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Gabriele Bolognini operates in the fields of opto-electronics and photonics at National Research Council (Consiglio Nazionale delle Ricerche), Institute for Microelectronics and Microsystems, Bologna, Italy, where he has been working since 2011.
He obtained his Laurea Degree in Physics (cum laude, University of Pisa, 2000) and a PhD Degree in Engineering (Innovative Technologies, Scuola Superiore Sant'Anna, 2005).
Since many years he has taken leading roles (Principal Investigator, Coordinator, WP leader and so forth) for several national and international competitive projects. He has been in charge of university courses on photonics at the University of Bologna, and at Scuola Superiore Sant'Anna in Pisa.
He has published more than 140 scientific papers, and is inventor of 6 patents.
His research interests encompass the fields of opto-electronics and photonics. In particular he is active on optical fiber sensor systems and technologies, more specifically on Raman- and Brillouin-based distributed sensors, on distributed acoustic sensing (DAS) as well as on FBG-based optical sensors; he has been also active on optical telecommunications (in particular on optical amplification systems such as EDFAs, Raman-based and SOAs), as well as on silicon photonics devices, nonlinear fiber optics, optical transmission systems and metrological applications.
Since many years has been a member of technical program committees in many national and international conferences (most notably the international Optical Fiber Sensors conference) and in editorial boards of scientific journals.
He also acts as a referee/evaluator for project proposals in several research funding programmes including EC Horizon 2020, EC RFCS, EC FP7, Canada NSERC, Italy PRIN, FIRB, SIR. He is a member of IEEE, and participates to the work of the committee of IEC SC86C/WG2 for fiber optic sensors standardization.
Since 2019 he is president of the national standardization committee: CEI SC86C 'Optical systems and active devices' (https://mycomitato.ceinorme.it/ricerca/comitato/dettaglio/4SC86C)
Bibliometric data
H-index: 31 (Google Scholar) - 29 (Scopus)
Citations: 2759 (Google Scholar) - 2427 (Scopus)
Publications: 164 (Google Scholar) - 145 (Scopus)
Recent projects
European Horizon 2020 SLAM-DAST (2021-2024)
He is the Scientific Coordinator of the European project "Smart LightwAve Multi-modal Distributed Acoustic Strain and Temperature sensor " (SLAM-DAST), funded by European Union through EIC (European Innovation council) Horizon 2020, the Framework Programme for Research and Innovation, Fast Track to Innovation (call EIC-FTI-2018-2020 - Fast Track to Innovation (FTI)) under grant agreement No. 971149. Project coordinator, head of CNR project unit and workpackage leader (main technical activity of CNR: research and development of distributed Brillouin and acoustic sensing system).
Distributed Acoustic Sensing (DAS) and Distributed Temperature-Strain Sensing (DTSS) are two ground-breaking Distributed Fibre Optic Sensor (D-FOS) technologies that allow large-scale measuring and mapping of acoustic vibrations, temperature, mechanical deformations, and pressure in a large variety of consumer-based, civil, industrial, and environmental applications, in particular for attaining the widespread technological nerve system in smart city environments, for instance in smart home/household monitoring (heating, survelliance, fire detection, structural heath, and so forth), as well as in product distribution/logistics (traffic, distribution and plant monitoring). This project's main objective is to develop, prototype and demonstrate, both in civil/industrial and especially in household/smart-city case studies, a new, cost-effective, Smart LightwAve Multi-modal Distributed Acoustic Strain and Temperature photonic sensing system (SLAM-DAST), which will integrate: - Distributed Temperature and mechanical deformation (Strain) Sensing (DTSS) and - Distributed Acoustic vibrations optical Sensing (DAS). For more information please visit the European Union Horizon 2020 portal project webpage:
https://cordis.europa.eu/project/id/971149
EU Horizon 2020 5D NANOPRINTING (2020-2024)
He is the Workpackage coordinator for the European project Horizon 2020 FET (Future ad Emerging Technologies), call H2020-FETOPEN-2018-2019-2020-01). “5D NanoPrinting Functional & Dynamic 3D Nano- MicroDevices by Direct Multi-Photon Lithography”. Workpackage 2: Experimental SetUp & Fabrication Tools (development of multi-parameter 2-photon absorption measurement system)
Main topics (Horizon 2020 descriptor): Optics / Material science Abstract: 5D NanoPrinting project aims to set a new paradigm in the 3D printing technology of micro- and nano-machines, providing an innovative integrated technological approach, based on two-photon 3D direct printing processes. By developing innovative smart/functional materials with tailorable properties via two photon absorption process and novel fabrication methodologies, it aims to propel forward the current state-of-the-art micro(nano)printing technologies, allowing faster prototyping and designing of nano- and micro-electromechanical systems (NEMS/MEMS). Breakthrough processes for 3D NEMS/MEMS) rapid prototyping will be developed, aspiring to become a novel gold standard for micro/nano-technologies, similarly to what 3D printing represented for manufacturing technologies in the last decade.
Project Web-site: https://5dnanoprinting.eu/project
EU Horizon 2020 PULSE (2017-2020)
He is the Scientific Coordinator of the European project "Pervasive Ubiquitous Lightwave Sensors" PULSe, funded by European Union through Horizon 2020, the Framework Programme for Research and Innovation, Fast Track to Innovation Pilot (call H2020-FTIPilot-2016-1) under grant agreement No. 737801. Project coordinator, head of CNR project unit and workpackage leader (main technical activity of CNR unit: research and development of fiber-optic sensing system).
Abstract: PULSe’s objective is to optimize, industrialize and secure the conditions for full market exploitation of the first cost-effective Brillouin distributed sensing solution based on a synergy of innovative interrogator equipment, strain sensing cable, data processing software and open-access market take-up support tools.
For more information please visit the project website:
MIUR FIRB MINOS (2013-2017)
MIcro- and NanO-structured photonic devices based on strained silicon for ultrafast Switching in Datacom applications
EU European Metrology Research Programme SIB02-REG3 (2013-2014)
- Distributed Raman amplification for phase coherent transfer of optical frequencies
EU Marie Curie (mobility) action INTERNEW (2017-2018)
Innovative interfaces for energy-related applications
https://www.bo.imm.cnr.it/unit/projects/internew-innovative-interfaces-energy-related-applications
Available MS theses in photonics:
- Quantum cryptography and quantum key distribution through optical fibers
- Optical fiber sensing employing stimulated Brillouin scattering effect
SCIENTIFIC PRODUCTION
156. Bastianini, F., Falcetelli, F., Bochenski, P., Rossi, L., Di Sante, R., Bolognini, G.
Evaluation of strain sensing cables for Brillouin optical time domain analysis through Swept Wavelength Interferometry
(2022) 2022 Italian Conference on Optics and Photonics, ICOP 2022, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85141772985&doi=10.1...
155. Rossi, L., Bastianini, F., Bolognini, G.
Linewidth narrowing and stabilization from a short cavity ring laser source design for fibre sensor applications
(2022) 2022 Italian Conference on Optics and Photonics, ICOP 2022, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85141756095&doi=10.1...
154. Falcetelli, F., Bastianini, F., Bocheński, P., Rossi, L., Di Sante, R., Bolognini, G.
Optical characterization of strain sensing cables for Brillouin optical time domain analysis
(2022) Journal of the European Optical Society-Rapid Publications, 18 (1), art. no. 7, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85140141553&doi=10.1...
153. Rossi, L., Bastianini, F., Bolognini, G.
Study of injection-locked stabilized, short cavity Brillouin ring laser source design for fiber sensing applications
(2022) Journal of the European Optical Society-Rapid Publications, 18 (1), art. no. 5, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85136969200&doi=10.1...
152. Bastianini, F., Falcetelli, F., Rossi, L., Bochenski, P., Di Sante, R., Bolognini, G.
Optical Fiber Sensor Strain Sensing Cable Characterization through Swept Wavelength Interferometry
(2021) Progress in Electromagnetics Research Symposium, 2021-November, pp. 1163-1169.
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85126396205&doi=10.1...
151. Rossi, L., Marini, D., Bastianini, F., Bolognini, G.
Enhanced performance short cavity Brillouin fiber ring laser for high-stability BOTDA sensing
(2020) Proceedings of IEEE Sensors, 2020-October, art. no. 9278695, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85098714108&doi=10.1...
150. Bastianini, F., Bochenski, P., Di Sante, R., Falcetelli, F., Rossi, L., Bolognini, G.
Strain Transfer Estimation for Complex Surface-Bonded Optical Fibers in Distributed Sensing Applications
(2020) Proceedings of 2020 Italian Conference on Optics and Photonics, ICOP 2020, art. no. 9300327, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85099590081&doi=10.1...
149. Bastianini, F., Bochenski, P., Di Sante, R., Falcetelli, F., Rossi, L., Bolognini, G.
Innovative Cable Design for Distributed Sensing Applications based on Stimulated Brillouin Scattering
(2020) Proceedings of 2020 Italian Conference on Optics and Photonics, ICOP 2020, art. no. 9300339, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85099573770&doi=10.1...
148. Rossi, L., Bastianini, F., Bolognini, G.
Brillouin optical time domain analysis employing a doubly resonant short cavity fiber ring laser with active stabilization
(2020) Proceedings of 2020 Italian Conference on Optics and Photonics, ICOP 2020, art. no. 9300323, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85099562822&doi=10.1...
147. Falcetelli, F., Rossi, L., Di Sante, R., Bolognini, G.
Strain transfer in surface-bonded optical fiber sensors
(2020) Sensors (Switzerland), 20 (11), art. no. 3100, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85085910056&doi=10.3...
146. Rossi, L., Marini, D., Bastianini, F., Bolognini, G.
Tunable and Stabilized Short Cavity Brillouin Fiber Ring Laser for BOTDA Sensing
(2020) Conference Proceedings - Lasers and Electro-Optics Society Annual Meeting-LEOS, 2020-May, art. no. 9193720, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85091667092&partnerI...
145. Bastianini, F., Bochenski, P., Di Sante, R., Falcetelli, F., Marini, D., Bolognini, G.
Strain Transfer Estimation for Complex Surface-Bonded Optical Fibers in Distributed Sensing Applications
(2020) Optics InfoBase Conference Papers, art. no. W4.55, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85136805849&partnerI...
144. Rossi, L., Marini, D., Bastianini, F., Bolognini, G.
Narrow linewidth short cavity Brillouin ring laser for BOTDA systems
(2020) Optics InfoBase Conference Papers, art. no. T3.93, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85136800084&partnerI...
143. Rossi, L., Marini, D., Bastianini, F., Bolognini, G.
Tunable and stabilized short cavity Brillouin fiber ring laser for BOTDA sensing
(2020) Optics InfoBase Conference Papers, Part F181-CLEO-AT 2020, art. no. JTu2G.11, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85095125138&doi=10.1...
142. Bastianini, F., Di Sante, R., Falcetelli, F., Bolognini, G., Marini, D.
Optical fiber sensing cables for brillouin-based distributed measurements
(2019) Sensors (Switzerland), 19 (23), art. no. 5172, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85075599943&doi=10.3...
141. Rossi, L., Marini, D., Bastianini, F., Bolognini, G.
Analysis of enhanced-performance fibre Brillouin ring laser for Brillouin sensing applications
(2019) Optics Express, 27 (20), pp. 29448-29460.
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85072711217&doi=10.1...
140. Marini, D., Rossi, L., Bastianini, F., Bolognini, G.
Wavelength-locked low-noise Brillouin ring laser for Brillouin sensing
(2019) 2019 International Workshop on Fiber Optics in Access Networks, FOAN 2019, art. no. 8933796, pp. 16-19.
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85077960534&doi=10.1...
139. Marini, D., Rossi, L., Bastianini, F., Bolognini, G.
Narrow Linewidth Fiber Brillouin Ring Laser for Sensing Applications
(2019) Progress in Electromagnetics Research Symposium, 2019-June, art. no. 9017878, pp. 2964-2969.
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85082002917&doi=10.1...
138. Rossi, L., Marini, D., Bastianini, F., Bolognini, G.
Brillouin Optical Time Domain Analysis with Wavelength-locked Low-noise Pump-probe Laser Scheme
(2019) Progress in Electromagnetics Research Symposium, 2019-June, art. no. 9017494, pp. 2958-2963.
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85081987152&doi=10.1...
137. Rossi, L., Marini, D., Bastianini, F., Bolognini, G.
Wavelength-Locked Doubly-Resonant Cavity Fibre Brillouin Ring Laser for BOTDA Sensing
(2019) 2019 Optical Fiber Communications Conference and Exhibition, OFC 2019 - Proceedings, art. no. 8696821, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85065477413&doi=10.1...
136. Rossi, L., Marini, D., Bastianini, F., Bolognini, G.
Wavelength-locked doubly-resonant cavity fibre Brillouin ring laser for BOTDA sensing
(2019) Optics InfoBase Conference Papers, Part F160-OFC 2019, art. no. OFC-2019-W2A.16, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85085542430&partnerI...
135. Marini, D., Rossi, L., Bastianini, F., Bolognini, G.
Enhanced performance low-noise Brillouin ring laser for Brillouin sensing
(2019) Proceedings of SPIE - The International Society for Optical Engineering, 11199, art. no. 111993I, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85073365851&doi=10.1...
134. Bastianini, F., Bolognini, G., Marini, D., Bocheński, P., Di Sante, R., Falcetelli, F.
Optical fiber cables for Brillouin distributed sensing
(2019) Proceedings of SPIE - The International Society for Optical Engineering, 11199, art. no. 1119926, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85073352503&doi=10.1...
133. Marini, D., Rossi, L., Bastianini, F., Bolognini, G.
Low-noise wavelength-locked Brillouin ring laser for Brillouin sensing
(2019) Proceedings of SPIE - The International Society for Optical Engineering, 11199, art. no. 1119924, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85073344612&doi=10.1...
132. Marini, D., Rossi, L., Bastianini, F., Bolognini, G.
Actively stabilized low-noise Brillouin fiber ring laser for Brillouin sensing
(2019) Proceedings of SPIE - The International Society for Optical Engineering, 10897, art. no. 108971U, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85068324530&doi=10.1...
131. Marini, D., Rossi, L., Bastianini, F., Bolognini, G.
Tunable lower-RIN Brillouin fiber ring laser for BOTDA sensing
(2018) 2018 Conference on Lasers and Electro-Optics, CLEO 2018 - Proceedings, art. no. 8427420, .
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85052574721&partnerI...
130. D. Marini, M. Iuliano, F. Bastianini, G. Bolognini, “BOTDA sensing employing a modified Brillouin fiber laser probe source”, IEEE/OSA Journal of Lightwave Technology, IEEE Press, NJ, U.S.A., vol. 36, n. 4, 2018, pp. 1131-1137. (ISSN: 0733-8724, DOI: 10.1109/JLT.2017.2772326, SCOPUS: 2-s2.0-85034265915)
129. M. Natali, S. D. Quiroga, L. Passoni, L. Criante, E. Benvenuti, G. Bolognini, L. Favaretto, M. Melucci, M. Muccini, F. Scotognella, F. Di Fonzo,S. Toffanin, “Simultaneous Tenfold Brightness Enhancement and Emitted-Light Spectral Tunability in Transparent Ambipolar Organic Light-Emitting Transistor by Integration of High-k Photonic Crystal”, Advanced functional Materials, vol. 27, n. 21, 2017, pp. 1605164-1-8. (ISSN: 1616-301X, SCOPUS: 10.1002/adfm.201605164)
128. D. Marini, M. Iuliano, F. Bastianini, G. Bolognini, “Brillouin-based fiber sensing system employing a modified Brillouin ring laser source”, 2017 Fotonica AEIT Italian Conference on Photonics Technologies - Padova, Italy, May 2017. (ISBN: 978-1-78561-757-7, DOI: 10.1049/cp.2017.0222)
127. M. Iuliano, D. Marini, F. Bastianini, G. Bolognini, “BOTDA sensing system employing a tunable low-cost Brillouin fiber ring laser pump-probe source”, Proc. SPIE, The International Society for Optical Engineering, vol. 10323, p. 509, 2017. (ISSN: 0227-786X)
126. S. Toffanin, M. Natali, S. D. Quiroga, L. Passoni, L. Criante, E. Benvenuti, G. Bolognini, L. Favaretto, M. Melucci, M. Muccini, F. Scotognella, F. Di Fonzo, “Simultaneous 10-fold brightness increase and emitted-light tunability in transparent ambipolar organic light-emitting transistor by integration with inorganic high-k photonic crystal”, Proc. SPIE, The International Society for Optical Engineering, vol. 10360, p. 10360-13. (ISSN: 0227-786X)
125. D. Marini, G. B. Montanari, F. Mancarella, F. Bonafè, M. Ferri, R. Balboni, G. Bolognini, “Birefringence and strain distribution analysis in silicon photonics structures”, Materials.it 2016 1st Italian Conference on Materials Science and Technology, Catania, Italy, Dec 2016, p. 363.
124. D. Marini, F. Bastianini, G. Bolognini, “Optical source for fiber optic distributed sensing based on Brillouin scattering”, Materials.it 2016 1st Italian Conference on Materials Science and Technology, Catania, Italy, Dec 2016, p. P015.
123. F. Bastianini, D. Marini, G. Bolognini, “Tunable Ring Laser for BOTDA and BOFDA Sensing”, 2016 Fotonica AEIT Italian Conference on Photonics Technologies - Rome, Italy, June 2016, p. 5.4.
122. S. Toffanin, M. Natali, S. D. Quiroga, G. P. Donati, E. Benvenuti, M. Melucci, G. Bolognini, L. Passoni, L. Criante, F. Scotognella, F. Di Fonzo, “Monolithic integration of oxide transparent multilayer photonic crystal as optoelectronic gate dielectric into organic light-emitting transistor platform”, 2016 Fotonica AEIT, Italian Conference on Photonics Technologies – Rome, Italy, June 2016, p. A.31.
121. M. Virgilio, B. Witzigmann, G. Bolognini, S. Guha, T. Schroeder, G. Capellini, “A CMOS-compatible switching/modulation concept based on strain-induced refractive-index tuning”, Optics Express, vol. 23, n. 5, pp. 5930-5940, 2015 (ISSN: 1094-4087)
120. C. Clivati, G. Bolognini, D. Calonico, S. Faralli, A. Mura, F. Levi,, “In-field Raman amplification on coherent optical fiber links for frequency metrology”, Optics Express, vol. 23, n. 8, pp. 10604-10615, 2015 (ISSN: 1094-4087).
119. D. Marini, G. B. Montanari, F. Mancarella, F. Bonafè, M. Ferri, R. Balboni, G. Bolognini, “Strain assessment in strained-silicon photonic structures”, European Optical Society Topical Meeting on Optical Microsystems - Capri, Italy, Sep 2015, paper OFS’15_07.
118. G. Bolognini, C. Clivati, S. Faralli, F. Levi, A. Mura, D. Calonico, “Optical Frequency Transfer Employing Bi-Directional Distributed Raman Amplification”, European Optical Society Topical Meeting on Optical Microsystems - Capri, Italy, Sep 2015, paper, paper OmS’15_51.
117. F. Bastianini, D. Marini, G. Bolognini, “Modified Brillouin ring laser technology for Brillouin-based sensing”, Proc. SPIE, The International Society for Optical Engineering, vol. 9634, pp. 96345E, 2015. (ISSN: 0227-786X)
116. D. Marini, G. B. Montanari, F. Mancarella, M. Ferri, R. Balboni, G. Bolognini, “Study of birefringence and strain distribution in silicon waveguides and coupling structures”, 2015 Fotonica AEIT Italian Conference on Photonics Technologies - Turin, Italy, May 2015, paper A.7.6. (ISBN: 978-1-78561-068-4)
115. G. Bolognini, C. Clivati, S. Faralli, A. Mura, F. Levi, D. Calonico, “Coherent Frequency Transfer over Long-Haul and Shared Optical Fiber Links Employing Distributed Raman Amplification”, 2015 Fotonica AEIT Italian Conference on Photonics Technologies - Turin, Italy, May 2015, paper C.1.7. (ISBN: 978-1-78561-068-4)
114. G. B. Montanari, F. Mancarella, R. Balboni, D. Marini, F. Corticelli, M. Sanmartin, M. Ferri, G. Bolognini, “Induced strain in silicon waveguides and couplers”, Proc. SPIE, The International Society for Optical Engineering, vol. 9367, p. 93671L (ISSN: 0277-786X, SCOPUS: 2-s2.0-84928818903)
113. D. Marini, G. B. Montanari, F. Mancarella, M. Ferri, R. Balboni, G. Bolognini, “Lattice deformations in strained-silicon rib structures for photonic devices”, 2014 Fotonica AEIT Italian Conference on Photonics Technologies, Napoli, Italy, May 2014, P.1.25. (ISBN: 978-8-8872-3718-4, SCOPUS: 2-s2.0-84904480239)
112. G. Bolognini, S. Faralli, C. Clivati, F. Levi, A. Mura, D. Calonico, “Metrological transfer of phase-coherent optical frequencies over long distances employing distributed Raman amplification”, 2014 Fotonica AEIT Italian Conference on Photonics Technologies, May 2014, paper P.1.27. (ISBN: 978-8-8872-3718-4, SCOPUS: 2-s2.0-84904498267)
111. D. Marini, G. B. Montanari, F. Mancarella, M. Ferri, R. Balboni, G. Bolognini, “Study of Induced Strain in Silicon Rib Structures”, Proceedings of the 11th International IEEE Conference on Group IV Photonics, Paris, France, Aug 2014, p. 195-196. (ISSN: 1949-2081, SCOPUS: 2-s2.0-84914179724)
110. G. Bolognini, D. Calonico, C. Clivati, S. Faralli, A. Mura, F. Levi, “Distributed Raman amplification in phase coherent transfer of optical frequencies over long-haul and metro fiber links”, IEEE Photonics Conference, San Diego, USA, Oct 2014, p. We1.3. (ISBN: 978-145771504-4, SCOPUS: 2-s2.0-84921297890)
109. H. Schnatz, G. Bolognini, D. Calonico, E. Dierikx, G. Grosche, P. O. Hedekvist, A. Kuna, G. Marra, M. Merimaa, A. Niessner, P. E. Pottie, Ł. Śliwczyński, R. Slavik, V. Smotlacha, F. Spahic, “NEAT-FT: The European Fiber Link Collaboration”, Joint IEEE International Frequency Control Symposium (IFCS) and European Frequency and Time Forum (EFTF), Switzerland, 2014, p. A1L-A.1 (invited).
108. N. Andriolli, I. Cerutti, P. Pintus, M. Scaffardi, D. Marini, G. B. Montanari, F. Mancarella, M. Ferri, R. Balboni, G. Bolognini, “Challenges and Progress toward a Silicon-based Multi-Microring Optical Network-on-Chip”, Proceedings of EUCNC 2014, 23rd European Conference on Networks and Communications, Italy, June 2014, p. 1-5 (DOI: 10.1109/EuCNC.2014.6882631, SCOPUS: 2-s2.0-84906969146).
107. R. Balboni, G. Bolognini, F. Corticelli, M. Ferri, F. Mancarella, D. Marini, G. B. Montanari, “Strain determination by CBED in Si-rib structures for photonic devices”, 18th International Microscopy Congress, Prague, Czech Republic, Sep 2014, P. MS-8-P-2815. (ISBN 978-80-260-6720-7)
106. G. Bolognini, C. Clivati, G. Costanzo, M. Frittelli, F. Levi, A. Mura, S. Schiller, D. Calonico, “Giant-area fiber-optic gyroscope with Raman-based temperature sensing for metrological applications”, Proc. of SPIE, Vol. 9157, pp. 915724.1-4, 2014. (ISSN: 0227-786X, SCOPUS: 2-s2.0-84903204378)
105. M. Taki, M. A. Soto, F. Di Pasquale, G. Bolognini, “Differential pulsewidth-pair Brillouin optical time-domain analysis employing Raman amplification and optical pulse coding”, in Sensors and Microsystems, C. Di Natale et al. Eds., Lecture Notes in Electrical Engineering, vol. 268, Springer Verlag publ., pp. 251-254, 2014 (ISSN: 1876-1100, ISBN: 978-3-319-00683-3).
104. F. Di Pasquale, M. Soto, G. Bolognini, “Raman based distributed optical fiber temperature sensors: industrial applications and future developments”, in Photonics for Safety and Security, A. Cutolo, et al. edit., World Scientific Publishing Co., Nov 2013, pp. 88-113 (DOI: 10.1142/9789814412971_0005, ISBN: 978-981-4412-96-4)
103. G. Bolognini, A. Hartog, “Raman based fibre sensors: trends and applications”, Optical Fiber Technology, Opt. Fiber Technol. (2013), vol. 19, n. 6, Dec 2013, pp. 678-688. (ISSN: 1068-5200)
102. G. Bolognini, C. Clivati, D. Calonico, S. Faralli, F. Levi, A. Mura, N. Poli, “Fiber Raman amplification for metrological transfer of phase-coherent optical frequencies”, Proc. of 39th European Conference for Optical communications, London, UK, IET Conf. Publications, vol. 2013, n. 622, pp. 327-329, Sep 2013. (ISBN: 978-1-84919-759-5, DOI: 10.1049/cp.2013.1382).
101 C. Clivati, G. Bolognini, D. Calonico, S. Faralli, F. Levi, A. Mura, N. Poli, “Distributed Raman Optical Amplification in Phase Coherent Transfer of Optical Frequencies”, IEEE Photonics Technology Letters, IEEE Press, N.J., U.S.A., vol. 25, n. 17, Sep 2013, p. 1711-1714.
100 C. Clivati, G. Costanzo, M. Frittelli, D. Calonico, F. Levi, A. Mura, G. Bolognini, S. Faralli, N. Poli, “Distributed amplification for coherent optical fiber links”, in Fotonica 2013, 15° Convegno Nazionale delle Tecnologie Fotoniche, Milan, Italy, May 2013, p. C6.4 (ISBN 9788887237160).
99. C. Clivati, G. Bolognini, D. Calonico, G. Costanzo, S. Faralli, F. Levi, A. Mura, N. Poli, “Distributed Raman Amplification for long-haul optical frequency dissemination”, Joint IEEE International Frequency Control Symposium (IFCS) and European Frequency and Time Forum (EFTF), Czech Republic, 2013, pp. 1007-1009 (DOI: 10.1109/EFTF-IFC.2013.6702168, ISBN: 978-1-4799-0342-9)
98. M. Taki, M. A. Soto, G. Bolognini, F. Di Pasquale, “Study of Raman amplification in DPP-BOTDA sensing employing Simplex coding for sub-meter scale spatial resolution over long fiber distances”, Measurement Science Technology, Institute of Physics Publisher, vol. 24, n. 9, Sep 2013, pp. 094018-1, 094018 -6 (ISSN: 0957-0233).
97. T. Nannipieri, M. Taki, F. Zaidi, A. Signorini, M. A. Soto, G. Bolognini, F. Di Pasquale, “Hybrid BOTDA/FBG sensor for discrete dynamic and distributed static strain/temperature measurements”, Proc. of SPIE, Vol. 8421, pp. 842121.1-4, Oct 2012. (ISSN: 0227-786X)
96. M. Taki, M. A. Soto, G. Bolognini, F. Di Pasquale, “Raman-assisted DPP-BOTDA sensor employing Simplex coding with sub-meter scale spatial resolution over 93 km standard SMF”, Proc. of SPIE, Vol. 8421, pp. 842119M.1-4, Oct 2012. (ISSN: 0227-786X)
95. M. Soto, A. Signorini, T. Nanninipieri, S. Faralli, G. Bolognini, F. Di Pasquale, “Impact of Loss Variations on Double-Ended Distributed Temperature Sensors Based on Raman Anti-Stokes Signal Only”, IEEE/OSA Journal of Lightwave Technology, IEEE Press, NJ, U.S.A., vol. 30, n. 8, Apr. 2012, p. 1215-1222. (ISSN:0733-8724)
94. F. Zaidi, T. Nannipieri, M. A. Soto, A. Signorini, G. Bolognini, F. Di Pasquale, “Integrated hybrid Raman/FBG interrogation scheme for distributed temperature and point dynamic strain measurements”, Applied Optics, vol. 51, n. 30, Oct. 2012, p. 7268-7275. (ISSN: 1559-128X)
93. M. A. Soto, M. Taki, G. Bolognini, F. Di Pasquale, “Simplex-coded BOTDA sensor over 120 km SMF with 1 m spatial resolution assisted by optimized bidirectional Raman amplification”, IEEE Photonics Technology Letters, IEEE Press, N.J.,U.S.A., vol. 24, n. 20, Oct. 2012, p. 1823-1826.
92. M. Soto, M. Taki, G. Bolognini, F. Di Pasquale, “Optimization of a DPP-BOTDA sensor with 25 cm spatial resolution over 60 km standard single-mode fiber using Simplex codes and optical pre-amplification”, Optics Express, vol. 20, n. 7, pp. 6860-6869, Mar 2012 (ISSN: 1094-4087)
91. M. Taki, M. Soto, F. Di Pasquale, G. Bolognini, “Long-range distributed strain and temperature sensor based on Brillouin optical time-domain analysis employing Raman amplification and Simplex coding”, Fotonica 2012, Florence, Italy, pp. B6.1.1-6, May 2012. (ISBN: 978-8-8872-3714-6)
90. F. Zaidi, T. Nannipieri, M. Soto, A. Signorini, G. Bolognini, F. Di Pasquale, “Hybrid Raman/FBG-based sensing for simultaneous point dynamic strain and distributed temperature measurement”, Optical Fiber Communication Conference (OFC 2012) Tech. Dig., Optical Society of America, Washington, DC, 2012, JW2A.26. (ISBN: 978-1-55752-935-0)
89. M. Taki, M. Soto, G. Bolognini, F. Di Pasquale, “Enhanced-performance BOTDA sensing through optimized pulse coding and low-RIN bidirectional Raman amplification”, Optical Fiber Communication Conference (OFC 2012) Tech. Dig., Optical Society of America, Washington, DC, 2012, p. OTu1C.6. (ISBN: 978-1-55752-935-0)
88. M. Taki, M. Soto, F. Di Pasquale, G. Bolognini, “Long-range BOTDA sensing using optical pulse coding and single-source bi-directional distributed Raman amplification”, IEEE Sensors Conference 2011, Limerick, Ireland, pp. 382-385, Oct 2011. (ISSN : 1930-0395, ISBN: 978-1-4244-9290-9)
87. M. Soto, T. Nannipieri, A. Signorini, A. Lazzeri, F. Baronti, R. Roncella, G. Bolognini, F. Di Pasquale, “Raman-based distributed temperature sensor with 1 m spatial resolution over 26 km SMF using low-repetition-rate cyclic pulse coding”, Optics Letters, vol. 36, n. 13, pp. 2557-2559, July 2011.
86. M. Soto, T. Nannipieri, A. Signorini, A. Lazzeri, F. Baronti, R. Roncella, G. Bolognini, F. Di Pasquale, “Advanced cyclic coding technique for long-range Raman DTS systems with meter-scale spatial resolution over standard SMF”, IEEE Sensors 2011, Limerick, Ireland, pp. 878-881, Oct 2011. (ISSN : 1930-0395, ISBN: 978-1-4244-9290-9)
85. M. Taki, M. Soto, S. Faralli, F. Di Pasquale, G. Bolognini, “Study of long-range distributed sensors based on Brillouin optical time-domain analysis employing bi-directional Raman amplification”, Fotonica 2011, 13° Convegno Nazionale delle Tecnologie Fotoniche, Genova, Italy, May 2011, paper C1.5.(ISBN 9788887237122)
84. A. Signorini, T. Nannipieri, M. A. Soto, S. Faralli, G. Bolognini, F. Di Pasquale, “Sensori distribuiti di temperatura in fibra ottica basati su effetto Raman mediante rivelazione di sola radiazione Anti-Stokes in configurazione a loop”, Fotonica 2011, 13° Convegno Nazionale delle Tecnologie Fotoniche, Genova, Italy, May 2011, p. C1.6. (ISBN 9788887237122)
83. M. A. Soto, A. Signorini, T. Nannipieri, S. Faralli, G. Bolognini, F. Di Pasquale, “Distributed optical fiber temperature sensor using only anti-Stokes Raman scattering light in a loop configuration”, Proc. SPIE (OFS 2011), May 2011, p. . (ISSN: 0227-786X)
82. M. Taki, M. Soto, G. Bolognini, F. Di Pasquale, “Long-range distributed strain and temperature sensing with 40-cm spatial resolution based on DPP-BOTDA employing optical pre-amplification and Simplex coding”, OFC 2011 Tech. Dig., Los Angeles, USA, p. OTuL2
81. M. A. Soto, S. Faralli, M. Taki, G. Bolognini, F. Di Pasquale, “BOTDA sensor with 2-m spatial resolution over 120 km distance using bi-directional distributed Raman amplification”, Proc. SPIE (OFS 2011), May 2011, p. 7753-162. (ISSN: 0227-786X)
80. M. Soto, G. Bolognini, F. Di Pasquale, “Optimization of long-range BOTDA sensor with high resolution using first-order bi-directional Raman amplification”, Optics Express, vol. 19, n.5, pp. 4444-4457 (2011).
79. M. Soto, G. Bolognini, F. Di Pasquale, “Long-range Simplex-coded BOTDA sensor over 120 km distance employing optical pre-amplification”, Optics Letters, 2011, vol. 36, pp. 232-234.
78. M. A. Soto, A. Signorini, T. Nannipieri, S. Faralli, G. Bolognini, “High performance distributed temperature sensing using only anti-Stokes Raman scattering light in a loop configuration”, IEEE Photonics Technology Letters, IEEE Press, N.J.,U.S.A., vol. 23, n. 9, pp. 534-536, May 2011. ISI journal.
77. G. Bolognini, M. Soto, F. Di Pasquale, “Simultaneous distributed strain and temperature sensing based on combined Raman and Brillouin scattering using Fabry-Pérot lasers”, Meas. Sci. Technol., Aug 2010. (ISSN: 0957-0233) ISI journal
76. F. Baronti, A. Lazzeri, R. Roncella, R. Saletti, A. Signorini, M. A. Soto, G. Bolognini, F. Di Pasquale “'SNR enhancement of Raman–based long–range distributed temperature sensors using cyclic Simplex codes”, Electronics Lett., IET Press, vol. 46, Aug 2010. (ISSN:0013-5194) ISI journal
75 M. Soto, G. Bolognini, F. Di Pasquale, “Analysis of pulse modulation format in coded BOTDA sensors”, Optics Express, vol. 18, n. 14, pp. 14878-14892, Jun 2010. (ISSN:0733-8724)
74. M. Soto, G. Bolognini, F. Di Pasquale, “Laser Fabry-Perot per sensori distribuiti di temperatura e deformazione in fibra ottica basati su retro-diffusione Raman e Brillouin”, Fotonica 2010, Pisa, Italy, May 2010, paper C.6.5
73. M. A. Soto, G. Bolognini, F. Di Pasquale, “Impact of the pulse modulation format on distributed BOTDA sensors based on Simplex coding”, EWOFS 2010 Conference, Oporto, Portugal, Sep 2010, p 4.9.
72. M. Soto, G. Bolognini, F. Di Pasquale, L. Thévenaz, “Long-range Brillouin optical time-domain analysis sensor employing pulse coding techniques”, Meas. Sci. Technol., Aug 2010. (ISSN: 0957-0233) ISI journal
71. G. Bolognini, M. Soto, “Optical pulse coding in hybrid distributed sensing based on Raman and Brillouin scattering employing Fabry-Perot lasers”, Optics Express, vol. 18, n. 8, pp. 8459-8465, Apr 2010. (ISSN:0733-8724) ISI journal
70. M. Soto, G. Bolognini, F. Di Pasquale, L. Thévenaz, “Simplex-coded BOTDA sensor with 1 m spatial resolution over a 50 km range”, Optics Letters, vol. 135, n. 2, pp. 259-261, Jan 2010.
69. M. A. Soto, G. Bolognini, F. Di Pasquale, “Enhanced distributed hybrid sensor based on Brillouin and Raman scattering combining Fabry-Perot lasers and optical pulse coding”, Technical Digest, Optical Fiber Communication Conference OFC 2010, San Diego, USA, Mar 2010, paper OthA1.
68. A. Signorini, S. Faralli, M. Soto, G. Sacchi, F. Baronti, R. Barsacchi, A. Lazzeri, R. Roncella, G. Bolognini, F. Di Pasquale, “40 km long-range Raman-based distributed temperature sensor with meter-scale spatial resolution”, Technical Digest, Optical Fiber Communication Conference OFC 2010, San Diego, USA, Mar 2010, paper OWL2.
67. G. Bolognini, A. Bononi, “Reduction of double Rayleigh scattering noise in distributed Raman amplifiers employing higher-order pumping”, Optics Express, vol. 17, n. 9, pp. 6996-7003, Apr 2009.
66. M. A. Soto, G. Bolognini, F. Di Pasquale, “Distributed optical fibre sensors based on spontaneous Brillouin scattering employing multimode Fabry-Pérot lasers”, Electronics Letters, IET Press, vol. 45, n. 21, p. 1071-1072, Oct 2009. (ISSN:0013-5194)
65. G. Bolognini, M. Soto, F. Di Pasquale, “Fiber-optic distributed sensor based on hybrid Raman and Brillouin scattering employing multi-wavelength Fabry-Pérot lasers” , IEEE Photonics Technology Letters, IEEE Press, N.J.,U.S.A., vol. 21, n. 20, pp. 1523-1525, Oct 2009.
64. M. Soto, G. Bolognini, F. Di Pasquale, “Enhanced long-range distributed strain and temperature sensing using BOTDA and optical pulse coding”, ECOC 2009 Conference, Vienna, Austria, p PD.1.3 (post-deadline).
63. M. Soto, G. Bolognini, F. Di Pasquale, “Distributed strain and temperature sensing over 50 km of SMF with 1 m spatial resolution employing BOTDA and optical pulse coding”, Optical Fiber Sensor Conf., OFS 2009, Glasgow, UK, Tech. Digest, p. PD09-1 (post-deadline).
62. M. Soto, G. Bolognini, F. Di Pasquale, “Use of Fabry-Pérot lasers for simultaneous distributed strain and temperature sensing based on hybrid Raman and Brillouin scattering”, Optical Fiber Sensor Conf., OFS 2009, Glasgow, UK, Tech. Digest, p. OF101-73.
61. M. Soto, G. Bolognini, F. Di Pasquale, “Fabry-Perot lasers in simultaneous strain and temperature Brillouin-based distributed sensing”, ECOC 2009 Conference, Vienna, Austria, p Tu.4.1.5.
60. M. Soto, G. Bolognini, F. Di Pasquale, “Studio di prestazioni in sensori in fibra ottica per la misura simultanea di temperatura e deformazione basati su effetto Brillouin con utilizzo di codifica e rivelazione coerente”, Fotonica 2009, Pisa, Italy, paper C4.2.
59. M. A. Soto, G. Bolognini, F. Di Pasquale, “Enhanced simultaneous distributed strain and temperature fiber sensor employing spontaneous Brillouin scattering and optical pulse coding”, IEEE Photonics Technology Letters, IEEE Press, N.J., U.S.A., vol. 21, n. 7, pp. 450-452, Apr 2009. (ISSN:1041-1135)
58. M. A. Soto, G. Bolognini, F. Di Pasquale, “Performance improvement in Brillouin-based simultaneous strain and temperature sensors employing pulse coding in coherent detection schemes”, Technical Digest, Optical Fiber Communication Conference OFC 2009, San Diego, USA, Mar 2009, paper OthU4.
57. A. Signorini, M. A. Soto, S. Faralli, G. Bolognini, F. Di Pasquale, E. Fedeli, E. Marzilli, R. Tarelli, “Progetto e sviluppo di sensori distribuiti di temperatura in fibra ottica per rivelazione di incendi in gallerie ferroviarie”, Sicurezza ed Esercizio Ferroviario, Convegno Nazionale, Atti del Convegno, Roma, p. SEF09, 20 Marzo 2009.
56. M. A. Soto, G. Bolognini, F. Di Pasquale, “Analysis of optical coding in spontaneous Brillouin-based distributed temperature sensors”, Optics Express, vol. 16, n.23, Nov 2008, pp. 19097-19111.
55. T. Rogowski, S. Faralli, G. Bolognini, F. Di Pasquale, R. Di Muro, B. Nayar, “ Transient control in SOA-based WDM metro ring networks under Add/Drop using a reservoir channel”, IEEE Photonics Technology Letters, IEEE Press, N.J.,U.S.A., vol. 20, n.13, 2008. (ISSN:1041-1135)
54. M. A. Soto, P. K. Sahu, G. Bolognini, F. Di Pasquale, “Brillouin-based distributed temperature sensor employing pulse coding”, IEEE Sensors Journal, IEEE Press, NJ, U.S.A., vol. 8, n. 3, Mar 2008 (ISSN:0733-8724)
53. F. Di Pasquale, M. Soto, G. Bolognini, “Optical pulse coding applied to distributed temperature sensor using spontaneous Brillouin frequency shift”, Korea-Italy Bilateral Workshop on Photonics for Communication and Sensing, Oct 23-24, 2008 Seoul, Korea, p. 55-56
52. P. K. Sahu, M. A. Soto, J. Lee, G. Bolognini, N. Park, F. Di Pasquale, “Analysis of Brillouin-based distributed fiber sensors using optical pulse coding”, Technical Digest, Optical Fiber Communication Conference OFC 2008, San Diego, USA, Mar 2008, paper OMT1.
51. G. Bolognini, A. Bononi, “Analysis of double Rayleigh scattering noise in higher-order pumped distributed Raman amplifiers”, Proceedings of the European Conference on Optical Communication ECOC 2008, Sep 2008, Bruxelles, Belgium, vol. 5, pp.51-52.
50. M. A. Soto, G. Bolognini, F. Di Pasquale, “Optical Pulse Coding Applied to Distributed Temperature Sensor Using Coherent Detection of Spontaneous Brillouin Frequency Shift”, Proceedings of the European Conference on Optical Communication ECOC 2008, Sep 2008, Bruxelles, Belgium, vol. 3, pp.163-164.
49. M. A. Soto, G. Bolognini, F. Di Pasquale, “30-km spontaneous-Brillouin distributed temperature sensor employing Simplex-coding and low optical input power”, Proceedings of the IEEE Sensors Conference, Lecce, Italy, Oct 2008, pp. 282-285.
48. S. Faralli, G. Bolognini, M. A. Andrade, F. Di Pasquale, “Unrepeated WDM transmission systems based on advanced first- and higher-order Raman co-pumping technologies”, IEEE/OSA Journal of Lightwave Technology, IEEE Press, NJ, U.S.A., vol. 25, n. 11, Nov. 2007. (ISSN:0733-8724) ISI Journal
47. G. Bolognini, J. Park, M. A. Soto, N. Park, and F. Di Pasquale, “Analysis of distributed temperature sensing based on Raman scattering using OTDR coding and discrete Raman amplification”, Measurement Science Technology, vol. 18, n. 10, Oct 2007, pp. 3211-3218
46. T. Rogowski, S. Faralli, G. Bolognini, F. Di Pasquale, R. Di Muro, B. Nayar, “SOA-based WDM metro ring networks with link control technologies”, IEEE Photonics Technology Letters, IEEE Press, N.J., U.S.A., vol. 19, n. 20, Oct 2007, pp. 1670-1672. (ISSN:1041-1135)
45. M. A. Soto, P. K. Sahu, S. Faralli, G. Bolognini, F. Di Pasquale, B. Nebendahl, C. Rueck, “Distributed temperature sensor system based on Raman scattering using correlation-codes”, Electronics Letters, vol. 43, n. 16, Aug 2007. (ISSN:0013-5194)
44. S. Faralli, G. Bolognini, F. Di Pasquale, “Design optimisation of high power and low RIN lasers for efficient Raman co-pumping”, Technical Digest, Optical Fiber Communication Conference OFC 2007, paper JthA13. (ISBN:1-55752-802-0)
43. T. Rogowski, S. Faralli, G. Bolognini, F. Di Pasquale, R. Di Muro, B. Nayar, “Mitigation of XGM and add/drop induced penalties in SOA-based metro WDM ring networks”, Proceedings of the European Conference on Optical Communication ECOC 2007, Berlin, Germany, p. 9.4.3.
42. N. Park, J. Lee, J. Park, J. G. Shim, H. Yoon, J. H. Kim, K. Kim, J. Byun, G. Bolognini, D. Lee, F. Di Pasquale, “Coded optical time domain reflectometry: principle and applications”, in Proceedings of SPIE, the International Society for Optical Engineering, vol. 6781, Passive Components and Fiber-based Devices II, Ming-Jun Li et al. Editors, p. 6781-76 (2007). (ISSN: 0277-786X)
41. M. A. Soto, P. K. Sahu, S. Faralli, G. Sacchi, G. Bolognini, F. Di Pasquale, B. Nebendahl, C. Rueck, “High performance and highly reliable Raman based distributed temperature sensors based on correlation coded OTDR and multimode graded index fibers”, in Proceedings of SPIE, the International Society for Optical Engineering 2007, Vol. 6619, A. Cutolo et al. Editors, p. 66193B, 04-07-2007. (ISSN: 0277-786X)
40. F. Di Pasquale, S. Faralli, G. Bolognini, “Tecniche avanzate di amplificazione Raman co-propagante per sistemi di trasmissione ottica WDM non ripetuti”, Fotonica 2007, Atti del Convegno, Mantova, Italy, paper A7.1.
39. G. Bolognini, F. Di Pasquale, J. Park, N. Park, and M. A. Soto, “Sensori distribuiti di temperatura in fibra ottica basati su effetto Raman mediante codifica di impulso e amplificazione Raman concentrata”, Fotonica 2007, Atti del Convegno, Mantova, Italy, paper B5.2.
38. S. Faralli, G. Bolognini, G. Sacchi, F. Di Pasquale, “Raman amplifier structure”, brevetto di invenzione internazionale N. WO2007009915, publication date 25/01/2007, World Intellectual Property Organization (WIPO), Geneve, Switzerland.
37. G. Bolognini, S. Faralli, A. Chiuchiarelli, F. Falconi, F. Di Pasquale, “High-power and low-RIN lasers for advanced first- and higher-order Raman co-pumping”, IEEE Photonics Technology Letters, IEEE Press, NJ, U.S.A., Vol. 18, pp. 1591-1593 (2006). (ISSN:1041-1135)
36. J. Park, G. Bolognini, P. Kim, D. Lee, F. Di Pasquale, and N. Park, “Raman-based Distributed Temperature Sensor with Simplex Coding and Link Optimisation”, IEEE Photonics Technology Letters, IEEE Press, NJ, U.S.A., Vol. 18, pp. 1879-1881 (2006).
35. G. Bolognini, J. Park, P. Kim, D. Lee, F. Di Pasquale, N. Park, “Performance enhancement of Raman-based distributed temperature sensors using Simplex codes”, Technical Digest, Optical Fiber Communication Conference OFC 2006, Anaheim ,USA, Mar 2006, paper OtuL1. (ISBN:1-55752-802-0)
34. G. Bolognini, S. Faralli, G. Sacchi, C. Cantini, F. Di Pasquale, “A new high-power and low-RIN Raman pump laser for improved performance in long-span unrepeated WDM transmission systems”, Technical Digest, Optical Fiber Communication Conference 2006, Anaheim ,USA, Mar 2006, paper OWD3. (ISBN:1-55752-802-0)
33. S. Faralli, G. Bolognini, A. Chiuchiarelli, R. Magri, F. Falconi, and F. Di Pasquale, “Advanced first- and second-order Raman co-pumping schemes for improved performance in unrepeated WDM transmission systems”, Proceedings of the European Conference on Optical Communication ECOC 2006, Cannes, France, Sep 2006, p. Th.3.2.5. (ISBN:041-1135)
32. G. Bolognini, J. Park, A. Chiuchiarelli, N. Park, and F. Di Pasquale, “Improved performance in Raman-based distributed temperature sensing with coded OTDR and discrete Raman amplification”, Technical Digest, Optical Fiber Sensor Conference OFS 2006, Cancun, Mexico, Oct 2006, p. ThE45.(ISBN:1-55752-817-9)
31. C. Cantini, S. Faralli, G. Sacchi, G. Bolognini, F. Falconi, F. Di Pasquale, G. Prati, “Transmission of 8x10 Gb/s WDM channels over 70 dB of standard SM fiber based on advanced first-order Raman co-Pumping”, Technical Digest, Conference on Lasers and Electro-Optics CLEO 2006, Long Beach, USA, May 2006, paper CThP5. (ISBN: 1-55752-813-6)
30. G. Bolognini, J. Park, A. Chiuchiarelli, N. Park, and F. Di Pasquale, “Improved performance in Raman-based distributed temperature sensing with 255-bit coded OTDR”, Proc. of China-Italy Bilateral Workshop on Photonics for Communication and Sensing 2006, Oct 23-24, 2006 Xi'an, China, paper Tu1.4
29. F. Di Pasquale, G. Bolognini, S. Faralli, A. Chiuchiarelli, “Advanced Raman co-pumping schemes for improved performance in unrepeated WDM transmission systems”, Proc. of China-Italy Bilateral Workshop on Photonics for Communication and Sensing 2006, Oct 23-24, 2006 Xi'an, China, paper Mo4.3.
28. S. Faralli, G. Bolognini, G. Sacchi, F. Di Pasquale, “Struttura di amplificatore Raman”, brevetto di invenzione nazionale depositato N. MI2005A001422, 22nd July 2005 presso: Italian Patent and Trademark Office (Ufficio Italiano Brevetti e Marchi).
27. G. Bolognini, S. Sugliani, F. Di Pasquale, “Optimal bi-directional Raman pumping in dispersion-shifted fibers for WDM inter-channel FWM reduction”, IEE Electronics Letters, April 2005, Vol. 41, No. 9. (ISSN:0013-5194)
26. S. Faralli, G. Bolognini, G. Sacchi, S. Sugliani, F. Di Pasquale, “Bi-directional higher-order cascaded Raman amplification benefits for 10 Gb/s WDM unrepeated transmission systems”, IEEE/OSA Journal of Lightwave Technology, IEEE Press, NJ, U.S.A., Vol. 23, pp. 2427-2433 (2005). (ISSN:0733-8724)
25. S. Faralli, P. Kim, C. Cantini, G. Bolognini, G. Sacchi, N. Park, F. Di Pasquale, “High Performance Discrete Amplifier Based on a Second Order Fiber Raman Oscillator”, IEEE Photonics Technology Letters, IEEE Press, NJ, U.S.A., Vol. 17, pp. 2298-2300 (2005). (ISSN:1041-1135)
24. G. Bolognini, S. Faralli, S. Sugliani, G. Sacchi, F. Di Pasquale, “Bi-directional higher order Raman pumping for improved performances in long span 10 Gb/s WDM unrepeated transmission systems”, Technical Digest, Optical Fiber Communication Conference OFC 2005, Anaheim, USA, paper OME56. (ISBN: 1-55752-784-9)
23. S. Faralli, P. Kim, C. Cantini, G. Sacchi, G. Bolognini, N. Park, F. Di Pasquale, “High gain and low noise discrete amplifier based on a 2nd-order Raman fiber ring oscillator”, Proceedings of the European Conference on Optical Communication ECOC 2005, Glasgow, UK, Sep 2005, paper Th3.3.3. (ISBN:086341-547-4),
22. F. Di Pasquale, S. Faralli, G. Bolognini, C. Cantini, G. Sacchi, “Advanced bi-directional Raman pumping schemes for long span unrepeated WDM transmission systems”, in Proceedings of SPIE, the International Society for Optical Engineering, 2005, Vol. 6019, Passive Components and Fiber-based Devices II, Y. Sun et al. Editors, pp. 60190G.1-12. (ISSN: 0277-786X)
21. G. Bolognini, G. Sacchi, S. Faralli, C. Cantini, F. Di Pasquale, “Benefits of bi-directional Raman pumping for 10 Gb/s C-band WDM transmission over long DSF spans”, Technical Digest, Optical Amplifiers and their Applications OAA 2005, Budapest, Hungary, Aug 2005, paper ME5. (ISBN: 1-55752-790-3)
20. J. Park, G. Bolognini, P. Kim, D. Lee, F. Di Pasquale, and N. Park, “Performance enhancement of Raman distributed temperature sensor using Simplex codes”, Photonics Conference 2005, Korea, Nov. 2005, paper FP41.
19. G. Bolognini, S. Sugliani, F. Di Pasquale, “Pompaggio Raman bi-direzionale su fibre DSF per riduzione di FWM tra canali WDM”, Fotonica 2005, Atti del Convegno, Bari, Italy, 30 Maggio - 1 Giugno 2005, paper B6.2. (ISBN: 1-55752-790-3)
18. G. Bolognini, F. Di Pasquale, “Transient effects in gain clamped discrete Raman amplifier cascades”, IEEE Photonics Technology Letters, IEEE Press, NJ, U.S.A., Vol. 16, Jan 2004. (ISSN:1041-1135)
17. G. Bolognini, S. Sugliani, F. Di Pasquale, “Double Rayleigh scattering noise in Raman amplifiers using pump time-division multiplexing schemes”, IEEE Photonics Technology Letters, IEEE Press, NJ, U.S.A., Vol. 16, n. 5, May 2004. (ISSN:1041-1135)
16. S. Sugliani, G. Sacchi, G. Bolognini, S. Faralli, F. Di Pasquale, “Effective suppression of penalties induced by parametric nonlinear interaction in distributed Raman amplifiers based on NZ-S fibers”, IEEE Photonics Technology Letters, IEEE Press, NJ, U.S.A., Vol. 16, n. 1, Jan 2004. (ISSN:1041-1135)
15. G. Bolognini, S. Sugliani, F. Di Pasquale, “Impact of double Rayleigh scattering noise in time-division multiplexed Raman pumping schemes”, Technical Digest, Optical Fiber Communication Conference OFC 2004, Los Angeles, CA, U.S.A., 22-27 Feb 2004, paper WB5. (ISBN: 1-55752-767-9)
14. G. Sacchi, S. Sugliani, S. Faralli, G. Bolognini, F. Di Pasquale, “Penalties induced by resonant noise enhancement and their mitigation in counter-pumped distributed Raman amplifiers”, Technical Digest, Optical Amplifiers and their Applications Conference OAA 2004, Jun 2004, San Francisco, CA, USA, paper OWA1. (ISBN: 1-55752-774-1)
13. G. Bolognini, S. Sugliani, F. Di Pasquale, “Benefits of co-propagating Raman pumping for C-band WDM transmission in dispersion shifted fibers”, Proceedings of Photonics 2004, India, Dec 2004, paper FBR1.1.
12. S. Faralli, S. Sugliani, G. Sacchi, G. Bolognini, F. Di Pasquale, “Double Rayleigh scattering noise in higher-order distributed Raman pumping schemes”, Paper TuB2.6, Proceedings of Suboptic Conference 2004, 29 Mar – 1 Apr 2004, Monaco, Monaco.
11. G. Bolognini, “Design of Photonic Crystal Fibers for optical parametric amplification”, POWAG 2004 Summer School, July 2004, Bath, UK.
10. G. Bolognini, S. Faralli, F. Di Pasquale, “Resonant gain enhancement induced by pump RIN transfer in distributed Raman amplifiers”, Technical Digest, Optical Fiber Communication Conference OFC 2003, 22-27 Mar 2003, Atlanta, GA, U.S.A., paper ThB6. (ISBN: 1-55752-731-8)
9. G. Sacchi, S. Sugliani, G. Bolognini, S. Faralli, F. Di Pasquale, “Experimental analysis of gain clamping techniques for lumped Raman amplifiers”, Proceedings of the European Conference on Optical Communication ECOC 2003, 21-25 Sep 2003, Rimini, Italy, paper Tu3.2.4.
8. S. Sugliani, G. Sacchi, G. Bolognini, S. Faralli, F. Di Pasquale ,” Suppression of penalties induced by parametric non-linear interaction in counter-pumped distributed Raman amplifiers”, Proceedings of the European Conference on Optical Communication ECOC 2003, 21-25 Sep 2003, Rimini, Italy, paper Tu3.2.6.
7. G. Bolognini, S. Faralli, S. Sugliani, G. Sacchi, F. Di Pasquale, “Theoretical study of dynamics in gain clamped Raman amplifier cascades”, Proceedings of Conference of the Laser and Electro-Optics Society LEOS 2003, 20-26 Oct 2003, Tucson, Arizona, U.S.A., paper TU I2. (ISBN: 0-7803-7888-1)
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