[1] Andriolli N, Buron J, Ruepp S, Cugini F, Valcarenghi L, Castoldi P. Label preference schemes in GMPLS controlled networks. IEEE Communications Letters, 2006, 10(12): 849-851

[2] Azodolmolky S, Klinkowski M, Marin E, Careglio D, Pareta J S, Tomkos I. A survey on physical layer impairments aware routing and wavelength assignment algorithms in optical networks. Computer Networks, 2009, 53(7): 926-944

[3] Gnauck A H, Winzer P J. Optical phase-shift-keyed transmission. IEEE/OSA Journal of Lightwave Technology, 2005, 23(1): 115-130

[4] Schubert C, Schmidt-Langhorst C, Schulze K, Marembert V,Weber H G. Time division add-drop multiplexing up to 320 Gbit/s. In: Proceedings of Conference on Optical Fiber Communication Conference. 2005, 4, OThN2

[5] Phillips D, Ellis A D, Thiele H J, Manning R J, Kelly A E. 40 Gbit/s all optical regeneration and demultiplexing using a semiconductor non-linear interferometer. IEE Electronics Letters, 1998, 34(24): 2340-2342

[6] Diez S, Ludwig R, Weber H G. Gain-transparent SOA-switch for high-bitrate OTDM add/drop multiplexing. IEEE Photonics Technology Letters, 1999, 11(1): 60-62

[7] Liu Y, Tangdiongga E, Li Z, Zhang S, de Waardt H, Khoe G D, Dorren H J S. Error-free all-optical wavelength conversion at 160 Gb/s using a semiconductor optical amplifier and an optical bandpass filter. IEEE/OSA Journal of Lightwave Technology, 2006, 24(1): 230-236

[8] Verdurmen E J M, Zhao Y, Tangdiongga E, Turkiewicz J P, Khoe G D, de Waardt H. Error-free all-optical add-drop multiplexing using HNLF in a NOLM at 160 Gbit/s. IEE Electronics Letters, 2005, 41(6): 340-350

[9] Mulvad H, Galili M, Oxenlowe L K, Clausen A T, Jeppesen P, Gruner-Nielsen L. 640 Gbit/s optical time-division add-drop multiplexing in a non-linear optical loop mirror. IEEE/LEOS Winter Topicals Meeting Series, 2009, 209-210

[10] Wadsworth W J. Nonlinear wavelength conversion and pulse manipulation in photonic crystal fibres. In: Proceedings of Eouropean Conference Optical Communication. 2010, Th.9.F.1

[11] Bogoni A,Wu X, Fazal I,Willner A. 160 Gb/s time-domain channel extraction/insertion and all-optical logic operations exploiting a single PPLN waveguide. IEEE/OSA Journal of Lightwave Technology, 2009, 27(19): 4221-4227

[12] Liu S, Kwang J L, Kakande J, Parmigiani F, Slavik R, Petropoulos P, Richardson D J, Gallo K. Phase-sensitive wavelength conversion based on cascaded quadratic processes in periodically poled lithium niobate waveguides. In: Proceedings of Conference on Optical Fiber Communication. 2011, Th.9.F.1.

[13] Contestabile G, Maruta A, Sekiguchi S, Morito K, Sugawara M, Kitayama K. All-optical signal processing using QD-SOA. In: Proceedings of Electronics and Communications Conference. 2010, 200-201

[14] Leuthold J, Besse P A, Eckner J, Gamper E, Dülk M, Melchior H. All-optical space switches with gain and principally ideal extinction ratios. IEEE Journal of Quantum Electronics, 1998, 34(4): 622-633

[15] Nakamura S, Tajima K. Bit-rate-transparent non-return-to-zero alloptical wavelength conversion at up to 42 Gb/s by operating symmetric-Mach-Zehnder switch with new scheme. In: Proceedings of Conference on Optical Fiber Conference. 2004, FD3

[16] Hattori M, Nishimura K, Inohara R, Usami M. Bidirectional data injection operation of hybrid integrated SOA-MZI all-optical wavelength converter. IEEE/OSA Journal of Lightwave Technology, 2007, 25(2): 512-519

[17] Yi X, Yu R, Kurumida J, Ben Yoo S J. A theoretical and experimental study on modulation-format-independent wavelength conversion. IEEE/OSA Journal of Lightwave Technology, 2010, 28(4): 587-595

[18] Hatta T, Miyahara T, Miyazaki Y, Takagi K, Matsumoto K, Aoyagi T, Motoshima K, Mishina K, Maruta A, Kitayama K. Polarizationinsensitive monolithic 40-Gbps SOA-MZI wavelength converter with narrow active waveguides. IEEE Journal on Selected Topics in Quantum Electronics, 2007, 13(1): 32-39

[19] Poustie A, Wyatt R, McDougall R, Maxwell G, Hemenway B R. Optical timing jitter transfer characteristics of a 40 Gb/s hybrid integrated SOA-Mach-Zehnder interferometer all-optical regenerator. In: Proceedings of European Conference on Optical Communication. 2005, 3, 413-414

[20] Apostolopoulos D, Simos H, Petrantonakis D, Bogris A, Spyropoulou M, Bougioukos M, Vyrsokinos K, Pleros N, Syvridis D, Avramopoulos H. A new scheme for regenerative 40 Gb/s NRZ wavelength conversion using a hybrid integrated SOA-MZI. In: Proceedings of Conference on Optical Fiber Communication. 2010, OThS6

[21] Kang I, Dorrer C, Zhang L, Rasras M, Buhl L, Bhardwaj A, Cabot S, Dinu M, Liu X, Cappuzzo M, Gomez L, Wong-Foy A, Chen Y F, Patel S, Neilson D T, Jacques J, Giles C R. Regenerative all-optical wavelength conversion of 40 Gb/s DPSK signals using a SOA MZI. In: Proceedings of the 31st European Conference on Optical Communication. 2005, 6, 29-30

[22] Petrantonakis D, Zakynthinos P, Apostolopoulos D, Poustie A, Maxwell G, Avramopoulos H. All-optical four-wavelength burst mode regeneration using integrated quad SOA-MZI arrays. IEEE Photonics Technology Letters, 2008, 20(23): 1953-1955

[23] Wang J P, Savage S J, Robinson B S, Hamilton S A, Ippen E P, Mu R, Wang R, Spiekman L, Stefanov B B. Regeneration using an SOA-MZI in a 100-pass 10000-km recirculating fiber loop. In: Proceedings of Conference on Lasers and Electro-Optics. 2007, CMZ1

[24] Kim J Y, Kang J M, Kim T Y, Han S K. All-optical multiple logic gates with XOR, NOR, OR, and NAND functions using parallel SOA-MZI structures: theory and experiment. IEEE/OSA Journal of Lightwave Technology, 2006, 24(9): 3392-3399

[25] Martinez J M, Herrera J, Ramos F, Marti J. All-optical correlation employing single logic XOR gate with feedback. IEE Electronics Letters, 2006, 42(20): 1170-1171

[26] Aikawa Y, Shimizu S, Uenohara H. Demonstration of all-optical divider circuit using SOA-MZI-type XOR gate and feedback loop for forward error detection. IEEE/OSA Journal of Lightwave Technology, 2011, 29(15): 2259-2266

[27] Vlachos KG, Monroy I T, Koonen A M J, Peucheret C, Jeppesen P. STOLAS: switching technologies for optically labeled signals. IEEE Communications Magazine, 2003, 41(11): 9-15

[28] Pleros N, Zakynthinos P, Poustie A, Tsiokos D, Bakopoulos P, Petrantonakis D, Kanellos G.T, Maxwell G, Avramopoulos H. Optical signal processing using integrated multi-element SOA-MZI switch arrays for packet switching. IET Optoelectronics, 2007, 1(3): 120-126

[29] Zervas G, Sadeghioon L, Klonidis D, Qin Y, Nejabati R, Simeonidou D. Demonstration of novel multi-granular switch architecture on an application-aware end-to-end multi-bit rate OBS network testbed. In: Proceedings of ECOC 2007 Post-deadline papers. 2007, 1-2

[30] Manning R J, Davies D A O. Three-wavelength device for alloptical signal processing. Optics Letters, 1994, 19(12): 889-991

[31] Nguyen A, Porzi C, Serafino G, Fresi F, Contestabile G, Bogoni A. All-optical gated wavelength converter-eraser using a single SOAMZI. IEEE Photonics Technology Letters, 2011, 23(21): 1621-1623

[32] Pinna S, Porzi C, Contestabile G, Bogoni A. Broadband operation of high-speed all-optical gated wavelength shifter. IEEE Photonics Technology Letters, 2012, 24(17): 1546-1548

[33] Nguyen A, Porzi C, Pinna S, Contestabile G, Bogoni A. 40 Gb/s alloptical selective wavelength shifter. In: Proceedings of Conference on CLEO 2012: Science and Innovations. 2012, CM2A.2

[34] Porzi C, Contestabile G, Bogoni A. All-optical simultaneous drop and wavelength conversion of DPSK data. Optics Letters, 2012, 37(13): 2523-2525

[35] Morgan T J, Lacey J P R, Tucker R S. Widely tunable four-wave mixing in semiconductor optical amplifiers with constant conversion efficiency. IEEE Photonics Technology Letters, 1998, 10(10): 1401-1403

[36] Porzi C, Bogoni A, Potì L, Contestabile G. Polarization and wavelength-independent time-division demultiplexing based on copolarized-pumps FWM in an SOA. IEEE Photonics Technology Letters, 2005, 17(3): 633-635