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Vibrations and Waves. Extreme Example Tacoma Narrows Bridge Tacoma Narrows Bridge It stood for only 3 months before…. It stood for only 3 months before….

Published byFrederick Wilcox Modified over 8 years ago

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Presentation on theme: "Vibrations and Waves. Extreme Example Tacoma Narrows Bridge Tacoma Narrows Bridge It stood for only 3 months before…. It stood for only 3 months before…."— Presentation transcript:

1 Vibrations and Waves

2 Extreme Example Tacoma Narrows Bridge Tacoma Narrows Bridge It stood for only 3 months before…. It stood for only 3 months before…. http://www.youtube.com/watch?v=P0Fi1VcbpAI

3 Vibrations and waves SHM SHM Oscillation Oscillation Periodic Periodic f= -KX F= Restoring force K= spring constant X= displacement

4 Equilibrium Position Equilibrium Position Displacement Displacement Amplitude Amplitude Period-T, time needed for 1 full cycle (sec) Period-T, time needed for 1 full cycle (sec) Frequency- f, # of cycles per second (Hz) Frequency- f, # of cycles per second (Hz)

5 f= 1/T T= 1/f *Car Spring Example, pg. 311 Section 11-2 draws heavily from chpt. 6 Read on your own pg. 312- 314

6 Section 11-3, read the deriving of formula… Section 11-3, read the deriving of formula… T s = 2  m/k Formula for Period of Spring m= mass k= spring constant

7 Not direct relationship! Not direct relationship! T m/k Mass must QUADRUPLE to double period Mass must QUADRUPLE to double period We can Substitute… We can Substitute… f = 1/T = f = 1/2  k/m

8 What are T & f of the car example on pg.311 after hitting a bump? Assume shock absorbers are poor so car really oscillates a lot. What are T & f of the car example on pg.311 after hitting a bump? Assume shock absorbers are poor so car really oscillates a lot. T = 2  √m/k = 6.28 √ 1400kg/ 6500N/m =.92sec F = 1/.92 = 1.09Hz

9 A small insect (.3g) is caught in a spider web (mass-less). The web vibrates at 15Hz A small insect (.3g) is caught in a spider web (mass-less). The web vibrates at 15Hz a. estimate the value of K for the web b. find f for an insect of mass.1g.

10 f = 1/2  √K/m K = (2  f) 2 m = (6.26 x 15) 2 (3 x 10 -4 kg) 2.7 N/m Sub in for M 1 x 10 -4 kg f = 26Hz

11 Simple Pendulum What determines T for a Pendulum? What determines T for a Pendulum? Mass of bob Amplitude of swing Length of string Gravity of location × ×

12 Formula T p = 2  √ L / g F = 1 / T = ½  √ g / L For pendulums to be said to be in SHM the displacement angle has to be small- less than 15°

13 Damped Harmonic Motion Amplitude of a swinging spring on a pendulum slowly decreases in time until the oscillations stop all together. Amplitude of a swinging spring on a pendulum slowly decreases in time until the oscillations stop all together. X Time

14 Damping is caused by air friction and internal friction within the system Damping is caused by air friction and internal friction within the system Common dampening systems are shock absorbers and door closing mechanisms. Common dampening systems are shock absorbers and door closing mechanisms.

15 A = over damped (too slow) B= Critically damped C=under damped (still oscillating) C B A x time

16 Resonance… Forced Vibrations Objects have natural resonant frequencies. When vibrations are put on an object that are at the natural resonant frequency, an increase in amplitude is observed. Objects have natural resonant frequencies. When vibrations are put on an object that are at the natural resonant frequency, an increase in amplitude is observed.

17 If pushing is random- swing just bounces around If pushing is random- swing just bounces around But if you push with frequency equal to Natural Resonant Frequency(NRF) you can get a big amplitude But if you push with frequency equal to Natural Resonant Frequency(NRF) you can get a big amplitude Swing

18 examples… Tuning Fork Guitars http://www.youtube.com/watch?v=I4jdGf3RzCsyoutube

19 Wave Motion mechanical waves for now… mechanical waves for now… -OVER HEAD- -OVER HEAD- Is the velocity of a wave moving along a cord the same as the velocity of a particle of the cord? Is the velocity of a wave moving along a cord the same as the velocity of a particle of the cord? NO – velocities are different so are directions…

20 Waves don’t carry matter, carry matter,theytransferenergy

21 The parts of a single frequency wave

22 Types of waves Wave Motion Transverse Compression Rare factions Longitudinal S- waves Earth quake waves P- waves; only P travels through liquid

23

24 Water Waves Water Waves

25

26 Wave Formula V= f Velocity=wavelength x frequency

27 Reflection of Waves Wave fronts Plane waves Law of reflection

28 Wave Interference Principle of superposition Destructive interference Constructive Interference In phase or Out of phase

29 Standing Waves: Resonance Standing Waves Nodes Antinodes Natural frequencies Fundamental frequencies Overtones http://www.youtube.com/watch?feature=player_embedded&v=O z53w_k_j_A#!

30 Refraction and Diffraction

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