Differentialform/Äußere Ableitung/Rückzug/Berechung/Aufgabe/Lösung

Es ist
${}d\omega =d{\left(ydx+zdy+xdz\right)}=dy\wedge dx+dz\wedge dy+dx\wedge dz=-dx\wedge dy-dy\wedge dz+dx\wedge dz\,.$
Es ist
${}{\begin{aligned}\varphi ^{*}\omega &=v^{2}du^{2}+uvdv^{2}+u^{2}duv\\&=2v^{2}udu+2uv^{2}dv+u^{2}(udv+vdu)\\&={\left(2uv^{2}+u^{2}v\right)}du+{\left(2uv^{2}+u^{3}\right)}dv.\end{aligned}}$
Es ist
${}{\begin{aligned}d{\left({\left(2uv^{2}+u^{2}v\right)}du+{\left(2uv^{2}+u^{3}\right)}dv\right)}&=d{\left(2uv^{2}+u^{2}v\right)}du+d{\left(2uv^{2}+u^{3}\right)}dv\\&={\left(4uv+u^{2}\right)}dv\wedge du+{\left(2v^{2}+3u^{2}\right)}du\wedge dv\\&={\left(-4uv+2v^{2}+2u^{2}\right)}du\wedge dv.\end{aligned}}$
Der Rückzug ${}\varphi ^{*}d\omega$ ist
${}{\begin{aligned}\varphi ^{*}{\left(-dx\wedge dy-dy\wedge dz+dx\wedge dz\right)}&=-du^{2}\wedge dv^{2}-dv^{2}\wedge duv+du^{2}\wedge duv\\&=-4uvdu\wedge dv-2v^{2}dv\wedge du+2u^{2}du\wedge dv\\&={\left(-4uv+2v^{2}+2u^{2}\right)}du\wedge dv.\end{aligned}}$