Waves

1. Waves Physics H

2. Pendulum • A pendulum is simply a mass (bob) suspended from a string that can swing back and forth • The time it takes for the pendulum to swing back and forth is called the period. • Period depends on length of the pendulum, not on weight suspended. • The back and forth motion is called simple harmonic motion (SHM) • Produces a sine curve

3. The restoring force of a pendulum is a component of the bob’s weight • x-component pushes the bob toward equilibrium • At small angles, a pendulum follows SHM • At large angles this breaks down • Potential energy increases as displacement increases • Cons of energy still applies PE + KE = const.

4. The following holds true for a pendulum or a spring At the equilibrium point, v is a max At max displacement, force and “a” are max In SHM restoring force is proportional to displacement Hooke’s Law Felastic = -kx k = spring constant x = displacement - = force is always opposite direction from displacement See Figure 12-1 A stretched or compressed spring has elastic potential energy Hooke’s Law

5. Sample Problem 12A • If a mass of .55kg attached to a vertical spring stretches the spring 2.0cm from it’s equilibrium position, what is the spring constant? • Not accelerating so Nnet = 0 • Fnet = 0 = Felastic - FW

6. -kx – mg = 0 • Rearange k = -(mg)/x • k = -(.55kg)(9.8m/s2)/(-.02m) • k = 270 N/m

7. The period of a simple pendulum can be calculated with period = 2Π x square root of length / gravity Period of a mass spring system in SHM period = 2Π x square root of mass / spring constant Pendulum Mass-Spring

8. Ex • When a mass of 25g is attached to a certain spring, it makes 20 complete vibrations in 4.0s. What is the spring constant? • Calculate period first • 4.0s/20vibrations = .2s / vibration • Now use the formula

9. .2s = 2Π√(.025kg/k) • .1s/ Π = √(.025kg/k) square both sides • .00101s2 = .025kg / k • k = 25 N/m

10. Sample Problem 12B • You need to know the height of a tower, but darkness obscures the ceiling. You note that a pendulum extending from the ceiling almost touches the floor and that its period is 12 s. How tall is the tower?

11. Sample Problem 12C • The body of a 1275 kg car is supported on a frame by four springs. Two people riding in the car have a combined mass of 153 kg. When driven over a pothole in the road, the frame vibrates with a period of 0.840 s. For the first few seconds, the vibration approximates SHM. Find the spring constant of a single spring.

12. Homework • 12A-C odd

13. Wave Motion • Mechanical waves travel by molecules vibrating back and forth or up and down. • Sound, ocean wave • They have to travel through a medium • Water, air • Pulse – single traveling wave

14. Transverse Wave - Motion of the wave is at right angles to the direction the wave is moving. Longitudinal Wave - Motion of the wave is in the same direction as the direction the wave is moving. Wave Types

16. Waves are made up of several parts Crests - high points Troughs - low points Amplitude - distance from the midpoint to the crest or trough Wavelength - distance form the top of one crest to the top of the next. Frequency - How often a vibration occurs. Period - amount of time for 1 cycle Wave Description

17. Wave

18. Frequency • Frequency measures the number of times a wave oscillates in a given time (second) • Frequency is measured in hertz • 1 cycle per second = 1 hertz • frequency = 1/period • period = 1/frequency

19. Wave Speed • Wave speed depends on what type of medium it is traveling through • The speed of a wave is dependant upon 2 things, wavelength and frequency • Wave speed = wavelength x frequency • v = f

20. The Sears tower swings back and forth at a frequency of .1Hz what is its period? What is the wavelength of a 170Hz sound wave when the speed of sound in air is 340m/s? Frequency = 1/period .1Hz = 1/period Period = 10s v = f 340m/s =(170Hz)  = 2.0m Examples

21. Sample Problem 12D • The piano string tuned to middle C vibrates with a frequency of 264 Hz. Assuming the speed of sound in air is 343 m/s, find the wavelength of the sound waves produced by the string.

22. Interference • Occurs every time two waves overlap • Constructive- When crests of two waves overlap, it results in increased amplitude. The waves are said to be in phase • Destructive- When the crest of one wave overlaps with the trough of another wave, they cancel each other out. The waves are said to be out of phase with each other.

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24. Reflection • When ever a wave transfers from one medium to another, part of the wave reflects and part of the waves energy continues on. • At a free boundary, waves are reflected. • At a fixed boundary, waves are reflected and inverted.

25. Standing Waves • If a string attached to a wall vibrates at exactly the right frequency, it can produce a standing wave. • Standing Wave- A wave pattern that does not move along the string. • Node – There is no motion on the string • Antinode – midway between the nodes, vibrations have the largest amplitude

26. What are the two types of interference? How fast is a wave with a wavelength of 3m and a frequency of 212Hz moving? Describe the two types of waves. If a wave has a period of .2s, what is its frequency? A radio station has a frequency of 101 MHz, what is the period of its wave? What are the two points of importance on a standing wave? Review

27. Chapter 12 Review • p. 469 #8-9 • p. 470 #19-22 and 35 • p. 471 #36