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June 12, 2020 - Clif High
32:54
critical thinking - 6.12.0 - This shit is dangerous ! BSC DEMO !
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Time Text
As you can see or here, there's some force involved in these.
Jumping right into the demonstration here.
This is part of the Boskowitz Social Club.
The little floppy thing here is four neodium neodynium magnets.
They're spherical.
They're very, very, very strong.
You have to know what you're doing to separate them and watch out for your flesh.
You don't want to get the things to smack with any part of your anatomy in between them.
And they hurt, and this is not something for uh kids to play around with, besides which kids could probably swallow it and it would kill them.
So watch out.
But for adults, uh what this is a demonstration, or about to be a demonstration of magnetic field manipulation, and uh as a result directly of uh reading far enough into Boscovich to figure out uh the references he was making to how his theory relates to materials.
That is to say the end of part two and shading into part three, which is uh the application of the theory to physics, which in our sense would really be at least in the first part of part three, is really material science at a very interesting level.
And I discovered that Boscovich had uh also simultaneously and two, or not simultaneously, but 200 years plus earlier, uh had come to the same conclusions that uh Buckminster Fuller had in his uh description of the vector equilibrium.
And uh Boscovich describes it without labeling it.
Okay, he labels aspects of it that are quite clearly uh referencing the same thing that um uh Buckminster Fuller was describing in his writings.
Now, here's the demonstration component of this, okay.
If you have four of these, and and four is chosen for a very specific reason in order to show us that the dynamism and um uh contrariness of magnetic fields.
So each of these is a is a spherical magnet with the dielectric splitting going on in the middle that erupts into the magnetism that comes out of the element itself.
Here let me s do something to uh do we have anything that's basically I see I don't have I don't have a lot of iron stuff around.
Okay, there we go.
So here's uh so I just want you to see I'm not messing around.
There's that these indeed are uh magnets that attach to regular old metals.
Okay, so um these because of the nature of the field, and you know you can't have uh two north poles facing each other, two south poles, you try and squeeze them together, you're actually compressing the magnetic, the dialectic uh eruption as magnetism, and you're trying to compress it in a fluid sense, and you can only do it so far because it reacts as a fluid and in that sense.
But watch what can be done if you're aware of how these magnetic fields are actually shaped at a deeper level, and what may be able to be possible.
Now I'm gonna do something that is in essence a parlor trick, and I'll tell you how I'm doing it, and you could go ahead and replicate it as well.
But it's very interesting nonetheless, because of the science that it implies underneath it relative to the manipulation of the ether.
So if we were to collapse these into a little diamond shape, you see that we end up with this sort of squishy cube, and I can even squish the middle bits together, right?
And so the middle bits are are actually, I don't know if that's visible, they're not actually held together the way that they're held together on uh the diagonals of the cube.
I can push them together and they want to separate ever so slightly.
There we go.
It's difficult to get this camera to focus on that.
In any event, um, okay, so there.
So now I have a real shiny nose.
And you can see that it's together, but it's not really attracted.
So we don't have a an attraction pole.
We have a something in between that and a totally repulsing pole.
And I can push it apart only so far, so I can only get those two there, and then they collapse.
And so I'm I'm obviously, if you think about it from the Boscovich viewpoint, I'm going through those limit points, and those limit points are collapsing, and I'm going into the next level of limit points and structuring my way down in the magnetic strength that's emanating from the dielectric.
But it's as I structure down, I'm coming into harder and harder magnetic strength.
And ultimately, as you can see, it wants to, it wants to go back to this sort of open square kind of a formation.
Now here's where the manipulation comes in.
If you take this as a party trick and take it in and you get a bunch of drunk people, they will not be able to do this.
But the idea is let's turn that into a tetrahedron.
Instead of instead of it being a cube arrangement, let's twist it, and we'll twist the magnetic field.
And it's difficult to see it because I have to put my fingers on it.
But there, I've twisted the magnetic field to create this.
As you can see, it wants to squirrel away and climb away from me and so on, right?
And so basically what I'm trying to do is I'm trying to take these two on the outside and bring them together around this central point.
And there I'm holding it, and so you see it's sort of a tetrahedron, but I have to retain it on all sides, or it's gonna fly apart.
So you see that, right?
Now I can do something that will fix it.
And I did.
Ah, crap, and see it exploded.
Alright, I moved and it ruptured.
And so there, I have using one hand and I'm holding those four as a uh magnetic in a magnetic field in a fixed way that is not bound by my flesh.
I can actually set this down.
I just can't aim the camera down, and there's crap all over here anyway.
Uh but it is basically I'm only holding it just merely to hold that.
I'm not restraining the structure at all.
I have a dynamic composed spherical, contorted magnetic structure that is delicate, like you wouldn't believe, and the slightest little bit of disruption, and it returns to its state.
But if if you get it to this particular particular point where you go through and you collapse the magnetic limit points upon themselves, as Boscovich has described, you get to the other side, or or you get to a point of increased magnetic force as you head down towards the dielectric disruption.
And within this case, there is a, if you will, it's a crude analogy, there's a center of gravity effect among the four of these magnets, causing a particular kind of a blending of their field in this middle part uh of the magnetics uh of the structure as it is now.
And if you go down far enough in there and then you twist it to the other side of the um uh the ordinant to the other half of the ordinate, as he describes in his uh part two, then in essence you switch from repulsive force to attractive force, and it's bound right there.
But it's very delicately bound because it was your energy that pushed those two magnetic points together.
So it is um a capacitance for physical energy embodied in magnetism.
So there is a physical capacitor.
So if one wanted to, one could use this mechanism with sufficiently strong enough magnets uh to power something.
So it could be like a magnetic solenoid, right?
Because you could have a mechanism that would affix them against the magnetic force by doing what I'm doing here with this particular trick, and then use anything that was a minor amount of disruption in order to cause the greater force.
So let me put it to you this way.
That if we have X, so this is very much like hydraulics, okay.
So as you can see, it sits there.
Now, if we were to consider this field as in its initial state, that field in its initial state before I twisted it and fixed it the way I did, that let's just say that that uh field has an energy level that equaled X. We don't we don't have to assign numbers, it's not not pertinent, okay?
So that's initial state, the the energy level was X. Now, in order for me to get it to this state, I had to overcome the and now X by the way is perpetual.
X is perpetual.
It's the magnetic effect.
As long as that magnet exists and it's not destroyed, it's going to keep throwing out that effect.
So this is basically the energy coming out of that effect is a perpetual engine.
Here's a way to manipulate that perpetual engine.
What we do is we overcome, we do greater than X, but we don't do it continuously, we only do it momentarily.
So we have a factor of time involved.
The time it takes for me to do that initial twist.
And that overcomes the X. And then in order to counteract this tendency of it to perpetually want to stay in that state, we only have to apply to this a small fraction.
So let's just say that it's X divided.
I could apply a number, but I won't, but a very small fraction of X, okay?
So let's just say that it's uh a fraction of X, and so we can express it as X minus Y, and we can make a numeric value of that if we wanted to.
But there's no need for that at this point.
But so basically what I'm saying is that by the use of this particular amount of energy here, so this amount of energy right there is applied as applied as a one-time deal, right?
And that one time deal can overcome the perpetual nature nature of the magnetics.
So I'm able to apply a little trick here in the formation of this field, uh, and it's very small, but this the trick works no matter what the size of the magnet, because in in Boskowitz's um explanation as we understand this shit scales.
And it's it scales fantastically in our favor, okay.
So uh let me just divert for a second and say in our one-time deal to warp out a magnetic field, we discover that this value down here, the extra oomph, okay.
*sad music*
The extra oomph value that's required to fix the magnetic field decreases as the size of the or as the strength as the intensity of the dielectric increases.
All right, so the extra oomph required goes down as the strength of the unaltered field goes up.
And so it's so it's fantastic.
So as it scales, If I could physically handle, I mean, like physically pick them up and stuff, and overcome this amount right here, overcome that initial X by myself, I could do this with like um uh say I could get get 50 pound uh permanent magnets like this, right?
Get them all slicked up and polished and stuff, create one of these structures, uh, put it in a 55 gallon drum, because these things would be quite sizable, and then I could um uh put the lid on the drum and seal it all up.
I could take that 55 gallon drum and I could bury it under probably four or five feet of soil, and then I could come along with something and whoomp the earth, and that would shatter the magnet, just be just enough to overcome this value and cause that whole initial thing right there to re-explode to return it to that level.
And there's some time aspects of that too, because the longer it's compressed, the there's this lag component of a building creeping um uh I guess you'd want to say a propensity to gain further magnetic strength as it goes along, not dissipate.
And so, so, and then it would just blow the hell out of a big chunk of the earth.
You know, I don't mean like big chunk of the earth, I mean it would throw up, you know, a few few um a few dozen yards of dirt, that kind of thing, right?
And destroy the the 55 gallon drum and probably destroy the magnets as well.
Uh or or shatter them to a smaller return state.
But if you do it right, the the structure is quite stable.
And so there, I don't care.
I'm not trying to manufacture magnetic explosives.
Don't get me wrong, right?
That's not my point.
Um, they have some use underwater where you can't ah crap.
See, there it did.
I didn't even just so as I was saying underwater, I just shook it a little bit and it went boink.
Um they have some use under in places where uh it's difficult to sustain the explosive force without causing side effects, unwanted damage, scarring, and so on in the work you're trying to do.
All right, so you could, you could use magnetic explosives under those circumstances.
Um really in a magnetic explosive under those circumstances, just suddenly suddenly released magnetic field.
And it's not an EMP, okay, uh for some reasons that we can go into the dielectric exist.
It's not that we're contorting and creating any electricity in the process.
So, as far as I know, and I've had no, as far as my results uh so far, none of the experiments I've been doing along these lines have in any way interrupted my uh digital equipment around here whatsoever, right?
I do sometimes get resonance on uh digital electrical musical instruments that happen to be on uh they'll sometimes pick up um you know that that sort of thing from the effect of the magnetism being released in some of these experiments.
Um in any event, so it's tricky, but once you learn the technique, what you're basically doing is taking the structure, I told you I would tell you how it's done, and see it.
If you want to deliberately do it, it can sometimes be very difficult.
So there it is.
And what you're doing is you're folding, you're twisting, you're not squeezing the two wings together like that, or you can do ah, crap.
Okay, I see what I'm saying.
Okay, so you can do it, damn.
Hang on, hang on.
Okay, so you can do it that way, but it's extremely difficult.
I don't like doing it that way.
But basically, what I'm doing is I'm gonna squeeze these two opposing sides together.
I'm going to try and take the two south poles here on this on the on, let's just say the lateral, the horizontal ones, uh, in the middle here, and I'm going to try and take and pull them together, and those would be the two south poles trying to face each other.
While I'm doing that simultaneously, if I'm I'm gonna try and pull these two poles together here on the the lower and upper faces, and that's the two north poles together.
But but if you do that, you obviously get this fly apart approach, right?
But what you have to do is you have to use one of your fingers and twist one of the four elements involved so that you have three that are maintaining their status with each other, and then twist the other one so it's 90 90 um degrees out of phase with all of the others.
So you can actually feel it.
You can actually feel it with these small magnets.
And so uh you can do that, you can twist, and then you just twist one of them.
And when you do that, it locks it into place.
And so that's how you can create and form and distort magnetic fields for fun and profit, right?
Go ahead, take the idea, go out, figure out ways to make new magnetic door locks or whatever the hell, right?
You could make this into dozens of different kinds of stuff.
But be very advised that once you get up over these, what are those, three-eighths inch size, you're gonna start at half inch, three-quarter inch, man, three-quarters of an inch, you're gonna work your forearms like you would not believe to achieve that effect.
At one inch, you have to have equipment, and when the equipment fails, you are at risk because of that fly apart effect.
And you what basically ends up happening in when you're using these with one-inch magnets, is that the resulting magnetic force from the other three can propel one of those things fast enough and far enough to break two by fours and stuff in your wall.
Okay, punch right through sheetrock windows, uh uh dent the side of a freezer, uh, you know, damn near punch a hole in a metal cabinet.
So you've got to be really careful with this.
If you're gonna do this stuff, understand, read Boscovich first.
Don't just go out there and fuck around with it.
Um, because you'll kill yourself.
You know, I know I've very nearly have done that.
So um the the forces involved are cool.
And so now the now the and so on on this part here.
So now we've got the extra oomph.
Everybody understands what I'm talking about here with my magnetic experiments at the moment.
Um this is just an intervening stage, by the way, that we're headed to.
Let me get rid of these things.
Um this is just an intervening stage, right?
The goal is uh my floating RV, I need to have all different kinds of control systems, I need to have systems that actually uh provide the uh levitation support if we want to think of it that way, and so on and so on.
Um so it's necessary to investigate the fields and to work out all of these issues.
But now at this stage, it's also necessary in order to get to the more sophisticated use of those fields to develop shields.
So that's why I've started getting into various different uh ocular effects relative to light being delivered to my eyes.
Uh it is possible with devices to create incredible images of magnetic fields.
And you can see the twisting, you can see the limit points, you can see the repulsives, you can see the ordnance, you can see the um the ellipses, the whole thing, right?
And you can get a view of it that's that confirms everything Boscovich is saying.
Uh, and he said it in the 1700s.
But in order to do this kind of experimentation, it would be really helpful to be able to see these things in real time.
So the next goal, the secondary goal that we're trying to do, is to, I've got a couple of guys that are working with me, and that's usually why I'm getting up very early, is these two guys are in uh optics business, uh, one in in uh Europe and the other in Japan.
And uh we're trying to come up with optics that you'd be able to not only protect your eyes against this kind of phew effect, uh, but also to be able to put on these and be able to see the magnetic fields in as undistorted a fashion as we can.
But we don't really care about some levels of distortion because the they would get the uh uh the technology would get better over time, uh, but uh also because at some point uh you can make uh projections as to what's going to happen.
You don't have to see it down to a certain fine grade, you have to be able to see it how it's gonna collapse and twist and what the effects are and so on, and that's because in each and every one of these uh magnets, and it doesn't matter what the shape of the magnet is or how it was created, uh they're all kinds of impurities in the magnetic field that distort how the dielectric is putting out these corkscrews as the disruption occurs in the ether, right?
And so purity, and so this is why we're onto this materials quest and so on.
But it's going to really help in order to be able to do the manipulation to be able to see it as you're doing it.
Then it becomes a little bit easier to figure out torquing techniques, how much you have to move one in order to get the field over to here to get it locked by another one.
And so this is to some extent.
I find it similar to rope tricks.
Because I know a lot of knots and ropes and ways to make a knot seal and then be able to release it and under extreme conditions, heavy loads, hold half the load and snap, uh, you know, safety lines, uh, what are called rubber lines, uh, all of these kind of things where you can let the mass down half suddenly uh with and safely rapidly if you have to, uh, you know, because you've got the spring line on it and so on.
And it's very similar to that manipulating with the magnetic fields.
I find that conceptually, it helps to think of these as ropes of of magnets and uh magnetic force field uh lines twisting around this central core.
It's very difficult though to get into the uh conical aspect of that and to be able to wrap your head around how that conical aspect intrudes into the manipulation of the field itself.
Yeah.
Um so anyway, so uh so the shields I'm trying to talk about here are the the eye shields that also are going to provide us some kind of probably it'll have to be digital, and then we gotta worry about the impact of the electricity on ourselves as well as the uh you know our brains, but also as well as the experiment, because a lot of these magnetic experiments don't do well in the presence of electricity close to your body.
Uh obviously it has a tendency to distort the magnetic fields that you're attempting to uh create or manipulate for specific purposes.
Um first I set out just to validate Boscovich.
Now I understand that you can use Boscovich as Tesla did as like a training manual for whatever direction you want to go.
You know, creation of electricity, which is one part of the dielectric, dealing with the magnetism on the other side, which is the side I'm dealing with.
Uh there's also blends, there's all you know, power um control mechanisms, uh power production control mechanisms that are magnetic field oriented, so they're self-umling and self-failing and self-protecting.
Um they're basically all analog, so you know you'd have to have some kind of a digital interface to give you a number if you cared about it.
Uh, but in any event, so uh so that's the discussion here about the fields and the shields, and uh what and what in the demonstration.
And this is sort of like SBC, right?
Like this is the or no, BSC.
B S C the Boskowitz Social Club, uh, because it's kind of like, you know, uh computer programming, that kind of shit, where you do it in a group uh where we would have code reviews and everybody would sit around and say, okay, okay, I got this really, you know, uh uh butt shaping problem here.
How do I solve it?
Anybody ever run across this?
Is there a convenient design pattern that fits this?
And it was, you know, brainstorming, sharing ideas, and then you'd go off and write the code and come back and see how it worked, do the integration testing, yada yada yada.
Okay, so uh this kind of engineering uh I probably at this point it's safer to do it on your own, right?
Uh so far I haven't really put anybody else's life at risk with these magnets, but had I known what I was uh some of the effects, I wouldn't have started the way I did because I I was doing things that I now know to be very dangerous, and I was just, you know, the the luck of the stupid basically, uh, that it didn't fly apart and crack my skull open or something.
Um even these three eights, even these small magnets.
There's enough force in that little twisted tetrahedron there that if it were uh to shoot off that shot off from here and it shot off over easily two and a half feet, and it struck my metal retaining rod here.
That rod is there to protect me.
That that it should, because it's the way it's uh grounded and set up and stuff, it should have a and it does so far have a tendency to grab these things as they get out of hand.
Now uh mostly I do this behind a polycarbonate shield, right?
Uh so that uh it's sort of like a glove box, so that really the only part of me at risk is my hands and arms, but you'll if you can see it, I don't know if we can do that.
Some some nasty uh bruises as the bastards zing off your flesh.
Uh again, though, close, you're better off having it strike you very close than further away because of the nature of the impulse of the magnetism and the limit points.
So just be very advised, as I say here.
Let's write it down just so everybody understands.
Let's write it down just so everybody understands.
Okay.
This shit is dangerous.
Watch out, watch out.
All right, so I've got all other kinds of crap to talk about, but everybody's aware of all of the uh whack-a-doodle shit going on.
Wack-a-doodle shit's gonna continue, it's gonna get more wack-a-doodly, uh, there's gonna be more shit from the wackadoodles, and it's gonna pile higher and deeper.
People will probably, you know, over the next 40 years make PhDs out of analyzing all this wack-a-do shit.
The idea at this point is to survive the wack-a-doodle shit, thread your way through it, don't participate, stay out of the disease, stay out of the manipulation, don't get played by these fuckers, um, keep one's own counsel, work on your own stuff.
If you maintain this idea of uh non-expansive, non-participative, then you're not gonna get trapped into the communist parties of China's manipulation of the U.S. uh via social uh unrest, okay, which won't work.
It's the the poor stupid um people are thinking they're gonna have a Bolshevik revolution, but they they went to college, so they don't understand Bolshevik revolution succeeded only because the Russian revolution had succeeded before it and taken the Tsar out with all of his armies, etc.
Right?
It was the Russian people's revolution that did that.
And then in the time that they were they were forming the Russian people's Congress and running and building the Russian people's constitution, that's when the Bolsheviks took over.
And so it was a power play.
So the Bolsheviks were too weak to take over the social order completely.
They had to take it over when everything was dynamic and in shifting around.
We don't have those kind of conditions at the moment.
We have different kinds of dynamic and shifting around conditions, I grant you that, but not ones that favor uh communism taken over here in the United States.
You know, sorry guys, you're just gonna eat shit if you go that route.
Um, as you will discover fairly rapidly, because all of this stuff is time compressed, it's all going to play out this year.
Um took the Bolsheviks from the Russian revolution was taken over in 1917 by the Bolsheviks, and it took them 12 years until 1929 to subdue all of Russia.
It was that bad for them, right?
Because the Russians fought tooth and nail for 12 years uh against the rising um uh tyrannical rule of the people that declared themselves to be communists.
And you know, and we don't have those kind of conditions at the moment, nor do we have the 12 years to have this battle go on in the US uh for control here.
The climate and other things that gonna intrude on us right away.
So in the meantime, I'm gonna you know make my little uh floaty RV and make these um uh take these steps towards uh entirely different form of technology based on Tesla, actually based on Boscovich, okay.
Boscovich uh presents us with the dielectric, it's split into producing electricity and magnetism, okay.
So you can choose one, you can choose the other.
Tesla chose to get into the uh creation of energy for the uh uh embodiment of um or Or empowerment of uh humankind, how to put more energy into us, get more energy for uh every man in order to lift the entire species.
My approach is to uh put my mental energy into the magnetism.
I've emblematically labeled it as my float ERV because if I can achieve that, you wouldn't believe what we will have achieved, and we'll be able to go the shield route and be able to protect people from the crap that's coming in uh ways uh or in environmental ways from the environment.
Plus, we'll be able to go float off planet and do shit.
Uh so uh anyway, so like I say, that's the uh that's the end of this.
I'm trying to keep these things short.
I got a lot of shit to do.
Boscovich calls.
It's also uh cold as hell here.
We've got winter storms, uh truly winter storms, you know, for three and four inches of rain in a in 24 hours and uh debris like you wouldn't believe, washing up from appropriately um uh the same directions as we see in the winter, even though there's the summer berm on the beach.
So very uh clearly uh uh ice age conditions are starting to show up here on the coast.
I expect that that it'll be very hard to deny by the time we get through to December of this year uh that the ice age is here with us.
And we need to make um adjustments and do things now.
So, anyway, everybody get to work, read your Boscovich.
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