In APS, the spacetime position is represented as the paravector where the time is given by the scalar part, and e1, e2, e3 are the standard basis for position space. Throughout, units such that are used, called natural units. In the Pauli matrix representation, the unitbasis vectors are replaced by the Pauli matrices and the scalar part by the identity matrix. This means that the Pauli matrix representation of the space-time position is
The restricted Lorentz transformations that preserve the direction of time and include rotations and boosts can be performed by an exponentiation of the spacetime rotation biparavectorW In the matrix representation the Lorentz rotor is seen to form an instance of the SL group, which is the double cover of the Lorentz group. The unimodularity of the Lorentz rotor is translated in the following condition in terms of the product of the Lorentz rotor with its Clifford conjugation This Lorentz rotor can be always decomposed in two factors, one Hermitian, and the other unitary, such that The unitary elementR is called a rotor because this encodes rotations, and the Hermitian element B encodes boosts.
Four-velocity paravector
The four-velocity, also called proper velocity, is defined as the derivative of the spacetime position paravector with respect toproper timeτ: This expression can be brought to a more compact form by defining the ordinary velocity as and recalling the definition of the gamma factor: so that the proper velocity is more compactly: The proper velocity is a positive unimodular paravector, which implies the following condition in terms of the Clifford conjugation The proper velocity transforms under the action of the Lorentz rotorL as
Four-momentum paravector
The four-momentum in APS can be obtained by multiplying the proper velocity with the mass as with the mass shell condition translated into
The electromagnetic field is represented as a bi-paravector F: with the Hermitian part representing the electric fieldE and the anti-Hermitian part representing the magnetic fieldB. In the standard Pauli matrix representation, the electromagnetic field is: The source of the fieldF is the electromagnetic four-current: where the scalar part equals the electric charge densityρ, and the vector part the electric current densityj. Introducing the electromagnetic potential paravector defined as: in which the scalar part equals the electric potentialϕ, and the vector part the magnetic potentialA. The electromagnetic field is then also: The field can be split into electric and magnetic components. Where and F is invariant under a gauge transformation of the form where is a scalar field. The electromagnetic field is covariant under Lorentz transformations according to the law
The Maxwell equations can be expressed in a single equation: where the overbar represents the Clifford conjugation. The Lorentz force equation takes the form
The differential equation of the Lorentz rotor that is consistent with the Lorentz force is such that the proper velocity is calculated as the Lorentz transformation of the proper velocity at rest which can be integrated to find the space-time trajectory with the additional use of
