# How to find intersecting Y values along a bezier spline?

It's been a while since I did any maths* of this kind, so perhaps someone can answer this for me. I don't think this question is exactly what I want, because I am trying to find intersections for precise x values.

So I have a spline which goes from X,Y to XX,YY, with control points at each end. I think I would be correct in saying it will be a quadratic curve (the curve will not cross itself). I plan on using the path routines from the given graphics library (currently thinking HTML5 canvas) to draw this line, so I will not be drawing it myself.

I have a number of points, expressed as X + n, for which I want to find the Y value of the intersection. I am not asking for a position at a given point along the path, I am asking the position on the path where it intersects a line X.

I am planning to draw a vertical line to meet up with it, so if possible it would be great if the point were precise enough to meet up with the curve in a convincing looking way (not off by a couple of pixels).

The routines don't look to hard to draw the line myself, so I could do that and just test (with tolerance) for X values along the plot, if it comes to it.

*Math

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I'm not sure I'm entirely understanding what you want. You have a Bezier curve (cubic or quadratic?), and you want to find where a line X=k intersects the Bezier? Couldn't you plug k into the equation for the Bezier and solve for t? For example here, replace B(t) with k and solve for t. (It may be multi-valued.) See here for finding the roots of a cubic equation. –  user1118321 Jan 23 '12 at 1:19
I could, but I was hoping there might be a ready-baked function or library or something to do it for me (in pseudocode, JavaScript or C (which I can easily port to JS)). –  Joe Jan 23 '12 at 1:23

## 1 Answer

Recently I answered to a very similar question about how to transform 2d spline function f(t) into f(x). The answers there ranged from exact solution of a cubic equation (as cubic bezier splines are the most common ones) on the one end and simple bisecting on the other hand, with various root finding algorithms in between. Take your pick.

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