# Find the normal “N” on an ellipses through a point on a cross section

I'm trying to make a nice deflection effect in a little physics engine I've made. Right now it deflects nicely off the normal of a polygon edge. But instead of making a polygon with 100 edges to get a smooth effect of a "rounded deflection" I figured I could calculate the deflection normal using an ellipse instead.

So, what I'd really like is a function that takes a point P on a line segment and returns the normal N on the circumference of an imaginary ellipse(w,h). See the attached picture for some details.

To get a point on the circumference of an ellipse I'm pretty sure it's:

``````x=P.x+Math.sin()*w
y=P.y+Math.cos()*h
``````

but how can I get the normal from that?

Here's a fiddle with an attempt to implement the answer by Dr BDO Adams.

-

Equation of an ellipse point is

``````x=x_centre+a*cos(t)
y=y_centre+b*sin(t)
``````

For each point of ellipse you can find `t` as `atan2( (y-y_centre)/b , (x-x_centre)/a )`

When you know `t` tangent direction can be determined: `dx/dt,dy/dt`:

``````dx=-a*sin(t)
dy=b*cos(t)
``````

When you know tangent direction, just rotate it by 90 degrees and you have a normal:

``````nx=b*cos(t)
ny=a*sin(t)
``````

And to avoid calculating `t` we can combine it with the first two formulas:

``````nx=(x-x_centre)*b/a
ny=(y-y_centre)*a/b
``````
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First Use the atan2 function to get the angle of at the normal, and get a vector from that

``````theta = atan2(2y/semiminorradius, x/semimajorradius)
``````r = sqrt(tx^2+ty^2)
I've tried to implement this here but the resulting unit vector `~(0.55,0.83)` does not look correct. I'd expect something like `(0,1)` or `(0,-1)`. – Robert Sköld Nov 23 '12 at 14:11