Can a Functional Analysis Problem Be Solved Using a Sequence of Regions?

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SUMMARY

The discussion centers on the interpretation of continuity and differentiability in functional analysis, specifically addressing the statement "f is continuous means f is infinitely differentiable." Participants clarify that continuity does not imply differentiability, using the example of the function f(x) = |x|, which is continuous but not differentiable at x = 0. The term "smooth" is debated, with varying definitions across texts, leading to a consensus that "smooth" may refer to different levels of differentiability. Ultimately, the focus remains on understanding the implications of continuity for solving functional analysis problems.

PREREQUISITES
  • Understanding of basic calculus concepts, particularly continuity and differentiability.
  • Familiarity with the definitions of smooth functions in mathematical analysis.
  • Knowledge of functional analysis principles and terminology.
  • Experience with real-valued functions and their properties.
NEXT STEPS
  • Research the definitions and distinctions between continuous, continuously differentiable, and smooth functions.
  • Study the implications of the absolute value function in calculus and its differentiability properties.
  • Explore the concept of supremum norms and their applications in functional analysis.
  • Learn about sequences of regions and their use in proofs within functional analysis.
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Mathematics students, educators, and professionals in fields requiring a deep understanding of functional analysis, particularly those dealing with continuity and differentiability of functions.

wdlang
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Since, in the statement of the problem, f is only required to be continuous, not differentiable, what does f ' mean?
 
HallsofIvy said:
Since, in the statement of the problem, f is only required to be continuous, not differentiable, what does f ' mean?

f is continuous means f is infinitely differentiable
 
wdlang said:
f is continuous means f is infinitely differentiable

No it doesn't. Assume ##\displaystyle f\left(x\right)=\left|x\right|##. It's obviously continuous (##\displaystyle\forall a\in\mathbb{R}\ \left(\lim_{x\to a}\left|x\right|=\left|a\right|\right)##), but its derivative at 0 doesn't exist.
 
Whovian said:
No it doesn't. Assume ##\displaystyle f\left(x\right)=\left|x\right|##. It's obviously continuous (##\displaystyle\forall a\in\mathbb{R}\ \left(\lim_{x\to a}\left|x\right|=\left|a\right|\right)##), but its derivative at 0 doesn't exist.

ok, i mean smooth

sorry for that
 
wdlang said:
ok, i mean smooth

sorry for that

Okay. ##\displaystyle\dfrac{x\cdot\left|x\right|}{2}##. It's smooth, but its derivative is |x|.

Though I'm pretty sure you mean continuously differentiable, which is ideally what we'd assume.
 
Whovian said:
Okay. ##\displaystyle\dfrac{x\cdot\left|x\right|}{2}##. It's smooth, but its derivative is |x|.

Though I'm pretty sure you mean continuously differentiable, which is ideally what we'd assume.

Actually, I think he DOES mean smooth, a function is smooth (by definition) if it is infinitely differentiable. So your "counter-example" is not valid; in other words, ##\displaystyle\dfrac{x\cdot\left|x\right|}{2}## is not smooth.
 
"smooth" is not a standardized term. In some texts it means "infinitely differentiable" but in others it only means "the first derivative is continuous" and "infinitely smooth" is used to mean "infinitely differentiable". In some texts you will even see "sufficiently smooth" meaning "differentiable to whatever extent is necessary to prove this".
 
I've also seen "smooth" to mean "analytic" in the sense of Taylor series convergence, which would be separate from "infinitely differentiable".
 
  • #10
OKAY! We get it, there are a lot of different terms for the same thing, and sometimes the same term means different things. Let's focus on the post's question, not some terms; all we need to know is that the function "f is continuous means f is infinitely differentiable", and that's all we need to know to attempt to find a solution. Focus on that.
 
  • #11
Why take the absolute value squared, if the function is real valued? Just take the square of the function, right? Or is that the supremum norm of the function? i.e. |f| = sup(f)
 
  • #12
It loosk like you might be able to make one of those proofs like considering the sequence of regions where |f|<1/n, then blah blah. Not sure if that'll work, but t's first thing that popped into my head.
 

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