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input output equations - 6.9

6.3.2 Integrating Input-Output Equations

An input-output equation is already in a form suitable for normal integration techniques, with the left hand side being the homogeneous part, and the right hand side is the particular part. If the non homogeneous part includes derivatives, these determine the values of initial conditions. An example of explicitly solving such an equation is shown in Figure 6.10 and Figure 6.11.

The solution begins by evaluating the homogeneous equation.

	·· ·	·


	x + 3x + 2x = 4F + 5F
	x + 3x + 2x = 4F + 5F

The solution begins by evaluating the homogeneous equation as normal.

··	·
··	·
x + 3x + 2x		= 0
x + 3x + 2x		= 0
A2 + 3A + 2 = 0



	–3±	32 – 4( 2)	= –1, –2
	–3±	32 – 4( 2)
A =	------------------------------------
		2
		2

xh = C1e–t + C2e–2t

The particular solution can also be found as normal, assuming F is unit step function.

Guess,	x = A	·	··
		·	··
		x = 0	x = 0
0 + 3( 0) + 2A = 2( 0) + 5( 1)				5


			A =	2--
			A =

The derivative in the non-homogeneous solution must now be used to find the initial con-

ditions. However the initial position and velocity are known to be zero.

----

+ 3

----

+ 2x

----F

+ 5F

for a step function

( 0)

+ 2( 0)

+ 5( 0)

----

+ 3

----

u( t)

----

= dt

----

----x0

Note: This will be used as an initial condition

Figure 6.10 Integrating an input-output equation

input output equations - 6.10

The initial conditions can then be used to find the values of the coefficients. It will be assumed that the system starts undeflected and at rest.

x( t)

–t

–2t

= C1e

+ C2e

2--

x( 0)

–0

= C1e

+ C2e

2-- = 0

–t

–2t

x( t)

= –C1e

– 2C2e

x( 0) = –C1 – 2C2

= 4

– – C2

–

2-- – 2C2

= 4

The final equation can then be written.

x( t)

–t

–2t

= – e

–

2--e

2--

5 C1 = – C2 – --2

3 C2 = –--2

3 5

C1 = – –--2 – --2 = –1

Figure 6.11 Integrating an input-output equation (cont’d)

The example in Figure 6.10 is reconsidered with a sinusoidal input in Figure 6.12. In this case the initial acceleration is found to be non-zero. In practical terms, this can be ignored because only the initial position and velocity will be used to find the coefficients.

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