polar and time, lapse varying in radial, coordinate

chart coordinates: $x^\tilde{\mu} = \{t, r, \phi\}$
chart coordinate basis: $e_\tilde{\mu} = \{e_{\tilde{t}}, e_{\tilde{r}}, e_{\tilde{\phi}}\}$
embedding coordinates: $u^I = \{t, x, y\}$
embedding basis $e_I = \{e_{t}, e_{x}, e_{y}\}$
transform from basis to coordinate:
${{{ \tilde{e}}_t}^t} = {1}$; ${{{ \tilde{e}}_r}^r} = {1}$; ${{{ \tilde{e}}_{\phi}}^{\phi}} = {1}$

transform from coorinate to basis:
${{{ \tilde{e}}^t}_t} = {1}$; ${{{ \tilde{e}}^r}_r} = {1}$; ${{{ \tilde{e}}^{\phi}}_{\phi}} = {1}$

tensor index associated with coordinate $t$ is index $t$ with operator $e_{t}(\zeta) = $${\partial \zeta}\over{\partial t}$
tensor index associated with coordinate $r$ is index $r$ with operator $e_{r}(\zeta) = $${\partial \zeta}\over{\partial r}$
tensor index associated with coordinate $\phi$ is index $\phi$ with operator $e_{\phi}(\zeta) = $${\partial \zeta}\over{\partial\phi}$

flat metric: ${{{ \eta}_t}_t} = {-1}$; ${{{ \eta}_x}_x} = {1}$; ${{{ \eta}_y}_y} = {1}$

chart in embedded coordinates:
${{ u}^t} = {{{t}} {{\alpha}}}$; ${{ u}^x} = {{{r}} {{cos\left( \phi\right)}}}$; ${{ u}^y} = {{{r}} {{sin\left( \phi\right)}}}$

basis operators applied to chart:
${{{ e}_u}^I} = {{{ u}^I}_{,u}}$
${{{ e}_t}^t} = {\alpha}$; ${{{ e}_r}^t} = {{{t}} {{{\partial \alpha}\over{\partial r}}}}$; ${{{ e}_r}^x} = {cos\left( \phi\right)}$; ${{{ e}_r}^y} = {sin\left( \phi\right)}$; ${{{ e}_{\phi}}^x} = {-{{{r}} {{sin\left( \phi\right)}}}}$; ${{{ e}_{\phi}}^y} = {{{r}} {{cos\left( \phi\right)}}}$
${{{ e}^t}_t} = {\frac{1}{\alpha}}$; ${{{ e}^t}_x} = {{\frac{1}{\alpha}}{({-{{{t}} {{{\partial \alpha}\over{\partial r}}} {{cos\left( \phi\right)}}}})}}$; ${{{ e}^t}_y} = {{\frac{1}{\alpha}}{({-{{{t}} {{{\partial \alpha}\over{\partial r}}} {{sin\left( \phi\right)}}}})}}$; ${{{ e}^r}_x} = {cos\left( \phi\right)}$; ${{{ e}^r}_y} = {sin\left( \phi\right)}$; ${{{ e}^{\phi}}_x} = {{\frac{1}{r}}{({-{sin\left( \phi\right)}})}}$; ${{{ e}^{\phi}}_y} = {{\frac{1}{r}}{({cos\left( \phi\right)})}}$
${{{{{ e}_u}^I}} {{{{ e}^v}_I}}} = {\overset{u\downarrow v\rightarrow}{\left[\begin{matrix} 1 & 0 & 0 \\ 0 & 1 & 0 \\ 0 & 0 & 1\end{matrix}\right]}}$
${{{{{ e}_u}^I}} {{{{ e}^u}_J}}} = {\overset{I\downarrow J\rightarrow}{\left[\begin{matrix} 1 & 0 & 0 \\ 0 & 1 & 0 \\ 0 & 0 & 1\end{matrix}\right]}}$
basis determinant: ${det(e)} = {{{\alpha}} \cdot {{r}}}$
${{{{ c}_a}_b}^c} = {0}$
${{{ g}_u}_v} = {{{{{{{ e}_u}^I}} {{{{ e}_v}^J}}}} {{{{ \eta}_I}_J}}}$
${{{ g}_t}_t} = {-{{\alpha}^{2}}}$; ${{{ g}_t}_r} = {-{{{\alpha}} \cdot {{t}} {{{\partial \alpha}\over{\partial r}}}}}$; ${{{ g}_r}_t} = {-{{{t}} {{{\partial \alpha}\over{\partial r}}} {{\alpha}}}}$; ${{{ g}_r}_r} = {{1} - {{{{t}^{2}}} {{{{\partial \alpha}\over{\partial r}}^{2}}}}}$; ${{{ g}_{\phi}}_{\phi}} = {{r}^{2}}$
${{{ g}_u}_v} = {{{{{{{ e}_u}^I}} {{{{ e}_v}^J}}}} {{{{ \eta}_I}_J}}}$
metric determinant: ${det(g)} = {-{{{{r}^{2}}} {{{\alpha}^{2}}}}}$
${{{{ \Gamma}_a}_b}_c} = {{{\frac{1}{2}}} {{({{{{{{{{{ g}_a}_b}_{,c}} + {{{{ g}_a}_c}_{,b}}} - {{{{ g}_b}_c}_{,a}}} + {{{{ c}_a}_b}_c}} + {{{{ c}_a}_c}_b}} - {{{{ c}_c}_b}_a}})}}}$
commutation coefficients: ${{{{ c}_a}_b}^c} = {0}$
metric: ${{{ g}_t}_t} = {-{{\alpha}^{2}}}$; ${{{ g}_t}_r} = {-{{{\alpha}} \cdot {{t}} {{{\partial \alpha}\over{\partial r}}}}}$; ${{{ g}_r}_t} = {-{{{t}} {{{\partial \alpha}\over{\partial r}}} {{\alpha}}}}$; ${{{ g}_r}_r} = {{1} - {{{{t}^{2}}} {{{{\partial \alpha}\over{\partial r}}^{2}}}}}$; ${{{ g}_{\phi}}_{\phi}} = {{r}^{2}}$
metric inverse: ${{{ g}^t}^t} = {\frac{{1} - {{{{t}^{2}}} {{{{\partial \alpha}\over{\partial r}}^{2}}}}}{-{{\alpha}^{2}}}}$; ${{{ g}^t}^r} = {{\frac{1}{\alpha}}{({-{{{t}} {{{\partial \alpha}\over{\partial r}}}}})}}$; ${{{ g}^r}^t} = {{\frac{1}{\alpha}}{({-{{{t}} {{{\partial \alpha}\over{\partial r}}}}})}}$; ${{{ g}^r}^r} = {1}$; ${{{ g}^{\phi}}^{\phi}} = {\frac{1}{{r}^{2}}}$
metric derivative: ${{{{ {\partial g}}_t}_t}_r} = {-{{{2}} {{\alpha}} \cdot {{{\partial \alpha}\over{\partial r}}}}}$; ${{{{ {\partial g}}_t}_r}_t} = {-{{{\alpha}} \cdot {{{\partial \alpha}\over{\partial r}}}}}$; ${{{{ {\partial g}}_t}_r}_r} = {-{{{t}} {{({{{{\partial \alpha}\over{\partial r}}^{2}} + {{{\alpha}} \cdot {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}}})}}}}$; ${{{{ {\partial g}}_r}_t}_t} = {-{{{{\partial \alpha}\over{\partial r}}} {{\alpha}}}}$; ${{{{ {\partial g}}_r}_t}_r} = {-{{{t}} {{({{{{\partial \alpha}\over{\partial r}}^{2}} + {{{\alpha}} \cdot {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}}})}}}}$; ${{{{ {\partial g}}_r}_r}_t} = {-{{{2}} {{t}} {{{{\partial \alpha}\over{\partial r}}^{2}}}}}$; ${{{{ {\partial g}}_r}_r}_r} = {-{{{2}} {{{t}^{2}}} {{{\partial \alpha}\over{\partial r}}} {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}}}$; ${{{{ {\partial g}}_{\phi}}_{\phi}}_r} = {{{2}} {{r}}}$
1st kind Christoffel: ${{{{ \Gamma}_t}_t}_r} = {-{{{\alpha}} \cdot {{{\partial \alpha}\over{\partial r}}}}}$; ${{{{ \Gamma}_t}_r}_t} = {-{{{\alpha}} \cdot {{{\partial \alpha}\over{\partial r}}}}}$; ${{{{ \Gamma}_t}_r}_r} = {-{{{t}} {{\alpha}} \cdot {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}}}$; ${{{{ \Gamma}_r}_t}_r} = {-{{{t}} {{{{\partial \alpha}\over{\partial r}}^{2}}}}}$; ${{{{ \Gamma}_r}_r}_t} = {-{{{t}} {{{{\partial \alpha}\over{\partial r}}^{2}}}}}$; ${{{{ \Gamma}_r}_r}_r} = {-{{{{t}^{2}}} {{{\partial \alpha}\over{\partial r}}} {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}}}$; ${{{{ \Gamma}_r}_{\phi}}_{\phi}} = {-{r}}$; ${{{{ \Gamma}_{\phi}}_r}_{\phi}} = {r}$; ${{{{ \Gamma}_{\phi}}_{\phi}}_r} = {r}$
connection coefficients / 2nd kind Christoffel: ${{{{ \Gamma}^t}_t}_r} = {{\frac{1}{\alpha}}{({{\partial \alpha}\over{\partial r}})}}$; ${{{{ \Gamma}^t}_r}_t} = {{\frac{1}{\alpha}}{({{\partial \alpha}\over{\partial r}})}}$; ${{{{ \Gamma}^t}_r}_r} = {{\frac{1}{\alpha}}{({{{t}} {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}})}}$; ${{{{ \Gamma}^t}_{\phi}}_{\phi}} = {{\frac{1}{\alpha}}{({{{t}} {{{\partial \alpha}\over{\partial r}}} {{r}}})}}$; ${{{{ \Gamma}^r}_{\phi}}_{\phi}} = {-{r}}$; ${{{{ \Gamma}^{\phi}}_r}_{\phi}} = {\frac{1}{r}}$; ${{{{ \Gamma}^{\phi}}_{\phi}}_r} = {\frac{1}{r}}$
connection coefficients derivative: ${{{{{ {\partial \Gamma}}^t}_t}_r}_r} = {\frac{{{{{\partial^ 2 \alpha}\over{\partial r^ 2}}} {{\alpha}}} - {{{\partial \alpha}\over{\partial r}}^{2}}}{{\alpha}^{2}}}$; ${{{{{ {\partial \Gamma}}^t}_r}_t}_r} = {\frac{{{{{\partial^ 2 \alpha}\over{\partial r^ 2}}} {{\alpha}}} - {{{\partial \alpha}\over{\partial r}}^{2}}}{{\alpha}^{2}}}$; ${{{{{ {\partial \Gamma}}^t}_r}_r}_t} = {{\frac{1}{\alpha}}{({{\partial^ 2 \alpha}\over{\partial r^ 2}})}}$; ${{{{{ {\partial \Gamma}}^t}_r}_r}_r} = {\frac{-{{{t}} {{({{{{{\partial \alpha}\over{\partial r}}} {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}} - {{{\alpha}} \cdot {{{\partial^ 3 \alpha}\over{\partial r^ 3}}}}})}}}}{{\alpha}^{2}}}$; ${{{{{ {\partial \Gamma}}^t}_{\phi}}_{\phi}}_t} = {{\frac{1}{\alpha}}{({{{{\partial \alpha}\over{\partial r}}} {{r}}})}}$; ${{{{{ {\partial \Gamma}}^t}_{\phi}}_{\phi}}_r} = {\frac{{{t}} {{({{{{{\alpha}} \cdot {{{\partial \alpha}\over{\partial r}}}} - {{{r}} {{{{\partial \alpha}\over{\partial r}}^{2}}}}} + {{{r}} {{\alpha}} \cdot {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}}})}}}{{\alpha}^{2}}}$; ${{{{{ {\partial \Gamma}}^r}_{\phi}}_{\phi}}_r} = {-{1}}$; ${{{{{ {\partial \Gamma}}^{\phi}}_r}_{\phi}}_r} = {-{\frac{1}{{r}^{2}}}}$; ${{{{{ {\partial \Gamma}}^{\phi}}_{\phi}}_r}_r} = {-{\frac{1}{{r}^{2}}}}$
connection coefficients squared: ${{{{{ {(\Gamma^2)}}^t}_t}_r}_r} = {\frac{{{\partial \alpha}\over{\partial r}}^{2}}{{\alpha}^{2}}}$; ${{{{{ {(\Gamma^2)}}^t}_r}_r}_t} = {\frac{{{\partial \alpha}\over{\partial r}}^{2}}{{\alpha}^{2}}}$; ${{{{{ {(\Gamma^2)}}^t}_r}_r}_r} = {\frac{{{{\partial \alpha}\over{\partial r}}} {{t}} {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}}{{\alpha}^{2}}}$; ${{{{{ {(\Gamma^2)}}^t}_r}_{\phi}}_{\phi}} = {{\frac{1}{\alpha}}{({{{t}} {{{\partial \alpha}\over{\partial r}}}})}}$; ${{{{{ {(\Gamma^2)}}^t}_{\phi}}_t}_{\phi}} = {{\frac{1}{\alpha}}{({-{{{{\partial \alpha}\over{\partial r}}} {{r}}}})}}$; ${{{{{ {(\Gamma^2)}}^t}_{\phi}}_r}_{\phi}} = {\frac{{{t}} {{r}} {{({{{{\partial \alpha}\over{\partial r}}^{2}} - {{{\alpha}} \cdot {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}}})}}}{{\alpha}^{2}}}$; ${{{{{ {(\Gamma^2)}}^t}_{\phi}}_{\phi}}_r} = {{\frac{1}{\alpha}}{({{{t}} {{{\partial \alpha}\over{\partial r}}}})}}$; ${{{{{ {(\Gamma^2)}}^r}_r}_{\phi}}_{\phi}} = {-{1}}$; ${{{{{ {(\Gamma^2)}}^r}_{\phi}}_{\phi}}_r} = {-{1}}$; ${{{{{ {(\Gamma^2)}}^{\phi}}_r}_r}_{\phi}} = {\frac{1}{{r}^{2}}}$; ${{{{{ {(\Gamma^2)}}^{\phi}}_{\phi}}_r}_r} = {\frac{1}{{r}^{2}}}$; ${{{{{ {(\Gamma^2)}}^{\phi}}_{\phi}}_{\phi}}_{\phi}} = {-{1}}$
Riemann curvature, $\sharp\flat\flat\flat$: ${{{{{ R}^a}_b}_c}_d} = {0}$
Riemann curvature, $\sharp\sharp\flat\flat$: ${{{{{ R}^a}^b}_c}_d} = {0}$
Ricci curvature, $\sharp\flat$: ${{{ R}^a}_b} = {0}$
Gaussian curvature: $0$
Einstein $\sharp\flat$ / trace-reversed Ricci curvature: ${{{ G}^a}_b} = {0}$
divergence: ${{{{ A}^i}_{,i}} + {{{{{{ \Gamma}^i}_i}_j}} {{{ A}^j}}}} = {{{\partial {A^{t}}}\over{\partial t}} + {{\partial {A^{r}}}\over{\partial r}} + {{\partial {A^{\phi}}}\over{\partial\phi}} + {{{{A^{r}}}} \cdot {{{\partial \alpha}\over{\partial r}}} {{\frac{1}{\alpha}}}} + {{{{A^{r}}}} \cdot {{\frac{1}{r}}}}}$
geodesic:
${\overset{a\downarrow}{\left[\begin{matrix} \ddot{t} \\ \ddot{r} \\ \ddot{\phi}\end{matrix}\right]}} = {\overset{a\downarrow}{\left[\begin{matrix} {{{-2}} {{\dot{r}}} \cdot {{\dot{t}}} \cdot {{{\partial \alpha}\over{\partial r}}} {{\frac{1}{\alpha}}}} + {{{-1}} {{r}} {{t}} {{{\partial \alpha}\over{\partial r}}} {{{\dot{\phi}}^{2}}} {{\frac{1}{\alpha}}}} + {{{-1}} {{t}} {{{\dot{r}}^{2}}} {{{\partial^ 2 \alpha}\over{\partial r^ 2}}} {{\frac{1}{\alpha}}}} \\ {{r}} {{{\dot{\phi}}^{2}}} \\ {{-2}} {{\dot{\phi}}} \cdot {{\dot{r}}} \cdot {{\frac{1}{r}}}\end{matrix}\right]}}$

parallel propagators:

${{[\Gamma_t]}} = {\left[\begin{matrix} 0 & {\frac{1}{\alpha}}{({{\partial \alpha}\over{\partial r}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & 0\end{matrix}\right]}$

$\int\limits_{{{t_L}}}^{{{t_R}}}d t\left( \left[\begin{matrix} 0 & {\frac{1}{\alpha}}{({{\partial \alpha}\over{\partial r}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & 0\end{matrix}\right]\right)$ = $\left[\begin{matrix} 0 & {\frac{1}{\alpha}}{({-{{{{\partial \alpha}\over{\partial r}}} {{({{{t_L}} - {{t_R}}})}}}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & 0\end{matrix}\right]$

${ P}_t$ = ${e}^{( -{({\int\limits_{{{t_L}}}^{{{t_R}}}d t\left( \left[\begin{matrix} 0 & {\frac{1}{\alpha}}{({{\partial \alpha}\over{\partial r}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & 0\end{matrix}\right]\right)})})}$ = $\left[\begin{matrix} 0 & {\frac{1}{\alpha}}{({{{{\partial \alpha}\over{\partial r}}} {{({{{t_L}} - {{t_R}}})}}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & 0\end{matrix}\right]$

${{ P}_t}^{-1}$ = ${e}^{({\int\limits_{{{t_L}}}^{{{t_R}}}d t\left( \left[\begin{matrix} 0 & {\frac{1}{\alpha}}{({{\partial \alpha}\over{\partial r}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & 0\end{matrix}\right]\right)})}$ = $\left[\begin{matrix} 0 & {\frac{1}{\alpha}}{({-{{{{\partial \alpha}\over{\partial r}}} {{({{{t_L}} - {{t_R}}})}}}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & 0\end{matrix}\right]$

${{[\Gamma_r]}} = {\left[\begin{matrix} {\frac{1}{\alpha}}{({{\partial \alpha}\over{\partial r}})} & {\frac{1}{\alpha}}{({{{t}} {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & \frac{1}{r}\end{matrix}\right]}$

$\int\limits_{{{r_L}}}^{{{r_R}}}d r\left( \left[\begin{matrix} {\frac{1}{\alpha}}{({{\partial \alpha}\over{\partial r}})} & {\frac{1}{\alpha}}{({{{t}} {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & \frac{1}{r}\end{matrix}\right]\right)$ = $\int\limits_{{{r_L}}}^{{{r_R}}}d r\left( \left[\begin{matrix} {\frac{1}{\alpha}}{({{\partial \alpha}\over{\partial r}})} & {\frac{1}{\alpha}}{({{{t}} {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & \frac{1}{r}\end{matrix}\right]\right)$

${ P}_r$ = ${e}^{( -{({\int\limits_{{{r_L}}}^{{{r_R}}}d r\left( \left[\begin{matrix} {\frac{1}{\alpha}}{({{\partial \alpha}\over{\partial r}})} & {\frac{1}{\alpha}}{({{{t}} {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & \frac{1}{r}\end{matrix}\right]\right)})})}$
negIntConn $-{({\int\limits_{{{r_L}}}^{{{r_R}}}d r\left( \left[\begin{matrix} {\frac{1}{\alpha}}{({{\partial \alpha}\over{\partial r}})} & {\frac{1}{\alpha}}{({{{t}} {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & \frac{1}{r}\end{matrix}\right]\right)})}$
negIntConn $-{({\int\limits_{{{r_L}}}^{{{r_R}}}d r\left( \left[\begin{matrix} {\frac{1}{\alpha}}{({{\partial \alpha}\over{\partial r}})} & {\frac{1}{\alpha}}{({{{t}} {{{\partial^ 2 \alpha}\over{\partial r^ 2}}}})} & 0 \\ 0 & 0 & 0 \\ 0 & 0 & \frac{1}{r}\end{matrix}\right]\right)})}$