(New page: A system has the characteristics such that the input x(t) = exp(2jt) yields the output y(t) = exp(-2jt) and the input x(t) = exp(-2jt) yields the output y(t) = exp(2jt). What, then, is the...)
 
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A system has the characteristics such that the input x(t) = exp(2jt) yields the output y(t) = exp(-2jt) and the input x(t) = exp(-2jt) yields the output y(t) = exp(2jt). What, then, is the system's output for the input signal x(t) = cos(2t)?
 
A system has the characteristics such that the input x(t) = exp(2jt) yields the output y(t) = exp(-2jt) and the input x(t) = exp(-2jt) yields the output y(t) = exp(2jt). What, then, is the system's output for the input signal x(t) = cos(2t)?
  
Well, we know that exp(2jt) = cos(2t) + jsin(2t) and exp(-2jt) = cos(2t) - jsin(2t) according to Euler's Formula.
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Well, it appears that the system produces the inverse of the input to provide the output signal, effectively dividing one by whatever the input signal is. If this is the case, then the input x(t) = cos(2t) will result in the output signal y(t) = 1/(cos(2t)). Also, we know that exp(2jt) = cos(2t) + jsin(2t) and exp(-2jt) = cos(2t) - jsin(2t) according to Euler's Formula.

Revision as of 08:22, 18 September 2008

A system has the characteristics such that the input x(t) = exp(2jt) yields the output y(t) = exp(-2jt) and the input x(t) = exp(-2jt) yields the output y(t) = exp(2jt). What, then, is the system's output for the input signal x(t) = cos(2t)?

Well, it appears that the system produces the inverse of the input to provide the output signal, effectively dividing one by whatever the input signal is. If this is the case, then the input x(t) = cos(2t) will result in the output signal y(t) = 1/(cos(2t)). Also, we know that exp(2jt) = cos(2t) + jsin(2t) and exp(-2jt) = cos(2t) - jsin(2t) according to Euler's Formula.

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Abstract algebra continues the conceptual developments of linear algebra, on an even grander scale.

Dr. Paul Garrett