Lorentz Transformation, Poincaré Vectors and Poincaré Sphere in Various Branches of Physics

Tudor, Tiberiu

doi:10.3390/sym10030052

Cited by 12 publications

(11 citation statements)

References 38 publications

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“…Instead, the product of two boosts becomes the composition of a boost and a rotation. This extra rotation is present in many physical situations (Malykin, 2006;Tudor, 2018), such as through the Thomas precession in special relativity (Thomas, 1926) and the Wigner rotation in mathematical physics (Wigner, 1939). This effect has indeed been investigated for light's polarization degrees of freedom (Monzón and Sánchez-soto, 2001;Monzón and Sánchez-Soto, 1999a,b;Vigoureux, 1992;Vigoureux and Grossel, 1993), with the fascinating mathematical equivalence between indices of refraction for polarized light traveling through planar media and relative velocities of inertial frames in special relativity (Vigoureux, 1992).…”

Section: Mueller Matrix Calculusmentioning

confidence: 99%

“…Polarimetry and its relative ellipsometry (Azzam, 2011) do just that: they characterize substances by the unique changes they impart on light's polarization degrees of freedom (Collett, 1992). Highly precise measurements of polarization and its changes, i.e., polarimetry, have found applications in photonics (Yoon et al, 2020), bioimaging (Dulk et al, 1994;Firdous and Anwar, 2016;Ghosh et al, 2009;Tuchin, 2016), oceanography (Voss and Fry, 1984), remote sensing (Tyo et al, 2006), astronomy (Dulk et al, 1994;Tinbergen, 2005), and beyond.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Quantum Polarimetry

Goldberg

2021

Preprint

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Polarization is one of light's most versatile degrees of freedom for both classical and quantum applications. The ability to measure light's state of polarization and changes therein is thus essential; this is the science of polarimetry. It has become ever more apparent in recent years that the quantum nature of light's polarization properties is crucial, from explaining experiments with single or few photons to understanding the implications of quantum theory on classical polarization properties. We present a self-contained overview of quantum polarimetry, including discussions of classical and quantum polarization, their transformations, and measurements thereof. We use this platform to elucidate key concepts that are neglected when polarization and polarimetry are considered only from classical perspectives.

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Section: Mueller Matrix Calculusmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Quantum Polarimetry

Goldberg

2021

Preprint

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“…The main purpose of this paper is to show that the mathematical formulation that correctly describes polarization issues in optical communication is the spinor irreducible representation theory of the extended (as opposed to restricted) Lorentz Group. Although the idea of the Lorentz Group describing polarization in Optics is well known, [4]- [6] , it has never, to the best of my knowledge, been considered relevant to the field of optical communications. In this paper it will be analyzed why this happened, it will be proven that not taking into account these ideas is a serious mistake and it will be shown that polarization dependent (combined PMD-PDL) impairments can be easily reduced once the full implications of this mathematical formulation are understood.…”

Section: Introductionmentioning

confidence: 99%

“…[(ωΩ r ⃗⃗⃗⃗⃗⃗⃗⃗⃗⃗ + j ωΩ i ⃗⃗⃗⃗⃗⃗⃗ ). σ ⃗ ⃗ ] and the Lorentz transformation can be obtained from the traceless 2x2 matrix (3) by the exponential map as shown in (4). From this point of view, the combined PMD and PDL vector generates a restricted Lorentz transformation of the output polarization states and, if we choose to use Jones vectors to describe polarization states, we can regard these as a proper (restricted) Lorentz transformations of spin ½ particles [9]- [12].…”

Section: Introductionmentioning

confidence: 99%

On the correct mathematical description of polarization dependent impairments in Optical Communications

Janer¹

2022

Preprint

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In this paper it is shown that the mathematical framework that correctly describes the combined effects of polarization mode dispersion and polarization dependent losses is the irreducible spinor representation of the extended Lorentz Group. There are two kinds of states of polarizations that are relevant for the description of PMD-PDL effects. The optical process that allows to convert one kind into the other is identified as optical phase conjugation. The utility of the proposed mathematical framework is proven proposing a simple technique (based on optical phase conjugation) that cancels the PDL part of the impairments at the receiving end of the optical system.

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“…Since there is a close relationship between the proper Lorentz group, SO + (1,3), and SL(2,C) (SL(2,C) is the double cover of SO + (1,3)) this seems to be just a mathematical curiosity devoid of any practical interest. Possibly this is the reason why, although this relationship is known in Optics [4]- [6], it has never attracted any attention in the field of optical communications. In the following sections it will be show that this was a mistake because combined PMD-PDL induced impairments can be easily alleviated (the PDL part can be cancelled) when this fact and its precise mathematical formulation are taken into account.…”

Section: Introductionmentioning

confidence: 99%