Odyssey of light in nonlinear optical fibers: theory and applications
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Boca Raton ; London ; New York
CRC Press
[2016]
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| Beschreibung: | xxxi, 568 Seiten Illustrationen, Diagramme |
| ISBN: | 9781138749580 9781482236132 |
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| 245 | 1 | 0 | |a Odyssey of light in nonlinear optical fibers |b theory and applications |c edited by Kuppuswamy Porsezian, Ramanathan Ganapathy |
| 250 | |a First issued in paperback | ||
| 264 | 1 | |a Boca Raton ; London ; New York |b CRC Press |c [2016] | |
| 264 | 4 | |c © 2016 | |
| 300 | |a xxxi, 568 Seiten |b Illustrationen, Diagramme | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 650 | 4 | |a Fiber optics | |
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| 700 | 1 | |a Porsezian, Kuppuswamy |d 1963- |0 (DE-588)12447487X |4 edt | |
| 700 | 1 | |a Ganapathy, Ramanathan |4 edt | |
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Datensatz im Suchindex
| _version_ | 1804177764872355840 |
|---|---|
| adam_text | Contents
Foreword.............................................................xix
Preface..............................................................xxi
Acknowledgments......................................................xxv
Editors............................................................xxvii
Contributors........................................................xxix
Chapter 1 Basic nonlinear fiber optics............................1
K. Thyagarajan and Ajoy Qhatak
1.1 Introduction........................................1
1.2 Modes of a step-index fiber.........................1
1.3 Guided modes of a step-index fiber..................3
1.4 Single-mode fiber...................................5
1.4.1 Spot size of the fundamental mode...........6
1.5 Pulse dispersion in optical fibers..................7
1.5.1 Material dispersion.........................7
1.5.2 Waveguide dispersion........................8
1.5.3 Total dispersion............................9
1.5.4 Dispersion and maximum bit rate in
single-mode fibers.........................11
1.5.5 Dispersion-compensating fibers.............12
1.6 Nonlinear effects in optical fibers................13
1.6.1 Self-phase modulation......................13
1.7 Nonlinear Schrodinger equation.....................16
1.8 Spectral broadening due to SPM.....................18
1.8.1 Cross-phase modulation.....................18
1.8.2 Four-wave mixing...........................21
1.8.3 Fiber optic parametric amplifier...........25
1.8.4 Supercontinuum.............................27
Chapter 2 Waveguide electromagnetic pulse dynamics: Projecting
operators method........................................31
Mateusz Kuszner and Sergey Leble
2.1 Introduction.......................................31
2.2 Theory of initialization of a pulse propagation....33
vii
viii
Contents
2.2.1 Cauchy problem formulation in one spatial
dimension...................................33
2.2.2 Projection method for the ID Cauchy
problem.....................................34
2.2.3 Dispersion and nonlinearity with
polarization interaction, general relations.38
2.3 Comparison of results obtained with the multiple
scale method........................................39
2.4 Projection method for boundary regime propagation .. 41
2.5 Cylindrical waveguide...............................45
2.5.1 On transversal fiber modes..................45
2.5.2 Solution of the linear problem, a way to
the projecting procedure....................45
2.6 Including nonlinearity..............................54
2.7 Conclusion..........................................56
Chapter 3 Coupled-mode dynamics in continuous and discrete
nonlinear optical systems................................61
Alejandro Aceves
3.1 Coupled-mode dynamics in nonlinear optical systems.61
3.2 Parity-time optical coupled systems.................64
3.3 Binary arrays.......................................68
3.4 Dual-core photonic crystal fiber....................73
3.5 Fiber amplifiers.................................. 75
3.6 Future directions and conclusions...................75
Chapter 4 Continuous-discrete duality of the nonlinear Schrodinger
and Ablowitz-Ladik rogue wave hierarchies................79
A. Ankiewicz, D. J. Kedziora, and N. Akhmediev
4.1 Introduction........................................79
4.2 Theory..............................................80
4.2.1 Derivation of discrete result...............80
4.2.2 Darboux scheme..............................83
4.3 Rogue wave triplet..................................83
4.4 Discretization effects..............................85
4.5 Ablowitz-Ladik rogue wave hierarchy.................89
4.6 Conclusion..........................................93
Chapter 5 A theoretical study on modulational instability in relaxing
saturable nonlinear optical media........................97
Kuppuswamy Porsezian and K. Nithyanandan
5.1 Introduction...................................... 97
5.2 Scalar MI in the relaxing saturable nonlinearity
(SNL) system.................................. 99
Contents
ix
5.2.1 Theoretical framework.......................99
5.2.2 Linear stability analysis..................100
5.2.3 Results and discussion.....................100
5.3 Vector MI in a relaxing system with the effect of
walk-off and higher-order dispersion...............105
5.3.1 Theoretical framework......................105
5.3.2 Results and discussion.....................105
5.4 MI in a two-core nonlinear directional coupler with
relaxing nonlinearity............................. 110
5.4.1 Theoretical framework......................110
5.4.2 Results and discussion.....................110
5.5 MI in a two-core fiber with the effects of saturable
nonlinearity and coupling coefficient dispersion....114
5.5.1 Theoretical framework......................114
5.5.2 Results and discussion.....................114
5.6 Two-state behavior in the instability spectrum of a
saturable nonlinear system..........................122
5.6.1 Theoretical framework.................. 122
5.7 MI in a semiconductor doped dispersion decreasing
fiber............................................. 125
5.7.1 Theoretical framework......................125
5.7.2 Results and discussion.....................125
5.8 Summary and conclusion.............................128
Chapter 6 Modulational instabilities in a system of four coupled,
nonlinear Schrodinger equations with the effect of a
coupling coefficient...................................................133
H. Tagwo, S. Abdoulkary, A. Mohamadou, C. G.
Latchio Tiofack, and T. C. Kofane
6.1 Introduction.......................................133
6.2 Model..............................................135
6.3 Linear stability analysis..........................136
6.4 Modulational instability gain......................137
6.5 Propagation of waves through the system............140
6.6 Conclusion.........................................142
Chapter 7 Hidden symmetry reductions and the Ablowitz-Kaup-
Newell-Segur hierarchies for nonautonomous solitons.....145
V. N. Serkin, A. Hasegawa, and T. L. Belyaeva
7.1 Introduction.......................................145
7.2 Husimi-Taniuti and Talanov transformations in
quantum mechanics and the soliton theory............147
7.2.1 Darwin wave packet and Chen and Liu
accelerating soliton.......................149
X
Contents
7.2.2 Airy and Hermite accelerating wave pack-
ets in free space................................151
7.2.3 Coherent states, squeezed states, and
squeezions...............................153
7.3 Lax operator method and exact integrability of
nonautonomous nonlinear and dispersive models
with external potentials.........................157
7.4 Nonautonomous nonlinear evolution equations......160
7.4.1 Nonautonomous Hirota equation............160
7.4.2 Solitons of the nonautonomous Korteweg-
de Vries equation........................162
7.4.3 Nonautonomous modified Korteweg-de Vries
equation.................................164
7.5 Generalized NLSE and nonautonomous solitons......165
7.6 Soliton adaptation law to external potentials....168
7.7 Bright and dark NLSE nonautonomous solitons......169
7.8 Colored nonautonomous solitons...................172
7.9 Conclusion.......................................176
Chapter 8 Hot solitons, cold solitons, and hybrid solitons in fiber optic
waveguides...........................................189
P. Tchofo Dinda, E. Tchomgo Felenou, and C. M.
Ngabireng
8.1 Introduction.....................................189
8.2 Isothermic solitons..............................192
8.3 Hyperthermic solitons............................192
8.4 Hypothermic solitons.............................193
8.5 Hybrid solitons..................................193
Chapter 9 Optical solitary modes pumped by localized gain..........199
Boris A. Malomed
9.1 Introduction and models..........................199
9.2 Dissipative solitons pinned to hot spots in the ordi-
nary waveguide........................................205
9.2.1 Analytical considerations................205
9.2.2 Exact results............................205
9.2.3 Exact results for 7 = 0 (no linear
background loss).........................207
9.2.4 Perturbative results for the self-defocusing
medium...................................207
9.2.5 Perturbative results for the self-focusing
medium...................................208
9.2.6 Stability of the zero solution and its rela-
tion to the existence of pinned solitons.........209
Contents xi
9.2.7 Numerical results..........................210
9.2.8 Self-trapping and stability of pinned
solitons...................................210
9.2.9 Model with a double hot spot...............211
9.2.10 Related models........................... 213
9.3 Solitons pinned to the PT-symmetric dipole.........215
9.3.1 Analytical results.........................215
9.3.2 Numerical findings.........................216
9.4 Gap solitons supported by a hot spot in the Bragg
grating............................................219
9.4.1 Zero-order approximation...................220
9.4.2 First-order approximation..................220
9.4.3 Stability of the zero solution.............223
9.4.4 Numerical results..........................223
9.5 Discrete solitons pinned to the hot spot in the lossy
lattice............................................225
9.5.1 Analytical results.........................225
9.5.2 Numerical results..........................226
9.5.3 Self-defocusing regime (B — —1)............226
9.5.4 Self-focusing regime (B = H-l) ............228
9.6 Conclusion.........................................229
Chapter 10 Exploring the frontiers of mode locking with fiber lasers .. 235
Philippe Grelu
10.1 Introduction.......................................235
10.1.1 The wonder of mode locking.................235
10.1.2 Exploring the mode-locking frontier........236
10.1.3 Partially mode-locked regimes..............238
10.2 Soliton rain dynamics .............................238
10.2.1 Introduction...............................238
10.2.2 Fiber laser setup..........................239
10.2.3 First-order mode-locking transition........240
10.2.4 Soliton rain dynamics......................242
10.3 Chaotic pulse bunches.............................243
10.3.1 Extended chaotic bunches: dissipative rogue
waves......................................243
10.3.2 Compact chaotic bunches: Noise-like pulses. 245
10.3.3 Spectral rogue waves.......................246
10.4 Conclusion.........................................249
Chapter 11 Matter wave solitons and other localized excitations in
Bose-Einstein condensates in atom optics................253
P. Muruganandam and M. Lakshmanan
11.1 Introduction.......................................253
• •
XII
Contents
11.2 Gross-Pitaevskii equation..........................254
11.3 Matter wave bright and dark solitons...............256
11.3.1 One-soliton dynamics......................256
11.3.2 Time-independent trap.....................259
11.3.3 Time-dependent trap.......................260
11.3.4 Dark and bright multi-soliton dynamics.....260
11.3.5 iV-dark soliton solution..................265
11.4 Matter wave solitons in multi-component BECs.......266
11.4.1 Dark-bright solitons......................268
11.4.2 Bright—bright solitons....................270
11.5 Summary...........................................275
Chapter 12 PT-symmetric solitons......................................279
Chandroth P. Jisha and Alessandro Alberucci
12.1 Introduction......................................279
12.2 Ruling equation...................................280
12.3 P7~ linear modes..................................281
12.3.1 Particle conservation.....................283
12.4 Nonlinear modes...................................284
12.4.1 Gaussian potential........................285
12.4.2 Periodic potential........................287
12.5 Variational approach for periodic potential and
defocusing nonlinearity...........................291
12.6 Stability analysis................................294
12.6.1 Gaussian potential........................295
12.6.2 Periodic potential........................297
12.7 Dynamical evolution of the soliton................298
12.7.1 Gaussian potential........................298
12.7.2 Periodic potential........................299
12.8 Conclusion........................................300
Chapter 13 Suspended core photonic crystal fibers and generation
of dual radiation......................................305
Samudra Roy, Debashri Ghosh, and Shyamal K.
Bhadra
13.1 Introduction......................................305
13.2 Solid core photonic crystal fiber: A brief outline.308
13.3 Group velocity dispersion.........................309
13.4 Fabrication of suspended core PCFs................311
13.5 Characteristics of suspended core PCF...........313
13.6 Dual-resonant radiation...........................317
Contents
XIII
Chapter 14 Parabolic similaritons in optical fibers....................323
Finot Christophe and Boscolo Sonia
14.1 Introduction.......................................323
14.2 Short-pulse dynamics in normally dispersive fibers ... 324
14.2.1 Model and situation under investigation....324
14.2.2 Parabolic waveform as a transient stage of
evolution in a passive fiber...............325
14.2.3 Parabolic waveform as an asymptotic
attracting state of pulse evolution in a fiber
amplifier..................................327
14.3 Properties of self-similar pulses and extension to
other configurations...............................329
14.3.1 Parabolic similariton properties...........329
14.3.2 Impact of higher-order effects.............331
14.3.3 Extension to other configurations..........332
14.3.3.1 In dispersion-tailored fibers.....332
14.3.3.2 In fiber-based cavities...........332
14.3.3.3 In nonlinear waveguides...........333
14.4 Experimental generation of parabolic pulse shape...334
14.4.1 In passive segments........................334
14.4.2 In fiber amplifiers........................334
14.4.3 Through linear pulse shaping...............337
14.5 Applications of parabolic pulses...................337
14.5.1 High-power pulse amplification and
ultrashort pulse generation................337
14.5.2 Highly coherent continuums for optical
communications.............................339
14.5.3 Ultrafast all-optical signal processing....339
14.5.4 Spectral compression.......................340
14.6 Conclusion.........................................341
Chapter 15 Brillouin scattering: From characterization to novel
applications............................................351
Victor Lambin Iezzi, Sebastien Loranger, and
Raman Kashyap
15.1 Introduction.......................................351
15.2 Basic concepts.....................................352
15.2.1 Generalities...............................352
15.2.2 Spontaneous Brillouin scattering...........352
15.2.3 Stimulated Brillouin scattering............355
15.2.4 Brillouin gain.............................357
15.2.5 Power threshold............................360
15.2.6 Brillouin strain and temperature
dependence.................................363
XIV
Contents
15.2.7 Brillouin mitigation.......................367
15.2.8 Pump laser modulation......................368
15.2.9 Segmented fibers...........................368
15.2.10 Modulation via temperature or strain......368
15.2.11 Polarization and self-induced effects......369
15.3 Brillouin fiber laser..............................371
15.3.1 Continuous wave SBS lasers.................371
15.3.2 DFB Brillouin laser........................373
15.3.3 Multi-Stokes order comb....................374
15.3.4 Mode-locked Brillouin laser................378
15.3.5 Self-phase-locked Brillouin laser..........384
15.4 Brillouin scattering for sensors...................388
15.4.1 BOTDR......................................390
15.4.2 BOTDA......................................392
15.4.3 Advances in distributed sensing............394
15.4.4 Strain sensing vs. temperature sensing....395
15.4.5 Improving sensitivity......................396
15.4.6 Other techniques and limitations...........397
15.5 Conclusion.........................................400
Chapter 16 Nonlinear waves in metamaterials—Forward and
backward wave interaction...............................409
Andrei I. Maimistov
16.1 Introduction.......................................409
16.2 Forward and backward waves.........................410
16.2.1 Discrete linear models.....................410
16.2.2 Discrete nonlinear models for backward
waves......................................411
16.3 Resonant interaction of forward and backward
waves..............................................412
16.4 Parametric interaction.............................415
16.4.1 Second-harmonic generation.................415
16.4.2 Third-harmonic generation .................416
16.5 Waveguide systems: Couplers, arrays and bundles ....417
16.5.1 Alternating nonlinear optical waveguide
zigzag array...............................417
16.5.2 Linear properties of the alternating
waveguide zigzag array.....................419
16.5.3 Nonlinear waves in ANOWZA..................419
16.5.4 Alternating nonlinear optical waveguide
array......................................421
16.5.5 Linear properties of the alternating
waveguide array............................422
16.5.6 Nonlinear waves in ANOWA...................422
Contents
xv
16.5.7 Spatial discrete solitons in ANOWA........423
16.5.8 Bundles of waveguides.....................424
16.5.9 Linear modes of an alternating waveguide
bundle....................................424
16.5.10 Linear modes of the twisted alternating
waveguide bundle..........................425
16.5.11 Nonlinear solitary waves in ANOWB.........426
16.5.12 Oppositely directional couplers...........427
16.5.13 Gap solitons..............................428
16.5.14 Bistability...............................428
16.5.15 Modulation instability....................429
16.5.16 Waveguide amplifier based on ODC..........429
Chapter 17 Optical back propagation for compensation of dispersion and
nonlinearity in fiber optic transmission systems ......435
Xiaojun Liang, Jing Shao, and Shiva Kumar
17.1 Introduction......................................435
17.2 Optical back propagation using optical phase
conjugation........................................437
17.3 Optical back propagation with optimal step size....442
17.4 Ideal optical backpropagation using
dispersion-decreasing fiber........................450
17.5 Conclusion.........................................456
Chapter 18 Eigenvalue communications in nonlinear fiber channels.....459
Jaroslaw E. Prilepsky and Sergei K. Turitsyn
18.1 Introduction and main model description............461
18.2 Nonlinear Fourier transform associated with NLSE...464
18.2.1 Forward nonlinear Fourier transform
(Zakharov-Shabat direct scattering prob-
lem) for the focusing NLSE................465
18.2.2 Modification of the FNFT for the normal
dispersion case...........................467
18.2.3 Backward nonlinear Fourier transform
(Gelfand-Levitan-Marchenko equation).....467
18.2.4 Some remarks on numerical methods for
computing NFT and associated complexity . 468
18.3 Transmission using continuous nonlinear spectrum
— Normal dispersion case......................... 469
18.4 Method of nonlinear and linear spectra equalization
for low energy signals. Anomalous dispersion......472
18.4.1 Nonlinear spectrum expansions for low
signal amplitude..........................473
XVI
Contents
18.4.2 Linear and nonlinear spectra equalization
using signal pre-distortion...............474
18.4.3 Illustration of the method................475
18.4.3.1 Optical frequency division
multiplexing (OFDM) modulation 475
18.4.3.2 Spectra equalization for OFDM
input signals.....................476
18.5 Nonlinear inverse synthesis (NIS)
method—Anomalous dispersion........................478
18.5.1 General idea of the method................478
18.5.2 Illustration of the method................480
18.5.2.1 Synthesis of profiles from some
characteristic shapes in the
nonlinear spectral domain.........480
18.5.2.2 NIS for high-efficiency OFDM
transmission—Comparison with
digital backpropagation...........480
18.6 Conclusion.........................................486
Chapter 19 Digital coherent technology-based eigenvalue modulated
optical fiber transmission system.......................491
Akihiro Maruta, Yuki Matsuda, Hiroki Terauchi,
and Akifumi Toyota
19.1 Introduction.......................................491
19.2 Principle of eigenvalue demodulation...............492
19.3 Numerical demonstration of eigenvalue modulated
transmission.......................................493
19.4 Experimental demonstration of eigenvalue modu-
lated transmission......................................493
19.5 Noise tolerance of eigenvalues.....................498
19.6 Conclusion.........................................504
Chapter 20 Quantum field theory analog effects in nonlinear
photonic waveguides.....................................507
Andrea Marini and Fabio Biancalana
20.1 Optical analog of relativistic Dirac solitons in
binary waveguide arrays............................507
20.1.1 Introduction..............................507
20.1.2 Analytical soliton solutions ........... 508
20.1.3 Soliton propagation and generation........512
20.1.4 Dirac solitons ...........................515
20.1.5 Conclusion ...............................516
20.2 Optical analog of spontaneous symmetry breaking
and tachyon condensation in plasmonic arrays.......516
Contents xvii
20.2.1 Vacuum expectation value and nonlinear
tachyon-like Dirac equation................518
20.2.2 Spontaneous symmetry breaking..............519
20.3 Optical analog of neutrino oscillations in binary
waveguide arrays...................................520
20.3.1 Dirac limit: Neutrinos.....................522
20.3.2 Neutrino oscillations......................523
20.4 Negative frequencies in nonlinear optics...........525
20.4.1 Introduction...............................525
20.4.2 Existence and reality of negative frequen-
cies in optics......................................527
20.4.3 Derivation of the envelope equation for
the anatytic signal from the unidirectional
pulse propagation equation............... 529
20.4.4 Phase-matching conditions between soli-
ton and radiation..........................533
20.4.5 Numerical simulations......................535
20.4.6 Discussion and conclusion..................537
Index...................................................................545
gineering — Electrical
Odyssey of Light in Nonlinear Optical Fibers: Theory and Applications
presents a collection of breakthrough research portraying the odyssey of light
from optical solitons to optical rogue waves in nonlinear optical fibers. The
book provides a simple yet holistic view on the theoretical and application-ori-
ented aspects of light, with a special focus on the underlying nonlinear
phenomena.
Exploring the very frontiers of light-wave technology, the text covers the basics
of nonlinear fiberoptics and the dynamics of electromagnetic pulse propaga-
tion in nonlinear waveguides. It also highlights some of the latest advances in
nonlinear optical fiber technology, discussing hidden symmetry reductions and
Ablowitz-Kaup-Newell-Segur (AKNS) hierarchies for nonautonomous solitons,
state-of-the-art Brillouin scattering applications, backpropagation, and the
concept of eigenvalue communication —a powerful nonlinear digital signal
processing technique that paves the way to overcome the current limitations of
traditional communications methods in nonlinear fiber channels.
Key chapters study the feasibility of the eigenvalue demodulation scheme
based on digital coherent technology by throwing light on the experimental
study of the noise tolerance of the demodulated eigenvalues, investigate
matter wave solitons and other localized excitations pertaining to Bose-Ein-
stein condensates in atom optics, and examine quantum field theory analogue
effects occurring in binary waveguide arrays, plasmonic arrays, etc., as well as
their ensuing nonlinear wave propagation.
Featuring a foreword by Dr. Akira Hasegawa, the father of soliton communica-
tion systems, Odyssey of Light in Nonlinear Optical Fibers: Theory and
Applications serves as a curtain raiser to usher in the photonics era. The
technological innovations at the core of the book form the basis for the next
generation of ultra-high-speed computers and telecommunication devices.
|
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| author2 | Porsezian, Kuppuswamy 1963- Ganapathy, Ramanathan |
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| author_GND | (DE-588)12447487X |
| author_facet | Porsezian, Kuppuswamy 1963- Ganapathy, Ramanathan |
| building | Verbundindex |
| bvnumber | BV044449614 |
| callnumber-first | T - Technology |
| callnumber-label | TA1800 |
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| callnumber-search | TA1800 |
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| callnumber-subject | TA - General and Civil Engineering |
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| ctrlnum | (OCoLC)1028536439 (DE-599)BVBBV044449614 |
| dewey-full | 621.36/92 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 621 - Applied physics |
| dewey-raw | 621.36/92 |
| dewey-search | 621.36/92 |
| dewey-sort | 3621.36 292 |
| dewey-tens | 620 - Engineering and allied operations |
| discipline | Physik Elektrotechnik / Elektronik / Nachrichtentechnik |
| edition | First issued in paperback |
| format | Book |
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| id | DE-604.BV044449614 |
| illustrated | Illustrated |
| indexdate | 2024-07-10T07:53:16Z |
| institution | BVB |
| isbn | 9781138749580 9781482236132 |
| language | English |
| lccn | 015013881 |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-029850565 |
| oclc_num | 1028536439 |
| open_access_boolean | |
| owner | DE-703 DE-83 |
| owner_facet | DE-703 DE-83 |
| physical | xxxi, 568 Seiten Illustrationen, Diagramme |
| publishDate | 2016 |
| publishDateSearch | 2016 |
| publishDateSort | 2016 |
| publisher | CRC Press |
| record_format | marc |
| spelling | Odyssey of light in nonlinear optical fibers theory and applications edited by Kuppuswamy Porsezian, Ramanathan Ganapathy First issued in paperback Boca Raton ; London ; New York CRC Press [2016] © 2016 xxxi, 568 Seiten Illustrationen, Diagramme txt rdacontent n rdamedia nc rdacarrier Fiber optics Faseroptik (DE-588)4016498-6 gnd rswk-swf Nichtlineares Phänomen (DE-588)4136065-5 gnd rswk-swf Faseroptik (DE-588)4016498-6 s Nichtlineares Phänomen (DE-588)4136065-5 s DE-604 Porsezian, Kuppuswamy 1963- (DE-588)12447487X edt Ganapathy, Ramanathan edt Digitalisierung UB Bayreuth - ADAM Catalogue Enrichment application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=029850565&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis Digitalisierung UB Bayreuth - ADAM Catalogue Enrichment application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=029850565&sequence=000002&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA Klappentext |
| spellingShingle | Odyssey of light in nonlinear optical fibers theory and applications Fiber optics Faseroptik (DE-588)4016498-6 gnd Nichtlineares Phänomen (DE-588)4136065-5 gnd |
| subject_GND | (DE-588)4016498-6 (DE-588)4136065-5 |
| title | Odyssey of light in nonlinear optical fibers theory and applications |
| title_auth | Odyssey of light in nonlinear optical fibers theory and applications |
| title_exact_search | Odyssey of light in nonlinear optical fibers theory and applications |
| title_full | Odyssey of light in nonlinear optical fibers theory and applications edited by Kuppuswamy Porsezian, Ramanathan Ganapathy |
| title_fullStr | Odyssey of light in nonlinear optical fibers theory and applications edited by Kuppuswamy Porsezian, Ramanathan Ganapathy |
| title_full_unstemmed | Odyssey of light in nonlinear optical fibers theory and applications edited by Kuppuswamy Porsezian, Ramanathan Ganapathy |
| title_short | Odyssey of light in nonlinear optical fibers |
| title_sort | odyssey of light in nonlinear optical fibers theory and applications |
| title_sub | theory and applications |
| topic | Fiber optics Faseroptik (DE-588)4016498-6 gnd Nichtlineares Phänomen (DE-588)4136065-5 gnd |
| topic_facet | Fiber optics Faseroptik Nichtlineares Phänomen |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=029850565&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=029850565&sequence=000002&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA |
| work_keys_str_mv | AT porseziankuppuswamy odysseyoflightinnonlinearopticalfiberstheoryandapplications AT ganapathyramanathan odysseyoflightinnonlinearopticalfiberstheoryandapplications |