If space is not continuous, then is calculus wrong?

In summary, Shan Majid argues that if space is discrete, it would have implications for the applicability of calculus to the physical world.
  • #1
jessjolt2
16
0
Ok so mathematically you can divide any number by any other (nonzero) number and you can keep dividing that number however many times you want. Like dividing 1 by 2 and then by 2 again etc. And this is the basis of the famous paradox that mathematically, you can't really move from point a to b because first you need to get to the middle of a and b. and then to the middle of the middle. and then the middle of the middle of the middle, etc.

But what if space is not continuous, but quantized? Like what if there is a smallest possible length, and you cannot be in between that length, meaning you cannot physically divide that length by 2 to get to the middle (even though mathematically you could). Wouldnt that have some serious consequences on the physical application of calculus to the real world? (maybe not when working with large bodies, but definitely with small scales?) For example the intermediate value theorem wouldn't hold true...

Idk I am not calculus expert (only had calc I and II nd basic physics) but this thought occurred to me and has bothered me..
 
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  • #2
No, calculus has never had the ambition to give an exact description of space. There are many problems with calculus as a description of space: space and time being discrete, the existence of points which are infinitesimal small, lines which have a length but not width, etc.

Calculus should never be looked at as a complete description of our physical world, but merely as a very useful approximation. That is, when you throw a ball in the air, then its path isn't an exact parabola, but it can be approximated by parabolas. This is so with everything in physics: everything is an approximation of the real world. Exactness is never claimed.

But why are our approximations so good? We don't know. This is (in my opinion) the greatest mystery of the universe. Why is math so good in approximating the universal laws?
 
  • #3
First of all - math doesn't deal with the real space. It doesn't have to care about whether the real space is continuous or not, it does have to care about properties of the idealized space. And we define this idealized space to be as we want it to be.
 
  • #4
Space is 'out there'. Calculus is in your head, along with the other maths you use.
 
  • #5
Borek said:
First of all - math doesn't deal with the real space. It doesn't have to care about whether the real space is continuous or not, it does have to care about properties of the idealized space. And we define this idealized space to be as we want it to be.

But physics uses math and deals with real space...so it should care if space is continuous or not, at least when it is used to describe motion in space and watnot...

Does anyone know of any literature that discusses the relationship between the possible discreteness of space and mathematics?
 
  • #6
Good evening JessJolt.

You have touched on a deep and interesting question.

Shan Majid (professor of mathematics at London University) for instance offers exactly this quantisation as the reason for our difficulty in generating grand unified theories.

See his essay "Quantum spacetime and physical reality" in the book he edited

"On Space and Time"

(Cambridge University Press)

go well
 
  • #7
However, those are questions about physics, not about Calculus or whatever other mathematics is used to model physics.

If space is, in fact, discreet, it might mean that, for some questions about space, Calculus would not be the appropriate mathematical tool (which is what you perhaps meant), but it would not mean the Calculus itself was wrong.
 
  • #8
jessjolt2 said:
But physics uses math and deals with real space...so it should care if space is continuous or not, at least when it is used to describe motion in space and watnot...

Does anyone know of any literature that discusses the relationship between the possible discreteness of space and mathematics?

You seem to be missing the point made by the previous posters. The math does NOT deal directly with the real world, it is an approximation. It is a damned GOOD approximation and gives us excellent answers but the real world really doesn't care what the math says and the math really doesn't have to worry about the real world. WE have to worry about the correlation between the two, which you are rightly attempting to do, but this particular "problem" that you have brought up just ISN'T one and we'll keep using the math as long as it gives good answers.
 
  • #9
HallsofIvy said:
However, those are questions about physics, not about Calculus or whatever other mathematics is used to model physics.

If space is, in fact, discreet, it might mean that, for some questions about space, Calculus would not be the appropriate mathematical tool (which is what you perhaps meant), but it would not mean the Calculus itself was wrong.

Well from my experience it seems like calculus is the main mathematical tool in describing physics...

I read Majid's essay (thanks Studiot), and he describes some math that he and others developed to include the discrete nature of spacetime, although its too complex for me to understand lol, but it's interesting that in the future perhaps some more accurate mathematics will replace calculus as a main tool for describing physical reality..
 
  • #10
phinds said:
You seem to be missing the point made by the previous posters. The math does NOT deal directly with the real world, it is an approximation. It is a damned GOOD approximation and gives us excellent answers but the real world really doesn't care what the math says and the math really doesn't have to worry about the real world. WE have to worry about the correlation between the two, which you are rightly attempting to do, but this particular "problem" that you have brought up just ISN'T one and we'll keep using the math as long as it gives good answers.

Sorry, I didnt mean that calculus doesn't give good approximations nd that we should stop using it. But i still think its a problem that calculus can't describe nature at small scales if calculus assumes spacetime is continuous if it possibly isn't...my point is that there should be developed a math on the basis of discrete spacetime and to see if that math can work well with both small and large scales
 
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  • #11
jessjolt2 said:
Well from my experience it seems like calculus is the main mathematical tool in describing physics...

I read Majid's essay (thanks Studiot), and he describes some math that he and others developed to include the discrete nature of spacetime, although its too complex for me to understand lol, but it's interesting that in the future perhaps some more accurate mathematics will replace calculus as a main tool for describing physical reality..
But math isn't a tool for the sake of being a tool. It's a study in its own right, independent of reality. It's the fact that calculus happens to approximate the real world that makes it a tool. It wasn't designed to be a tool.

jessjolt2 said:
Sorry, I didnt mean that calculus doesn't give good approximations nd that we should stop using it. But i still think its a problem that calculus can't describe nature at small scales if calculus assumes spacetime is continuous if it possibly isn't...my point is that there should be developed a math on the basis of discrete spacetime and to see if that math can work well with both small and large scales
Again, calculus isn't developed to describe reality. If one is worried about discrete intervals, one can just use difference quotients and Riemann sums; problem solved.
 
  • #13
jessjolt2 said:
Sorry, I didnt mean that calculus doesn't give good approximations nd that we should stop using it. But i still think its a problem that calculus can't describe nature at small scales if calculus assumes spacetime is continuous if it possibly isn't...my point is that there should be developed a math on the basis of discrete spacetime and to see if that math can work well with both small and large scales

Yes, but it is NOT a problem for CALCULUS. I guess that's what threw me about your reasoning. It is a problem for US in that we may need to find a better approximation tool if it comes to that, but as other posters have pointed out, this is NOT a flaw in calculus.

I do agree w/ you that it is unfortunate that it may be that calculus, which is one of our best tools, is not applicable in situations where we might wish it to be.
 
  • #14
You can't say Calculus is wrong unless it isn't consistent. Calculus is just a bunch of definition that turns out to be useful.
 
  • #15
TylerH said:
. It wasn't designed to be a tool.
I'm not sure this is correct. It was the need to describe natural phenomena that lead to the discovery/development of calculus. So, I think it was, at least initially, designed to be a tool.
 
  • #16
Robert1986 said:
It was the need to describe natural phenomena that lead to the discovery/development of calculus.
That depends on whether you're a Leibniz or Newton man :wink:
 
  • #17
Hootenanny said:
That depends on whether you're a Leibniz or Newton man :wink:

It is my understanding that Newton developed calculus as a way to describe physical stuff, is this correct? I don't really know what Liebniz was doing, but was it purely mathematical? I always thought that Liebniz's mathematical interests were motivated by solving problems. Am I wrong in this?

Either way, I understand what you are saying :)
 
  • #18
Robert1986 said:
It is my understanding that Newton developed calculus as a way to describe physical stuff, is this correct? I don't really know what Liebniz was doing, but was it purely mathematical? I always thought that Liebniz's mathematical interests were motivated by solving problems. Am I wrong in this?

Either way, I understand what you are saying :)
In a nutshell, as far as I know, Newton developed calculus in order to solve physical problems, Leibniz developed calculus to find the area under a curve. :smile:
 
  • #19
Hootenanny said:
In a nutshell, as far as I know, Newton developed calculus in order to solve physical problems, Leibniz developed calculus to find the area under a curve. :smile:

Ahhh, I see. So it looks like Liebniz was doing purely mathematical stuff. Interesting.
 
  • #20
An accurate title for the original post would be "If space is not a continuum then calculus is not applicable".

I wonder how Zeno's paradoxes get resolved if calculus is not applicable.
 
  • #21
Stephen Tashi said:
An accurate title for the original post would be "If space is not a continuum then calculus is not applicable".

I wonder how Zeno's paradoxes get resolved if calculus is not applicable.

At the risk of contradicting what everyone "knows" to be true, I don't think that Zeno's paradoxes have been resolved. Mathematically they have, because we can sum an infinite series. But in the physical universe, we'd have to accept that we complete infinitely many tasks every time we take a step. There's no physical evidence that this is true.

Zeno's paradoxes are intimately related to the question of whether space is a continuum -- a question whose answer is currently unknown and may well be unknowable.
 
  • #22
SteveL27 said:
Zeno's paradoxes are intimately related to the question of whether space is a continuum

I don't think so. Zeno's paradox is just an example of how you can incorrectly apply a mathematical concept in a way that makes no sense. And it HAS been solved. We KNOW that its conclusion is silly by everyday practical evidence so the "paradox" is just a word game, based as I said, on the inappropriate application of a math concept it a nonsensical way.
 
  • #23
phinds said:
I don't think so. Zeno's paradox is just an example of how you can incorrectly apply a mathematical concept in a way that makes no sense. And it HAS been solved. We KNOW that its conclusion is silly by everyday practical evidence so the "paradox" is just a word game, based as I said, on the inappropriate application of a math concept it a nonsensical way.

Can't Zeno's paradox be taken as proof that space isn't continuous?
 
  • #24
good evening jess,

Do you understand the difference between 'continuous' and infinitely divisible?
 
  • #25
jessjolt2 said:
Can't Zeno's paradox be taken as proof that space isn't continuous?

No, Zeno's paradox can be taken as proof that math can be applied inappropriately

As Korzybski famously said "the map is not the territory". Math is a model, not the real world.
 
  • #26
Math is a model, not the real world.

Don't you think that's a bit harsh?

Maths is a discipline in its own right with a very real world existence, even though it is abstract.

It is true that we can and do use mathematical constructs to obtain indications of the way other systems will behave because we can observe the same or very similar structures in both.

Doing so does not make either any less real or distinct any more than using balls on sticks to 'model' molecules makes invalidates either of these.

Maths, of course, is not the only abstract system in existence. Colour is another.
 
  • #27
Studiot said:
Don't you think that's a bit harsh?
could be ... doesn't seem that way to me

Maths, of course, is not the only abstract system in existence. Colour is another.

Color doesn't seem to be in the same league as math. Color is very subjective and even culturally variable (I don't mean just the names of the colors, I mean the perceptive training that comes with it, such as having dozens of names for hues of red and thus learning to see differences that you and I might not see at all). This doesn't happen with math.
 
  • #28
Colour was just the first and simplest example that came to mind.
 
  • #29
phinds said:
No, Zeno's paradox can be taken as proof that math can be applied inappropriately

As Korzybski famously said "the map is not the territory". Math is a model, not the real world.


So would you say that Zeno's paradox has NOT been refuted or explained in physics? And if not, then would you say that it provides a proof that space can't be infinitely divisible? Where is math being applied inappropriately?
 
  • #30
SteveL27 said:
So would you say that Zeno's paradox has NOT been refuted or explained in physics? And if not, then would you say that it provides a proof that space can't be infinitely divisible? Where is math being applied inappropriately?

I'm an engineer. Zeno's paradox says you can't get from here to there. My experience says you CAN get from here to there. As an engineer, that pretty much ends it for me.
 
  • #31
phinds said:
I'm an engineer. Zeno's paradox says you can't get from here to there. My experience says you CAN get from here to there. As an engineer, that pretty much ends it for me.

Then how do you refute/explain the paradox?
 
  • #32
SteveL27 said:
Then how do you refute/explain the paradox?
Simple: It's nonsense.

The non-technical part of me sees that philosophers worry about the silliest things. Next.

The engineer in me sees this simple answer as obviously true. I get from A to B all the time. Next.

The physicst in me sees that until we know better, space and time are continuous. Motion is not a bunch of discrete tasks. Next.

The mathematician in me sees that under the right conditions, a countably infinite number of finite numbers can sum to form a finite number. This is one of those conditions. Next.
 
  • #33
D H said:
Simple: It's nonsense.

The non-technical part of me sees that philosophers worry about the silliest things. Next.

The engineer in me sees this simple answer as obviously true. I get from A to B all the time. Next.

The physicst in me sees that until we know better, space and time are continuous. Motion is not a bunch of discrete tasks. Next.

The mathematician in me sees that under the right conditions, a countably infinite number of finite numbers can sum to form a finite number. This is one of those conditions. Next.

Yep. Personally, I'm particularly attached to the engineer point of view but the others are just as good.
 
  • #34
D H said:
Simple: It's nonsense.

The non-technical part of me sees that philosophers worry about the silliest things. Next.

The engineer in me sees this simple answer as obviously true. I get from A to B all the time. Next.

The physicst in me sees that until we know better, space and time are continuous. Motion is not a bunch of discrete tasks. Next.

The mathematician in me sees that under the right conditions, a countably infinite number of finite numbers can sum to form a finite number. This is one of those conditions. Next.


Just for my own understanding ... could you please point out the specific logical flaw in Zeno's paradox? Saying "it's nonsense" has a certain rhetorical finality; but it's lacking in the intellectual satisfaction department.
 
  • #35
SteveL27 said:
Just for my own understanding ... could you please point out the specific logical flaw in Zeno's paradox? Saying "it's nonsense" has a certain rhetorical finality; but it's lacking in the intellectual satisfaction department.
See all the other points in D_H's post. For me, his final point is the most persuasive. Zeno maintained that an infinite number of finite steps could not be finite. This was his mistake.
 
<h2>1. What is the concept of continuity in mathematics?</h2><p>Continuity is a fundamental concept in mathematics that describes the smoothness and connectedness of a function or a geometric object. In simple terms, a function is continuous if there are no sudden jumps or breaks in its graph.</p><h2>2. How does the concept of continuity relate to space and calculus?</h2><p>In calculus, the concept of continuity is closely related to the idea of a continuous space. This means that the space can be smoothly and continuously mapped onto itself without any breaks or gaps. Calculus is built upon the assumption of a continuous space, and many of its fundamental principles and equations rely on this assumption.</p><h2>3. Is there any evidence to suggest that space is not continuous?</h2><p>While there is currently no definitive evidence to suggest that space is not continuous, some theories in physics, such as loop quantum gravity, propose that space may be made up of discrete, indivisible units. However, these theories are still being researched and are not yet widely accepted.</p><h2>4. If space is not continuous, does that mean calculus is wrong?</h2><p>No, it does not necessarily mean that calculus is wrong. While the concept of continuity is a fundamental assumption in calculus, it is possible to adapt the principles and equations of calculus to work with a non-continuous space. This has been explored in areas of mathematics such as non-standard analysis.</p><h2>5. How would a non-continuous space affect our understanding of the universe?</h2><p>If space were found to be non-continuous, it would have significant implications for our understanding of the universe. It could potentially challenge our current theories of gravity and the structure of space-time, and would require a re-evaluation of many fundamental principles in physics and mathematics.</p>

1. What is the concept of continuity in mathematics?

Continuity is a fundamental concept in mathematics that describes the smoothness and connectedness of a function or a geometric object. In simple terms, a function is continuous if there are no sudden jumps or breaks in its graph.

2. How does the concept of continuity relate to space and calculus?

In calculus, the concept of continuity is closely related to the idea of a continuous space. This means that the space can be smoothly and continuously mapped onto itself without any breaks or gaps. Calculus is built upon the assumption of a continuous space, and many of its fundamental principles and equations rely on this assumption.

3. Is there any evidence to suggest that space is not continuous?

While there is currently no definitive evidence to suggest that space is not continuous, some theories in physics, such as loop quantum gravity, propose that space may be made up of discrete, indivisible units. However, these theories are still being researched and are not yet widely accepted.

4. If space is not continuous, does that mean calculus is wrong?

No, it does not necessarily mean that calculus is wrong. While the concept of continuity is a fundamental assumption in calculus, it is possible to adapt the principles and equations of calculus to work with a non-continuous space. This has been explored in areas of mathematics such as non-standard analysis.

5. How would a non-continuous space affect our understanding of the universe?

If space were found to be non-continuous, it would have significant implications for our understanding of the universe. It could potentially challenge our current theories of gravity and the structure of space-time, and would require a re-evaluation of many fundamental principles in physics and mathematics.

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