Signals and Systems: Difference between revisions

HW #1 - Make a personal page on this wiki (Chris Lau)(Jodi S. Hodge)(Chris Wills)
HW #2 - Write a tutorial about installing and/or using Octave (Chris Lau)(Jodi S. Hodge)(Victor Shepherd)
HW #3 - Show graphically that $\int_{- \infty}^{\infty} e^{j 2 π f (t - u)} d f = δ (t - u)$ (Chris Lau)(Jodi S. Hodge)(Chris Wills)(Victor Shepherd)

HW #4 - Given a linear time-invariant system where $u (t)$ produces an output $w (t)$ , find the output due to any function $x (t)$ (Chris Lau)
HW #5:
- Part 1 - Find $F [e^{- σ t} x (t) u (t)]$ and relate it to the Laplace Transform. Derive the Inverse Laplace Transform of this from the inverse Fourier Transform.
- Part 2 -
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HW #6 Pick a property of the Fourier Transform & present it on the Wiki. Make a table with all your properties. Interpret your property. (Ben Henry)

People Involved with this Wiki

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 * HW #4 - Given a linear time-invariant system where <math>\ u(t) </math> produces an output <math>\ w(t) </math>, find the output due to any function <math>\ x(t) </math> ([[HW 4|Chris Lau]])
-* HW #5 - Find <math> \ F[e^{- \sigma t} x(t)u(t)] </math>
+* HW #5:
+** Part 1 -  Find <math> \ F[e^{- \sigma t} x(t)u(t)] </math> and relate it to the Laplace Transform. Derive the Inverse Laplace Transform of this from the inverse Fourier Transform.
+** Part 2 - [[Image:20101006KeyDSCN3161.jpg|thumb|300px|center]]
 * HW #6 Pick a property of the Fourier Transform & present it on the Wiki. Make a table with all your properties. Interpret your property. ([[HW 6|Ben Henry]])