1. Simple Harmonic Motion Lecturer: Professor Stephen T. Thornton

2. Reading Quiz Which one of the following does not represent simple harmonic motion?
Distribution of student exam grades.
Automobile car springs.
Loudspeaker cone.
A mass oscillating at the end of a spring.

3. Answer: A

4. Last Time Bernoulli equation/principle
Applications of Bernoulli principle
Read remaining sections of Chapter.

5. Oscillations Simple harmonic motion Periodic motion Springs Energy
Today
Oscillations
Simple harmonic motion
Periodic motion
Springs
Energy

6. Oscillations Do demos Cone inside loudspeaker Car coil springs
Figure Caption: Photo of a car’s spring. (Also visible is the shock absorber, in blue—see Section 14–7.)
Solution: a. k = F/x = 6.5 x 104 N/m.
b. x = F/k = 4.5 cm
Cone inside loudspeaker
Car coil springs

7. Oscillations of a Spring
If an object vibrates or oscillates back and forth over the same path, each cycle taking the same amount of time, the motion is called periodic. The mass and spring system is a useful model for a periodic system.
Figure Caption: A mass oscillating at the end of a uniform spring.

8. Oscillations of a Spring
Displacement is measured from the equilibrium point.
Amplitude A is the maximum displacement.
A cycle is a full to-and-fro motion.
Period is the time required to complete one cycle.
Frequency is the number of cycles completed per second.
Figure Caption: Force on, and velocity of, a mass at different positions of its oscillation cycle on a frictionless surface.

9. Oscillations, simple harmonic motion, periodic motion
Start with periodic motion:
T = period of one cycle of periodic motion
f = 1/T = frequency of motion
unit of period: second
unit of frequency: 1 cycle/s = 1 Hz (hertz)

10. Displaying Position Versus Time for Simple Harmonic Motion
Chart paper moving up
pen

11. Simple Harmonic Motion as a Sine or a Cosine

12. Simple harmonic motion
We can describe this motion mathematically quite easily:
We obtain same result for time t and t + T. Look at previous slide.
Math gives same result:

13. t = 0
t = 0

14. Simple Harmonic Motion
Any vibrating system where the restoring force is proportional to the negative of the displacement is in simple harmonic motion (SHM), and is often called a simple harmonic oscillator (SHO).
F = ma = - kx Newton’s second law:
with solutions of the form:

15. Simple Harmonic Motion
The velocity and acceleration for simple harmonic motion can be found by differentiating the displacement:
Figure Caption: Displacement, x, velocity, dx/dt, and acceleration, d2x/dt2, of a simple harmonic oscillator when φ = 0.

16. Simple Harmonic Motion
Because then

17. Conceptual Quiz
A) 0
B) A/2
C) A
D) 2A
E) 4A
A mass on a spring in SHM has amplitude A and period T. What is the total distance traveled by the mass during a time interval T?
Answer: 5

18. Conceptual Quiz
A) 0
B) A/2
C) A
D) 2A
E) 4A
A mass on a spring in SHM has amplitude A and period T. What is the total distance traveled by the mass after a time interval T?
In the time interval T (the period), the mass goes through one complete oscillation back to the starting point. The distance it covers is A + A + A + A (4A).

19. Conceptual Quiz
A mass on a spring in SHM has amplitude A and period T. At what point in the motion is v = 0 and a = 0 simultaneously?
A) x = A
B) x > 0 but x < A
C) x = 0
D) x < 0
E) none of the above
Answer: 5

20. Conceptual Quiz
A mass on a spring in SHM has amplitude A and period T. At what point in the motion is v = 0 and a = 0 simultaneously?
A) x = A
B) x > 0 but x < A
C) x = 0
D) x < 0
E) none of the above
If both v and a were zero at the same time, the mass would be at rest and stay at rest! Thus, there is NO point at which both v and a are both zero at the same time.
Follow-up: Where is acceleration a maximum?

21. Connection between uniform circular motion and simple harmonic motion.
There is a remarkable relationship between the two.
Do projected uniform circular motion demo.

22. Oscillations of a Spring
If the spring is hung vertically, the only change is in the equilibrium position, which is at the point where the spring force equals the gravitational force.
This is the new equilibrium point.
The mass oscillates about this level.
Figure Caption: (a) Free spring, hung vertically. (b) Mass m attached to spring in new equilibrium position, which occurs when ΣF = 0 = mg – kx0.

23. Energy

24. E is total mechanical energy = K + U. E will be conserved in this case
E is total mechanical energy = K + U E will be conserved in this case. We are assuming frictionless motion.

25. Energy as a Function of Position in Simple Harmonic Motion

26. Energy as a Function of Time in Simple Harmonic Motion

27. Look at simulations http://physics. bu. edu/~duffy/semester1/semester1
Look at simulations Simple harmonic motion

28. Spring Oscillation. A vertical spring with spring stiffness constant 305 N/m oscillates with an amplitude of 28.0 cm when kg hangs from it. The mass passes through the equilibrium point (y = 0) with positive velocity at t = 0. (a) What equation describes this motion as a function of time? (b) At what times will the spring be longest and shortest?
Giancoli, 4th ed, Problem 14-15

29. Oscillating Mass. A mass resting on a horizontal, frictionless surface is attached to one end of a spring; the other end is fixed to a wall. It takes 3.6 J of work to compress the spring by 0.13 m. If the spring is compressed, and the mass is released from rest, it experiences a maximum acceleration of 15 m/s2. Find the value of (a) the spring constant and (b) the mass.
Giancoli, 4th ed, Problem 14-35

30. Conceptual Quiz B) 1/2 N C) 1 N D) 2 N E) 4 N A) 1/4 N
A spring can be stretched a distance of 60 cm with an applied force of 1 N. If an identical spring is connected in parallel with the first spring, and both are pulled together, how much force will be required to stretch this parallel combination a distance of 60 cm?
Answer: 4

31. Conceptual Quiz B) 1/2 N C) 1 N D) 2 N E) 4 N A) 1/4 N
A spring can be stretched a distance of 60 cm with an applied force of 1 N. If an identical spring is connected in parallel with the first spring, and both are pulled together, how much force will be required to stretch this parallel combination a distance of 60 cm?
Each spring is still stretched 60 cm, so each spring requires 1 N of force. But because there are two springs, there must be a total of 2 N of force! Thus, the combination of two parallel springs behaves like a stronger spring!!