# Finding Y given X on a Cubic Bezier Curve?

So I've been looking around for some sort of method to allow me to find the Y-coordinate on a Cubic Bezier Curve, given an x-coordinate on it.

I've come across lots of places telling me to treat it a cubic function then attempt to find the roots, which I understand HOWEVER the equation for a Cubic Bezier curve is (for x-coords): X(t) = (1-t)^3 * X0 + 3*(1-t)^2 * t * X1 + 3*(1-t) * t^2 * X2 + t^3 * X3

What confuses me is the addition of the (1-t) values. For instance, if I fill in the X values with some random numbers...

400 = (1-t)^3 * 100 + 3*(1-t)^2 * t * 600 + 3*(1-t) * t^2 * 800 + t^3 * 800

then rearrange to the Cubic equation style:

800t^3 + 3*(1-t)800t^2 + 3(1-t)^2*600t + (1-t)^3*100 -400 = 0

I still have the trouble of the (1-t) blocks. I can't work out how I am supposed to solve t when the (1-t) is unknown in the first place.

Any ideas?

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More a maths question... –  Oliver Charlesworth Jul 3 '12 at 0:23
Very well, I'll go ask the Maths people instead. I assumed it being used in computing would mean people here might know. Thank you. –  Captain Awesome Jul 3 '12 at 0:25

There are three common ways of expressing a cubic bezier curve.

First x as a function of t

``````x(t) = sum( f_i(t) a_i )
= (1-t)^3 * x0 + 3*(1-t)^2 * t * x1 + 3*(1-t) * t^2 * x2 + t^3 * x3
``````

Secondly y as a function of x

``````y(x) = sum( f_i(x) a_i )
= (1-x)^3 * y0 + 3*(1-x)^2 * x * y1 + 3*(1-x) * x^2 * y2 + x^3 * y3
``````

These first two are mathematically the same, just using different names for the variables.

Judging by your description "find the Y-coordinate on a Cubic Bezier Curve, given an x-coordinate on it." I'm guessing that you've got a question using the second equation are are trying to rearrange the first equation to help you solve it, where as you should be using the second equation. If thats the case, then no rearranging or solving is required - just plug your x value in and you have the solution.

Its possible that you have an equation of the third kind case, which is the ugly and hard case. This is both the x and y parameters are cubic Beziers of a third variable t.

``````x(t) = sum( f_i(t) x_i )
y(t) = sum( f_i(t) y_i )
``````

If this is your case. Let me know and I can detail what you need to do to solve it.

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Developing the expression further should get you rid of the `(1 - t)` factors

If you run:

``````expand(800*t^3 + 3*(1-t)*800*t^2 + 3*(1-t)^2*600*t + (1-t)^3*100 -400 = 0);
``````

In either wxMaxima or Maple (you have to add the parameter `t` in this one though), you get:

``````100*t^3 - 900*t^2 + 1500*t - 300 = 0
``````

Solve the new cubic equation for `t` (you can use the cubic equation formula for that), after you got `t`, you can find `x` doing:

``````x = (x4 - x0) * t      (asuming x4 > x0)
``````
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I think this is a fair CS question, so I'm going to attempt to show how I solved this. Note that a given x may have more than 1 y value associated with it. In the case where I needed this, that was guaranteed not to be the case, so you'll have to figure out how to determine which one you want.

I iterated over t generating an array of x and y values. I did it at a fairly high resolution for my purposes. (I was looking to generate an 8-bit look-up table, so I used ~1000 points.) I just plugged t into the bezier equation for the next x and the next y coordinates to store in the array. Once I had the entire thing generated, I scanned through the array to find the 2 nearest x values. (Or if there was an exact match, used that.) I then did a linear interpolation on that very small line segment to get the y-value I needed.

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So I've been looking around for some sort of method to allow me to find the Y-coordinate on a Cubic Bezier Curve, given an x-coordinate on it.

Consider a cubic bezier curve between points (0, 0) and (0, 100), with control points at (0, 33) and (0, 66). There are an infinite number of Y's there for a given X. So there's no equation that's going to solve Y given X for an arbitrary cubic bezier.

For a robust solution, you'll likely want to start with De Casteljau's algorithm

Split the curve recursively until individual segments approximate a straight line. You can then detect whether and where these various line segments intercept your x or whether they are vertical line segments whose x corresponds to the x you're looking for (my example above).

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