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* Wave vs particle * Mechancal vs non-mechancal * Longitudinal vs Transverse * Spreading of waves
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* A disturbance which travels through a medium from one point in space to the others. * A medium is the matter through which a wave travels * E.g. pond- water; sound- air; earthquake- Earth * Mechanical waves- require a medium * Electromagnetic waves- do not require a medium; instead these waves consist of changing electric and magnetic fields * E.g. light and radiowaves
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* Energy is transferred from one place to another in a wave motion. * WAVES TRANSFER ENERGY! * Motion of the medium (particles of the medium) is usually periodically vibratory. * Only the shape or form of wave travels, not the medium. * Energy may spread out as waves travel (drop pebble, circles get larger as they spread outwards)
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Vibrational Motion * Vibration: in a general sense, anything that switches back and forth, to and fro, side to side, in and out, off and on, loud and soft, or up and down is vibrating. A vibration is a wiggle in time. * Wave: a wiggle in both space and time is a wave. A wave extends from one place to another. * Vibrations and waves: the source of all waves is something that is vibrating. Waves are propagations of vibrations throughout space. repeats * Harmonic motion occurs when a vibration repeats and is converted (no energy input is needed to continue the motion)
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A wave is an oscillation that travels. A ball floating on water can oscillate up and down in harmonic motion. The surface of the water oscillates in response and the oscillation spreads outward from where it started.
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* B. Properties of Periodic Motion Cycle : A cycle is a unit of motion that repeats.
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* B. Categories of Waves Waves are classified into different types according to their natures :
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According to the direction of vibration, waves are classified into : (a) Transverse wave; ( doing ‘the wave’, string on a door knob) (b) Longitudinal waves (sound waves, sslinky- stretch and move directly toward the end) ONLINE DEMO: http://www.acoustics.salford.ac.uk/schools/teacher/lesson1/lesson1inter active.html
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* The waveform appears in the shape of sine curve. * A wave in which the motions of the matter particles are perpendicular to the direction of propagation of the wave itself. Water waves, pulse in a stretched string,transverse wave demonstrator. Examples
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* A wave in which the motions of the matter particles are in the same direction as the wave propagation. Examples Sound, or a spring oscillating up and down
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* A material medium is necessary for the transmission for mechanical waves. Mechanical waves cannot travel through vacuum. * Due to forces on particles in the “medium” that are next to each other, the disturbance is transmitted from one layer to the next through the medium.
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* Material medium is not essential for propagation. e/m waves travel through vacuum. * Disturbance of electric and magnetic fields travelling through space. * All electromagnetic waves are transverse waves. X-rays, radio waves, micro-waves,etc. examples
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* Amplitude * Wavelength ( ) * Frequency (f) * Period (T) * Wave velocity (v) A wave is usually described by the following terms : Each term will be explained….
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* The amplitude is the maximum displacement of the medium from its equilibrium position. The amplitude of a wave refers to the distance from the equilibrium point (or ½ the distance from highest to lowest point of vibration) * The wavelength ( ) is the minimum distance between two points which are in phase. * The frequency (ƒ) is the number of complete oscillations made in one second. The frequency of a wave refers to how many “waves” pass by a point in a given amount of time (usually a second) Unit : Hz * The period (T) The period of a wave is the time for a to make one complete cycle. Period, being a time, is measured in units of time such as seconds, hours, days or years. It is the time taken for one complete oscillation. It is related to frequency by T = 1/ƒ Unit : s
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* Graphing harmonic motion- using paper and string * When oscillations are small, the motion is called simple harmonic motion (shm) and can be described by a simple sine curve. * See animation See animation
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* Use construction paper- string -glue * create a transverse wave * Label parts * Crest‘- highest part off rest of transverse wave * Trough-lowest part off rest of transverse wave * Amplitude-maximum displacement off rest * Wavelength-distance between two points –crest to crest * Frequency- to how many “waves” pass by a point in a given amount of time (usually a second) the entire sheet is one second * Period-time for a wave to make one complete cycle.
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* Flip side of transverse wave model * create a longitudinal wave – draw slinky-like model * Label parts * Compression-Crest- particles – highest density * Rarefaction -Trough-particles stretched * Amplitude-maximum displacement off rest-compression to rest * Wavelength-distance between two points –compression to compression * Frequency- to how many “waves” pass by a point in a given amount of time (usually a second) the entire sheet is one second * Period-time for a wave to make one complete cycle.
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E. The Wave Equation The wave velocity is the displacement traveled by the wave in one second …….... The wave velocity (v) is related to frequency and wavelength by -- v = ƒ The Wave Equation
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U sing the Wave Equation U sing the Wave Equation Example : A travelling wave of wavelength 0.6m moves at a speed of 3.0 m/s. What is the period of this wave ? Then the period of this wave is ??? Period T = 1/ƒ T = 1/5.0 or 0.2 s = 0.6 m, v = 3.0 m/s f = ? By using the wave equation, v = ƒ ƒ = v/ f = (3.0 m/s)/(0.6 m) ƒ = 5.0 Hz The unit of ‘m’ cancel out—and you are left with 5.0/s which is 5.0 Hz
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* The speed of a wave equals the frequency times the wavelength. v = f Frequency (cycles/sec) Wavelength (m) Speed (m/sec)
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* A student does an experiment with waves in water. * The student measures the wavelength of a wave to be 5 centimeters. * By using a stopwatch and observing the oscillations of a floating ball, the student measures a frequency of 4 Hz. * If the student starts a wave in one part of a tank of water, how long will it take the wave to reach the opposite side of the tank 2 meters away?
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* Calculate the wave equation using graph paper model activity * Sine curve- draw 1,2,4,5,10, 20 waves – each wave has an amplitude of 2 blocks to crest and 2 blocks to trough. CALCULATE: * Frequency-period * wavelength * Wave speed
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