(Part 2)
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<math>\,x(t)=\frac{sin(t)}{t}\,</math>
 
<math>\,x(t)=\frac{sin(t)}{t}\,</math>
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The function could be made continuous by:
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<math>\,y(t)=\sum_{k\in \mathbb{Z}}x(t+2\pi k)=\sum_{k\in \mathbb{Z}}\frac{sin(t+2\pi k)}{t+2\pi k}\,</math>
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'''Proof:'''

Revision as of 21:00, 11 September 2008

Part 1

The function was chosen at random from HW1: HW1.4 Hang Zhang - Periodic vs Non-period Functions_ECE301Fall2008mboutin

$ \,x(t)=2cos(2\pi t)\, $


Periodic Signal in DT:

If $ x(t) $ is sampled at $ period=0.1 $, the function

$ \,y[n]=x[0.1n]=2cos(\frac{2\pi n}{10})\, $

is periodic, since

$ \,\exists N\in \mathbb{Z}, N\not= 0\, $ such that $ \,y[n]=y[n+N], \forall n\in \mathbb{Z}\, $

$ \,2cos(\frac{2\pi n}{10})=2cos(\frac{2\pi n}{10}+\frac{2\pi N}{10})\, $

This is true when

$ \,\frac{2\pi N}{10}=2\pi \, $

$ \,N=10\, $


This can be seen in the following plot:

Jkubasci dt periodic ECE301Fall2008mboutin.jpg

Non-Periodic Signal in DT:

However, if $ x(t) $ is sampled at $ period=1/2\pi $, the function

$ \,z[n]=x[\frac{n}{2\pi}]=2cos(n)\, $

is not periodic in DT, since there is no integer $ N\in \mathbb{Z}, N\not= 0 $ such that

$ \,z[n]=z[n+N], \forall n\in \mathbb{Z}\, $

$ \,2cos(n)=2cos(n+N)\, $

This would be true when

$ \,N=2\pi k, k\in \mathbb{Z}, k\not= 0\, $

$ \,\frac{N}{k}=2\pi \, $

but, $ 2\pi $ is irrational, thus there are no values for the integers $ \,N,k\, $ that will satisfy this equation.

This can be seen in the following plot:

Jkubasci dt nonperiodic ECE301Fall2008mboutin.jpg

Part 2

The non-periodic function was chosen from HW1: HW1.4 Ben Horst_ECE301Fall2008mboutin. It appears to be possible with this function since the function decays in the positive and negative x directions.

$ \,x(t)=\frac{sin(t)}{t}\, $


The function could be made continuous by:

$ \,y(t)=\sum_{k\in \mathbb{Z}}x(t+2\pi k)=\sum_{k\in \mathbb{Z}}\frac{sin(t+2\pi k)}{t+2\pi k}\, $


Proof:

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Abstract algebra continues the conceptual developments of linear algebra, on an even grander scale.

Dr. Paul Garrett