Towards Conceiving Feasible Fully Optical Routers, Multiplexers and Synchronizers

Outgoing from the overwhelming evidence for untenability of the Einstein’s Second postulate on light speed invariance for two inertial systems moving with respect to each other, firstly a crucial Reductio-ad-Absurdum proof has been provided, followed by the proposal for experimental verification for the mechanism of increasing or decreasing the group light signal velocity by relative motion of transmitter with respect to the receiver. The proposed experiment emulates the binary stars configuration, without any intervening interstellar medium, that - based on up-to-date Ritz’s Emission Theory – ‘amortizes’ the light velocity during the propagation and contributes to discrepancy between the variations in stars’ luminosity and the Doppler shifts presented in line spectra as received on Earth. Experimental results of the proposed set-up can be used as Proof of Concept for feasibility of both imposing delay and advancement of optical signals, so that by heavy downsizing of the proposed experimental set-up through utilization of nanotechnology and related photonics advancements, the time of arrival of optical signals can be appropriately adjusted (with accompanying signals time-frequency domain scaling) to enable implementation of entirely optical multiplexers, routers and synchronizers. To provide comparison with the conventionally pursued methods which emulate the electronics-based digital signals processing technology, bit- and packet-level multiplexers are used

PDF

___

Phipps T. 1993, On Hertz’s Invariant Form of Maxwell’s Equations, Physics Essays 6 /2 pp. 249-256, http://dx.doi.org/10.4006/1.3029059
Nikolaev G.V. 1997, Non-contradictory Electrodynamics – Theory, Experiment, Paradox, in Russian, Tomsk Polytechnical University, ISBN 5-89503-014-9, English translation available at http://www.doverchiv.narod.ru/Nikolaev/Nikolaev_modern _electrodynamics.htm
Meyl K. 2012, Self-consistent Electrodynamics, Progress in Electromagnetics Research Symposium (PIERS-2012) Proceedings, Moscow, Russia, August, 2012.
Einstein A. 1920, Aether and the Theory of Relativity, http://www.mountainman.com.au/aether_0.html
Ritz W. 1908, Recherches critiques sur l'Électrodynamique générale, Ann. de chim. et phys., 13, 1908; an extensive account can be found in Physics in Perspective 6 (2004) 4– 28, A.A. Martinez, “Ritz, Einstein and Emission Hypothesis.”
De Sitter W. 1913, “Ein astronomischer Beweis für die Konstanz der Lichtgeschwindigkeit,” Phys. Zeit. 14 , pp. 429-.
Zitrin . et al. 2014, A Geometrically Supported z ∼ 10 Candidate Multiply Imaged by the Hubble Frontier Fields Cluster A1744, The Astrophysical Journal Letters, 793:L12 (6pp), 2014 September 20, doi:10.1088/2041-8205/793/1/L12
Ramaswami R. et al. 2010, Optical Networks – A Practical Perspective, 3rd Ed., Elsevier Inc.
Anonymous: www.physikevolution.de, article ‘Jenseits der Lichtgeschwindichkeit,’ English translation at https://www.dropbox.com/s/n21cte2i3baj4ux/Beyond%20th e%20Lightspeed.doc?dl=0 or at the request from author of this paper ( nedics@uns.ac.rs or nedic.slbdn@gmail.com ).
Nedić S. 2015, Velocity of Dirac-Delta EM Perturbation, Galilean Electrodynamics & GED-EAST, Volume 26, Special Issue 1, Spring.
Nedić S. 2009, On GPS Signal Multipath Modeling in Dynamic Environments, IEEE Aerospace Conference, http://dx.doi.org/10.1109/AERO.2009.4839415
Zetik R. and Thomae R.S. 2013, Ultra-Wideband Channel Sounder – Design, Construction and Selected Applications, TELFOR Journal, Vol. 5, No. 1.