# Rotating a Vector in 3D Space

I am making an android project in opengl es that uses accelerometer to calculate change in specific axes and my aim is to rotate my spacecraft-like object's movement vector. The problem is that i can't understand the math behind rotation matrices. Default movement vector is 0,1,0 , means +y, so the object looks upward in the beginning. and i am trying to rotate its movement vector so i can move the object where it points. I can gather rotation changes in phone. x-axis : rotate, y-axis : rotate, z-axis : rotate. How can i rotate my movement vector using rotation matrix ?

• This HTML5 presentation on transforms explains transformations in greater detail with animations; it also explains how to handle complex transforms (concatenation of multiple elementary transforms) and also about transforming coordinate systems. – legends2k Sep 28 '15 at 13:43

## 2 Answers

If you want to rotate a vector you should construct what is known as a rotation matrix.

## Rotation in 2D

Say you want to rotate a vector or a point by θ, then trigonometry states that the new coordinates are

``````    x' = x cos θ − y sin θ
y' = x sin θ + y cos θ
``````

To demo this, let's take the cardinal axes X and Y; when we rotate the X-axis 90° counter-clockwise, we should end up with the X-axis transformed into Y-axis. Consider

``````    Unit vector along X axis = &lt;1, 0&gt;
x' = 1 cos 90 − 0 sin 90 = 0
y' = 1 sin 90 + 0 cos 90 = 1
New coordinates of the vector, &lt;x', y'&gt; = &lt;0, 1&gt;  ⟹  Y-axis
``````

When you understand this, creating a matrix to do this becomes simple. A matrix is just a mathematical tool to perform this in a comfortable, generalized manner so that various transformations like rotation, scale and translation (moving) can be combined and performed in a single step, using one common method. From linear algebra, to rotate a point or vector in 2D, the matrix to be built is

``````    |cos θ   −sin θ| |x| = |x cos θ − y sin θ| = |x'|
|sin θ    cos θ| |y|   |x sin θ + y cos θ|   |y'|
``````

## Rotation in 3D

That works in 2D, while in 3D we need to take in to account the third axis. Rotating a vector around the origin (a point) in 2D simply means rotating it around the Z-axis (a line) in 3D; since we're rotating around Z-axis, its coordinate should be kept constant i.e. 0° (rotation happens on the XY plane in 3D). In 3D rotating around the Z-axis would be

``````    |cos θ   −sin θ   0| |x|   |x cos θ − y sin θ|   |x'|
|sin θ    cos θ   0| |y| = |x sin θ + y cos θ| = |y'|
|  0       0      1| |z|   |        z        |   |z'|
``````

around the Y-axis would be

``````    | cos θ    0   sin θ| |x|   | x cos θ + z sin θ|   |x'|
|   0      1       0| |y| = |         y        | = |y'|
|−sin θ    0   cos θ| |z|   |−x sin θ + z cos θ|   |z'|
``````

around the X-axis would be

``````    |1     0           0| |x|   |        x        |   |x'|
|0   cos θ    −sin θ| |y| = |y cos θ − z sin θ| = |y'|
|0   sin θ     cos θ| |z|   |y sin θ + z cos θ|   |z'|
``````

Note: axis around which rotation is done has no sine or cosine elements in the matrix. I hope this makes the rotation case clear.

## Composition

The aforementioned matrices rotate an object as if the object is at a distance r = √(x² + y²) from the origin; lookup polar coordinates to know why. This rotation will be with respect to the world space origin. Usually we need to rotate an object around its own frame/pivot and not around the world's. Since not all objects are at the world origin, rotating using these matrices will not give the desired result of rotating around the object's own frame. Hence you need to learn about translation too. You'd first translate (move) the object to world origin (so that the object's origin would align with the world's, thereby making r = 0), perform the rotation with one (or more) of these matrices and then translate it back again to its previous location. The order in which the transforms are applied matters.

I urge you to read about linear and affine transformations and their composition to perform multiple transformations in one shot, before playing with transformations in code. Without understanding the basic maths behind it, debugging transformations would be a nightmare. I found this lecture video to be a very good resource. Another resource is this tutorial on transformations that aims to be intuitive and illustrates the ideas with animation.

Note: This method of performing rotations follows the Euler angle rotation system, which is simpler to teach and to grasp. This works perfectly fine for 2D and for simple 3D cases; but when rotation needs to be performed around all three axes at the same time then Euler angles are not sufficient for this due to an inherent deficiency in this system which manifests itself as Gimbal lock. People resort to Quaternions in such situations, which is more advanced than this but doesn't suffer from Gimbal locks when used correctly.

• If some one is interested in the reason behind gimbal lock: sundaram.wordpress.com/2013/03/08/… – legends2k May 14 '13 at 11:20
• Please keep in mind that Quaternions doesn't solve the Gimbal lock and has nothing to do with it. Quaternions and Matrices are just encodings for the actual rotation/orientation. The cause of gimbal lock is not the encoding but the sequential rotation. Using quaternions to represent 3 euler angles will cause gimbal lock. – concept3d Jan 21 '14 at 13:10
• Gimbal lock arises from representating a rotation transform as multiple component rotations about different axes -- aka Euler angles. This scenario allows you to rotate one axis onto another, resulting in a loss of a degree of freedom and the dreaded gimble lock. One needs to represent 3D rotations with 1 and only one quaternion and not 3. Then use that for interpolation and compositing, which effectively avoids gimbal lock. For further detail refer Quaterions and their Applications to Rotation in 3D Space. – legends2k Jan 21 '14 at 13:31
• That's exactly what I was trying to say. In the end quaternions are usually converted to matrices (for the renderer). That implies that again the encoding is not the problem, but actually losing a degree of freedom after each rotation. – concept3d Jan 21 '14 at 13:33
• +1 Thank you for being positive while taking my criticism ( A lot of people actually doesn't take it with open mind especially I lack the rep.) – concept3d Jan 21 '14 at 13:40

Reference docs here: http://developer.android.com/reference/android/opengl/Matrix.html

1. Build a rotation matrix
2. Transform the vector with the matrix

You don't need to understand the math, the library functions will get the job done.

• thank you very much, i'd also like to know math parts. this will do the work but i will be glad if i can also get mathematical explanation. – deniz Jan 30 '13 at 16:31
• Then I can't help you, because I don't understand it myself :) – Minthos Jan 30 '13 at 16:33