Application of Quaternions to Obtain Analytic Solutions to Systems of Polarization Components

The usual way to describe mathematically a beam of coherent light passing through a system of waveplates is via the Jones vector and Jones matrix. This paper will show that a quaternion can be used to represent both the optical signal and the waveplate component it passes through, replacing the Jones vector and the Jones matrix. The quaternion description is easier to manipulate than the matrix-vector description; for example it can be inverted. As well as the Jones vector, the state of polarization (SOP) of an optical signal is often described as a three-dimensional vector on the Poincar\'e sphere, or as a polarization ellipse, and it will be shown how these three forms are closely related to the quaternion representation. Similarly, the action of a waveplate may be represented as a rotation about an axis on the Poincar\'e sphere, and that rotation is shown to have a logarithm-exponential relationship to the waveplate's quaternion. The paper presents rules to decide if two optical signals are aligned or orthogonal in phase or in polarization from their quaternions, and presents the quaternion operations to change the phase or change the SOP. Light passing through a system of waveplates is written as a product of quaternions, and it can be hard to simplify or manipulate that expression because quaternion multiplication does not commute. The paper brings together several mathematical tools that allow such a quaternion product to be rearranged, including the new idea of partial conjugation. Finally, a worked example is included of the quaternion mathematics applied to a waveplate problem that has not been solved before. It is shown that an endless optical phase shifter can be built using three rotatable waveplates, and equations for the angles of rotation are derived to produce the desired phase shift for given input and output SOPs.