# Calculate top-left and bottom right of a Rectangle GIven Origin, Direction & Size

I did a search on this, but didn't find a question that quite matched what I was after. I want the user to be able to define a textured plane. The parameters I have are:

• Size (A Vector2)
• Direction (A Vector3)
• Origin (A Vector3)

So, I want to be able to calculate the 4 vertices of the rectangle given the above information. So, if I wanted a plane facing up, with a width and height of 1000:

• Size = (1000, 1000)
• Direction = 0, 1, 0 (Up)
• Origin = 0, 0, 0

So this would define a plane on the X & Z axis, facing upwards. What I do not understand is how to calculate the 4 corners in 3D space given this information. Do I need extra information, or is there a better way to arbitrarily specify a plane?

Edit : Current Code

In the following code:

• Size = 10000, 10000
• Center = 0, 0, 0
• Normal = 0, 1, 0

``````        Vector3 arb = new Vector3(1, 1, 1);
Vector3 planeY = Vector3.Normalize(Vector3.Cross(Normal, arb));
Vector3 planeX = Vector3.Normalize(Vector3.Cross(Normal, planeY));

planeX *= Size.X / 2;
planeY *= Size.Y / 2;

Vector3[] ret =  new Vector3[4]
{
(Center - planeX - planeY),
(Center - planeX + planeY),
(Center + planeX - planeY),
(Center + planeX + planeY)
};
``````
-

Your plane isn't fully defined yet. You need another vector going along the plane, the so called 'tangent' vector. In your above example, where should the Y-axis of the texture be pointing? Along the X-axis, along the Z-axis? Or maybe a completely different user defined axis? Your tangent vector is a vector that should point in the general direction where the X-axis of the plane should go.

Let's say we have a tangent vector as well, it doesn't neccesarilly need to point along the plane. You can construct the plane as follows:

``````        Vector3[] vertices(Vector2 size, Vector3 center, Vector3 normal, Vector3 tangent)
{
Vector3 planeY = Vector3.Normalize(Vector3.Cross(normal, tangent));
Vector3 planeX = Vector3.Normalize(Vector3.Cross(normal, planeY));

planeX *= size.X / 2;
planeY *= size.Y / 2;

vertices = new Vector3[]
{
(center - planeX - planeY),
(center - planeX + planeY),
(center + planeX - planeY),
(center + planeX + planeY),
};
return vertices;
}
``````

planeX and planeY are normalized vectors which point along X and Y axes of the plane itself. By multiplying these by size / 2, we get 2 vectors that span from the center to the edge of the plane in both X and Y directions. By adding these two together in different ways, we get the four corners.

Here's a diagram so you can get a better picture in your head. The tangent vector T is "flattened" onto the X-axis.

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Hi Hannash, thanks for your comment and example code. Assuming `tangent` is the UP Vector in your example, I reconstructed what you did passing `Vector3.Up` instead of tangent, but planeY's values are all `NaN`, so not sure what's happening here. What might be the reason is that my Normal is `0,1,0`, because I want this particular plane to be facing upwards. And so it's getting called as `Vector3.Cross("0, 1, 0", "0, 1, 0")' which I am sure is wrong. –  Moo-Juice Oct 20 '11 at 17:10
That is exactly the reason :), choose any other value for up and it will work fine. You can't define a plane with the same X-axis as the direction it is facing itself. –  Hannesh Oct 20 '11 at 17:16
I figured so I provided a up-vector of (1,1,1). Given an origin of `0, 0, 0`, a Normal of `0, 1, 0` and a Size of `10000, 10000`, I get some very odd results. [0] = `{X:0.0002441406 Y:0 Z:7071.068}`. [1] = `{X:7071.068 Y:0 Z:0.0002441406}`, [2] = `{X:-7071.068 Y:0 Z:-0.0002441406}` and [3] = `{X:-0.0002441406 Y:0 Z:-7071.068}`. Trying to figure out what is wrong. I really appreciate your help on this. –  Moo-Juice Oct 20 '11 at 17:19
I just updated my post with the current code I have. When it comes to maths and me, the wheel's going but the hamster's dead. –  Moo-Juice Oct 20 '11 at 17:23
That looks right. What were you expecting? The plane lies on the X & Z axis, (the X & Z components are ~0). You tangent points diagonally, so your plane is rotated by 45 degrees. Try Vector3.Left for a "normal" plane. –  Hannesh Oct 20 '11 at 17:33

This is fine as a definition of a plane: you have a point and the normal vector. You need to get two vectors (A & B) on the plane and add one (A * one of the size values) to the origin to get the second corner. Add the second vector (B * the other size value) to get the third corner and add both vectors * their corresponding size values to the origin to get the forth corner.

To get the first vector, calculate the cross product of the normal vector (Direction) with an arbitrary vector (not equal to the direction). This will give you vector A. To get vector B calculate the cross product of A and the Direction.

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Thank you for this. I am not entirely sure what you mean by an "arbitrary vector (not equal to the direction)". I am trying to visualise what this would look like, but not getting very far. Thanks for your prompt response. –  Moo-Juice Oct 20 '11 at 16:42
Well, the direction is a 3D vector, so create a new vector with any 3 values that are not equal to the Direction vector's values. The cross product of this will give you a normalized vector orthoganal to the Direction. You can multiply this new vector by one of the Size properties to get the second corner. –  Kell Oct 20 '11 at 16:49