Differential Geometry/Frenet-Serret Formulae

The derivatives of the vectors t, p, and b can be expressed as a linear combination of these vectors. The formulae for these expressions are called the Frenet-Serret Formulae. This is natural because t, p, and b form an orthogonal basis for a three-dimensional vector space.

Of course, we know already that ${\displaystyle \frac{dt}{ds}=\kappa p}$ and ${\displaystyle \frac{db}{ds}=-\tau p}$ so it remains to find ${\displaystyle \frac{dp}{ds}}$. First, we differentiate ${\displaystyle p\cdot p=1}$ to obtain ${\displaystyle \frac{dp}{ds}\cdot p=0}$ so it takes on the form ${\displaystyle \frac{dp}{ds}=at+cb}$. We take the dot product of this with t to obtain ${\displaystyle a=\frac{dp}{ds}\cdot t}$. Taking the derivative of ${\displaystyle p\cdot t=0}$, we get ${\displaystyle \frac{dp}{ds}\cdot t+p\cdot \frac{dt}{ds}=0}$ or ${\displaystyle \frac{dp}{ds}\cdot t=-p\cdot \frac{dt}{ds}=-\kappa p\cdot p=-\kappa }$. Also, taking the dot product of ${\displaystyle \frac{dp}{ds}=at+cb}$ with b, we obtain ${\displaystyle c=\frac{dp}{ds}\cdot p}$. Taking the derivative of ${\displaystyle p\cdot b=0}$, we get ${\displaystyle \frac{dp}{ds}\cdot b=-p\cdot \frac{db}{ds}=\tau }$. Thus, we arrive at the following expression for ${\displaystyle \frac{dp}{dt}}$:

${\displaystyle \frac{dp}{dt}=-\kappa t+\tau b}$.

This formula, combined with the previous two formulae, are together called the Frenet-Serret Formulae and they can be represented by a skew-symmetric matrix.

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