Updated: June 2014
`
`VâÜÜ|vâÄâÅ i|àtx Éy
`Dan M. Marom
`
`Dan Mark Marom
`July 14, 1967 in Detroit, Michigan (U.S.A.)
`Applied Physics Department
`School of Computer Science and Engineering
`Edmund Safra Campus
`Hebrew University
`Jerusalem, Israel
`+972 (54) 627-6614
`+972 (2) 658-4851
`+972 (2) 658-4844
`danmarom@mail.huji.ac.il
`
`Mechanical Engineering (1985-1989)
`Tel Aviv University
`Magna Cum Laude (GPA: 88.58/100)
`Electrical Engineering (1991-1995)
`Tel Aviv University
`Magna Cum Laude (GPA: 94.24/100)
`Prof. David Mendlovic
`Dynamic optical interconnections with multistage
`architectures
`Electrical Engineering (1995-2000)
`University of California, San Diego
`(GPA: 4.0/4.0)
`Prof. Yeshaiahu Fainman
`Femtosecond-rate optical signal processing
`with applications in ultrafast communications
`
` Personal Detail
`Full name:
`Date and place of birth:
`Address:
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`Cell:
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`Fax:
`Email:
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` Education
`B.Sc.:
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`M.Sc.:
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`Thesis advisor:
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`Thesis title:
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`Ph.D.:
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`Petitioner Ciena Corp. et al.
`Exhibit 1029-1
`
`

`

` Employment history
`2013-present
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`2005-2013
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`2000-2005
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`Associate Professor
`Hebrew University
`Senior Lecturer
`Hebrew University
`Member of the Technical Staff
`Advanced Photonics Research Department
`Bell Laboratories, Lucent Technologies
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` Professional Activities
`General Chair of Optical MEMS 2015 conference, to take place in Jerusalem, August
`2015.
`Technical co-Chair of Photonics in Switching 2014 (Optical Systems subcommittee).
`Program committee member for Optoelectronics and Communications Conference
`(OECC) 2014.
`Technical committee member of iNNOVEX, 2014.
`IEEE Young Investigator Award Committee Member, 2013-2014.
`Senior Editor of IEEE Photonics Technology Letters, 2013-present.
`Associate Editor of IEEE Photonics Technology Letters, 2008-2013.
`Co-Chair of IEEE Optical MEMS 2004 conference, Japan, August 2004.
`Program committee member for Optical Fiber Communications (OFC), 2006-08.
`Program committee member for Conference on Lasers and Electro-Optics (CLEO), 2007-
`2009.
`Program committee member for the Annual Meeting of the Laser and Electro-Optics
`Society (LEOS), 2008-2010.
`Program committee member for Frontiers in Optics (FiO, formerly the Annual Meeting of
`the Optical Society of America), 2008-2013.
`Program committee member for Optical MEMS, 2004-2006, 2013-present
`Committee member for ISF awards in optics 2009, 2013.
`Reviewer for OSA journals (Journal of the Optical Society of America, Optics Letters,
`Optics Express, Applied Optics), IEEE journals (Journal of Lightwave Technology,
`Photonics Technology Letters), and SPIE (Optical Engineering).
`Member of Optical Society of America (OSA).
`Senior Member of Institute of Electrical and Electronics Engineers (IEEE-LEOS).
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`
`
`Petitioner Ciena Corp. et al.
`Exhibit 1029-2
`
`

`

` University Activities
`Faculty Candidate Screening Committee, School of Engineering, 2014-present.
`Research Student Authority member, Applied Physics representative, 2013-present.
`Graduate student advisor for Applied Physics Department, 2007-2013.
`Curriculum committee for NanoScience program, 2011-present.
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`
` Awards, Citations, Honors, Fellowships
`2014: Photonics Society Distinguished Lecturer Award
`2008: Senior Member, IEEE Photonics Society
`2006: Peter Brojde Excellence in Engineering Award
`2006: Golda Meir Fellowship
`1999: Best Student Paper Award of LEOS Annual Meeting.
`1996-2000: Fannie and John Hertz Foundation fellow
`1995-1996: Powell Foundation fellowship
`
`
` Synopsis of Research Activity
`Optical Waveguide-based Devices
`Creating functional devices based on optical waveguides with tailored material properties.
`Waveguides fabricated from polymers enable the host material to be easily doped with
`nanocrystals. The composite route with colloidal nanocrystals is an effective alternative to
`epitaxial fabrication methodologies, enabling simpler fabrication, greater diversity of
`materials, and freedom from lattice-matching considerations. Semiconductor nanocrystals,
`in particular, can be used for their very fast dynamics associated with electronic
`nonlinearities. The current research activity is investigating the doping of polymer
`waveguides with semiconductor nanocrystals for “fast” applications in the telecom space
`(optical modulators, amplifiers, limiters, lasing properties, etc.).
`Optical Switching via MEMS and LCoS spatial light modulators
`Inventor, lead researcher, and developer of the first Wavelength-Selective 1×K Switch, a
`device that can switch individual optical channels from a DWDM input port to multiple
`(K) output ports with low-loss, low polarization dependencies, ultra wide and flat
`bandwidth response, and channel equalization capability. The switch’s desirable attributes
`are fundamental for the creation of all-optical networks, and today constitute a market
`segment of many $100M per annum. The MEMS technology has also been used for
`tunable channelized dispersion compensation and approximate inverse filtering of
`distorted data signals in 2-R optical signal regeneration. Many of these operations are now
`performed with LCoS technology in the lab, demonstrating various photonic spectral
`processors. Using two-dimensional dispersion schemes, demonstrated filtering with 3
`GHz resolution across the entire C-band, representing a record space-bandwidth product.
`
`Petitioner Ciena Corp. et al.
`Exhibit 1029-3
`
`

`

`Demonstrated optimized MEMS spectral amplitude and phase modulator, based on
`diffractive optics principles and simplified actuation by mechanically linking mirror
`elements. WSS functionality extension to support networking functionality over Space-
`Division Multiplexing, whether in the form of multi-core or few-mode fibers platforms.
`Ultrafast optics and Communications
`Specialization in instantaneous spatial-temporal signal processing using optical
`nonlinearities. Performed first real-time space-to-time conversion experiments using
`cascaded three wave mixing processes in a spatial-temporal processor. Real-time
`correlation experiments between spatial domain signals and temporal domain signals.
`Real-time four-wave mixing of spectrally decomposed waves for phase conjugation and
`time reversal of complex amplitude ultrafast waveforms. Achieved enhanced temporal
`resolution (or super-resolution) by operating a real-time time-to-space converter in the
`nonlinear conversion regime. Working towards extending performance of processors via
`planar lightwave integration. Demonstrated and analyzed a data communication format
`based on ultrafast pulse packets in a time division multiplexing scheme using real-time
`spatial-temporal processors for multiplexing from and demultiplexing to slower
`electronics. Investigated a code division multiple access/pulse position modulation format
`(CDMA/PPM), with ultrafast pulses. CDMA facilitates network management by
`interference suppression, with efficient bandwidth utilization by PPM.
`Nonlinear Optics
`Optical solitons, and soliton perturbations and collisions. Investigated soliton-Airy
`collisions and soliton shedding from Airy pulses, all in the temporal domain (one-
`dimensional media, i.e. single mode fiber or plane waves).
`Optical Switching via Polarization modulation
`Built a transparent bypass-exchange optical switch (2×2) based on birefringent crystals
`and a liquid crystal polarization modulator. Switch was scaled up to perform reduced-state
`44 switching, enabling optical implementation of a three-dimensional multistage
`interconnection network. Team leader, design, construction, and testing of two
`generations of a folded 88 optical multistage interconnection network with transparent
`switches based on birefringent computer generated holograms and polarization control.
`Routing algorithm and switching performed by control computer.
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` 
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` Research Grants: Raised approximately $2.5M in 8 years.
`Rectangular core mode division multiplexing platform, from HUJI Applied Science Fund,
`2014. Awarded 25,000 USD.
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`INSPACE: Spatial‐Spectral Flexible Optical Networking, FP7-ICT-Call 11. 2014-2017.
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`300,000 Euro.
`Spatial Mode Multiplexing, from HUJI Applied Science Fund, 2012. Awarded 40,000
`USD.
`Nonlinear Doped-Polymer Optical Waveguide Devices for Photonic Information
`Processing from Israel Science Foundation, 2012-2016. Awarded 1,100,000 ILS.
`
`Petitioner Ciena Corp. et al.
`Exhibit 1029-4
`
`

`

`FOX-C: Flexible Optical Cross-connect Nodes enabling next generation flexible optical
`networking, FP7-ICT-Call 8. 2013-2016. 320,000 Euro.
`LED test box for fruit preservation extension, 2012-13. Awarded 50,000 GBP by Wolfson
`Foundation.
`Industry sponsored development project, details under NDA, 2012-2014. Awarded
`105,000 USD.
`Photonically Assisted Analog-to-Digital Conversion, Ministry of Industry and Trade
`under Kamin program, 2011-2013. Awarded 800,000 NIS for two years.
`OTONES: Optical Access Networking using OFDM Tones, EC under ERANetPlus
`program, 2011-2014. Awarded 105,000 Euro (as subcontractor to Finisar).
`TeraSanta: Creating an efficient terabit/secOFDM channel, Ministry of Industry and Trade
`under Magnet program, 2010-2014. Awarded 1,220,000 NIS for first four years (now
`being extended to fifth and last year).
`Photonically-assisted analog-to-digital conversion, from HUJI Applied Science Fund,
`2010. Awarded 40,000 USD.
`Nonlinear optical waveguide devices composed of semiconductor nanocrystals in a
`polymer host. From HUJI Science Faculty Fund, 2010. Awarded 17,000 USD.
`Alignment and Fixation of Semiconductor Nanocrystals Embedded in Polymeric
`Matrices; The Critical Step on the Path towards Novel Optical Devices, from HUJI
`Applied Science Fund, 2008. Awarded 25,000 USD.
`Adaptive Photonic Spectral Processor (PSP) for Mitigating Transmission Impairments,
`from Israel Science Foundation, 2007-2009. Awarded 155,000 USD.
`Adaptive optics at 1.55 microns, from (Israel Defense Development Agency (Mafaat),
`2008-2010. Awarded 450,000 NIS.
`Undergraduate Optoelectronics Laboratory, from Intel, 2007. Awarded 40,000 USD.
`
` 
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` Educator Experiences
`Supervised M.Sc. students:
`2006-2009: Yoram Palti: Complex Optical (Amplitude and Phase) Device
`Characterization Tool
`2007-2009: Yaron Glazer: Novel Polymeric Waveguides Optimized For Nanocrystals
`Hosting
`2007-2009: David Seinfeld (advanced to direct PhD)
`2008-2010: Asael Adler: High Index Contrast Polymer Optical Waveguides
`2008-2010: Jonathan Dunayevsky: MEMS Spatial Light Modulator for Spectral
`Phase and Amplitude Modulation
`2008-2011: Amitai Rudnik: Airy-Solitons interactions
`
`Petitioner Ciena Corp. et al.
`Exhibit 1029-5
`
`

`

`2009-2012: Yiska Fatal: Soliton shedding from Airy pulses in Kerr media
`2009-2013: Moran Bin-Nun: Polymerical Waveguide Platform Fabrication
`Optimization
`2010-2013: Yedidya Lior: Nonlinear Optical Waveguides from Dilute Composites
`Consisting of Polymer with Partially Aligned Nanorods
`2011-2014: Ori Golani (Working on photonic ADC)
`2011-present: Miri Blau (advanced to direct PhD)
`2011-present: Leonid Pascar (Working on wavelength-selective cross-connect)
`2012-present: Noam Goldstein (Working on AWG error measurement and trimming)
`2012-present: Roy Rudnick (Working on spectral processing devices)
`2013-present: Avishag Amit (Working on high resolution WSS)
`2013-present: Israel Weiss (Working on 3D dielectric structures on fiber tip)
`Supervised Ph.D. students:
`2009-2013: David Sinefeld: Adaptive optics for fast optical communication: Spatial
`solutions for spectral issues.
`2008-present: Dror Shayovitz (working on ultrafast time to space conversion)
`2013-present: Yedidya Lior (working on polymer/nanocrystal nonlinearities)
`2013-present: Moran Bin-Nun (working on polymer/nanocrystal device fabrication)
`2013-present: Miri Blau (working on space division multiplexing)
`
`
`Class instruction:
`Year
`Course
`Course name
`number
`83510
`
`GW optics
`
`05-06
`
`Type
`
`Cred Sem.
`
`Lec + sec 3
`
`05-06
`
`83839
`
`Opt. Comm.
`
`Lecture
`
`2
`
`06-07
`
`83510
`
`GW optics
`
`Lec + sec 3
`
`06-07
`06-07
`
`83410
`83839
`
`OptoElec lab
`Opt. Comm.
`
`Lab
`Lecture
`
`3
`2
`
`07-08
`
`83510
`
`GW optics
`
`Lec + sec 4
`
`07-08
`07-08
`
`83410
`83839
`
`OptoElec lab
`Opt. Comm.
`
`Lab
`Lecture
`
`3
`2
`
`Extra
`Instrs.
`-
`
`-
`
`-
`
`-
`-
`
`-
`
`-
`-
`
`Audience
`
`Mandatory/
`Elective
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`Mandatory
`B.Sc.
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`Mandatory
`B.Sc.
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`
`A
`
`B
`
`A
`
`A
`B
`
`A
`
`A
`B
`
`Petitioner Ciena Corp. et al.
`Exhibit 1029-6
`
`

`

`08-09
`08-09
`08-09
`
`83876
`83410
`83510
`
`NL optics
`OptoElec lab
`GW optics
`
`3
`Lec
`3
`Lab
`Lec + sec 4
`
`09-10
`
`83510
`
`GW optics
`
`Lec + sec 4
`
`09-10
`09-10
`
`83410
`83839
`
`OptoElec lab
`Opt. Comm.
`
`Lab
`Lecture
`
`3
`2
`
`10-11
`
`83510
`
`GW optics
`
`Lec + sec 4
`
`10-11
`10-11
`11-12
`
`11-12
`11-12
`
`83410
`83876
`83510
`
`83410
`83839
`
`OptoElec lab
`NL optics
`GW optics
`
`3
`Lab
`3
`Lec
`Lec + sec 4
`
`OptoElec lab
`Opt. Comm.
`
`Lab
`Lecture
`
`3
`2
`
`12-13
`
`83510
`
`GW optics
`
`Lec + sec 4
`
`12-13
`12-13
`13-14
`
`13-14
`13-14
`
`83410
`83876
`83510
`
`83410
`83839
`
`OptoElec lab
`NL optics
`GW optics
`
`3
`Lab
`3
`Lec
`Lec + sec 4
`
`OptoElec lab
`Opt. Comm.
`
`Lab
`Lecture
`
`3
`2
`
` Legend: GW optics – Guided wave optics
`
`
`NL optics – NonLinear optics
`
`
`
`
`A
`B
`
`A
`
`A
`A
`A
`
`A
`B
`
`A
`
`A
`A
`A
`
`A
`B
`
`-
`-
`-
`
`-
`
`-
`-
`
`-
`
`-
`-
`-
`
`-
`-
`
`-
`
`-
`-
`-
`
`-
`-
`
`A
`A
`B
`
`A
`
`Elective
`M.Sc.
`Mandatory
`B.Sc.
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`Mandatory
`B.Sc.
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`Mandatory
`B.Sc.
`Elective
`M.Sc.
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`Mandatory
`B.Sc.
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`Mandatory
`B.Sc.
`Elective
`M.Sc.
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`Mandatory
`B.Sc.
`B.Sc.+M.Sc. Man (BSc)
`Elec (MSc)
`OptoElec lab – OptoElectronics lab
`Opt. Comm. – Optical Communications
`
`Petitioner Ciena Corp. et al.
`Exhibit 1029-7
`
`

`

`Updated: May 2014
`Publication List of Dan M. Marom
` Scientific Publications
`1. D. M. Marom and D. Mendlovic, “Compact, all-optical, bypass-exchange switch,”
`Appl. Opt., Vol. 35, No. 2, pp. 248-53, 1995.
`2. D. M. Marom and D. Mendlovic, “All-Optical Reduced State 4*4 Switch,” under
`'Recent Research' in Opt. and Photon. News, Vol. 7, No. 3, p.43, March 1996.
`3. D. M. Marom and D. Mendlovic, “Comment on a new routing algorithm for a class of
`rearrangeable networks,” IEEE Trans. Comput., Vol. 46, No. 6, p. 734, June 1997.
`4. D. M. Marom, P.-C. Sun, and Y. Fainman, “Analysis of spatial-temporal converters for
`all-optical communication links,” Appl. Opt., Vol. 37, No. 14, pp. 2858-68, 1998.
`5. D. M. Marom, N. Konforti, and D. Mendlovic, “All-optical stage of an Omega
`network,” Appl. Opt., Vol. 37, No. 29, pp. 6946-50, 1998.
`6. D. M. Marom, P. E. Shames, F. Xu, and Y. Fainman, “Folded free-space polarization-
`controlled multistage interconnection network,” Appl. Opt., Vol. 37, No. 29, pp. 6884-
`91, 1998.
`7. D. M. Marom, D. Panasenko, P.-C. Sun, and Y. Fainman, “Spatial-temporal wave
`mixing for space-to-time conversion,” Opt. Lett., Vol. 24, No. 8, pp. 563-565, 1999.
`8. D. M. Marom, D. Panasenko, R. Rokitski, P.-C. Sun, and Y. Fainman, “Instantaneous
`processing of ultrafast waveforms by wave mixing spectrally decomposed waves,” Opt.
`and Photon. News, Vol. 10 (Special Issue of Optics in 1999), p. 41, 1999.
`9. D. M. Marom, D. Panasenko, R. Rokitski, P.-C. Sun, and Y. Fainman, “Time reversal
`of ultrafast waveforms by wave mixing spectrally decomposed waves,” Opt. Lett., Vol.
`25, No. 2, pp. 132-134, 2000.
`10. D. M. Marom, D. Panasenko, R. Rokitski, P.-C. Sun, Y. Fainman, “Reply to Comment
`on ‘Time reversal of ultrafast waveforms by wave mixing spectrally decomposed
`waves’,” Opt. Lett., Vol. 25, No. 16, p. 1209, 2000.
`11. D. M. Marom, D. Panasenko, P.-C. Sun, and Y. Fainman, “Femtosecond-rate space-to-
`time conversion,” J. Opt. Soc. Am. B, Vol. 17, No. 10, pp. 1759-1773, 2000.
`12. D. M. Marom, D. Panasenko, P.-C. Sun, and Y. Fainman, “Linear and nonlinear
`operation of a time-to-space processor,” J. Opt. Soc. Am. A, Vol. 18, No. 2, pp. 448-458,
`2001.
`13. D. M. Marom, D.Panasenko, P.-C. Sun, Y. T. Mazurenko, and Y. Fainman, “Real-time
`spatial-temporal signal processing with optical nonlinearities,” IEEE J. of Select. Topics
`in Quant. Electron., Vol. 7, No. 4, pp. 683-693, 2001.
`
`Petitioner Ciena Corp. et al.
`Exhibit 1029-8
`
`

`

`14. K. S. Kim, D. M. Marom, L. B. Milstein, and Y. Fainman, “Hybrid pulse position
`modulation/ultrashort light pulse code-division multiple-access systems-part I:
`Fundamental analysis,” IEEE Trans. on Commun., Vol. 50, No. 12, pp. 2018-2031,
`2002.
`15. K. S. Kim, D. M. Marom, L. B. Milstein, and Y. Fainman, “Hybrid pulse position
`modulation/ultrashort light pulse code-division multiple-access systems-part II: time-
`space processor and modified schemes,” IEEE Trans. on Commun., Vol. 51, No. 7,
`pp. 1135-1148, 2003.
`16. D. S. Greywall, C.-S. Pai, S.-H. Oh, C.-P. Chang, D. M. Marom, P. A. Busch, R. A.
`Cirelli, J. A. Taylor, F. P. Klemens, T. W. Sorch, J. E. Bower, W. Y.-C. Lai, and H. T.
`Soh, “Monolithic fringe-field-activated crystalline silicon tilting-mirror devices,” IEEE
`J. Microelectromech. Syst., Vol. 12, No. 5, pp. 702-707, 2003.
`17. S.-H. Oh and D. M. Marom, “Attenuation mechanism affect on filter shape in
`channelized dynamic spectral equalizers”, Appl. Opt., Vol. 43, No. 1, pp. 127-131, 2004.
`18. J. Leuthold, D. M. Marom, S. Cabot, J. J. Jaques, R. Ryf, and C. R. Giles, “All-optical
`wavelength conversion using a pulse reformatting optical filter,” IEEE J. Lightwave
`Technol., Vol. 22, No. 1, pp. 186-192, 2004.
`19. D. T. Neilson, R. Ryf, F. Pardo, V. A. Aksyuk, M.-E. Simon, D. O. Lopez, D. M.
`Marom, and S. Chandrasekhar, “MEMS-based channelized dispersion compensator
`with flat passbands,” IEEE J. Lightwave Technol., Vol. 22, No. 1, pp. 101-105, 2004.
`20. D. M. Marom, D. T. Neilson, D. S. Greywall, C. S. Pai, Nagesh R. Basavanhally,
`Vladimir A. Aksyuk, Daniel O. López, Flavio Pardo, M. E. Simon, Y. Low, P.
`Kolodner, and C. A. Bolle, “Wavelength-Selective 1×K Switches using Free-Space
`Optics and MEMS Micromirrors: Theory, Design, and Implementation,” IEEE J.
`Lightwave Technol., Vol. 23, No. 4, pp. 1620-30, 2005.
`Appointment at HUJI.
`21. D. M. Marom, C. R. Doerr, M. A. Cappuzzo, E. Y. Chen, A. Wong-Foy, L. T. Gomez,
`and S. Chandrasekhar, “Compact colorless tunable dispersion compensator with 1000
`ps/nm tuning range for 40-Gb/s data rates,” IEEE J. Lightwave Technol., Vol. 24, No. 1,
`pp. 237-241, 2006.
`22. D. T. Neilson, C. R. Doerr, D. M. Marom, R. Ryf, and M. Earnshaw, “Wavelength-
`Selective Switching for Optical Bandwidth Management,” Bell Labs Technical Journal
`Vol. 11, pp. 105-128, 2006. (Invited paper).
`23. D. M. Marom, “Enabling Devices using MicroElectroMechanical System (MEMS)
`Technology for Optical Networking,” Adv. Sci. and Technol. 55, 145-149, 2008.
`24. D. Sinefeld and D. M. Marom, “Hybrid Guided-Wave/Free-Space Optics Photonic
`Spectral Processor Based on LCoS Phase Only Modulator,” Photon. Technol. Lett. 22,
`510-512, 2010.
`25. D. Sinefeld and D. M. Marom, “Insertion Loss and Crosstalk Analysis of a Fiber
`Switch based on a Pixelized Phase Modulator,” IEEE J. Lightwave Technol. 29, 69-77,
`2011.
`
`Petitioner Ciena Corp. et al.
`Exhibit 1029-9
`
`

`

`26. D. Sinefeld, S. Ben-Ezra, C. R. Doerr, and D. M. Marom, “Colorless compact tunable
`optical dispersion compensator based solely on linear translation,” Opt. Lett. 36, 1410-2,
`2011.
`27. D. Shayovitz and D. M. Marom, “High resolution time-to-space conversion at 1.55 μm
`by collinearly phase-matched SFG,” Opt. Lett. 36, 1957-9, 2011.
`28. D. Sinefeld, C. R. Doerr, and D. M. Marom, “Photonic Spectral Processor Employing
`Two-Dimensional WDM Channel Separation and a Phase LCoS Modulator” Opt.
`Express 19, 14532-41, 2011.
`29. Y. Fattal, A. Rudnick, and D. M. Marom, “Soliton shedding from Airy pulses in Kerr
`media,” Opt. Express 19, 17298-307, 2011.
`30. A. Rudnick and D. M. Marom, “Airy-Soliton Interactions in Kerr Media,” Opt.
`Express. 19, 25570-25582, 2011.
`31. D. Sinefeld and D. M. Marom, “Tunable Fiber Ring Laser with an Intra-Cavity High
`Resolution Filter Employing Two-Dimensional Dispersion and LCoS Modulator,” Opt.
`Lett. 37, 1-3, 2012.
`32. D. Sinefeld, Y. Fattal, and D. M. Marom, “Generation of WDM adaptive-rate pulse
`bursts by cascading narrow/wideband tunable optical dispersion compensators,” Opt.
`Lett. 37, 4290-92, 2012.
`33. M. Blau and D. M. Marom, “Optimization of Spatial Aperture-Sampled Mode
`Multiplexer for a Three-Mode Fiber,” Photon. Technol. Lett. 24, 2101-2104, 2012.
`34. D. Shayovitz, H. Herrmann, W. Sohler, R. Ricken, C. Silberhorn, and D. M. Marom,
`“High resolution time-to-space conversion of sub-picosecond pulses at 1.55µm by non-
`degenerate SFG in PPLN crystal,” Opt. Express. 20, 27388-27395, 2012.
`35. Y. Lior and Dan M. Marom, “Effective permittivity and third-order nonlinear
`susceptibility for a dilute composite consisting of partially aligned nanorods,” J. Opt.
`Soc. Am. B, Vol. 30, No. 7, pp. 1864-1871, 2013.
`36. Y. Dunayevsky and D. M. Marom, “MEMS spatial light modulator for phase and
`amplitude modulation of spectrally dispersed light,” IEEE J. Microelectromech. Syst.
`22, pp. 1213-1221, 2013.
`37. D. Sinefeld, S. Ben-Ezra, and D. M. Marom, “Nyquist-WDM filter shaping with a
`high-resolution colorless photonic spectral processor,” Opt. Lett. 38, pp. 3268–3271,
`2013.
`38. D. Shayovitz, H. Herrmann, W. Sohler, R. Ricken, C. Silberhorn, and D. M. Marom,
`“Time-to-space conversion of ultrafast waveforms at 1.55 μm in a planar periodically
`poled lithium niobate waveguide,” Opt. Lett. 38, pp. 4708–4711, 2013.
`39. L. E. Nelson, M. D. Feuer, K. Abedin, X. Zhou, T. F. Taunay, J. M. Fini, B. Zhu, R.
`Isaac, R. Harel, G. Cohen, and D. M. Marom, “Spatial Superchannel Routing in a Two-
`Span ROADM System for Space Division Multiplexing,” IEEE J. Lightwave Technol.
`32, 783-789, 2014.
`
`Petitioner Ciena Corp. et al.
`Exhibit 1029-10
`
`

`

`40. D. Sinefeld, D. Shayovitz, O. Golani, and D. M. Marom, “Tunable WDM sampling
`pulse streams using a spatial phase modulator in a biased pulse shaper,” Opt. Lett. 39,
`pp. 642-645, 2014.
`41. A. Agmon, M. Nazarathy, D. M. Marom, S. Ben-Ezra, A. Tolmachev, R. Killey, P.
`Bayvel, L. Meder, M. Hübner, W. Meredith, G. Vickers, P. C. Schindler, R.
`Schmogrow, D. Hillerkuss, W. Freude, C. Koos, and J. Leuthold, “OFDM/WDM PON
`with Laserless, Colorless 1  Gb/s ONUs Based on Si-PIC and Slow IC,” IEEE J. Opt.
`Commun. Netw. 6, pp. 225-237, 2014.
`42. O. Golani, L. Mauri, F. Pasinato, C. Cattaneo, G. Consonnni, S. Balsamo, and D. M.
`Marom, “A photonic analog-to-digital converter using phase modulation and self-
`coherent detection with spatial oversampling,” Opt. Express. 22, 12273-12282, 2014.
`
` Book Chapters
`3. D. M. Marom, “Microsystems in Optical Communication Networks,” in Comprehensive
`Microsystems, Eds. Yogesh B. Gianchandani, Osamu Tabata, and Hans Zappe, First
`Edition, Elsevier (Amsterdam), Chapter 3.08, pp. 219-265, 2008.
`Appointment at HUJI.
`2. Y. Fainman and D. M. Marom, “Instantaneous imaging and processing of ultrafast
`waveforms,” in Encyclopedia of Modern Optics, Eds. B. Guenther, A. Miller, L. Bayvel,
`and J. Midwinter, 2004.
`1. Y. Fainman, P.-C. Sun, Y. Mazurenko, D. M. Marom, and K. Oba, “Nonlinear spatio-
`temporal processing with femtosecond laser pulses,” NATO Science Series- 3/75 on
`“Unconventional Optical Elements for Information Storage, Processing, and
`Communication”, ed. E. Marom, N. A. Vianos, A. A. Friesem, and J. W. Goodman,
`Kluwer academic publishers, Netherlands, pp. 163-171, 2000.
`
` Lectures and Presentations at Conferences
`1. D. M. Marom and D. Mendlovic, “All-Optical Reduced State 4*4 Switch,” 1995 OSA
`Annual Meeting, Portland, OR, Sept. 95.
`2. D. M. Marom and D. Mendlovic, “All-Optical Reduced State 4*4 Switch,” 1996 ICO
`Annual Meeting, Taejon, South Korea, August 96.
`3. D. M. Marom, P.-C. Sun and Y. Fainman, “Temporal phase conjugation with space-
`time processors,” Technical digest of OSA topical meeting on holography, pp. 62-65,
`Boston, MA, April 1996.
`4. D. M. Marom, P. Shames, F. Xu, R. R. Rao, and Y. Fainman, “Compact free-space
`multistage interconnection network demonstration,” Technical digest of OSA topical
`meeting of Optics for Computing, p. 192-194, Lake Tahoe, UT, March 1997.
`5. D. M. Marom, P. Shames, F. Xu, R. R. Rao, and Y. Fainman, “Compact free-space
`multistage interconnection network demonstration,” IEEE 8th Annual Workshop on
`Interconnections within High-Speed Digital Systems, Santa Fe, NM, May 1997.
`
`Petitioner Ciena Corp. et al.
`Exhibit 1029-11
`
`

`

`6. D. M. Marom, P.-C. Sun, and Y. Fainman, “Communication with ultrashort pulses and
`parallel-to-serial and serial-to-parallel converters,” IEEE Lasers and Electro-Optics
`Society 1997 Annual Meeting, pp. 32-33, San Francisco, CA, Nov. 1997.
`7. Y. Fainman, P.-C. Sun, Y. Mazurenko, K. Oba, D. Marom, “Storage formats for
`ultrahigh speed communication and processing,” AFOSR Workshop on Applications of
`Spectral Hole Burning, Montana State University, Bozman, MO, March 1998.
`8. Y. Fainman, F. Xu, R. Tyan, D. Marom, P. Shames, P.-C. Sun, J. Ford, A. Scherer, and
`A. Krishnamoorthy, “Polarization selective diffractive optical elements and
`applications,” 1998 OSA Topical Meeting on Diffractive Optics, Technical Digest, pp.
`50-52, Kona, Hawaii, June 1998. Invited Speaker.
`9. Y. Fainman, F. Xu, R. Tyan, P.-C. Sun, J. Ford, A. Scherer, A. Krishnamoorthy, D. M.
`Marom, P. Shames, “Multifunctional Diffractive Optics for Optical Interconnects,”
`1998 International Conference on Telecommunications, Vol. III, pp. 489-493, Greece,
`June 1998.
`10. P.-C. Sun, K. Oba, D. Marom, Y. Mazurenko, and Y. Fainman, "Spatio-temporal
`Conversion, Storage, and Processing using Femtosecond Optical Pulses," SPIE 43rd
`Annual Meeting, Proc. SPIE 3470, San Diego, CA, July 1998. Invited Speaker.
`11. Y. Fainman, F. Xu, R. Tyan, P.-C. Sun, J. Ford, A. Scherer, A. Krishnamoorthy, D. M.
`Marom, P. Shames, “Multifunctional Diffractive Optics for Optical interconnects,”
`Topical Meeting of the International Commission for Optics: “Optics for Information
`Infrastructure,” Nankai University, Tianjin, China, August 1998. Invited Speaker.
`12. D. M. Marom, P.-C. Sun, and Y. Fainman, "Analysis of time-to-space converter," 1998
`OSA Annual Meeting, Baltimore, MD, Oct. 98.
`13. D. M. Marom, L. B. Milstein, and Y. Fainman, "Hybrid optical code division multiple
`access/pulse position modulation technique with self-referencing," 1998 OSA Annual
`Meeting, Baltimore, MD, Oct. 98.
`14. D. M. Marom, D. Panasenko, P.-C. Sun, and Y. Fainman, “Real-time spatial-temporal
`signal processing by wave-mixing with cascaded second-order nonlinearities,” OSA
`Topical Meeting of Optics for Computing, Technical Digest, pp. 161-163, Snowmass
`Village, CO, April 1999.
`15. D. M. Marom, D. Panasenko, P.-C. Sun, and Y. Fainman, “Spatial-temporal pulse
`waveform synthesis by wave-mixing with cascaded second-order nonlinearities,”
`Conference on Lasers and Electro-optics (CLEO ‘99), p. 47, Baltimore, MD, May 1999.
`Invited Speaker.
`16. D. M. Marom, D. Panasenko, R. Rokitski, P.-C. Sun, and Y. Fainman, “Triple
`correlation pulse characterization in a spatial-temporal processor,” 1999 OSA Annual
`Meeting, Santa Clara, CA, Sept. 1999.
`17. Y. Fainman, P.-C. Sun, Y. Mazurenko, D. M. Marom, and K. Oba, “Nonlinear spatio-
`temporal processing with femtosecond laser pulses,” NATO Workshop on “
`Unconventional Optical Elements for Information Storage, Processing, and
`Communication”, Kiryat Anavim, Israel, October 1999. Invited Speaker.
`
`Petitioner Ciena Corp. et al.
`Exhibit 1029-12
`
`

`

`18. Y. Fainman, D. M. Marom, K. Oba, D. Panasenko, Y. Mazurenko, and P.-C. Sun,
`“Nonlinear space-time information processing,” Euro-American Workshop on
`Optoelectronic Information Processing, Colmar, France, May 1999; also appeared in the
`Critical review of SPIE, Optoelectronic Information Processing, B. Javidy and P.
`Refregier, ed., pp. 41-60, 1999. Invited Speaker.
`19. Y. Fainman, D. M. Marom, K. Oba, D. Panasenko, Y. T. Mazurenko, and P.-C. Sun,
`“Nonlinear spatio-temporal processing,” IEEE Lasers and Electro-Optics Society 1999
`Annual Meeting, p. 562-3, San Francisco, CA, Nov. 1999. Invited Speaker.
`20. D. M. Marom, D. Panasenko, R. Rokitski, P.-C. Sun, and Y. Fainman, “Instantaneous
`time reversal of complex amplitude ultrafast waveforms,” IEEE Lasers and Electro-
`Optics Society 1999 Annual Meeting, pp. 890-1, San Francisco, CA, Nov. 1999.
`1999 Best Student Paper Award winner.
`21. D. M. Marom, K. S. Kim, L. B. Milstein, Y. Fainman, “Hybrid pulse position
`Modulation/ultrashort light pulse code division multiple access for data networking,”
`Optics in Computing 2000, Proc. SPIE 4089, pp. 479-484, Quebec City, Canada, June
`2000.
`22. Y. Fainman, D. Marom, D. Panasenko, R. Rokitski, K. Oba, Y. Mazurenko, and P.-C.
`Sun, “Optical conversion between space and time parallelism,” Optics in Computing
`2000, Proc. SPIE 4089, p. 1028, Quebec City, Canada, June 2000. Invited Speaker.
`23. P.-C. Sun, D. M. Marom, D. Panasenko, R. Rokitski, P. C. Lin, Y. T. Mazurenko, and
`Y. Fainman, “Nonlinear space-time information processing,” SPIE’s 45-th Annual
`Meeting, Proc. SPIE 4113, pp.1-12, July 2000. Keynote Address
`24. L. B. Milstein, Y. Fainman, D. M. Marom, K. Kim, “Optical CDMA for Internet
`Operation at Terabit Rates,” 2000 Second Annual International Symposium on
`Advanced Radio Technologies (ISART 2000), Boulder, CO, September 2000. Invited
`Speaker.
`25. Y. Fainman, D. M. Marom, D. Panasenko, Y. Mazurenko, and P. C. Sun, “Superfast
`information processing with femtosecond laser pulses,” International Optical Congress
`“Optics - XXI Century”, St. Petersburg, October 2000. Invited Speaker.
`26. Y. Fainman, D. Panasenko, R. Rokitski, D. M. Marom, Y. Mazurenko, and P.-C. Sun,
`“Nonlinear space-time processing,” IEEE Lasers and Electro-Optics Society 2001
`Annual Meeting, p. 849, La Jolla, CA, Nov. 2001. Invited Speaker.
`27. D. M. Marom, D. T. Neilson, D. S. Greywall, N. R. Basavanhally, P. R. Kolodner, Y.
`L. Low, F. Pardo, C. A. Bolle, S. Chandrasekhar, L. Buhl, C. R. Giles, S.-H. Oh, C. S.
`Pai, K. Werder, H. T. Soh, G. R. Bogart, E. Ferry, F. P. Klemens, K. Teffeau,
`J. F. Miner, S. Rogers, J. E. Bower, R. C. Keller, and W. Mansfield, “Wavelength-
`selective 1×4 Switch for 128 WDM Channels at 50 GHz Spacing,” Optical Fiber
`Conference (OFC 2002), Anaheim, CA, March 2002. Post Deadline Paper FB-7.
`28. D. Panasenko, R. Rokitski, D. M. Marom, Y. Mazurenko, P.-C. Sun, N. Alic and
`Y. Fainman. “Nonlinear optical information processing with femtosecond pulses,” 2002
`SPIE AeroSense Meeting, Proc. SPIE 4737. Invited Speaker.
`
`Petitioner Ciena Corp. et al.
`Exhibit 1029-13
`
`

`

`29. Y. Fainman, D. Panasenko, R. Rokitski, D. M. Marom, K. Oba, Y. Mazurenko, and P.
`C. Sun, “Ultrafast nonlinear optical processing using femtosecond laser pulses,”
`IQEC/LAT 2002, Moscow, June 2002. Invited Speaker.
`30. Y. Fainman, D. Panasenko, R. Rokitski, D. M. Marom, Y. Mazurenko, and P. C. Sun,
`“Nonlinear Processing with Ultrashort Laser Pulses,” Photonics North Conference,
`Quebec, Canada, June 2002. Invited Speaker.
`31. D. M. Marom, “Wavelength selective 1×K switches for transparent optical networks,”
`Asia-Pacific Optical and Wireless Communications (APOC 2002), Shanghai, China,
`October 2002. Invited Speaker.
`32. D. M. Marom and S.-H. Oh, “Filter-shape dependence on attenuation mechanism in
`channelized dynamic spectral equalizers,” IEEE Lasers and Electro-Optics Society 2002
`Annual Meeting, pp. 416-417, Glasgow, Scotland, Nov. 2002.
`33. D. T. Neilson, R. Ryf, F. Pardo, V. A. Aksyuk, M.-E. Simon, D. O. Lopez, D. M.
`Marom, S. Chandrasekhar, “Channelized dispersion compensator with flat pass bands
`using an array of deformable MEMS mirrors,” Optical Fiber Conference (OFC 2003),
`Atlanta, GA, March 2003. Post Deadline Paper
`34. J. Leuthold, D. M. Marom, S. Cabot, R. Ryf, P. Bernasconi, F. Baumann, J. Jaques,
`“Matched optical filter all-optical wavelength converter with low input-power and high
`signal quality,” Optical Fiber Conference (OFC 2003), Atlanta, GA, March 2003. Post
`Deadline P