Jump to content

Recommended Posts

Posted

Since everyone's posting questions here, I thought I'd post a nice question I got on my Analysis III assignment last week. It's a bit involved (and somewhat pointless) but I thought it was pretty nice for some reason:

 

Let [math]f : [a,b] \to \mathbb{R}[/math] be a regulated function, and let [math](x_n)_{n=1}^{\infty}[/math] be a sequence in [math](a,b)[/math] such that [math](x_n) \to a[/math] as [math]n \to \infty[/math]. Show that [math]( f(x_n) )_{n=1}^{\infty}[/math] is a Cauchy sequence.

Posted

It just struck me that for some reason, when I looked up regulated functions the other day, nobody seemed to know about them so maybe they're known under a different name; if anyone doesn't know what the hell I'm on about, please let me know :)

Posted

i ve been doing some stuff on sequences and sub sequences, but havent come across regulated functions or cauchy sequences. could u explain what they are

Posted

A Cauchy sequence is defined as follows:

 

A sequence [math](a_n)[/math] is Cauchy if [math]\forall \epsilon > 0 \,\,\, \exists N \in \mathbb{N}[/math] such that [math]\forall n, m > N, \,\,\, | a_n - a_m | < \epsilon[/math].

 

A function [math]f : [a,b] \to \mathbb{R}[/math] is regulated if [math]\forall \epsilon > 0\,\,\, \exists \varphi[/math] where [math]\varphi[/math] is a step function such that [math]| \varphi(x) - f(x) | < \epsilon[/math].

  • 2 weeks later...
Posted

Actually, thinking about this (i've never heard of regulated functions so was interested in doing this):

 

[math]|f(x_n)-f(x_m)|=|f(x_n)-\varphi(x_n)+\varphi(x_n)-\varphi(x_m)+\varphi(x_m)-f(x_m)|[/math]

 

use the triangle inequality to make that into three terms, and that [math]\varphi[/math] is a step function to conclude that since x_n converges to a, that all those terms can be made either less than e, and the whole thing less than 3e, or each less than e/3, and the whole less than e, for all n,m greater than some N.

 

Is that the proof you found? I only write it out to check because that style of argument is very useful, and is what you'll see when you show that a continuous function on a closed bounded interval is uniformly continuo

Posted
Actually' date=' thinking about this (i've never heard of regulated functions so was interested in doing this):

 

[math']|f(x_n)-f(x_m)|=|f(x_n)-\varphi(x_n)+\varphi(x_n)-\varphi(x_m)+\varphi(x_m)-f(x_m)|[/math]

 

use the triangle inequality to make that into three terms, and that [math]\varphi[/math] is a step function to conclude that since x_n converges to a, that all those terms can be made either less than e, and the whole thing less than 3e, or each less than e/3, and the whole less than e, for all n,m greater than some N.

 

Is that the proof you found? I only write it out to check because that style of argument is very useful, and is what you'll see when you show that a continuous function on a closed bounded interval is uniformly continuo

 

That's the one. It's quite a nice proof, or so I thought :)

 

The advantage of regulated functions is that you can define their integral as follows:

 

If f is regulated on [a,b], with a sequence of step functions [math](\psi_n)[/math] converging uniformly to f (i.e. [math]d(f, \psi_n) \to 0[/math] as [math]n\to\infty[/math]), then define [math]\int_a^b f = \lim_{n\to\infty} \int_a^b \psi_n[/math].

 

I'm not sure how this relates to Riemann sums (mainly because I haven't done them yet) so I'll leave that to someone else.

Posted
Actually' date=' thinking about this (i've never heard of regulated functions so was interested in doing this):

 

[math']|f(x_n)-f(x_m)|=|f(x_n)-\varphi(x_n)+\varphi(x_n)-\varphi(x_m)+\varphi(x_m)-f(x_m)|[/math]

 

use the triangle inequality to make that into three terms, and that [math]\varphi[/math] is a step function to conclude that since x_n converges to a, that all those terms can be made either less than e, and the whole thing less than 3e, or each less than e/3, and the whole less than e, for all n,m greater than some N.

 

Is that the proof you found? I only write it out to check because that style of argument is very useful, and is what you'll see when you show that a continuous function on a closed bounded interval is uniformly continuo

 

That's the one. It's quite a nice proof, or so I thought :)

 

The advantage of regulated functions is that you can define their integral as follows:

 

If f is regulated on [a,b], with a sequence of step functions [math](\psi_n)[/math] converging uniformly to f (i.e. [math]d(f, \psi_n) \to 0[/math] as [math]n\to\infty[/math]), then define [math]\int_a^b f = \lim_{n\to\infty} \int_a^b \psi_n[/math].

 

I'm not sure how this relates to Riemann sums (mainly because I haven't done them yet) so I'll leave that to someone else.

Posted

Yeah, it's all pretty interesting stuff. We've just moved onto Fourier series, so expect the same kind of thing.

Posted

Yeah, it's all pretty interesting stuff. We've just moved onto Fourier series, so expect the same kind of thing.

Posted

Yeah, they seem to be piling the work on atm, completely snowed under with all the assignments that are due in ;)

Posted

Yeah, they seem to be piling the work on atm, completely snowed under with all the assignments that are due in ;)

Create an account or sign in to comment

You need to be a member in order to leave a comment

Create an account

Sign up for a new account in our community. It's easy!

Register a new account

Sign in

Already have an account? Sign in here.

Sign In Now
×
×
  • Create New...

Important Information

We have placed cookies on your device to help make this website better. You can adjust your cookie settings, otherwise we'll assume you're okay to continue.