WWH - Calculating a Rotation Matrix Based on Location/Target

Published August 23, 1999 by Paul Nettle, posted by Myopic Rhino
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The purpose of a WWH is to expand one's knowledge on a topic they already understand, but need a reference, a refresher course, or to simply extend what they already know about the topic. WWH is the quick tutor. Just the [W]hat, [W]hy and [H]ow

[size="5"]What

The purpose here is to describe how to obtain a proper matrix given a location and a target (or a vector), and an amount of roll.

This document will also emulate the specific nature of 3DS cameras, when it comes to the degenerate case (input vector points directly up).

The accompanying source code is in C++.

[size="5"]Why

This is useful when dealing with cameras in a 3D world, or when you need to orient an object based on a vector, rather than roll/pitch/yaw components.

[size="5"]How

[size="3"]Define

cVector - dx, dy, dz
cMatrix - 3x3 matrix class (consisting of 3 cVectors)

The input Vector must be a directional vector. So for location->target, calculate like this:

vector = target - camera;
There is a problem with creating rotation matricies out of direction vectors. There is a degenerate case when the [delta y] of the direction vector is anything but zero. 3D Studio handles this in a special way, and here's a solution to it.

[size="3"]Testing

Many people claim to have perfectly working code, and I have found that in over 50% of them, this was not the case.

To test this, simply view an object from all 6 directions (above, below, left, right, front, back). Make sure the view vector contains two 0 components and a 1 component (i.e. [0,0,1] or [0,-1,0]).

The degenerate cases are [0,1,0] and [0,-1,0]. Pay special attention to the degenerate cases.

This code based on the descriptions in _Computer Graphics Principles and Practice_ (page 222) by Foley, van Dam, Feiner and Hughes.


[size="3"]Source

cMatrix cMatrix::generateMatrix( cVector &vector, const float rollDegrees )
{
// Get our direction vector (the Z vector component of the matrix)
// and make sure it's normalized into a unit vector

cVector zAxis(vector);
zAxis.normalize();

// Build the Y vector of the matrix (handle the degenerate case
// in the way that 3DS does) -- This is not the TRUE vector, only
// a reference vector.

cVector yAxis;

if (!zAxis.dx && !zAxis.dz)
yAxis = cVector(-zAxis.dy, 0.0f, 0.0f );
else
yAxis = cVector(0.0f, 1.0f, 0.0f);

// Build the X axis vector based on the two existing vectors

cVector xAxis = yAxis.cross( zAxis );
xAxis.normalize();

// Correct the Y reference vector

yAxis = xAxis.cross( zAxis );
yAxis.normalize();
yAxis = -yAxis;

// Generate rotation matrix without roll included

cMatrix rot(xAxis, yAxis, zAxis);

// Generate the Z rotation matrix for roll (bank)

cMatrix roll(MATRIX_Z, rollDegrees);

// Concatinate them for a complete rotation matrix that includes
// all rotations

cMatrix result = roll * rot;

// All done

return result;
}
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The purpose here is to describe how to obtain a proper matrix given a location and a target (or a vector), and an amount of roll. This document also emulates the specific nature of 3DS cameras, when it comes to the degenerate case.

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