You Can't Measure Time

I did. I hate having to explain to friends that irrational doesn't mean stupid, but "without a ratio"

Yes, it's a very approachable video on a complex mathematical issue. I am passing it around. I really love mathematics, but it's sometimes difficult to explain this concept to people that are not into math but are curious about many things and will love to know.

"A very normal ball drop led me to infinity"
Literally every young man experiences this at a certain age.

@@donepearce "irrational doesn't mean stupid"
That irrational means illogical or unreasonable. It's not about numbers.

how do I get a two-way ticket to the "Numberland" :) ... how many dimensions are there, does anyone know 🤔

We could create a new set of numbers I would call the "useful numbers" which would be a countably finite set of numbers containing every number any human will ever need for any purpose. In that sense just describing or even thinking about a number would add it to that set, but that set would never be infinite.

Well if you have to measure it exactly you end up with uncountably infinite number of words to describe it considering the gravitational pull of all the objects with mass in universe along with quantum interactions and air resistance it experienced , so impossible....😂

In fact, wouldn't it be describable by relating the time (t) to the mass of the ball (m), acceleration due to gravity (g) and height of the bridge (h)?

… with a certain set of conditions that we could describe here in detail if we had an infinite amount of room but one of the conditions will be the time at which it was dropped so we’ll need to get the release time and then hope it’s an unfathomable miracle that the exact time of day she let go of the ball isn’t a transcendental, so here we go again…

nice try 😊

thanks :) there is a physicist and a mathematician in all of us and they struggle for power

Why 44 decimal places?

Now I wonder the likelyhood of it being an undescribable trancendental if restricted to 44 decimals instead of infinite. Is it now 0 instead of 100 percent?

@@backwashjoe7864 Because 5.39124760 * 10^-44 is the Planck time, the smallest meaningful timestep.

@@backwashjoe7864 A unit of Planck time is 5.39×10−44 seconds. It's the smallest unit of time that makes physical sense, at least according to current theories. There could be smaller segments of time, but we currently can't describe them through physics. That wasn't the point of this video though :)

better to study noncommutative time-frequency nonlocality a la Fields Medal math professor Alain Connes

Agree

The only video I've seen. Early on in the video, my thought, if you can define two points, there are always infinite number of points between them no matter how close they are together.

@@ralphparker not in the physical world, where we have a Planck length

I recommend you check out the Numberphile videos on the same subject. They are so much fun:
- *Transcendental Numbers - Numberphile*
- *All the Numbers - Numberphile*

And the explanation is so beautifully done by Jade turning her head around in a breathtaking way!

Thanks for watching!

plus that fast turn to a back camera.

Jade is incomparable. 😃😍

Rational is dual to irrational -- numbers.
Rational, analytic (noumenal) is dual to empirical, synthetic (phenomenal) -- Immanuel Kant.
Subgroups are dual to subfields -- the Galois Correspondence.
Homology (convergence, syntropy) is dual to co-homology (divergence, entropy).
The integers are self dual as they are their own conjugates -- the conjugate root theorem.
The tetrahedron is self dual.
The cube is dual to the octahedron.
The dodecahedron is dual to the icosahedron.
"Always two there are" -- Yoda.
Concept are dual to percepts" -- the mind duality of Immanuel Kant.
Mathematicians create new concepts from their perceptions or observations all the time -- conceptualization is a syntropic process -- teleological.
Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics!

@@ezrasteinberg2016 Comparable only to herself...which is one of those small sets she was describing, yes? :)

I'm just spit-balling here -- don't know if this is actually workable, but . . . .
I think we are all comfortable with pretending that her set-up (minus the limitations of the laptop) is capable of perfect precision, right?
What if she has a measuring system with multiple known time delay lines. So for one event, we could get hundreds of measurements of the time. Those delays could be calibrated to fall within certain known fractions of a CPU cycle. By comparing the measurements at the different "beats" we could get precision to many more decimal places (I think).
So, I'm certain that is the setup that she used :-)

@@fewwiggle Dude was clicking stop by hand. I don't think the speed of the processor is the biggest source of inaccuracy in that measurement :D.

I'd also argue that, given that we only have physics to describe a finite temporal resolution(thanks, Planck), you can one hundo find a rational number to describe the exact time, at least within our known physics.

The funny thing is, if you could measure time exactly, you would know nothing about the energy of the ball.

@@LarsPensjo check out Alain Connes 2015 talk to physicists on noncommutativity as the origin of time and entropy. Fascinating stuff! See Professor Basil J. Hiley for followup.

"almost certainly" I would go so far as to say certainly. Simply by bisecting the interval, we can achieve any arbitrarily small precision,!

@@PunnamarajVinayakTejas My review of math professor Joseph Mazur's book "The Motion Paradox" - reissued under a different title. Professor Mazur does an expert job of giving the behind-the-scenes wrangling of conceptual philosophy which gave rise to applied science. What is the difference between time and motion exactly? If that question seems too abstract, this book proves the opposite.
Most college graduates assume that Zeno's paradoxes of motion were solved by calculus with its continuous functions. Mazur puts the calculus at the heart of the book, from Descartes and Cavalieri to Galileo, Newton and last but not least Mazur's favorite: Gabrielle-Emilie de Breteuil.
In fact, upon investigation, one finds many top scientists still studying and learning from the anomalies in infinite measurement. Regarding relativity Mazur states the wonder of absolute motion is that it "conspires with our measuring instruments to prevent any possibility of detection."
As Mazur points out "we don't measure with infinitesmial instruments" and so the perceptual illusion of time continuity remains despite the reliance of science on discrete symbols. With attempts at a unification of quantum mechanics and relativity Zeno's paradoxes reemerge with full-force in the "Calabi-Yau manifold." Mazur writes that the original concept of dimension still holds but now means measuring more by abstract reason than by sight.
Although each scientist featured by Mazur appears to have increasingly solved the paradox of motion in the end I think Zeno will be avenged and science will return to right back where it started. There seems to be a deadlocked struggle between discreteness (particle) and continuity (wave) in science and Mazur argues that indeed Nature "makes jumps" despite seeming continuous. But Mazur admits we are left with "splitting operations that can take place only in the mind."

Right? She invaded my personal space bubble through the internet lol

Tell me about it. I watched that section on loop at 0.25x speed

Yeah. 'bummer' got me evry time

The rule of two -- Darth Bane, Sith lord.
Rational is dual to irrational -- numbers.
Rational, analytic (noumenal) is dual to empirical, synthetic (phenomenal) -- Immanuel Kant.
Subgroups are dual to subfields -- the Galois Correspondence.
Homology (convergence, syntropy) is dual to co-homology (divergence, entropy).
The integers are self dual as they are their own conjugates -- the conjugate root theorem.
The tetrahedron is self dual.
The cube is dual to the octahedron.
The dodecahedron is dual to the icosahedron.
"Always two there are" -- Yoda.
Concept are dual to percepts" -- the mind duality of Immanuel Kant.
Mathematicians create new concepts from their perceptions or observations all the time -- conceptualization is a syntropic process -- teleological.
Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics!

"No Mr Bond, I expect you to count the transcendental numbers"

That was sort of like what I was thinking, Quantum Mechanics tells us that there are fundamental limits to how precise any physical property can be defined, thus there will ALWAYS be a rational value that uniquely specifies a given possible value from all other possible values. Mathematics might have infintes and infintesimals, but the Physical Universe doesn't

@@RichardDamonThat proves you can’t have a perfect circle. Right?

@@RichardDamon " thus there will ALWAYS be a rational value that uniquely specifies a given possible value from all other possible values."
Nope, not even close.
All it means is that there is no 1 true value as it is always a range of possibilities. But for timescales that can still be shorter than a planck-time, it is just fundamentally impossible to measure.

@@ABaumstumpf No, it isn't a "Measurement" phenomenon, it is that time is actually indeterminate at that scale, so time doesn't exist finer than that. You could say that the idea of a "Precise Time" doesn't exist. Just as no integer exists between 1 and 2, no time exists between one time quanta and the next.

@@RichardDamon "it is that time is actually indeterminate at that scale, so time doesn't exist finer than that."
Nice claim, but again - that is not what is says.
Also "No, it isn't a "Measurement" phenomenon"
I never claimed that - so why the strawmen?
"Just as no integer exists between 1 and 2, no time exists between one time quanta and the next."
Which is 100% wrong.

We don't know if there is a finite smallest length. We just know that there is a smallest (Planck) length that it would even theoretically be possible to measure.

@@John_Fx It would be correct to say that it would be the smallest length *physically possible* which would apply to matter and energy within our universe. Anything smaller than that wouldn't make sense from a Physics perspective, which would include things like dropping a ball. Therefore, the amount of time, as well as the distance that the ball dropped, would be rational.

Rational is dual to irrational -- numbers.
Rational, analytic (noumenal) is dual to empirical, synthetic (phenomenal) -- Immanuel Kant.
Subgroups are dual to subfields -- the Galois Correspondence.
Homology (convergence, syntropy) is dual to co-homology (divergence, entropy).
The integers are self dual as they are their own conjugates -- the conjugate root theorem.
The tetrahedron is self dual.
The cube is dual to the octahedron.
The dodecahedron is dual to the icosahedron.
"Always two there are" -- Yoda.
Concept are dual to percepts" -- the mind duality of Immanuel Kant.
Mathematicians create new concepts from their perceptions or observations all the time -- conceptualization is a syntropic process -- teleological.
Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics!

This was really interesting, but I'm not sure, if I understood correctly. Are the following two statements correct? 1) "The natural numbers are able to assign a unique label to all algebraic numbers." 2) "A single transcendental number contains all natural numbers infinitely many times as intervals of its digits."

Thank you for watching!

Keep it in your pants Moses... she has a boyfriend.

@@thomasp.crenshaw185 he doesnt care

Rational is dual to irrational -- numbers.
Rational, analytic (noumenal) is dual to empirical, synthetic (phenomenal) -- Immanuel Kant.
Subgroups are dual to subfields -- the Galois Correspondence.
Homology (convergence, syntropy) is dual to co-homology (divergence, entropy).
The integers are self dual as they are their own conjugates -- the conjugate root theorem.
The tetrahedron is self dual.
The cube is dual to the octahedron.
The dodecahedron is dual to the icosahedron.
"Always two there are" -- Yoda.
Concept are dual to percepts" -- the mind duality of Immanuel Kant.
Mathematicians create new concepts from their perceptions or observations all the time -- conceptualization is a syntropic process -- teleological.
Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics!

​@@thomasp.crenshaw185"What is a comment that says more about the speaker than the spoken to?"

😂

But you van make only a finite amount of videos

​@@gabriellasso8808yes, but that just means there's a potentially infinite amount of videos you could still make on the subject 😝

​@@sVieira151countably infinite number of videos*

I thought Planck units were just what can be, in theory, meaningfully measured. As in, it doesn't mean there's nothing smaller, it's just that we would never be able to measure it.

Do numbers in general exist?

@@tomshieff You're right, it is currently unknown if the planck measurements are actually real or just limits of measurement. They can be calculated using the uncertainty principle and our current understanding of gravity (relativity), so until someone finds an accurate model of quantum gravity, no one knows if the planck measurements are actually real.

The limits that define the Planck units are fundamental, but it's definitely not known that everything is integer multiples of them.
This is similar to the idea behind loop quantum gravity, which experiments have found no evidence of (and good, albeit not 100% definitive, evidence against).

@@jb7650 That highly depends on what you mean by existing. Does the color red exist? Not red objects, but the color itself. Whether or not abstract objects exist is more of a philosophical question than a physics question. By "do not exist in the real world", I meant irrational distances or timespans, i.e. π seconds or √2 meters.

😂

​@@upandatomYour shorts are good, too, just less exciting to open the app and find! Definitely *not* terrible.

​@@CDCI3Yeah terrible is a strong word. They're nice. This is just better

I thought uncomputable and indescribable numbers were the same?

The transcendental numbers pi and e can be calculated to any given accuracy by a Turing machine,. so they are computable.

@@GarryDumblowski Computable numbers are described by their Turing machine, so they are describable.
The converse is not true. I will describe a number that is not computable. Start by enumerating all Turing machines T_1, T_2, T_3,. ... Set a_i = 0 if T_i halts and set a_i = 1 if T_i does not halt. Now let alpha = sum_i a_i/2^i. The number alpha is describable, because I just described it, but it is not computable.

I recently rewatched Matt Parker's Numberphile video "all the numbers" where he talked about the computable numbers, and the normal numbers(numbers which contain any arbitrary string of numbers)

​​@@ronald3836how is that number not computeable? If you chose to enumerate the machines by alternating between on that does halt and one that does not then your answer is a geometric series that converges and can be computed to any arbitrary level of precision.
It's 0.0101010... in binary which is 1/3?

Which means it actually is rational. Though I guess then the question becomes, what exactly counts as the start and the end. At the level of Planck times, the concept of "the moment it touches the floor" probably isn't so clear cut.

​@1vader I think that the instant that either the acceleration is first zero, or the velocity is first zero after release, would be two good candidates for defining "touching the floor". It depends on whether you want to define "touching the floor" to be defined as when it exerts enough force to have altered the object's velocity, or to define it as when the objectsvdownward velocity is cancelled. But then again, air resistance would affect those two points, so maybe it needs to be specified as occuring in a vacuum? 🤷🏻‍♂️

@@AMcAFaves That's still thinking on a way too macro level. Not all of the atoms of the ball will come to a stop at the same time. And at the scale of plank times, we could differentiate stuff on an even smaller scale where the particles might not even have something like a defined location. Actually, because of Heisenberg's uncertainty principle, I guess it wouldn't even be possible to know.

@@1vader Good point. I suppose the closest we could come would only be some sort of statistical model of the atoms in the object.

​@@1vaderBrilliant.... Our perception of touching holding seeing are actually averaged out of infinitessimely smaller events we can't perceive

i consider myself an imaginative person yet i struggle to imagine a liquid nitrogen cooling system in a stock-looking macbook outside with no visible condensation

The ending had me laughing out loud!

😂

Penso que não é bem assim, entendemos muitas coisas, porém somos limitados e essa limitação não se dá basicamente em nossa capacidade mental, ela se define mais pelo nosso tamanho em proporção ao universo ao redor, não entendo que haja algo que a mente humana esteja impossibilitada de entender para sempre, mas certamente há muito que não podemos alcançar, medir, ver etc, ou seja, coisas que são necessárias para que possamos chegar no entendimento. Não é uma questão de inteligência, mas de nossas limitações em relação ao contexto onde estamos inseridos. Pior que, uma das coisas que entendemos, é que tinha que ser assim, pelo menos nesse universo nessa vida, não haveria como ser diferente.

we have invented maths, but cant understand everything in maths.

Rational is dual to irrational -- numbers.
Rational, analytic (noumenal) is dual to empirical, synthetic (phenomenal) -- Immanuel Kant.
Subgroups are dual to subfields -- the Galois Correspondence.
Homology (convergence, syntropy) is dual to co-homology (divergence, entropy).
The integers are self dual as they are their own conjugates -- the conjugate root theorem.
The tetrahedron is self dual.
The cube is dual to the octahedron.
The dodecahedron is dual to the icosahedron.
"Always two there are" -- Yoda.
Concept are dual to percepts" -- the mind duality of Immanuel Kant.
Mathematicians create new concepts from their perceptions or observations all the time -- conceptualization is a syntropic process -- teleological.
Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics!

Injective is dual to surjective synthesizes bijective or isomorphism (duality).
Rational is dual to irrational -- numbers.
Rational, analytic (noumenal) is dual to empirical, synthetic (phenomenal) -- Immanuel Kant.
Subgroups are dual to subfields -- the Galois Correspondence.
Homology (convergence, syntropy) is dual to co-homology (divergence, entropy).
The integers are self dual as they are their own conjugates -- the conjugate root theorem.
The tetrahedron is self dual.
The cube is dual to the octahedron.
The dodecahedron is dual to the icosahedron.
"Always two there are" -- Yoda.
Concept are dual to percepts" -- the mind duality of Immanuel Kant.
Mathematicians create new concepts from their perceptions or observations all the time -- conceptualization is a syntropic process -- teleological.
Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics!

Thank you for watching and supporting :)

Synthetic a priori knowledge -- Immanuel Kant.
Knowledge is dual according to Immanuel Kant.
Rational is dual to irrational -- numbers.
Rational, analytic (noumenal) is dual to empirical, synthetic (phenomenal) -- Immanuel Kant.
Subgroups are dual to subfields -- the Galois Correspondence.
Homology (convergence, syntropy) is dual to co-homology (divergence, entropy).
The integers are self dual as they are their own conjugates -- the conjugate root theorem.
The tetrahedron is self dual.
The cube is dual to the octahedron.
The dodecahedron is dual to the icosahedron.
"Always two there are" -- Yoda.
Concept are dual to percepts" -- the mind duality of Immanuel Kant.
Mathematicians create new concepts from their perceptions or observations all the time -- conceptualization is a syntropic process -- teleological.
Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics!

Glad to see this comment. It reminded me to become a Patreon

are you not really a patron?

You know this might actually simplify the problem. You could define the time to be exactly 2 seconds for some observer, and then leave finding the observer as an exercise for the student.

@@pontifier It doesn't get shorter than in the freely falling frame of the ball itself though, so since that is around 2.4s, your 2s isn't feasible, I fear...

@@landsgevaer dang, you're right... Let's set it to 3

The problem is you haven't described it precisely enough to make it reproducible.
The ratio of the diameter of a circle to its circumference is reproducible because it's based on theoretically perfect geometric objects.
If you were to reproduce her experiment, the probability of measuring the exact same number is essentially zero because there's no way for you to perfectly replicate the experiment to infinite precision. All of the subtle forces of gravity from the Earth, Sun, Moon, etc... would all be different and would result in a different measurement.
So for you to describe her number, your description would also have to specify the exact initial conditions of her experiment including for example the starting height, time it was dropped, etc.., but those numbers when measured to infinite precision are ALSO likely to be indescribable.
So there actually isn't any way to perfectly describe her experiment to reproduce her exact number.
The way you described it doesn't specify her specific number, it specifies an infinite set of numbers.

Rational is dual to irrational -- numbers.
Rational, analytic (noumenal) is dual to empirical, synthetic (phenomenal) -- Immanuel Kant.
Subgroups are dual to subfields -- the Galois Correspondence.
Homology (convergence, syntropy) is dual to co-homology (divergence, entropy).
The integers are self dual as they are their own conjugates -- the conjugate root theorem.
The tetrahedron is self dual.
The cube is dual to the octahedron.
The dodecahedron is dual to the icosahedron.
"Always two there are" -- Yoda.
Concept are dual to percepts" -- the mind duality of Immanuel Kant.
Mathematicians create new concepts from their perceptions or observations all the time -- conceptualization is a syntropic process -- teleological.
Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics!

One down. Uncountably many to go! Better get cracking!

And there's a further problem with the "describable" label... What's the smallest number that CANNOT be described using words? 😈

Sure, you could declare that the ball takes exactly 1 Bleep to reach the ground. But would that be usefull ?
As soon as you want to translate your Bleep unit into another unit like the second, you'll be back to square one.
Unless you decide your Bleep unit is the new standard, and any time measurement must be expressed in Bleeps. However if your goal is to avoid dealing with strange numbers, then you must create a new unit fit for any new measurement you make, and forget about comparing results between experiments. Maybe that's not such a good idea after all. :p

@@theslay66 - Did you fail to understand my last sentence? I tried to make it succinct so the reader would have a little "aha" moment. Was it effective for you?

@@rubiks6 Your last sentence doesn't solve the problem in any way.

Rational is dual to irrational -- numbers.
Rational, analytic (noumenal) is dual to empirical, synthetic (phenomenal) -- Immanuel Kant.
Subgroups are dual to subfields -- the Galois Correspondence.
Homology (convergence, syntropy) is dual to co-homology (divergence, entropy).
The integers are self dual as they are their own conjugates -- the conjugate root theorem.
The tetrahedron is self dual.
The cube is dual to the octahedron.
The dodecahedron is dual to the icosahedron.
"Always two there are" -- Yoda.
Concept are dual to percepts" -- the mind duality of Immanuel Kant.
Mathematicians create new concepts from their perceptions or observations all the time -- conceptualization is a syntropic process -- teleological.
Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics!

@@hyperduality2838 - Okeydoke.

I think Fred is a better name.

Thanks for helping!

😂

Me too!

At one moment I thought the Stern-Brocot Tree would make an appearance… a clean way to show every positive rational number (well, by clean I mean there are no duplicates)… and you can do a binary search on it with your irrational number and each further depth on your search leads you to a better approximation, already in reduced form.

Thank you for watching! Maybe you can show it to your daughter :)

@@upandatom I forwarded the link to my daughter. As a math junkie I know she will love it.

Well, for calculus, you don't need the different types of infinity. All you need to know is if a quantity is bounded or grows unbounded. That's true for science, engineering, and many other fields of math as well. Even within math, the different infinities arise only when you get deep into Axiomatic Set Theory. Which-however fascinating it is in its own right-isn't useful in science and engineering.
After all, human knowledge is so vast, it's impossible to learn all of it in one lifetime, let alone a mere 4 years of college. If you want to graduate in a reasonable amount of time-so that you can leave academia, come out into the real world, solve real-world problems, and earn a living-it shouldn't come as a surprise that you were taught very specific subjects that were relevant to your major, while vastly more subjects were left untaught. Luckily, we all have the option to learn more if we are so inclined.

@@nHansWell said. As I approach retirement I still learn new things every single day. Keep my brain active. I'm too nerdy to do otherwise :)

Well the idea behind that last point wasnt to be practically useful. It's that no matter how useless or useful, we simply cannot describe 100% of all numbers (statistically)
But yeah that is indeed a description

@@fahrenheit2101 Yup, that's right.

thank you so much :)

Yeah, that got me too (to laugh out gently). ;-)
So nice.
Thanks!( to Jade) and to you, putting into words what I thought to say as well.

thank you so much!

@@upandatom Simply wonderful - having you been taking drama courses, too?

We are all Jade. 👏

Haha no we didn’t 🥲

Thank you! Yes it’s a fascinating concept :)

@@upandatom it really is!

How precisely can you define that velocity you mentioned however? You will run in the same problem eventually, since you are just shifting on what part of the equation of the event needs to be exactly defined.
You will also run into the whole issue of uncertainty at a certain level of precision where it becomes involved in quantum dynamics and that is just opening another can of worms outside of just the mathematical principles of it.

But wouldn't that be describing an approximation of the number? Like, if you try to reproduce the number based in this description, you would get very similar results, sure, but you can't guarantee the same number to pop up? I'm not a mathematician tho, so idk

I have a similar question. The problem only arises because of the units you select. You could just say, the time it took is 1 Ballbridge, which is the amount of time it takes for this ball to fall from this bridge under these conditions. Then the problematic number becomes how many seconds there are in a Ballbridge, which you can just describe as "the number of seconds in a Ballbridge." What is the number you can't do this for? If you talk about it, you've described it.

Each of the other numbers you mention (height) has the same problem of being hard (impossible) to know exactly. Theoretically. In a physical world made up of quantum elements, "infinitely exact" isn't a meaningful concept.

In theory, technically, the number you get by the result of a given experimental process can be described as "the result of (description of the experimental process)", that that description does not actually tell us anything meaningful - the whole point of describing a number that is the answer to some question is to be able to understand that answer in some greater, more meaningful context.
There is also the problem that a given description may not actually describe a specific number, or may require as part of its description other 'merely describable' numbers - for example, your suggestion involves things like the acceleration due to gravity at Earth's surface (itself only an approximation, and a number which varies from moment to moment, with latitude and longitude, and with height above the surface), and also involves descriptions of individuals who are not constant with time, performing actions with initial conditions that are not specifiable with exactness except to describe them 'as what they are' in the same ultimately unhelpful way.
Which is all to say that, in a very technical sense, the number is technically describable as the result of a very specific description of events which happened, described unambiguously (though only descriptively) in their time and location, the actual value of that number becomes utterly inaccessible - Describable numbers need not be computable.
We then reach an interesting philosophical possibility - we are assuming that all mathematically possible numbers are physically possible. We know that, for example, pi (square units) is the area of a circle that is one unit in radius... but *can we physically make a circle*? Does it physically matter if we cannot exactly express pi if we cannot *make* pi in the physical world? After all, there is some evidence that space is, in a sense, 'pixelated', quantized with some minimum possible meaningful distance, meaning any attempt at any physical circle will only be 'approximately' a circle. Likewise, even with something as simple as sqrt(2), can we say with certainty that a triangle with unit legs can physically exist to the point that its hypotenuse is an irrational value, given that the length of that hypotenuse must be some whole number multiple of that minimum possible length (so must therefore be rational).
Perhaps it is not so surprising that we cannot meaningfully describe most of the numbers that can mathematically exist, since, even as big as the observable universe is, it is finite, and thus can only contain a finite number of combinations of things... If the entire universe, and all 10^80 particles it contained were a mechanism for storing binary data, it could only represent 2^(10^80) different unique states - a very very large number, but still finite.

Actually, there's even better basic question: Does the inability to form pairing with integers implies that the set is bigger?
Consider the rationals again. Whether you construct a 1-to-1 mapping with naturals depends on which order you choose to count them. Some of the infinite possible permutations of rationals map to naturals (like the diagonal case) and some don't (like the row-by-row case). It is entirely possible that the set of reals is no bigger than set of naturals and all if its permutations are not 1-to-1 mappings to naturals.
As a very rough imperfect analogy, just because a cube can't fit inside a triangle does not mean it's bigger. It may simply be of "incompatible shape" but the same size.

​@@KohuGaly I can answer that for you. When one or both sets are finite, it's pretty straightforward to figure out which is bigger. The difficulty arises only when both are infinite. Particularly because-as you pointed out-depending on how you do the mapping, sometimes set A will seem bigger, and sometimes set B will seem bigger.
So mathematicians define it this way: If there is at least one way in which the two sets can be put into a 1-to-1 correspondence with each other, then they have the same cardinality (i.e. size). It doesn't matter if you can find other mappings where one set appears bigger than the other. In fact, you can always find alternative mappings where either of the sets can be made to appear bigger than the other. But, like I said, it doesn't matter. So long as a 1-to-1 mapping exists, the sets are of the same cardinality-other mappings notwithstanding.
With Integers and Rationals, you can put them in a 1-to-1 mapping by following the technique discussed in the video. (The video paired Positive Integers to Positive Rationals, but you can easily extend the idea to include all Integers and all Rationals.) That's why they have the same cardinality. Sure, there are other mappings where the Rationals appear bigger, because, after all, the Integers are a proper subset of the Rationals. Strangely enough, you can even find mappings where the Integers appear bigger. But those don't matter, because a 1-to-1 correspondence exists.
For the same reason, Odd Numbers and Integers have the same cardinality, though-again-Odd Numbers are a proper subset of the Integers.
If no 1-to-1 correspondence exists, we say that the two sets have different cardinalities. Note that you have to _prove_ that a 1-to-1 correspondence is impossible. That's exactly what Cantor did-he _proved_ that Rationals and Reals _cannot_ be put into a 1-to-1 mapping with each other. So they are of different cardinalities. His proof showed that regardless of how you map rational numbers to real numbers, there will always be at least one real number left over that cannot be matched to rational numbers. So the cardinality of real numbers is greater than that of rational numbers.
Let me give you my own analogy. Suppose we want to find if 25 is a perfect square. We examine a few potential roots: 3x3=9, 4x4=16, 6x6=36. So we found some numbers, which when squared, _don't_ give 25. Does that mean that 25 is not a perfect square? No, because there exists at least one number, 5, which when squared, does give 25. That's sufficient to say that 25 is a perfect square. The behavior of other numbers when squared doesn't matter. This is analogous to showing that Integers and Rationals _can_ be paired 1-to-1.
What about 30, is that a perfect square? Well, 5x5=25, 7x7=49, 10x10=100. So 5, 7, and 10 are not square roots of 30. Does that prove that 30 is not a perfect square? No, that wasn't a satisfactory proof. Maybe an integer that we didn't examine could turn out to be the square root of 30. To prove that 30 is not a perfect square, we have to prove that no integer exists which, when squared, gives 30. (Can you prove that 30 is not a perfect square?) This is analogous to showing that Reals and Rationals can _never_ be paired 1-to-1.

Rational is dual to irrational -- numbers.
Rational, analytic (noumenal) is dual to empirical, synthetic (phenomenal) -- Immanuel Kant.
Subgroups are dual to subfields -- the Galois Correspondence.
Homology (convergence, syntropy) is dual to co-homology (divergence, entropy).
The integers are self dual as they are their own conjugates -- the conjugate root theorem.
The tetrahedron is self dual.
The cube is dual to the octahedron.
The dodecahedron is dual to the icosahedron.
"Always two there are" -- Yoda.
Concept are dual to percepts" -- the mind duality of Immanuel Kant.
Mathematicians create new concepts from their perceptions or observations all the time -- conceptualization is a syntropic process -- teleological.
Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics!

Rational is dual to irrational -- numbers.
Rational, analytic (noumenal) is dual to empirical, synthetic (phenomenal) -- Immanuel Kant.
Subgroups are dual to subfields -- the Galois Correspondence.
Homology (convergence, syntropy) is dual to co-homology (divergence, entropy).
The integers are self dual as they are their own conjugates -- the conjugate root theorem.
The tetrahedron is self dual.
The cube is dual to the octahedron.
The dodecahedron is dual to the icosahedron.
"Always two there are" -- Yoda.
Concept are dual to percepts" -- the mind duality of Immanuel Kant.
Mathematicians create new concepts from their perceptions or observations all the time -- conceptualization is a syntropic process -- teleological.
Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics!

Who?

How did you type the square root symbol? Was it on mobile?