# Point Inside Circle Collision Response: How do you keep the Point inside of the circle?

I have given a diagram of my current small problem that I need help with. My main purpose is to keep the point from going outside the circle. Nothing else.

The center of the circle is positioned at (x, y).

I only solved a little bit of the problem, and that is the collision detection part of my problem, as given below:

``````public void bound(Point p, Circle c){
double distance = Math.hypot(p.x - c.x, p.y - c.y);
//Clueless from here on out.
}
}
``````

The part where I left a comment is the spot I couldn't figure anything out. I did tried to set the point's `velocityX` and `velocityY` to 0, but I realized the point will just stay put whenever it touches the circle.

So, I'm sort of stuck.

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This isn't really a programming question, it's a mechanics question (and is therefore off-topic). Assuming an elastic collision, the reflection is specular. You just need to calculate the tangent to the circle at the point of collision. –  Oliver Charlesworth Jul 20 '12 at 14:54
How do you get the tangent to the circle at the point of collision? I tried `Math.atan2()`, but people say that's an arc tangent. Should I be using `Math.tan()` instead? –  tom_mai78101 Jul 20 '12 at 14:59
It's not very tricky, but it's hard to explain without a diagram. I suggest you draw out a diagram, and figure out the geometry. –  Oliver Charlesworth Jul 20 '12 at 15:00
Is this homework? –  davidfrancis Jul 20 '12 at 15:04
No, it's not homework. –  tom_mai78101 Jul 20 '12 at 15:06

I have resolved this issue.

``````public void reflect(Hole h){
//R = -2*(V dot N)*N + V
//N is normalized.
double nx = (this.position[0]+this.diameter/2) - (h.x+16);
double ny = (this.position[1]+this.diameter/2) - (h.y+16);
double nd = Math.hypot(nx, ny);
if (nd == 0)
nd = 1;
nx /= nd;
ny /= nd;
double dotProduct = this.speed[0]*nx+this.speed[1]*ny;
this.speed[0] += (float)(-2*dotProduct*nx);
this.speed[1] += (float)(-2*dotProduct*ny);
}

public void reflectResponse() {
for (int i = 0; i <= 1; i++) {
position[i] -= speed[i];
speed[i] *= 0.992f;
}
}
``````

I tried Oli Charlesworth's method from the comments, but it made things more... "complicated" than I expected. Someone else mentioned I used a completely 100%, vector-based algorithm, since I'm relying a lot on vector-based movements.

TIPS TO THOSE WHO DO READ THIS:

1. If you're working on object movements and collisions with vectors, seek vector-based algorithms.
2. If you're working with angles (either degrees or radians), use Oli Charlesworth's method.
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