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Lecture 22 Second order system natural response

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1 Lecture 22 Second order system natural response
Review Mathematical form of solutions Qualitative interpretation Second order system step response Related educational materials: Chapter 8.4

2 Second order input-output equations
Governing equation for a second order unforced system: Where  is the damping ratio (  0) n is the natural frequency (n  0)

3 Homogeneous solution – continued
Solution is of the form: With two initial conditions: ,

4 Damping ratio and natural frequency
System is often classified by its damping ratio, :  > 1  System is overdamped (the response has two time constants, may decay slowly if  is large)  = 1  System is critically damped (the response has a single time constant; decays “faster” than any overdamped response)  < 1  System is underdamped (the response oscillates) Underdamped system responses oscillate

5 Overdamped system natural response
>1: We are more interested in qualitative behavior than mathematical expression

6 Overdamped system – qualitative response
The response contains two decaying exponentials with different time constants For high , the response decays very slowly As  increases, the response dies out more rapidly

7 Critically damped system natural response
=1: System has only a single time constant Response dies out more rapidly than any over-damped system

8 Underdamped system natural response
<1: Note: solution contains sinusoids with frequency d

9 Underdamped system – qualitative response
The response contains exponentially decaying sinusoids Decreasing  increases the amount of overshoot in the solution

10 Example For the circuit shown, find: The equation governing vc(t)
n, d, and  if L=1H, R=200, and C=1F Whether the system is under, over, or critically damped R to make  = 1 Initial conditions if vc(0-)=1V and iL(0-)=0.01A

11 Part 1: find the equation governing vc(t)

12 Part 2: find n, d, and  if L=1H, R=200 and C=1F

13 Part 3: Is the system under-, over-, or critically damped?
In part 2, we found that  = 0.2

14 Part 4: Find R to make the system critically damped

15 Part 5: Initial conditions if vc(0-)=1V and iL(0-)=0.01A

16 Simulated Response

17

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