Where are the irrational numbers?

In summary, the series of rational numbers is continuous, and between any two rational numbers, there exists another rational number. However, there is an infinite number of irrationals between any two rational numbers.
  • #1
smolloy
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Rational numbers are those that can be represented as a/b.

It is simple (I think) to demonstrate that the series of rationals is continuous, since, for any two rational numbers, X=a/b, and Y=c/d, you can always find at least one rational number between them.
[tex]\frac{X+Y}{2} = \frac{ad+bc}{2bd}[/tex]
This derivation works for *any* pair of rational numbers, no matter how close, so the series of rationals is continuous.

But, doesn't this mean that there is nowhere -- no gaps -- in which we can fit irrational numbers?

Does this mean that, logically speaking, pi doesn't really exist between 3.14 and 3.15 on rational number line?

Do the irrationals exist in a completely separate series to rationals (similarly to the way in which reals and imaginary numbers are on different series)?

Perhaps I should put my copy of Russell's "Principles of Mathematics" away, and stop pretending I'm a mathematician? ;)
 
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  • #2
Your "proof" is that between any 2 rationals is another rational. This still does not make a continuum.
 
  • #3
Hmmm... I thought that that was the definition of a continuum. No?

Between *any* two rationals is another, third, rational. So between the third rational and one of the first two is yet another, fourth, rational. Etc. Ad infinitum.
 
  • #4
Like mathman said, just because there exists a rational number between rational numbers a and b, this doesn't mean that there's no irrational numbers between a and b. In fact, there exists an infinite number of irrational numbers between a and b.
 
  • #5
Thanks guys.

So, between the rationals a and b, there exists an infinite number of other rationals, as well as infinity of irrationals. Two series interlaced within the series of the reals. Yes?
 
  • #6
smolloy said:
Thanks guys.

So, between the rationals a and b, there exists an infinite number of other rationals, as well as infinity of irrationals. Two series interlaced within the series of the reals. Yes?

Yes, in fact the union of the set of rational numbers and irrational numbers is equivalent to the set of real numbers.
 
  • #7
OK. This is becoming clearer. I was tricked by the seemingly illogical impossibility of interleaving two continuous series, but I guess "common sense" breaks down when you start to consider infinite numbers and infinitesimals.

Could an irrational be considered to be defined as the limit of some converging series of rationals? In fact, can't such a series be used to converge to pi?
 
  • #8
smolloy said:
OK. This is becoming clearer. I was tricked by the seemingly illogical impossibility of interleaving two continuous series, but I guess "common sense" breaks down when you start to consider infinite numbers and infinitesimals.

Could an irrational be considered to be defined as the limit of some converging series of rationals? In fact, can't such a series be used to converge to pi?

Well, I know some irrational numbers can. For instance:

[tex]\sum_{n=1}^\infty \frac{1}{n^2} = \frac{\pi ^2}{2}[/tex]

All of them though? That I'm not sure about.
 
  • #9
Oh, I wasn't suggesting all irrationals could be defined as a limit. I meant "an irrational" -- meaning that there are one or more irrationals that could be defined in this way. Then it struck me that there was an ancient method for finding an approximation to pi that can be extended to an infinitely long series converging to the irrational value of pi.

Something to do with finding the circumference of an n-sided regular polygon, and then letting n go to infinity and then dividing by the diameter.
 
  • #10
Actually the property of the rationals you are describing when you say that "between any two rationals (or indeed, any two real numbers) is another rational" is the property of the rationals being dense in the space of all real numbers. And this is equivalent to the existence, for any real number x, of an infinite sequence of rational numbers which converges to x. For example, any irrational number can be written as a non-repeating decimal, eg, 0.343512309..., and the following is a sequence of rationals converging to it: 0.3, 0.34, 0.343, 0.3435, ... .
 
  • #11
gb7nash said:
Well, I know some irrational numbers can. For instance:

[tex]\sum_{n=1}^\infty \frac{1}{n^2} = \frac{\pi ^2}{2}[/tex]

All of them though? That I'm not sure about.
.


I don't know if this is what you are referring to, but you can cut the first terms of the
decimal expansion of an irrational to get a sequence of rationals that converge to it,
e.g., for Pi:

a<sub>1</sub>=3

a<sub>2</sub>=3.1

......

.......

a<sub>n</sub>=3... (first n digits in decimal expansion of Pi)


Same for any irrational --or rational.

I didn't notice that Static X had already said this.

Sorry, my "quote" button suddenly became disabled after my first quote.


Smolloy: AFAIK, there are no infinitesimals at play here; you seem to be doing standard
analysis. It is an issue of order properties of the reals and their subsets. By a different
perspective, the rationals are not really continuous: the rationals are a totally-disconnected subspace of the reals.
 
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  • #12
Bacle said:
.
I don't know if this is what you are referring to, but you can cut the first terms of the
decimal expansion of an irrational to get a sequence of rationals that converge to it,
e.g., for Pi:

Of course. I think the OP was looking for a closed formula to determine the nth digit of an irrational number (in this case pi) in the form of a series, but I could be mistaken.
 
  • #13
Every real number can be written as the limit of a converging sequence of rationals, (e.g. their decimal expansion up to the n'th digit), and we often define the real numbers as the equivalence classes of converging sequences of rational numbers, where two sequences are equal if their difference converge to 0.
 
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  • #14
gb7nash said:
Well, I know some irrational numbers can. For instance:

[tex]\sum_{n=1}^\infty \frac{1}{n^2} = \frac{\pi ^2}{2}[/tex]

All of them though? That I'm not sure about.

yes you can construct a cauchy seqence of rational numbers by "truncation of digits" given an irrational number this is how you complete the rationals into the reals
 
  • #15
prove that between any two rational numbers, there is a rational number; then prove that between any two rational numbers there is an irrational number ( you can take an irrational number between 0 and 1 to start with ) ; then you are all set to prove that for any x and y in the reals there is an irrational number in between them
 
  • #16
smolloy said:
Rational numbers are those that can be represented as a/b.

It is simple (I think) to demonstrate that the series of rationals is continuous, since, for any two rational numbers, X=a/b, and Y=c/d, you can always find at least one rational number between them.
[tex]\frac{X+Y}{2} = \frac{ad+bc}{2bd}[/tex]
This derivation works for *any* pair of rational numbers, no matter how close, so the series of rationals is continuous.

But, doesn't this mean that there is nowhere -- no gaps -- in which we can fit irrational numbers?

Does this mean that, logically speaking, pi doesn't really exist between 3.14 and 3.15 on rational number line?

Do the irrationals exist in a completely separate series to rationals (similarly to the way in which reals and imaginary numbers are on different series)?

Perhaps I should put my copy of Russell's "Principles of Mathematics" away, and stop pretending I'm a mathematician? ;)

The amount of irrational numbers is VERY MUCH MORE than rational numbers. Draw a line and put 2 notches, label the notch on the left 0 the notch on the right 1. Place the tip of your pencil somewhere on the line. Do this every second for the next BILLION YEARS! I would be very surprised if you could hit a rational number even once! In fact, I'm not even sure you could hit the line, but let's pretend you could hit the line every time. I still don't think a rational number could be hit even after a TRILLION YEARS etc. So according to this 'thought' experiment someone can say rationals DO NOT EXIST because you are pointing to an irrational ALL THE TIME! In probability, the probability of pointing to a rational is 0% the probability of pointing to an irrational is 100% The infinity of irrationals 'swallows' up the infinity of rationals and rationals become insignificant as compared to irrationals. Isn't that amazing? I recommend you read about Georg Cantor, father of elementary set theory and how he analyses infinity.
 
  • #17
agentredlum said:
The amount of irrational numbers is VERY MUCH MORE than rational numbers. Draw a line and put 2 notches, label the notch on the left 0 the notch on the right 1. Place the tip of your pencil somewhere on the line. Do this every second for the next BILLION YEARS! I would be very surprised if you could hit a rational number even once! In fact, I'm not even sure you could hit the line, but let's pretend you could hit the line every time. I still don't think a rational number could be hit even after a TRILLION YEARS etc. So according to this 'thought' experiment someone can say rationals DO NOT EXIST because you are pointing to an irrational ALL THE TIME! In probability, the probability of pointing to a rational is 0% the probability of pointing to an irrational is 100% The infinity of irrationals 'swallows' up the infinity of rationals and rationals become insignificant as compared to irrationals. Isn't that amazing? I recommend you read about Georg Cantor, father of elementary set theory and how he analyses infinity.

The more technical reason for this is that the rational numbers between 0 and 1 are countable and the irrational numbers between 0 and 1 are uncountable. It's pretty cool that there's practically no chance of "picking" a rational number.
 
  • #18
Also, consider the famous Dirichlet function in x-y plane. It goes like this...'let y= 0 for x rational, let y=1 for x irrational This 'piecewise' defined function has the amazing property of being DEFINED everywhere on the real x-axis but being continuous NOWHERE in the x-y plane! So the notion of continuity is 'tricky' and the notion of 'in-between' becomes meaningless as soon as you dive into the realm of fractions and beyond. One final 'nightmarish' thought...if you are fortunate enough to swim out to the realm of complex numbers...you lose the notion of ORDER so you cannot tell which one comes before or after another! 1 and 2 are integers but are also in the set of complex numbers. When you 'treat' them in the set of complex numbers, 1 does NOT come before 2, 1 does NOT come after 2, 1 does NOT EQUAL 2 WTF? right? This only happens AFTER you extend the real numbers to include complex. In the set of real numbers ORDER still persists. Isn't that amazing?
 
  • #19
gb7nash said:
The more technical reason for this is that the rational numbers between 0 and 1 are countable and the irrational numbers between 0 and 1 are uncountable. It's pretty cool that there's practically no chance of "picking" a rational number.

It makes me very happy that you (like myself) think it's pretty cool. The technical explanation completely disregards the 'cool' part. The way math is taught...they teach the technical reasons, they disregard the cool parts. I like to be FASCINATED (like Spock) If you teach me the rationals are countable, the irrationals are not, it doesn't mean very much to me. Show me Cantor's diagonal argument, still doesn't mean much more. (Although I agree it is a very clever argument) If you show me the consequences of the ideas formed by thousands of years of itellectual, independant, creative thought of humanity, then chances are i will be fascinated. Most mathematicians are not good story-tellers and as a consequence popularity of mathematics suffers. The way math is taught...they teach the technicalities and leave the 'cool consequences' to be discovered by the student. This is wrong approach, not everyone is genius enough to discover cool consequences for themselves, consequences that took humanity thousands of years to discover. However, EVERYONE, whether genius or not, has the RIGHT to know about the 'cool' MATHEMATICS. Also, is it any wonder why most mathematicians SEEM arrogant. In this system of teaching they have had to figure out almost everything by themselves and now feel 'privelaged' for having this knowledge. You ask a question and they throw some technical theorem at you which really doesn't explain much, unless you know, but if you know then you wouldn't ASK the question. They appear more like MAGICIANS guarding their secrets instead of professors who's JOB is to spread the knowledge. Am i wrong?
 
  • #20
take an interval of length 1/1000, and cut it in half. Plop the first half down on top of the rational number 1/2. Then cut the rest in half again plop half down on top of the rational number 1/3. Do it again and plop halkf down on 2/3. Keep on covering the rational numbers 1/4, 3/4, 1/5, 2/5,... by increasingly smaller intervals. Continue forever.

Or work faster and faster so that you finish the job in 1 second if you prefer.

Then you will covered all the positive rational numbers by an interval of length 1/1000.

so there is not a very big set of rational numbers. i.e. they have length zero.
 
  • #21
mathwonk said:
take an interval of length 1/1000, and cut it in half. Plop the first half down on top of the rational number 1/2. Then cut the rest in half again plop half down on top of the rational number 1/3. Do it again and plop halkf down on 2/3. Keep on covering the rational numbers 1/4, 3/4, 1/5, 2/5,... by increasingly smaller intervals. Continue forever.

Or work faster and faster so that you finish the job in 1 second if you prefer.

Then you will covered all the positive rational numbers by an interval of length 1/1000.

so there is not a very big set of rational numbers. i.e. they have length zero.

I loooooooooove this explanation, you know why? Cause it's FASCINATING! Let me tell a personal story. Years ago I was reading a book on elementary number theory. I didn't know much about math then (don't know much about math now lol) There was a graph in there sort of like a 45 degree rotated bell curve not too complicated, i think it was cubic in x-y plane, and the author claimed the graph did NOT pass through any rational point with BOTH x,y co-ordinates rational. I found that fascinating even though i understood the explanation why. The equation was fairly simple. I showed it to a professor friend of mine who had a Phd in Autumorphic Forms and knew a lot about number theory. 'This is amazing' i said to him ' you have this graph with an infinite number of points extending in opposite directions and you mean to tell me it's never going to hit a rational point?' He said 'y = pi never hits a rational point' 'but it's not a straight line, it's curvy' i said
'doesn't matter' he said 'given the fact that the set of irrational points is SO MUCH BIGGER than the set of rational points, the AMAZING thing is that ANY function hits ANY rational points at all'

I was fascinated. We never spoke of it again because i knew he didn't like to answer questions too much. I was not angry, i was grateful because most didn't like to answer ANY questions at all so i appreciated what little time he spent with me. A few weeks later and intense study on my part, i agreed with him.
 
  • #22
I’ve been noting the discussion about irrational numbers on the number line with great interest and have two questions: Is anyone aware of attempts to correlate points on the traditional number line with the idea that real world space and time are probably discrete at the scale called the Plank distance or Plank volume? My understanding is that in the our world where nothing exists in lengths, areas and volumes smaller than the Plank size, the experience of an infinite number of points or the experience of irrational numbers altogether would not exist (except of course, in our minds). If this is true, in efforts to understand the so called “real world” using mathematics, might it be more productive to modify the number line to reflect a finite number of points of Plank size and investigate descriptions of the world using mathematics based on that kind of fundamental structure?
 
  • #23
cb174503 said:
I’ve been noting the discussion about irrational numbers on the number line with great interest and have two questions: Is anyone aware of attempts to correlate points on the traditional number line with the idea that real world space and time are probably discrete at the scale called the Plank distance or Plank volume?

I've heard of this, though my knowledge on it is very limited. This is more of a physics question than mathematical question though. In the sense of the real numbers, time and length are not discrete.

cb174503 said:
If this is true, in efforts to understand the so called “real world” using mathematics, might it be more productive to modify the number line to reflect a finite number of points of Plank size and investigate descriptions of the world using mathematics based on that kind of fundamental structure?

In terms of preciseness, this would probably be better. However, you would need some kind of mechanism/scheme to determine the actually length of a Planck. This would require insane detail, since if you're off by just a tiny bit, the error between the actual length and the observed length will amplify when measuring visible objects.
 
  • #24
This was in the news recently ...

http://io9.com/5818008/the-universe-probably-isnt-a-giant-hologram-after-all

Evidently some clever physicists measured something down to 1 ten-trillionth of the Planck length. I don't know enough physics to make sense of the article but it came to mind as I was reading this discussion.

In any event, math and physics are not the same thing. Certainly it's fair to say that the mathematical notion of the real numbers as the continuum does not correspond to what modern physicists think about physical space.

That doesn't mean math isn't useful. Even if physical space is quantized, the mathematical continuum is still a handy model for doing calculations. But we have no evidence for infinite sets in the physical universe, let alone uncountable ones.
 
  • #25
In words, the Plank length is defined as the square root of (the reduced Plank constant times the Gravitational constant divided by the speed of light cubed). The reduced Plank constant component is the Plank constant divided by 2 pi. The yield from this function is an approximation of 1.616252(81)*10-35 meters. This number has a fairly long history of being tested experimentally and indicates a scale below which not only does nothing exist, but nothing can exist even philosophically. Nothing, that is, but what a conscious mind might consider – and a conscious mind can consider anything, including a universe constructed of green elephants. Green elephants don’t count without evidence. Nor apparently, as SteveL27 mentioned, do infinite sets.

As for the debate about whether the number line represents a continuous or discrete reality, doesn’t the existence (?) of irrational numbers themselves hint at discontinuities on the number line within the current framework of traditional mathematics?

A Plank distance is extraordinarily small, but as gb7nash mentioned, it is still an approximation, but one being refined as experimental evidence continues to come along. His additional comment that any size error would cause problems is accurate also. Size error would be due to ultimately and irreconcilably to field fluctuations at that scale, but I wouldn’t think of that as a reason not to pursue the idea. Averages and approximations can be standardized and updated in a fair way in order to illuminate the terrain. And although it may be difficult at present to stamp an exact size, the concept exists and is accepted because of the evidence and that in itself should have some meaning or significance that could inform the subject of number theory even as mathematics informs physics. As an approximation it would seem a useful tool and if nothing else, would remove irrational numbers and infinities from the number line. That would be just a beginning.

If one were to accept this and think it out, other possibilities might derive from the use of a change in what we’ve known as the traditional number line. What would it mean to construct lines, areas and volumes from Plank size “points”? Formal mathematical systems would probably have to be deveoped to make things coherent. Examples that might be derived: descriptions what of the exact beginning of time and space may have looked like and a more certain proposition that the universe must be bounded if it contains only a finite number of Plank “points” to elimination or confirmation of the possibility of time travel. Now, how one gets to there from here, I don’t think I have all the knowledge or horsepower needed to make that trip which is why I asked the question I did in my previous post. But, maybe some young soul somewhere….thinking his or her thinks…about mathematics….could help the physicists along.

For myself, I would choose the found knowledge about the world through physics and other disciplines and try to bend the traditional philosophies of mathematics to conform to that knowledge in hope of discovering more about what the world is and how it works. It has been done before and it was mathematicians who did it.
 
  • #26
In deference to those of you who have been participating in this thread “Where are the irrational numbers…” I realize the issue was primarily a discussion of the mathematics and not the physics of numbers – and I have personally enjoyed reading your discussions. Nevertheless, math and physics are probably the most closely related of the major scientific disciplines and I couldn’t resist the thread question. But having written my previous posts, I would like to make some concluding assertions.

If you accept the experimental evidence from physics that leads to the recognition of the reality of quantized or discrete space as a feature of the real world, how would a mathematician consider the following set of statements?

1. The discrete nature of space is characterized by “points” – Plank points – that are not the same as pure mathematical points, i.e., dimensionless entities. Plank points are extremely tiny features that have a dimension measured by the quantity called Plank length. Plank points might be described as tiny spheres with a diameter of the Plank length.
2. Constructing a number line of Plank points yields a series of countable real numbers rather than a continuum or line with “in between” numbers. That series is a finite number of points from any point “a” to any point “b”.
3. On such a number line there cannot be places where irrational numbers (otherwise known as partial Plank spheres) exist as each point has a label representing a real number with no spaces between. This because nothing in the real world can be said to exist smaller than the Plank distance.
4. It then follows that irrational numbers as a feature of standard mathematics are in fact, constructs of the human mind and exist only there, not in a quantized world such as ours apparently is. And that is my answer to the question posed!
5. But, last…following again, irrational numbers also do not exist “a priori” in the real world.

Then, just for fun… another feature of the real world which experimental physics has demonstrated is a phenomenon called Entanglement. Briefly, entanglement is the process where separate pairs of things (experimentally, subatomic particles) interact and then separate. After separation, no matter how long the time or how far the distance, the measurement of a characteristic of one member will cause the other member to have a correlated feature of corresponding value.

Consider as mathematicians that at the beginning of time our universe was the size of a Plank point. At that time – likely the first instant of time, everything was interacting at that single instant and then expanded into the universe we see today. Everything was entangled at the beginning and still is. If that were and is the case, it isn’t too much of a stretch to view the number line as consisting of two features, zero for nothing and 1 for everything else. Taking into account this perspective, the number line looks strikingly like a simple (?) binary system…which also implies that all numbers except perhaps the zero and the one are constructs of the human mind and did not exist “a priori”, before all else. (as I recall, this has been a debate among mathematicians for at least several centuries)
cb
 
  • #27
cb174503 said:
In deference to those of you who have been participating in this thread “Where are the irrational numbers…” I realize the issue was primarily a discussion of the mathematics and not the physics of numbers – and I have personally enjoyed reading your discussions. Nevertheless, math and physics are probably the most closely related of the major scientific disciplines and I couldn’t resist the thread question. But having written my previous posts, I would like to make some concluding assertions.

If you accept the experimental evidence from physics that leads to the recognition of the reality of quantized or discrete space as a feature of the real world, how would a mathematician consider the following set of statements?

1. The discrete nature of space is characterized by “points” – Plank points – that are not the same as pure mathematical points, i.e., dimensionless entities. Plank points are extremely tiny features that have a dimension measured by the quantity called Plank length. Plank points might be described as tiny spheres with a diameter of the Plank length.
2. Constructing a number line of Plank points yields a series of countable real numbers rather than a continuum or line with “in between” numbers. That series is a finite number of points from any point “a” to any point “b”.
3. On such a number line there cannot be places where irrational numbers (otherwise known as partial Plank spheres) exist as each point has a label representing a real number with no spaces between. This because nothing in the real world can be said to exist smaller than the Plank distance.
4. It then follows that irrational numbers as a feature of standard mathematics are in fact, constructs of the human mind and exist only there, not in a quantized world such as ours apparently is. And that is my answer to the question posed!
5. But, last…following again, irrational numbers also do not exist “a priori” in the real world.

Then, just for fun… another feature of the real world which experimental physics has demonstrated is a phenomenon called Entanglement. Briefly, entanglement is the process where separate pairs of things (experimentally, subatomic particles) interact and then separate. After separation, no matter how long the time or how far the distance, the measurement of a characteristic of one member will cause the other member to have a correlated feature of corresponding value.

Consider as mathematicians that at the beginning of time our universe was the size of a Plank point. At that time – likely the first instant of time, everything was interacting at that single instant and then expanded into the universe we see today. Everything was entangled at the beginning and still is. If that were and is the case, it isn’t too much of a stretch to view the number line as consisting of two features, zero for nothing and 1 for everything else. Taking into account this perspective, the number line looks strikingly like a simple (?) binary system…which also implies that all numbers except perhaps the zero and the one are constructs of the human mind and did not exist “a priori”, before all else. (as I recall, this has been a debate among mathematicians for at least several centuries)
cb

You raise some fantastic questions and make interesting observations. I would like you to notice that you cannot fill any volume with tiny spheres, no matter how small you make the sphere there will always be spaces left over not within any spere. You can fill space using the Platonic Solids but this introduces fractions and irrational numbers.

One more thing about spheres. Suppose the radius is Planck Length. Then Volume, surface area, circumference of great circle, all become irrational because they are related to pi.

IMHO i think quantization is dead and only serves as a useful tool to explain limited phenomena such as spectrum of hydrogen atom and photoelectric effect. Quantization fails to explain the next element helium and all others on the periodic table.:smile:

[EDIT] There may be a way to disregard irrational values in the 'real world' by using DeBroglie wavelenth and uncertainty principle. Wave nature of particles makes them 'fuzzy' and uncertainty principle makes exact simultaneas measurement of position and momentum impossible. If you can't get it exactly, you can still approximate it as close as you like by a rational number.:smile:

[EDIT2] You can approximate pi as close as you like using rational numbers only. You can approximate any irrational by using rationals only. Since no one can compute the exact value of irrationals, what's the difference.

However if you replace sqrt(2) by a rational approximation in a calculation it introduces difficulties in calculations and rounding errors, so it is much better to manipulate sqrt(2) as an abstract symbol using the rules of algebra and make the approximation at the end. So the philosophical abstraction of an irrational is very useful in the real world for making accurate measurements. IMHO quantization is not as useful, unless you quantize at the last step, which we can do anyway if we want.
 
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  • #28
My compliments to Agentredlum for so quickly spotting and pointing out the failure of my simplistic description of Plank points – and in such a concise and to the point way (pun intended). Concise and to the point is something I have trouble doing at times.

Your comments about my description of Plank points are correct. I used the simile of spheres to get the thought across in a less complicated and too idealized way. I tried to avoid use of too many words – but as a result I lost accuracy. So, rather than perfect or even “nearly like” spheres is not the best description because of the problems with spheres completely filling space which Agentredlum notes. I’ll no doubt still be too inaccurate, but perhaps a better description of Plank points is as a mushy configuration of space that may be more or less accurately visualized as tiny roundish marshmallows rather than spheres. These marshmallow like points have dimension of a sort and are compacted together to fill all of space - and they compose all of space. One can only say that their average diameter is the Plank length….quantized space with an average volume of a Plank volume. If a set of them could be arranged in a line, they would constitute a finite number line without partial pieces representing places between points – that is without irrational components. The assertion is based on the idea of quantum fluctuations which are tiny, messy creations of energy/matter on a similar scale. Your edits seem to acknowledge a similar path.

I can’t say whether the ideas supporting quantization are dead or not, but if they are, I hope they are revived. My posts here support quantization by way of suggesting the idea that the math used to calculate quanta of various sorts is based on a philosophy of number theory which includes infinites as part of a counting continuum in the form of the idealized standard number line. Infinities as reflected by the presence of irrational numbers confound calculations that are supposed to reflect the physical world and lead to results that either are not interpretable or lend themselves to ridiculous interpretations. So, you are also correct to note that extending the description of the hydrogen spectrum to other elements has met with difficulty. My answer is I believe the reason may be due to using math (including pi) based on a continuous numbering system.

…and I really like your edits… they strike me as thoughts that would yield results if they could be formally adopted – not to replace traditional math as a philosophy, but to replace certain mathematical applications as descriptions of the real world. The problem would be in how to actually formalize things. Particularly good is to use the DeBroglie wavelength and uncertainty principle as an approximation mechanism. It would certainly be a candidate. I suspect that is very nearly in line with what I am advocating. The alternate use of approximations by rounding the irrationals will eliminate the irrationals by substituting the closest rational number at the cutoff point. Pretty much the same as quantizing space to the Plank length. I have often wondered what a study of the 31st to maybe the 39th decimal place of the irrationals would yield – down to and just past the theoretical Plank length - would it be true randomness or would patterns be detected?

More to your edit 2, I’ll mention that the difference in “what’s the difference” is partial or in-between points that when included in calculations yield the kind of results I mentioned earlier. Too often none, confusing or ridiculous.

Lastly, your mention of the square root of 2 is interesting, but in a different way. I would propose that by rounding the root, one would have to either squeeze the triangle very slightly to make the end points connect, yielding a triangle whose internal angles add to less than 180 degrees… or stretch it slightly, yielding a triangle whose internal angles are more than 180 degrees. Neither of these are necessarily outside the realm of reality. My speculation is that quantized space reflects a closed universe by necessity, one in which the internal angles of triangles are less than 180 degrees – and not as an approximation, but as the reality of the nature of quantized space. I understand the physicists are trying to do experiments that will decide the question, but I’ve not heard any results. Hopefully the results will not be interpreted in a ridiculous way.

So, Agentredlum, I cannot say you are incorrect with your comments, but rather to say there is plenty of room for debate and exploration. I think I understand your point of view and I do appreciate the response. I believe you can see I am seeking to plant seeds rather than cut down the forest, but I sense that I’ve beaten this particular subject near to death and do not wish to wear out my welcome by overdoing it. For others who’ve seen and thought about where the irrationals are and witnessed my words…Thanks!
 
  • #29
cb174503 said:
For others who’ve seen and thought about where the irrationals are and witnessed my words…Thanks!

Eek! A physicist! In math land! Your physical properties do not threaten my philosophical number land! j/k :)

I spent a good part of the day looking for the irrationals myself. They sifted through my fingers like sand. I was trying to work through chapter 1 of my analysis book for next year. It was mostly about cuts, Dedekind and the like. Or maybe just Dedekind... Anyone want to put forth a proof that between any two reals is an irrational using cuts?
 
  • #30
cb174503 said:
My compliments to Agentredlum for so quickly spotting and pointing out the failure of my simplistic description of Plank points – and in such a concise and to the point way (pun intended). Concise and to the point is something I have trouble doing at times.

Your comments about my description of Plank points are correct. I used the simile of spheres to get the thought across in a less complicated and too idealized way. I tried to avoid use of too many words – but as a result I lost accuracy. So, rather than perfect or even “nearly like” spheres is not the best description because of the problems with spheres completely filling space which Agentredlum notes. I’ll no doubt still be too inaccurate, but perhaps a better description of Plank points is as a mushy configuration of space that may be more or less accurately visualized as tiny roundish marshmallows rather than spheres. These marshmallow like points have dimension of a sort and are compacted together to fill all of space - and they compose all of space. One can only say that their average diameter is the Plank length….quantized space with an average volume of a Plank volume. If a set of them could be arranged in a line, they would constitute a finite number line without partial pieces representing places between points – that is without irrational components. The assertion is based on the idea of quantum fluctuations which are tiny, messy creations of energy/matter on a similar scale. Your edits seem to acknowledge a similar path.

I can’t say whether the ideas supporting quantization are dead or not, but if they are, I hope they are revived. My posts here support quantization by way of suggesting the idea that the math used to calculate quanta of various sorts is based on a philosophy of number theory which includes infinites as part of a counting continuum in the form of the idealized standard number line. Infinities as reflected by the presence of irrational numbers confound calculations that are supposed to reflect the physical world and lead to results that either are not interpretable or lend themselves to ridiculous interpretations. So, you are also correct to note that extending the description of the hydrogen spectrum to other elements has met with difficulty. My answer is I believe the reason may be due to using math (including pi) based on a continuous numbering system.

…and I really like your edits… they strike me as thoughts that would yield results if they could be formally adopted – not to replace traditional math as a philosophy, but to replace certain mathematical applications as descriptions of the real world. The problem would be in how to actually formalize things. Particularly good is to use the DeBroglie wavelength and uncertainty principle as an approximation mechanism. It would certainly be a candidate. I suspect that is very nearly in line with what I am advocating. The alternate use of approximations by rounding the irrationals will eliminate the irrationals by substituting the closest rational number at the cutoff point. Pretty much the same as quantizing space to the Plank length. I have often wondered what a study of the 31st to maybe the 39th decimal place of the irrationals would yield – down to and just past the theoretical Plank length - would it be true randomness or would patterns be detected?

More to your edit 2, I’ll mention that the difference in “what’s the difference” is partial or in-between points that when included in calculations yield the kind of results I mentioned earlier. Too often none, confusing or ridiculous.

Lastly, your mention of the square root of 2 is interesting, but in a different way. I would propose that by rounding the root, one would have to either squeeze the triangle very slightly to make the end points connect, yielding a triangle whose internal angles add to less than 180 degrees… or stretch it slightly, yielding a triangle whose internal angles are more than 180 degrees. Neither of these are necessarily outside the realm of reality. My speculation is that quantized space reflects a closed universe by necessity, one in which the internal angles of triangles are less than 180 degrees – and not as an approximation, but as the reality of the nature of quantized space. I understand the physicists are trying to do experiments that will decide the question, but I’ve not heard any results. Hopefully the results will not be interpreted in a ridiculous way.

So, Agentredlum, I cannot say you are incorrect with your comments, but rather to say there is plenty of room for debate and exploration. I think I understand your point of view and I do appreciate the response. I believe you can see I am seeking to plant seeds rather than cut down the forest, but I sense that I’ve beaten this particular subject near to death and do not wish to wear out my welcome by overdoing it. For others who’ve seen and thought about where the irrationals are and witnessed my words…Thanks!

Let me say that i am not an expert, i am a layperson with some mathematical training, so it may be possible to quantize. My opinions are not 'etched in stone' You are also correct about there being a lot of room for debate. I do not want to appear as wanting to find fault with your points (pun intended). Believe me when i say that i would love it if someone can quantize space, or even a number line. I put those edits because i wanted you to know that i can see it your way. I am not stubborn nor do i wish to propogate my own theories. I am still in the learning phase and merely wish to point out what IMHO i consider logical inconsistencies with the notion of quantization. Also you make some great points about the necessity of quantization, believe me, i agree with many of your points, but i am not convinced that the phenomenon of quantization can be saved, and even if it could be saved it would be very complicated.

You mentioned volume. Since the Planck length is smaller than 1 any volume you create using the Planck length will have a numerical value SMALLER than the numerical value of the Planck length. How would you incorporate this into your system that is quantized according to Planck length? If the volume is equal to the numerical value of the Planck length then i am interested to know the dimensions of this geometrical solid.

An example: Suppose volume is a cube with side Planck length. Then the numerical value you get is about 10^-105. This is a lot smaller than the quantized value. Problems like this arise with any kind of geometrical object, including marshmellows, you can't even make a square with side Planck length without violating quantization.

Lets make the problem simpler so i can make my point without confusion. Pretend PL is .5 and you have a quantized system that does not allow smaller values. Then someone asks,'what happens if you square PL?'
You get .25 which is a smaller value than PL. 'No problem' you say, 'I'll just put .25 into my system as an exception.' What if you square the exception? then you get a smaller number still. You can repeat this process ad infinitem. You always get a number smaller than the previous and greater than zero. So you are rapidly creating an INFINITE number of exceptions approaching zero in your quantized system that was designed to have a FINITE number of points between zero and one. This is one of the reasons IMHO i believe quantization is dead.

This last paragraph was meant as a hypothetical dialogue.:smile:

One final point about Planck constant, the units are J-s if you simplify the units
J=(Newton)(meter)...Newton=(kg)(meter)/(second^2) so J-s gives (kg)(meter^2)/(second)
mass multiplied by the square of the length divided by time. How do they turn this into a 'Planck Length'?

[EDIT] Oh wait a second...cb explained it in post #25
 
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  • #31
ArcanaNoir said:
Eek! A physicist! In math land! Your physical properties do not threaten my philosophical number land! j/k :)

I spent a good part of the day looking for the irrationals myself. They sifted through my fingers like sand. I was trying to work through chapter 1 of my analysis book for next year. It was mostly about cuts, Dedekind and the like. Or maybe just Dedekind... Anyone want to put forth a proof that between any two reals is an irrational using cuts?

I like mathwonk 'cuts' better than Dedekind 'cuts' see post #20:smile:
 
  • #32
You could also "fit" the real numbers on an arbitrarily small interval, so I don't see how the "length" of the rational numbers in any case would be relevant as a comparison to the reals.
 
  • #33
I just assumed cuts because that's what the chapter focused on. I think I got it though (no cuts necessary). I posted my attempt in homework help to see what people think.
 
  • #34
disregardthat said:
You could also "fit" the real numbers on an arbitrarily small interval, so I don't see how the "length" of the rational numbers in any case would be relevant as a comparison to the reals.

How would you fit the reals?

mathwonk fits the rationals by making a list and using a 1-1 correspondence between every member of his list and a mathwonk 'cut'

Cantor proved the reals cannot be listed.

How would you fit the reals?

:smile:
 
  • #35
agentredlum said:
How would you fit the reals?

mathwonk fits the rationals by making a list and using a 1-1 correspondence between every member of his list and a mathwonk 'cut'

Cantor proved the reals cannot be listed.

How would you fit the reals?

:smile:

There exists a bijection between [itex]\mathbb{R}[/itex] and any arbitrary small interval. So the reals can be "fitted" in any arbitrary small interval.
 
<h2>1. Where can I find irrational numbers?</h2><p>Irrational numbers can be found on the number line, just like rational numbers. However, unlike rational numbers which can be expressed as a ratio of two integers, irrational numbers cannot be expressed as a simple fraction. They are often represented by decimal expansions that do not terminate or repeat.</p><h2>2. Are there more irrational numbers than rational numbers?</h2><p>Yes, there are infinitely more irrational numbers than rational numbers. In fact, the set of irrational numbers is uncountable, meaning that there is no way to list them all in a systematic way. This is because between any two rational numbers, there are infinitely many irrational numbers.</p><h2>3. Can irrational numbers be negative?</h2><p>Yes, irrational numbers can be both positive and negative. For example, the square root of 2 is an irrational number and it can be either positive (√2 ≈ 1.414) or negative (-√2 ≈ -1.414).</p><h2>4. How are irrational numbers used in real life?</h2><p>Irrational numbers are used in many real-life applications, such as in engineering, physics, and computer science. They are used to represent quantities that cannot be expressed as a simple fraction, such as the circumference of a circle or the diagonal of a square. They are also used in various mathematical models and equations to describe natural phenomena.</p><h2>5. Can irrational numbers be simplified?</h2><p>No, irrational numbers cannot be simplified because they are already in their simplest form. Unlike rational numbers, which can be simplified by finding their greatest common factor, irrational numbers have no common factors and cannot be reduced any further.</p>

1. Where can I find irrational numbers?

Irrational numbers can be found on the number line, just like rational numbers. However, unlike rational numbers which can be expressed as a ratio of two integers, irrational numbers cannot be expressed as a simple fraction. They are often represented by decimal expansions that do not terminate or repeat.

2. Are there more irrational numbers than rational numbers?

Yes, there are infinitely more irrational numbers than rational numbers. In fact, the set of irrational numbers is uncountable, meaning that there is no way to list them all in a systematic way. This is because between any two rational numbers, there are infinitely many irrational numbers.

3. Can irrational numbers be negative?

Yes, irrational numbers can be both positive and negative. For example, the square root of 2 is an irrational number and it can be either positive (√2 ≈ 1.414) or negative (-√2 ≈ -1.414).

4. How are irrational numbers used in real life?

Irrational numbers are used in many real-life applications, such as in engineering, physics, and computer science. They are used to represent quantities that cannot be expressed as a simple fraction, such as the circumference of a circle or the diagonal of a square. They are also used in various mathematical models and equations to describe natural phenomena.

5. Can irrational numbers be simplified?

No, irrational numbers cannot be simplified because they are already in their simplest form. Unlike rational numbers, which can be simplified by finding their greatest common factor, irrational numbers have no common factors and cannot be reduced any further.

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