I have an Archimedean spiral determined by the parametric equations x = r t * cos(t) and y = r t * sin(t).
I need to place n points equidistantly along the spiral. The exact definition of equidistant doesn't matter too much - it only has to be approximate.
Using just r, t and n as parameters, how can I calculate the coordinates of each equidistant point?
You want to place points equidistantly corresponding to arc length. Arc length for Archimedean spiral (formula 4) is rather complex
s(t) = a/2 * (t * Sqrt(1 + t*t) + ln(t + Sqrt(1+t*t)))
and for exact positions one could use numerical methods, calculating t values for equidistant s1, s2, s3... arithmetical progression. It is possible though.
First approximation possible - calculate s(t) values for some sequence of t, then get intervals for needed s values and apply linear interpolation.
Second way - use Clackson scroll formula approximation, this approach looks very simple (perhaps inexact for small t values)
t = 2 * Pi * Sqrt(2 * s / a)
Checked: quite reliable result
s still contains θ? If so, then surely the formula will not work (as my t is the document's θ); if not so, then what is s? Thank you!
Jun 25, 2017 at 16:49
r=a*t/(2Pi), and a=20 in your case, s=a*t^2/(4Pi), t=2*sqrt(Pi*s/a), r=sqrt(s*a/Pi)
xyplane? And what range of the spiral do you want to split? Sincetis not defined, it could be infinite. And you can't deal withinfinityin a finite context. Please rewise and update your question.for(var i=0; i<n; ++i) console.log({x: i*r*Math.PI*2, y:0 })? All points are on the parametric spiral and all exactly byr*Math.PI*2away from each other.y = 0isn't a spiral