3.1 form 4 general wave properties
TRANSCRIPT
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WAVES
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What are waves? a wave is a disturbance that transfers energy
from place to place.
◦ Light energy moving from the computer screen
to your eye moves as light waves.
◦ Sound energy moving from a radio to your ear
moves as sound waves.
What carries waves? A medium, a medium is
the material through which a wave travels.
◦ Waves can move along ropes, strings or
across the surface of water & even some can
travel through space
Wave which move energy from place to place
are called progressive waves
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Waves are everywhere in nature
Examples of waves
◦ Sound waves,
◦ visible light waves,
◦ radio waves,
◦ microwaves,
◦ water waves,
◦ sine waves,
◦ telephone chord waves,
◦ stadium waves,
◦ earthquake waves,
◦ waves on a string,
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What causes waves?
Waves are created when
a source of energy
causes a medium to
vibrate.
A vibration is a repeated
back and forth or up
and down motion.
So, vibrating object is a
source of waves
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Wave Fronts Wave fronts are the lines or surfaces
connecting the particles moving at
the same phase and are at the same
distance from a wave source.
· Wave fronts are always perpendicular
to the direction of propagation.
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TYPES OF WAVESThere are two (2) types of waves: transverse and longitudinal
waves
1. Transverse waves
the vibrations are at a 90 degree angle to
the direction of travel of the wave.
n.a rasih/waves
Direction
Vibratio
ns
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n.a rasih/waves
Examples = electromagnetic waves, ripples on water,
waves on a rope, sine wave,
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Parts of a transverse wave
n.a rasih/waves
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2. Longitudinal waves
n.a rasih/waves
- In Longitudinal waves the vibrations are along the same
direction as the wave.
-Particles of the medium vibrate parallel to the direction of
propagation of the wave
- Example: sound waves & waves on a spring waves
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Parts of a longitudinal wave
A longitudinal wave, made up of compressions and rarefactions
- Compressions are areas where particles are close together
- Rarefactions - areas where particles are spread out.
The particles move in a direction that is parallel to the direction of
wave propagation.
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parts of a transverse waves
Wavelength ()
Amplitude (A)
Frequency (f)
Period (T)
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Wavelength Distance between two neighbouring peaks
(crests) or two neighbouring troughs on a distance graph
Distance of two neighbouring points which are vibrating together in same way (in phase)
Distance moved by the wave during one oscillation.
Waveform showing wavelength and amplitude
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Displacement & Amplitude
Displacement of a particle on a wave = its distance
from its rest/equilibrium position
◦ Vector quantity (+ve or –ve)
Amplitude = maximum displacement of a particle in the
wave
Represents the energy being transferred by the wave.
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Period & Frequency The period of a wave is the time for a
particle in the wave to make one
complete cycle/vibration.
The frequency of a wave is the number
of complete vibrations (cycles) per unit
time or in one second. Frequency is
measured in Hertz (Hz).
1 Hz = 1 cycle per second.
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Period (T) & Frequency (f) (cont)
Tf
1
The lower the frequency is the longer the time period
will be.
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Wave speed is measured in metres per second (m/s).
What is the formula for wave
speed?For any set of waves, the wave speed (v) can be calculated from the frequency (f)
and wavelength () using this formula:
What are the units of speed, frequency and wavelength?
Frequency is measured in hertz (Hz).
Wavelength is measured in metres (m).
wave speed = frequency x wavelength
v = f x
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x
A formula triangle helps you to rearrange a formula.
The formula triangle for wave speed (v), frequency (f) and wavelength ()
is shown below.
Cover the quantity that you are trying to work out, which gives the rearranged
formula needed for the calculation.
So to find frequency (f), cover
up f…
…which gives the
formula…
Can I use a formula triangle?
f =v
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Examples:
1. A wave has frequency of 50 Hz and a wavelength of 10 m. What is the speed of the wave?
solution : v = f λ
= ( 50x10)
= 500m/s
2. A wave has frequency of 5 Hz and a speed of 25 m/s. What is the wavelength of the wave?
solutions: λ = v /f
= (25/5)
= 5m
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Everyday life applications of waves.
Communication e.g Radio and TV waves.
You can cook with waves. e.g Microwaves.
Eels and snakes use transverse body
waves to push against the water or ground
to help them move.
Ultrasonic or high-frequency sound waves
have been used to clean jewelry and
teeth.
Burglar alarms can use the lazer light to
detect motion in a room.
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Exercise:
1. A wave with a frequency of 14 Hz has a wavelength of 3 meters. At what speed will this wave travel?
2. The speed of a wave is 65 m/sec. If the wavelength of the wave is 0.8 meters, what is the frequency of the wave?
3. A wave has a frequency of 46 Hz and a wavelength of 1.7 meters. What is the speed of this wave
4.If 120 waves are produced per minute ,find (a)frequency (b) the period
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1. A wave has a wavelength of 15 cm and has a
frequency of 10 waves/second. What is the
speed of the wave?
2.The speed of a wave on a rope is 50cm/s and
it’s wavelength is 10cm. What is it’s
frequency?
3.A wave is traveling with a velocity of 125m/s
and has a frequency of 20 waves/second.
What is the length of the wave?
Homework Questions
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Dangers of waves{tsunami
2004}
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WAVE EFFEECTS
- Waves can undergo reflection, refraction
and diffraction.
- The properties of waves can be investigated
using Ripple tanks
n.a rasih/waves
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n.a rasih/waves
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Waves transfer energy without
transferring matter.
Frequency= waves/time
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1. Reflection
- Reflection is the bouncing back of waves as they strike a barrier.
- The angle at which the waves strike the barrier is equal to the angle at which they leave the barrier.
n.a rasih/waves
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2. Refraction
- As waves move from one medium to
another, their speed and wavelength
changes.
- Frequency remains the same.
- Refraction is the bending of a wave
as it moves from one medium to
another as a result of change in wave
speed.n.a rasih/waves
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Refraction of water waves As water waves move
from shallow to deep
waters:
a. Wave speed increases,
b. Wavelength reduces
c. Frequency remains
unchanged.
As water waves move
from deep to shallow
waters:a. Wave speed reduces
b. Wavelength increases
c. Frequency remains
unchanged.
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Diffraction of water wavesDiffraction is the ability of waves to bend round the sides of an obstacle or
spread out as they pass through a gap.
When waves pass a barrier they curve around it slightly. When they pass through a
small opening, they spread out almost as if they had come from a point source. These
effects happen for any type of wave: water; sound; light; seismic waves, etc.
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