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I've been doing a lot of research on the topic and found a couple of post that where helpful but I just can't get this right.

I am developing a very simple structural analysis app. In this app I need to display a graph showing the internal stress of the beam. The graph is obtained by the formula:

y = (100 * X / 2) * (L - X)

where L is the known length of the beam (lets say its 1 for simplicity). And X is a value between 0 and the Length of be beam. So the final formula would be:

y = (100 * X / 2) * (1 - x) where  0 < X < 1.

Assuming my start and end points are P0 = (0,0) and P2 = (1,0). How can I obtain P2 (control point)?? I have been searching in the Wikipedia page but I am unsure how to obtain the control point from the quadratic bezier curve formula:

B(t) = (1 - t)^2 * P0 + 2*(1 - t)*t * P1 + t^2 * P2

I'm sure it must be such an easy problem to fix… Can anyone help me out?

P.S.: I also found this, How to find the mathematical function defining a bezier curve, which seems to explain how to do the opposite of what I am trying to achieve. I just can't figure out how to turn it around.

share|improve this question
If you haven't, you may want to take a look at Math.SE – Aboutblank Jun 22 '13 at 18:32
Thanks! I already looked into the maths section. I just don't know what to do with the "t" value. I tried doing the same as the question I linked but the "t" remains, so I'm left with a useless coordinate. – t0t3m Jun 22 '13 at 18:46
up vote 4 down vote accepted

We want the quadratic curve defined by y to match the quadratic Bezier curve defined by B(t).

Among the many points that must match is the peak which occurs at x = 0.5. When x = 0.5,

y = (100 * x / 2) * (1 - x)

    100     1      25
y = ---- * ---  = ---- = 12.5
     4      2       2

Therefore, let's arrange for B(0.5) = (0.5, 12.5):

B(t) = (1-t)^2*(0,0) + 2*(1-t)*t*(Px, Py) + t^2*(1,0)
(0.5, 12.5) = B(0.5) = (0,0) + 2*(0.5)*(0.5)*(Px, Py) + (0.25)*(1,0)

0.5 = 0.5 * Px + 0.25
12.5 = 0.5 * Py

Solving for Px and Py, we get

(Px, Py) = (0.5, 25)

And here is visual confirmation (in Python) that we've found the right point:

import matplotlib.pyplot as plt
import numpy as np

x = np.linspace(0, 1, 100)
y = (100*x/2)*(1-x)
t = np.linspace(0, 1, 100)
P0 = np.array([0,0])
P1 = np.array([0.5,25])
P2 = np.array([1,0])
B = ((1-t)**2)[:,np.newaxis]*P0 + 2*((1-t)*t)[:,np.newaxis]*P1 + (t**2)[:,np.newaxis]*P2
plt.plot(x, y)
plt.plot(B[:,0], B[:,1])

Running python, we see the two curves overlap:

enter image description here

How did I know to choose t = 0.5 as the parameter value when B(t) reaches its maximum height?

Well, it was mainly based on intuition, but here is a more formal way to prove it:

The y-component of B'(t) equals 0 when B(t) reaches its maximum height. So, taking the derivative of B(t), we see

0 = 2*(1-2t)*Py
t = 0.5 or Py = 0

If Py = 0 then B(t) is a horizontal line from (0,0) to (1,0). Rejecting this degenerate case, we see B(t) reaches its maximum height when t = 0.5.

share|improve this answer
Wow! Thank you very much unutbu. That was easy… So let me get this straight, reading your code I conclude that the maximum point of the bezier occurs at t = 0.5. Is this ALWAYS the case? – t0t3m Jun 22 '13 at 19:37
@t0t3m: It was just a lucky guess. But I've added above a more formal argument why t=0.5 is the right choice. – unutbu Jun 22 '13 at 21:42
I edited the control point math with the changes @Teeppeem pointed out. I think I got it right but feel free to check it out. The graph for visual confirmation is still the same one. – t0t3m Jun 23 '13 at 17:17
@t0t3m: Yep, Teepeemm is right. – unutbu Jun 23 '13 at 17:31

Your quadratic bezier curve formula has a typo in the middle term. It should be:
B(t) = (1 - t)^2 * P0 + 2 * (1 - t) * t * P1 + t^2 * P2
This means you should take the P1=(1,50) that @unutbu found and divide the coordinates in half to get P1=(.5,25). (This won't matter if you're plotting the parametric equation on your own, but if you want something like LaTeX's \qbezier(0,0)(.5,25)(1,0), then you'll need the corrected point.)

The P1 control point is defined so that the tangent lines at P0 and P2 intersect at P1. Which means that if (P1)x=(P2)x, the graph should be vertical on its righthand side (which you don't want).

In response to your comment, if you have a quadratic y=f(x), then it is symmetrical about its axis (almost tautologically). So the maximum/minimum will occur at the average of the roots (as well as the control point).

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I was actually going to ask that right now. The new control point (0.5, 25) makes a lot more sense tan the previous (1,50). I already corrected the formula. Thanks! – t0t3m Jun 23 '13 at 17:00

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