:40:26.040 --> 01:40:28.040
So, let's see.
01:40:31.040 --> 01:40:33.040
Zoom in and get these.
01:40:35.040 --> 01:40:39.040
And meanwhile, Congress is auctioning off all those frequencies.
01:40:39.040 --> 01:40:41.040
Yeah, exactly.
01:40:41.040 --> 01:40:46.040
To the highest bidder, so they can pollute and cause even more cancer.
01:40:46.040 --> 01:40:49.040
Well, yeah, this is what I'm trying to say to you here.
01:40:49.040 --> 01:41:02.040
So, if we just auto this, let's just say that we went from 900 kilohertz, right, so we can catch Rife's frequencies, all right?
01:41:02.040 --> 01:41:14.040
So, our start frequency is 900 kilohertz, and our stop frequency is going to be 2 megahertz.
01:41:17.040 --> 01:41:19.040
That's all we're looking at right now.
01:41:19.040 --> 01:41:20.040
Yeah.
01:41:20.040 --> 01:41:23.040
That's...see the frequencies in here?
01:41:23.040 --> 01:41:24.040
Yeah.
01:41:24.040 --> 01:41:26.040
The peaks.
01:41:26.040 --> 01:41:30.040
So, now if we marker this, what do we want?
01:41:30.040 --> 01:41:38.040
We want for the cancer frequency, we want 1607, right?
01:41:38.040 --> 01:41:40.040
See 666?
01:41:40.040 --> 01:41:42.040
See it's coming up on the peak here?
01:41:42.040 --> 01:41:43.040
Mm-hmm.
01:41:43.040 --> 01:41:49.040
Okay, so you could...this is just something that I'm going to bring up to everybody.
01:41:49.040 --> 01:41:57.040
You could build a crystal filter that just picks this up, right here.
01:41:57.040 --> 01:41:58.040
Picks what up?
01:41:58.040 --> 01:42:00.040
Picks the cancer frequency up.
01:42:00.040 --> 01:42:01.040
Right.
01:42:01.040 --> 01:42:09.040
And amplify that, and all you'd have to do is pulse that, and you would have the machine for cancer.
01:42:09.040 --> 01:42:14.040
If Rife's frequencies are on.
01:42:14.040 --> 01:42:15.040
Yeah.
01:42:14.040 --> 01:42:15.040
Right.
01:42:15.040 --> 01:42:16.040
If not, it would miss it.
01:42:16.040 --> 01:42:22.040
If on, it would miss it, but you'd want to sweep this a little bit, so you do, you know, back and forth.
01:42:22.040 --> 01:42:26.040
So you could have one machine for cancer, one for tuberculosis.
01:42:26.040 --> 01:42:27.040
You could.
01:42:27.040 --> 01:42:28.040
One for...
01:42:27.040 --> 01:42:28.040
Yeah, the virus.
01:42:28.040 --> 01:42:29.040
Different crystals.
01:42:29.040 --> 01:42:36.040
Yeah, yeah, you would want to hit the rod and the virus at the same time, so you'd need to combine those two.
01:42:36.040 --> 01:42:37.040
Anthrax or...
01:42:37.040 --> 01:42:41.040
Yeah, you could do that, because see, it's already existing.
01:42:41.040 --> 01:42:42.040
Right.
01:42:42.040 --> 01:42:44.040
Those frequencies are already existing in the noise.
01:42:44.040 --> 01:42:45.040
Right.
01:42:45.040 --> 01:42:50.040
So it's a matter of amplifying the noise, and I'm not sure that this is amplified.
01:42:50.040 --> 01:42:54.040
Yes, RF preamps on.
01:42:54.040 --> 01:42:59.040
So all we have to do now is change this attenuation.
01:42:59.040 --> 01:43:02.040
We're at 2 dB there.
01:43:02.040 --> 01:43:07.040
Scale division there, and now we can see a much bigger, see.
01:43:07.040 --> 01:43:10.040
So see, look, it's already there, Pat.
01:43:10.040 --> 01:43:13.040
And there's multiples in there.
01:43:13.040 --> 01:43:14.040
Yeah.
01:43:14.040 --> 01:43:16.040
So it's like scanning itself, you notice that?
01:43:16.040 --> 01:43:17.040
Yeah.
01:43:17.040 --> 01:43:19.040
Tony, that they're jumping around.
01:43:19.040 --> 01:43:23.040
So if you built a crystal filter that just filtered this...
01:43:23.040 --> 01:43:24.040
Yeah.
01:43:25.040 --> 01:43:38.040
And if we just filter this, and this is blocked out and that's blocked out, and we amplify this, and then we pulse it, there's his cancer.
01:43:38.040 --> 01:43:39.040
Yeah.
01:43:39.040 --> 01:43:41.040
So that's what I got to say.
01:43:41.040 --> 01:43:44.040
Excuse me, that rifle...
01:43:44.040 --> 01:43:46.040
Well, I'm pretty sure that he did.
01:43:46.040 --> 01:43:47.040
Yeah.
01:43:48.040 --> 01:43:53.040
Well, if you scan above and below it a little ways...
01:43:53.040 --> 01:43:55.040
Yeah, you'll hit it.
01:43:55.040 --> 01:44:06.040
If you filter this out, and that means building a crystal filter, and that filter ignores this end and that end, and just lets this come through.
01:44:06.040 --> 01:44:11.040
Now you amplify that, and you pulse that, and you can see the bands in here.
01:44:11.040 --> 01:44:13.040
I don't know if we can span that out.
01:44:13.040 --> 01:44:14.040
Yeah, we can.
01:44:14.040 --> 01:44:15.040
Okay, see, notice that?
01:44:15.040 --> 01:44:16.040
Mm-hmm.
01:44:16.040 --> 01:44:17.040
See?
01:44:17.040 --> 01:44:20.040
It's scanning it, it's moving around itself.
01:44:20.040 --> 01:44:21.040
Yeah.
01:44:21.040 --> 01:44:22.040
So it's hitting it.
01:44:24.040 --> 01:44:25.040
See it here?
01:44:27.040 --> 01:44:29.040
It's bouncing up and down the...
01:44:29.040 --> 01:44:32.040
Now let's change this, and then we can...
01:44:32.040 --> 01:44:38.040
If we change this scale, can move it up so you can see it.
01:44:38.040 --> 01:44:40.040
So see the dot?
01:44:40.040 --> 01:44:41.040
Mm-hmm.
01:44:42.040 --> 01:44:44.040
And see it's like a double beat?
01:44:44.040 --> 01:44:45.040
It tries to stare and gets up there.
01:44:45.040 --> 01:44:53.040
So I know that these natural healing frequencies were already in the noise that surrounded it.
01:44:53.040 --> 01:44:59.040
And so this, just to recap, you're actually amplifying the natural noise that surrounds it right now.
01:44:59.040 --> 01:45:01.040
Yeah, and I'm hitting his frequency.
01:45:01.040 --> 01:45:03.040
And you're hitting the cancer frequency.
01:45:03.040 --> 01:45:04.040
Yeah.
01:45:05.040 --> 01:45:11.040
And see, if I take the marker, it's telling me, I can look at all the frequencies I can hit.
01:45:11.040 --> 01:45:13.040
Like you said, you...
01:45:15.040 --> 01:45:17.040
See it? See here's these peaks?
01:45:17.040 --> 01:45:18.040
Yeah.
01:45:18.040 --> 01:45:21.040
If this happens to be one of his frequencies, I can amplify that.
01:45:21.040 --> 01:45:22.040
Yeah.
01:45:22.040 --> 01:45:25.040
See, or I could go over here and I could look at this one.
01:45:26.040 --> 01:45:28.040
It's already there.
01:45:29.040 --> 01:45:30.040
Just...
01:45:30.040 --> 01:45:38.040
Nature has supplied everything that we need to keep ourselves healthy, but the problem is we're masking all this out.
01:45:38.040 --> 01:45:45.040
So am I correct in saying that? Why 200 years ago there were far fewer illnesses like cancer?
01:45:45.040 --> 01:45:50.040
Yeah, there were far fewer illnesses. I mean, but once you got an illness, they didn't have anything to cure you.
01:45:50.040 --> 01:45:51.040
Right, right.
01:45:51.040 --> 01:45:52.040
You just died.
01:45:52.040 --> 01:45:53.040
Yeah.
01:45:53.040 --> 01:46:00.040
So basically that's, you know, what I wanted to present to you was that you can hit it.
01:46:00.040 --> 01:46:06.040
And here's the machine here, Tony, that's doing the work.
01:46:07.040 --> 01:46:08.040
And this is a...
01:46:08.040 --> 01:46:10.040
That's what we're going to talk about in the next...
01:46:10.040 --> 01:46:13.040
Yeah, that's what we're going to talk about this one in the next...
01:46:13.040 --> 01:46:14.040
Right.
01:46:14.040 --> 01:46:16.040
...machine, because it's more like a...
01:46:16.040 --> 01:46:17.040
So we might even take that out.
01:46:17.040 --> 01:46:18.040
...Piori machine.
01:46:18.040 --> 01:46:19.040
I'll just give it a quick...
01:46:19.040 --> 01:46:20.040
Yeah.
01:46:20.040 --> 01:46:24.040
And like Tony said, you know, this guy is well documented in France.
01:46:24.040 --> 01:46:25.040
Right.
01:46:25.040 --> 01:46:26.040
Yeah.
01:46:26.040 --> 01:46:30.040
So I'm glad I could share this with everybody.
01:46:30.040 --> 01:46:43.040
Okay. Well, I think everybody owes you a great debt of gratitude, John, for not trying to patent this work and not trying to hide it from the public, but for bringing it out to the public.
01:46:43.040 --> 01:46:48.040
And as I said, I think everyone owes you an incredible debt of gratitude.
01:46:48.040 --> 01:46:51.040
Well, I think they're going to need it here coming up in the future.
01:46:51.040 --> 01:46:54.040
Well, and on that uplifting note, we'll...
01:46:55.040 --> 01:46:56.040
We'll end this segment.
01:46:56.040 --> 01:46:57.040
Okay.
01:46:58.040 --> 01:47:00.040
Tell them what I said. Have a good day now.
01:47:04.040 --> 01:47:05.040
Okay. This is...
01:47:05.040 --> 01:47:08.040
I want to explain to everybody. This is a Moppa.
01:47:08.040 --> 01:47:13.040
And you can see inside there that it's a tube. This is exactly what Reif's unit was.
01:47:13.040 --> 01:47:15.040
This is a remake.
01:47:16.040 --> 01:47:21.040
And it's very critical that everything matches up on this.
01:47:21.040 --> 01:47:30.040
Because this is very difficult to get the signals in and out of because it's just a triode tube.
01:47:30.040 --> 01:47:33.040
It's much easier with a solid state unit.
01:47:34.040 --> 01:47:38.040
But anyway, let's have a go at it. Let's turn it on.
01:47:38.040 --> 01:47:43.040
And we'll see if we can catch the fundamental first.
01:47:45.040 --> 01:47:48.040
And there's the fundamental frequency.
01:47:49.040 --> 01:47:51.040
And it's actually scanning.
01:47:52.040 --> 01:47:55.040
So let's see here. Let's get this up.
01:47:55.040 --> 01:47:57.040
Let's find out where it is.
01:47:58.040 --> 01:48:00.040
So we can set the generator.
01:48:01.040 --> 01:48:06.040
Okay, this one's oscillating. Now watch as I turn this, I'm going to change the direction.
01:48:06.040 --> 01:48:07.040
Where do you turn?
01:48:07.040 --> 01:48:12.040
I'm turning the tuning so I can get the fundamental above three, see?
01:48:13.040 --> 01:48:14.040
Okay.
01:48:14.040 --> 01:48:16.040
So now I'm going to mark that.
01:48:17.040 --> 01:48:20.040
And I'm at 279.
01:48:30.040 --> 01:48:33.040
Ah, see? Marker.
01:48:35.040 --> 01:48:38.040
Now this is an out band way out there, Tony.
01:48:39.040 --> 01:48:41.040
See as I tune this.
01:48:42.040 --> 01:48:46.040
Okay, now it's sweeping. See it's modulating and sweeping.
01:48:47.040 --> 01:48:49.040
So this has a pump wave?
01:48:49.040 --> 01:48:52.040
No, no. This is a straight rife unit.
01:48:52.040 --> 01:48:53.040
Okay.
01:48:53.040 --> 01:48:55.040
And there's the bands.
01:48:55.040 --> 01:48:56.040
Right.
01:48:56.040 --> 01:48:58.040
And see now it's modulating.
01:48:58.040 --> 01:48:59.040
Okay.
01:48:59.040 --> 01:49:02.040
And these are the frequencies that it's scanning and hitting.
01:49:04.040 --> 01:49:09.040
So it looks a little bit different here on this unit.
01:49:11.040 --> 01:49:14.040
And I'm going to scan this out.
01:49:15.040 --> 01:49:18.040
I'm going to attempt to scan it out.
01:49:21.040 --> 01:49:23.040
See how it looks?
01:49:23.040 --> 01:49:24.040
Yep.
01:49:24.040 --> 01:49:29.040
And you can see that it's scanning here and then it'll reappear when it comes back.
01:49:29.040 --> 01:49:32.040
Because it's hitting those bands, see?
01:49:32.040 --> 01:49:35.040
It's hitting all these bands and then bang.
01:49:37.040 --> 01:49:39.040
And there's the tube over there.
01:49:39.040 --> 01:49:41.040
It's lit up.
01:49:41.040 --> 01:49:43.040
So this is the actual tube you're using?
01:49:43.040 --> 01:49:48.040
Yes, that's yeah. And right now I'm running from 50 to...
01:49:48.040 --> 01:49:50.040
And you can feel that.
01:49:50.040 --> 01:49:52.040
You know.
01:49:53.040 --> 01:49:56.040
You can see that it's a little bit different.
01:49:56.040 --> 01:49:59.040
And it's actually scanning all the frequencies.
01:49:59.040 --> 01:50:01.040
Right up here.
01:50:03.040 --> 01:50:06.040
And there are those packets again, see?
01:50:09.040 --> 01:50:11.040
See them?
01:50:14.040 --> 01:50:21.040
And I'm doing the best I can do with this because this is just definitely antique.
01:50:22.040 --> 01:50:24.040
When did you build this?
01:50:24.040 --> 01:50:28.040
Well I built this back in 2000.
01:50:29.040 --> 01:50:32.040
When we were all working on...
01:50:33.040 --> 01:50:40.040
Jeff Garfin, the rest of us were all working on it and you can see that it's doing its thing.
01:50:45.040 --> 01:50:47.040
I'm getting some interference.
01:50:47.040 --> 01:50:49.040
Oh yeah, you don't want to do that.
01:50:49.040 --> 01:50:53.040
Don't get too close because the RF is going to burn your chip and your camera.
01:50:55.040 --> 01:51:00.040
So let's take it away so you can see that it's really there.
01:51:00.040 --> 01:51:01.040
What is this now?
01:51:01.040 --> 01:51:08.040
Well I just turned it off so you can see that when it scans and gets the bands...
01:51:14.040 --> 01:51:17.040
Get this thing up. See it's barely lit right now.
01:51:18.040 --> 01:51:21.040
Because I've got it turned way down because I don't want to burn things up.
01:51:21.040 --> 01:51:23.040
But here, you can see it here.
01:51:25.040 --> 01:51:28.040
A little out of this and I'll hold on to it.
01:51:28.040 --> 01:51:30.040
There you go. See it?
01:51:31.040 --> 01:51:35.040
Pretty good. Well you can see it scanning the frequencies there.
01:51:35.040 --> 01:51:36.040
Okay.
01:51:36.040 --> 01:51:37.040
See?
01:51:42.040 --> 01:51:45.040
So that's exactly what Hoylan was doing.
01:51:45.040 --> 01:51:48.040
And it's scanning the generators.
01:51:48.040 --> 01:51:50.040
It's changing it. See it?
01:51:50.040 --> 01:51:51.040
Right.
01:51:51.040 --> 01:51:52.040
See?
01:51:54.040 --> 01:51:59.040
So just to reiterate, Hoylan was actually scanning...
01:51:59.040 --> 01:52:03.040
Hoylan, no. One specific frequency.
01:52:03.040 --> 01:52:05.040
I am sweeping.
01:52:05.040 --> 01:52:06.040
Okay.
01:52:06.040 --> 01:52:09.040
So that you can see the bands appear on the Mopa.
01:52:09.040 --> 01:52:10.040
Got it.
01:52:11.040 --> 01:52:13.040
And then on the opa scope we're seeing...
01:52:13.040 --> 01:52:16.040
You're seeing the packets. See how it scans?
01:52:16.040 --> 01:52:19.040
It's kind of hard to get it in because it's...
01:52:23.040 --> 01:52:24.040
There you go.
01:52:24.040 --> 01:52:26.040
I'm getting RF.
01:52:26.040 --> 01:52:29.040
Yes. See? Yeah. Don't get too close to it.
01:52:29.040 --> 01:52:32.040
So see? You can see here that it's sweeping.
01:52:32.040 --> 01:52:33.040
Yeah.
01:52:35.040 --> 01:52:39.040
And I've got the power turned down and this tube is quite hot.
01:52:41.040 --> 01:52:45.040
So what the doctors would do would hold the tube like this...
01:52:46.040 --> 01:52:48.040
in the area.
01:52:48.040 --> 01:52:51.040
And then they would sweep the dial.
01:52:51.040 --> 01:52:53.040
That's what Reif's doctors would do.
01:52:53.040 --> 01:52:56.040
Yeah. If you had something here, they would hold the tube here.
01:52:56.040 --> 01:52:57.040
Right.
01:52:57.040 --> 01:53:00.040
See? And now I'm scanning all these frequencies.
01:53:02.040 --> 01:53:08.040
So who knows what it's doing. It's probably affecting my Stevie Wonder glasses.
01:53:08.040 --> 01:53:09.040
It's affecting the camera.
01:53:09.040 --> 01:53:12.040
I know. Because it's real RF.
01:53:12.040 --> 01:53:18.040
I mean, this is a big oscillator compared to the solid state.
01:53:18.040 --> 01:53:21.040
A big oscillator compared to the solid state.
01:53:25.040 --> 01:53:28.040
Okay. This is your tank coil.
01:53:28.040 --> 01:53:30.040
And you...
01:53:30.040 --> 01:53:34.040
By tapping this, you can get different power levels to the tube.
01:53:34.040 --> 01:53:36.040
This is a triode tube.
01:53:37.040 --> 01:53:41.040
And then, of course, you've got your RF choke here and your tuning...
01:53:41.040 --> 01:53:47.040
where you can tune the fundamental frequency a little bit.
01:53:47.040 --> 01:53:50.040
The implement transformer and power transformer.
01:53:50.040 --> 01:53:51.040
Okay.
01:53:51.040 --> 01:53:57.040
And then your audio is... I've got it on clip leads, but it actually goes in here.
01:53:57.040 --> 01:54:00.040
And the antenna is hooked up out here.
01:54:00.040 --> 01:54:04.040
So when you turn it on, it lights up.
01:54:05.040 --> 01:54:08.040
And then if we take the...
01:54:11.040 --> 01:54:14.040
I'm going to hold it so I can get the best signal there.
01:54:14.040 --> 01:54:18.040
And it takes a while for it to warm up. That's the problem with them.
01:54:18.040 --> 01:54:19.040
Yeah.
01:54:19.040 --> 01:54:23.040
Because they drift around for a while until they...
01:54:24.040 --> 01:54:27.040
They probably have to end this thing. There we go.
01:54:27.040 --> 01:54:32.040
Once the analyzer has caught it, then you can see it sweep.
01:54:32.040 --> 01:54:36.040
So it's going to sweep and make the same bands.
01:54:37.040 --> 01:54:39.040
Yep. Good.
01:54:39.040 --> 01:54:40.040
Okay.
01:54:40.040 --> 01:54:41.040
Okay.
01:54:41.040 --> 01:54:42.040
Thank you all.
01:54:42.040 --> 01:54:43.040
Thank you, John.
01:54:43.040 --> 01:54:45.040
I'm glad I could show you this.
01:54:45.040 --> 01:54:50.040
Well, you know, it's nice to see the way, you know, you've been developing this process.
01:54:50.040 --> 01:54:53.040
Well, since 1975.
01:54:53.040 --> 01:54:54.040
Yeah.
01:54:54.040 --> 01:54:57.040
And you've been developing this process for a long time.
01:54:58.040 --> 01:55:01.040
Well, since 1975.
01:55:01.040 --> 01:55:02.040
Yeah.
01:55:02.040 --> 01:55:04.040
I've been working on it, so...
01:55:04.040 --> 01:55:05.040
Yeah.
01:55:05.040 --> 01:55:06.040
There you go.
01:55:06.040 --> 01:55:07.040
Thank you.
01:55:27.040 --> 01:55:28.040
Thank you.
01:55:57.040 --> 01:55:59.040
Okay.