free Video lecture
description
Transcript of free Video lecture
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
Video.edhole.com
How to use Laplace
Find differential equations that describe system
Obtain Laplace transformPerform algebra to solve for output or
variable of interestApply inverse transform to find solution
Video.edhole.com
What are Laplace transforms?
j
j
st1
0
st
dse)s(Fj2
1)}s(F{L)t(f
dte)t(f)}t(f{L)s(F
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 < 0Video.edhole.com
Evaluating F(s) = L{f(t)}
Hard Way – do the integral
0
st
0 0
t)as(stat
at
0
st
dt)tsin(e)s(F
tsin)t(f
as
1dtedtee)s(F
e)t(f
s
1)10(
s
1dte)s(F
1)t(flet
let
let
Integrate by partsVideo.edhole.com
Evaluating F(s)=L{f(t)}- Hard Way
remember vduuvudv
)tcos(v,dt)tsin(dv
dtsedu,eu stst
0
stst
0 0
st
0
stst
dt)tcos(es)1(e
dt)tcos(es)tcos(e[dt)tsin(e ]
)tsin(v,dt)tcos(dv
dtsedu,eu stst
0
stst
0
st
0
st
0
st
dt)tsin(es)0(edt)tsin(es)tsin(e[
dt)tcos(e
]
20
st
0
st2
0 0
st2st
s1
1dt)tsin(e
1dt)tsin(e)s1(
dt)tsin(es1dt)tsin(se
let
let
Substituting, we get:
It only gets worse…Video.edhole.com
Evaluating F(s) = L{f(t)}
This is the easy way ...Recognize a few different transformsSee table 2.3 on page 42 in textbookOr see handout .... Learn a few different properties Do a little math
Video.edhole.com
Table of selected Laplace Transforms
1s
1)s(F)t(u)tsin()t(f
1s
s)s(F)t(u)tcos()t(f
as
1)s(F)t(ue)t(f
s
1)s(F)t(u)t(f
2
2
at
Video.edhole.com
More transforms
1nn
s
!n)s(F)t(ut)t(f
665
2
1
s
120
s
!5)s(F)t(ut)t(f,5n
s
!1)s(F)t(tu)t(f,1n
s
1
s
!0)s(F)t(u)t(f,0n
1)s(F)t()t(f
Video.edhole.com
Note on step functions in Laplace
0
stdte)t(f)}t(f{L
0t,0)t(u
0t,1)t(u
Unit step function definition:
Used in conjunction with f(t) f(t)u(t) because of Laplace integral limits:
Video.edhole.com
Properties of Laplace Transforms
LinearityScaling in timeTime shift“frequency” or s-plane shiftMultiplication by tn
IntegrationDifferentiation
Video.edhole.com
Properties: Linearity
)s(Fc)s(Fc)}t(fc)t(fc{L 22112211 Example :
1s
1)
1s
)1s()1s((
2
1
)1s
1
1s
1(
2
1
}e{L2
1}e{L
2
1
}e2
1e
2
1{y
)}t{sinh(L
22
tt
tt
Proof :
)s(Fc)s(Fc
dte)t(fcdte)t(fc
dte)]t(fc)t(fc[
)}t(fc)t(fc{L
2211
0
st22
0
st11
st22
0
11
2211
Video.edhole.com
)a
s(F
a
1)}at(f{L
Example :
22
22
2
2
s
)s
(1
)1)s(
1(
1
)}t{sin(L
Proof :
)a
s(F
a
1
due)u(fa
1
dua
1dt,
a
ut,atu
dte)at(f
)}at(f{L
a
0
u)a
s(
0
st
let
Properties: Scaling in Time
Video.edhole.com
Properties: Time Shift
)s(Fe)}tt(u)tt(f{L 0st00
Example :
as
e
)}10t(ue{Ls10
)10t(a
Proof :
)s(Fedue)u(fe
due)u(f
tut,ttu
dte)tt(f
dte)tt(u)tt(f
)}tt(u)tt(f{L
00
0
0
0
st
0
sust
t
0
)tu(s
00
t
st0
0
st00
00
let
Video.edhole.com
Properties: S-plane (frequency) shift
)as(F)}t(fe{L at
Example :
22
at
)as(
)}tsin(e{L
Proof :
)as(F
dte)t(f
dte)t(fe
)}t(fe{L
0
t)as(
0
stat
at
Video.edhole.com
Properties: Multiplication by tn
)s(Fds
d)1()}t(ft{L
n
nnn
Example :
1n
n
nn
n
s
!n
)s
1(
ds
d)1(
)}t(ut{L
Proof :
)s(Fs
)1(dte)t(fs
)1(
dtes
)t(f)1(
dtet)t(f
dte)t(ft)}t(ft{L
n
nn
0
stn
nn
0
stn
nn
0
stn
0
stnn
Video.edhole.com
The “D” Operator
1. Differentiation shorthand
2. Integration shorthand)t(f
dt
d)t(fD
dt
)t(df)t(Df
2
22
)t(f)t(Dg
dt)t(f)t(gt
)t(fD)t(g
dt)t(f)t(g
1a
t
a
if
then then
if
Video.edhole.com
Properties: Integrals
s
)s(F)}t(fD{L 1
0
Example :
)}t{sin(L1s
1)
1s
s)(
s
1(
)}tcos(D{L
22
10
Proof :
let
stst
0
st
10
es
1v,dtedv
dt)t(fdu),t(gu
dte)t(g)}t{sin(L
)t(fD)t(g
t
0
st0
st
dt)t(f)t(g
s
)s(Fdte)t(f
s
1]e)t(g
s
1[
0
)()( dtetft st
If t=0, g(t)=0
for so
slower than
0
)()( tgdttf 0 steVideo.edhole.com
Properties: Derivatives(this is the big one)
)0(f)s(sF)}t(Df{L Example :
)}tsin({L1s
11s
)1s(s
11s
s
)0(f1s
s
)}tcos(D{L
2
2
22
2
2
2
2
Proof :
)s(sF)0(f
dte)t(fs)]t(fe[
)t(fv,dt)t(fdt
ddv
sedu,eu
dte)t(fdt
d)}t(Df{L
0
st0
st
stst
0
st
let
Video.edhole.com
Difference in
The values are only different if f(t) is not continuous @ t=0
Example of discontinuous function: u(t)
)0(f&)0(f),0(f
1)0(u)0(f
1)t(ulim)0(f
0)t(ulim)0(f
0t
0t
Video.edhole.com
?)}t(fD{L 2
)0('f)0(sF)s(Fs)0('f))0(f)s(sF(s
)0('f)}t(Df{sL)0(g)s(sG)}t(gD{L
)0('f)0(Df)0(g),t(Df)t(g
2
2
let
)0(f)0(sf)0('fs)0(fs)s(Fs)}t(fD{L )'1n()'2n()2n()1n(nn
NOTE: to takeyou need the value @ t=0 for
called initial conditions!We will use this to solve differential equations!
)t(f),t(Df),...t(fD),t(fD 2n1n
)}t(fD{L n
Properties: Nth order derivatives
Video.edhole.com
Properties: Nth order derivatives
)0(f)s(sF)}t(Df{L )}t(fD{L 2
)0(f)s(sF)}t(Df{L)}t(g{L)s(G
)0('f)0(g
)t(Df)t(g
)0(g)s(sG)}t(Dg{L
)t(fD)t(Dgand)t(Df)t(g 2
)0('f)0(sf)s(Fs)0('f)]0(f)s(sF[s)0(g)s(sG)}t(Dg{L 2
.etc),t(fD),t(fD 43
Start with
Now apply again
letthen
remember
Can repeat for
)0(f)0(sf)0('fs)0(fs)s(Fs)}t(fD{L )'1n()'2n()2n()1n(nn Video.edhole.com
Relevant Book Sections
Modeling - 2.2Linear Systems - 2.3, page 38 onlyLaplace - 2.4Transfer functions – 2.5 thru ex 2.4
Video.edhole.com