Answer to Question #140049 in Differential Geometry | Topology for Askin

Question #140049

If f:R^n-->R is a smooth function, define hypersurface f(x)=c for some constant c, then prove velocity vector is orthogonal to the normal vector i.e <\nabla f(p),v_{\gamma}(p)>=0

Expert's answer

We have been provided that "f:\\R^n\\rightarrow \\R" is "\\mathscr{C}^{\\infty}" . let us define the level set by

"M_f:=\\{\\vec x\\in \\R^n:f(\\vec x)=c\\}"

Let "\\gamma:(a,b)\\rightarrow \\R^n" is smooth path such that "t\\mapsto\\gamma(t)" , for "t\\in (a,b),a,b\\in \\R" which passes through "M_f" . let "\\gamma(\\theta)=p\\in\\R^n" for "\\theta\\in (a,b)" and denote "v_{\\gamma}(p)=\\gamma'(\\theta)" is velocity vector passes through "p" .

Thus, by chain rule we get,

"\\frac{d}{dt}[f(\\gamma(t))]=f'(\\gamma(t))v_{\\gamma}(p)"

Since, "\\nabla f:U\\rightarrow \\R^n" is smooth map from open set "U" to "\\R^n" such that

"\\nabla f(\\vec x)=(D_1f(\\vec x),...,D_nf(\\vec x))"

Thus, "\\nabla f(\\gamma(t))^T=f'(\\gamma(t))" , Hence, we get

"\\frac{d}{dt}[f(\\gamma(t))]=f'(\\gamma(t))v_{\\gamma}(p)=\\frac{d}{dt}(c)=0\\\\\n\\implies <\\nabla f(p),v_{\\gamma}(p)>=0"