# Rotation Matrix given angle and point in X,Y,Z

I am doing image manipulation and I want to rotate all of the pixels in xyz space based on an angle, the origin, and an x,y, and z coordinate.

I just need to setup the proper matrix (4x4) and then I will be good from there. The Angle is in degrees, not radians and the x,y,z are all going to be from -1 to 1 (floats)

EDIT:

Ok, here is the code that I whipped up to do the rotation about a given line defined by the origin and an X, Y, Z coorinate.

``````        float ang = angD * (float)(Math.PI / 180);  // from degrees to radians, if needed
//U = n*n(t) + cos(a)*(I-n*n(t)) + sin(a)*N(x).

var u = MatrixDouble.Identity(4);  // 4x4 Identity Matrix
u = u.Multiply(Math.Cos(ang));

var n = new MatrixDouble(1, 4, new List<double> { x, y, z, 0 });
var nt = n.Transpose();

// This next part is the N(x) matrix.  The data is inputted in Column
// first order and fills in the 4x4 matrix with the given 16 Doubles
var nx = new MatrixDouble(4, 4, new List<double> { 0, z, -y, 0, -z, 0, x, 0, y, -x, 0, 0, 0, 0, 0, 1 });

nx = nx.Multiply(Math.Sin(ang));

var ret = nt.Multiply(n);
ret[3, 3] = 1;

u = u.Subtract(ret);

``````

It's a little complicated and I'm using a custom Matrix library, but nothing up there should be too hard to implement with any functioning Matrix lib.

Phew, lots of math!

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So what's the question? – user405725 Mar 4 '11 at 2:04
I'm guessing you want the point defined by the "x, y and z coordinate" to remain invariant. How are you representing a point in xyz space as a 4-vector? – Beta Mar 4 '11 at 4:35
I'm not representing the points as a 4x4 vector. The transformation matrix is the 4x4 and the point is a 4x1. Multiplying them together gets me my p' which is the pixel only rotated. I'll update my post with the code that I made. – joe_coolish Mar 4 '11 at 5:26
A "4x4 vector"? You are not being careful with terminology. – Beta Mar 4 '11 at 21:14
Wow, I feel dumb. 4x4 Matrix :) lol, at least I didn't say Matrice!!! heehee – joe_coolish Mar 23 '11 at 17:10

The complete rotation matrices are derived and given at https://sites.google.com/site/glennmurray/Home/rotation-matrices-and-formulas.

From the paper:

5.2 The simplified matrix for rotations about the origin

Note this assumes that (u, v, w) is a direction vector for the axis of rotation and that u^2 + v^2 + w^2 = 1.

If you have a point (x, y, z) that you want to rotate, then we can obtain a function of of seven variables that yields the rotated point:

f(x, y, z, u, v, w, theta) =

The paper also includes matrices and formulas for rotations about an arbitrary axis (not necessarily through the origin), Java code available under the Apache license, and a link to a web app that illustrates rotations.

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Thou the math was a bit much to digest, this did end up working. It took me a bit, but I got it working and it is a general case. Thank you! – joe_coolish Mar 4 '11 at 5:23

Use the Matrix3D Structure (MSDN) - Represents a 4 x 4 matrix used for transformations in 3-D space

Take a look here for a tutorial: Building a 3D Engine

Essentially, matrices are built for X, Y, and Z rotations and then you can multiply the rotations in any order.

``````public static Matrix3D NewRotateAroundX(double radians)
{
var matrix = new Matrix3D();
return matrix;
}
{
var matrix = new Matrix3D();
return matrix;
}
{
var matrix = new Matrix3D();
return matrix;
}
``````
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While it is true that you can multiply the matrices in any order, you will not necessarily get the same answer if you do so. Matrix multiplication is not commutative. I give an example of products of rotation matrices about the axes giving different answers for different orders of multiplication in the paper linked at in my answer. – Glenn Mar 4 '11 at 2:48
While it is true that MatrixX * MatrixY does not necessarily equal MatrixY * MatrixX, it is up to the OP to decide the order of multiplication. – Jordan Arron Mar 4 '11 at 2:50
You're confusing 2 different Matrix3D's. Even though you reference the MSDN, that Matrix 3D doesn't have a "_matrix" member. – user316117 Dec 3 '15 at 20:47

Function `rotateAroundAxis()` rotates point around any axis in 3D. It is my solution to the rotation in 3D using analytic geometry and programming to model the process. The code is in JavaScript.

``````function rotateAroundAxis(A, B, C, alpha, precision) {
// A is rotated point, BC is axis, alpha is angle
// A, B, C are points in format [Ax, Ay, Az], alpha is float, precision is int
// A2 is output in format [A2x, A2y, A2z]
if((A[0] - B[0])*(A[1] - C[1]) == (A[1] - B[1])*(A[0] - C[0]) && (A[1] - B[1])*(A[2] - C[2]) == (A[1] - C[1])*(A[2] - B[2]) && (A[0] - B[0])*(A[2] - C[2]) == (A[0] - C[0])*(A[2] - B[2])) {
return A
}// Return the original point if it is on the axis.
var D = findClosestPoint(A, B, C, precision);
var w = crossProduct(new Array(C[0] - B[0], C[1] - B[1], C[2] - B[2]), new Array(C[0] - A[0], C[1] - A[1], C[2] - A[2]));
var W = pointPlusVector(A, w);
var sizeAW = vectorSize(A, W);
var sizeDA = vectorSize(D, A);
var sizeAE = sizeDA*(Math.sin(0.5*alpha))/(Math.cos(0.5*alpha));
var E = new Array(A[0] + (W[0] - A[0])*sizeAE/sizeAW, A[1] + (W[1] - A[1])*sizeAE/sizeAW, A[2] + (W[2] - A[2])*sizeAE/sizeAW);
var sizeDE = vectorSize(D, E);
var sizeEF = sizeAE*Math.sin(alpha/2);
var F = new Array(D[0] + (E[0] - D[0])*(sizeDE - sizeEF)/sizeDE, D[1] + (E[1] - D[1])*(sizeDE - sizeEF)/sizeDE, D[2] + (E[2] - D[2])*(sizeDE - sizeEF)/sizeDE);
var A2 = new Array(A[0] + 2*(F[0] - A[0]), A[1] + 2*(F[1] - A[1]), A[2] + 2*(F[2] - A[2]))
return A2;
}

function angleSize(A, S, B) {
ux = A[0] - S[0]; uy = A[1] - S[1]; uz = A[2] - S[2];
vx = B[0] - S[0]; vy = B[1] - S[1]; vz = B[2] - S[2];
if((Math.sqrt(ux*ux + uy*uy + uz*uz)*Math.sqrt(vx*vx + vy*vy + vz*vz)) == 0) {return 0}
return Math.acos((ux*vx + uy*vy + uz*vz)/(Math.sqrt(ux*ux + uy*uy + uz*uz)*Math.sqrt(vx*vx + vy*vy + vz*vz)));
}

function findClosestPoint(N, B, C, precision) {
// We will devide the segment BC into many tiny segments and we will choose the point F where the |NB F| distance is the shortest.
if(B[0] == C[0] && B[1] == C[1] && B[2] == C[2]) {return B}
var shortest = 0;
for(var i = 0; i <= precision; i++) {
var Fx = Math.round(precision*precision*(B[0] + (C[0] - B[0])*i/precision))/(precision*precision);
var Fy = Math.round(precision*precision*(B[1] + (C[1] - B[1])*i/precision))/(precision*precision);
var Fz = Math.round(precision*precision*(B[2] + (C[2] - B[2])*i/precision))/(precision*precision);
var sizeF = vectorSize(new Array(N[0], N[1], N[2]), new Array(Fx, Fy, Fz));
if(i == 0 || sizeF < shortest) { // first run or condition
shortest = sizeF;
F = new Array(Fx, Fy, Fz);
}
}
// recursion, if it is an outer point return findClosestPoint(we mirror further point in the closer one)
if(F[0] == Math.round(precision*precision*(B[0]))/(precision*precision) && F[1] == Math.round(precision*precision*(B[1]))/(precision*precision) && F[2] == Math.round(precision*precision*(B[2]))/(precision*precision)) { // F == B
if(Math.round(precision*precision*180*angleSize(C, B, N)/Math.PI)/(precision*precision) <= 90){return F} else {return findClosestPoint(N, new Array(2*B[0] - C[0], 2*B[1] - C[1], 2*B[2] - C[2]), B, precision)}
} else if (F[0] == Math.round(precision*precision*(C[0]))/(precision*precision) && F[1] == Math.round(precision*precision*(C[1]))/(precision*precision) && F[2] == Math.round(precision*precision*(C[2]))/(precision*precision)) { // F == C
if(Math.round(precision*precision*180*angleSize(B, C, N)/Math.PI)/(precision*precision) <= 90) {return F} else {return findClosestPoint(N, C, new Array(2*C[0] - B[0], 2*C[1] - B[1], 2*C[2] - B[2]), precision)}
} else {return F;}
}

function vectorSize(A, B) {
var ux = A[0] - B[0];
var uy = A[1] - B[1];
var uz = A[2] - B[2];
return Math.sqrt(ux*ux + uy*uy + uz*uz);
}

function crossProduct(u, v) {
return (new Array(u[1]*v[2] - u[2]*v[1], u[2]*v[0] - u[0]*v[2], u[0]*v[1] - u[1]*v[0]));
}

function pointPlusVector (A, v) {
return (new Array(A[0] + v[0], A[1] + v[1], A[2] + v[2]));
}
``````
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