I know that a ruled surface is a surface with parametrization $x(u,v)$ = $c(u)$ + $vf(u)$ where if $I$ $\subset$ $R$ is an interval, $c$: $I$ $\mapsto$ $R^3$ and $f$ : $I$ $\mapsto$ $R^3$ are smooth curves with $f$ $\neq$ $0$ on $I$. The curve $c$ is called the directrix and the $f(u)$ are called the rulings. If I'm not mistaken, is a ruled surface regular at a point $p$ = $x(u,v)$ provided that $f(u)$ $\bigwedge$ $c'(u)$ = $vf(u)$ $\bigwedge$ $f'(u)$ and $x_u$ $\bigwedge$ $x_v$ $\neq$ $0$? I actually think that only the second condition is really required, or are both of them required? Are the two conditions equivalent, and is there any other extra requirement? I'd really appreciate some input on this, thanks.
When a ruled surface can be regular
4
$\begingroup$
differential-geometry
surfaces
-
0I could be wrong, but since the rulings $f(u)$ are actually a vector, won't $f(u)$ and $f'(u)$ be parallel and therefore $vf(u) \bigwedge f'(u)=0$? What am I missing? – 2011-04-09
-
0@Adrian notice that $v$ is the linear parameter, $f(u)$ need not be linear. The statement that "the $f(u)$ are called the rulings" seems misleading. – 2011-04-09
-
0The surface is regular at $p$ if $x_u \wedge x_v \neq 0$. If you explicitly compute this from your given equation, you see that $p$ is *not* regular exactly when $f(u) \wedge c'(u) = vf'(u) \wedge f(u)$, which is not quite the same as what you wrote as the first "requirement". – 2011-04-09
-
0@yasmar So then only the second statement is enough to say that the ruled surface is regular? What about my first "requirement?" – 2011-04-09
-
0The second statement is more or less the definition of regular, regardless of whether or not the surface is ruled. I expect you miss-copied the first statement from somewhere. – 2011-04-09
1 Answers
2
Let $x(u,v)=c(u)+vf(u)$ where $u\in I$. Note that by definition, $x(u,v)$ is a regular surface if $x_u\wedge x_v\neq 0$. Simple computation gives $x_u(u,v)=c'(u)+vf'(u)$ and $x_v(u,v)=f(u)$, which implies that $$x_u\wedge x_v=c'(u)\wedge f(u)+vf'(u)\wedge f(u).$$ Therefore, $x(u,v)$ is a regular surface if and only if $c'(u)\wedge f(u)+vf'(u)\wedge f(u)\neq 0$.