describe what is meant by wave motion as illustrated by vibration in ropes, springs and ripple tanks
understand and use the terms displacement, amplitude, phase difference, period, frequency, wavelength and speed
understand the use of the time-base and y-gain of a cathode-ray oscilloscope (CRO) to determine frequency and amplitude
derive, using the definitions of speed, frequency and wavelength, the wave equation v = f λ
recall and use v = f λ
understand that energy is transferred by a progressive wave
recall and use intensity = power/area and intensity ∝ (amplitude) 2 for a progressive wave
7.2 Transverse and longitudinal waves
compare transverse and longitudinal waves
analyse and interpret graphical representations of transverse and longitudinal waves
7.3 Doppler effect for sound waves
understand that when a source of sound waves moves relative to a stationary observer, the observed frequency is different from the source frequency (understanding of the Doppler effect for a stationary source and a moving observer is not required)
use the expression f ο = fs v /(v ± vs ) for the observed frequency when a source of sound waves moves relative to a stationary observer
7.4 Electromagnetic spectrum
state that all electromagnetic waves are transverse waves that travel with the same speed c in free space
recall the approximate range of wavelengths in free space of the principal regions of the electromagnetic spectrum from radio waves to γ-rays
recall that wavelengths in the range 400–700nm in free space are visible to the human eye
7.5 Polarisation
understand that polarisation is a phenomenon associated with transverse waves
recall and use Malus’s law (I = I0 cos2 θ ) to calculate the intensity of a plane polarised electromagnetic wave after transmission through a polarising filter or a series of polarising filters