Optical Subcarrier Generation Long Xiao 03/12/2003.

Slides:



Advertisements
Similar presentations
COMMUNICATION SYSTEM EEEB453 Chapter 3 (III) ANGLE MODULATION
Advertisements

About Omics Group OMICS GroupOMICS Group International through its Open Access Initiative is committed to make genuine and reliable contributions to the.
Mode locked laser array monolithically integrated with SOA and EA modulator L. Hou, M. Haji, A. E. Kelly, J. M. Arnold, A. C. Bryce.
1 ISIS-IPHOBAC SUMMER SCHOOL, May 17-18, 2007, Budapest, Hungary "Broadband Architectures and Functions" Generation and processing of UWB Signals over.
In Search of the “Absolute” Optical Phase
Particle Accelerator Engineering, London, October 2014 Phase Synchronisation Systems Dr A.C. Dexter Overview Accelerator Synchronisation Examples Categories.
Space-time positioning at the quantum limit with optical frequency combs Workshop OHP September 2013 Valérian THIEL, Pu JIAN, Jonathan ROSLUND, Roman SCHMEISSNER,
Towards a Laser System for Atom Interferometry Andrew Chew.
40Gbit/s Coherent Optical Receiver Using a Costas Loop
E&CE 477 Photonic Communications Systems & Devices Winter 2006 Instructor: Hamed Majedi.
Microwave Photonics Applications of Stimulated Brillouin Scattering Dr. Avi Zadok, School of Engineering, Bar-Ilan University
Frequency Bistability in a Diode Laser Using Diffraction Gratings Forrest Smith 1, Weliton Soares 2, Samuel Alves 2, Itamar Vidal 2, Marcos Oria 2 1 State.
Danielle Boddy Durham University – Atomic & Molecular Physics group Laser locking to hot atoms.
EE 230: Optical Fiber Communication Lecture 10 From the movie Warriors of the Net Light Sources and Transmitters.
Fiber-Optic Communications James N. Downing. Chapter 5 Optical Sources and Transmitters.
Proprietary & Confidential1 OPLL vision... Coherent WDM systems:  INCREASED BANDWIDTH BY > 10 X  LOWER COST PER BIT  Closely spaced, long haul WDM systems.
Frequency Tuning in a Pasotron Carleen Boyer, John Rodgers, and Dan Lathrop University of Maryland.
1 ISIS-IPHOBAC SUMMER SCHOOL, May 17-18, 2007, Budapest, Hungary "Broadband Architectures and Functions" Photonic microwave signal processing Jianping.
ECE1352F University of Toronto 1 60 GHz Radio Circuit Blocks 60 GHz Radio Circuit Blocks Analog Integrated Circuit Design ECE1352F Theodoros Chalvatzis.
Wireless RF Receiver Front-end System – Wei-Liang Chen Wei-Liang Chen Wireless RF Receiver Front-end System Yuan-Ze University, VLSI Systems Lab
LLRF Phase Reference System The LCLS linac is broken down into 4 separate linac sections. The LCLS injector will reside in an off axis tunnel at the end.
RoFS-Pforzheim Prof. Bogdan Galwas Warsaw University of Technology.
Coherent System in Remote Antenna Application
1 Timing and RF Distribution NLC -> ILC Josef Frisch.
Quadrature Amplitude Modulation (QAM) format
This teaching material is a part of e-Photon/ONe Master study in Optical Communications and Networks Course and module: Author(s): No part of this presentation.
New MMIC-based Millimeter-wave Power Source Chau-Ching Chiong, Ping-Chen Huang, Yuh-Jing Huang, Ming-Tang Chen (ASIAA), Shou-Hsien Weng, Ho-Yeh Chang (NCUEE),
Spectroscopy with comb-referenced diode lasers
Effects of EDFA Gain on RF Phase Noise in a WDM Fiber Optic Link John Summerfield, Mehdi Shadaram, and Jennifer Bratton Photonics Research Laboratory Department.
Controlling the dynamics time scale of a diode laser using filtered optical feedback. A.P.A. FISCHER, Laboratoire de Physique des Lasers, Universite Paris.
Microwave Traveling Wave Amplifiers and Distributed Oscillators ICs in Industry Standard Silicon CMOS Kalyan Bhattacharyya Supervisors: Drs. J. Mukherjee.
Chapter 10 Optical Communication Systems
Volker Schlott SV84, LL-RF Workshop, CERN, October 11 th, 2005 Femto-Second Stable Timing and Synchronization Systems Volker Schlott, PSI Motivation –
Sophie BaronTTC1 TTC status February 2005 ATLAS electronics.
It follows that and Step 1: Assume system to be described as, where y is the output, u is the input and is the vector of all unknown parameters. Step 2:
INTRODUCTION  Tunable lasers are different to traditional lasers because they can continuously change their emission wavelength, or color, in a given.
Injection Locked Oscillators Optoelectronic Applications E. Shumakher, J. Lasri, B. Sheinman, G. Eisenstein, D. Ritter Electrical Engineering Dept. TECHNION.
Wireless Communication Technologies 1 Phase noise A practical oscillator does not produce a carrier at exactly one frequency, but rather a carrier that.
LC Voltage Control Oscillator AAC
Simple Multiwavelength Time-Division Multiplexed Light Source for Sensing Applications Thilo Kraetschmer and Scott Sanders Engine Research Center Department.
Arm Length Stabilisation for Advanced Gravitational Wave Detectors Adam Mullavey, Bram Slagmolen, Daniel Shaddock, David McClelland Peter Fritschel, Matt.
RF Phase Noise in WDM Fiber Optic Links Mehdi Shadaram, Cecil Thomas *, John Summerfield, and Pushkar Chennu Department of Electrical and Computer Engineering,
S. ChelkowskiSlide 1WG1 Meeting, Birmingham 07/2008.
Tuning Fork Scanning Probe Microscopy Mesoscopic Group Meeting November 29, 2007.
Center for Excellence in Engineering Education Photonic Generation of Millimeter Wave Signals for Wireless Applications Mehdi Shadaram Department of Electrical.
A Thermospheric Lidar for He 1083 nm, Density and Doppler Measurements
報告人 : 洪國慶. Outline INTRODUCTION EXPERIMENTAL DETAILS RESULTS AND DISCUSSION CONCLUSION REFERENCES 2.
I.Introduction II. System Design B.E. Unks, N. A. Proite, D. D. Yavuz University of Wisconsin – Madison The above figure shows a block diagram of the apparatus.
Development of a System for High Resolution Spectroscopy with an Optical Frequency Comb Dept. of Applied Physics, Fukuoka Univ., JST PRESTO, M. MISONO,
FM GENERATION Direct Method: when the frequency of carrier is modulated by information signal Indirect Method: when the phase of carrier is modulated.
Tze-Wei Liu Y-C Hsu & Wang-Yau Cheng
Champaign, June 2015 Samir Kassi, Johannes Burkart Laboratoire Interdisciplinaire de Physique, Université Grenoble 1, UMR CNRS 5588, Grenoble F-38041,
Ultra-stable, high-power laser systems Patrick Kwee on behalf of AEI Hannover and LZH Advanced detectors session, 26. March 2011 Albert-Einstein-Institut.
COTS Programme Plenary 5/03/15 A. J. Seeds Department of Electronic and Electrical Engineering, University College London, Torrington Place, London, WC1E.
Date of download: 6/25/2016 Copyright © 2016 SPIE. All rights reserved. Photograph (top) and structure (bottom) of the transmitter module. Figure Legend:
Date of download: 7/5/2016 Copyright © 2016 SPIE. All rights reserved. Basic principle of the proposed circuit. The lower portion of the figure contains.
Multiple Isotope Magneto-Optical Trap from a Single Diode Laser
Integrated Semiconductor Modelocked Lasers
Single and dual wavelength Er:Yb double clad fiber lasers
Chien-Feng Lee, Sheng-Lyang Jang, Senior Member, IEEE, and M. -H
Homodyne readout of an interferometer with Signal Recycling
A 13.5-mW 5-GHz Frequency Synthesizer With Dynamic Divider
Tbit/s Optical Data Transmission
Optoelectronic Microwave Oscillators
Phase Noise… How much is too much?
Rose-Hulman Institute of Technology Terre Haute, IN
Phase Noise… How much is too much?
Stabilizing the Carrier-Envelope Phase of the Kansas Light Source
Fiber Laser Part 1.
Phase Noise… How much is too much?
Presentation transcript:

Optical Subcarrier Generation Long Xiao 03/12/2003

Outline Optical Subcarrier generate Optical phase locked loop (OPLL)

Four Methods of Optical Generation of a Millimeter-wave subcarrier Direct modulation of a laser diode. External modulation. Laser mode locking. Heterodyning of two single-mode lasers.

A Tunable Millimeter-Wave Optical Transmitter

Photograph of Two Laser Module

Spectrum of the Heterodyne Signal The 0.3 nm wavelength separation between the outputs of two microchip-lasers corresponds to 90 GHz heterodyne signal.

Performance of the Heterodyne System Continuous 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 Signal Master Laser Slave Laser Photodector Reference Signal Loop Filter Optical Coupler

Diagram of the Phase Locked Loop With Delay Line

Packaged Optical Phase Locked Loop

References [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 , October [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 , Jul, [4] Yao, X. Steve, et al, “Multiloop optoelectronic oscillator”, IEEE Journal of Quantum Electronics, v36, n1, pp 79-84, [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 , March [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 [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 [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 [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 [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 1990.

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2025 SlidePlayer.com. Inc. All rights reserved.