# Minimum perpendicular Distance of a point to a line in 3D plane algorithm

How to find the minimum perpendicular distance of point from a line in 3D plane?

Please give me the logic and I will try to code on myself.

Please let me know how to do it in terms of x,y,z that is in terms of coordinate systems.

I am finding it a bit difficult to find the right solution which will be easy from a coding point of view. Online solutions are little bit rusty to understand. So please help me.

Please note line is given in terms of 3D space equation.

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in which form do you have the rect expression? –  Lopoc Oct 23 '09 at 21:44
In terms of x, y, z format. –  Test Oct 23 '09 at 21:51
A line is not determined by one equation in 3-d space. Do you mean the distance to a plane? Otherwise, how is the line specified? –  UncleO Oct 23 '09 at 21:56

Given point A and a line, pick two different points on the line (B and C). Calculate the area of the triangle ABC with use of Heron's formula. Multiply the area by 2 and divide it by length of [BC]. You have the result you needed.

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Is it valid for a 3d plane. –  Test Oct 23 '09 at 21:50
Three points always form a plane. A triangle always is a triangle. @Pavel: nice trick, by the way. –  Arthur Reutenauer Oct 23 '09 at 21:56
Three points form a plane if they are not all co-linear. –  JimN Oct 23 '09 at 22:05
@Test , yes, that will work for 3d. Just use 3d distance to calculate lengths of triangle edges. @JimN , if A is happen to be on the line, the algorithm will work anyway. @Arthur Reutenauer , a +1 for a "nice trick" ? ;-) –  Pavel Shved Oct 23 '09 at 22:11
@Pavel: Agreed. I was responding to Arthur's comment. –  JimN Oct 23 '09 at 22:23

For an infinite line, the minimum distance is the length of line segment at right-angles to the infinite line passing through the point starting at the line and ending at the point. The direction of the perpendicular is given by the cross product of the unit normal to the plane and the unit vector along the line, the foot of the perpendicular is given by simultaneous solution of the equation for the first line, and for the perpendicular through the point. The distance between the points is what you are after.

For a finite line, this is a solution only if the foot of the perpendicular is on the segment; otherwise it's the shorter of the distance between the point and either end of the segment.

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You say the line is given as an equation in 3D, but really planes are given by equations. And since the line is said to be lying in a 3D plane, presumably given by another equation, the line is actually the intersection of two planes.

To get the direction vector of the line, take the cross product of the normals to the two planes. If you use Pavel's method, you don't need this.

To get a point on the line, pick some value for x, say x = 0. Then solve the two equations for y and z after plugging in that value. To find another point to use in Pavel's method, set x to some other value, say x = 1, and solve the system again.

If the line is oriented the wrong way (perpendicular to the x axis), x may be a fixed value. In that case, try setting y to two fixed values. If that still doesn't work, try z. Also, check that the original planes are not parallel, so that there actually is a line of intersection.

To solve the question without Pavel's method, cross the direction of the line with the vector formed by the given point and a point you found on the line. Now cross that result with the line direction to get a new vector. Dot that vector with the original point and again with a point on the line. Take the difference, and divide by the length of the vector.

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+1 for the mental image of line as a plane in 3D. I got stuck until I knew that their intersection is actually the line. –  karmanaut Mar 16 '13 at 5:30