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Waves & Vibration

The Doppler effect describes the change in wave frequency when there is relative motion between the wave source and its observer. If the source approaches the observer, the frequency increases, and if it moves away, the frequency decreases.

Waves & Vibration

Waves & Vibration

Doppler effect

Doppler effect refers to the change in wave frequency during the relative motion between a wave source and its observer.
When a source moves towards a stationary listener (Vobserver=0)
When the source moves away from the listener
If the source is receding from the detector/observer, the speed of the source is positive
If the source is approaching the detector/observer, the speed of the source is negative

Boundary Behaviour

Diffraction
The spreading out of waves, especially when they pass through an opening which is smaller than the wavelength. It is the bending of waves around small openings or past corners

We can think of diffraction as light entering a dark room. When the door is closed, the path of light is forbidden to enter the room. Only until the door is opened partially, the light transfers inside with a bend around the door. In this case, the door acts as an obstacle in the path of light.

Refraction
-When a wave changes speed as it moves through a new medium but the frequency remains the same -The speed of any mechanical wave as it propagates through a medium is dependent mainly on the type of medium. The denser the medium, the slower the speed

In simpler terms, we can evaluate the concept of refraction present in bodies of water. When you insert an object straight into the water it may create an illusion making it seem as if the object has bent. This is because water is denser than air, so when light goes from air to water it slows down which causes a shift in the lights direction.

Transmission of a Pulse Across a Boundary from Less to More Dense
-In this situation, part of the wave is reflected and another part of the wave is transmitted. -The transmitted pulse is upright, while the reflected pulse is inverted
-Consider a thin rope attached to a thick rope, making the point where the two ropes are attached the boundary. -At this point, an incident pulse will transfer from the less dense medium (thin rope) to the boundary with a more dense medium (thick rope).
What are Reflections? -A wave is a “perfect” transfer of energy. When the wave reaches a barrier, the energy is reflected back. -If a wave changes from a crest to a trough (or vice versa) at a particular point, it has experienced a change of phase (its phase depends on how the wave is attached) -The two types of reflection are: (Free-end reflection, Fixed-end reflection)
Fixed-End Reflection: -A wave’s medium being attached to a fixed end. Meaning, the end of the medium will not be able to move (reflection from rigid obstacle) -In this reflection, the reflected wave is inverted from the incoming wave (with the same speed, wavelength, and amplitude as the incident pulse) -Results in phase change: (crest-> trough) (trough-> crest)
Free-End Reflection: -When a wave’s medium is attached to a stationary object as a free object.This means that the end of the medium is allowed to slide up and down. -A reflection where the medium is free, results in the reflected wave that is not inverted (no phase change)

Standing Waves

Resonance:
-Resonance is the response of an object that is free to vibrate to a periodic force with the same frequency as the natural frequency of the object. -The natural or resonant frequencies of an object are those that produce standing waves

The source of any sound is a vibrating object. Instruments such as woodwinds, the brasses and the organ pipes produce sound from the vibrations of standing waves in a column of air within a pipe or tube. Most wind instruments are either of the Open-Open tube type or Open-Closed tube type.

Closed air column: -An air column that is closed at one end and open at the other is called a closed air column. At a closed-end, the air in the tube comes into contact with the solid surface (instrument or mouth). The air particles at the closed end can’t vibrate freely and have zero particle displacement creating a node. -When a vibrating tuning fork is held over the open end of such a column and the length of the column is increased, the loudness increases sharply at very specific lengths (i.e. points of resonance). -A clarinet is an example of a wind musical instrument that is open at one end by the bell-shaped termination and the other end is closed by the mouth.

Ln= (2n-1)lambda/4, for n=1,2,3... -For media with a fixed end and a free end -Node at one end and antinode at other end -In this case the shortest possible length to produce a standing wave is l/4

Open-end air column: -If both ends of the tube are uncovered or open, the musical instrument is said to contain an open-end air column. At an open end, the air in the tube comes into contact with the atmospheric air at atmospheric pressure. The air particles at the open end can vibrate freely and have maximum particle displacement making an antinode. -A variety of instruments operate on the basis of open-end air columns; examples include the brass instruments such as the flute and trombone and woodwinds such as the saxophone and oboe. Even wind chimes and some organ pipes serve as open-end air columns.

What are Standing Waves: -A standing wave is the combination of two waves, moving in opposite direction; each having the same amplitude and frequency. The three different cases: -Standing waves between two fixed ends -Standing waves between two free ends -Standing waves between a combination of one fixed and one free end
Standing waves between a combination of one fixed and one free end
Standing waves between two free ends
Standing waves between two fixed ends

Types of Mechanical Waves

What are Mechanical Waves? -Mechanical waves produce when particles vibrate in a medium in which the wave propagates. Therefore, transferring energy through a medium. -A mechanical wave can be transverse or longitudinal
Transverse Waves: -A wave in which particles of the medium move in a direction perpendicular to the direction which the wave moves
Longitudinal Waves: -A wave in which particles of the medium move in a direction parallel to the direction which the wave moves

Rarefraction: The region in a longitudinal wave in which the medium’s particles are farther apart

Compression: The region in a longitudinal wave in which the medium’s particles are closer together

Principle of Superposition

The two types of interferences that prove this concept are constructive and destructive interference.
Destructive Interference: -When two identical waves arrive exactly out of phase such that they precisely align crest to trough, producing destructive interference. The resulting amplitude is zero for destructive interference as the waves completely cancel out each other

A crest and a trough meet and cancel each other out

Constructive Interference: -When two identical waves arrive at the same point exactly in phase such that the crests of the two waves are precisely aligned, as are the troughs. This superposition produces constructive interference. It produces a wave that has twice the amplitude of the individual waves, but has the same wavelength.

Two crests/troughs meet and form a super-crest/super-trough

- When two waves meet, they will always “interfere” with each other. The individual waves will add together (superposition) so that a new wavefront is created. - In general, the concept of amplitude addition is called “The Principle of Superposition"
As each pulse moves in a constant speed of 2 squares per second, on a string which is 16 squares long. The resultant displacement (green) is equal to the sum of the displacements of the individual waves at the point

Sound Characteristics

Pitch
The sensation of a frequency is commonly referred to as the pitch of a sound. A high pitch sound corresponds to a high frequency sound wave and a low pitch sound corresponds to a low frequency sound wave
Loudness
The loudness of a sound is also determined by the sensitivity of the ear. The human ear is more sensitive to some frequencies than to others. The volume we receive thus depends on both the amplitude of a sound wave and whether its frequency lies in a region where the ear is more or less sensitive
The amplitude of a sound wave determines its loudness or volume. A larger amplitude means a louder sound, and a smaller amplitude means a softer sound. Sound energy is a longitudinal wave, the amplitude of a longitudinal wave is a difference in pressure (pressure is the force per unit area)

P= F/A Where P is the pressure, F is the force, and A is the area

Sound Intensity
Mach Number
-If you are traveling faster than Mach 1 (331m/s), your speed is supersonic -If your speed is below Mach 1, your speed is subsonic
M= air speed of object/ local speed of sound
The mach number is the ratio of the airspeed of an object to the local speed of sound
The Speed of Sound in Air
To calculate the speed of sound in different temperatures use: v=331.4+(0.606)T
The speed of sound in air depends on the temperature of the air
Beats
Beat Frequency= f1-f2
-To get a standing wave, the two waves must have identical frequencies. Beats are produced when waves of similar but not identical frequencies interact. You would like two different sound waves to produce audible beats then have two different frequencies. Since the frequencies are slightly off, the interference produces alternating periods of high and low amplitudes. -Beats can be used to assess very small differences in frequency between two waves, because you can hear the change in loudness

Characteristics of Waves

Universal Wave Equation: -The rate at which a wave is travelling through a medium; also a measure of how fast the energy in the wave is moving
Another way to calculate wave speed (if you have the period) V=lambda/T
What are Waves? Waves are disturbances that transfer energy from one place to another
Cycle: -One complete oscillation
Wavelength: -The distance between two similar points in successive identical cycles in a wave. The length between successive crests/troughs are equal (measured in meters)
Frequency: -The number of complete cycles that appear in unit time, measured in hertz (Hz)

Equation: f=1/T

Period: -The time for a vibrating particle to complete one cycle
Trough: -The lowest point on a transverse wave
Crest: -The highest point on a transverse wave (also called the peak)
Amplitude: -The maximum displacement of the particles from the equilibrium position. It’s distance between the resting position and the maximum displacement of the wave.