they are caused by mechanical
vibrations in a substance
vibrations are PARALLEL to
the direction of travel
Human ears can hear frequencies
from 20Hz to 20,000Hz
the ability to hear higher
frequencies declines with age
Sound waves can be reflected to
produce ECHOES
Nota:
When calculating the distance of a reflecting surface from a person, remember that an echo goes there and back (divide by two)
E.G. Sound travels at 340m/s. A person hears an echo 0.4 seconds after shouting - how far away is the reflecting surface?
(340 x 0.4) = 136
136/2 = 68m
only hard, flat surfaces can
reflect sound
e.g. flat walls & floors
Soft objects/surfaces absorb sound
e.g. carpets, curtains & furniture
Sound waves can also be DIFFRACTED
the WAVELENGTH should be of the same order as the
size of the obstacle or gap that diffracts the waves
FREQUENCY
determines the PITCH of a sound
the higher the frequency
the higher the pitch
= the number of
vibrations each second
measured in Hertz (Hz)
AMPLITUDE
determines the LOUDNESS
(VOLUME) of a sound
the greater the amplitude, the
more energy the wave carries
and the louder the sound
the 'height' of the wave
OSCILLOSCOPE
a device used to display the shape
of an electrical wave
a short wavelength on the screen
corresponds to a high frequency
ULTRASOUND
waves with frequencies higher than
20,000Hz (20MHz)
non-ionising (safer than X-rays)
used for pre-natal scanning or to break down
kidney stones so that they could be removed
Ultrasound scanners use a transducer to
produce and detect ultrasound waves
Nota:
Again, the echoes are going there AND back, so the calculations will probably be halved again
pulses of ultrasound are directed into the body
they partially reflect from the tissue boundaries
the reflected pulses are detected by the transducer
s = v x t
distance (between interfaces in various media)
= wave speed x time taken