3
$\begingroup$

If $\alpha(s)$ is a unit speed curve with $k\ne0$, how can we show that the equation of the osculating plane through $\alpha(0)$ is $[x-\alpha(0),\alpha'(0),\alpha''(0)] = 0$. (I mean 3 equal bars for the equal sign)

So what I'm thinking is we can use the fact that $[u,v,w] = [u\times v,w]$ and $k = T'/N$, Frenet serret doesn't look too helpful so I'm stuck. The definition of osculating plane is the plane $\alpha(s)$ perpendicular to $B$ (spanned by $T$ and $N$).

1 Answers 1

2

I suppose that in your question you are using the following notation

\begin{align} &[u,v,w]&&\text{triple product of}\;u,v,w\\ &[u,v]&&\text{inner product of}\;u,v \end{align}

Given that, by definition

\begin{align} T&=\alpha'\\ N&=T'/k=\alpha''/k\\ B&=T\times N \end{align}

I should recall that the equation of a plane of normal $\mathbf{n}=(A,B,C)$ and containing the point $\mathbf{x}_0=(x_0,y_0,z_0)$ is given by

$ [\mathbf{n},\mathbf{x}-\mathbf{x}_0]=0\implies A(x-x_0)+B(y-y_0)+C(z-z_0)=0 $

the plane perpendicular to $B$ and passing by $\alpha(0)$ is given by (using your notations)

\begin{align} &[B,\mathbf{x}-\alpha(0)]=0 \\ &[T\times N,\mathbf{x}-\alpha(0)] =0\\ &[T,N,\mathbf{x}-\alpha(0)] =0\\ &[\alpha'(0),\alpha''(0),\mathbf{x}-\alpha(0)]=0 \end{align}

where $k$ has been removed from the last equation, begin not zero.

  • 0
    Many Thanks $f$or your help!2012-09-10