Calculus Breakdown: Understanding Principle Assumptions & Limits

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Discussion Overview

The discussion centers around the conditions under which the integral transformation from \(\int^t_0 \frac{dp}{dt} dt\) to \(\int^{p(t)}_{p(0)} dp\) is valid. Participants explore the assumptions regarding the smoothness and differentiability of the functions involved, as well as the implications of these properties on the validity of the transformation.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested
  • Mathematical reasoning

Main Points Raised

  • One participant questions the validity of the integral transformation and seeks to understand the assumptions behind it, particularly regarding the smoothness of \(p(t)\) and \(t\).
  • Another participant asserts that \(\frac{dp}{dt}\) must exist and that \(p(t)\) should be bijective or monotonic for the transformation to hold.
  • Concerns are raised about the subtleties of the chain rule and the conditions under which it applies, particularly in relation to differentiability and continuity.
  • Some participants discuss the robustness of integrals compared to derivatives, noting that integrals can handle piecewise discontinuities, while derivatives cannot be defined at such points.
  • There is a discussion about the implications of differentiability versus smoothness, with one participant clarifying that differentiability does not necessarily imply smoothness.
  • Another participant mentions the substitution rule for integrals, emphasizing the need for differentiability and continuity of the functions involved for the transformation to be valid.
  • One participant expresses a desire to explore other potential breakdowns of the transformation beyond the non-existence of \(\frac{dp}{dt}\).

Areas of Agreement / Disagreement

Participants express varying views on the conditions necessary for the integral transformation to be valid. While some agree on the importance of differentiability and continuity, others highlight the nuances and potential exceptions, indicating that the discussion remains unresolved with multiple competing perspectives.

Contextual Notes

Participants reference concepts such as measure theory and the Lebesgue-Radon-Nikodym theorem, indicating that a deeper understanding of these topics may be necessary to fully grasp the implications of the discussed transformations.

LogicalTime
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quick question, I was watching an MITOCW physics lecture and I want to know where a principle breaks down.

\int^t_0 \frac{dp}{dt} dt = \int^{p(t)}_{p(0)} dp

how do I know such a thing is allowed? where does this break down? does it break down if p or t does not have property such as smoothness?

here is the little section of the lecture where I saw it:
http://www.youtube.com/watch?v=Lkuo6nZ6nZM#t=12m30s

I am never comfortable until I know what is being assumed and where something breaks. Thanks!
 
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Well dp/dt has to exist for a start. p(t) probably needs to be bijective as well (monotonic will do).

This thing is the chain rule. (It's everywhere, look it up)
Or integration by substitution (I think there's a proof on Wikipedia that isn't too bad)
 
chain rule has this form:
092a91734fb9c50d36fba56732186ba2.png


since the forms are not exactly the same, I am concerned about subtleties.
 
perhaps p(t) has to be differentiable with respect to t, not just piecewise differentiable? otherwise dp/dt would not be defined for certain points?
 
[edit] Oh, let me think about that.
[edit again] Integration ignores isolated "points", heuristically (sets of zero measure? I don't know any measure theory). Piecewise is fine. It's basically the chain rule in the opposite direction.

meow
And let f=1 after you get that proof.
Also, try not to write
<br /> \int^t_0 \frac{dp}{dt} dt<br />
Because the 't' inside the integral is like a dummy variable. It's not a big deal usually though.

Integration is, intuitively, "more likely" to work than differentiation (you can integrate some discontinuous curves, for example...but there's no chance to differentiate on both sides of a discontinuity). As long as derivatives exist, we should be okay. Don't quote me on that though. Forgot all my analysis.

[edit] We can integrate over piecewise discontinuity just fine. (I hate to say it, but using the 'area under a curve' analogy, we can see there's no problem.[/edit]

Physical examples are unlikely to involve anything close to pathological functions.
 
yep I know integrals are quite robust

does not \frac{dp}{dt}[\tex] on its own imply that p(t) is smooth, or that the derivative is continuous since otherwise the limit could have 2 values at a particular time t (one limit coming from the right (+) and one coming from the left(-))
 
We have a chain rule for a differentials as well, dp=p&#039;(t)dt. For example if p=t^3 then dp=3t^2dt. Furthermore with the integral given in the OP you know for sure that p&#039;(t) exist and if a function is differentiable it is of course smooth and continuous.
 
Oh, right.
Okay.
Well. Usually, yeah.

But p(t)= -t^2 for t<0 and t^2 for t>0 and p=0 at t=0 isn't smooth, is it?

When we move to physics though, we don't mind if dp/dt doesn't exist at some particular points.

If a function is differentiable, it doesn't have to be smooth, but it does have to be continuous.
A bunch of pathological functions involving sin(1/x) are going to be differentiable once, but not smooth.
 
You're right I was sloppy in my use of smooth. Functions are smooth if derivatives of any order exist, not just one. However his question, as I understood it, was how you go from the first integral to the second. If the first integral doesn't exist, because p'(t) does not exist then there is no point in continuing. The question only makes sense if p(t) is differentiable in the first place.
 
Last edited:
  • #10
exactly I am comfortable with where integrals exist. I am trying to explore where
\frac{dp}{dt} dt = dp
breaks down. It seems the only way for us to break this is to make
\frac{dp}{dt}
not exist. Do you think this is right or could it break some other way?
 
  • #11
Are you aware that this is just the substitution rule for integrals?

Substitution rule:
<br /> \int g(f(x))f&#039;(x)dx=\int g(y)dy <br />

with y=f(x)

This works if f is differentiable with a continuous derivative, if g is continuous and if the composition g \circ f exists.
 
  • #12
LogicalTime said:
exactly I am comfortable with where integrals exist. I am trying to explore where
\frac{dp}{dt} dt = dp
breaks down. It seems the only way for us to break this is to make
\frac{dp}{dt}
not exist. Do you think this is right or could it break some other way?
The Lebesgue-Radon-Nikodym theorem goes into that. You need to know a bit of measure theory, treating the integrals of functions as measures.
 

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