In a 3D sense you are first concerned with not with a circle but with the plane where the circle lies on. Then you can find the point of intersection between the ray (line) and the plane (disk).

I like to use homogeneous coordinates for point, planes and lines and I hope you are familiar with vector dot `·`

and cross products `×`

. Here is the method:

Plane (disk) is defined by a point vector `r=[rx,ry,rz]`

and a normal direction vector `n=[nx,ny,nz]`

. Together they form a plane `W=[W1,W2]=[n,-r·n]`

.

Line (ray) is defined by two point vectors `r_A=[rAx,rAy,rAz]`

and `r_B=[rBx,rBy,rBz]`

. Together they form the line `L=[L1,L2]=[r_B-r_A, r_A×r_B]`

The intersecting Point is defined by `P=[P1,P2]=[L1×W1-W2*L2, -L2·W1]`

, or expanded out as

```
P=[ (r_B-r_A)×n-(r·n)*(r_A×r_B), -(r_A×r_B)·n ]
```

The coordinates for the point are found by `r_P = P1/P2`

where `P1`

has three elements and `P2`

is scalar.

Once you have the coordinates you check the distance with the center of the circle by `d=sqrt((r_p-r)·(r_p-r))`

and checking `d<=R`

where `R`

is the radius of the circle. Note the difference in notation between a scalar multiplication `*`

and a dot product `·`

If you know for sure that the circles lie on the ground (`r=[0,0,0]`

) and face up (`n=[0,0,1]`

) then you can make a lot of simplifications to the above general case.

[ref: Plucker Coordinates]

**Update:**

When using the ground (with +Z up) as the plane (where circles lie), then use `r=[rx,ry,0]`

and `n=[0,0,1]`

and the above intersection point simplifies to

```
r_p = [ rBy-rAy, rAx-rBx, 0] / (rAy*rBx-rAx*rBy)
```

of which you can check the distance to the circle center.