Line 11: Line 11:
 
(i)
 
(i)
 
<math>y(a(t) + b(t)) =?= y(a(t)) + y(b(t))</math>
 
<math>y(a(t) + b(t)) =?= y(a(t)) + y(b(t))</math>
 +
 
<math>e^{a(t) + b(t)} =?= e^{a(t)} + e^{b(t)}</math>
 
<math>e^{a(t) + b(t)} =?= e^{a(t)} + e^{b(t)}</math>
 +
 
<math>e^{a(t)}e^{b(t)} \ne e^{a(t)} + e^{b(t)}</math>
 
<math>e^{a(t)}e^{b(t)} \ne e^{a(t)} + e^{b(t)}</math>
  
 
and
 
and

Revision as of 17:35, 8 September 2008

Definition

A system is a linear system if (i) the output produced by first summing any two inputs and then putting the result through the system is identical to the output produced by first putting both signals through the system separately and then summing the results and (ii) the output produced by first multiplying an input signal by a constant and then putting the result through the system is identical to the output produced by first putting the original signal through the system and then multiplying the result by the constant.

Example 1: Linear System

Example 2: Non-Linear System

$ y(t) = e^{x(t)} $

(i) $ y(a(t) + b(t)) =?= y(a(t)) + y(b(t)) $

$ e^{a(t) + b(t)} =?= e^{a(t)} + e^{b(t)} $

$ e^{a(t)}e^{b(t)} \ne e^{a(t)} + e^{b(t)} $

and

Alumni Liaison

Correspondence Chess Grandmaster and Purdue Alumni

Prof. Dan Fleetwood