# How do I calculate a normal?

Okay, so say I got a rectangle (This is all 2d) made from Thing A's x,y,width and height. How would I calculate it's normal?

-
What do you mean by a normal of a rectangle? –  biziclop Mar 29 '11 at 17:20
I don't know, maybe like which way it's facing? –  CyanPrime Mar 29 '11 at 17:23
I need to know which way it's facing so I can reflect stuff off it. –  CyanPrime Mar 29 '11 at 17:26
@CyanPrime In 2d, there's only one way a rectangle can be facing, okay, maybe two: up and down. I don't think that's what you want. What do you need this normal for then? –  biziclop Mar 29 '11 at 17:27
He means a normal from a line, not a normal from a rectangle. –  J T Mar 29 '11 at 19:35

Cyan,

You are NOT looking for the normal as defined by the cross product or 3 dimensions. One minute and I will explain..

EDIT:

From this answer, it is obvious that what you are looking for is simply a vector perpendicular to a line. Not a vector perpendicular to a plane.

To mathematically evaluate

``````R = A - 2<A, N> N
``````

You must first have a firm understanding of a Euclidean Vector.

Given a vector A (your angle of incidence):

``````A = <ax, ay>
``````

Given the vector B (which represents a vector of the wall being bounced off of):

``````B = <bx, by>
``````

The normal (perpendicular) to this vector is simply rotated 90 degrees. Mathematically:

``````N = <nx, ny> = <-bx, by>
``````

Therefore R =

``````R = A - 2<A, N> N = ...
``````

Lets first evaluate the Dot Product

``````<A, N> = ax*nx + ay*ny = ax*(-bx) + ay*by = ay*by - ax*bx
``````

Then:

``````R = <ax, ay> - 2*(ay*by - ax*bx) * N
= <ax, by> - <2*(ay*by - ax*bx)*nx, 2*(ay*by - ax*bx)*ny>
= <ax, by> - <2*(ay*by - ax*bx)*(-bx), 2*(ay*by - ax*bx)*(by)>
= < ax + 2*bx*(ay*by - ax*bx), ay - 2*by*(ay*by - ax*bx) >
``````

So all you need to do is determine a vector representing the wall you are bouncing off of (which is B), and your incident Vector (which is A).

EDIT (because of comment):

You really ought to spend time reviewing the link I posted to Euclidean vectors...

The basic idea is that you define an arbitrary mathematical origin. (Say for example, and the bottom of your wall). A vector representing your wall is then just an arrow, from the top to the bottom (or the bottom to the top). With the origin described at the base, this arrow will point 0 units in the x direction, but 100 units in the y direction. Therefore your vector for the wall (B) is just:

``````B = < 0, 100 >
``````

(Note that the width of your wall is unimportant - it would bounce the same with a wall 1px thick, 50 px thick, or 100px thick).

But you'll want to normalize this vector so it has unit magnitude (length of 1). So the vector becomes:

``````B = <0, 1>
``````

This follows from:

``````Vector length = sqrt( bx^2 + by^2 ) = sqrt( 0^2 + 1^2 ) = 1
``````

N is then:

``````N = <1, 0>  // for the left hand side wall
N = <-1, 0> // for the right hand side wall
``````
-
Sorry about the late reply, I fell asleep. But I'm wondering something. B = <bx, by> Now how would I get 1 number like that from a line? Let's say my line is (50, 0) and (50, 100) making it 1px wide, and 100px tall, and a normal of 90 (i think?) how do I turn this wall into one vector for B? –  CyanPrime Mar 29 '11 at 19:12
@CyanPrime: See my post. Please review the vector mathematics I posted a link to. –  J T Mar 29 '11 at 19:24
@J T - I think your eq. 'N = <nx, ny> = <-bx, by>' should actually be <-by, bx>? –  ysap Mar 30 '11 at 1:19
@ysap: You are correct for a a 90 degree clockwise rotation. But I don't think it matters all that much in this case. :) –  J T Mar 31 '11 at 17:56

If by "normal" you mean a perpendicular vector, take a look at the cross product: for the vectors

``````<a1, a2, a3>
``````

and

``````<b1, b2, b3>
``````

the cross product is

``````<a2 * b3 - b2 * a3, a1 * b3 - b1 * a3, a1 * b2 - b1 * a2>
``````

... but "normal" in pure 2D doesn't make much sense.

-
Cross product is for coordinates in 3 dimensional space. –  Mahesh Mar 29 '11 at 17:22
@mahesh: 2D is 3D with one dimension fixed... –  Marc B Mar 29 '11 at 17:23
Using this approach, the normal of every rectangle is (0,0,1). –  biziclop Mar 29 '11 at 17:25
@CyanPrime: It works for 2D (and as others pointed out, it gives you some multiple of `<0, 0, 1>`), but the answer is in 3D by definition... –  Mehrdad Mar 29 '11 at 17:26
@CyanPrime In this case you need the normal of an edge of the rectangle. Since your rectangles are always aligned with your coordinates, your normals will be (0,1), (0,-1), (1,0) or (-1,0) depending on whether it's the top, left, bottom or right edge. –  biziclop Mar 29 '11 at 17:35

Take the vectors that define the edges of your rectangle as the vectors you are trying to cross.

-

Well if your rectangle is on the XY plane, then a normal is (0,0,1). No need for algebra!

-
It can be (0, 0, -1) too –  Andrew Mar 29 '11 at 17:26
@Andrew: Note that @Blindy said "a normal is (0,0,1)", not "the normal". –  Mehrdad Mar 29 '11 at 17:28
What if it's rotated to like a 60 degree angle? I'm hoping for a formula I can code in and make it so stuff will bounce off the rect no matter the angle. –  CyanPrime Mar 29 '11 at 17:28
@Mehrdad, precisely. @CyanPrime, Mehrdad already gave you the general formula. I don't think you understand what exactly a normal is. –  Blindy Mar 29 '11 at 17:59

The normal to the whole rectangle will be perpendicular to the plane of the rectangle (along the third dimension).

If you mean normal to a side of the rectangle (but in the same plane as the rectangle), then you can calculate the slopes of the sides, and the slope of the normal will be negative reciprocal of the slope of the side to which it is normal. (Or undefined if the slope of the side is zero.) If you want to put this normal on the rectangle, the midpoint of the side is a good place for it.

-

What cyanprime is looking for is a normal of 1 line in 2D space.

That normal has to fulfill the following condition:

m_line * m_normal = -1

whereas m_line is the magnitude of the line and m_normal is the magnitude of the normal.

=> m_normal = -1 / m_line

Obviously produces errors if m_line = 0. So you will want to treat that case specially.

If m_line is not 0, you get your 2D-Vector

normal_vector = (1, m_normal)

-

Be careful. A rectangle has two possible normals:

In the plane it has 4 normals:

-
While the drawing is pretty, a rectangle has an infinite amount of normals. –  Blindy Mar 29 '11 at 18:01
@Blindy: Whoooops I upvoted your comment accidentally. :( No, it doesn't have an infinite number of normals... vectors are just directions, not points. :\ –  Mehrdad Mar 29 '11 at 18:09
@Mehrdad indeed! –  belisarius Mar 29 '11 at 18:31
@Blindy It has infinite boundary points, not normals –  belisarius Mar 29 '11 at 18:32

A normal in 2D is the vector that did 90 degrees in the object, in the opposite direction of the object that should hit it comes.

There's fixed values for those normals, and those are:

West (1, 0); East (-1, 0); North (0, -1); South (0, 1);

-