Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

Sign up and start helping → Learn more about Documentation →

I've managed to implement other collisions: AABB vs AABB, Circle vs Circle, Poly vs Poly etc, but introducing the circle is bringing up strange problems even though in theory the implementation should be straight forward after implementing these other collisions. From what i understand the AABB vs Circle implementation should work like this:

  1. Test against the X axis for collision
  2. Test against the Y-axis for collision
  3. Test the axis that is from the circle's center to the closest vertex of the AABB

I suspect that it might be a problem when i'm doing the projection on the 3rd step, but i've used the same projection technique for poly's what i've used here for the AABB and the min and max projection for the circle should be the circle's center then minus and plus the radius respectively - at least as i understand it.

I've added some reference pictures also (yellow = no collision, red = collision)
http://imgur.com/a/C2fDO

bool AABBCircleCollision(Point center1, int halfWidth1, int halfHeight1, Point center2, int radius2)
{   

    /***** TEST THE X-AXIS *****/
    double min1, max1, min2, max2;

    min1 = (center1.x - halfWidth1);
    max1 = (center1.x + halfWidth1);
    min2 = (center2.x - radius2);
    max2 = (center2.x + radius2);

    if(max1 <= min2 || max2 <= min1) {
        return false;
    }

    // At this point it is intersecting on the X-axis, now find out if it is on the left or right
    bool onRight;
    if(min2 - max1 > min1 - max2)
        onRight = true;
    else
        onRight = false;

    /***** TEST THE Y-AXIS *****/
    min1 = (center1.y - halfHeight1);
    max1 = (center1.y +  halfHeight1);
    min2 = (center2.y - radius2);
    max2 = (center2.y + radius2);

    if(max1 <= min2 || max2 <= min1) {
        return false;
    }

    // Like for the X-axis, find if the circle is above or below the AABB
    bool onBottom;
    if(min2 - max1 > min1 - max2)
        onBottom = true;
    else
        onBottom = false;

    /***** START TESTING THE AXIS BETWEEN CIRCLE'S CENTER AND CLOSEST VERTEX *****/
    // Get the point of the AABB closest to the circles center
    double vertX, vertY;
    if(onRight)
        vertX = center1.x + halfWidth1;
     else 
        vertX = center1.x - halfWidth1;

    if(onBottom)
        vertY = center1.y + halfHeight1;
    else
        vertY = center1.y - halfHeight1;

    // Get the axis vector between the closest point and the circles center
    double axisX = center2.x - vertX;
    double axisY = center2.y - vertY;

    // Normalise it
    double magV = sqrt(axisX * axisX + axisY * axisY);
    axisX /= magV;
    axisY /= magV;

    // Project the AABB onto the axis
    std::vector<Point> verts; // Here i'm creating the verts on the fly to see if this thing works. USE A BETTER WAY TO HANDLE THIS
    verts.push_back(Point(center1.x - halfWidth1, center1.y - halfHeight1));
    verts.push_back(Point(center1.x + halfWidth1, center1.y - halfHeight1));
    verts.push_back(Point(center1.x + halfWidth1, center1.y + halfHeight1));
    verts.push_back(Point(center1.x - halfWidth1, center1.y + halfHeight1));

    min1 = std::numeric_limits<double>::max(), max1 = -min1; // Reset min and max values

    for(int j=0; j < verts.size(); j++) {
        double proj = (axisX * verts[j].x + axisY * verts[j].y);
        min1 = std::min(proj, min1);
        max1 = std::max(proj, max1);
    }

    // Project the circle onto the axis
    min2 = axisX * (center2.x - radius2) + axisY * (center2.y - radius2);
    max2 = axisX * (center2.x + radius2) + axisY * (center2.y + radius2);

    printf("%f <= %f || %f <= %f\n", max1, min2, max2, min1);
    if(max1 <= min2 || max2 <= min1) {
        return false;
    }

    return true;
}
share|improve this question
    
You can reduce the amount branches by mirroring the coordinates (with abs()) among the center axis. At that point you can first check if the distance^2 of the circle to the (single) corner < r^2. Squaring gets rid of the sqrt. Then check if circlex > box_x+r or circley > box_y+r to reject. – Aki Suihkonen Apr 12 '13 at 17:51
    
@AkiSuihkonen this doesn't employ the SAT like approach does it? The reason i wanted to use the SAT approach is that, even though i'm only returning a bool, i could later extend the functions to return the minimum translation vector for better collision response etc. – Joe Staines Apr 13 '13 at 14:23
    
@JoeStaines: on a side note, have you considered using GJK? This would make your life easier, especially if you plan on adding new convex shapes and minimum distance support. – BenC Apr 16 '13 at 12:23
    
@JoeStaines: this website also has some good indications on SAT (using Voronoi Regions etc.). – BenC Apr 16 '13 at 12:31
    
Why not use the Circle vs Circle algorithm on each vertex? You are doing (practically) the same time complexity determining the closest point anyway. The literal difference would be the sqrt function instead of checking whether it is on the left, top, etc. – SGM1 Apr 21 '13 at 21:08

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Browse other questions tagged or ask your own question.