10/10,13,16,17 - Fourier Transform Properties

Properties of the Fourier Transform

Linearity

$F\left[a\,x(t)+b\,x(t)\right]$	$=\int _{-\infty }^{\infty }\left[a\,x(t)+b\,x(t)\right]e^{-j\,2\pi f\,t}\,dt$
	$=a\int _{-\infty }^{\infty }\,x(t)\,e^{-j\,2\pi f\,t}\,dt+b\int _{-\infty }^{\infty }\,x(t)\,e^{-j\,2\pi f\,t}\,dt$
	$=a\,F[x(t)]+b\,F[x(t)]$

Time Invariance (Delay)

$F[x(t-t_{0})]\,\!$	$=\int _{-\infty }^{\infty }x(t-t_{0})\,e^{-j\,2\pi f\,t}\,dt$	Let $u=t-t_{0}\,\!$ and $du=dt\,\!$
	$=\int _{-\infty }^{\infty }x(u)\,e^{-j\,2\pi f\,(u+t_{0})}\,du$
	$=e^{-j\,2\pi f\,t_{0}}\int _{-\infty }^{\infty }x(u)\,e^{-j\,2\pi f\,u}\,du$
	$=e^{-j\,2\pi f\,t_{0}}\,F[x(t)]$

Frequency Shifting

$F\left[e^{j\,2\pi f\,t}x(t)\right]$	$=\int _{-\infty }^{\infty }\left[e^{j\,2\pi f_{0}\,t}x(t)\right]e^{-j\,2\pi f\,t}\,dt$
	$=\int _{-\infty }^{\infty }x(t)\,e^{-j\,2\pi (f-f_{0})\,t}\,dt$
	$=X(f-f_{0})\,\!$

Double Sideband Modulation

$F[cos(2\pi f_{0}\,t)\cdot x(t)]$	$=\int _{-\infty }^{\infty }{\frac {e^{j\,2\pi f_{0}\,t}+e^{-j\,2\pi f_{0}\,t}}{2}}x(t)\,e^{-j\,2\pi f\,t}\,dt$
	$={\frac {1}{2}}\int _{-\infty }^{\infty }x(t)\left[e^{-j\,2\pi (f-f_{0})\,t}+e^{-j\,2\pi (f+f_{0})\,t}\right]\,dt$
	$={\frac {1}{2}}X(f-f_{0})+{\frac {1}{2}}X(f+f_{0})$

Differentiation in Time

$x(t)\,\!$	$=F^{-1}\left[X(f)\right]$
$F\left[{\frac {dx}{dt}}\right]$	$=F\left[{\frac {d}{dt}}F^{-1}\left[X(f)\right]\right]$
	$=F\left[{\frac {d}{dt}}\int _{-\infty }^{\infty }X(f)\,e^{j\,2\pi f\,t}\,df\right]$
	$=F\left[\int _{-\infty }^{\infty }j\,2\pi fX(f)e^{j\,2\pi f\,t}\,df\right]$
	$=F\left[j\,2\pi f\,F^{-1}[X(f)]\right]$
	$=j\,2\pi f\,X(f)$	Thus ${\frac {dx}{dt}}$ is a linear filter with transfer function $j\,2\pi f$

The Game (frequency domain)

You can play the game in the frequency or time domain, but not both at the same time
- Then how can you use the Fourier Transform, but can't build up to it?

Input	LTI System	Output	Reason
$\delta (t)\,\!$	$\Longrightarrow$	$h(t)\,\!$	Given
$\delta (t)\,e^{-j\,2\,\pi f\,t}$	$\Longrightarrow$	$h(t)\,e^{-j\,2\,\pi f\,t}$	Proportionality
$\int _{-\infty }^{\infty }\delta (t)\,e^{-j\,2\,\pi f\,t}\,dt=F[\delta (t)]=1$	$\Longrightarrow$	$\int _{-\infty }^{\infty }h(t)\,e^{-j\,2\,\pi f\,t}\,dt=F[h(t)]=H(f)$	Superposition
$\int _{-\infty }^{\infty }\delta (t-\lambda )\,e^{-j\,2\,\pi f\,t}\,dt=F[\delta (t-\lambda )]=1\cdot e^{-j\,2\,\pi f\,\lambda }$	$\Longrightarrow$	$H(f)\cdot e^{-j\,2\,\pi f\,\lambda }$	Time Invariance
$x(\lambda )\cdot 1\cdot e^{-j\,2\,\pi f\,\lambda }$	$\Longrightarrow$	$x(\lambda )\cdot H(f)\cdot e^{-j\,2\,\pi f\,\lambda }$	Proportionality
$\int _{-\infty }^{\infty }x(\lambda )\cdot 1\cdot e^{j\,2\,\pi f\,\lambda }\,d\lambda =X(F)$	$\Longrightarrow$	$\int _{-\infty }^{\infty }x(\lambda )\cdot H(f)\cdot e^{j\,2\,\pi f\,\lambda }\,d\lambda =X(F)\,H(f)$	Superposition

Having trouble seeing $F\left[x(t)*h(t)\right]=X(f)\cdot H(f)$
Since we were dealing in the frequency domain, is that the reason why multiplying one side did not result in a convolution on the other?

The Game (Time Domain??)

Input	LTI System	Output	Reason
$1\cdot e^{j\,2\,\pi f_{0}\,t}$	$\Longrightarrow$	$h(t)e^{j\,2\,\pi f_{0}\,t}=e^{j\,2\,\pi f_{0}\,t}h(t)$	Proportionality
		$\int _{-\infty }^{\infty }h(\lambda )\cdot e^{j\,2\,\pi f_{0}\,(t-\lambda )}\,d\lambda$	Why d lambda instead of dt?
		$e^{j\,2\,\pi f_{0}\,\lambda }\int _{-\infty }^{\infty }h(\lambda )\cdot e^{-j\,2\,\pi f_{0}\,\lambda }\,d\lambda$
		$e^{j\,2\,\pi f_{0}\,t}\,H(f_{0})$
$X(f_{0})\cdot e^{j\,2\,\pi f_{0}\,t}$	$\Longrightarrow$	$X(f_{0})\cdot e^{j\,2\,\pi f_{0}\,t}\,H(f_{0})$	Proportionality, Why isn't this a convolution?
$\int _{-\infty }^{\infty }X(f_{0})\cdot e^{j\,2\,\pi f_{0}\,t}\,df_{0}=x(t)$	$\Longrightarrow$	$\int _{-\infty }^{\infty }X(f_{0})H(f_{0})\cdot e^{j\,2\,\pi f_{0}\,t}\,df_{0}=F^{-1}\left[X(f)H(f)\right]$	Superposition, Not X(f_0)H(f_0)?

Relation to the Fourier Series

$x(t)\,\!$	$=x(t+T)\,\!$
	$=\sum _{n=-\infty }^{\infty }\alpha _{n}e^{j\,2\pi n\,t/T}$
	$=\underbrace {\sum _{m=-\infty }^{-1}\alpha _{m}e^{j\,2\pi m\,t/T}} _{Negativefrequencies}+\alpha _{0}+\sum _{n=1}^{\infty }\alpha _{n}e^{j\,2\pi n\,t/T}$
	$=\sum _{n=1}^{\infty }\alpha _{-n}e^{-j\,2\pi n\,t/T}+\alpha _{0}+\sum _{n=1}^{\infty }\alpha _{n}e^{j\,2\pi n\,t/T}$	Let $n=-m\,\!$ and reverse the order of summation
		Note that $\alpha _{-n}e^{-j\,2\pi n\,t/T}$ is the complex conjugate of $\alpha _{n}e^{j\,2\pi n\,t/T}$
	$=\alpha _{0}+2\Re \left[\sum _{n=1}^{\infty }\alpha _{n}e^{j\,2\pi n\,t/T}\right]$	$x(t)+x(t)^{*}=2\,\Re \left[x(t)\right]$

How can we assume that the answer exists in the real domain? You can break any function down into a Taylor series. There are even and odd powers in the series.

Remember from 10/02 - Fourier Series that $\alpha _{n}={\frac {1}{T}}\int _{-T/2}^{T/2}x(t)e^{-j\,2\,\pi \,n\,t/T}\,dt$

$\alpha _{n}=\left|\alpha _{n}\right|\,e^{j\theta }$ ?
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Building up to $F\left[u(t)\right]$

$e^{i\pi }\,\!$	$=\cos \pi +i\sin \pi .\,\!$	Euler's Identity
$r_{0}(t)\,\!$	$=-r_{0}(-t)\,\!$	Real odd function of t
$F\left[r_{0}(t)\right]\,\!$	$=\int _{-\infty }^{\infty }r_{0}(t)\,e^{-j\,2\pi \,f\,t}\,dt$
	$=\int _{-\infty }^{\infty }r_{0}(t)\,\left[\cos(-2\pi \,f\,t)+j\sin(-2\pi \,f\,t)\right]\,dt$
	$=\int _{-\infty }^{\infty }r_{0}(t)\,\left[\cos(2\pi \,f\,t)-j\sin(2\pi \,f\,t)\right]\,dt$	$\cos(-x)=\cos(x)\,\!$ & $\sin(-x)=-\sin(x)\,\!$
	$=j\int _{-\infty }^{\infty }r_{0}(t)\,\sin(-2\pi \,f\,t)\,dt$	$r_{0}(t)\cdot j\sin(-2\pi \,f\,t)$ = Real odd. Integrates out over symmetric limits.
	$=\,\!$ Imaginary Odd function of $f\,\!$
$r_{e}(t)\,\!$	$=r_{e}(-t)\,\!$	Real even function of t
$F\left[r_{e}(t)\right]\,\!$	$=\int _{-\infty }^{\infty }r_{e}(t)\,e^{-j\,2\pi \,f\,t}\,dt$
	$=\int _{-\infty }^{\infty }r_{e}(t)\,\left[\cos(-2\pi \,f\,t)+j\sin(-2\pi \,f\,t)\right]\,dt$
	$=\int _{-\infty }^{\infty }r_{e}(t)\,\left[\cos(2\pi \,f\,t)-j\sin(2\pi \,f\,t)\right]\,dt$	$\cos(-x)=\cos(x)\,\!$ & $\sin(-x)=-\sin(x)\,\!$
	$=\int _{-\infty }^{\infty }r_{e}(t)\,\cos(-2\pi \,f\,t)\,dt$	$r_{e}(t)\cdot \cos(-2\pi \,f\,t)$ = Real odd. Integrates out over symmetric limits.
	$=\,\!$ Real Even function of $f\,\!$

Definitions

$x(t)\,\!$	$=x_{e}(t)+x_{(}o)t\,\!$	Can't x(t) have parts that aren't even or odd?
$x_{e}(t)\,\!$	$={\frac {x(t)+x(-t)}{2}}$
$x_{o}(t)\,\!$	$={\frac {x(t)-x(-t)}{2}}$
$u(t)\,\!$	$={\frac {1+\operatorname {sgn}(t)}{2}}$	$\operatorname {sgn}(t)={\begin{cases}1,&t>0\\0,&t=0\\-1,&t<0\end{cases}}$
$u_{e}(t)\,\!$	$={\frac {1}{2}}$
$u_{o}(t)\,\!$	$={\frac {\operatorname {sgn}(t)}{2}}$

$F\left[u(t)\right]$

$F\left[{\frac {1}{2}}\right]$	$=\int _{-\infty }^{\infty }{\frac {1}{2}}e^{-j\,2\,\pi \,f\,t}\,dt$
	$={\frac {1}{2}}\delta (f)$
$F\left[{\frac {\operatorname {sgn}(t)}{2}}\right]$	$=\int _{-\infty }^{\infty }{\frac {\operatorname {sgn}(t)}{2}}e^{-j\,2\,\pi \,f\,t}\,dt$
	$={\frac {1}{2}}\left[\int _{-\infty }^{0}-1\cdot e^{-j\,2\,\pi \,f\,t}\,dt+\int _{0}^{\infty }1\cdot e^{-j\,2\,\pi \,f\,t}\,dt\right]$
	$=\underbrace {{\frac {1}{2}}\int _{0}^{-\infty }e^{j\,2\,\pi \,f\,u}\,du} _{\begin{matrix}u=-t\\du=-dt\end{matrix}}+\underbrace {{\frac {1}{2}}\int _{0}^{\infty }e^{-j\,2\,\pi \,f\,u}\,du} _{\begin{matrix}u=t\\du=dt\end{matrix}}$
	$=\int _{0}^{-\infty }{\frac {e^{j\,2\,\pi \,f\,u}+e^{-j\,2\,\pi \,f\,u}}{2}}\,du$
	$=\int _{0}^{-\infty }\cos(2\,\pi \,f\,u)\,du$

10/10,13,16,17 - Fourier Transform Properties

Contents

Properties of the Fourier Transform

Linearity

Time Invariance (Delay)

Frequency Shifting

Double Sideband Modulation

Differentiation in Time

The Game (frequency domain)

The Game (Time Domain??)

Relation to the Fourier Series

Building up to $F\left[u(t)\right]$

Definitions

$F\left[u(t)\right]$

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10/10,13,16,17 - Fourier Transform Properties

Properties of the Fourier Transform

Linearity

Time Invariance (Delay)

Frequency Shifting

Double Sideband Modulation

Differentiation in Time

The Game (frequency domain)

The Game (Time Domain??)

Relation to the Fourier Series

Building up to F [ u ( t ) ] {\displaystyle F\left[u(t)\right]}

Definitions

F [ u ( t ) ] {\displaystyle F\left[u(t)\right]}

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Building up to $F\left[u(t)\right]$

$F\left[u(t)\right]$