$\Sigma F, a$ towards centre, $v$ tangential
- $F_{centrip} = {{mv^2} \over r} = {{4 \pi^2 rm} \over T^2}$
+ $\Sigma F = F_{centrip} = {{mv^2} \over r} = {{4 \pi^2 rm} \over T^2}=T \sin \theta = mg \tan \theta$
\includegraphics[height=4cm]{graphics/circ-forces.png}
% -----------------------
\subsection*{Vertical circular motion}
- $T =$ tension, e.g. circular pendulum
+ % $T =$ tension, e.g. circular pendulum
- $T+mg = {{mv^2}\over r}$ at highest point
+ $T+mg = {{mv^2}\over r}, v = \sqrt{rg}$ (top)
- $T-mg = {{mv^2} \over r}$ at lowest point
+ $T-mg = {{mv^2} \over r}, v = \sqrt{2rg}$ (bottom)
$E_K_{\text{bottom}}=E_K_{\text{top}}+mgh$
\item vertical component gravity: $a_y = -g$
\end{itemize}
- \begin{align*}
- v=\sqrt{v^2_x + v^2_y} \tag{vectors} \\
- h={{u^2\sin \theta ^2}\over 2g} \tag{max height}\\
- x=ut\cos\theta \tag{$\Delta x$ at $t$} \\
- y=ut \sin \theta-{1 \over 2}gt^2 \tag{height at $t$} \\
- t={{2u\sin\theta}\over g} \tag{time of flight}\\
- d={v^2 \over g}\sin \theta \tag{horiz. range} \\
- \end{align*}
+ % \begin{align*}
+ $v=\sqrt{v^2_x + v^2_y}$ \hfill vectors \\
+ $h={{u^2\sin \theta ^2}\over 2g}$ \hfill max height \\
+ $x=ut\cos\theta$ \hfill $\Delta x$ at $t$ \\
+ $y=ut \sin \theta-{1 \over 2}gt^2$ \hfill height at $t$ \\
+ $t={{2u\sin\theta}\over g}$ \hfill time of flight \\
+ $d={v^2 \over g}\sin \theta$ \hfill horiz. range \\
+ % \end{align*}
\includegraphics[height=3.2cm]{graphics/projectile-motion.png}
\item{Force-time: $A=\Delta \rho$}
\item{Force-disp: $A=W$}
\item{Force-ext: $m=k,\quad A=E_{spr}$}
- \item{Force-dist: $A=\Delta \operatorname{gpe}$}
+ \item{$F_g$-dist: $A=\Delta \operatorname{gpe}$}
\item{Field-dist: $A=\Delta \operatorname{gpe} / \operatorname{kg}$}
\end{itemize}
$x={2mg \over k}$
+ Vertical: $\Delta E = {1 \over 2}kx^2 + mgh
+
% -----------------------
\subsection*{Motion equations}
% -----------------------
\subsection*{Lorentz factor}
- $$\gamma = {1 \over {\sqrt{1-{v^2 \over c^2}}}}$$
+ $$\gamma = {1 \over {\sqrt{1-{v^2 \over c^2}}}}, \quad v = c\sqrt{1-{1 \over \gamma^2}}$$
$t=t_0 \gamma$ ($t$ longer in moving frame)
$m=m_0 \gamma$ (mass dilation)
- $$v = c\sqrt{1-{1 \over \gamma^2}}$$
-
% -----------------------
\subsection*{Energy and work}
\begin{itemize}
\item monopoles: lines towards centre
- \item dipoles: field lines $+ \rightarrow -$ or $\operatorname{N} \rightarrow \operatorname{S}$ (or perpendicular to wire)
+ \item dipoles: field lines $+ \rightarrow -$ or $\operatorname{N} \rightarrow \operatorname{S}$ (two magnets) or $\rightarrow$ N (single)
\item closer field lines means larger force
\item dot: out of page, cross: into page
\item +ve corresponds to N pole
+ \item Inv. sq. ${E_1 \over E_2} = ({r_2 \over r_1})^2$
\end{itemize}
\includegraphics[height=2cm]{graphics/field-lines.png}
\[{V_p \over V_s}={N_p \over N_s}={I_s \over I_p} \tag{xfmr coil ratios} \]
\textbf{Lenz's law:} $I_{\operatorname{emf}}$ opposes $\Delta \Phi$ \\
- (emf creates $I$ with associated field that opposes $\Delta \phi$)
+ (emf creates $I$ with associated field that opposes $\Delta \Phi$)
\textbf{Eddy currents:} counter movement within a field
\subsection*{Power transmission}
% \begin{align*}
- \[V_{\operatorname{rms}}={V_{\operatorname{p\rightarrow p}}\over \sqrt{2}} \]
+ \[V_{\operatorname{rms}}={V_{\operatorname{p}}\over \sqrt{2}}={V_{\operatorname{p\rightarrow p}}\over {2 \sqrt{2}}} \]
\[P_{\operatorname{loss}} = \Delta V I = I^2 R = {{\Delta V^2} \over R} \]
\[V_{\operatorname{loss}}=IR \]
% \end{align*}
\includegraphics[height=4cm]{graphics/dc-motor-2.png}
\includegraphics[height=3cm]{graphics/ac-motor.png} \\
- Force on current-carying wire, not copper \\
+ Force on I-carying wire, not Cu \\
$F=0$ for front & back of coil (parallel) \\
Any angle $> 0$ will produce force \\
% \end{wrapfigure}
% -----------------------
\subsection*{Polarisation}
\includegraphics[height=3.5cm]{graphics/polarisation.png} \\
- Reduces total amplitude (transverse only)
+ Transverse only. Reduces total $A$.
% -----------------------
\subsection*{Diffraction}
% \(\Delta x\) = fringe spacing \\
\(l\) = distance from source to observer\\
\(d\) = separation between each wave source (e.g. slit) \(=S_1-S_2\)
- \item diffraction $\propto {\lambda \over d}$
+ \item diffraction $\propto {\lambda \over d} \propto$ fringe spacing
+ \item $d(|\overrightarrow{S_1W}|-|\overrightarrow{S_2W}|)=d \Delta x = \lambda l$
\item significant diffraction when ${\lambda \over \Delta x} \ge 1$
- \item diffraction creates distortion (electron $>$ optical microscopes)
+ \item diffraction creates distortion (electron $\gt$ optical microscopes)
\end{itemize}
\subsection*{Refraction}
\includegraphics[height=3.5cm]{graphics/refraction.png}
- When a medium changes character, light is \emph{reflected}, \emph{absorbed}, and \emph{transmitted}
+ When a medium changes character, light is \emph{reflected}, \emph{absorbed}, and \emph{transmitted}. $\lambda$ changes, not $f$.
angle of incidence $\theta_i =$ angle of reflection $\theta_r$
\subsection*{Uncertainty principle}
- measuring location of an e- requires hitting it with a photon, but this causes $\rho$ to be transferred to electron, moving it.
+ $\Delta x \approx {\text{slit width} \over 2$}
+
+ measurement: $\rho$ transferred to e-\\ slit: possibility of diff. before slit
\subsection*{Wave-particle duality}
\end{multicols}
+\begin{center}
+ \includegraphics[height=2.95cm]{graphics/spectrum.png}
+\end{center}
+
\end{document}