(New page: =Linear Systems= A linear system is defined as a system that if two inputs were placed in parallel into a system and then summed yields the same result as adding two inputs together and th...) |
|||
Line 22: | Line 22: | ||
<math>x(t) + w(t) -> SYSTEM -> y(t)+z(t) \ </math> | <math>x(t) + w(t) -> SYSTEM -> y(t)+z(t) \ </math> | ||
− | If <math>x(t) = t \ </math> and <math>w(t) = t^2 \ </math>, and the SYSTEM multiplies any input | + | If <math>x(t) = t \ </math> and <math>w(t) = t^2 \ </math>, and the SYSTEM multiplies any input multiplies by 3, then the result <math>y(t)+z(t) \ </math> would equal <math>3x(t)+3w(t) \ </math> for both parallel, system-passed and then summed as well as summed then system-passed methods. |
=Example of Nonlinear System= | =Example of Nonlinear System= |
Revision as of 08:54, 12 September 2008
Linear Systems
A linear system is defined as a system that if two inputs were placed in parallel into a system and then summed yields the same result as adding two inputs together and then placed into that system.
In another form, it may be translated as:
Parallel: A -> SYSTEM -> C B -> SYSTEM -> D
where the resulting sum is C+D.
Sum: A+B -> SYSTEM -> C+D.
Example of Linear System
$ x(t) -> SYSTEM -> y(t) \ $
$ w(t) -> SYSTEM -> z(t) \ $
with sum equaling $ y(t)+z(t) \ $
$ x(t) + w(t) -> SYSTEM -> y(t)+z(t) \ $
If $ x(t) = t \ $ and $ w(t) = t^2 \ $, and the SYSTEM multiplies any input multiplies by 3, then the result $ y(t)+z(t) \ $ would equal $ 3x(t)+3w(t) \ $ for both parallel, system-passed and then summed as well as summed then system-passed methods.