# calculating parameters for defining subsections of quadratic bezier curves

I have a quadratic bezier curve described as (startX, startY) to (anchorX, anchorY) and using a control point (controlX, controlY).

I have two questions:

(1) I want to determine y points on that curve based on an x point.

(2) Then, given a line-segment on my bezier (defined by two intermediary points on my bezier curve (startX', startY', anchorX', anchorY')), I want to know the control point for that line-segment so that it overlaps the original bezier exactly.

Why? I want this information for an optimization. I am drawing lots of horizontal beziers. When the beziers are larger than the screen, performance suffers because the rendering engine ends up rendering beyond the extents of what is visible. The answers to this question will let me just render what is visible.

• Out of curiosity, what's the project? – outis Apr 16 '10 at 21:37
• Part 2 needs to be clarified. What do you mean by mini-bezier curve? What parameters? If you mean control points, don't you already have them for the curve? – outis Apr 16 '10 at 21:49
• Thanks for your feedback outis. I rewrote (2) and added an explanation. – jedierikb Apr 16 '10 at 22:02

## Part 1

The formula for a quadratic Bezier is:

```B(t) = a(1-t)2    + 2bt(1-t)   + ct2
= a(1-2t+t2) + 2bt - 2bt2 + ct2
= (a-2b+c)t2+2(b-a)t + a```

where bold indicates a vector. With Bx(t) given, we have:

`x = (ax-2bx+cx)t2+2(bx-ax)t + ax`

where vx is the x component of v.

```     -2(bx-ax) ± 2√((bx-ax)2 - ax(ax-2bx+cx))
t = -----------------------------------------
(2ax(ax-2bx+cx))

ax-bx ± √(bx2 - axcx)
= ----------------------
ax(ax-2bx+cx)```

Assuming a solution exists, plug that t back into the original equation to get the other components of B(t) at a given x.

## Part 2

Rather than producing a second Bezier curve that coincides with part of the first (I don't feel like crunching symbols right now), you can simply limit the domain of your parametric parameter to a proper sub-interval of [0,1]. That is, use part 1 to find the values of t for two different values of x; call these t-values i and j. Draw B(t) for t ∈ [i,j]. Equivalently, draw B(t(j-i)+i) for t ∈ [0,1].

• +1 you did an admirable job without latex – ldog Apr 16 '10 at 22:31
• Thank you for your help. In solving the quadratic, I believe there are a couple minor mistakes in your solution? Any event, got it to work! Appreciated. – jedierikb Apr 19 '10 at 20:58
• @jedierikb, RE: mistakes: quite possibly. What in particular are you referring to? – outis Apr 19 '10 at 21:44

The t equation is wrong, you need to use eq(1)

``````(1) x = (ax-2bx+cx)t2+2(bx-ax)t + ax
``````

and solve it using the the quadratic formula for the roots (2).

``````           -b ± √(b^2 - 4ac)
(2)  x = -----------------
2a
``````

Where

``````a = ax-2bx+cx
b = 2(bx-ax)
c = ax - x
``````
• I just saw this now (note: with enough reputation, you can comment; users will be notified of comments on their posts). – outis Dec 17 '18 at 22:36
• This is what I did. Going back over my calculation, I don't see an error. What's my mistake? – outis Dec 17 '18 at 22:37