# Center point on html quadratic curve

I have a quadratic curve drawn on html canvas using `context.quadraticCurveTo(controlX, controlY, endX, endY);` .

I have the control-point and the starting and end points, which are not necessarily level with each other horizontally.

How can I find the centre point on the curve using these parameters?

Actually I want to put a div tag on this center point. Is there any equation solving involved in this process?

• Please explain what you mean by "control point" and "starting" and "ending" points. – Val Redchenko Feb 8 '12 at 13:50
• The control point is a point which is responsible for curve shape, the start point is the point where the curve starts and the end pont is one where the curve ends. – me_digvijay Feb 8 '12 at 13:55
• No single point can be responsible for the curve's shape - the curve's shape is defined by values of a,b,c when written in general form. Your starting and ending points - are they level with each other horizontally? Do you have an equation you are plotting? – Val Redchenko Feb 8 '12 at 13:56
• please take a look on qudraticCurveTo(a,b,c) function in htmlcanvas/javascript. It draws the curve according to the control points and the endpoint – me_digvijay Feb 8 '12 at 14:00

`quadraticCurveTo` draws a quadratic Bézier curve.

The formulas to calculate the coordinates of a point at any given position (from 0 to 1) on the curve are

``````x(t) = (1-t)^2 * x1 + 2 * (1-t) * t * x2 + t^2 * x3
y(t) = (1-t)^2 * y1 + 2 * (1-t) * t * y2 + t^2 * y3
``````

where (x1, y1) is the starting point, (x2, y2) is the control point and (x3, y3) is the end point.

So, turning that into JavaScript, we end up with something like

``````function _getQBezierValue(t, p1, p2, p3) {
var iT = 1 - t;
return iT * iT * p1 + 2 * iT * t * p2 + t * t * p3;
}

function getQuadraticCurvePoint(startX, startY, cpX, cpY, endX, endY, position) {
return {
x:  _getQBezierValue(position, startX, cpX, endX),
y:  _getQBezierValue(position, startY, cpY, endY)
};
}
``````

If you pass the start, end and control points to `getQuadraticCurvePoint` there, along with `0.5` for the halfway position, you should get an object with the X and Y coordinates.

Disclaimer -- I didn't test the code, so your mileage may vary, but it seems right. ;)

EDIT: I tested the code here in a jsfiddle. http://jsfiddle.net/QA6VG/206/

Here's a page describing the quadratic equation and it's solution: wiki page . And here is a good tutorial on the subject, complete with diagrams: tutorial

• This page I know and also i am looking at it but I want to calculate the center point using javascript. I dont know how to find the center point. – me_digvijay Feb 8 '12 at 13:57
• If your starting and ending points are level with each other horizontally, then the x coordinate of the curve will be directly in the middle (i.e.) x_start + ((x_end - x_start) / 2) and the y coordinate can be found by substituting this x value into the original equation instead of x and solving it. Do you have the equation? – Val Redchenko Feb 8 '12 at 14:00
• This is the real problem man. I have random start and end points – me_digvijay Feb 8 '12 at 14:01
• Where does the curve come from in the first place? Do you have an equation describing it? – Val Redchenko Feb 8 '12 at 14:13

A possible way:

``````// compute coordinates of the middle point of a quadratic Bezier curve

// compute relative coordinates of a point on the curve using t and c
// t is a number between 0 and 1
// c is an array of 3 points:
//     the initial point of the curve (always (0,0))
//     the "handle" point of the curve
//     the final point of the curve
var t1, t1_2a, t1_2b, t1_2c;
t1 = 1 - t;
t1_2a = t1 * t1;
t1_2b = (2 * t) * t1;
t1_2c = t * t;
return {
x: (c[0].x * t1_2a) + (t1_2b * c[1].x) + (t1_2c * c[2].x),
y: (c[0].y * t1_2a) + (t1_2b * c[1].y) + (t1_2c * c[2].y)
};
}

var k, km = 1000,
km2 = (km >> 1),
len = 0,
len2, x, y, a = new Array(km + 1);
// compute curve lengths from start point to any point
// store relative point coordinates and corresponding length in array a
for (k = 0; k <= km; k++) {
a[k] = {
len: 0
};
if (k > 0) {
x = a[k].pt.x - a[k - 1].pt.x;
y = a[k].pt.y - a[k - 1].pt.y;
a[k].len = a[k - 1].len + Math.sqrt(x * x + y * y);
}
}
// retrieve the point which is at a distance of half the whole curve length from start point
// most of the time, this point is not the one at indice km2 in array a, but it is near it
len2 = a[km].len / 2;
if (a[km2].len > len2)
for (k = km2; k >= 0; k--) {
if (len2 >= a[k].len) break;
} else
for (k = km2; k <= km; k++) {
if (len2 <= a[k].len) break;
}
// return absolute coordinates of the point
return {
x: Math.round((a[k].pt.x + m.x) * 100) / 100,
y: Math.round((a[k].pt.y + m.y) * 100) / 100
};
}
``````

And the corresponding jsfiddle: jsfiddle.net/pTccL/