User:Craig Pemberton/Physics

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This page is a summary of the equations one might cover in an introductory physics course.

Where possible this list has avoided using any specific system of units. Axioms are in green, definitions are in blue, and theorems are black.

SI Prefixes[edit]

significand${\displaystyle \times 1000^{n}}$

Translation and rotation[edit]

time	${\displaystyle t}$	${\displaystyle t}$
mass	${\displaystyle m}$	${\displaystyle m}$
position	${\displaystyle x}$	${\displaystyle \theta }$
duration	${\displaystyle \Delta t}$	${\displaystyle \Delta t}$
displacement	${\displaystyle \Delta x}$	${\displaystyle \Delta \theta }$
conservation of mass	${\displaystyle \Delta m}$	${\displaystyle \Delta m}$
velocity	${\displaystyle v=dx/dt}$	${\displaystyle \omega =d\theta /dt}$
acceleration	${\displaystyle a=dv/dt}$	${\displaystyle \alpha =d\omega /dt}$
jerk	${\displaystyle j=da/dt}$	${\displaystyle j=d\alpha /dt}$
inertia	${\displaystyle {\color {blue}m=\int dm=\Sigma m_{i}}}$	${\displaystyle {\color {blue}I=\int r^{2}dm=\Sigma r^{2}m_{i}}}$
kinetic energy	${\displaystyle E_{k}=mv^{2}/2}$	${\displaystyle E_{k}=I\omega ^{2}/2}$
momentum	${\displaystyle P=mv}$	${\displaystyle L=I\omega }$
conservation of mass	${\displaystyle \Delta m=0}$	${\displaystyle \Delta m=0}$
conservation of energy	${\displaystyle \Delta E=0}$	${\displaystyle \Delta E=0}$
conservation of momentum	${\displaystyle \Delta P=0}$	${\displaystyle \Delta L=0}$
force	${\displaystyle {\color {blue}f=dP/dt}=ma=-dU/dx}$	${\displaystyle {\color {blue}\tau =dL/dt}=I\alpha }$ ${\displaystyle =\mathbf {r} \times \mathbf {f} }$
impulse	${\displaystyle {\color {blue}J=\int fdt}}$	${\displaystyle {\color {blue}J=\int \tau dt}}$
work	${\displaystyle {\color {blue}W=\int fdx}=\mathbf {f} \cdot \mathbf {d} }$	${\displaystyle {\color {blue}W=\int \tau d\theta }}$
power	${\displaystyle {\color {blue}P=dW/dt}=fv}$	${\displaystyle {\color {blue}P=dW/dt}=\tau \omega }$
Newton's Third Law	${\displaystyle f_{ab}=-f_{ba}}$	${\displaystyle \tau _{ab}=-\tau _{ba}}$

Equations for constant acceleration[edit]

displacement	${\displaystyle \Delta v=at}$	${\displaystyle \Delta \omega =\alpha t}$
time	${\displaystyle \Delta (v^{2})=2a\Delta x}$	${\displaystyle \Delta (\omega ^{2})=2\alpha \Delta \theta }$
acceleration	${\displaystyle \Delta x=t\Delta v/2}$	${\displaystyle \Delta \theta =t\Delta \omega /2}$
initial velocity	${\displaystyle \Delta x=-at^{2}/2+v_{2}t}$	${\displaystyle \Delta \theta =-\alpha t^{2}/2+\omega _{2}t}$
final velocity	${\displaystyle \Delta x=+at^{2}/2+v_{1}t}$	${\displaystyle \Delta \theta =+\alpha t^{2}/2+\omega _{1}t}$

Common forces[edit]

spring force, lies parallel to spring	${\displaystyle f_{k}=-kd}$
weight, points toward the centre of gravity	${\displaystyle f_{g}=-f_{n}=mg}$
tension, lies within the cord	${\displaystyle f_{t}=f}$
static friction maxiumum, lies tangent to the surface	${\displaystyle f_{s}=\mu _{s}f_{n}}$
kinetic friction, lies tangent to the surface	${\displaystyle f_{k}=\mu _{k}f_{n}}$
drag force, tangent to the path	${\displaystyle f_{d}=\mu _{d}\rho av^{2}/2}$

Mapping rotation to translation[edit]

centripetal force, points to the axis of rotation	${\displaystyle f_{c}=mv^{2}/r}$
angular to linear displacement	${\displaystyle x=\theta r}$
angular to linear speed	${\displaystyle v=\theta \omega }$
angular to linear acceleration tangential component	${\displaystyle a_{t}=\alpha r}$
angular to linear acceleration radial component	${\displaystyle a_{r}=\omega ^{2}r}$
angular to linear acceleration centripetal acceleration	${\displaystyle \alpha =v^{2}/r}$

Other[edit]

work done by a spring, positive when relaxes	${\displaystyle W_{s}=-k\Delta (x^{2})/2}$
inertial frames	${\displaystyle x_{PA}=x_{PB}+x_{AB}}$
	${\displaystyle v_{PA}=v_{PB}+v_{AB}}$
	${\displaystyle a_{PA}=a_{PB}+0}$
greatest distance	${\displaystyle 1/8}$ rotations
trajectory	${\displaystyle y=x\tan \theta -gx^{2}/(2V_{0}\cos \theta )^{2}}$
flight distance	${\displaystyle v_{0}^{2}\sin {2\theta }/g}$
flight time?	${\displaystyle T=2\pi r/v}$
terminal velocity	${\displaystyle v_{t}={\sqrt {2fg/(\mu _{d}\rho A)}}}$
elastic potential energy	${\displaystyle u(x)=kx^{2}/2}$
mechanical energy	${\displaystyle {\color {blue}E_{mec}=K+U}}$
work by type of energy	${\displaystyle W=\Delta E_{mec}+\Delta E_{th}+\Delta E_{int}}$
friction creates heat	${\displaystyle \Delta E_{th}=f_{k}d}$
center of mass COM	${\displaystyle \mathbf {r} _{com}=M^{-1}\Sigma m_{i}\mathbf {r} _{i}}$
	${\displaystyle x_{com}=M^{-1}\int xdm,\cdots }$
for constant density:	${\displaystyle x_{com}=V^{-1}\int xdV,\cdots }$
COM is in all planes of symmetry	${\displaystyle }$
elastic collision	${\displaystyle \Delta E_{k}=0}$
inelastic collision	${\displaystyle \Delta E_{k}=}$maximum
?	${\displaystyle \mathbf {P} _{1i}+\mathbf {P} _{2i}=\mathbf {P} _{1f}+\mathbf {P} _{2f}}$
system COM remains inert	${\displaystyle \mathbf {v} _{com}={(\mathbf {P} _{1i}+\mathbf {P} _{2i}) \over (M_{1}+M_{2})}=const}$
elastic collision, 1D, M2 stationary	${\displaystyle v_{1f}={(m_{1}-m_{2}) \over (m_{1}+m_{2})}v_{1i}}$
	${\displaystyle v_{2f}={(2m_{1}) \over (m_{1}+m_{2})}v_{1i}}$
first rocket equation,thrust	${\displaystyle t=Rv_{rel}=Ma}$
second rocket equation	${\displaystyle -v_{i}+v_{f}=v_{rel}ln(M_{i}/M_{f})}$
parallel axis theorem	${\displaystyle I=I_{com}+Mh^{2}}$
smooth rolling	${\displaystyle v_{com}=R\omega }$
	${\displaystyle x_{arc}=R\theta }$
	${\displaystyle x_{com}=R\alpha }$
down a ramp axis x	${\displaystyle a_{com,x}=-{\frac {g\sin \theta }{I_{com}/MR^{2}}}}$

Thermodynamics[edit]

irreversible	${\displaystyle }$
adiabatic	${\displaystyle \Delta Q=0}$
molecules	${\displaystyle N}$
temperature	${\displaystyle T}$
degrees of freedom	${\displaystyle f}$
linear expansion	${\displaystyle dL/dt=\alpha L}$
volume expansion	${\displaystyle dV/dt=3\alpha V}$
heat	${\displaystyle \Delta E_{Q}}$ due to ${\displaystyle \Delta T}$
heat capacity	${\displaystyle C_{th}=\Delta T/Q}$
specific heat	${\displaystyle c_{th}=m\Delta T/Q}$
heat of vaporization	${\displaystyle L_{v}=Q/m}$
heat of fusion	${\displaystyle L_{f}=Q/m}$
work due to gas expansion	${\displaystyle W=\int _{i}^{f}pdV}$
adiabatic	${\displaystyle \Delta E_{int}=W}$
constant volume	${\displaystyle \Delta E_{int}=Q}$
free expansion	${\displaystyle \Delta E_{int}=0}$
closed cycle	${\displaystyle Q+W=0}$
thermal conductivity	${\displaystyle \kappa }$
thermal resistance	${\displaystyle R=L/\kappa }$
conduction rate	${\displaystyle P_{cond}=A(T_{H}-T_{C})/(L/\kappa )=Q/t}$
steady state conduction through a composite slab	${\displaystyle P_{cond}=A(T_{H}-T_{C})/\Sigma (L/\kappa )}$
Stefan-Boltzmann constant	${\displaystyle \sigma =5.67*10^{-8}?}$
thermal radiation	${\displaystyle P_{rad}=\sigma \epsilon AT_{sys}^{4}}$
thermal absorption	${\displaystyle P_{rad}=\sigma \epsilon AT_{env}^{4}}$
Boltzmann Constant	${\displaystyle k=1.38\times 10^{-23}J/K}$
ideal gas law	${\displaystyle PV=kTN}$
work, constant temperature	${\displaystyle W=kTNln(V_{f}/V_{i})}$
work, constant volume	${\displaystyle W=0}$
work, constant pressure	${\displaystyle W=p\Delta V}$
translational energy	${\displaystyle E_{k,avg}=kTf/2}$
internal energy	${\displaystyle E_{int}=NkTf/2}$
mean speed	${\displaystyle v_{avg}={\sqrt {(kT/m)(8/\pi )}}}$
mode speed	${\displaystyle v_{prb}={\sqrt {(kT/m)2}}}$
root mean square speed	${\displaystyle v_{rms}={\sqrt {(kT/m)3}}}$
mean free path	${\displaystyle \lambda =1/({\sqrt {2}}\pi d^{2}N/V)}$?
Maxwell's Speed Distribution	${\displaystyle P(v)=4\pi (m/(2\pi kT))^{3/2}V^{2}e^{-(mv^{2}/(2kT))}}$
molecular specific heat at a constant volume	${\displaystyle C_{V}=Q/(N\Delta T)}$
?	${\displaystyle \Delta E_{int}=NC_{V}\Delta T}$
molecular specific heat at a constant pressure	${\displaystyle C_{p}=Q/(N\Delta T)}$
?	${\displaystyle W=p\Delta V=Nk\Delta T}$
?	${\displaystyle k=C_{p}-C_{V}}$
adiabatic expansion	${\displaystyle pV^{\gamma }=constant}$
adiabatic expansion	${\displaystyle TV^{\gamma -1}=constant}$
four special processes on page 529	${\displaystyle }$
multiplicity of configurations	${\displaystyle W=N!/n_{1}!n_{2}!}$
microstate in one half of the box	${\displaystyle n_{1},n_{2}}$
Boltzmann's entropy equation	${\displaystyle S=klnW}$
entropy	${\displaystyle {\color {blue}S=-k\sum _{i}P_{i}\ln P_{i}\!}}$
change in entropy	${\displaystyle \Delta S=\int _{i}^{f}(1/T)dQ\approx Q/T_{avg}}$
change in entropy	${\displaystyle \Delta S=kNln(V_{f}/V_{i})+NC_{V}ln(T_{f}/T_{i})}$
force due to entropy	${\displaystyle f=-Tds/dx}$
engine efficiency	${\displaystyle \epsilon =|W|/|Q_{H}|}$
Carnot engine efficiency	${\displaystyle \epsilon _{c}=(|Q_{H}|-|Q_{L}|)/|Q_{H}|=(T_{H}-T_{L})/T_{H}}$
refrigerator performance	${\displaystyle K=|Q_{L}|/|W|}$
Carnot refrigerator performance	${\displaystyle K_{C}=|Q_{L}|/(|Q_{H}|-|Q_{L}|)=T_{L}/(T_{H}-T_{L})}$
Zeroth Law of Thermodynamics	temperature is an equivalence relation
First Law of Thermodynamics	${\displaystyle \Delta E_{int}=Q+W}$
Second Law of Thermodynamics	${\displaystyle \Delta S\geq 0}$
Third Law of Thermodynamics	${\displaystyle S=S_{structural}+CT}$

Waves[edit]

phasor	${\displaystyle }$
node	${\displaystyle }$
antinode	${\displaystyle }$
period	${\displaystyle T}$
amplitude	${\displaystyle x_{m}}$
decibel	${\displaystyle dB}$
torsion constant	${\displaystyle \kappa =-\tau /\theta }$
amplitude	${\displaystyle x_{m}}$
frequency	${\displaystyle f=1/T=\omega /(2\pi )}$
angular frequency	${\displaystyle \omega =2\pi f=2\pi /T}$
phase angle	${\displaystyle \phi }$
phase	${\displaystyle (\omega t+\phi )}$
damping constant	${\displaystyle b}$
damping force	${\displaystyle f_{d}=-bv}$
phase	${\displaystyle ky-\omega t}$
angular wave number	${\displaystyle k}$
phase constant	${\displaystyle \phi }$
linear density	${\displaystyle \mu }$
harmonic number	${\displaystyle n}$
harmonic series	${\displaystyle f=v/\lambda =nv/(2L)}$
wavelength	${\displaystyle \lambda =k/(2\pi )}$
bulk modulus	${\displaystyle B=\Delta p/(\Delta V/V)}$
path length difference	${\displaystyle \Delta L}$
resonance	${\displaystyle \omega _{d}=\omega }$
phase difference	${\displaystyle \phi =2\pi \Delta L/\lambda }$
fully constructive interference	${\displaystyle \Delta L/\lambda =n}$
fully destructive interference	${\displaystyle \Delta L/\lambda =n+0.5}$
intensity	${\displaystyle I=P/A=\rho v\omega ^{2}s_{m}^{2}/2}$
source power	${\displaystyle P_{s}}$
sound intensity by distance	${\displaystyle I=P_{s}/(4\pi r^{2})}$
standard reference intensity	${\displaystyle I_{0}}$
sound level	${\displaystyle \mathrm {B} =(10dB)log(I/I_{0})}$
pipe, two open ends	${\displaystyle f=v/\lambda =nv/(2L)}$
pipe, one open end	${\displaystyle f=v/\lambda =nv/(4L)}$ for n odd
beats	${\displaystyle s(t)=[2s_{m}\cos \omega 't]\cos \omega t}$
beat frequency	${\displaystyle f_{beat}=f_{1}-f_{2}}$
Doppler effect	${\displaystyle f'=f(v+-v_{D})/(v+-v_{S})}$
Mach cone angle	${\displaystyle \sin \theta =v/v_{s}}$
average wave power	${\displaystyle P_{avg}=\mu v\omega ^{2}x_{m}^{2}/2}$
pressure amplitude	${\displaystyle \Delta p_{m}=(v\rho \omega )x_{m}}$
wave equation	${\displaystyle {\frac {\partial y}{\partial x^{2}}}={\frac {1}{v^{2}}}{\frac {\partial ^{2}y}{\partial t^{2}}}}$
wave superposition	${\displaystyle x'(y,t)=x_{1}(y,t)+x_{2}(y,t)}$
wave speed	${\displaystyle v=\omega /k=\lambda /T=\lambda f}$
wave speed on a stretched string	${\displaystyle v={\sqrt {f_{t}/\mu }}}$
angular frequency of a linear simple harmonic oscillator	${\displaystyle \omega ={\sqrt {k/m}}}$
angular frequency of an angular simple harmonic oscillator	${\displaystyle \omega ={\sqrt {I/\kappa }}}$
angular frequency of a low amplitude simple pendulum	${\displaystyle \omega ={\sqrt {L/g}}}$
angular frequency of a low amplitude physical pendulum	${\displaystyle \omega ={\sqrt {I/mgh}}}$
speed of sound	${\displaystyle v={\sqrt {B/\rho }}}$
damped angular frequency	${\displaystyle \omega '={\sqrt {(k/m)-(b^{2}/4m^{2})}}}$
displacement	${\displaystyle x(t)=\cos(\omega t+\phi )x_{m}}$
damped displacement	${\displaystyle x(t)=\cos(\omega 't+\phi )x_{m}(e^{-bt/2m})}$
velocity	${\displaystyle v(t)=\sin(\omega t+\phi )x_{m}(-\omega )}$
acceleration	${\displaystyle a(t)=\cos(\omega t+\phi )x_{m}(-\omega ^{2})}$
transverse sinusoidal wave	${\displaystyle x(y,t)=\sin(ky-\omega t)x_{m}}$
wave travelling backwards	${\displaystyle x(y,t)=\sin(ky+\omega t)x_{m}}$
resultant wave	${\displaystyle x'(y,t)=\sin(ky-\omega t+\phi /2)x_{m}(2\cos \phi /2)}$
standing wave	${\displaystyle x'(y,t)=\cos(\omega t)(2y\sin ky)}$
sound displacement function	${\displaystyle x(y,t)=\cos(ky-\omega t)x_{m}}$
sound pressure-variation function	${\displaystyle \Delta p(y,t)=\sin(ky-\omega t)\Delta p_{m}}$
potential harmonic energy	${\displaystyle E_{U}(t)=kx^{2}/2=kx_{m}^{2}\cos ^{2}(\omega t+\phi )/2}$
kinetic harmonic energy	${\displaystyle E_{K}(t)=kx^{2}/2=kx_{m}^{2}\sin ^{2}(\omega t+\phi )/2}$
total harmonic energy	${\displaystyle E(t)=kx_{m}^{2}/2=E_{U}+E_{K}}$
damped mechanical energy	${\displaystyle E_{mec}(t)=ke^{-bt/m}x_{m}^{2}/2}$

Gravitation[edit]

gravity	${\displaystyle f_{G}=Gm_{1}m_{2}/r^{2}}$
potential energy	${\displaystyle E_{G}=-Gm_{1}m_{2}/r}$
potential energy	${\displaystyle E_{g}=ma_{g}y}$
standard gravity	${\displaystyle {\color {blue}a_{g}=Gm_{Earth}/r_{Earth}^{2}}\approx 9.81m/s^{2}}$
${\displaystyle Wg=mgd\cos \theta }$
?	${\displaystyle \Delta k=W_{lift}+W_{g}}$
potential work	${\displaystyle \Delta u=-W}$
understand path independence	${\displaystyle W_{ab,1}=W_{ab,2}=\cdots }$
?	${\displaystyle W_{pull}=-W_{s}}$

Electricity[edit]

electric constant	${\displaystyle \epsilon _{0}F/m}$
electrostatic constant	${\displaystyle k=1/(4\pi \epsilon _{0})m/F}$
Coulomb's law	${\displaystyle F=k|q_{1}||q_{2}|/r^{2}}$
elementary charge	${\displaystyle e}$ in Coloumbs
electric charge	${\displaystyle q=ne}$ for integer n
conservation of charge	${\displaystyle \Delta e=0}$
test charge	${\displaystyle q_{0}}$
electric field	${\displaystyle \mathbf {E} =\mathbf {F} /q_{0}}$
electric field of a point charge	${\displaystyle \mathbf {E} q=\mathbf {F} }$
electric field lines	end at a negative charge
r hat?	${\displaystyle {\hat {r}}}$
electric field of a point charge	${\displaystyle \mathbf {E} =\mathbf {F} /q_{0}=(1/(\epsilon _{0}4\pi ))q/r^{2}{\hat {r}}}$
electric dipole moment	${\displaystyle \mathbf {p} }$
?	${\displaystyle z}$
electric field of a dipole moment	${\displaystyle E=(1/(\epsilon _{0}2\pi ))(p/z^{3})}$
electric field of a charged ring	${\displaystyle E=qz/(\epsilon _{0}4\pi (z^{2}+R^{2})^{(}3/2)}$
surface charge density	${\displaystyle \sigma =Q/A}$
electric field of a charged disk	${\displaystyle E=(\sigma /\epsilon _{0}2)(1-z/{\sqrt {z^{2}+R^{2}}})}$
torque on a dipole	${\displaystyle \mathbf {\tau } =\mathbf {p} \times \mathbf {E} }$
potential energy of a dipole	${\displaystyle U=-\mathbf {p} \cdot \mathbf {E} }$
work done on a dipole	${\displaystyle W_{a}=-W=\Delta U}$
Gaussian surface	?
flux	?
?	${\displaystyle \mathbf {A} }$
electric flux	${\displaystyle \Phi =\oint \mathbf {E} \cdot d\mathbf {A} }$
Gauss' law	${\displaystyle q_{enc}=\epsilon _{0}\Phi }$
Gauss' law	${\displaystyle q_{enc}=\epsilon _{0}\oint \mathbf {E} \cdot d\mathbf {A} }$
volume charge density	${\displaystyle \rho =Q/V}$
linear charge density	${\displaystyle \lambda =Q/L}$
acceleration due to charge	${\displaystyle a=qE/m}$
conducting surface	${\displaystyle E=\sigma /\epsilon _{0}}$
electric field of a line of charge	${\displaystyle E=\lambda /\epsilon _{0}2\pi r}$
non-conducting sheet of charge	${\displaystyle E=\sigma /\epsilon _{0}2}$
electric field outside spherical shell r>=R	${\displaystyle E=q/\epsilon _{0}4\pi r^{2}}$
electric field inside spherical shell r<R	${\displaystyle E=0}$
electric field of uniform charge r<=R	${\displaystyle E=qr/\epsilon _{0}4\pi R^{3}}$
electric potential energy	${\displaystyle U}$
Work done by electric potential energy	${\displaystyle \Delta U=-W}$
finite potential energy of the system	${\displaystyle U-W_{\infty }}$
electric potential	${\displaystyle V=U/q}$
electric potential difference	${\displaystyle \Delta V=\Delta U/q=-W/q}$
potential defined	${\displaystyle V=-W_{\infty }/q}$
potential from the electric field	${\displaystyle \Delta V=-\int _{i}^{f}\mathbf {E} \cdot d\mathbf {s} }$
potential of a point charge	${\displaystyle V=q/\epsilon _{0}4\pi r}$
potential of a point charge group	${\displaystyle V=\Sigma V_{i}=(1/\epsilon _{0}4\pi )\Sigma q_{i}/r_{i}}$
potential of a dipole	${\displaystyle V=p\cos \theta /\epsilon _{0}4\pi r^{2}}$
potential of continuous charge	${\displaystyle V=\int dV=(1/\epsilon _{0}4\pi )\int dq/r}$
field from potential	${\displaystyle \mathbf {E} =\nabla V}$
potential of a pair of point charges	${\displaystyle U=W=q_{2}V=q_{1}q_{2}/\epsilon _{0}4\pi r}$
capacitance	${\displaystyle C=q/V}$
parallel plate capacitor	${\displaystyle C=\epsilon _{0}A/d}$
cylindrical capacitor	${\displaystyle C=\epsilon _{0}2\pi L/\ln(b/a)}$
spherical capacitor	${\displaystyle C=\epsilon _{0}4\pi ba/(b-a)}$
isolated spherical capacitor	${\displaystyle C=\epsilon _{0}4\pi R}$
parallel capacitors	${\displaystyle C_{eq}=\Sigma C_{i}}$
series capacitors	${\displaystyle 1/C_{eq}=\Sigma 1/C_{i}}$
potential energy stored in a capacitor	${\displaystyle U=q^{2}/2C=CV^{2}/2}$
energy density	${\displaystyle u=\epsilon _{0}E^{2}/2}$
dielectric constant	${\displaystyle \kappa \geq 1}$
dimensions of capacitance	${\displaystyle C=\epsilon _{0}{\mathcal {L}}}$
dielectric	${\displaystyle \epsilon _{0}\to \epsilon _{0}\kappa }$
Gauss' law with dialectric	${\displaystyle q=\epsilon _{0}\oint \kappa \mathbf {E} \cdot d\mathbf {A} }$
electric displacement	${\displaystyle \mathbf {D} =\epsilon _{0}\kappa \mathbf {E} }$
current	${\displaystyle i=dq/dt}$
charge density	${\displaystyle \mathbf {J} =i/A}$
?	${\displaystyle i=\int JdA}$
drift speed	${\displaystyle \mathbf {v} _{d}}$
?	${\displaystyle \mathbf {J} =ne\mathbf {v} _{d}/m^{3}}$
resistance	${\displaystyle R=V/i}$
resistivity in ohm-meters	${\displaystyle \rho =\mathbf {E} /\mathbf {J} }$
conductivity	${\displaystyle \sigma =\mathbf {J} /\mathbf {E} =1/\rho }$
?	${\displaystyle R/\rho =L/A}$
variation of resistivity with temperature	${\displaystyle \rho -\rho _{0}=\rho _{0}\alpha (T-T_{0})}$
temperature coefficient of resistivity	${\displaystyle \alpha }$
Ohm's law	${\displaystyle V=iR}$
electrical power	${\displaystyle P=iV}$
resistive dissipation	${\displaystyle P=i^{2}R=V^{2}/R}$
emf	${\displaystyle {\mathcal {E}}=dW/dq=iR}$
rules for calculating emf	loop, resistance, emf
internal resistance	${\displaystyle i={\mathcal {E}}/(R+r)}$
resistors in series	${\displaystyle R_{eq}=\Sigma R_{i}}$
resistors in parallel	${\displaystyle 1/R_{eq}=1/\Sigma R_{i}}$
potential difference across a real battery	${\displaystyle p={\mathcal {E}}-iR}$
power of an emf device	${\displaystyle P_{emf}=i{\mathcal {E}}}$
Kirchoff's junction rule	${\displaystyle i_{in}=i_{out}}$
RC charging a capacitor	${\displaystyle q=C{\mathcal {E}}(1-e^{-t/RC}}$
RC charging a capacitor	${\displaystyle i=({\mathcal {E}}/R)e^{-t/RC}}$
RC charging a capcitor	${\displaystyle V_{C}={\mathcal {E}}(1-e^{-t/RC}}$
capacitive time constant	${\displaystyle \tau =RC}$
magnetic field	${\displaystyle \mathbf {F} _{B}=q\mathbf {v} \times \mathbf {B} }$
Hall effect	${\displaystyle n=Bi/Vle}$
circulating charged particle	${\displaystyle |q|vB=mv^{2}/r}$
cyclotron resonance condition	${\displaystyle f=f_{osc}}$
force on a current	${\displaystyle \mathbf {F} _{B}=i\mathbf {L} \times \mathbf {B} }$
magnetic moment	${\displaystyle \mu =NiA}$
magnetic dipole torque	${\displaystyle \mathbf {\tau } =\mathbf {\mu } \times \mathbf {B} }$
magnetic potential energy	${\displaystyle U(\theta )=-\mathbf {\mu } \cdot \mathbf {B} }$
magnetism constant	${\displaystyle \mu _{0}}$, in Tm/A
Biot-Savart law	${\displaystyle d\mathbf {B} =(\mu _{0}/4\pi )(id\mathbf {s} \times {\hat {r}}/r^{2})}$
magnetic field due to a long straight wire	${\displaystyle B=\mu _{0}i/2\pi R}$
magnetic field due to a semi-infinite straight wire	${\displaystyle B=\mu _{0}i/4\pi R}$
magnetic field at the center of a circular arc	${\displaystyle B=\mu _{0}i\phi /4\pi R}$
Ampere's law	${\displaystyle \oint \mathbf {B} \cdot d\mathbf {s} =\mu _{0}i_{enc}}$
ideal solenoid	${\displaystyle B=\mu _{0}in}$
toroid	${\displaystyle B=\mu _{0}iN/2\pi r}$
current carrying coil	${\displaystyle \mathbf {B} =\mu _{0}\mathbf {\mu } /2\pi z^{3}}$
magnetic flux through A	${\displaystyle \Phi _{B}=\int \mathbf {B} \cdot d\mathbf {A} }$
?	${\displaystyle \Phi _{B}=BA}$
Faraday's law	${\displaystyle {\mathcal {E}}=d\Phi _{B}/dt}$
Lenz's law	${\displaystyle ?}$
Faraday's law	${\displaystyle \oint \mathbf {E} \cdot d\mathbf {s} =-d\Phi _{B}/dt}$
inductance	${\displaystyle L=N\Phi _{B}/i}$
solenoid	${\displaystyle L/l=\mu _{0}n^{2}A}$
self-induced emf	${\displaystyle {\mathcal {E}}_{L}=-Ldi/dt}$
RL circuit	${\displaystyle Ldi/dt+Ri={\mathcal {E}}}$
RL circuit rise of current	${\displaystyle i={\mathcal {E}}/R(1-e^{-t/\tau _{L}})}$
RL circuit time constant	${\displaystyle \tau _{L}=L/R}$
RL circuit decay of current	${\displaystyle i={\mathcal {E}}e^{-t/\tau _{L}}/R=i_{0}e^{-t/\tau _{L}}}$
magnetic energy	${\displaystyle U_{B}=Li^{2}/2}$
magnetic energy density	${\displaystyle u_{B}=B^{2}/2\mu _{0}}$
mutual induction	${\displaystyle {\mathcal {E}}_{1}=-Mdi_{2}/dt,{\mathcal {E}}_{2}=-Mdi_{1}/dt}$
LC circuit	${\displaystyle \omega =1/{\sqrt {LC}}}$
LC oscillations	${\displaystyle Ld^{2}q/dt^{2}+q/C=0}$
LC charge	${\displaystyle q=Qcos(\omega t+\phi )}$
LC current	${\displaystyle i=-\omega Qsin(\omega t+\phi )}$
LC electrical energy	${\displaystyle U_{E}=q^{2}/2C=Q^{2}cos^{2}(\omega t+\phi )/2C}$
[[]]	${\displaystyle U_{B}=Q^{2}sin^{2}(\omega t+\phi )/2C}$
RLC circuit ODE	${\displaystyle Ld^{2}/q/dt^{2}+Rdq/dt+q/C=0}$
RLC circuit ODE solution	${\displaystyle q=QeT^{-Rt/2L}cos(\omega 't+\phi )}$
resistive load	${\displaystyle V_{R}=I_{R}R}$
capacitive reactance	${\displaystyle X_{C}=1/\omega _{d}C}$
capacitive load	${\displaystyle V_{C}=I_{C}X_{C}}$
inductive reactance	${\displaystyle X_{L}=\omega _{d}L}$
inductive load	${\displaystyle V_{L}=I_{L}X_{L}}$
phase constant	${\displaystyle tan\phi =X_{L}-X_{C}/R}$
electromagnetic resonance	${\displaystyle \omega _{d}=\omega =1/{\sqrt {LC}}}$
rms current	${\displaystyle I_{rms}=I/{\sqrt {2}}}$
rms voltage	${\displaystyle V_{rms}=V/{\sqrt {2}}}$
rms emf	${\displaystyle {\mathcal {E}}_{rms}={\mathcal {E}}_{m}/{\sqrt {2}}}$
average power	${\displaystyle P_{avg}={\mathcal {E}}I_{rms}cos\phi }$
transformation of voltage	${\displaystyle V_{s}N_{p}=V_{p}N_{s}}$
transformation of currents	${\displaystyle I_{s}N_{s}=I_{p}N_{p}}$
transformer reistance	${\displaystyle R_{e}q=(Np/Ns)^{2}R}$
Gauss' law for magnetic fields	${\displaystyle \Phi _{B}=\oint \mathbf {B} \cdot d\mathbf {A} =0}$
Maxwell's law of induction	${\displaystyle \oint \mathbf {B} /cdotd\mathbf {s} =\mu _{0}\epsilon _{0}d\Phi _{E}/dt}$
Ampere-Maxwell law	${\displaystyle \oint \mathbf {B} \cdot d\mathbf {s} =\mu _{0}\epsilon _{0}d\Phi _{E}/dt+\mu _{0}i_{enc}}$
displacement current	${\displaystyle i_{d}=\epsilon _{0}d\Psi _{E}/dt}$
Ampere-Maxwell law	${\displaystyle \oint \mathbf {B} \cdot d\mathbf {s} =\mu _{0}i_{d,enc}+\mu _{0}i_{enc}}$
induced magnetic field inside a circular capacitor	${\displaystyle B=(\mu _{0}i_{d}/2\pi R^{2})r}$
induced magnetic field outside a circular capacitor	${\displaystyle B=\mu _{0}i_{d}/2\pi rr}$
spin magnetic dipole moment	${\displaystyle \mathbf {\mu _{s}} =-e\mathbf {S} /m}$
Bohr magneton	${\displaystyle \mu _{B}=eh/4\pi m}$
?	${\displaystyle U=-\mathbf {\mu } _{s}\cdot \mathbf {B} _{ext}=-\mu _{s,z}B_{ext}}$
orbital magnetic dipole moment	${\displaystyle \mathbf {\mu } _{orb}=-e\mathbf {L} _{o}rb/2m}$
?	${\displaystyle U=-\mathbf {\mu } _{orb}\cdot \mathbf {B} _{ext}=-\mu _{orb,z}B_{ext}}$