Split up the surface [tex]S[/tex] into three main components [tex]S_1,S_2,S_3[/tex], where
[tex]S_1[/tex] is the region in the plane [tex]y=0[/tex] bounded by [tex]x^2+z^2=1[/tex];
[tex]S_2[/tex] is the piece of the cylinder bounded between the two planes [tex]y=0[/tex] and [tex]x+y=2[/tex];
and [tex]S_3[/tex] is the part of the plane [tex]x+y=2[/tex] bounded by the cylinder [tex]x^2+z^2=1[/tex].
These surfaces can be parameterized respectively by
[tex]S_1:~\mathbf s_1(u,v)=\langle u\cos v,0,u\sin v\rangle[/tex]
where [tex]0\le u\le1[/tex] and [tex]0\le v\le2\pi[/tex],
[tex]S_2:~\mathbf s_2(u,v)=\langle\cos v,u,\sin v\rangle[/tex]
where [tex]0\le u\le2-\cos v[/tex] and [tex]0\le v\le2\pi[/tex],
[tex]S_3:~\mathbf s_3(u,v)=\langle u\cos v,2-u\cos v,u\sin v\rangle[/tex]
where [tex]0\le u\le1[/tex] and [tex]0\le v\le2\pi[/tex].
The surface integral of a function [tex]f(x,y,z)[/tex] along a surface [tex]R[/tex] parameterized by [tex]\mathbf r(u,v)[/tex] is given to be
[tex]\displaystyle\iint_Sf(x,y,z)\,\mathrm dS=\iint_Sf(\mathbf r(u,v))\left\|\frac{\partial\mathbf r(u,v)}{\partial u}\times\frac{\partial\mathbf r(u,v)}{\partial v}\right\|\,\mathrm du\,\mathrm dv[/tex]
Assuming we're just finding the area of the total surface [tex]S[/tex], we take [tex]f(x,y,z)=1[/tex], and split up the total surface integral into integrals along each component surface. We have
[tex]\displaystyle\iint_{S_1}\mathrm dS=\int_{u=0}^{u=1}\int_{v=0}^{v=2\pi}u\,\mathrm dv\,\mathrm du[/tex]
[tex]\displaystyle\iint_{S_1}\mathrm dS=\pi[/tex]
[tex]\displaystyle\iint_{S_2}\mathrm dS=\int_{v=0}^{v=2\pi}\int_{u=0}^{u=2-u\cos v}\mathrm du\,\mathrm dv[/tex]
[tex]\displaystyle\iint_{S_2}\mathrm dS=4\pi[/tex]
[tex]\displaystyle\iint_{S_3}\mathrm dS=\int_{u=0}^{u=1}\int_{v=0}^{v=2\pi}\sqrt2u\,\mathrm dv\,\mathrm du[/tex]
[tex]\displaystyle\iint_{S_3}\mathrm dS=\sqrt2\pi[/tex]
Therefore
[tex]\displaystyle\iint_S\mathrm dS=\left\{\iint_{S_1}+\iint_{S_2}+\iint_{S_3}\right\}\mathrm dS=(5+\sqrt2)\pi\approx20.151[/tex]
