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Lecture 11 First-order Circuits (1)

Lecture 11 First-order Circuits (1). Hung-yi Lee. Dynamic Circuits. Capacitor, Inductor. (Chapter 5). Time Domain. Frequency Domain. S-Domain. (Chapter 9). (Chapter 6,7). (Chapter 11,13). Abstract. Textbook. First-Order Circuits Chapter 5.3, 9.1. First-Order Circuits.

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Lecture 11 First-order Circuits (1)

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  1. Lecture 11First-order Circuits (1) Hung-yi Lee

  2. Dynamic Circuits Capacitor, Inductor (Chapter 5) Time Domain Frequency Domain S-Domain (Chapter 9) (Chapter 6,7) (Chapter 11,13) Abstract

  3. Textbook • First-Order Circuits • Chapter 5.3, 9.1

  4. First-Order Circuits • Containing only one capacitor or inductor The networks excluding capacitor or inductor only contains sources and resistors. Can always be simplified by Thevenin or Norton Theorem

  5. First-Order Circuits RC: RL:

  6. First Order Circuits (this lecture) voc and isc should be dynamic … … … … …

  7. Unit Step Function

  8. Perspective • Differential Equation • Superposition • State

  9. Perspective 1:Differential Equation

  10. Zero-Input Response- RC

  11. Zero-Input Response - RC Find vc(t) and ic(t) Capacitor is open circuit

  12. Zero-Input Response - RC Find vc(t) and ic(t) Capacitor is open circuit

  13. Zero-Input Response - RC Find vc(t) and ic(t) ? ?

  14. Zero-Input Response - RC ic(t0) is unknown Voltage on the capacitor should be continuous

  15. Zero-Input Response - RC ic(t0) is unknown Assume

  16. Zero-Input Response - RC

  17. Zero-Input Response - RC

  18. Zero-Input Response - RC

  19. Zero-Input Response - RL

  20. Zero-Input Response - RL

  21. Zero-Input Response … Voltage, Current Voltage of C, Current of L How fast?

  22. Step Response - RC

  23. Step Response - RC • Solved by differential equation

  24. Step Response - RC vN(t) is general solution vF(t) is special solution vN(t) is the solution of vF(t) is the solution of

  25. Step Response - RC

  26. Step Response … Voltage, Current Voltage of C, Current of L How fast?

  27. Step Response

  28. Step Response … Rise time 90% time 10% time

  29. Step Response + Initial Condition

  30. Step Response - RC

  31. Perspective 2:Superposition

  32. Step Response • Solved by Superposition

  33. Step Response … … = … … Suppress v1, find vc2(t) - Suppress v2, find vc1(t)

  34. Step Response

  35. Pulse Response Solved by Superposition

  36. Pulse Response = … - …

  37. Pulse Response

  38. Pulse Response (If x is small) If

  39. Step Response + Initial Condition Violate Superposition?

  40. Step Response + Initial Condition The initial condition is automatically fulfilled. Do not have to consider the initial condition anymore

  41. Step Response + Initial Condition Zero-Input Response! Step Response (without initial condition)!

  42. Step Response + Initial Condition Differential Equation Superposition Zero-input Response Special solution General solution Step Response The initial condition is considered in the general solution term. The initial condition is automatically fulfilled.

  43. Perspective 3:State

  44. State • The capacitor voltages and inductor currents constitute the state variables of any circuit. (P410) If the circuit does not have any capacitor or inductor The currents or voltages at time t do not depend on their values not at t. Why?

  45. State • The capacitor voltages and inductor currents constitute the state variables of any circuit. (P410) With capacitor or inductor You can not explain the current or voltage at present unless considering the past.

  46. State • The capacitor voltages and inductor currents constitute the state variables of any circuit. (P410) …… If we know the voltage before at t0 We do not care about the current before t0 Capacitor voltages are States

  47. State • The capacitor voltages and inductor currents constitute the state variables of any circuit. (P410) State at t0 Source after t0

  48. State • The capacitor voltages and inductor currents constitute the state variables of any circuit. (P410) The response after t0 From Input after t0 (Ignore state) From state at t0 (Ignore input)

  49. Response y(t): voltage of capacitor or current of inductor y(t) = general solution + special solution = = = natural response +forced response = state response (zero input) + inputresponse (zero state)

  50. Zero-InputResponse … Ignore everything before t0 Considering the circuit from t0: State: vc(t0)=V0 Lead to No input after t0

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