(New page: == Formal Definition for a Stable System== A system is stable if for all input functions x(t) there exists an output y(t) where y(t) is less than a constant M (Bounded inputs yield bounded...)
 
 
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== Formal Definition for a Stable System==
 
== Formal Definition for a Stable System==
A system is stable if for all input functions x(t) there exists an output y(t) where y(t) is less than a constant M (Bounded inputs yield bounded outputs, system does not approach infinity)
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A system is stable if for all bounded input functions x(t)(system approaches +/- infinity) there exists an output y(t) where y(t) is less than a constant M (Bounded inputs yield bounded outputs, system does not approach infinity)
 
== Formal Definition for a Non-Stable System==
 
== Formal Definition for a Non-Stable System==
A system is not stable if there always exists an input x(t) such that the absolute value of the output y(t) is greater than any y(t) calculated thus far.(system approaches +/- infinity)
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A system is not stable if there always exists an bounded input x(t) such that the absolute value of the output y(t) is greater than any y(t) calculated thus far.

Latest revision as of 12:51, 19 September 2008

Formal Definition for a Stable System

A system is stable if for all bounded input functions x(t)(system approaches +/- infinity) there exists an output y(t) where y(t) is less than a constant M (Bounded inputs yield bounded outputs, system does not approach infinity)

Formal Definition for a Non-Stable System

A system is not stable if there always exists an bounded input x(t) such that the absolute value of the output y(t) is greater than any y(t) calculated thus far.

Alumni Liaison

Ph.D. on Applied Mathematics in Aug 2007. Involved on applications of image super-resolution to electron microscopy

Francisco Blanco-Silva