User talk:Paul Wormer/scratchbook1

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Rotations in

Consider a real 3×3 matrix R with columns r1, r2, r3, i.e.,

.

The matrix R is orthogonal if

The matrix R is a proper rotation matrix, if it is orthogonal and if r1, r2, r3 form a right-handed set, i.e.,

Here the symbol × indicates a cross product and is the antisymmetric Levi-Civita symbol,

and if two or more indices are equal.

The matrix R is an improper rotation matrix if its column vectors form a left-handed set, i.e.,

The last two equations can be condensed into one equation

by virtue of the the fact that the determinant of a proper rotation matrix is 1 and of an improper rotation −1. This can be proved as follows: The determinant of a 3×3 matrix with column vectors a, b, and c can be written as scalar triple product

.

Remember that for a proper rotation the columns of R are orthonormal and satisfy,

Likewise the determinant is −1 for an improper rotation.

Theorem

A proper rotation matrix R can be factorized thus

which is referred to as the Euler z-y-x parametrization, or also as

the Euler z-y-z parametrization.

Here the matrices representing rotations around the z, y, and x axis, respectively, over arbitrary angle φ, are

Proof

First the Euler z-y-x-parametrization will be proved by describing an algorithm for the factorization of R. Consider to that end the matrix product

The columns of the matrix product are for ease of reference designated by a1, a2, and a3. Note that the multiplication by Rx1) on the right does not affect the first column, so that a1 = r1 (the first column of the matrix to be factorized). Solve and from the first column of R,

This is possible. First solve for from

Then solve for from the two equations:

Knowledge of and determines the vectors a2 and a3.

Since a1, a2 and a3 are the columns of a proper rotation matrix they form an orthonormal right-handed system. The plane spanned by a2 and a3 is orthogonal to and hence the plane contains and . Thus the latter two vectors are a linear combination of the first two,

Since are known unit vectors we can compute

These equations give with .

Augment the 2×2 matrix to the 3×3 matrix , then

This concludes the proof of the z-y-x parametrization.

The Euler z-y-z parametrization is obtained by a small modification of the previous proof. Solve and from (the rightmost multiplication by Rz1) does not affect r3) and then consider

or, The equation for R can be written as

which proves the Euler z-y-z parametrization. It is common in this parametrization to write