Below is a list of the equations that you are not given in the formula booklet in your examinations.

The formula booklet itself can be found by clicking here.

Module 2 – Foundations of Physics

• Converting units
• Percentage uncertainties

Module 3

• $F = ma$
• $W = mg$
• $E_{k} = \frac{1}{2}mv^{2}$
• $E_{p} = mgh$
• $Impulse = F \Delta t$

Module 4

• $eV = \frac{1}{2}mv^{2}$
• $R = \frac{V}{I}$
• $W = IVt$
• $kWh = kW's \ \times \ hrs$
• $d sin \theta = n \lambda$
• Standing Waves:
Closed at both ends: $L = \frac{n}{2 \lambda}$
Open one end and closed at the other: $L = \frac{2n-1}{4 \lambda}$
• $eV = \frac{hc}{\lambda}$

Module 5

• $T(K) \approx \Theta (^{o}C) \ + \ 273$
• $PV = constant$ (Boyle’s law)
$\frac{P}{T} = constant$ (Gay-Lussac’s law)
• Boltzmann Constant, $k = \frac{R}{N_{A}}$
• From $v = \pm \omega \sqrt{A^{2}-x^{2}}$ , $v_{max} = \omega A$
• Gravitational potential energy $E = mV_{g} = -\frac{GMm}{r}$
• $hf = \Delta E$ and $\frac{hc}{\lambda} = \Delta E$

Module 6

• $\epsilon = \epsilon_{r}\epsilon_{0}$
• $d \rightarrow u + \ ^{0}_{-1}e + \bar{\nu}$
• $u \rightarrow d + \ ^{0}_{+1}e + \nu$

Please comment below if you feel I have missed something and I will resolve it.