I have a line from A to B and a circle positioned at C with the radius R.
What is a good algorithm to use to check whether the line intersects the circle? And at what coordinate along the circles edge it occurred?
I have a line from A to B and a circle positioned at C with the radius R. What is a good algorithm to use to check whether the line intersects the circle? And at what coordinate along the circles edge it occurred? 


Taking
Compute: Then the intersection is found by..
to get:
So we get:



No one seems to consider projection, am I completely off track here? Project the vector Like this: 


I would use the algorithm to compute the distance between a point (circle center) and a line (line AB). This can then be used to determine the intersection points of the line with the circle. Let say we have the points A, B, C. Ax and Ay are the x and y components of the A points. Same for B and C. The scalar R is the circle radius. Here is the algorithm



Okay, I won't give you code, but since you have tagged this algorithm, I don't think that will matter to you. First, you have to get a vector perpendicular to the line. You will have an unknown variable in That is, This will give you the closest point on the line to the circle. 


Another method uses the triangle ABC area formula. The intersection test is simpler and more efficient than the projection method, but finding the coordinates of the intersection point requires more work. At least it will be delayed to the point it is required. The formula to compute the triangle area is : area = bh/2 where b is the base length and h is the height. We chose the segment AB to be the base so that h is the shortest distance from C, the circle center, to the line. Since the triangle area can also be computed by a vector dot product we can determine h.
UPDATE 1 : You could optimize the code by using the fast inverse square root computation described here to get a good approximation of 1/LAB. Computing the intersection point is not that difficult. Here it goes
If h = R then the line AB is tangent to the circle and the value dt = 0 and E = F. The point coordinates are those of E and F. You should check that A is different of B and the segment length is not null if this may happen in your application. 


You can find a point on a infinite line that is nearest to circle center by projecting vector AC onto vector AB. Calculate the distance between that point and circle center. If it is greater that R, there is no intersection. If the distance is equal to R, line is a tangent of the circle and the point nearest to circle center is actually the intersection point. If distance less that R, then there are 2 intersection points. They lie at the same distance from the point nearest to circle center. That distance can easily be calculated using Pythagorean theorem. Here's algorithm in pseudocode:
EDIT: added code to check whether found intersection points actually are within line segment. 


This solution I found seemed a little easier to follow then some of the other ones. Taking:
I would solve for the equation of the line in slopeintercept form. However, I didn't want to have to deal with difficult equations with
By the way, whenever I subtract points from each other I am subtracting the Anyway, I now solve for the equation of the line with
Ok. Now I need to set these equations equal. First I need to solve the circle's equation for
Then I set them equal:
And solve for the quadratic equation (
Now I have my
So I put this into the quadratic formula:
And substitute in by values then simplify as much as possible:
This is almost as far as it will simplify. Finally, separate out to equations with the ±:
Then simply plug the result of both of those equations into the
I hope this helps! P.S. If anyone finds any errors or has any suggestions, please comment. I am very new and welcome all help/suggestions. 


You'll need some math here: Suppose A = (Xa, Ya), B = (Xb, Yb) and C = (Xc, Yc). Any point on the line from A to B has coordinates (alpha*Xa + (1alpha)Xb, alphaYa + (1alpha)*Yb) = P If the point P has distance R to C, it must be on the circle. What you want is to solve
that is
if you apply the ABCformula to this equation to solve it for alpha, and compute the coordinates of P using the solution(s) for alpha, you get the intersection points, if any exist. 


If you find the distance between the center of the sphere (since it's 3D I assume you mean sphere and not circle) and the line, then check if that distance is less than the radius that will do the trick. The collision point is obviously the closest point between the line and the sphere (which will be calculated when you're calculating the distance between the sphere and the line) Distance between a point and a line: 


I wrote a small script to test intersection by projecting circle's center point on to line.
http://jsfiddle.net/ercang/ornh3594/1/ If you need to check the collision with the segment, you also need to consider circle center's distance to start and end points.



If the line's coordinates are A.x, A.y and B.x, B.y and the circles center is C.x, C.y then the lines formulae are: x = A.x * t + B.x * (1  t) y = A.y * t + B.y * (1  t) where 0<=t<=1 and the circle is (C.x  x)^2 + (C.y  y)^2 = R^2 if you substitute x and y formulae of the line into the circles formula you get a second order equation of t and its solutions are the intersection points (if there are any). If you get a t which is smaller than 0 or greater than 1 then its not a solution but it shows that the line is 'pointing' to the direction of the circle. 


Just an addition to this thread... Below is a version of the code posted by pahlevan, but for C#/XNA and tidied up a little:



This Java Function returns a DVec2 Object. It takes a DVec2 for the center of the circle, the radius of the circle, and a Line.






Weirdly I can answer but not comment... I liked Multitaskpro's approach of shifting everything to make the centre of the circle fall on the origin. Unfortunately there are two problems in his code. First in the underthesquareroot part you need to remove the double power. So not:
but:
In the final coordinates he forgets to shift the solution back. So not:
but:
The whole function then becomes:



I have created this function for iOS following the answer given by


