18

How do I calculate the intersection between a ray and a plane?

Code

This produces the wrong results.

float denom = normal.dot(ray.direction);

if (denom > 0)
{
    float t = -((center - ray.origin).dot(normal)) / denom;

    if (t >= 0)
    {
        rec.tHit = t;
        rec.anyHit = true;
        computeSurfaceHitFields(ray, rec);
        return true;
    }
}

Parameters

ray represents the ray object.
ray.direction is the direction vector.
ray.origin is the origin vector.
rec represents the result object.
rec.tHit is the value of the hit.
rec.anyHit is a boolean.

My function has access to the plane:
center and normal defines the plane

  • 2
    When you say this does not work, what specifically isn't working? Is it crashing, are the results wrong? does it fail to compile? – Matt Coubrough Jun 1 '14 at 0:18
  • 2
    Is your normal vector guaranteed to point away from the ray origin? Otherwise, denom < 0 might very well still produce an intersection. – wonce Jun 1 '14 at 0:21
23

As wonce commented, you want to also allow the denominator to be negative, otherwise you will miss intersections with the front face of your plane. However, you still want a test to avoid a division by zero, which would indicate the ray being parallel to the plane. You also have a superfluous negation in your computation of t. Overall, it should look like this:

float denom = normal.dot(ray.direction);
if (abs(denom) > 0.0001f) // your favorite epsilon
{
    float t = (center - ray.origin).dot(normal) / denom;
    if (t >= 0) return true; // you might want to allow an epsilon here too
}
return false;
  • 1
    What is center and what is ray origin? – Lily Dec 6 '15 at 7:05
  • 1
    center here is a known point on the plane. This uses the "Point-normal" description for the plane. – Joan Charmant Mar 6 '16 at 10:34
  • 1
    I have to point out that you should use fabs() and not abs() because abs() converts the input parameter to int. – Tara Jun 24 '16 at 18:56
  • 4
    @Duckdoom5: I was obviously talking about C++, because the question is tagged as C++. I assume you are talking about std::abs() (which has different overloads) and not abs() (which only deals with integers). Since the answer contains abs() instead of std::abs() and doesn't use a using directive either, I assume this to be a mistake. See here for more information: stackoverflow.com/questions/21392627/… – Tara Oct 11 '16 at 1:56
  • @Duckdoom5 I hope you'll delete that comment. It's wrong and you'll confuse novices with wrong information. – Glenn Maynard May 21 '17 at 6:13
8

First consider the math of the ray-plane intersection:

In general one intersects the parametric form of the ray, with the implicit form of the geometry.

So given a ray of the form x = a * t + a0, y = b * t + b0, z = c * t + c0;

and a plane of the form: A x * B y * C z + D = 0;

now substitute the x, y and z ray equations into the plane equation and you will get a polynomial in t. you then solve that polynomial for the real values of t. With those values of t you can back substitute into the ray equation to get the real values of x, y and z. Here it is in Maxima:

enter image description here

Note that the answer looks like the quotient of two dot products! The normal to a plane is the first three coefficients of the plane equation A, B, and C. You still need D to uniquely determine the plane. Then you code that up in the language of your choice like so:

Point3D intersectRayPlane(Ray ray, Plane plane)
{
    Point3D point3D;

    //  Do the dot products and find t > epsilon that provides intersection.


    return (point3D);
}
  • I can't seem to find more on the implicit formula for a ray. What do a, t, and a0 represent in x(t)? Thank you! – brain56 Jun 25 '19 at 1:22
  • The ray is in parametric form, whilst the plane is implicit form. See cs.umd.edu/~djacobs/CMSC427/RayTracing.pdf – vwvan Jun 25 '19 at 8:00
  • 2
    That - sign next to the t = is nearly invisible. – Mateen Ulhaq Nov 12 '19 at 13:15
3

implementation of vwvan's answer

Vector3 Intersect(Vector3 planeP, Vector3 planeN, Vector3 rayP, Vector3 rayD)
{
    var d = Vector3.Dot(planeP, -planeN);
    var t = -(d + rayP.z * planeN.z + rayP.y * planeN.y + rayP.x * planeN.x) / (rayD.z * planeN.z + rayD.y * planeN.y + rayD.x * planeN.x);
    return rayP + t * rayD;
}
  • 1
    Why did you write the two dot products in full in the $t$ calculation instead of calling $Vector3.Dot(rayP, planeN)$? – The Coding Wombat May 8 '19 at 22:19
1

Let the ray be given parametrically by p = p0 + t*v for initial point p0 and direction vector v for t >= 0.

Let the plane be given by dot(n, p) + d = 0 for normal vector n = (a, b, c) and constant d. If r is a point on the plane, then d = - dot(n, r). Fully expanded, the plane equation may also be written ax + by + cz + d = 0.

Substituting the ray into the plane equation gives:

t = - (dot(n, p) + d) / dot(n, v)

Example implementation:

std::optional<vec3> intersectRayWithPlane(
    vec3 p, vec3 v,  // ray
    vec3 n, float d  // plane
) {
    float denom = dot(n, v);

    // Prevent divide by zero:
    if (abs(denom) <= 1e-4f)
        return std::nullopt;

    // If you want to ensure the ray reflects off only
    // the "top" half of the plane, use this instead:
    if (-denom <= 1e-4f)
        return std::nullopt;

    float t = -(dot(n, p) + d) / dot(n, v);

    // Use pointy end of the ray.
    // It is technically correct to compare t < 0,
    // but that may be undesirable in a raytracer.
    if (t <= 1e-4)
        return std::nullopt;

    return p + t * v;
}
  • I wrote this answer to provide a complete working example for the ax + by + cz + d = 0 form. Additionally discusses what to do if we only wish to reflect rays off a normally oriented plane (i.e. the front side of the plane... not its back). – Mateen Ulhaq Nov 12 '19 at 13:41
  • Also, see this answer for a derivation of Snell's Law in vector form, and its solution for the parameter t. – Mateen Ulhaq Nov 14 '19 at 13:11

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