Rotation invariant of surface

Question

Let $(x, y, f(x,y))$ be a surface in $\mathbb{R^3}$. It is written in a book without proof that all rotation invariant (rotating around $z$-axis) of $f$ are combinations of the following four quantities:

• $\Delta f = f_{xx}+f_{yy}$
• $||\nabla f||^2=f_x^2 + f_y ^2$
• $\det{H} = f_{xx} f_{yy} - f_{xy}^2$
• $(\nabla f, H \nabla f) = f_{xx}f_x^2 + 2f_{xy}f_xf_y+f_{yy}f_y^2$

How do I prove this?

Definition of rotation invariant

My book doesn't provide a precise definition of rotation invariant but I think this is defined as follows:

Let $R[F]={C^{\infty}(\mathbb{R}^2)}[F_{x}, F_{y}, F_{xx}, F_{xy}, F_{yy}, ...]$ be a polynomial ring of infinite variables and $R(F)$ be its field of fractions. Elements in $R(F)$ can be seen as functionals. For a element $H(F)\in R(F)$, we define that $H(F)$ is rotation invariant iff for any rotation $T:\mathbb{R}^2 \rightarrow \mathbb{R}^2$around the origin and for any $f\in C^{\infty}(\mathbb{R}^2)$, $H(f\circ T)=H(f)\circ T$ holds.

Definition of combinations

Let $S(F)$ be a field of fractions of the ring $C^{\infty}(\mathbb{R}^2)[\Delta F, ||\nabla F||, \det{H},(\nabla F, H \nabla F)]$. A combination of the four quantities means an element of $S(F)$.

Answer 1

The result is not correct. Rotations around the $z$-axis preserve the radial vector field $X=\partial_r$, i.e. $X(x,y)=(x,y)$. Such rotations hence preserve $df(X)=xf_x+yf_y$. This is not expressible in terms of the above invariants, as they do not have any first order linear invariants.

Maybe you want to consider the group generated by rotations around all vertical axes, i.e. the group of orientation preserving rigid motions of the plane. Your differential operators are invariant under that group, and that group is probably what the author of the book intended.