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Vibrations and Waves. Honors Physics. Biblical Reference. Then we will no longer be infants, tossed back and forth by the waves . Ephesians 4:14. Simple Harmonic Motion. Back and forth motion that is caused by a force that is directly proportional to the displacement.
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Vibrations and Waves Honors Physics
Biblical Reference Then we will no longer be infants, tossed back and forth by the waves. Ephesians 4:14
Simple Harmonic Motion • Back and forth motion that is caused by a force that is directly proportional to the displacement. • The displacement centers around an equilibrium position.
Springs – Hooke’s Law • One of the simplest type of simple harmonic motion is called Hooke's Law. • This is primarily in reference to springs.
Springs – Hooke’s Law The negative sign tells us that “F” is a restoring force; it works in the oppositedirection of the displacement.
Hooke’s Law Common formulas which are set equal to Hooke's law are Newton’s Second Law and weight.
Example A 0.55 kg mass is attached to a vertical spring, which stretches 36 cm from it’s original equilibrium position. What is the spring constant?
Example A load of 50 N attached to a spring hanging vertically stretches the spring 5.0 cm. The spring is now placed horizontally on a table and stretched 11.0 cm. What force is required to stretch the spring this amount?
Springs are like Waves and Circles The amplitude, A, of a wave is the same as the displacement ,x, of a spring. Both are in meters. Crest Equilibrium Line Trough
CREST Period Equilibrium Line • Period (T): the time for one revolution or one completeoscillation (one crest and trough). • Oscillations could also be called vibrations and cycles. • Ts= sec/cycle Trough • In the wave above we have 1.75 cycles or waves (vibrations or oscillations). • Assume that the wave crosses the equilibrium line in one second intervals. • T = 3.5 seconds/1.75 cycles. T = 2 sec.
Frequency • The Frequencyof a wave is the inverse of Period. • That means that the frequency is cycles/sec. • The commonly used unit is Hertz (HZ).
Measuring SHM for a Spring • The period of a Spring-Mass System is: • Proportional to 2 • Inversely proportional to the square root of the spring constant • Proportional to the square root of the mass on the spring • The greater the mass, the larger the period • The greater the spring constant (more stiff), the smaller the period
Example A 125 N object vibrates with a period of 3.56 seconds when hanging from a spring. Find the spring constant.
Measuring SHM for a Pendulum • The period of a pendulum is: • Proportional to 2 (it’s sweeping out an arc of a circle) • Inversely proportional to the square root of gravity • Proportional to the square root of the length of the pendulum
Example The height of a tower is unknown, but a pendulum, extending from the ceiling almost touches the floor. If the period of the pendulum is 12 s, what is the approximate height of the tower?
What is a wave A Wave is a vibration or disturbance in space. A Mediumis the substance that all sound waves travel through and need to have in order to move.
Longitudinal Waves Longitudinal Wave - A fixed point will move parallel with the wave motion 2 areas: Compression - an area of high molecular density and pressure Rarefaction - an area of low molecular density and pressure
Transverse Waves Transverse Wave - A fixed point will move perpendicular with the wave motion. Wave parts:Crest, Trough, Wavelength, Amplitude, Frequency, Period
Properties of Waves All waves have 4 basic properties: Amplitude Wavelength λ lambda Frequency f Speed c
Properties of Waves Amplitude –the maximum distance the wave moves up and down. The more energy a wave has the greater the amplitude.
Properties of Waves Wavelength – the distance between two corresponding parts of a wave Short Waves can complete more cycles than Long Waves in the same amount of time.
Properties of Waves Frequency – the number of complete waves that pass a given point Frequency is measured in the unit called Hertz (Hz). A wave that occurs every second has a frequency of 1 Hz.
Properties of Waves Speed – the distance a wave travels in a given amount of time. The speed of sound through air is 331 m/s.
Wave Speed You can find the speed of a wave by multiplying the wave’s wavelength in meters by the frequency (cycles per second). Since a “cycle” is not a standard unit this gives you m/s.
Example A harmonic wave is traveling along a rope. It is observed that the oscillator that generates the wave completes 40.0 vibrations in 30.0 s. Also, a given maximum travels 425 cm along a rope in 10.0 s . What is the wavelength?
Wave Behavior Superposition- The combination of two overlapping waves Interference- The result of superposition
Standing Waves A standing wave is produced when a wave that is traveling is reflected back upon itself. Two main parts of standing waves: • Antinodes – Areas of maximum amplitude • Nodes – Areas of zero amplitude
Interference Interference is the interaction between waves that meet There are two types of interference: Constructive and Destructive
Reflection When an object hits a surface it can not pass, it bounces back. This is called reflection.
Refraction The bending of waves due to a change in speed is called refraction.
Diffraction When a wave moves around a barrier or through an opening in a barrier, it bends and spreads out. This is known as diffraction.