Okay so I'm trying to get a separating axis theorem algorithm to work (for collision detection) and I need to find the minimal perpendicular vector between a point and a line. I'm not asking for the minimum perpendicular distance (which I know how to find) but rather the vector that would have the same magnitude as that distance and that goes from an arbitrary point and a point on the line. I know the location of the point, a point on the line, and a unit vector giving the direction of the line.

What I tried doing was first finding the minimal distance between the point and the line.

The next part is confusing but I: 1) Found the vector between the point and the point on the line I know 2) Found the vector between the point on the line and the point on the line plus the unit vector giving the direction of the line 3) Took the cross product of these two vectors (I'll call this cross product A) 4) Took the cross product of the unit vector giving the direction of the line and the vector from cross product A (I'll call this cross product B) 5) Normalized cross product B 6) Scaled cross product B by the minimal distance

Anyways that whole attempt failed miserably. Can anyone tell me how I am supposed to find this vector?

  • are you writing a program to do this, or just trying to do your Physics/Calc homework? Mar 8, 2011 at 1:38
  • 3
    It's for a game I'm writing for fun, like I said it's for collision detection.
    – user421215
    Mar 8, 2011 at 1:41
  • Though this is a physics question, as it is put in a generic form, it applies to other realms. It helped me to find the normal on a cylinder collision for ray tracing.
    – fde-capu
    Aug 25, 2020 at 18:57

2 Answers 2


If I understood your question correctly, I believe this is what you're looking for:

P - point
D - direction of line (unit length)
A - point in line

X - base of the perpendicular line

  / |
 /  v

(P-A).D == |X-A|

X == A + ((P-A).D)D
Desired perpendicular: X-P

where the period represents the dot product and |X-A| means magnitude.

  • Right. That's what I meant by "period" :)
    – Pablo
    Mar 8, 2011 at 2:29
  • sorry missed that. Anyway it seems like it wants to work but for some reason my SAT algorithm is a little off. Things are colliding when they shouldn't be. I'm thinking what you gave me probably works since the collisions seem 'more correct' now, and I have all sorts of markers which seem more on target now. Thank you very much but unfortunately it seems I've made some other sort of error in code.
    – user421215
    Mar 8, 2011 at 2:42
  • OMG yes finally got it to work, I had unintentionally been applying a rotation transformation twice.
    – user421215
    Mar 8, 2011 at 4:13
  • At X == A + ((P-A).D)D, what operand is in front of the final D?
    – Emil S.
    Feb 24, 2022 at 19:56
  • To answer my own question: It's normal scalar multiplication because (P-A).D is a scalar. Maybe I was working too late yesterday.
    – Emil S.
    Feb 25, 2022 at 15:30

enter image description here

From the above figure, you have:

q = p + s --> s = q - p = q - (p2-p1) = q + p1 - p2

==> s^ = |q - p2 - p1| / |s|   (unitary vector)

Also:   |s| = |q| sin c = |q|sin(b-a)

b = arcsin (qy / |q|); a = arcsin( p1y / |p1| )

where: |q| = (qx^2 + qy^2)^1/2

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