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The Octonions, also called the Cayley-Dixon algebra, defined over a commutative ring are an eight-dimensional non-associative algebra. Their construction from quaternions is similar to the construction of quaternions from complex numbers (see QuaternionXmpPage ).
As Octonion creates an eight-dimensional algebra, you have to give eight components to construct an octonion.
Or you can use two quaternions to create an octonion.
You can easily demonstrate the non-associativity of multiplication.
As with the quaternions, we have a real part, the imaginary parts i, j, k, and four additional imaginary parts E, I, J and K. These parts correspond to the canonical basis (1,i,j,k,E,I,J,K).
For each basis element there is a component operation to extract the coefficient of the basis element for a given octonion.
A basis with respect to the quaternions is given by (1,E). However, you might ask, what then are the commuting rules? To answer this, we create some generic elements.
We do this in Axiom by simply changing the ground ring from Integer to Polynomial Integer.
Note that quaternions are automatically converted to octonions in the obvious way.
Finally, we check that the normnormOctonion, defined as the sum of the squares of the coefficients, is a multiplicative map.
Since the result is 0, the norm is multiplicative.