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Published byMalcolm Edwards Modified over 9 years ago
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Waves
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Wave Properties Waves are propagated by a vibrating source Pulse – single disturbance created by a single oscillation Periodic Wave – periodic disturbance created by a continuously vibrating source
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Definition Mechanical Wave - transfer of energy through a medium Waves can move over large distances, but the particles of the medium only vibrate about fixed positions Waves transport energy but not matter Mechanical waves must travel through a medium
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Types of Waves Transverse – particles in medium vibrate perpendicular to the direction of the wave motion A crest trough
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Crest – max displacement Trough – minimum displacement λ – wavelength – distance between two successive crests (or troughs) A – amplitude – maximum displacement from the rest position
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Longitudinal Waves Particles vibrate parallel to the direction of wave motion
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Compression – wave particles are compacted closely together Rarefaction – where particles are spread out Wavelength – distance between two corresponding in phase points Amplitude – maximum displacement from rest
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Damping Initial amplitude of the wave depends on the initial energy of the source Energy decreases over time, so the amplitude does as well - damping
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Wave Equation The velocity of a wave is related to its wavelength and frequency Velocity – speed the wave travels Frequency – number of cycles that pass a given point per second (in Hertz) - measured by crests per second v = λf
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Example A wave has a wavelength of 5m and a frequency of 3 Hz. What is its speed? A crest of a wave in a pool takes 2.5sec to travel from one end to the other end (20m). It is noticed that 10 crests pass by a mark in 15 sec. What is the wavelength?
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The frequency of a wave is determined by the rate that the source produces them The velocity of a wave depends on the properties of the medium
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Velocity of Transverse In transverse waves the velocity depends on the tension (tightness) of the medium and the mass/length of the medium Greater tension increase both v and f v = √(F t /(m/L))
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Example A wave of wavelength.30m is traveling down a 300m long wire of mass 15kg. If the wire is under a tension of 1000N, what is the velocity and frequency of the wave?
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Longitudinal Velocity Velocity in longitudinal waves depends on the elasticity(E) of the material and the density(ρ) of the material v = √(E/ ρ)
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Example You can hear a train approaching by putting your ear to the track. How long does it take for a sound wave to travel 1.0km down a steel track? E = 2.0x10 11 N/m 2 and ρ = 7.8x10 3 kg/m 3
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