Chapter 14: Simple Harmonic Motion

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Chapter 14 - Simple Harmonic Motion
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Chapter 14: Simple Harmonic Motion Evaluations and Lab exam are on Monday , Dec 3 during class time in SIMS 209. Lab exam will be on pre-labs, demos, and theory in the pre-labs Final Exam: SIMS 209 Section of 9:30am: exam Monday, Dec 10 at 11:30pm Section of 11:00am: exam Thursday, Dec 6 at 8:00am

14-2 Simple Harmonic Motion Example 14-4: Loudspeaker. The cone of a loudspeaker oscillates in SHM at a frequency of 262 Hz (“middle C”). The amplitude at the center of the cone is A = 1.5 x 10-4 m, and at t = 0, x = A. (a) What equation describes the motion of the center of the cone? (b) What are the velocity and acceleration as a function of time? (c) What is the position of the cone at t = 1.00 ms (= 1.00 x 10-3 s)? Figure 14-9. Caption: Example 14-4. A loudspeaker cone. Solution: a. The angular frequency is 1650 rad/s, so x = (1.5 x 10-4m)cos(1650t). b. The maximum velocity is 0.25 m/s, so v = -(0.25 m/s)sin(1650t). The maximum acceleration is 410 m/s2, so a = -(410 m/s2)cos(1650t). c. At t = 1 ms, x = -1.2 x 10-5 m.

Problem 13 13. (II) Figure 14–29 shows two examples of SHM, labeled A and B. For each, what is (a) the amplitude, (b) the frequency, and (c) the period? (d) Write the equations for both A and B in the form of a sine or cosine.

14-3 Energy in the Simple Harmonic Oscillator We already know that the potential energy of a spring is given by: The total mechanical energy is then: The total mechanical energy will be conserved, as we are assuming the system is frictionless.

14-3 Energy in the Simple Harmonic Oscillator If the mass is at the limits of its motion, the energy is all potential. If the mass is at the equilibrium point, the energy is all kinetic. We know what the potential energy is at the turning points: Figure 14-10. Caption: Energy changes from potential energy to kinetic energy and back again as the spring oscillates. Energy bar graphs (on the right) are described in Section 8–4.

14-3 Energy in the Simple Harmonic Oscillator The total energy is, therefore, And we can write: This can be solved for the velocity as a function of position: where

14-3 Energy in the Simple Harmonic Oscillator Example 14-7: Energy calculations. For the simple harmonic oscillation of Example 14–5 (where m=0.300kg, k = 19.6 N/m, A = 0.100 m, x = -(0.100 m) cos 8.08t, and v = (0.808 m/s) sin 8.08t), determine (a) the total energy, (b) the kinetic and potential energies as a function of time, (c) the velocity at half amplitude (x = ± A/2), and (d) the kinetic and potential energies when the mass is 0.050 m from equilibrium Solution: a. E = ½ kA2 = 9.80 x 10-2 J. b. U = ½ kx2 = (9.80 x 10-2 J) cos2 8.08t, K = ½ mv2 = (9.80 x 10-2 J) sin2 8.08t. c. v = 0.70 m/s d. U = 2.5 x 10-2 J, K = E – U = 7.3 x 10-2 J.

14-3 Energy in the Simple Harmonic Oscillator This graph shows the potential energy function of a spring. The total energy is constant. Figure 14-11. Caption: Graph of potential energy, U = ½ kx2. K + U = E = constant for any point x where –A ≤ x ≤ A. Values of K and U are indicated for an arbitrary position x.

14-5 The Simple Pendulum A simple pendulum consists of a mass at the end of a lightweight cord. We assume that the cord does not stretch, and that its mass is negligible. Figure 14-13. Caption: Strobe-light photo of an oscillating pendulum photographed at equal time intervals.

14-5 The Simple Pendulum In order to be in SHM, the restoring force must be proportional to the negative of the displacement. Here we have: which is proportional to sin θ and not to θ itself. Figure 14-14. Caption: Simple pendulum. However, if the angle is small, sin θ ≈ θ.

14-5 The Simple Pendulum Therefore, for small angles, we have: where The period and frequency are:

14-5 The Simple Pendulum So, as long as the cord can be considered massless and the amplitude is small, the period does not depend on the mass. Figure 14-15. Caption: The swinging motion of this lamp, hanging by a very long cord from the ceiling of the cathedral at Pisa, is said to have been observed by Galileo and to have inspired him to the conclusion that the period of a pendulum does not depend on amplitude.

14-5 The Simple Pendulum Example 14-9: Measuring g. A geologist uses a simple pendulum that has a length of 37.10 cm and a frequency of 0.8190 Hz at a particular location on the Earth. What is the acceleration of gravity at this location? Answer: Solving the pendulum frequency equation for g gives g = 9.824 m/s2.

14-5 The Simple Pendulum Problem 41 41. (I) A pendulum has a period of 1.35 s on Earth. What is its period on Mars, where the acceleration of gravity is about 0.37 that on Earth?

14-6 The Physical Pendulum and the Torsional Pendulum A physical pendulum is any real extended object that oscillates back and forth. The torque about point O is: Substituting into Newton’s second law gives: Figure 14-16. Caption: A physical pendulum suspended from point O.

14-6 The Physical Pendulum and the Torsional Pendulum For small angles, this becomes: which is the equation for SHM, with

14-6 The Physical Pendulum and the Torsional Pendulum A torsional pendulum is one that twists rather than swings. The motion is SHM as long as the wire obeys Hooke’s law, with Figure 14-18. Caption: A torsion pendulum. The disc oscillates in SHM between θmax and –θmax . (K is a constant that depends on the wire.)  

Problem 49 49. (II) The balance wheel of a watch is a thin ring of radius 0.95 cm and oscillates with a frequency of 3.10 Hz. If a torque of 1.1X10-5 Nm causes the wheel to rotate 45°, calculate the mass of the balance wheel.