B.Sc. II Year Mr. Shrimangale G.W.

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Presentation transcript:

B.Sc. II Year Mr. Shrimangale G.W. Laplace Transform B.Sc. II Year Mr. Shrimangale G.W.

Why use Laplace Transforms? Find solution to differential equation using algebra Relationship to Fourier Transform allows easy way to characterize systems No need for convolution of input and differential equation solution Useful with multiple processes in system

How to use Laplace Find differential equations that describe system Obtain Laplace transform Perform algebra to solve for output or variable of interest Apply inverse transform to find solution

What are Laplace transforms? t is real, s is complex! Inverse requires complex analysis to solve Note “transform”: f(t)  F(s), where t is integrated and s is variable Conversely F(s)  f(t), t is variable and s is integrated Assumes f(t) = 0 for all t < 0

Evaluating F(s) = L{f(t)} Hard Way – do the integral let let let Integrate by parts

Evaluating F(s)=L{f(t)}- Hard Way remember let Substituting, we get: let It only gets worse…

Evaluating F(s) = L{f(t)} This is the easy way ... Recognize a few different transforms See table 2.3 on page 42 in textbook Or see handout .... Learn a few different properties Do a little math

Table of selected Laplace Transforms

More transforms

Note on step functions in Laplace Unit step function definition: Used in conjunction with f(t)  f(t)u(t) because of Laplace integral limits:

Properties of Laplace Transforms Linearity Scaling in time Time shift “frequency” or s-plane shift Multiplication by tn Integration Differentiation

Properties: Linearity Example : Proof :

Properties: Scaling in Time Example : Proof : let

Properties: Time Shift Example : Proof : let

Properties: S-plane (frequency) shift Example : Proof :

Properties: Multiplication by tn Example : Proof :

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