I need to create a 3 by 3 real orthonormal symbolic matrix in Mathematica. How can I do so?

Although I really like the idea of Marcellus' answer to his own question, it's not completely correct. Unfortunately, the conditions he arrives at also result in
evaluating to a zero matrix! This is clearly not right. Here's an approach that's both correct and more direct:
i.e. multiplying a rotation matrix by its transpose results in the identity matrix, and the determinant of a rotation matrix is 1. 


I have found a "direct" way to impose special orthogonality. See below.
Then
gives 1;...and
gives the identity matrix; ...finally
gives a Zero matrix. ======================================================================== This is what I was looking for when I asked my question! However, let me know your thought on this method. Marcellus 


Marcellus, you have to use some parametrization of SO(3), since your general matrix has to reflect the RP^{3} topology of the group. No single parametrization will cover the whole group without either multivaluedness or singular points. Wikipedia has a nice page about the various charts on SO(3). Maybe one of the conceptually simplest is the exponential map from the Lie algebra so(3).
Define an antisymmetric, real
Then
If we write
Note that this is basically the same parametrization as RotationMatrix gives. Compare with the output from



You seem to want some
Here is how this works:
You can check that the matrix is orthonormal, by using 


Not that I recommend this, but...
So q2 is a symbolic orthogonal matrix (assuming we work over reals). 

