# Point of contact of 2 OBBs?

I'm working on the physics for my GTA2-like game so I can learn more about game physics.

The collision detection and resolution are working great.

I'm now just unsure how to compute the point of contact when I hit a wall.

Here is my OBB class:

``````public class OBB2D
{
private Vector2D projVec = new Vector2D();
private static Vector2D projAVec = new Vector2D();
private static Vector2D projBVec = new Vector2D();
private static Vector2D tempNormal = new Vector2D();
private Vector2D deltaVec = new Vector2D();

// Corners of the box, where 0 is the lower left.
private  Vector2D corner[] = new Vector2D[4];

private Vector2D center = new Vector2D();
private Vector2D extents = new Vector2D();

private RectF boundingRect = new RectF();
private float angle;

//Two edges of the box extended away from corner[0].
private  Vector2D axis[] = new Vector2D[2];

private double origin[] = new double[2];

public OBB2D(float centerx, float centery, float w, float h, float angle)
{
for(int i = 0; i < corner.length; ++i)
{
corner[i] = new Vector2D();
}
for(int i = 0; i < axis.length; ++i)
{
axis[i] = new Vector2D();
}
set(centerx,centery,w,h,angle);
}

public OBB2D(float left, float top, float width, float height)
{
for(int i = 0; i < corner.length; ++i)
{
corner[i] = new Vector2D();
}
for(int i = 0; i < axis.length; ++i)
{
axis[i] = new Vector2D();
}
set(left + (width / 2), top + (height / 2),width,height,0.0f);
}

public void set(float centerx,float centery,float w, float h,float angle)
{
float vxx = (float)Math.cos(angle);
float vxy = (float)Math.sin(angle);
float vyx = (float)-Math.sin(angle);
float vyy = (float)Math.cos(angle);

vxx *= w / 2;
vxy *= (w / 2);
vyx *= (h / 2);
vyy *= (h / 2);

corner[0].x = centerx - vxx - vyx;
corner[0].y = centery - vxy - vyy;
corner[1].x = centerx + vxx - vyx;
corner[1].y = centery + vxy - vyy;
corner[2].x = centerx + vxx + vyx;
corner[2].y = centery + vxy + vyy;
corner[3].x = centerx - vxx + vyx;
corner[3].y = centery - vxy + vyy;

this.center.x = centerx;
this.center.y = centery;
this.angle = angle;
computeAxes();
extents.x = w / 2;
extents.y = h / 2;

computeBoundingRect();
}

//Updates the axes after the corners move.  Assumes the
//corners actually form a rectangle.
private void computeAxes()
{
axis[0].x = corner[1].x - corner[0].x;
axis[0].y = corner[1].y - corner[0].y;
axis[1].x = corner[3].x - corner[0].x;
axis[1].y = corner[3].y - corner[0].y;

// Make the length of each axis 1/edge length so we know any
// dot product must be less than 1 to fall within the edge.

for (int a = 0; a < axis.length; ++a)
{
float l = axis[a].length();
float ll = l * l;
axis[a].x = axis[a].x / ll;
axis[a].y = axis[a].y / ll;
origin[a] = corner[0].dot(axis[a]);
}
}

public void computeBoundingRect()
{
boundingRect.left = JMath.min(JMath.min(corner[0].x, corner[3].x), JMath.min(corner[1].x, corner[2].x));
boundingRect.top = JMath.min(JMath.min(corner[0].y, corner[1].y),JMath.min(corner[2].y, corner[3].y));
boundingRect.right = JMath.max(JMath.max(corner[1].x, corner[2].x), JMath.max(corner[0].x, corner[3].x));
boundingRect.bottom = JMath.max(JMath.max(corner[2].y, corner[3].y),JMath.max(corner[0].y, corner[1].y));
}

public void set(RectF rect)
{
set(rect.centerX(),rect.centerY(),rect.width(),rect.height(),0.0f);
}

// Returns true if other overlaps one dimension of this.
private boolean overlaps1Way(OBB2D other)
{
for (int a = 0; a < axis.length; ++a) {

double t = other.corner[0].dot(axis[a]);

// Find the extent of box 2 on axis a
double tMin = t;
double tMax = t;

for (int c = 1; c < corner.length; ++c) {
t = other.corner[c].dot(axis[a]);

if (t < tMin) {
tMin = t;
} else if (t > tMax) {
tMax = t;
}
}

// We have to subtract off the origin

// See if [tMin, tMax] intersects [0, 1]
if ((tMin > 1 + origin[a]) || (tMax < origin[a])) {
// There was no intersection along this dimension;
// the boxes cannot possibly overlap.
return false;
}
}

// There was no dimension along which there is no intersection.
// Therefore the boxes overlap.
return true;
}

public void moveTo(float centerx, float centery)
{
float cx,cy;

cx = center.x;
cy = center.y;

deltaVec.x = centerx - cx;
deltaVec.y  = centery - cy;

for (int c = 0; c < 4; ++c)
{
corner[c].x += deltaVec.x;
corner[c].y += deltaVec.y;
}

boundingRect.left += deltaVec.x;
boundingRect.top += deltaVec.y;
boundingRect.right += deltaVec.x;
boundingRect.bottom += deltaVec.y;

this.center.x = centerx;
this.center.y = centery;
computeAxes();
}

// Returns true if the intersection of the boxes is non-empty.
public boolean overlaps(OBB2D other)
{
if(right() < other.left())
{
return false;
}

if(bottom() < other.top())
{
return false;
}

if(left() > other.right())
{
return false;
}

if(top() > other.bottom())
{
return false;
}

if(other.getAngle() == 0.0f && getAngle() == 0.0f)
{
return true;
}

return overlaps1Way(other) && other.overlaps1Way(this);
}

public Vector2D getCenter()
{
return center;
}

public float getWidth()
{
return extents.x * 2;
}

public float getHeight()
{
return extents.y * 2;
}

public void setAngle(float angle)
{
set(center.x,center.y,getWidth(),getHeight(),angle);
}

public float getAngle()
{
return angle;
}

public void setSize(float w,float h)
{
set(center.x,center.y,w,h,angle);
}

public float left()
{
return boundingRect.left;
}

public float right()
{
return boundingRect.right;
}

public float bottom()
{
return boundingRect.bottom;
}

public float top()
{
return boundingRect.top;
}

public RectF getBoundingRect()
{
return boundingRect;
}

public boolean overlaps(float left, float top, float right, float bottom)
{
if(right() < left)
{
return false;
}

if(bottom() < top)
{
return false;
}

if(left() > right)
{
return false;
}

if(top() > bottom)
{
return false;
}

return true;
}

public static float distance(float ax, float ay,float bx, float by)
{
if (ax < bx)
return bx - ay;
else
return ax - by;
}

public Vector2D project(float ax, float ay)
{
projVec.x = Float.MAX_VALUE;
projVec.y = Float.MIN_VALUE;

for (int i = 0; i < corner.length; ++i)
{
float dot = Vector2D.dot(corner[i].x,corner[i].y,ax,ay);

projVec.x = JMath.min(dot, projVec.x);
projVec.y = JMath.max(dot, projVec.y);
}

return projVec;
}

public Vector2D getCorner(int c)
{
return corner[c];
}

public int getNumCorners()
{
return corner.length;
}

public static float collisionResponse(OBB2D a, OBB2D b,  Vector2D outNormal)
{

float depth = Float.MAX_VALUE;

for (int i = 0; i < a.getNumCorners() + b.getNumCorners(); ++i)
{
Vector2D edgeA;
Vector2D edgeB;
if(i >= a.getNumCorners())
{
edgeA = b.getCorner((i + b.getNumCorners() - 1) % b.getNumCorners());
edgeB = b.getCorner(i % b.getNumCorners());
}
else
{
edgeA = a.getCorner((i + a.getNumCorners() - 1) % a.getNumCorners());
edgeB = a.getCorner(i % a.getNumCorners());
}

tempNormal.x = edgeB.x -edgeA.x;
tempNormal.y = edgeB.y - edgeA.y;

tempNormal.normalize();

projAVec.equals(a.project(tempNormal.x,tempNormal.y));
projBVec.equals(b.project(tempNormal.x,tempNormal.y));

float distance = OBB2D.distance(projAVec.x, projAVec.y,projBVec.x,projBVec.y);

if (distance > 0.0f)
{
return 0.0f;
}
else
{
float d = Math.abs(distance);

if (d < depth)
{
depth = d;
outNormal.equals(tempNormal);
}
}
}

float dx,dy;
dx = b.getCenter().x - a.getCenter().x;
dy = b.getCenter().y - a.getCenter().y;
float dot = Vector2D.dot(dx,dy,outNormal.x,outNormal.y);
if(dot > 0)
{
outNormal.x = -outNormal.x;
outNormal.y = -outNormal.y;
}

return depth;
}

public Vector2D getMoveDeltaVec()
{
return deltaVec;
}
};
``````
-

I'm now just unsure how to compute the point of contact when I hit a wall.

You can represent a wall with a simple plane.

The OBB-vs-plane intersection test is the simplest `separating axis test` of them all:

If two convex objects don't intersect, then there is a plane where the projection of these two objects will not intersect.

A box intersects plane only if the plane normal forms a separating axis. Compute the projection of the box center and the projected radius (4 dot products and a few adds) and you're good to go (you also get penetration depth `for free`).

The condition looks as follows:

|d| <= a1|n*A1| + a2|n*A2| + a3|n*A3|

Here:

`d` distance from the center of the box to the plane.

`a1...a3` the extents of the box from the center.

`n` normal of the plane

`A1...A3` the x,y,z-axis of the box

Some pseudocode:

``````//Test if OBB b intersects plane p
int TestOBBPlane(OBB b, Plane p)
{
// Compute the projection interval radius of b onto L(t) = b.c + t * p.n
float r = b.e[0]*Abs(Dot(p.n, b.u[0])) +
b.e[1]*Abs(Dot(p.n, b.u[1])) +
b.e[2]*Abs(Dot(p.n, b.u[2]));

// Compute distance of box center from plane
float s = Dot(p.n, b.c) – p.d;

// Intersection occurs when distance s falls within [-r,+r] interval
return Abs(s) <= r;
}
``````

The OBB-vs-OBB intersection test is more complicated.

Let us refer to this great tutorial:

In this case we no longer have corresponding separating lines that are perpendicular to the separating axes. Instead, we have separating planes that separate the bounding volumes (and they are perpendicular to their corresponding separating axes).

In 3D space, each OBB only has 3 unique planes extended by its faces, and the separating planes are parallel to these faces. We are interested in the separating planes parallel to the faces, but in 3D space, the faces are not the only concern. We are also interested in the edges. The separating planes of interest are parallel to the faces of the boxes, and the separating axes of interest are perpendicular to the separating planes. Hence the separating axes of interest are perpendicular to the 3 unique faces of each box. Notice these 6 separating axes of interest correspond to the 6 local (XYZ) axes of the two boxes.

So there are 9 separating axes to consider for edges collision in addition to the 6 separating axes we already have found for the faces collision. This makes the total number of possible separating axes to consider at 15.

Here are the 15 possible separating axes (L) you will need to test:

``````CASE 1:  L = Ax
CASE 2:  L = Ay
CASE 3:  L = Az
CASE 4:  L = Bx
CASE 5:  L = By
CASE 6:  L = Bz
CASE 7:  L = Ax x Bx
CASE 8:  L = Ax x By
CASE 9:  L = Ax x Bz
CASE 10: L = Ay x Bx
CASE 11: L = Ay x By
CASE 12: L = Ay x Bz
CASE 13: L = Az x Bx
CASE 14: L = Az x By
CASE 15: L = Az x Bz
``````

Here:

`Ax` unit vector representing the x-axis of A

`Ay` unit vector representing the y-axis of A

`Az` unit vector representing the z-axis of A

`Bx` unit vector representing the x-axis of B

`By` unit vector representing the y-axis of B

`Bz` unit vector representing the z-axis of B

Now you can see the algorithm behind the OBB-OBB intersection test.

By `test` i mean to test some axis as the separating axis. –  Sergey K. Nov 14 '12 at 12:36