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I have a 3D point (point_x,point_y,point_z) and I want to project it onto a 2D plane in 3D space which (the plane) is defined by a point coordinates (orig_x,orig_y,orig_z) and a unary perpendicular vector (normal_dx,normal_dy,normal_dz).

How should I handle this?enter image description here

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  • Consult the "orthographic projection" section on: en.wikipedia.org/wiki/3D_projection Mar 7, 2012 at 16:48
  • From the answers below it seems there is confusion about what result you're looking for out of this projection: Is it the 3D point on the plane nearest to your point of interest? Is it a 2D point in the coordinate system of the plane? Something else?
    – tmpearce
    Mar 7, 2012 at 17:13
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    It seems clear to me that he wants to find the point on the plane that is nearest to (point_x, point_y, point_z); that is the point labeled (planar_x, planar_y, planar_z) in the diagram. (All coordinates in the global coordinate system.) Therefore I believe the answer from @tmpearce is correct.
    – aldo
    Mar 7, 2012 at 18:31

7 Answers 7

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  1. Make a vector from your orig point to the point of interest:

v = point-orig (in each dimension);

  1. Take the dot product of that vector with the unit normal vector n:

dist = vx*nx + vy*ny + vz*nz; dist = scalar distance from point to plane along the normal

  1. Multiply the unit normal vector by the distance, and subtract that vector from your point.

projected_point = point - dist*normal;

Edit with picture: I've modified your picture a bit. Red is v. dist is the length of blue and green, equal to v dot normal. Blue is normal*dist. Green is the same vector as blue, they're just plotted in different places. To find planar_xyz, start from point and subtract the green vector.

Projection of point onto plane

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  • 1
    What's needed is the cross product, not dot. But this is also not enough. Please read my answer
    – valdo
    Mar 7, 2012 at 16:52
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    @valdo Depends if you want the nearest distance to the plane, or a vertical point. I interpreted his post as wanting the nearest point.
    – tmpearce
    Mar 7, 2012 at 16:55
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    Ok, if so - you're right. But I interpret it other way. The word "projection" usually means obtaining 2 coordinates on the plane. Nevertheless let's the question author decide what he/she meant.
    – valdo
    Mar 7, 2012 at 17:01
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    You need to incorporate d to get the perpendicular distance from a point to a plane, otherwise you are assuming the plane passes through the origin.
    – bobobobo
    Jul 15, 2013 at 18:40
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    @dev_nut Yes, the normal vector in the question was already defined as unit length, and I continued to use it that way. Thanks for your comment though - it made me realize this is worth clarifying in the answer. I edited the answer to make it clear that the unit normal is the appropriate vector to use.
    – tmpearce
    Apr 7, 2014 at 20:12
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This is really easy, all you have to do is find the perpendicular (abbr here |_) distance from the point P to the plane, then translate P back by the perpendicular distance in the direction of the plane normal. The result is the translated P sits in the plane.

Taking an easy example (that we can verify by inspection) :

Set n=(0,1,0), and P=(10,20,-5).

enter image description here

The projected point should be (10,10,-5). You can see by inspection that Pproj is 10 units perpendicular from the plane, and if it were in the plane, it would have y=10.

So how do we find this analytically?

The plane equation is Ax+By+Cz+d=0. What this equation means is "in order for a point (x,y,z) to be in the plane, it must satisfy Ax+By+Cz+d=0".

What is the Ax+By+Cz+d=0 equation for the plane drawn above?

The plane has normal n=(0,1,0). The d is found simply by using a test point already in the plane:

(0)x + (1)y + (0)z + d = 0

The point (0,10,0) is in the plane. Plugging in above, we find, d=-10. The plane equation is then 0x + 1y + 0z - 10 = 0 (if you simplify, you get y=10).

A nice interpretation of d is it speaks of the perpendicular distance you would need to translate the plane along its normal to have the plane pass through the origin.

Anyway, once we have d, we can find the |_ distance of any point to the plane by the following equation:

enter image description here

There are 3 possible classes of results for |_ distance to plane:

  • 0: ON PLANE EXACTLY (almost never happens with floating point inaccuracy issues)
  • +1: >0: IN FRONT of plane (on normal side)
  • -1: <0: BEHIND plane (ON OPPOSITE SIDE OF NORMAL)

Anyway,

enter image description here

Which you can verify as correct by inspection in the diagram above

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    @bobobobo: You got me really confused there by writing "...just add -10...". You inexplicitly multiplied the result of np + d by -1, just to write add instead of subtract. :P I spent some time interpreting your answer, so I'll summarize it for others. Given a plane defined by normal n and scalar d, the point p' on the plane closest to the given point p can be found by: 1) p' = p - (np + d) * n If the plane is instead defined by normal n and a point on the plane o you suggest using: 2) d = -no
    – Mr.H
    Jan 27, 2017 at 14:34
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This answer is an addition to two existing answers. I aim to show how the explanations by @tmpearce and @bobobobo boil down to the same thing, while at the same time providing quick answers to those who are merely interested in copying the equation best suited for their situation.

Method for planes defined by normal n and point o

This method was explained in the answer by @tmpearce.

Given a point-normal definition of a plane with normal n and point o on the plane, a point p', being the point on the plane closest to the given point p, can be found by:

  1. p' = p - (n ⋅ (p - o)) × n

Method for planes defined by normal n and scalar d

This method was explained in the answer by @bobobobo.

Given a plane defined by normal n and scalar d, a point p', being the point on the plane closest to the given point p, can be found by:

  1. p' = p - (np + d) × n

If instead you've got a point-normal definition of a plane (the plane is defined by normal n and point o on the plane) @bobobobo suggests to find d:

  1. d = -no

and insert this into equation 2. This yields:

  1. p' = p - (np - no) × n

A note about the difference

Take a closer look at equations 1 and 4. By comparing them you'll see that equation 1 uses n ⋅ (p - o) where equation 2 uses np - no. That's actually two ways of writing down the same thing:

  1. n ⋅ (p - o) = np - no = np + d

One may thus choose to interpret the scalar d as if it were a 'pre-calculation'. I'll explain: if a plane's n and o are known, but o is only used to calculate n ⋅ (p - o), we may as well define the plane by n and d and calculate np + d instead, because we've just seen that that's the same thing.

Additionally for programming using d has two advantages:

  1. Finding p' now is a simpler calculation, especially for computers. Compare:
  • using n and o: 3 subtractions + 3 multiplications + 2 additions
  • using n and d: 0 subtractions + 3 multiplications + 3 additions.
  1. Using d limits the definition of a plane to only 4 real numbers (3 for n + 1 for d), instead of 6 (3 for n + 3 for o). This saves ⅓ memory.
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    This will be extremely helpful, except I'm not sure what . means vs * Could you show in simple terms what the operations boil down to on a per component basis for the vectors?
    – M2tM
    Jul 15, 2022 at 5:30
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    Hi @M2tM. It's been a while since I wrote this answer. ⋅ means the dot product. With * I meant to indicate the cross product. (The latter was not immediately obvious to myself as well, but can be deduced from the fact that p and p' are in the same plane of which n is the normal. This means that p' = p + some vector orthogonal to n. Orthogonal vectors are a hint in the direction of the cross product.) I replaced any * in my answer with × for future readers. Thanks for noticing!
    – Mr.H
    Jul 17, 2022 at 21:20
  • Awesome, thank you! Great thoughts, I figured . was dot product, but I wasn't getting what I expected so I wanted to dig in a bit and ask and it turns out indeed, I was treating the * as multiply instead of cross. Thanks for re-visiting this!
    – M2tM
    Jul 18, 2022 at 22:05
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    @Mr.H how can we make a cross product between a scalar and a vector? A cross product is defined between two vectors if I'm not mistaken? (en.wikipedia.org/wiki/Cross_product) eqs. 2 and 4 contain (n⋅p + d) and (n⋅p - n⋅o), which are both scalar quantities. Am I misunderstanding?
    – Glxblt76
    Sep 29, 2022 at 8:25
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    At least one equation in this is wrong (the first one). That should not be a cross product.
    – Basti
    Oct 25, 2023 at 12:10
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It's not sufficient to provide only the plane origin and the normal vector. This does define the 3d plane, however this does not define the coordinate system on the plane.

Think that you may rotate your plane around the normal vector with regard to its origin (i.e. put the normal vector at the origin and "rotate").

You may however find the distance of the projected point to the origin (which is obviously invariant to rotation).

Subtract the origin from the 3d point. Then do a cross product with the normal direction. If your normal vector is normalized - the resulting vector's length equals to the needed value.

EDIT

A complete answer would need an extra parameter. Say, you supply also the vector that denotes the x-axis on your plane. So we have vectors n and x. Assume they're normalized.

The origin is denoted by O, your 3D point is p.

Then your point is projected by the following:

x = (p - O) dot x

y = (p - O) dot (n cross x)

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  • :You are right , the point is above the plane ,and vertical to it.So , you say do "point-orig" ,then cross product of the previous vector with normal and the result is what i want?
    – George
    Mar 7, 2012 at 17:03
  • Just to clarify for future readers: n cross x results in y, in case you have y given instead of n. The projection to 2D is just the dot-product projection on the normalized axis directions. Feb 10, 2015 at 9:25
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Let V = (orig_x,orig_y,orig_z) - (point_x,point_y,point_z)

N = (normal_dx,normal_dy,normal_dz)

Let d = V.dotproduct(N);

Projected point P = V + d.N

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  • Not quite: everything's good up until the last step, but instead you want point - d*N
    – tmpearce
    Mar 7, 2012 at 16:54
  • my first step is : V = (orig_x,orig_y,orig_z) - (point_x,point_y,point_z). So my base point is 'point' not the origin.. so, I should add.. Mar 7, 2012 at 17:06
  • is d.N a dot product or a cross product?
    – BenKoshy
    Feb 26, 2020 at 22:27
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I think you should slightly change the way you describe the plane. Indeed, the best way to describe the plane is via a vector n and a scalar c

(x, n) = c

The (absolute value of the) constant c is the distance of the plane from the origin, and is equal to (P, n), where P is any point on the plane.

So, let P be your orig point and A' be the projection of a new point A onto the plane. What you need to do is find a such that A' = A - a*n satisfies the equation of the plane, that is

(A - a*n, n) = (P, n)

Solving for a, you find that

a = (A, n) - (P, n) = (A, n) - c

which gives

A' = A - [(A, n) - c]n

Using your names, this reads

c = orig_x*normal_dx + orig_y*normal_dy+orig_z*normal_dz;
a = point_x*normal_dx + point_y*normal_dy + point_z*normal_dz - c;
planar_x = point_x - a*normal_dx;
planar_y = point_y - a*normal_dy;
planar_z = point_z - a*normal_dz;

Note: your code would save one scalar product if instead of the orig point P you store c=(P, n), which means basically 25% less flops for each projection (in case this routine is used many times in your code).

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Let r be the point to project and p be the result of the projection. Let c be any point on the plane and let n be a normal to the plane (not necessarily normalised). Write p = r + m d for some scalar m which will be seen to be indeterminate if their is no solution. Since (p - c).n = 0 because all points on the plane satisfy this restriction one has (r - c).n + m(d . n) = 0 and so m = [(c - r).n]/[d.n] where the dot product (.) is used. But if d.n = 0 there is no solution. For example if d and n are perpendicular to one another no solution is available.

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