**Notation**

*Quaternions* are defined in a four-space with bases {1, i, j, k}. Hamilton famously carved the fundamental relationship into the stone of the Brougham Bridge in Dublin:

i^{2} = j^{2} = k^{2} = i j k = -1.

There are many equivalent quaternion parameterizations, but here I'll use a {scalar, **vector**} form.

1.) A = {a0, **a**} and B = {b0, **b**}, where A and B are quaternions, a0 and b0 are scalars, and **a** and **b** are three-vectors.

2.) X = { 0, **x** } is a *vector quaternion*.

3.) The (non-commutative) *quaternion product* derives directly from the properties of i, j and k above, A⊗B = {a0 b0 - **a**.**b**, a0 **b** + b0 **a** + **a** x **b**}

4.) The *quaternion conjugate* is A^{*} = {a0, - **a**}

5.) The *conjugate of a quaternion product* is the product of the conjugates in reverse order.

(A⊗B)^{*} = B^{*}⊗A^{*}

6.) The *conjugate of a vector quaternion* is its negative. X^{*} = {0, -**x** } = -X

7.) The *quaternion norm* is |A| = √(A⊗A^{*}) = √( a0² + **a**.**a** )

8.) A *unit quaternion* is one that has a norm of 1.

9.) A unit three-vector **x** = {x_{1}, x_{2}, x_{3}} with **x** . **x** = 1 is expressible as a *unit vector quaternion* X = { 0, **x** }, |X| = 1.

10.) The *spherical rotation* of a quaternion vector X by an angle θ about a unit vector axis **n** is Q⊗X⊗Q^{*},
where Q is the quaternion {cos(θ/2), sin(θ/2) **n** }. Note that |Q| = 1.

Notice the form of the quaternion vector product. Given vector quaternions X_{1} = { 0, **x**_{1} ) and X_{2} = { 0, **x**_{2} }, the quaternion product is X_{2}⊗X_{1}^{*} = { **x**_{1}.**x**_{2}, **x**_{1} × **x**_{2} }. The quaternion reunites the dot product as the scalar part and cross product as the vector part, divorced over a hundred years ago. Neither of these products is invertible, but the quaternion is in the way described below.

**Inversion**

Find the spherical transform quaternion Q_{12} to rotate vector X_{1} to align with vector X_{2}.

From above

X_{2} = Q_{12}⊗X_{1}⊗Q_{12}^{*}

Multiplying both sides by X_{1}^{*},

X_{2}⊗X_{1}^{*} = Q_{12}⊗X_{1}⊗(Q_{12}^{*}⊗X_{1}^{*})

Remember that the rotation axis **n** derives from the cross product **x**_{1}×**x**_{2}, so **n** . **x**_{1} = 0. and Q^{*}⊗X^{*} = (X⊗Q)^{*} = X^{*}⊗Q, leaving

X_{2}⊗X_{1}^{*} = Q_{12}⊗X_{1}⊗X_{1}^{*}⊗Q_{12} = Q_{12}⊗Q_{12}

So the quaternion transform can be solved directly as

Q_{12} = √(X_{2}⊗X_{1}^{*})

You're on your own for the quaternion square root. There are lots of ways to do it, and the best will depend on your application, considering speed and stability.

--hth,

Fred Klingener