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\begin{document}
 \parindent=0cm
\section*{Base point change}
Let $X$ be path-connected. For $x_0,x_1 \in X$, compare
$\pi_1(X,x_0)$ with $\pi_1(X,x_1)$. Choose a path $\rho$ from
$x_0$ to $x_1$ and define $\phi_{\rho} : \pi_1(X,x_0) \rightarrow
\pi_1(X,x_1)$ by $[\alpha] \mapsto [\overline{\rho}*\alpha*\rho]$.
Then {$\phi_{\rho}$ is an isomorphism.}\\

\begin{proof}

(1) $\phi_{\rho}$°¡ homomorphismÀÓÀ» º¸ÀÌÀÚ.

$\,\,\hspace{1em}\phi_{\rho}[\alpha * \beta]=[\overline{\rho}
* \alpha * \beta* \rho]$

$ \hspace{5.5em}=[ \overline{\rho} * \alpha * \rho *
\overline{\rho}* \beta * \rho]$

$ \hspace{5.5em}=[ \overline{\rho} * \alpha * \rho
][\overline{\rho}* \beta * \rho]$

$ \hspace{5.5em}=\phi_{\rho}[\alpha]\phi_{\rho}[\beta]$.\\


(2) Define $\phi_{\overline{\rho}} : \pi_1(X,x_1) \rightarrow
\pi_1(X,x_0)$ by $[\bet] \mapsto [\rho * \bet * \overline{\rho}]$.


Then,$(\phi_{\overline{\rho}} \circ \phi_{\rho})[\alpha]=
\phi_{\overline{\rho}}[\overline{\rho} * \alpha * \rho] =[\rho
* \overline{\rho}
* \alpha * \rho * \overline{\rho}] = [\alpha]$.\\
µû¶ó¼­ $\phi_{\overline{\rho}} \circ \phi_{\rho} = id$.\\



Similarly, $\phi_{\rho}\circ \phi_{\overline{\rho}}= id$.


\end{proof}\\


ÇÑÆí, ¶Ç´Ù¸¥ path $\sigma$°¡ ÁÖ¾îÁ³À»¶§  ¸¸ÀÏ $\rho \simeq \sigma$
À̶ó¸é  $\phi_{\rho}$ = $\phi_{\sigma}$ ÀÌ´Ù. \\



{\bf ¼÷Á¦ 2. }\\
ÀϹÝÀûÀ¸·Î homotopic ÇÏÁö ¾ÊÀº µÎ path ${\rho}$, ${\sigma}$¿¡
´ëÇØ\\
$\hspace*{11em}\,\,\,\phi_{\rho}$

$\hspace{7em}\pi_1(X,x_0)\rightarrow \pi_1(X,x_1)$

$\hspace{9em}\phi_{\sigma}\searrow \hspace{3em}\uparrow \mu$

$\hspace{12em}\pi_1(X,x_1)$

¿¡¼­ $\mu=\phi_{\rho}\circ\phi_{\sigma^{-1}}$ ·Î µÎ¸é ÀÌ´Â
isomorphism ÀÌ µÇ°í, ÀÌ°ÍÀº ¾î¶² loop¿¡ ÀÇÇÑ  conjugation (an
inner automorphism of $\pi_1(X,x_1))$ÀÌ µÊÀ» º¸¿©¶ó.

\end{document}