Ch. 3: Forced Vibration of 1-dof system

Ch. 3: Forced Vibration of 1-DOF System

3.4 Periodic Excitation

(

)

(

)

( )

( )

( )

( )

0

0

2

1

1

2

1

2

2

0

0

FBD and assume 

   

,    

,    

2

Write 

 in the Fourier series expansion

2

,    

,    

,   0

1

1

x

x

n

n

in

t

n

n

T

in

t

n

y

x

F

ma

mx

k

y

x

k x cx

k

k

c

mx cx

k

k

x

k y

m

m

y t

A

y t

C e

y t

B

t

t

T

T

T

C

y t e

dt

Be

T

T

ω

ω

ω

ζ

ω

π

ω

∞

=−∞

−

−

>

⎡

⎤

=

=

−

−

−

⎣

⎦

+

+

+

+

=

=

=

=

=

= +

≤ ≤

=

=

∑

∑

∫

(

)

0

0

0

0

2

2

2

2

2

0

0

0

1

Integration formula:  

  and  

1

2

1

,  

0

2

2

2

2

T

T

in

t

in

t

ax

ax

ax

ax

T

T

in

t

in

t

T

T

n

A

dt

te

dt

T

T

e

e

e dx

c

xe dx

ax

c

a

a

B

e

A

e

iA

C

in

t

n

T

T

T

n

in

in

T

T

A

C

B

ω

ω

π

π

π

π

π

π

−

−

−

+

=

+

=

− +

⎡

⎤

⎡

⎤

⎢

⎥

⎢

⎥

⎛

⎞

⎢

⎥

=

+

−

−

=

≠

⎢

⎥

⎜

⎟

⎢

⎥

⎝

⎠

⎛

⎞

⎢

⎥

−

−

⎢

⎥

⎜

⎟

⎣

⎦

⎝

⎠

⎣

⎦

= +

∫

∫

∫

∫

Ch. 3: Forced Vibration of 1-DOF System

3.4 Periodic Excitation

( )

(

)

( )

( )

(

)

( )

(

)

(

)

0

0

1

0

1

2

1

2

2

0

0

1

2

2

2

0

0

1

2

2 Re

cos

sin

2

2

1

sin

2

1

Frequency response  

1

2

1

1

2

1

1

2

n

n

n

n

n

n

n

n

n

A

iA

y t

B

n

t

i

n

t

n

A

A

y t

B

n

t

n

H

i

k

k

r

i

r

H

i

n

n

k

k

i

H

n

n

k

k

ω

ω

π

ω

π

ω

ζ

ω

ω

ω

ζ

ω

ω

ω

ω

ζ

ω

ω

∞

=

∞

=

⎡

⎤

∴

= + +

+

⎢

⎥

⎣

⎦

= + −

=

⎡

⎤

+

− +

⎣

⎦

=

⎡

⎤

⎛

⎞

⎛

⎞

⎢

⎥

+

−

+

⎜

⎟

⎜

⎟

⎢

⎥

⎝

⎠

⎝

⎠

⎣

⎦

=

⎛

⎞

⎛

⎞

⎜

⎟

+

−

+

⎜

⎟

⎜

⎟

⎝

⎠

⎝

⎠

∑

∑

( )

(

)

0

1

2

2

0

2

2

0

1

1

2

2

,    

tan

1

1

sin

2

n

n

n

ss

n

n

n

n

H

n

k

k A

A

x

t

B

H

n

t

H

k

k

n

ω

ζ

ω

ω

ω

ω

π

−

∞

=

⎛

⎞

−

⎜

⎟

⎝

⎠

=

⎛

⎞

⎛

⎞

⎛

⎞

− ⎜

⎟

⎜

⎟

⎜

⎟

⎝

⎠

⎝

⎠

⎝

⎠

⎛

⎞

=

+

−

+

⎜

⎟

+

⎝

⎠

∑

Ch. 3: Forced Vibration of 1-DOF System

3.4 Periodic Excitation

Ch. 3: Forced Vibration of 1-DOF System

3.4 Periodic Excitation

Ch. 3: Forced Vibration of 1-DOF System

3.4 Periodic Excitation

Ch. 3: Forced Vibration of 1-DOF System

3.4 Periodic Excitation

Ch. 3: Forced Vibration of 1-DOF System

3.4 Periodic Excitation

Ch. 3: Forced Vibration of 1-DOF System

3.4 Periodic Excitation

Ch. 3: Forced Vibration of 1-DOF System

3.4 Periodic Excitation

Ch. 3: Forced Vibration of 1-DOF System

3.4 Periodic Excitation

Ch. 3: Forced Vibration of 1-DOF System

3.4 Periodic Excitation

Ch. 3: Forced Vibration of 1-DOF System

3.5 

Non-periodic Excitation

Harmonic and steady-state excitation and response are 

conveniently described in the frequency domain.  For

deterministic non-periodic excitation and response, time

domain technique is more suitable.

We cannot find the repeated pattern that lasts forever 

(both in the past & future) for the non-periodic excitation.

System response to the unit impulse, called the impulse 

response, will be first studied.  Then, this fundamental

response will be used to synthesize the response of the

LTI system to arbitrary excitation.

3.5 Non-periodic Excitation

Ch. 3: Forced Vibration of 1-DOF System

3.5 Non-periodic Excitation

Ch. 3: Forced Vibration of 1-DOF System

Impulse

The unit impulse, or Dirac delta function, is defined as

This means that the unit impulse is zero everywhere

except in the neighborhood of  t=a.  Since the area

under the graph δ-t  is  1,  the  value  of                        is  very 

large in the vicinity of t=a.

The impulse of magnitude    , which may represent a

large force acting over a short period, can be written as

3.5 Non-periodic Excitation

(

)

(

)

0  for 

1

t

a

t

a

t

a dt

δ

δ

∞

−∞

−

=

≠

−

=

∫

(

)

t

a

δ

−

ˆ

F

( )

(

)

ˆ

F t

F

t

a

δ

=

−

Ch. 3: Forced Vibration of 1-DOF System

3.5 Non-periodic Excitation

Ch. 3: Forced Vibration of 1-DOF System

The unit impulse has a useful property called the

“sampling property”.  Multiplying a continuous function 

by                , and integrating w.r.t. time:

which is just the value of f(t) at t=a.  This is a way in

evaluating integrals involving with impulse.

3.5 Non-periodic Excitation

( )

f t

(

)

t

a

δ

−

( ) (

)

( ) (

)

( )

f t

t

a dt

f a

t

a dt

f a

δ

δ

∞

∞

−∞

−∞

−

=

−

=

∫

∫

Ch. 3: Forced Vibration of 1-DOF System

Impulse response

The impulse response, h(t), is the response to the unit

impulse, δ(t), applied at t=0 with zero initial conditions.

The impulse response is very important since it contains 

all the system characteristics and can be used to find

the response to arbitrary excitation of LTI system via the 

convolution integral theorem.

The impulse response of a 1 DOF MBK system must

satisfy

subject to i.c.

3.5 Non-periodic Excitation

( )

( )

( )

( )

mh t

ch t

kh t

t

δ

+

+

=

( )

( )

0

0,  

0

0

h

h

=

=

Ch. 3: Forced Vibration of 1-DOF System

3.5 Non-periodic Excitation

( )

(

)

( )

0

0

0

Get rid of the impulse function by

integrating over the duration  0,

 of the impulse

1

Take limit as 

0 and apply the i.c.

to evaluate the integral on the left hand side:

lim

mh

ch

kh dt

t dt

m

ε

ε

ε

ε

δ

ε

→

+

+

=

=

→

∫

∫

( )

( )

( )

( )

( )

( )

( )

( )

( )

( )

( )

( )

0

0

0

0

0

0

0

0

0

0

0

lim

0

0,  assuming 

 is not continuous

lim

lim

0

0,  assuming 

 is continuous

lim

lim

0

0,  assuming 

 is continuous

0

1

h t dt

mh t

mh

h t

ch t dt

ch t

ch

h t

kh t dt

gh

t

h t

mh

ε

ε

ε

ε

ε

ε

ε

ε

ε

ε

ε

+

→

+

→

→

→

→

+

=

=

≠

=

=

=

=

=

∴

=

∫

∫

∫

Ch. 3: Forced Vibration of 1-DOF System

Therefore, the effect of a unit impulse at t=0 is to

produce equivalent initial velocity (impulse-momentum)

Now, we are ready to find the impulse response.  The

equivalent system is a homogeneous system with i.c.

If the system is underdamped, the impulse response is

Note that the above i.c. is not the actual i.c.

3.5 Non-periodic Excitation

( )

0

1 /

h

m

+

=

( )

( )

0

0,  

0

1 /

h

h

m

=

=

( )

1

sin

,  0

0,  0

n

t

d

d

e

t t

m

h t

t

ζω

ω

ω

−

⎧

≥

⎪

= ⎨

⎪

<

⎩

Ch. 3: Forced Vibration of 1-DOF System

3.5 Non-periodic Excitation

Impulse response of underdamped system

Ch. 3: Forced Vibration of 1-DOF System

( )

x t

Linear Time Invariant (LTI) system has the characteristic 

that the shape of the response will not be influenced by

the time the input is applied to the system.  That is

3.5 Non-periodic Excitation

LTI system

( )

f t

LTI system

(

)

f t

a

−

(

)

x t

a

−

Hence if the impulse is applied at t=t

o

, the response is

( )

(

)

(

)

0

0

0

0

1

sin

,  

0,  

n

t t

d

d

e

t

t

t

t

m

h t

t

t

ζω

ω

ω

−

−

⎧

−

≥

⎪

= ⎨

⎪

<

⎩

Ch. 3: Forced Vibration of 1-DOF System

Total response of underdamped MBK with i.c. x(a)=x

0

and v(a)=v

0 

subject to the impulse force                 

3.5 Non-periodic Excitation

(

)

ˆ

F

t

a

δ

−

( )

(

)

(

)

(

)

(

)

(

)

(

)

(

)

(

)

(

)

( )

(

)

(

)

(

)

1

2

1

2

1

2

ˆ

      

sin

cos

sin

ˆ

      

sin

cos

,   

ˆ

sin

cos

          

n

n

n

n

h

p

t a

t a

d

d

d

d

t a

d

d

d

t a

n

d

d

d

x t

x

x

F

e

A

t

a

A

t

a

e

t

a

m

F

e

A

t

a

A

t

a

t

a

m

F

x t

e

A

t

a

A

t

a

m

ζω

ζω

ζω

ζω

ω

ω

ω

ω

ω

ω

ω

ζω

ω

ω

ω

−

−

−

−

−

−

−

−

=

+

=

−

+

−

+

−

⎧

⎫

⎛

⎞

⎪

⎪

=

+

−

+

−

≥

⎜

⎟

⎨

⎬

⎪

⎪

⎝

⎠

⎩

⎭

⎧

⎫

⎛

⎞

⎪

⎪

= −

+

−

+

−

⎜

⎟

⎨

⎬

⎪

⎪

⎝

⎠

⎩

⎭

+

(

)

(

)

(

)

1

2

ˆ

cos

sin

n

t a

d

d

d

d

d

F

e

A

t

a

A

t

a

m

ζω

ω

ω

ω

ω

ω

−

−

⎧

⎫

⎛

⎞

⎪

⎪

+

−

−

−

⎜

⎟

⎨

⎬

⎪

⎪

⎝

⎠

⎩

⎭

Ch. 3: Forced Vibration of 1-DOF System

Total response of underdamped MBK with i.c. x(a)=x

0

and v(a)=v

0 

subject to the impulse force                 

3.5 Non-periodic Excitation

(

)

ˆ

F

t

a

δ

−

( )

( )

( )

(

)

(

)

(

)

(

)

0

0

1

2

0

2

0

2

1

2

0

1

0

0

0

0

0

Apply i.c. 

 and 

 to solve for   and 

:

ˆ

ˆ

1

  and  

1

sin

cos

,   

n

n

d

d

n

d

t a

n

d

d

d

x a

x

x a

v

A

A

x

A

F

v

A

A

m

F

A

x

A

x

v

m

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