Optical Subcarrier GenerationOutlineFour Methods of Optical Generation of a Millimeter-wave subcarrierA Tunable Millimeter-Wave Optical TransmitterPhotograph of Two Laser ModuleSpectrum of the Heterodyne SignalPerformance of the Heterodyne SystemDiagram of the Optical Phase Locked Loop With Reference SignalDiagram of the Phase Locked Loop With Delay LinePackaged Optical Phase Locked LoopReferencesReferencesOptical Subcarrier GenerationLong Xiao03/12/2003OutlineOptical Subcarrier generateOptical phase locked loop (OPLL)Four Methods of Optical Generation of a Millimeter-wave subcarrierDirect modulation of a laser diode.External modulation.Laser mode locking.Heterodyning of two single-mode lasers.A Tunable Millimeter-Wave Optical TransmitterPhotograph of Two Laser ModuleSpectrum of the Heterodyne SignalThe 0.3 nm wavelength separation between the outputs of two microchip-lasers corresponds to 90 GHz heterodyne signal.Performance of the Heterodyne SystemContinuous tuning range (CTR): 45 GHz.Sensitivity: 13.4 MHz/ V.Phase noise: -90 dBc/Hz at 10 kHz offset.Diagram of the Optical Phase Locked Loop With Reference SignalMaster LaserSlave LaserPhotodectorReferenceSignalLoopFilterOpticalCouplerDiagram of the Phase Locked Loop With Delay Line Tunable optical/millimeter wave transmitter Photodetector Loop filter Photodetector X OutputPackaged Optical Phase Locked LoopReferences[1] Y. LI, A. J. C. Vieira, S. M. Goldwasser, P. R. Herczfeld, “Rapidly Tunable Millimeter-Wave Optical Transmitter for Lidar/Radar”, IEEE Transactions on Microwave Theory and Techniques, special issue on microwave and millimeter-wave photonics, Vol. 49, No. 10, pp. 2048-2054, October 2001.[2] Y. Li, S. Goldwasser, P. R. Herczfeld, “Optical Generated Dynamically Tunable,Low Noise Millimeter Wave Signals Using Microchip Solid Satte Lasers.[3] Yao, X. Steve, et al, “Optoelectronic oscillator for photonic systems”, IEEE Journal of Quantum Electronics, v32, n7, pp 1141-1149, Jul, 1996.[4] Yao, X. Steve, et al, “Multiloop optoelectronic oscillator”, IEEE Journal of Quantum Electronics, v36, n1, pp 79-84, 2000.[5] R. T. Ramos, A. J. Seeds, “Delay, Linewidth and Bandwidth Limitations in Optical Phase-locked Loop Design”, Electronics Letters, Vol. 26, No. 6, pp 389-391, March 1990.[6] A. C. Bordonalli, C. Walton, A. J. Seeds, ”High-Performance Homodyne Optical Injection Phase-Lock Loop Using Wide-Linewidth Semiconductor Lasers”, IEEE Photonics Technology Letters, Vol. 8, No. 9, September 1996.References [7] R. T. Ramos and A. J. Seeds, “comparison between first-order and second-order optical phase-lock loops”, IEEE microwave and guided wave letters, vol. 4, no. 1. January 1994.[8] L. N. Langley, M. D. Elkin, C. Edge, M. J. Wale, U. Gliese, X. Huang, and A. J. Seeds, “packaged semiconductor laser optical phase-locked loop (OPLL) for Photonic generation, processing and transmission of microwave signals. IEEE Transcations on microwave theory and techniques, vol. 47, no. 7, July 1999.[9] L. G. Kazovsky, and D. A. Atlas, “A 1320 nm experimental optical phase-locked loop”, IEEE Photonics technology letters, vol. 1. No. 11, November 1989.[10] L. G. Kazovsky, and B. Jensen, “experimental relative frequency stabilization of a set of lasers using optical phase-locked loops”, IEEE Photonics technology letters, vol. 2. No. 7, July 1990.[11] L. G. Kazovsky, and D. A. Atlas, “A 1320-nm experimental optical phase-locked loop: performance investigation and PSK homodyne experiments at 140 Mb/s and 2 Gb/s”. Journal of Lightwave technology, vol. 8. No. 9. September
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