Universal Acceleration - falling slinky experiment
« on: July 17, 2018, 05:02:51 AM »
How the FErs want to take on the video where UA is debunked.


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Offline Pete Svarrior

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Re: Universal Acceleration - falling slinky experiment
« Reply #1 on: July 17, 2018, 08:39:23 AM »
Let us begin with a friendly reminder that, as per Einstein's Equivalence Principle, UA is should be locally indistinguishable from the RET gravitational model. This is, in effect, part of your own model (or at least an undeniable consequence thereof). By proposing that you could locally distinguish between UA and RET from just slightly above the Earth's surface, you are doing more to attack your own model than ours.

But let's consider the mechanics of a slinky, and figure out why it's the top that falls first. I'll explain the issue in layman's terms, but if you'd like more detail, there are plenty of resources available online. I will also ask for some patience from our native English speaker lounge - I'm certain I got some of my terminology wrong. Mechanics is not my strongest field, and translating this stuff on the fly is tough business.

Though it ultimately won't matter, let's assume that the Earth's gravity operates exactly as it would in the Round Earth model for now. The answer is tension.  As the slinky's springiness causes it to contract back to its normal state, we can easily illustrate the forces acting on both ends of the slinky like so:



These is just an illustration of how tension works on the slinky itself, with no account of any other forces. I'll glance over some details for the sake of brevity and assert that the scalar FS1 is equal to FS2 - a slinky is generally close enough to uniform, so naturally the tension would be distributed evenly.

Now, we know that the slinky was released by someone holding it off the top of a bridge, and that the slinky was at rest just prior to that. What caused it to expand? Right now, I'm assuming RET, so the answer is simple: weight. The slinky got pulled apart until the spring's internal forces were able to balance out its weight. If this were not true, we'd be observing the slinky either expanding or contracting prior to being released. In other words, we now know that at the time of the slinky's release FS2 was equal to W. Again, since the slinky is largely uniform, weight will affect both ends of the slinky equally, like so:



So, why does the slinky fall top-first in a Round Earth model? We know that FS2=W, and thus the bottom of the spring is in equilibrium at that very moment. Meanwhile, the top of the spring is affected by two downward forces. The top starts falling, but the bottom doesn't. The balance of forces changes over time, but the entire scene doesn't take long, so for most practical purposes the bottom doesn't move until the slinky mostly contracts on itself.

Right, so that's RET covered. How does FET change? Well, weight is (mostly) gone, so we're back to our first diagram - except this time the entire world is accelerating upwards:



We have to ask ourselves the same question we did before - how did the spring get to its expanded-yet-resting state? This time, the bottom of the spring was not being held by anything, and the Earth was accelerating upwards, together with the person holding the spring, and the spring's top. But not the bottom. Eventually, we reached a state where the spring's tension would cause the bottom of the spring to accelerate in tandem with the rest of the system. At this point it's more intuitive for me to think of the system in terms of acceleration rather than force, but the conversions are trivial, so please just bear with me.

We now know the following about our scenario:
  • The bridge, person on the bridge, and the top of the spring are accelerating upwards at ~9.81ms^-2 due to UA
  • The bottom of the slinky is also accelerating upwards at ~9.81ms^-2 due to the spring's restoring force

    Immediately prior to the spring's release, we'd be looking at something along the lines of:

    Where FX=FS1*2
  • The spring is now released, so the top is no longer subject to UA (and, indeed, starts accelerating downward due to the same restoring forces), while the bottom remains at equilibrium

As expected, these situations are precisely analogous - it's just representing the same scenario from an inertial vs non-inertial frame of reference. The error in the video is assuming that the bottom of the slinky is not accelerating together with the Earth - but we know it must be, it's a fundamental consequence of how the experiment was set up. After all, if these were not analogous, RET would be an impossibility and we wouldn't need to have this discussion :)
« Last Edit: July 17, 2018, 09:00:53 AM by Pete Svarrior »
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Re: Universal Acceleration - falling slinky experiment
« Reply #2 on: July 17, 2018, 09:20:57 AM »
Pete is right.
UA on FE is generally indistinguishable from RE gravity on earth.

But there are many differences, though they are harder to detect:

Since the earth is not a perfect sphere, there are locations where gravity is slightly less or more on RE.
Since the earth is spinning, the gravitational force at the equator is negated ever so slightly from the centrifugal force on RE.
Gravity on RE is dependent on the distance to the object, and as such we have lower gravitational force at higher altitudes.
Since the moon is so big and close, it also opposes the gravitational force, most noticeable by creating tides both on the earth side facing the moon and the opposite side of earth on RE.
The sun is so far away from RE, that it really makes no difference in the forces here on earth.

On FE, the excuse is Celestial Gravitation, which doesn't explain the constant gravitational difference at the equator, doesn't explain tides at the opposite side of the moons location, and doesn't explain why the sun doesn't create tides like the moon (even though its the same altitude and size), it also doesn't explain lesser gravitational force at higher altitudes or different locations.
« Last Edit: July 17, 2018, 09:22:37 AM by SphericalEarther »

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Offline Pete Svarrior

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Re: Universal Acceleration - falling slinky experiment
« Reply #3 on: July 17, 2018, 11:40:10 AM »
Regardless of other contentions, I hope we can agree that this particular argument is not strong, and that the thread title of "UA debunked" is a bit far-fetched in this instance.
Read the FAQ before asking your question - chances are we already addressed it.
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BillO

Re: Universal Acceleration - falling slinky experiment
« Reply #4 on: July 17, 2018, 12:00:22 PM »
Yes, that video is completely wrong.  The shown behavior of the slinkies would be exactly the same under UA.  The force acting on the bottom of the spring due to the tension in the spring must necessarily be exactly enough to counter the acceleration, either due to gravity or otherwise.  To suggest it wouldn't is to admit you don't know how springs work.  I detest video's like that.

However the 'contentions' brought up by SphericalEarther are hard to ignore and should not be brushed aside so quickly in a thread entitled "UA is debunked".  Unless a model can be formulated to be consistent with those contentions and UA, then UA is effectively debunked and should be removed from your FE hypothesis.  It's being there is really doing you no good.

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Offline Pete Svarrior

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Re: Universal Acceleration - falling slinky experiment
« Reply #5 on: July 17, 2018, 12:15:53 PM »
BillO, you continue to struggle with the rules here. The OP is about a very specific subject. I asked that we don't go off-topic, to which your response is "no, we should go off-topic". That's not on.

If you want to discuss your other issues with UA, there are already threads about these subjects - this is another reason as to why trying to hijack this thread and turn it into another CG thread is not helpful. Meanwhile, given that this thread is not a successful debunking of UA, I will re-title it into something more appropriate so that it can be easily found in the future.
« Last Edit: July 17, 2018, 12:18:37 PM by Pete Svarrior »
Read the FAQ before asking your question - chances are we already addressed it.
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Re: Universal Acceleration - falling slinky experiment
« Reply #6 on: July 17, 2018, 06:46:59 PM »
Regardless of other contentions, I hope we can agree that this particular argument is not strong, and that the thread title of "UA debunked" is a bit far-fetched in this instance.
I agree, slinky experiment proves absolutely nothing.

I have though seen some FEers claim a slinky is proof against RE gravity, but they were youtube FEers.

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Offline Pete Svarrior

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Re: Universal Acceleration - falling slinky experiment
« Reply #7 on: July 17, 2018, 07:36:26 PM »
I have though seen some FEers claim a slinky is proof against RE gravity, but they were youtube FEers.
Yeah, I've seen that (only today, while trying to figure out how big the "slinky debate" is). I think we can safely agree that arguments on both sides stem from a misunderstanding of the mechanics at hand
Read the FAQ before asking your question - chances are we already addressed it.
Follow the Flat Earth Society on Twitter and Facebook!

If we are not speculating then we must assume

BillO

Re: Universal Acceleration - falling slinky experiment
« Reply #8 on: July 18, 2018, 03:18:20 AM »
Yeah, I've seen that (only today, while trying to figure out how big the "slinky debate" is). I think we can safely agree that arguments on both sides stem from a misunderstanding of the mechanics at hand
Very true on both sides of this question and many more.  Sometimes it seems difficult to sift through all the nonsense on Youtube.