Difference between revisions of "HW4.3 Hetong Li ECE301Fall2008mboutin" - Rhea

Latest revision as of 17:41, 26 September 2008

Suppose we have a LTI CT signal y(t)=2x(t)

i) $y(t)=2x(t)=> h(t)=2\delta(t)$

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

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

$=\int_{-\infty}^\infty 2\delta(\tau)e^{-s\tau}d\tau$

$=2e^{-s*0}$

$$ =2 $$

$$ x(t)=3cos(3t) $$

$=\frac{3}{2}[(e^{j3t})+(e^{-j3t})]$

$=\frac{3}{2}(e^{j3t})+\frac{3}{2}(e^{-j3t})$

since we have $e^{st}$ has a response of $H(s)e^{st}$

so we can get

$y(t)=\frac{3}{2}[(e^{j3t})+(e^{-j3t})]H(s)$

$=\frac{3}{2}(e^{j3t})H(j3)+\frac{3}{2}(e^{-j3t})H(-3j)$

$=3e^{j3t}+3e^{-j3t} = 6cos(3t)$

Coefficients:

we observe that the output is just double the input, so the coefficients should be doubleed,too

From Q1 we can get that when k=1, $$ a_1=3 $$ , and when k=-1, $a_{-1}=3$

others are all zero

@@ Line 8: / Line 8: @@
 ii)
 <math>H(s)=\int_{-\infty}^\infty h(\tau)e^{-j\omega\tau}d\tau</math>
-<math>\=\int_{-\infty}^\infty h(\tau)e^{-s\tau}d\tau</math>
+<math>=\int_{-\infty}^\infty h(\tau)e^{-s\tau}d\tau</math>
+<math>=\int_{-\infty}^\infty 2\delta(\tau)e^{-s\tau}d\tau</math>
+<math>=2e^{-s*0}</math>
+<math>=2</math>
+==Response of the Signal and Fourier Series Coefficients==
+<math>x(t)=3cos(3t)</math>
+<math>=\frac{3}{2}[(e^{j3t})+(e^{-j3t})]</math>
+<math>=\frac{3}{2}(e^{j3t})+\frac{3}{2}(e^{-j3t})</math>
+since we have <math>e^{st}</math> has a response of <math>H(s)e^{st}</math>
+so we can get
+<math>y(t)=\frac{3}{2}[(e^{j3t})+(e^{-j3t})]H(s)</math>
+<math>=\frac{3}{2}(e^{j3t})H(j3)+\frac{3}{2}(e^{-j3t})H(-3j)</math>
+<math>=3e^{j3t}+3e^{-j3t} = 6cos(3t)</math>
+Coefficients:
+we observe that the output is just double the input,
+so the coefficients should be doubleed,too
+From Q1 we can get that when k=1, <math>a_1=3</math>, and when k=-1,<math>a_{-1}=3</math>
+others are all zero