P
Periklis Petropoulos
Researcher at University of Southampton
Publications - 540
Citations - 10305
Periklis Petropoulos is an academic researcher from University of Southampton. The author has contributed to research in topics: Optical fiber & Fiber Bragg grating. The author has an hindex of 47, co-authored 515 publications receiving 9330 citations. Previous affiliations of Periklis Petropoulos include Karlsruhe Institute of Technology.
Papers
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Journal ArticleDOI
Demonstration of Space-to-Wavelength Conversion in SDM Networks
V.J.F. Rancaño,Saurabh Jain,T.C. May-Smith,Emilio Hugues-Salas,Shuangyi Yan,George Zervas,Dimitra Simeonidou,Periklis Petropoulos,David J. Richardson +8 more
TL;DR: A scheme for the conversion of spatially multiplexed channels to a wavelength superchannel is presented and characterized and the viability of deployment at network nodes located at the boundaries between spatial-division-multiplexed and standard single-mode fiber wavelength division multiplexing networks is demonstrated.
Journal ArticleDOI
Analysis of acceptable spectral windows of quadratic cascaded nonlinear processes in a periodically poled lithium niobate waveguide
TL;DR: It is concluded that the tuning bandwidths of both cascaded processes should be similar in the pulsed pump regime once the pump pulse bandwidths approach that of SFG (i.e. the cSHG/DFG bandwidth is not limited by the CW SHG bandwidth).
Proceedings ArticleDOI
PSA-based all-optical multi-channel phase regenerator
Francesca Parmigiani,Kyle R. H. Bottrill,Radan Slavik,David J. Richardson,Periklis Petropoulos +4 more
TL;DR: In this article, the authors demonstrate simultaneous phase regeneration of six NRZ BPSK signals in a single nonlinear medium using FWM-based phase sensitive amplification and BER measurements confirm OSNR improvement and negligible cross-talk across all the regenerated channels.
Proceedings ArticleDOI
Nonlinear generation of ultra-flat broadened spectrum based on adaptive pulse shaping
TL;DR: In this article, a technique to nonlinearly generate precise spectral shapes in an adaptable and power-efficient fashion was proposed, and the generation of a spectrum with a 7-nm 0.5-dB bandwidth was demonstrated to prove the validity of the approach.
The generation recognition and re-coding of 64-bit 160 Gbit/s optical code sequences using superstructured fiber Bragg gratings
TL;DR: This work reports the sequential generation, recognition and recoding of 160Gbits, 64-bit bipolar optical codes using superstructured fiber Bragg gratings, representing an eightfold increase in code length relative to previous demonstrations of pulse processing using such technology.