3. Introductory Video: Simple Harmonic Motion Simple Harmonic Motion

4. Objectives  Know the requirements for simple harmonic motion (SHM).  Know the terms equilibrium position, displacement, amplitude, period, and frequency. Be able to determine the values for these terms from a graph.  Calculate elastic potential energy from displacement and spring constant.  Calculate kinetic energy and velocity of an oscillating object using conservation of mechanical energy.

5. Objectives  Understand the relationship between the unit circle and SHM and how the two of them relate to the sinusoidal nature of SHM.  Know the meaning of angular velocity (ω) and how to compute it.  Use angular velocity and amplitude to compute position, velocity, and acceleration.

6. Oscillation vs. Simple Harmonic Motion  An oscillation is any motion in which the displacement of a particle from a fixed point keeps changing direction and there is a periodicity in the motion i.e. the motion repeats in some way.  In simple harmonic motion, the displacement from an equilibrium position and the force/acceleration are proportional and opposite to each other.

7. Simple Harmonic Motion: Spring

8. Definitions  Understand the terms displacement, amplitude and period  displacement (x) – distance from the equilibrium or zero point  amplitude (A) – maximum displacement from the equilibrium or zero point  period (T) – time it takes to complete one oscillation and return to starting point

9. Definitions

10.  Understand the terms period and frequency  frequency (f) – How many oscillations are completed in one second, equal to the inverse of the period  period (T) – Time for one complete oscillation

11. Simple Harmonic Motion  In simple harmonic motion, the displacement from an equilibrium position and the force/acceleration are proportional and opposite to each other.

12. Simple Harmonic Motion: Spring  The spring possesses an intrinsic restoring force that attempts to bring the object back to equilibrium:  This is Hooke’s Law  k is the spring constant (kg/s 2 )  The negative sign is because the force acts in the direction opposite to the displacement -- restoring force

13. Simple Harmonic Motion: Spring  Meanwhile, the inertia of the mass executes a force opposing the spring, F=ma:  spring executing force on mass  mass executing force on spring

14. Simple Harmonic Motion: Spring  Elastic Potential Energy:  Kinetic Energy:

15. Simple Harmonic Motion: Spring  Conservation of Energy:

16. Simple Harmonic Motion  Understand that in simple harmonic motion there is continuous transformation of energy from kinetic energy into elastic potential energy and vice versa

17. Simple Harmonic Motion: Spring

18. no displ, no energy, no accl max displ, max PE, max accl, zero KE half max displ, half max PE, half max accl, half max KE zero displ, zero PE, zero accl, max KE max displ, max PE, max accl, zero KE

19. Simple Harmonic Motion: Spring  These forces remain in balance throughout the motion:  The relationship between acceleration and displacement is thus,

20. Simple Harmonic Motion: Spring  Satisfies the requirement for SHM that displacement from an equilibrium position and the force/acceleration are proportional and opposite to each other

21. Relating SHM to Motion Around A Circle

22. Velocity

23. Period

25. Frequency

26. Radians  One radian is defined as the angle subtended by an arc whose length is equal to the radius

27. Radians

28. Angular Velocity

29. Position

30. Velocity

31. Acceleration

32. Relating SHM to Motion Around A Circle  These equations yield the following graphs

33. Relating SHM to Motion Around A Circle  These equations yield the following graphs

34. Relating SHM to Motion Around A Circle  These equations yield the following graphs

35. Relating SHM to Motion Around A Circle  These equations yield the following graphs

36. Relating SHM to Motion Around A Circle  These equations yield the following graphs

37. Relating cos to sin

38. Definitions  Understand the terms displacement, amplitude and period  displacement (x) – distance from the equilibrium or zero point  amplitude (A) – maximum displacement from the equilibrium or zero point  period (T) – time it takes to complete one oscillation and return to starting point

39. Definitions

40. Objectives  Know the requirements for simple harmonic motion (SHM).  Know the terms equilibrium position, displacement, amplitude, period, and frequency. Be able to determine the values for these terms from a graph.  Calculate elastic potential energy from displacement and spring constant.  Calculate kinetic energy and velocity of an oscillating object using conservation of mechanical energy.

41. Objectives  Understand the relationship between the unit circle and SHM and how the two of them relate to the sinusoidal nature of SHM.  Know the meaning of angular velocity (ω) and how to compute it.  Use the relationship between the unit circle and SHM to compute position, velocity, and acceleration.

43. #1 - 12 Homework