I J ( \ \ ERBIUM-DOPED FIBER AMPLIFIERS Principles and Applications EMMANUEL DESURVIRE Department of Electrical Engineering Columbia University ffiWlLEY ~INTERSCIENCE A JOHN WILEY & SONS, INC., PUBLICATION This text is printed on acid-free paper. @> Copyright 0 2002 by John Wiley & Sons. Inc .. Hoboken. New Jersey. All rights reserved. Published simultaneously in Canada. No part of this publication may be reproduced. stored in a retrieval system or transmined in any form or by any means. electronic. mechanical. photocopying. recording. scanning or otherwise. except as permined under Section 107 or 108 of the 1976 United States Copyright Act, without either the prior wrinen permission of the Publisher. or authorization through payment of the appropriate per-copy fee to the Copyright Clearance Center. 222 Rosewood Drive. Danvers. MA 01923. (978) 750-8400. fax (978) 750-4744. Requests to the Publisher for permission should be addressed to the Permissions Depanment. John Wiley & Sons. Inc .• 605 Third Avenue. New York. NY 10158-0012. (212) 850-6011. fax (212) 850-6008. E-Mail: [email protected]. For ordering and customer service. call1-800-CALL WILEY. Lib",,., 0/ COllgress ClI,lIIogillg ill Pllbliclldoll 0.111: Desurvire. Emmanuel. 1955- Erbium-doped fiber amplifiers: principles and applications I Emmanuel Desurvire. p. cm. Includes bibliographical references and index. ISBN 0-471-58977-2 (cloth: acid-free paper) ISBN 0-471-26434-2 (paper) I. Lasers. 2. Optical amplifiers. 3. Optical fibers. I. Title. TAI667.D47 1994 621.382 '75-<1c20 93-22410 CIP Printed in the United States of America 10 9 8 7 6 5 4 3 2 1 PREFACE The field of optical fiber communications is now nearly 20 years old, and the maturity of this technology is well reflected by the accelerated rate at which optical fiber links currently are being deployed over the continents and across the oceans. The progress can be measured by considering that existing transoceanic fiber links based on digital communication techniques can transmit 40,000 to 80,000 simultaneous telephone conversations, as compared to 48 in the first telephone cable deployed in 1956 between the United Kingdom and the United States! Formidable technical obstacles had to be overcome in order to reach this performance: essentially, these had to do with manufacturing optical fibers with lowest possible loss and developing reliable laser sources that could survive being turned on and off for several years. A sense of luck may have guided the pioneers of this field because, in spite of such overwhelming difficulties, the technology has never seemed to come to a dead end. In our present information age, where data highways increase in length every day to form gigantic networks on a planetary scale, lightwave technology has a bright future indeed. Yet, in spite of the tremendous information-carrying capacity offered by lightwave systems, the demand for transoceanic communications is still growing at a constant rate of 25% a year. The demand may become even greater in terrestrial systems, although harder to quantify, as it will follow not only the natural growth of intercity communications, but also the predictable emergence of large-size computer networks and fiber-to-the-home loops. Then, and this will not be the first time, one may wonder whether the limits of lightwave technology are going to be felt soon. What are the limits of its capacity? These are not to be found in the optical fiber itself. Between 1.3 and 1.55-Jlm, it offers a comfortable bandwidth of 45 THz still largely underused. Then come the switching electronics used to generate electrical signals and modulate optical sources: for the fastest transistors, the potential bandwidth is up to 100 GHz, only a few times greater than the performance of currently available devices, and greater than the modulation bandwidth of semiconductor optical sources. The real limitation is the need to regenerate optical signals as they undergo attenuation and loss when propagating along a fiber link or network. v vi PREFACE The task of signal regeneration traditionally has been that of electronic repeaters in which optical signals are converted into current by a photodiode; the current is then regenerated and converted back into light by a laser diode. Repeaters must be placed at intervals such that the optical signal power never drops below a level where the probability of misreading digital symbols becomes unacceptably high. Current transatlantic fiber links typically have a 70-km repeater spacing-about 100 repeaters over their 7500-km length. The electronic speed of the repeaters is fixed once and for all and cannot be upgraded. This limits the information rate of repeatered systems. Another drawback of electronic regeneration is that wavelength multiplexing is difficult and costly. This is because many parallel repeaters are needed to combine several optical channels into the same fiber. By the end of the 19805, experts in the field agreed that the maximum capacity of unrepeatered systems, expressed in terms of a bit-rate -length product, had reached its peak. In the future, large systems spanning continental and intercontinental distances would definitely have to rely upon the use of electronic repeaters. This view has now been radically changed, due to the recent and forceful emergence of optical amplifiers, which have taken the form of laser-diode-pumped erbium-doped fibers. Yet again, luck shines on lightwave technology. In 1985,just when conventional unrepeatered systems had approached their peak performance, a research group at the University of Southamptol) showed that optical fibers can exhibit laser gain at a wavelength ncar 1.55 Jlm. The fibers were doped with the rare earth erbium and were activated or pumped with low powers of visible light. In 1986, the author and a small group at AT&T Bell Laboratories joined the investigation. In the years to follow, the primary research work of the University of Southampton and Bell Labs would have tremendous consequences in the conception of lightwave systems. Indeed, if practical optical amplifiers were available, they would offer a much wider operating bandwidth (4 THz) and could then replace electronic repeaters used so far in optical communications. No matter how noble the attempt, any breakthrough in the old field of lightwave systems needs a bit of luck. The lucky nature of erbium ions is that they have some properties of radiative decay with a long excited state lifetime in a glass host, such as the fused silica used to make optical fibers. Their 1.55 Jlm lasing wavelength happens to fall in the spectral region where optical fibers have the lowest loss-a narrow window used for long-haul communications. But that's not all. Miniature semiconductor laser diodes (as opposed to cumbersome, water-cooled laser sources) can be used to pump the erbium-doped fibers, which makes them practical as optical amplifier devices. And the gain characteristics of erbium-doped fibers offer all these advantages: polarization insensitivity, temperature stability, quantum-limited noise figure, and immunity to interchannel crosstalk. These advantages could hardly be achieved, all at once, with other optical amplifier approaches. By early 1989, the first laser-diode-pumped fiber amplifier devices had appeared and system breakthroughs followed at an unprecedented rate. The first experimental systems with lengths of about 1000 km and operations at multigigabit rates without electronic repeaters were demonstrated. They represent a level of performance that no expert could have predicted only a few years ago. At AT&T Bell Laboratories, fiber loop experiments in which data were recirculated many times in order to emulate the characteristics of very long-haul systems based on optical amplifier chains, showed transmission potentials up to 20,000 km. Symbolically, this length is nearly the longest PREFACE vII distance possible on earth. Early in 1993, AT&T and the Japanese company KDD reported a straight fiber link incorporating as many as 274 Er-doped fiber amplifiers; the link was 9000 km long and carried optical data at to Gbit/s-a record capacity of 9O.Thit/s.krn and 100 times the performance level of unrepeatered systems in 1985. Such radical improvements have caused a wide consensus about the importance of optical amplifiers in future optical communications, both in long-haul and network system applications. By 1995, the first transoceanic cables based on optical amplifiers will be deployed over both the Atlantic and Pacific. Each of these high capacity links will have the potential to carry as many as 600,000 voice channels. And we are only witnessing the beginnings of this technology. The motivation for this book has been to provide the basic materials of a comprehensive introduction to the principles and applications of erbium-doped fiber amplifiers. The literature is abundant on this relatively new subject of many different facets. Each facet reflects issues ranging from the most fundamental to the most applied. For this reason, the student, the communications systems engineer, or the research scientist approaching this field for the first time may feel confused about where to start. This book is intended to answer the most basic and practical questions. How is light amplified in the doped fiber? How much spontaneous emission noise is generated at the output? How does amplification affect the photon statistics and signal-to-noise ratio? What are the ultimate noise limits of fiber amplifiers? Why do detectors with optical preamplifiers perform better than avalanche photodiodes? What are the optimal locations of optical amplifiers in a system? What are the current types and architectures of amplifier-based systems? The book is organized in three parts that can be read independently. Part A is theoretical. It deals with the fundamentals of light amplification and noise in single-mode fibers, as well as the principles of photodetection of digital signals with optical amplifiers. Part B outlines the characteristics of erbium-doped fibers, from spectroscopic features to fiber amplifier gain and saturation properties. Part C concerns both device and system applications of erbium-doped fibers. The author is grateful to many coworkers at AT&T Bell laboratories, whose expertise, rigor, and team spirit made the investigation of erbium-doped fiber amplifiers a very challenging and rewarding experience. EMMANUEL DESURVIRE New York April /993 CONTENTS LIST OF ACRONYMS AND SYMBOLS xv A FUNDAMENTALS OF OPTICAL AMPLIFICATION IN ERBIUM-DOPED SINGLE-MODE FI BERS 1 MODELING LIGHT AMPLIFICATION IN ERBIUM-DOPED SINGLE-MODE FIBERS 3 Introduction I 3 1.1 Atomic Rate Equations for Three-level Laser Systems I 5 1.2 Atomic Rate Equations in Stark Split Laser Systems I 8 1.3 Gain Coefficient and Fiber Amplifier Gain I 10 1.4 Amplified Spontaneous Emission I 16 1.5 General Rate Equations for Pump, Signal, and ASE I 17 1.6 Numerical Resolution I 26 1.7 Rate Equations With Step Er-doping I 28 1.8 Rate Equations With Confined Er-doping I 33 1.9 Analytical Model for Unsaturated Gain Regime I 36 1.10 Analytical Models for Low Gain Regime I 40 1.11 Density Matrix Description I 46 1.12 Modeling Inhomogeneous Broadening I 59 ix X CONTENTS 2 FUNDAMENTALS OF NOISE IN OPTICAL FIBER AMPLIFIERS 65 Introduction / 65 2.1 Minimum Amplifier Noise and Temperature / 68 2.2 Quantum Description of Noise / 72 2.3 Photon Statistics in Linear Gain Regime / 78 2.4 Optical Signal-to-noise Ratio and Noise Figure / 98 2.5 Lumped Amplifier Chains / 114 2.6 Distributed Amplifiers / 121 2.7 Photon Statistics of Optical Amplifier Chains / 136 2.8 Nonlinear Photon Statistics / 140 3 PHOTO DETECTION OF OPTICALLY AMPLIFIED SIGNALS 154 Introduction / 154 3.1 Quantum Photodetection Statistics / 156 3.2 Semiclassical Description of Photodetection / 163 3.3 Enhancement of Signal-to-noise Ratio By Optical Preamplification / 167 3.4 Optical Preamplification Versus Avalanche Photodetection / 172 3.5 Bit-error Rate and Receiver Sensitivity in Digital Direct Detection / 174 3.6 Bit-error Rate and Receiver Sensitivity in Digital Coherent Detection / 186 3.7 Digital Photodetection With Optical Amplifier Chains / 191 3.8 Analog Signal Photodetection / 195 B CHARACTERISTICS OF ERBIUM-DOPED FIBER AMPLIFIERS 4 CHARACTERISTICS OF ERBIUM-DOPED FIBERS 207 Introduction / 207 4.1 Characteristics of Laser Glass / 208 4.2 Fabrication of RE-doped Fibers / 212 4.3 Energy Levels of ErJ + : glass and Relaxation Processes / 215 4.4 Laser Line Broadening / 225 4.5 Determination of Transition Cross Sections / 244 4.6 Characterization of Er-doped Fiber Parameters / 270 4.7 Pump and Signal Excited State Absorption / 277 4.8 Energy Transfer and Cooperative Upconversion / 282 4.9 Refractive Index Changes and Resonant Dispersion / 295 4.10 Effect of Pump and Signal Polarization / 303 CONTENTS xl 5 GAIN, SATURATION AND NOISE CHARACTERISTICS OF ERBIUM-DOPED FIBER AMPLIFIERS 306 Introduction / 306 5.1 Characteristics of Pump Laser Diodes and EDF A-related Optical Components / 309 5.2 Gain Versus Pump Power / 319 5.3 Gain Versus Signal Power and Amplifier Saturation / 337 5.4 ASE Noise and Noise Figure / 354 5.5 Amplifier Self-saturation / 373 5.6 Optimization of Fiber Amplifier Parameters / 382 5.7 Amplifier Phase Noise / 399 5.8 Effects of Reflections and Rayleigh Backscattering / 404 5.9 Transient Gain Dynamics / 410 5.10 Picosecond and Femtosecond Pulse Amplification / 420 5.11 Soliton Pulse Amplification / 422 5.12 Other Types of Fiber Amplifiers / 440 C DEVICE AND SYSTEM APPLICATIONS OF ERBIUM-DOPED FIBER AMPLIFIERS 6 DEVICE APPLICATIONS OF EDFAs 455 Introduction / 455 6.1 Distributed and Remotely Pumped Fiber Amplifiers / 456 6.2 Reflective and Bidirectional Fiber Amplifiers / 461 6.3 Automatic Gain and Power Control / 469 6.4 Spectral Gain Equalization and Flattening / 480 6.5 Optically Controlled Gates and Switches / 487 6.6 Recirculating Delay Lines / 499 6.7 Fiber Lasers / 511 7 SYSTEM APPLICATIONS OF EDFAs 524 Introduction / 524 7.1 EDFA Preamplifiers / 527 7.2 Digital Linear Systems / 534 7.3 Soliton Systems I 559 7.4 Analog Systems I 568 7.5 Local Area Networks I 574 xii CONTENTS APPENDICES A RATE EQUATIONS FOR STARK SPLIT THREE-LEVEL LASER SYSTEMS 585 B COMPARISON OF LPo1 BESSEL SOLUTION AND GAUSSIAN APPROXIMATION FOR THE FUNDAMENTAL FIBER MODE ENVELOPE 587 C EXAMPLE OF PROGRAM ORGANIZATION AND SUBROUTINES FOR NUMERICAL INTEGRATION OF GENERAL RATE EQUATIONS (1.68) 591 D EMISSION AND ABSORPTION COEFFICIENTS FOR THREE-LEVEL LASER SYSTEMS WITH GAUSSIAN MODE ENVELOPE APPROXIMATION 596 E ANALYTICAL SOLUTIONS FOR PUMP AND SIGNAL+ASE IN THE UNSATURATED GAIN REGIME, FOR UNIDIRECTIONAL AND BIDIRECTIONAL PUMPING 600 F DENSITY MATRIX DESCRIPTION OF STARK SPLIT THREE-LEVEL 607 LASER SYSTEMS G RESOLUTION OF THE AMPLIFIER PGF DIFFERENTIAL EQUATION IN THE LINEAR GAIN REGIME 614 H CALCULATION OF THE OUTPUT NOISE AND VARIANCE OF LUMPED AMPLIFIER CHAINS 622 I DERIVATION OF A GENERAL FORMULA FOR THE OPTICAL NOISE FIGURE OF AMPLIFIER CHAINS 624 J DERIVATION OF THE NONLINEAR PHOTON STATISTICS MASTER EQUATION AND MOMENT EQUATIONS FOR TWO- OR THREE-LEVEL LASER SYSTEMS 627 K SEMICLASSICAL DETERMINATION OF NOISE POWER SPECTRAL DENSITY IN AMPLIFIED LIGHT PHOTODETECTION 631 L DERIVATION OF THE ABSORPTION AND EMISSION CROSS SECTIONS THROUGH EINSTEIN's A AND B COEFFICIENTS 634 M CALCULATION OF HOMOGENEOUS ABSORPTION AND EMISSION CROSS SECTIONS BY DECONVOLUTION OF EXPERIMENTAL CROSS SECTIONS 638 N RATE EQUATIONS FOR THREE-LEVEL SYSTEMS WITH PUMP EXCITED STATE ABSORPTION 640