Difference between revisions of "HW2.D Josh Long ECE301Fall2008mboutin" - Rhea

Latest revision as of 14:17, 12 September 2008

Time invariance is where the output is not effected by time. As the book puts it the behavior and characteristics of the system are fixed over time.

$$ Y(t) = x(t - 1) $$

$$ S_1 = Y(t) = x(t - 1) $$

$$ S_2 = Y(t) = x(t - t_o) $$

$$ x(t) -> S1 -> S2 -> x(t - t_o - 1) $$

$$ x(t) -> S2 -> S1 -> x(t - t_o - 1) $$

$$ x(t - t_o - 1) = x(t - t_o - 1) $$

Since they are equal it is time invariant.

(Time variant problem was taken from the in class "exercise" section I posted)

$$ Y(t) = x(t - 1) - x(1 - t) $$

$$ S_1 = Y(t) = x(t - 1) - x(1 - t) $$

$$ S_2 = Y(t) = x(t - t_o) $$

$$ x(t) -> S1 -> S2 -> x(t - t_o - 1) - x(1 - t + t_o) $$

$$ x(t) -> S2 -> S1 -> x(t - t_o - 1) - x(1 - t - t_o) $$

$$ x(t - t_o - 1) - x(1 - t + t_o) =/= x(t - t_o - 1) - x(1 - t - t_o) $$

Since they are not equal it is time variant.

@@ Line 3: / Line 3: @@
 == Time Invariant Problem ==
+<math>Y(t) = x(t - 1)</math>
+<math>S_1 = Y(t) = x(t - 1)</math>
+<math>S_2 = Y(t) = x(t - t_o)</math>
+<math>x(t) -> S1 -> S2 -> x(t - t_o - 1)</math>
+<math>x(t) -> S2 -> S1 -> x(t - t_o - 1)</math>
+<math> x(t - t_o - 1) = x(t - t_o - 1)</math>
+Since they are equal it is time invariant.
 == Time Variant Problem ==
 (Time variant problem was taken from the in class "exercise" section I posted)
+<math>Y(t) = x(t - 1) - x(1 - t)</math>
+<math>S_1 = Y(t) = x(t - 1) - x(1 - t)</math>
+<math>S_2 = Y(t) = x(t - t_o)</math>
+<math>x(t) -> S1 -> S2 -> x(t - t_o - 1) - x(1 - t + t_o)</math>
+<math>x(t) -> S2 -> S1 -> x(t - t_o - 1) - x(1 - t - t_o)</math>
+<math> x(t - t_o - 1) - x(1 - t + t_o) =/= x(t - t_o - 1) - x(1 - t - t_o)</math>
+Since they are not equal it is time variant.