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Dated 02/07/13 with 
{\bf THREE NEW CORRECTIONS}
where LATEST vector printout does not match postscript file.
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I {\bf new change: no subscript (calligraphic A) on integral.}

  {\bf correction: more space between Tr and Pexp} 

  {\bf NEW CORRECTION: in top equation superscripts 3 and 4 must be straight, not italic.}

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$V_K(t) = (t+t^3-t^4)(\sqrt{t}+\sqrt{t}^{\,-1})$
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$V_K(e^{2\pi i/(k+2)}) = \frac{1}{Z}\int
\left (\mbox{Tr Pexp}\oint_KA\right )e^{(ik/4\pi)CS(A)}\mathcal{D}A $
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II {\bf correction: last subscript is n, not m }
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$C_{ijk} \eta^{kl} C_{lmn} = C_{mjk} \eta^{kl} C_{lin}$
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III {\bf NEW CORRECTION: subscripts must all be straight, not italic}

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$R_{12} R_{23} R_{12} = R_{23} R_{12} R_{23}$
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IV
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{\it Equations for Lorenz attractor:} 
$$\frac{\ds dx}{\ds dt} = \sigma(y-x)$$
$$\frac{\ds dy}{\ds dt} = x(\rho-z) -y$$
$$\frac{\ds dz}{\ds dt} = xy - \beta z$$
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V {\bf correction: show difference between $v$ and $\nu$ greek nu ($v$'s have
subscripts)}

Note: we need to work on graphic
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$\p_t v_i + v_j \p_j v_i $
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$= -\p_i p + \nu \p_j \p_j v_i$
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VI {\bf new change: bold dx instead of d ``ell.''}

Note: we need to work on the graphic.
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$\int_{C_1}{\bf A}\cdot {\bf dx} - \int_{C_2}{\bf A}\cdot {\bf dx}
= \frac{1}{2\pi}\Phi$
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VII {\bf correction: center letter in second term is $\gamma$ (Greek gamma)
and not $r$.}

{\bf correction: last $\sigma$ is a SUBscript.}

{\bf correction: please find better calligraphic L, more like Palmer.}
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\noindent{\it Supergravity:}
$${\mathcal L}=R-\bar{\psi}_{\mu}\gamma^{\mu\rho\sigma}D_{\rho}\psi_{\sigma}$$
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VIII
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$r_S=2Gm/c^2$
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IX 
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$\chi = V - E + F$
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$2\pi\chi = \int_M K~dA$
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X. {\it Pythagoras:}
$$c^2 = a^2 + b^2$$
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XI. {\it Babylonian Tablet}
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XII. {\it Golden mean = partial fraction expansion:} {\bf NEW CORRECTION: in subscript of F, the
number 1 must be set straight.}

$$\lim_{n\rightarrow\infty}\frac{F_{n+1}}{F_n} = {1}+ \frac{\ds 1}{1+\dots} $$
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XIII. {\it Archimedes:}
$$v=\frac{2}{3}V$$
$$a=\frac{2}{3}A$$

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