# calculating intersection point of quadratic bezier curve

This is definitely pushing the limits for my trig knowledge.

Is there a formula for calculating an intersection point between a quadratic bezier curve and a line?

Example:

in the image below, I have P1, P2, C (which is the control point) and X1, X2 (which for my particular calculation is just a straight line on the X axis.)

What I would like to be able to know is the X,Y position of T as well as the angle of the tangent at T. at the intersection point between the red curve and the black line.

After doing a little research and finding this question, I know I can use:

``````t = 0.5; // given example value
x = (1 - t) * (1 - t) * p[0].x + 2 * (1 - t) * t * p[1].x + t * t * p[2].x;
y = (1 - t) * (1 - t) * p[0].y + 2 * (1 - t) * t * p[1].y + t * t * p[2].y;
``````

to calculate my X,Y position at any given point along the curve. So using that I could just loop through a bunch of points along the curve, checking to see if any are on my intersecting X axis. And from there try to calculate my tangent angle. But that really doesn't seem like the best way to do it. Any math guru's out there know what the best way is?

I'm thinking that perhaps it's a bit more complicated than I want it to be.

• Maybe Pomax can offer you some help. Dec 27, 2014 at 5:31
• I'm pretty sure I covered it in the Primer, in the section on curve intersection. Simply rotate your curve and line so that the line "lines up" with the x-axis, and now you've reduced "finding the intersection" to "root finding" (with aligning explained here) Mar 11, 2016 at 7:01

``````y=ax^2+bx+c // where a,b,c are known
``````

Line formula:

``````// note: this `B` is not the same as the `b` in the quadratic formula ;-)

y=m*x+B  // where m,B are known.
``````

The curve & line intersect where both equations are true for the same [x,y]:

Here's annotated code and a Demo:

``````// canvas vars
var canvas=document.getElementById("canvas");
var ctx=canvas.getContext("2d");
var cw=canvas.width;
var ch=canvas.height;

// linear interpolation utility
var lerp=function(a,b,x){ return(a+x*(b-a)); };

// qCurve & line defs
var p1={x:125,y:200};
var p2={x:250,y:225};
var p3={x:275,y:100};
var a1={x:30,y:125};
var a2={x:300,y:175};

// calc the intersections
var points=calcQLintersects(p1,p2,p3,a1,a2);

// plot the curve, line & solution(s)
var textPoints='Intersections: ';
ctx.beginPath();
ctx.moveTo(p1.x,p1.y);
ctx.moveTo(a1.x,a1.y);
ctx.lineTo(a2.x,a2.y);
ctx.stroke();
ctx.beginPath();
for(var i=0;i<points.length;i++){
var p=points[i];
ctx.moveTo(p.x,p.y);
ctx.arc(p.x,p.y,4,0,Math.PI*2);
ctx.closePath();
textPoints+=' ['+parseInt(p.x)+','+parseInt(p.y)+']';
}
ctx.font='14px verdana';
ctx.fillText(textPoints,10,20);
ctx.fillStyle='red';
ctx.fill();

///////////////////////////////////////////////////

function calcQLintersects(p1, p2, p3, a1, a2) {
var intersections=[];

// inverse line normal
var normal={
x: a1.y-a2.y,
y: a2.x-a1.x,
}

// Q-coefficients
var c2={
x: p1.x + p2.x*-2 + p3.x,
y: p1.y + p2.y*-2 + p3.y
}

var c1={
x: p1.x*-2 + p2.x*2,
y: p1.y*-2 + p2.y*2,
}

var c0={
x: p1.x,
y: p1.y
}

// Transform to line
var coefficient=a1.x*a2.y-a2.x*a1.y;
var a=normal.x*c2.x + normal.y*c2.y;
var b=(normal.x*c1.x + normal.y*c1.y)/a;
var c=(normal.x*c0.x + normal.y*c0.y + coefficient)/a;

// solve the roots
var roots=[];
d=b*b-4*c;
if(d>0){
var e=Math.sqrt(d);
roots.push((-b+Math.sqrt(d))/2);
roots.push((-b-Math.sqrt(d))/2);
}else if(d==0){
roots.push(-b/2);
}

// calc the solution points
for(var i=0;i<roots.length;i++){
var minX=Math.min(a1.x,a2.x);
var minY=Math.min(a1.y,a2.y);
var maxX=Math.max(a1.x,a2.x);
var maxY=Math.max(a1.y,a2.y);
var t = roots[i];
if (t>=0 && t<=1) {
// possible point -- pending bounds check
var point={
x:lerp(lerp(p1.x,p2.x,t),lerp(p2.x,p3.x,t),t),
y:lerp(lerp(p1.y,p2.y,t),lerp(p2.y,p3.y,t),t)
}
var x=point.x;
var y=point.y;
// bounds checks
if(a1.x==a2.x && y>=minY && y<=maxY){
// vertical line
intersections.push(point);
}else if(a1.y==a2.y && x>=minX && x<=maxX){
// horizontal line
intersections.push(point);
}else if(x>=minX && y>=minY && x<=maxX && y<=maxY){
// line passed bounds check
intersections.push(point);
}
}
}
return intersections;
}``````
``````body{ background-color: ivory; padding:10px; }
#canvas{border:1px solid red;}``````
``````<h4>Calculate intersections of QBez-Curve and Line</h4>
<canvas id="canvas" width=350 height=350></canvas>``````

• He asked for bezier function, for which there is no y(x), but only parametric representations x(t),y(t)
– Gigo
Dec 27, 2014 at 7:35
• That kind of confuses me more. Would you be able to add an example with values? I find I can understand better when i see things working. Dec 27, 2014 at 13:50
• @Gigo: Oops, My tired brain didn't recognize that at 1am last night--my bad. So now the math is quite more complex. You could transform the line-curve pair so the line is axis aligned and then calculate roots. Gigo, have you already coded this solution? If not, I'll pay the penalty and code up the solution for tyler Mackenzie... Dec 27, 2014 at 18:34
• @Gigo, I posted the code to calculate intersections of a QBez & a Line. Dec 28, 2014 at 7:40
• How can we solve the same problem for 3D bezier and line intersection? For example for the points: var p1={ x:0, y:0, z: 1 }; var p2={ x:100, y:0, z: 1 }; var c={ x:0, y:0, z: -5 }; var x1={ x:0, y:0, z: 0 }; var x2={ x:100, y:0, z: 0 }; Mar 21, 2019 at 16:25

If you only need an intersection with a straight line in the x-direction you already know the y-coordinate of the intersection. To get the x-coordinate do something like this:

• The equation for your line is simply `y = b`
• Setting it equal to your y-equation of the beziér function `y(t)` gets you:
`b = (1 - t) * (1 - t) * p[0].y + 2 * (1 - t) * t * p[1].y + t * t * p[2].y`
• Solving* for t gets you:
`t = (p[0].y - p[1].y - sqrt(b*a + p[1].y*p[1].y - p[0].y*p[2].y)) / a`
with `a = p[0].y - 2*p[1].y + p[2].y`
• Insert the resulting t into your x-equation of the beziér function `x(t)` to get the x-coordinate and you're done.

You may have to pay attention to some special cases, like when no solution exists, because the argument of the square root may then become negative or the denominator (`a`) might become zero, or something like that.

(*) I used wolfram alpha to solve the equation because I'm lazy: Wolfram alpha solution.

• I really like this method. much simpler and elegant when calculating a horizontal or vertical line. Very useful for my application. Dec 28, 2014 at 20:34
• Very useful for scanline conversion of shapes! Feb 21, 2016 at 6:51
• Note that if you translate and rotate both the bezier curve and the intersecting line, such that the intersecting line equals the x-axis, that this method is always possible to use for Bézier-line crossings. May 19, 2020 at 12:21

calculate line's tangθ with x-coordinate

then intersection of the curve's (x, y) should be the same tangθ

so solution is

a = line's x distance from (line.x,0) to (0,0)

(curve.x + a) / curve.y = tangθ (θ can get from the line intersection with x-coordidate)