In this section, the real
subalgebras generated by a single split-quaternion are studied and classified. Let be a split-quaternion. Its
real part is . Let be its
nonreal part. One has , and therefore p^2=w^2+2wq-N(q). It follows that is a real number if and only is either a real number ( and ) or a
purely nonreal split quaternion ( and ). The structure of the subalgebra \mathbb R[p] generated by follows straightforwardly. One has : \mathbb R[p]=\mathbb R[q]=\{a+bq\mid a,b\in\mathbb R\}, and this is a
commutative algebra. Its
dimension is two except if is real (in this case, the subalgebra is simply \mathbb R). The nonreal elements of \mathbb R[p] whose square is real have the form with a\in \mathbb R. Three cases have to be considered, which are detailed in the next subsections.
Nilpotent case With above notation, if q^2=0, (that is, if is
nilpotent), then , that is, x^2-y^2-z^2=0. This implies that there exist and in \mathbb R such that and : p=w+a\mathrm i + a\cos(t)\mathrm j + a\sin(t)\mathrm k. This is a parametrization of all split-quaternions whose nonreal part is nilpotent. This is also a parameterization of these subalgebras by the points of a circle: the split-quaternions of the form \mathrm i + \cos(t)\mathrm j + \sin(t)\mathrm k form a
circle; a subalgebra generated by a nilpotent element contains exactly one point of the circle; and the circle does not contain any other point. The algebra generated by a nilpotent element is isomorphic to \mathbb R[X]/\langle X^2\rangle and to the plane of
dual numbers.
Imaginary units s This is the case where . Letting n=\sqrt{N(q)}, one has : q^2 =-q^*q=N(q)=n^2=x^2-y^2-z^2. It follows that belongs to the
hyperboloid of two sheets of equation x^2-y^2-z^2=1. Therefore, there are real numbers such that and : p=w+n\cosh(u)\mathrm i + n\sinh(u)\cos(t)\mathrm j + n\sinh(u)\sin(t)\mathrm k. This is a parametrization of all split-quaternions whose nonreal part has a positive norm. This is also a parameterization of the corresponding subalgebras by the pairs of opposite points of a hyperboloid of two sheets: the split-quaternions of the form \cosh(u)\mathrm i + \sinh(u)\cos(t)\mathrm j + \sinh(u)\sin(t)\mathrm k form a hyperboloid of two sheets; a subalgebra generated by a split-quaternion with a nonreal part of positive norm contains exactly two opposite points on this hyperboloid, one on each sheet; and the hyperboloid does not contain any other point. The algebra generated by a split-quaternion with a nonreal part of positive norm is isomorphic to \mathbb R[X]/\langle X^2+1\rangle and to the field \Complex of
complex numbers.
Hyperbolic units s.(the vertical axis is called in the article) This is the case where . Letting n=\sqrt{-N(q)}, one has : q^2 = -q^*q=N(q)=-n^2=x^2-y^2-z^2. It follows that belongs to the
hyperboloid of one sheet of equation . Therefore, there are real numbers such that and : p=w+n\sinh(u)\mathrm i + n\cosh(u)\cos(t)\mathrm j + n\cosh(u)\sin(t)\mathrm k. This is a parametrization of all split-quaternions whose nonreal part has a negative norm. This is also a parameterization of the corresponding subalgebras by the pairs of opposite points of a hyperboloid of one sheet: the split-quaternions of the form \sinh(u)\mathrm i + \cosh(u)\cos(t)\mathrm j + \cosh(u)\sin(t)\mathrm k form a hyperboloid of one sheet; a subalgebra generated by a split-quaternion with a nonreal part of negative norm contains exactly two opposite points on this hyperboloid; and the hyperboloid does not contain any other point. The algebra generated by a split-quaternion with a nonreal part of negative norm is isomorphic to \mathbb R[X]/\langle X^2-1\rangle and to the
ring of
split-complex numbers. It is also isomorphic (as an algebra) to \mathbb R^2 by the mapping defined by (1,0)\mapsto \frac{1+X}2, \quad (0,1)\mapsto \frac{1-X}2.
Stratification by the norm As seen above, the purely nonreal split-quaternions of norm and form respectively a hyperboloid of one sheet, a hyperboloid of two sheets and a
circular cone in the space of non real quaternions. These surfaces are pairwise
asymptote and do not intersect. Their
complement consist of six connected regions: • the two regions located on the concave side of the hyperboloid of two sheets, where N(q)>1 • the two regions between the hyperboloid of two sheets and the cone, where 0 • the region between the cone and the hyperboloid of one sheet where -1 • the region outside the hyperboloid of one sheet, where N(q) This stratification can be refined by considering split-quaternions of a fixed norm: for every real number the purely nonreal split-quaternions of norm form an hyperboloid. All these hyperboloids are asymptote to the above cone, and none of these surfaces intersect any other. As the set of the purely nonreal split-quaternions is the
disjoint union of these surfaces, this provides the desired stratification. == Colour space ==