Difference between revisions of "HW4.3 Ben Horst ECE301Fall2008mboutin" - Rhea

Revision as of 15:46, 25 September 2008

Homework 4 Ben Horst: 4.1 :: 4.3 :: 4.4

y(t) = 3x(t) which is proven as an LTI system ( shown here)

y( $\delta(t)$ ) = 3( $\delta(t)$ )

=>impulse response = $3\delta(t)$

Find H(s):

H( $j\omega$ ) = $\int_{-\infty}^{\infty}h(\tau)e^{-j\omega\tau}d\tau$ , where $j\omega$ is s.

H(s) = $\int_{-\infty}^{\infty}h(\tau)e^{-s\tau}d\tau$

H(s) = $\int_{-\infty}^{\infty}3\delta(\tau)e^{-s\tau}d\tau$

By the Sifting property, this is:

H(s) = $$ 3e^0 $$

thus,

H(s) = $$ 3 $$

From previous part of homework:

$x(t) = 2\sin(6t) + 4\cos(3t)$

From the previously computed math, we can determine all the coefficients: $\ \ a_{-2} = 1; \ \ a_{-1} = 2; \ \ a_{0} = 0; \ \ a_1 = 2;\ \ a_{2} = -1$

The fundamental period of the function is found from: $e^{j\omega_0}$ where he period T = ${2\pi \over \omega_o}$

Thus, the fundamental period = ${2\pi \over 3}$

Given that y(t) = $\sum_{k=-\infty}^{\infty} a_kH(j\omega_0 k) e^{j\omega_0 k}$ from pg228 in Signals and Systems (Oppenheim & Willsky)

Thus:

y(t) = 1(3) $e^{-2jt}$ + 2(3) $e^{-1jt}$ + 0(3) $e^{0jt}$ + 2(3) $e^{1jt}$ - 1(3) $e^{2jt}$

y(t) = 3 $e^{-2jt}$ + 6 $e^{-jt}$ + 6 $e^{jt}$ - 3 $e^{2jt}$

@@ Line 49: / Line 49: @@
 ===Response===
 Given that y(t) = <math>\sum_{k=-\infty}^{\infty} a_kH(j\omega_0 k) e^{j\omega_0 k}</math> from pg228 in Signals and Systems (Oppenheim & Willsky)
 Thus:
 y(t) = 1(3)<math>e^{-2jt}</math> + 2(3)<math>e^{-1jt}</math> + 0(3)<math>e^{0jt}</math> + 2(3)<math>e^{1jt}</math> - 1(3)<math>e^{2jt}</math>
-y(t) = 3<math>e^{-2jt}</math> + 6<math>e^{-1jt}</math> + 6<math>e^{1jt}</math> - 3<math>e^{2jt}</math>
+y(t) = 3<math>e^{-2jt}</math> + 6<math>e^{-jt}</math> + 6<math>e^{jt}</math> - 3<math>e^{2jt}</math>