Abstract
A simultaneous unidirectional and bidirectional chaos-based optical communication scheme based on a hybrid coupling semiconductor laser system that consists of one center semiconductor laser (CSL) and multiple side semiconductor lasers (SSLs) is proposed numerically. In this scheme, the SSLs oriented in a linear chain mutually couple with the adjacent SSLs and they are subjected to identical unidirectional injections from the CSL which is a chaotic external cavity semiconductor laser. We theoretically analyze the conditions for different types of chaos synchronization based on the symmetry operation mechanism and injection-locking mechanism, and numerically investigate the influences of operation parameters, parameter mismatch robustness, chaos pass filtering effects and communication performance of the hybrid coupling semiconductor laser system. The simulation results demonstrate that with proper selection of the unidirectional and mutual coupling conditions, the SSLs can synchronize with each other isochronally and simultaneously synchronize to the CSL completely or laggardly, which enables the proposed system to achieve a unidirectional broadcasting communication from the CSL to the SSLs and a bidirectional communication among the SSLs simultaneously. The proposed scheme is beneficial to the implementation of optical chaos communication networks.
Similar content being viewed by others
References
Ohtsubo J. Chaos synchronization and chaotic signal masking in semiconductor lasers with optical feedback. IEEE J Quantum Electron, 2002, 38: 1141–1154
Yan S L, Che Z Y, Chen W J. Chaotic laser synchronization and its application in optical fiber secure communication. Sci China Ser F-Inf Sci, 2004, 47: 332–347
Klein E, Mislovaty R, Kanter I, et al. Public-channel cryptography using chaos synchronization. Phys Rev E, 2005, 72: 016214
Wang A B, Wang Y C. Chaos correlation optical time domain reflectometry. Sci China Inf Sci, 2010, 53: 398–404
Argyris A, Syvrids D, Larger L, et al. Chaos-based communications at high bit rates using commercial fibre-optic links. Nat, 2005, 437: 343–346
Liu J M, Chen H F, Tang S. Optical communication systems based on chaos in semiconductor lasers. IEEE Trans Circuits Syst I-Regul Pap, 2001, 48: 1475–1483
Vicente R, Mirasso C R, Fischer I. Simultaneous bidirectional message transmission in a chaos-based communication scheme. Opt Lett, 2007, 32: 403–405
Jiang N, Pan W, Luo B, et al. Properties of leader/laggard chaos synchronization in mutually coupled external-cavity semiconductor lasers. Phys Rev E, 2010, 81: 066217
Klein E, Gross N, Kopelowitz E, et al. Public-channel cryptography based on mutual pass filtering. Phys Rev E, 2006, 74: 046201
Rontani D, Locquet A, Sciamanna M, et al. Spectrally efficient multiplexing of chaotic light. Opt Lett, 2010, 35: 2016–2018
Pisarchik N A, Ruiz-Oliveras R F. Optical chaotic communication using generalized and complete synchronization. IEEE J Quantum Electron, 2010, 46: 279–284
Jiang N, Pan W, Yan L S, et al. Chaos synchronization and communication in mutually coupled semiconductor lasers driven by a third laser. J Lightwave Technol, 2010, 28: 1978–1986
Vicente R, Perez T, Mirasso C R. Open-versus closed-loop performance of synchronized chaotic external-cavity semiconductor lasers. IEEE J Quantum Electron, 2002, 38: 1197–1204
Lang R, Kobayashi K. External optical feedback effects on semiconductor injection laser properties. IEEE J Quantum Electron, 1980, 16: 347–355
Heil T, Fischer I, Elsasser W. Chaos synchronization and spontaneous symmetry-breaking in symmetrically delaycoupled semiconductor lasers. Phys Rev Lett, 2001, 86: 795–798
Chiang M C, Chen H F, Liu J M. Synchronization of mutually coupled systems. Opt Commun, 2006, 261: 86–90
Vicente R, Fischer I, and Mirasso C R. Synchronization properties of three-coupled semiconductor lasers. Phys Rev E, 2008, 78: 066202
Kanakidis D, Argyris A, Bogris A, et al. Influence of the decoding process on the performance of chaos encrypted optical communication systems. J Lightwave Technol, 2006, 24: 335–341
Jiang N, Pan W, Luo B, et al. Influence of injection current on the synchronization and communication performance of closed-loop chaotic semiconductor lasers. Opt Lett, 2011, 36: 3197–3199
Bogris A, Rizomiliotis P, Chlouverakis K E, et al. Feedback phase in optically generated chaos: A secret key for cryptographic applications. IEEE J Quantum Electron, 2008, 44: 119–124
Jiang N, Pan W, Yan L S, et al. Chaos synchronization and communication in multiple time-delayed coupling semiconductor lasers driven by a third laser. IEEE J Sel Top Quantum Electron, 2011, 17: 1220–1227
Li X F, Pan W, Luo B, et al. Mismatch robustness and security of chaotic optical communications based on injectionlocking chaos synchronization. IEEE J Quantum Electron, 2006, 42: 953–960
Fischer I, Liu Y, Davis P. Synchronization of chaotic semiconductor laser dynamics on subnanosecond time scales and its potential for chaos communication. Phys Rev E, 2000, 62: 011801(R)
Paul J, Lee M W, Shore K A. Effect of chaos pass filtering on message decoding quality using chaotic external-cavity laser diodes. Opt Lett, 2004, 29: 2497–2499
Murakami A, Shore K A. Chaos-pass filtering in injection-locked semiconductor laser. Phys Rev A, 2005, 72: 053810
Bogris A, Kanakidis D, Argyris A, et al. Performance characterization of a closed-loop chaotic communication system including fiber transmission in dispersion shifted fibers. IEEE J Quantum Electron, 2004, 40: 1326–1336
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Jiang, N., Pan, W., Luo, B. et al. Simultaneous unidirectional and bidirectional chaos-based optical communication using hybrid coupling semiconductor lasers. Sci. China Inf. Sci. 57, 1–11 (2014). https://doi.org/10.1007/s11432-012-4721-5
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11432-012-4721-5