Thin Film-Based Gires–Tournois Resonator (GTR) as Quasi-optical Analogue of the Thomas Rotation Angle Effect in Special Relativity

Thin Film-Based Gires–Tournois Resonator (GTR) as Quasi-optical Analogue of the Thomas Rotation Angle Effect in Special Relativity

We present an unconventional approach to generate an optical analogue of the Thomas rotation angle found in Special Relativity (SR) by using a thin-film–based Gires–TournoisResonator (GTR). At first glance, the phase response of the GTR seems to fail as an optical analogue for the Thomas rotation an...

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Main Authors: Dingel, Benjamin B, Buenaventura, A, Chua, A R, Libatique, Nathaniel Joseph C
Format: text
Published: Archīum Ateneo 2019
Subjects:
Electrical and Computer Engineering
Physics
Online Access:https://archium.ateneo.edu/ecce-faculty-pubs/124
https://www.sciencedirect.com/science/article/abs/pii/S0030401819307928
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Institution: Ateneo De Manila University
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spelling ph-ateneo-arc.ecce-faculty-pubs-11182022-04-19T11:16:58Z Thin Film-Based Gires–Tournois Resonator (GTR) as Quasi-optical Analogue of the Thomas Rotation Angle Effect in Special Relativity Dingel, Benjamin B Buenaventura, A Chua, A R Libatique, Nathaniel Joseph C We present an unconventional approach to generate an optical analogue of the Thomas rotation angle found in Special Relativity (SR) by using a thin-film–based Gires–TournoisResonator (GTR). At first glance, the phase response of the GTR seems to fail as an optical analogue for the Thomas rotation angle in the phase domain but we demonstrate that an analogue can be successfully constructed in the intensity domain by combining the GTR with a Michelson interferometer (MI), thus forming an interferometer known as the Michelson–Gires–Tournois Interferometer (MGTI). Thomas rotation angle is a spatial rotation of the reference frame due to the Einstein velocity addition (EVA) law of two successive relativistic velocities travelling in non-collinear directions, whereas, the GTR is a thin-film based asymmetric Fabry–Perot resonator (FPR) with a partially reflecting front mirror, and a 100% rear-reflecting mirror. We investigate in detail, both analytically and numerically, the Thomas rotation angle’s full behaviour under various parameter conditions. This approach offers the following advantages: (i) it leads to a simpler overall configuration, (ii) it measures the Thomas rotation angle directly requiring only a single optical parameter instead of multiple parameters compared with other methods, and (iii) it requires no sophisticated multilayer thin film design. 2019-09-05T07:00:00Z text https://archium.ateneo.edu/ecce-faculty-pubs/124 https://www.sciencedirect.com/science/article/abs/pii/S0030401819307928 Electronics, Computer, and Communications Engineering Faculty Publications Archīum Ateneo Electrical and Computer Engineering Physics
institution Ateneo De Manila University
building Ateneo De Manila University Library
continent Asia
country Philippines
Philippines
content_provider Ateneo De Manila University Library
collection archium.Ateneo Institutional Repository
topic Electrical and Computer Engineering
Physics
spellingShingle Electrical and Computer Engineering
Physics
Dingel, Benjamin B
Buenaventura, A
Chua, A R
Libatique, Nathaniel Joseph C
Thin Film-Based Gires–Tournois Resonator (GTR) as Quasi-optical Analogue of the Thomas Rotation Angle Effect in Special Relativity
description We present an unconventional approach to generate an optical analogue of the Thomas rotation angle found in Special Relativity (SR) by using a thin-film–based Gires–TournoisResonator (GTR). At first glance, the phase response of the GTR seems to fail as an optical analogue for the Thomas rotation angle in the phase domain but we demonstrate that an analogue can be successfully constructed in the intensity domain by combining the GTR with a Michelson interferometer (MI), thus forming an interferometer known as the Michelson–Gires–Tournois Interferometer (MGTI). Thomas rotation angle is a spatial rotation of the reference frame due to the Einstein velocity addition (EVA) law of two successive relativistic velocities travelling in non-collinear directions, whereas, the GTR is a thin-film based asymmetric Fabry–Perot resonator (FPR) with a partially reflecting front mirror, and a 100% rear-reflecting mirror. We investigate in detail, both analytically and numerically, the Thomas rotation angle’s full behaviour under various parameter conditions. This approach offers the following advantages: (i) it leads to a simpler overall configuration, (ii) it measures the Thomas rotation angle directly requiring only a single optical parameter instead of multiple parameters compared with other methods, and (iii) it requires no sophisticated multilayer thin film design.
format text
author Dingel, Benjamin B
Buenaventura, A
Chua, A R
Libatique, Nathaniel Joseph C
author_facet Dingel, Benjamin B
Buenaventura, A
Chua, A R
Libatique, Nathaniel Joseph C
author_sort Dingel, Benjamin B
title Thin Film-Based Gires–Tournois Resonator (GTR) as Quasi-optical Analogue of the Thomas Rotation Angle Effect in Special Relativity
title_short Thin Film-Based Gires–Tournois Resonator (GTR) as Quasi-optical Analogue of the Thomas Rotation Angle Effect in Special Relativity
title_full Thin Film-Based Gires–Tournois Resonator (GTR) as Quasi-optical Analogue of the Thomas Rotation Angle Effect in Special Relativity
title_fullStr Thin Film-Based Gires–Tournois Resonator (GTR) as Quasi-optical Analogue of the Thomas Rotation Angle Effect in Special Relativity
title_full_unstemmed Thin Film-Based Gires–Tournois Resonator (GTR) as Quasi-optical Analogue of the Thomas Rotation Angle Effect in Special Relativity
title_sort thin film-based gires–tournois resonator (gtr) as quasi-optical analogue of the thomas rotation angle effect in special relativity
publisher Archīum Ateneo
publishDate 2019
url https://archium.ateneo.edu/ecce-faculty-pubs/124
https://www.sciencedirect.com/science/article/abs/pii/S0030401819307928
_version_ 1731309299914768384

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