# How to find whether a point in a 3D space lies inside a truncated cone?

How can I detect if a point is inside of a cone or not, in 3D space? will not help because a truncated cone can be a cylinder.

I tried another method which involves too many calculations and is huge.

I'm looking for easier ways to find the presence/absence of a point inside a truncated cone.

``````Mid point of bottom of the truncated cone -> x,y,z
Mid point of top of the truncated cone -> x, y2, z
BottomRadius = r1
TopRadius = r2
``````
-

## 2 Answers

It seems it would be sufficient to test for two conditions, which both must be true:

• the point must be above the cone base, and below cone top. A one dimensional test. Use distance from cone base for next step, to be performed only if the result of this step was found to be true.
• the point must be within circumference of the circular cone slice, as determined by the distance from base. Again a relatively simple, also one-dimensional test (distance of point from cone axis compared against slice radius)

Seems pretty straightforward, or am I missing something?

-
This solution looks so cool.. –  cegprakash Jul 4 at 10:01

Sorry for the sloppy formulation but I would proceed as follows:

1. Compute the center points c_1, c_2 of both cone circles.
2. Compute a line going through c_1 and c_2
3. Compute the distance of your point p to this line and during this, calculate the point q on the line being closest to p (see the Wikipedia article)
4. If q is not between c_1 and c_2, p lies outside
5. If q is between c_1 and c_2, the distance dist(p,q) has to be smaller than the radius of the cone at point q. Maybe the radius can be calculated something like this: r(q) := dist(q,c_1)/dist(c_1, c_2) * r_1 + dist(q,c_2)/dist(c_1, c_2) * r_2 with r_1 being the circle radius at c_1 and r_2 the radius of the other circle.
6. So if dist(p,q) > r(q) , the point lies outside

So two conditions have to be tested

-
This method is what I specified as "method which involves too many calculations". :) –  cegprakash Jul 4 at 10:51
I think this describes pretty much the same approach, only in different words. –  Deleted User Jul 4 at 10:55
It looks only more complicated since I tried to include the actual formulas :-) But Bushmill and I had the same idea so this is an indicator that this might be a good way to do it –  PhilLab Jul 4 at 11:38