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Mike Horvath <mik### [at] gmail com> wrote:
> See here:
>
>
https://math.stackexchange.com/questions/2857219/formula-for-the-offset-curve-of-an-ellipsoid
>
> Mike
>
>
>
> On 7/19/2018 9:36 PM, Mike Horvath wrote:
> > On 7/19/2018 8:25 PM, Bald Eagle wrote:
> >>
> >> Also of interest:
> >>
> >> http://xahlee.info/SpecialPlaneCurves_dir/Parallel_dir/parallel.html
> >>
> >
> > Xah Lee says the parametric formula for an offset curve is
> >
> > { xf[t] + d yf'[t]/Sqrt[xf'[t]^2 + yf'[t]^2],
> > yf[t] - d xf'[t]/Sqrt[xf'[t]^2 + yf'[t]^2] }
> >
> > Not sure how to extend that into three dimensions. (I might be able to
> > make an SOR using that formula, but I'd rather not.)
> >
> >
> > Wikipedia says the parametric formula for an ellipsoid is
> >
> > <math>\begin{align}
> > x&=a\cos(\theta)\cos(\varphi),\\
> > y&=b\cos(\theta)\sin(\varphi),\\
> > z&=c\sin(\theta),\end{align}\,\!</math>
> >
> > where
> > <math>
> > -\frac \pi 2 \le \theta\le \frac \pi 2,
> > \qquad
> > -\pi\le \varphi\le \pi.
> > </math>
> >
> > Not sure what the derivative of this is. (Calculus was years ago...)
> >
> >
> > Mike
Many years ago I ever do something for the same goal.
http://news.povray.org/povray.binaries.images/thread/%3Cweb.5264d1b954cff585cc1fd1150%40news.povray.org%3E/?ttop=423056
&toff=750
But not the same, I used the math formula, not parametric formula. And just suit
for a small offset(a thin shell)
Because it is just an approximation.
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