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Lecture 17

Explore the natural response in RL circuits and first-order systems. Learn to derive governing equations, determine initial conditions, and sketch responses. Check your results against circuit physics for accuracy. Gain insights into time constants and practical examples to enhance understanding.

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Lecture 17

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  1. Lecture 17 Review: RC circuit natural response RL circuit natural response General first order system natural response First order circuit examples Related educational materials: Chapter 7.3

  2. RC circuit natural response – review • Governing equation: • Initial condition: • Response:

  3. RL circuit natural response – overview • No power sources • Circuit response is due to energy initially stored in the inductor • i(t=0) = I0 • Inductor’s initial energy is dissipated through resistor after switch is closed

  4. RL Circuit Natural Response • Find i(t), t>0 if the current through the inductor prior to motion of the switch is i(t=0-) = I0

  5. Derive governing first order differential equation on previous slide • Determine initial conditions; emphasize that current through inductor cannot change suddenly

  6. RL Circuit Natural Response – continued

  7. Finish derivation on previous slide • Sketch response on previous slide

  8. RL Circuit Natural Response – summary • Inductor current: • Exponential function: • Write i(t) in terms of :

  9. Notes: • L and R set time constant • Increase L => Time constant increases )more energy to dissipate) • Decreasing R => time constant increases (energy dissipates more slowly)

  10. First order system natural response – summary • RC circuit: • Solution: • Alternate form of governing equation: • RL circuit: • Solution: • Alternate form of governing equation:

  11. General first order system natural response • Governing equation: • Initial condition: • Form of solution:

  12. Checking results • Our analyses are becoming more mathematically complex • Checking your results against expectations about the circuit’s physical behavior is essential! • For first order circuits, it is often possible to determine the circuit response directly from the circuit itself • However, I recommend doing the math and using the circuit physics to double-check the math

  13. 1. Checking the time constant • Governing equation: • RC circuit time constant: • RL circuit time constant: • Note: • In the time constant expressions, the resistance is the equivalent resistance seen by the energy storage element • An outcome of Thévenin’s theorem

  14. Example 1 • Find v(t), t>0

  15. Example 1 – continued • Equivalent circuit, t>0. v(0) = 3V.

  16. Example 1 – checking results

  17. Example 2 • Find iL(t), t>0

  18. Example 2 – continued • Equivalent circuit, t>0. iL(0) = 0.33A

  19. Example 2 – checking results

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