Periodic Complex exponential signal

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Homework Help Overview

The discussion revolves around understanding the periodicity of complex exponential signals, particularly focusing on the implications of the angular frequency \( \omega \) being zero versus non-zero. Participants explore the conditions under which the signal remains periodic and the mathematical relationships involved.

Discussion Character

  • Conceptual clarification, Mathematical reasoning

Approaches and Questions Raised

  • Participants discuss the application of Euler's formula and its relevance to the periodicity of the signal. Questions arise regarding the derivation of specific conditions, such as \( \omega T = m \cdot 2\pi \), and the implications of these conditions for the periodicity of the cosine function.

Discussion Status

Some participants express confusion about specific mathematical expressions and their meanings, while others provide insights that help clarify the relationships between the variables involved. There appears to be a productive exchange of ideas, with some participants gaining understanding through the discussion.

Contextual Notes

Participants are navigating through the complexities of periodic signals and the mathematical definitions that govern them, with some uncertainty about the assumptions underlying the problem setup.

bibo_dvd
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hello guys ..
first of all , iam not sure that i should type this thread here . so excuse me for that

in this problem i can understand the part until it's said that w=0 then x(t)=1, which is periodic for any value of T
but i can't understand the part after that in the case of w is not equal to zero
so help me with this please :)
Thx guys

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Perhaps Euler's formula will be of help:
$$
e^{i \omega_0 T} = \cos(\omega_0 T) + i \sin (\omega_0 T)
$$
 
okay , i know Euler's formula but i can't understand " wt=m*2*pi " or "T=m*(2pi/w) m=positive integer"

how did this part was given ??
 
You want ##
e^{i \omega_0 T} = \cos(\omega_0 T) + i \sin (\omega_0 T) = 1
##, meaning that ##\cos(\omega_0 T)=1## and ##\sin (\omega_0 T)=0##. What are the values of ##\omega_0 T## for which these equalities hold?
 
omg , now i understand , we need cos(wT) to be always 1 , so cos (2*pi) and (4*pi) and so on , yaaaayyyyy :D
Thx man for help :)
 

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