10/3,6 - The Game: Difference between revisions

Revision as of 17:37, 12 November 2008

The Game

The idea behind the game is to use linearity (superposition and proportionality) and time invariance to find an output for a given input. An initial input and output are given.

Input	LTI System	Output	Reason
$δ (t)$	$⟹$	$h (t)$	Given
$δ (t - λ)$	$⟹$	$h (t - λ)$	Time Invarience
$x (λ) δ (t - λ)$	$⟹$	$x (λ) h (t - λ)$	Proportionality
$x (t) = \int_{- \infty}^{\infty} x (λ) δ (t - λ) d x$	$⟹$	$\underset{C o n v o l u t i o n I n t e g r a l}{\underset{⏟}{\int_{- \infty}^{\infty} x (λ) h (t - λ) d x}}$	Superposition

With the derived equation, note that you can put in any $x (t)$ to find the given output. Just change your t for a lambda and plug n chug.

Example 1

Let $x (t) = e^{j 2 π n t / T} = e^{j 2 π ω_{n} t}$

$e^{j 2 π ω_{n} t}$	$= \int_{- \infty}^{\infty} e^{j 2 π ω_{n} λ} h (t - λ) d λ$	Let $t - λ = u$ thus $d u = - d λ$
	$= - \int_{\infty}^{- \infty} e^{j 2 π ω_{n} (t - u)} h (u) d u$	The order of integration switched due to changing from $- λ = u$
	$= \underset{e i g e n v a l u e}{\underset{⏟}{(\int_{- \infty}^{\infty} e^{- j 2 π ω_{n} u} h (u) d u)}} \underset{e i g e n f u n c t i o n}{\underset{⏟}{e^{j 2 π ω_{n} t}}}$
	$= ⟨ h ∣ e^{j 2 π ω_{n} u} ⟩ e^{j 2 π ω_{n} t}$	Different notation
	$= H (ω_{n}) e^{j 2 π ω_{n} t}$	Different notation

@@ Line 32: / Line 32: @@
 With the derived equation, note that you can put in '''any''' <math> x(t) \,\! </math> to find the given output. Just change your t for a lambda and plug n chug.
-==Example==
+==Example 1==
 Let <math>x(t) = e^{j2\pi nt/T} = e^{j2\pi \omega_n t}</math>
 {| border="0" cellpadding="0" cellspacing="0"
@@ Line 56: / Line 56: @@
 |Different notation
 |}
+==Example 2==

10/3,6 - The Game: Difference between revisions

Revision as of 17:37, 12 November 2008

The Game

Example 1

Example 2

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