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One-Way
 
One-Way
 
+
<math>
 
x1(t) -> [sys] -> y1(t) = cos(t) -> (X)*a +++
 
x1(t) -> [sys] -> y1(t) = cos(t) -> (X)*a +++
 
                             =  a*cos(t)+b*sin(t) = z(t)
 
                             =  a*cos(t)+b*sin(t) = z(t)
 
x2(t) -> [sys] -> y2(t) = sin(t) -> (X)*b +++
 
x2(t) -> [sys] -> y2(t) = sin(t) -> (X)*b +++
 
+
</math>
  
 
Reverse-Way
 
Reverse-Way

Revision as of 11:20, 12 September 2008

Linearity

So a system is linear if its inputs x1(t), x2(t) or (x1[n], x2[n] for Discrete Time signals) yield outputs y1(t), y2(t) such as the response: a*x1(t)+b*x2(t) => a*y1(t)+b*y2(t).


Example: Linear

One-Way $ x1(t) -> [sys] -> y1(t) = cos(t) -> (X)*a +++ = a*cos(t)+b*sin(t) = z(t) x2(t) -> [sys] -> y2(t) = sin(t) -> (X)*b +++ $

Reverse-Way

cos(t) = x1(t)*a +++

            =   a*cos(t)+b*sin(t) -> [sys] -> w(t)= a*cos(t)+b*sin(t)

sin(t) = x2(t)*b +++


since w(t) = z(t) then the inputs are the same as the outputs which makes this a linear system.

Example: Non-Linear

One-way


y[n] = 2*x[n]^3

x1[n] -> [sys] -> y1[n]=2*x1[n]^3 -> (X)*a +++

                                 = a*2*x1[n]^3+2*b*x2[n]^3

x2[n] -> [sys] -> y2[n]=2*x2[n]^3 -> (X)*b +++

Reverse-way


x1[n] -> (X)*a +++

             = a*x1[n]+b*x2[n] -> [sys] -> 2*z[n]^3 = 2*(a*x1[n] + b*x2[n])^3

x2[n] -> (X)*b +++


However, since 2*a*x1[n]^3 + 2*b*x2[n] != 2(a*x1[n] + b*x2[n])^3 = 8*a^3*x1[n]^3 + 8*b^3*x2[n]^3 the system is not linear because the two inflexive operations are not equal to each other.

Alumni Liaison

Ph.D. 2007, working on developing cool imaging technologies for digital cameras, camera phones, and video surveillance cameras.

Buyue Zhang