european conference on optical communication ; 28 … · 2008. 7. 15. · 28th european conference...
TRANSCRIPT
28th European Conference
on Optical
COMMUNICATION
IEEE Catalog Number: 02TH8640ISBN VOL 1 - 87-90974-63-8ISBN VOL 2 - 87-90974-64-6ISBN VOL 3 - 87-90974-65-4ISBN VOL 4 - 87-90974-66-2ISBN POST DEADLINE PAPERS:
87-90974-67-0
SEPTEMBER 8-12, 2002 • BELLA CENTER • COPENHAGEN • DENMARK
ORGANIZED BY COM CENTER • SUPPORTING ORGANISATIONS: IEEE / LEOS, EUREL
EDITOR: PER DANIELSEN, COM, TECHNICAL UNIVERSITY OF DENMARK
TIB/UB Hannover 89
128 007 605
VOLUME 3 • WEDNESDAY • SEPTEMBER 11 • 2002
nqs
Volume 3 - table of contents
Tutorial 6
CONTROL PLANE FOR OPTICAL NETWORKS: THE STATE OF
THE STANDARDS
Saha D. Tellium, USA
Symposium 3 - Raman AmplifiersChair: C Larsen
Symposium 3.01
UTLRA-WIDE BAND TELLURITE-BASED FIBRE RAMAN AM¬
PLIFIERS
MoriA, Masuda H, Shimizu M. NTT corporation, Japan
Symposium 3.02
ULTRABROADBAND FIBER RAMAN AMPLIFIERS
Emori Y. Furukawa Electric, Japan
Symposium 3.03
SCALING THE RAMAN GAIN COEFFICIENT OF OPTICAL
fIBERS '
RottwittK(l), Bromage J(2), Leng L(2). 1: OFS Fitel, Denmark, 2:
OIK Fitel, USA
Symposium 3.04 <
QUASI-CONSTANT SIGNAL POWER TRANSMISSION
Bouteiller J-Q Brar K, Headley C. OFS Laboratories, USA
Symposium 3.05 \^
DIRECT COMPARISON OF ELECTRICAL AND OPTICAL MEAS¬
UREMENTS OF DOUBLE RAYLEIGH SCATTER NOISE
Smokovdin V, Lewis S A E, Chernikov S V. IPF Technology, UK
6.1 Dispersion CompensationChair: E lannone
6.1.1
STATUS AND FUTURE PROMISES FOR DISPERSION COM¬
PENSATING FIBRES
GrQner-Nielsen L, Edvold B. OFS Fitel Denmark l/S, Danmark
6.1.2
ERROR-FREE TUNABLE DISPERSION SLOPE COMPENSATION
FOR 40-Gb/s WDM SYSTEMS USING NON-CHANNELI-ZED 3rd-
ORDER CHIRPED FIBER BRAGG GRATINGS
SongYW(1), Pan Z(1), Yu C(1), Wang Y(1), Popelek J(2), Li H(2),
Li Y(2), Willner A E( 1). 1: University of Southern California, USA.2:
Phaethon Communications, USA
6.1.3
AUTOMATIC DISPERSION COMPENSATION FOR WDM
SYSTEM BY MODE-SPLITTING OF TONE-MODULATED CS-RZ
SIGNAL
Kuwahara S, Hirano A, Miyamoto Y, Murata K. NTTCorporation,
Japan
6.1.4
SIGNED ONLINE CHROMATIC DISPERSION DETECTION AT
40Gb/s WITH ASUB-PS/NM DYNAMIC ACCURACY
Sandel D, Mirvoda V, WOst F, Noe R, Hinz SO). University
Paderborn, Germany. 1: Siemens AG, Germany
6.1.5
EVALUATION OF THIRD-ORDER DISPERSION COMPENSA¬
TION BY PHASE MODULATION FOR 160 Gb/s RZ DATA US¬
ING AN ALL-OPTICAL SAMPLING SYSTEM
Hellstrdm E, Westlund M, Sunnerud H, Karlsson M, Andrekson P
A*.Chalmers University of Technology, Sweden. *CENiX Inc., USA
6.1.6
DISPERSION MANAGEMENT OPTIMIZATION FOR 160Gb/s
TRANSMISSION SYSTEMS USING RZ OR CS-RZ MODULATION
FORMATS
Frignac Y, Bissessur H, Pecci P, Bigo, S. Alactel, Research and In¬
novation, France
6.2 Planar Lightwave Circuits III
Chair: M R Poulsen
6.2.1
MULTIMODE FIBER MATCHED ARRAYED WAVE-GUIDES
GRATING-BASED (DE-)MULTIPLEXER FOR SHORT-DISTAN-CE
COMMUNICATIONS
MusaS, Borreman A, Pandraud G(1), Knijn P, Sengo G, Diemeer
M B J, Driessen A. University of Twente, The Netherlands. 1:
OpsiTech, France
6.2.2
LOW-INSERTION LOSS ATHERMAL AWG MULTI/DEMULTI-
PLEXER BASED ON PERFLUORINATED POLYMERS
Gao Reny., Gao R, Takayama K, Yeniay A, Garito A F. Photon-X,
Inc., USA
6.2.3
CENTRAL WAVELENGTH TRIMMING OF ALL-POLYMER
ATHERMAL AWG MULTIPLEXER
KeilN, Yao H H, Zawadzki C, Garbe S, RadmerO. Heinrich-Hertz-
Institut, Germany
6.2.4
FABRICATION AND ANALYSIS OF LOW DISPERSION AR-
RAYED-WAVEGUIDE GRATINGS WITH NARROW CHANNEL
SPACING
Yan M, Cao D, McGreer K A, Lam J. Lightwave Microsystems
Corp, USA
6.2.5
NEW PHASE CHARACTERISATION METHOD OF AWG FROM
TRANSMISSION AND GROUP DELAY MEASUREMENTS
LAzaroJA, Koppenborg J. Alcatel R&l, Germany
Volume 3 - table of contents
6.2.6
64 x 64-CHANNEL UNIFORM-LOSS AND CYCLIC-FREQUEN¬
CY ARRAYED-WAVEGUIDE GRATING ROUTER MODULE
KameiS, Ishii M, Itoh M, ShibataT, KitagawaT. NTT Corporation,
Japan
6.2.7
SCALABLE 128 x 128 OPTICAL SWITCH SYSTEM COMPOSED
OF PLANAR LIGHTWAVE CIRCUIT AND FIBER SHEET FOR
OPTICAL CROSSCONNECT
Goh T, Takahashi H, WatanabeT, Kobayashi M, Shibata T, Ishii M,
Sohma S, Abe Y, Okuno M, Hibino Y. NTT Corporation, Japan
6.3 Ail-optical ProcessingChair: N Doran
6.3.1
OPTICAL SIGNAL PROCESSING USING NONLINEAR FIBERS
Watanabe S, Futami F. Fujitsu Laboratories Ltd., Japan
6.3.2
OPTICAL 3R REGENERATION WITH ALL-OPTICAL TIMING
EXTRACTION AND SIMULTANEOUS WAVELENGTH CONVER¬
SION USING ASINGLE ELECTRO-ABSORPTION MODULATOR
AwadES, ChoPS, Richardson C, MoultonN, GoldharJ. University
of Maryland
6.3.3
NOVEL 3R REGENERATOR ARCHITECTURE WITH WAVE¬
LENGTH FLEXIBLE OUTPUT
Sartorius B, Slovak J, Bornholdt C, Nolting H-P. Heinrich-Hertz-
Institut, Germany
6.3.4
BENEFIT OF SPM-BASED ALL-OPTICAL RESHAPER FOR
DWDM SYSTEM USING OTDM RECEIVER
Yoshikane N, Morita I, Edagawa N. KDDI R&D Laboratories Inc.,
Japan
6.3.5
ALL-OPTICAL FIBER SIGNAL PROCESSING BASED ON BAL¬
ANCED NOLM AND IM8ALANCED NOLM
ChiN, Oxenlawe L, Siahlo A, Jeppesen P. COM, Technical University
of Denmark
6.3.6
40 Gb/s OPTICAL NOISE SUPPRESSION AND WAVELENGTH
CONVERSION BY MQWSATURABLE ABSORBER INTEGRATED
IN A FABRY-PEROT CAVITY
PantouvakiM(1), Burr E(1), Feced R(2), Fice M{2), Gwilliam R(3),
Roberts J S(4), Seeds A J(1). 1: University College London, UK. 2:
Nortel Networks, UK. 3: University of Surrey, UK. 4: University of
Sheffield, UK
6.4 Transparant NetworkingChair: A Gladisch
6.4.1
TRANSPARENT OPTICAL NETWORKING TRANSMISSION AND
IMPAIRMENTS THROUGH 12 DISTINCT OPTICAL NODES
DownieJ D, Sauer M, Franzen A, Ricketts D, Fu X,
Hemenway R. Corning Incorporated, USA
6.4.2
AUTOMATICWAVELENGTH SERVICE DEMONSTRATION US¬
ING 38 WAVELENGTHS AND 10.66 Gb/s THROUGH 12 INDE¬
PENDENT TRANSPARENT WDM NODES FOR LONG-HAUL
NETWORKING
FuX, Sauer M, Franzen A, Webb D, Ricketts D, Kaliniouk V, Li M,
DownieJ, Ruffin B, Onuorah A, Grzybowski R, Flavin T(2), Atkins
P(2), Davey R(2), Wagner R E, Hemenway R. 1: Corning Incorpo¬
rated, USA. 2: BTexact, UK
6.4.3
TRANSPARENT FOUR-FIBER OPTICAL CHANNEL SHARED
PROTECTION RING WITH SPAN AND RING SWITCHING
UMJ, Lelic I, Onuorah A, Tebben D J, Soulliere M J, Hilbert S T,
Gray M W, Zhao M, Kaliniouk V, Guiziou L, JouannoJ-M, Killian
K, Shacklette L, Hemenway B R, Wagner R E. Corning Incorprated,
USA
6.4.4
EXPERIMENTAL VALIDATION OF A TRANSPARENT WAVE¬
BAND-BASED OPTICAL BACKBONE NETWORK
PenninckxD, Charlet G, Antona J-C, Noirie L. Alcatel R&l, France
6.4.5
POLARIZATION MULTIPLEXING IN A REMOTELY-CONFIGU¬
RABLE PHOTONIC NETWORK
Hecker-Denschlag N E, Schairer W, Fischler W, Richter A,
Auernhammer T, Lankl B. Siemens AG, Germany
6.4.6
8 CASCADED LINEAR OPTICAL AMPLIFIERS IN A 200km,
8x10-Gb/s, METRO WDM RING FEATURING STATIC AND
DYNAMIC SWITCHING OF CHANNELS
CrijnsJJJ(l), Spiekman L H(1),van den Hoven G N(1), Tangdiongga
E<2), de Waardt H(2). 1: Genoa Corporation. 2: Eindhoven Uni¬
versity, The Netherlands
6.4.7
TECHNIQUES FOR SUPPRESSION OF RAMAN AND EDFA GAIN
TRANSIENTS IN DYNAMICALLY SWITCHED TRANSPARENT
PHOTONIC NETWORKS
Goeger G, Lankl B. Siemens AG, Germany
Volume 3 - table of contents
Tutorial 7
WDM IN THE METRO
Berthold J CIENA, USA
Symposium 3 - Raman Amplifiers (cont.)Chair: C Larsen
Symposium 3.06
RAMAN AMPLIFICATION IN ULTRA LONG HAUL SYSTEMS
NissovM, Foursa D G, Kidorf H D, Pilipetskii A N.Tyco. Telecom¬
munications, USA
Symposium 3.07
LOW-COST, HIGH-CAPACITY ULTRA-LONG-HAUL WDM SYS¬
TEMS BASED ON WIDE-BAND RAMAN AMPLIFICATION
ChbatM W, Fevrier H A. Xtera Communications, Inc., USA
Symposium 3.08
ALL-RAMAN AMPLIFIED LINKS IN COMPARISON TO EDFA-
LINKS IN CASE OF SWITCHED TRAFFIC
SchulzeE, Malach M, Raub F. OFS, Germany
Symposium 3.09
IMPACT OF DISCRETE RAMAN AMPLIFIER ARCHITECTURE
ON NONLINEAR IMPAIRMENTS
Thiele HJ, Bromage J, Nelson L. OFS Laboratories, USA
Symposium 3.10
EXPERIMENTAL INVESTIGATION OF PERFORMANCE IM¬
PROVEMENT BY CO-PROPAGATING RAMAN AMPLIFICA¬
TION IN REPEATERLESS SYSTEMS
Davenet M, Manach L, Favre F, Merlaud F, Leguen D, Billes L,
Georges T. Corvis Algety, France
7.1 Polarisation Mode Dispersion 1
Chair: P Andrekson
7.1.1
MITIGATION OF HIGHER ORDER PMD BY DISTRIBUTING
PMD COMPENSATORS IN THE TRANSMISSION LINE
Xie C Lucent Technologies, USA
7.1.2
COMPARISON OF POWER PENALTIES DUE TO FIRST- AND
ALL-ORDER PMD DISTORTIONS
Lima A 0(1), Lima I T(1), Adali T(1), Menyuk C R(2).
1: University of Maryland, USA. 2: PhotonEx, USA
7.1.3
ADAPTIVE PMD COMPENSATION IN A 160 Gb/s RZ TRANS¬
MISSION SYSTEM USING EYE MONITOR FEEDBACK
Buchali F(1), BQlow H(1). Baumert W(1), Schmidt M(1), Schuh
K(1), Lach E(1), Corbel E(2), Berger J(3), Ludwig R(3), Schubert
C(3), Weber H G(3). 1: Alcatel, Germany. 2: Alcatel, France. 3:
HHI, Germany
7.1.4
PMD MITIGATION BY FREQUENCY DIVERSE DETECTION
RECEIVER EMPLOYING ERROR-CORRECTION FUNCTION
Tomizawa M, Kisaka Y, Hirano A, Miyamoto Y. NTT Corporation,
Japan
7.1.5
ADAPTIVE ELECTRONIC EQUALIZATION USING HIGHER-OR¬
DER STATISTICS FOR PMD COMPENSATION IN LONG-HAUL
FIBER-OPTIC SYSTEMS
Koc U-V, Tu K-Y, Kaneda N. Lucent Technologies, USA
7.1.6
HIGH SENSITIVITY PERFORMANCE MONITORING AND IM¬
PAIRMENT COMPENSATION VIA TWO-PHOTON ABSORP¬
TION IN A PHOTON-COUNTING SILICON AVALANCHE
PHOTODIODE
Roth J M(1), Moeller L(2), Xu C(2), Knox W H(3), Bergman K(4).
1: Princeton University, USA. 2: Lucent Technologies, USA.3:
University of Rochester, USA. 4; Columbia University, USA
7.1.7
80 GBIT/S PMD COMPENSATION USING A HYBRID INTE¬
GRATED ALL-OPTICAL EXOR CIRCUIT
/to X, Sato R, Kasahara R, Ogawa I, Kawaguchi Y, Shibata Y, Ohki
A, Inoue Y, Kondo Y, Tohmori Y, Suzuki Y. NTT Corporation, Ja¬
pan
7.2 Gratings And Filters
Chair: P Chavel
7.2.1
UV-CURABLE SILICONE WRITE-THROUGH COATINGS FOR
FIBER BRAGG GRATINGS
Walker CB, Paolucci D. 3M Company, USA
7.2.2
TEMPERATURE-COMPENSATION OF FIBER BRAGG GRATINGS
BY POLYETHYLENE FIBER REINFORCED PLATICS
Oe K(1), Hashimoto T(1), Yano H(1), Mikami 0(2) Kakinuma S(2),
Yamanaka A(3). 1: Kyoto Institute of Technology, Japan. 2: Tokai
University, Japan. 3: Toyobo Co., Ltd., Japan
Volume 3 - table of contents
7.2.3
BRAGG GRATING PACKAGE FOR SIMPLE BROAD-RANGE
TUNING
MokhtarMRO), Ibsen M(1,2), Butler S A(1), SetSY(3), Richardson
D J(1,2), Payne D N(1,2), 1: University of Southhampton, UK. 2:
Southhampton Photonics Incorporated, UK. 3: Micron Optics Inc.,
USA
7.2.4
EXTERNAL SURROUNDING INSENSITIVE LONG PERIOD FIBER
GRATING
Tsuda X(1), Uemura Y<1), Koyamada Y(2)._1: The Furukawa Elec¬
tric Co., LTD, Japan. 2: Ibaraki University, Japen
7.2.5
TWO-POINT SOURCE GRATING WRITING METHODS
Ashton BJ, Canning J. 2: University of Sydney, Australia
7.2.6
LOW TEMPERATURE-SENSITIVE SILICA-BASEDWAVEGUIDE
BRAGG GRATING ON CRYSTALLIZED GLASS SUBSTRATE
Kintaka K(1), Nishii J(1), Kawamoto Y(2), Sakamoto A(3).
1: National Institute of Advanced Industrial Science and Technolo¬
gy, Japan. 2: Moritex Co., Japan. 3: Nippon Electric Glass Co.,
Ltd., Japan
7.2.7
LOW-DISPERSION FIBRE BRAGG GRATINGSWRITTEN USING
THE POLARIZATION CONTROL METHOD
Deyerl H-J, Plougmann N, Jensen J B D, EI-BezJ, Sarensen H R,
Peucheret C, Kristensen M. COM, Technical University of Den¬
mark, Denmark
7.3 All-optical RegenerationChair: I Bennion
7.3.1
ALL-OPTICAL RESHAPING/RETIMING OPERATION OF
INTERSUBBAND ABSORPTION SWITCH USING InGaAs/AIAs/
AlAsSb COUPLED QUANTUM WELLS
Simoyama X, Akiyama T, Gopal A V, Yoshida H, Mozume T,
Ishikawa H. The Femtosecond Technology Research Association,
Japan
7.3.2
NOVEL, HIGH-STABILITY 3R ALL-OPTICAL REGENE-RATOR
BASED ON POLARIZATION SWITCHING IN A SEMICONDUC¬
TOR OPTICAL AMPLIFIER
Gavioli G, Bayvel P. University College London, UK
7.3.3
BIT-RATE TUNABLE ALL-OPTICAL REGENERATION BY SOA-
BASED POLARIZATION DISCRIMINATED SWITCH USING
VARIABLE DIFFERENTIAL GROUP DELAY GE-NERATOR
Tsurusawa M, Inohara R, Nishimura K, Usami M. KDDI R&D Labo¬
ratories Inc., Japan
7.3.4
POWER EQUALIZATION AND SIGNAL REGENERATION WITH
DELAY INTERFEROMETER ALL-OPTICAL WAVELENGTH CON¬
VERTERS
LeutholdJ, Kauer M, Duelk M. Lucent Technologies, USA
7.3.5
OPERATION MARGINS OF 40Gbit/s SOA-MZI USED IN DIF¬
FERENTIAL SCHEME FOR OPTICAL 3R REGENE-RATION
Lavigne B, Balmefrezol E, Brindel P, Dagens B, Pierre L, Pecci P,
Brenot R, Leclerc O. Alcatel CIT/R&I, France
7.3.6
EXPERIMENTAL DEMONSTRATION AT 10 Gbps OF 2R OPTI¬
CAL REGENERATION IN A FIBER-BASED MZI WITH LOAS
Zhao M, De Merlier J, Morthier G, Baets R. Ghent University-
IMEC, Belgium
7.3.7
SINGLE-STAGE ALL-OPTICAL 3R AT 40 Gb/s RETAINING IN¬
PUT WAVELENGTH USING SAGNAC INTERFE-ROMETER IN¬
TEGRATED WITH PARALLEL-AMPLIFIER STRUCTURE (SIPAS)
Shibata Y, Kikuchi N, Oku S, Ito T, Okamoto H, Kawaguchi Y,
Kondo Y, Suzuki Y, Tohmori Y. NTT Corporation, Japan
7.4 Network Management and control
Chair: G Junyent
7.4.1
PHOTONICS IN THE 6* EUROPEAN RESEARCH FRAMEWORK
PROGRAM
Kalbe G. European Commission, Directorate General Informa¬
tion Society,
7.4.2
DEMONSTRATION OF FAST RESTORATION FOR DISTRIBUTED
CONTROL PLANE ON PHOTONIC NETWORK
Shimano K, Sahara A, Koga M, Takigawa Y, Sato K-l. Nippon
Telegraph and Telephone, Japan
7.4.3
LINK-BASED PHOTONIC PATH PERFORMANCE PREDICTION
AND CONTROL
Friskney R, Warbrick K, Poliakoff S, Heath R. Nortel Networks,
UK
Volume 3 - table of contents
7.4.4
SPECTRAL MONITORING OF OSNR IN HIGH-SPEED NET¬
WORKS
KilperD C, Chandrasekhar S, Buhl L, Agarwal A, Maywar D. Lucent
Technologies, USA
7.4.5
OSNR MONITORING FOR FAULT MANAGEMENT IN HIGH
SPEED NETWORKS
Weingartner W, Kilper D C. Lucent Technologies, USA
7.4.6
AUTONOMOUS ABSOLUTE-WAVELENGTHCONTROL
Hashimoto E, Katagiri Y. Nippon Telegraph and Telephone
Corporation, Japan
Tutorial 8
NOISE IN OPTICAL AMPLIFIERS AND THE NOISE FIGURE
DEFINITION
HausA. H Massachusetts Institute of Technology, USA
8.1 40 Gb/s Based Transmission
Chair: G Hill
8.1.1
NETWORK SYSTEM ARCHITECTURE BASED ON 43 Gbit/s OTN
ITU-T STANDARD
Kataoka X, Tomizawa M, Tada Y. NTT Corporation, Japan
8.1.2
1.6 Tb/s (40 x 40 Gb/s) DPSK TRANSMISSION WITH DIRECT
DETECTION
BissessurH, Charlet G, Gohin E, Simonneau C, Pierre L, Idler W(1).
Alcatel R&l, France. 1: Alcatel, Germany
8.1.3
3.2 TB/S (40 X 80 GB/S) STRAIGHT-LINE TRANSMISSION OVER
735 KM OF NDSF WITH 0.8 bit/s/Hz SPECTRAL EFFICIENCY
Duffy SM, Verghese S, Henion S, Romkey B, Rao H G, Weldon K
R. PhotonEx Corporation, USA
8.1.4
40 Gbit/s x 4 CHANNEL, ALL-OPTICAL MULTI-CHANNEL
LIMITER BASED ON SPECTRALLY FILTERED OPTICAL
SOLITONS
Ohara X, Takara H, Hirano A, Mori K, Kawanishi S. NTT Corpora¬
tion, Japan
8.1.S
0.8bit/S/Hz OF INFORMATION SPECTRAL DENSITY BY VES¬
TIGIAL SIDEBAND FILTERING OF 42.66 Gb/s NRZ
Idler W, Charlet G\ Dischler R, Frignac Y*, Bigo S*.AIcatel R&l,
Germany. * Alcatel, France
8.1.6
INVESTIGATION OF INTRA-CHANNEL NONLINEAR DISTOR¬
TION IN 40GBIT/S TRANSMISSION OVER NON-ZERO DISPER¬
SION SHIFTED FIBRE
Mikhailov V, Appathurai S, Killey R I, Bayvel P. University College
London,UK
8.2 Metropolitan Network TechniquesChair: P Gambini
8.2.1
STUDY ON FULL SPECTRUM DIRECTLY MODULATED CWDM
TRANSMISSION OF 10 Gb/s PER CHANNEL OVER WATER-
PEAK-SUPPRESSED NON-ZERO DISPERSION SHIFTED FIBER
Sogawa /, Kaida N, Iwai K, Takagi T, Nakabayashi T, Sasaki G.
Sumitomo Electric Industries, Ltd., Japan
8.2.2
ULTRA-HIGH CAPACITY TRANSMISSION OVER 3 KM OF LE¬
GACY 50um MULTIMODE-FIBRE USING C-BAND HDWDM
AND QUADRATURE-SUBCARRIER MULTIPLEXING
RochatE(l), Kourtessis P(1>, Webster M(2), Quinlan T(1), Dudley
S<1), Walker S D(1), Penty R V(2), Parker M C(3), White I H(2).
1: University of Essex, UK. 2: Cambridge University, UK 3: FujitsuNetwork Communications Inc., UK
8.2.3
PHOTONIC PARALLEL-TO-SERIAL CONVERTER USING MSM-
PDs FOR BYPASS/DROP SELF-ROUTING
Xakahata K, Nakahara T, Takenouchi H, Takahashi R, Suzuki H.
NTT Corporation, Japan.
8.2.4
DWDM DEMULTIPLEXING WITH 25-GHZ CHANNEL SPACING
FOR 60-GHZ BAND RADIO-ON-FIBER SYSTEMS
Toda H(1), Yamashita T(1), Kitayama K-i(1), Kuri T(2).1: Osaka
University, Japan 2: Communications Research Laboratory, Japan
8.2.5
10-GBIT/S BURST-MODE CLOCK AND DATA RECOVE-RY
UNITS FOR OPTICAL PACKET-BASED SYSTEMS
Kimura 5, Okada A, Endo J, Tanobe H, Suzuki Y, Matsuoka M.
NTT Photonics Laboratories, Japan
8.2.6
RAMAN AMPLIFIED METRO MULTIPLE RING NETWORKS
WITH PUMP POWER DISTRIBUTION NODE
Aoki Y, Kinoshita S. Fujitsu Network Communications, Inc., USA
8.2.7
40 dB MODULATION DEPTH ENHANCEMENT OF OPTICALLY
CARRIED MICROWAVE SIGNALS, BYSTIMULATED BRILLOUIN
SCATTERING IN OPTICAL FIBRES
Norcia 5, Tonda-Goldstein S, Dolfi D, Huignard J-P. Thales Re¬
search and Technology-France, France
Volume 3 - table of contents
8.3 Sources/Fiber Lasers
Chair: J T Kringlebotn
8.3.1
NOVEL 40GHz PULSE SOURCE WITH <350 FEMTO-SECOND
TIMING JITTER
Weingarten K J, SpOhler G J, Dymott M, Klimov I, Luntz G, Baraldi
L, Kilburn I, Crosby P, Thomas S, Zehnder O, Teisset C Y, Brownell
M, Dangel R(1), Offreln B J(1), Bona G L(1), Buccafusca 0(2), Kaneko
Y(2), Krainer L(4), Paschotta R(3), Keller U(3). GigaTera Inc., Swit¬
zerland. 1: IBM Research, Switzer-land. 2: Agilent Technologies,
USA. 3: Swiss Federal Institute of Technology, Switzerland
8.3.2
MULTI-WAVELENGTH, TUNABLE, HIGH-POWER RZ PULSE
SOURCE FOR WDM SYSTEMS BASED ON OPTICAL PARAMET¬
RIC AMPLIFICATION
7broi/n/d/s7'Sunnerud H.Hedekvist P-O, Andrekson P A*. Chalmers
University, Sweden. 2: *Cenix Inc., USA
8.3.3
GENERATION OF ULTRAHIGH REPETITION RATE PULSE
BURSTS USING SUPERIMPOSED FIBER BRAGG GRATINGS
Azafta J(1), Slavik R(2), Kockaert P(2,3), Chen L R(1), La Rochelle
5(2). 1: McGill University, Canada. 2: Universite Laval, Canada. 3:
Universite libre de Bruxelles, Belgium
8.3.4
NOVEL METHOD TO INCREASE PULSE REPETITION FRE¬
QUENCY IN FIBRE RING LASERS
Gupta K K(1), Onodera N(2), Hyodo M(1), Abedin K S(1),
Watanabe M(1), Ravikumar J(3). 1: Communications Research
Laboratory, Japan. 2: National Defense Academy, Japan 3: MSI
Marcony Company, Singapore
8.3.5
AN 8-CHANNEL FIBRE-DFB LASER WDM-TRANSMITTER
PUMPED WITH A SINGLE 1.2W Yb-FIBRE LASER OPERATED
AT977nm
Fu L B(1), Selvas R(1), Ibsen M(1,2), Sahu J K(1), Alam S-U(2),
Nilsson J(1,2), Richarsdon D J(1,2), Payne D N(1,2). Codemard
C(2), Goncharov S(3), Zalevsky l(3), Grudinin A B(2). 1: University
of Southampton, UK. 2: Southampton Photonics Inc., UK. 3: Milon
Laser, Russia
8.3.6
ALL-OPTICAL PULSE-RATE MULTIPLICATION USING FRAC¬
TIONAL TALBOT EFFECT AND FIELD TO INTENSITY CONVER¬
SION BY CROSS GAIN MODULATION
Atkins S, Dahan D, Fischer B. Institute of Technology, Israel
8.3.7
IMPROVED PERFORMANCE OF A160 Gb/s FIBRE BASED ALL-
OPTICAL SWITCH USING RECTANGULAR GATING PULSES
Schubert C, Ludwig R, Watanabe S(1), Futami F(1), Ferber S, Berger
J, Schmidt C, Weber H G. Heinrich-Hertz-lnstitut, Germany.1:
Fujitsu Lab. Ltd., Japan
8.4 All-optical DemulitiplexingChair: K White
8.4.1
320-Gbit/s DEMULTIPLEXING WITH MONOLITHIC PD-EAM
OPTICAL GATE
Kodama 5, Yoshimatsu T, Ito H. NTT Corporation, Japan
8.4.2
ULTRAFAST OPERATION OF OPTICAL TIME-DIVISION
DEMULTIPLEXER USING QUASI-PHASE MATCHED LiNb03
DEVICE
Klkuchl K(1), Fukuchi Y(1), Suzuki A(2), Kunimatsu D(2), Ito H(3).
1: University of Tokyo, Japan. 2: Femtosecond Technology Re¬
search Association, Japan. 3: Tohoku University, Japan
8.4.3
160-Gbit/s DEMULTIPLEXING TO BASE RATES OF 10 AND 40
Gbit/s WITH A MONOLITHICALLY INTEGRATED SOA-MACH-
ZEHNDER INTERFEROMETER
HeidM(l), Jansen S L(2), Spalter S(1), Meissner E(1), Vogt W(3),
Melchior, H(3). 1: SIEMENS AG, Germany. 2: Eindhoven University
of Technology, The Netherlands. 3: Swiss Federal Institute ofTech¬
nology, Switzerland.
8.4.4
40-GHz OPTICAL CLOCK RECOVERY FROM A 160-Gbit/s
OPTICAL DATA STREAM USING A REGENE-RATIVELY MODE-
LOCKED SEMICONDUCTOR LASER
Ohno X, Sato K, Shimizu T/Furuta T, Ito H. NTT Corporation, Ja¬
pan
8.4.5
FAST CLOCKED DECISION - A NOVEL ULTRA HIGH SPEED
SWITCHING TECHNIQUE
Nolting H-P, Sartorius B, Heinrich Hertz-lnstitut, Germany
8.4.6
STANDING-WAVE ENHANCED ELECTROABSORPTION MO¬
DULATOR FOR 80Gb/s TO 10Gb/s OTDM DEMULTIPLEXING
Chou H-F, Chiu Y-J, Bowers J, Rau L, Rangarajan S, Blumenthal D
J. University of California, Santa Barbara, USA
Volume 3 - table of contents
8.4.7
INTERSUBBAND TRANSITIONS WITH VERY LOW (FJ/um2)
SWITCHING ENERGY FOR ALL-OPTIC SWITCHES: DESIGN
AND REALIZATION
Gopal A V, Simoyama T, Yoshida H, Muzume T, Ishikawa H.
Femtosecond Technology Research Association, Japan
8.5 Optical Packet SwitchingChair: G Mogensen
8.5.1
OPTICAL PACKET SWITCHED METRO NETWORKS
Le Sauze N(1), Dotaro E(1), Ciavaglia L(1), Dupas A(1), Chiaroni
D(1), Ge A(2), Sridhar K(2), Dembeck L(3), Koerber W(3), Wolde
J(3). 1: Alcatel, France. 2: Alcatel, USA 3: Alcatel, Germany
8.5.2
COMPOSITE PACKET SWITCHED WDM NETWORK
BoroditskyMO), Lam C F(2), SmiljanicAO), Frigo NJ(1), Dreyer K
F(3), Ackerman D A(4), Johnson J E(4), Ketelsen L J P(4), Chen
A(4). 1: AT&T Labs-Research. 2: OpVista. 3: Lucent Technologies.4: Agere Systems, USA
8.5.3
A PACKET SCHEDULING ALGORITHM FORTHE 2x2 PHOTO¬
NIC PACKET SWITCH WITH FDL BUFFERS
Baba K-i, Takemori R, Murata M, Kitayama K-i. Osaka University,
Japan
8.5.4
CHOOSING AN APPROPRIATE BUFFER STRATEGY FOR AN
OPTICAL PACKET SWITCH WITH A FEED-BACK FDL BUFFER
Develder C, Pickavet M, Demeester P. Ghent University - IMEC,
Belgium
8.5.5
SIZE AND CASCADABILITY LIMITS OF SOA BASED BURST
SWITCHING NODES
Feng H, Patzak E, Saniter J. Heinrich-Hertz-lnstitut, Germany
8.5.6
DATA REWRITE OF WAVELENGTH CHANNEL USING SATU¬
RATED SOA MODULATOR FOR WDM METRO/ACCESS NET¬
WORKS WITH CENTRALIZED LIGHT SOURCES
Xakesue H, Sugie T. NTT Access Network, Japan
Fibers and waveguide components
P1.1
DISCRETE RAMAN AMPLIFIERS WITH PUMP REFLECTORS
FOR INCREASED GAIN AND EFFICIENCY
Nicholson J. OFS Laboratories, USA
P1.2
ALL-OPTICAL SWITCHING BY OPTICAL FIBERGRATING COU¬
PLER
Sasaki Y(1), MineoH(1),Yokota H<1), Shiojiri Y(2). KanbeH(2). 1:
Ibaraki University, Japan.2: Kochi University of Technology, Japan
P1.3
JITTER CHARACTERISTICS OF A FOUR-WAVE-MIXING BASED
CLOCK EXTRACTOR
Bilenca A, Dahan D, Lasri J, Eisenstein G.Technion, Israel
P1.4
ALL-SILICA DOUBLE-CLAD HEXAGONAL YB:ER FIBERS
CroteauA, Le Foulgoc K, Meneghini C, Ptneau t, Lauzon J. INO,
Canada
P1.5
EFFECT OF GAIN DISTRIBUTION AND PUMP NOISE TRANS¬
FER ON NOISE GENERATION IN RAMAN AMPLIFIERS
Dallot V, Gallion P, Bridoux E. Ecole Nationale SupeYieure des
Telecommunications, France
P1.6
WAVELENGTH SENSITIVITY OF POLARIZATION DEPENDENT
LOSS MEASUREMENTS IN SWEPT LASER SYSTEMS
Anderson D. Tektronix, USA
P1.7
NONLINEAR COEFFICIENT MEASUREMENf METHOD FOR
OPTICAL FIBERS BASED ON FREQUENCY RESPONSE OF IN¬
TENSITY MODULATION
Mori X, Furukawa H. Anritsu Corporation, Japan
P1.8
ACCURATE TUNING OF THE HIGHLY-NEGATIVE-CHROMATIC-
DISPERSION WAVELENGTH IN DUAL CONCENTRIC CORE FI¬
BRE BY MACRO-BENDING
FGvrierS, Auguste J-L, Blondy J-M, Peyrilloux A, Roy P, Pagnoux
D. IRCOM, France
P1.9
FLUORINATED POLYIMIDE WAVEGUIDE FABRICATED USING
REPLICATION PROCESS WITH ANTISTICKING LAYER
Shioda T. Mitsui Chemicals, Inc., Japan
P1.10
NONLINEAR PHOTOSENSITIVITY COMPENSATION FOR FLAT
DISPERSION BRAGG GRATING FABRICATION
Besley J A, Reekie L, Weeks C, Bolger J A. JDS Uniphase, Aus¬
tralia
P1.11
GRADED-INDEX PLASTIC OPTICAL FIBERS EXCEEDING
Ishigure X Koike Y. Keio University, Japan
Volume 3 - table of contents
P1.12
THE NEW OPTICAL COUPLING WITH THE SUPER WIDE
RANGE AR BY THE GRIN-COAT
Anzaki X Mori K, Kunisada T, Nakama K, Nakamura K, Honda M,
Enjoji K, Oikawa M, Fukuzawa T. Nippon Sheet Glass, Japan
P1.13
RAMAN NOISE FIGURE IN DISPERSION-MANAGED FIBERS
Kobyakov A, Vasilyev M, Tsuda S, Giudice G, Ten S,
Corning Inc., USA
P1.14
DESIGN OF CLADDING PUMPED EDFAS USING A SPATIALLY
RESOLVED NUMERICAL MODEL
Sf'monneau C, Provost L, Bousselet P, Leplingard F, Moreau C,
Gasca L, Bayart D. Alcatel Research & Innovation, France.
PI.15
NOVEL ALL-FIBER BANDPASS FILTER BASED ON HOLLOW
OPTICAL FIBER
Choi S, Eom T J, Yu J W, Lee B H, Oh K. Institute of Science and
Technology, Korea
P1.16
1545NM-PUMPED LONG-WAVELENGH-BAND ERBIUM-
DOPED FIBER AMPLIFIER WITH ENHANCED POWER CON¬
VERSION EFFICIENCY
Choi B-H(l), Chu M-J(2), Park H-H(1). 1: The University of Mel¬
bourne, Australia. 2: Optical Link Technology Team, ETRI, Korea
PI.17
ADJUSTABLE DISPERSION COMPENSATORS WITH WAVE¬
LENGTH TUNABILITY BASED ON ENHANCED THERMAL
CHIRPING OF FIBER BRAGG GRATINGS
Dabarsyah B, Goh C S, Khijwania S K, Set S Y, Katoh K, Kikuchi K.
The University of Tokyo, Japan
P1.18
NOISE SUPPRESSION IN A HARMONICALLY MODE-LOCKED
FIBRE RING LASER
Zhao DO), Lai Y(1), Shu X(2), Zhang W(2), Zhang L(1), Bennion
1(1). 1: Aston University, UK. 2: Indigo Photonics Ltd. UK
P1.19
LOW POWER CONSUMPTION SILICA-BASED MULTI-CHAN¬
NEL VARIABLE OPTICAL ATTENUATOR USING PLANAR
LIGHTWAVE CIRCUITTECHNOLOGY FOR MULTIFUNCTIONAL
APPLICATION
Hatayama H, Shiozaki M, Hirose C, Saitoh T, Komiya T, Semura S,
Katsuyama T, Yamabayashi N, Sumitomo Electric Industries, Ltd.,
Japan
"\
P1.20
PASSBAND FLATTENING AND REJECTION BAND BROADEN¬
ING OF A PERIODIC MACH-ZEHNDER WAVELENGTH FlbTER
BY ADDING A TUNED RING RESONATOR ,'^
Roeloffzen C, de Ridder R M, Sengo G, Worhoff K, Drie'ssen A.'
University of Twente, The Netherlands •'
P1.21
HIGH-POWER STABLE MACH-ZEHNDER-INTERFE-ROMETER-
TYPE 15-WAVELENGTH MULTIPLEXER FOR 1480NM BAND
PUMPING
Seo K, Iwaya M, Shiino M, Tanaka K, Hideshima Y. The Furukawa
Electric Co., Ltd., Japan
P1.22
BACKWARD AND FORWARD FOUR WAVE MIXING WITH
NONLINEAR FIBER INCREASED IN BRILLOUIN GAIN BAND¬
WIDTH BY ACOUSTIC BEAT
Oh I. Mokpo National University, Korea
P1.23
RELATIONSHIP BETWEEN RELATIVE DISPERSION SLOPE OF
A TRANSMISSION FIBER AND THE USABLE BANDWIDTH
AFTER DISPERSION COMPENSATING
RathjeJ, Gruner-Nielsen L OFS Fitel Denmark, Denmark
P1.24
BROADBAND HIGH POWER FIBER VARIABLE OPTICAL
ATTENUATOR FOR GAIN CONTROL OF RAMAN AMPLIFIER
Shin W, Jeong Y, Oh K.Kwangju Institute of Science and Technol¬
ogy, Korea
P1.25
A +24 dBm TWO STAGE HYBRID ER DOPED - Er/Yb CO-
DOPED DOUBLE CLAD FIBER AMPLIFIER FOR THE C BAND
EvenP, Tallaron N, Monteville A, Metayer B, Ossikovski R, Pureur
D. HighWave Optical Technologies, France
P1.26
BANDWITH AND CHIRP CHARACTERISATION OF WA¬
VELENGTH CONVERSION BASED ON ELECTROAB-SORPTION
MODULATORS
Xu L, Oxenlawe L K, Chi N, Romstad F P, Yvind K, M0rk J, Jeppesen
P, Hoppe K, Hanberg J(1).COM, Technical University of Denmark,
Denmark.(1) Giga-An Intel Company
P1.27
MEMS VOA WITH POLYMERIC THERMAL MICRO-ACTUA¬
TORS
Diemeer M, Dekker R(1). University of Twente, The Netherlands.
(1) JDS Uniphase Corporation, Ottawa
Volume 3 - table of contents
P1.28
ALTERNATE WAVELENGTH-SWITCHING IN A DUAL-WAVE¬
LENGTH MODE-LOCKED FIBER LASER
Chen L R(1), Pudo D(1), Lim K L(1), Zhang L(2), Bennion l(2).1: McGill University, Canada. 2: Aston University, UK
P1.29
LIMITATIONS OF LOW PDL ALL-FIBER LARGE BAND FABRY-
PEROT FILTERS
Slavik R, LaRocheile S, Doucet S. Universite Laval, Canada
P1.30
BACKSCATTERING RECAPTURE FACTOR MEASURE-MENTS
USING OPTICAL CONTINUOUS WAVE
REFLECTOMETRY
ArtigJia M, Locaputo M, Ruocchio C. Pirelli Cables & Systems
Telecom, Italy
P1.31
HIGH REFRACTIVE INDEX CONTRAST TRANSMISSION GRAT¬
ING FOR INTEGRATED OPTICAL WAVELENGTH DIVISION
MULTIPLEXING
Wiechmann S, Heider H J, Muller J.Technical University of
Hamburg-Harburg, Germany
P1.32
SPATIAL CHARACTERIZATION OF FBG'S USING LAYER PEEL¬
ING
Waagaard O H, R0nnekleiv E, Kringlebotn J T.Optoplan AS, Nor¬
way
P1.33
BROADBAND PMD EQUALIZATION
Eyal AO), Yariv A(2). 1: Tel-Aviv University, Israel. 2: California
Institute of Technology, USA
P1.34
MULTIPLE SPAN DISPERSION COMPENSATION USING ALL-
FIBER HIGHER-ORDER-MODE DISPERSION COMPENSATORS
Ghalmi S, Ramachandran S, Monberg E, Wang Z, Yan M,
Dimarcello F, Reed W, Wisk P, Fleming J. OFS Laboratories, USA
P1.35
WIDE-BAND HIGH NEGATIVE DISPERSION-FLATTENED FIBER
Jeon J U, Seo H K, Lee YT. Operations Support System Laboratory,
Korea
P1.36
IMPROVING EFFICIENCY OF SUPERCONTINUUM GENERA¬
TION IN PHOTONIC CRYSTAL FIBERS BY DIRECT DEGENER¬
ATE FOUR-WAVE-MIXING
NikolovN1(1,2), BangOO), BjarklevAO). 1: Technical University
of Denmark. 2: Ris0 National Laboratory, Denmark
P1.37
EFFICIENT HIGH-CONCENTRATION Er:Yb DOPED LINEAR
WAVEGUIDE AMPLIFIERS
XaccheoSO), Jose G(1), Sorbelio G(1), Osellame R(1), Migliorati
D(1), Laporta P(1), Foglietti V(2), Cienci E(2), Jiang 5(3),
Peyghambarian N(3). 1: Politecnico di Milano, Italy. 2: IESS-CNR,'
Italy. 3: Tucson University, Tucson, AZ
P1.38
OPTICAL LOSS ANALYSIS OF SILICON RICH NITRIDE
WAVEGUIDES
Martens H, Andersen K N, Svendsen W £. COM, Technical Uni¬
versity of Denmark, Denmark
Optoelectronics and semiconductor integratedDevices
P2.1
NEW HIGH POWER RIDGE-WAVEGUIDE 980 NM LASER DI¬
ODES
KawasakiK, Shigihara K, Yoshida Y, Yamamura S-i, Yagi T, Mitsui
Y. Mitsubishi Electric Corporation, Japan
P2.2
40 GHz HYBRID MODE-LOCKED LASER DIODE WITH IMPED¬
ANCE-MATCHING CIRCUIT
Arahira S, Mineo N, Tachibana K, Ogawa Y. Oki Electric Industry
Co., Ltd. Japan
P2.3
ELECTRO-THERMALLYTUNABLEDIELECTRICMIRROR MEM¬
BRANES FOR OPTICAL FILTERS AND VCSELS
RiemenschneiderF(1), Halbritter H(1), Hess GO), Jacquet J(2), Plais
A(2), Sigmund J(1), Meissner P(1). 1: Technische UniversitSt
Darmstadt, Germany. 2: OPTO+, Alcatel Research & Innovation,
France
P2.4
MODE CONTROL OF WIDELY-TUNABLE SG-DBR LASERS
Larson M, Bai M, Bingo D, Ramdas N, Penniman S, Fish G A,
Coldren L D. Agility Communications, USA
P2.5
PHOTONIC BANDGAP EFFECT IN DISORDERED ARRAYS OF
SCATTERERS: IMPLICATIONS TO BROADBAND, LOW-LOSS
WAVEGUIDING
Leosson K(1), Bozhevolnyi S(2), Volkov V(2), Boltasseva A(3). 1:
Micro Managed Photons A/S, Denmark. 2: Aalborg University,
Denmark. 3: COM, Technical University of Denmark, Danmark
P2.6
ALL-OPTICAL WAVELENGTH CONVERSION WITH NRZ-RZ
FORMAT CONVERSION
Chow C W, Wong C S, Tsang H K. 1: The Chinese University of
Hong Kong.
Volume 3 - table of contents
P2.7
HIGHLY RELIABLE 40mW, 25GHz X 20 CH THERMALLY TUN¬
ABLE DFB LASER MODULE INTEGRATED WITH WAVE¬
LENGTH MONITOR
Mukaihara TO), Nasu H(1), Kimoto T(1), Tamura S(1), Nomura
T(1), Shinagawa TO), Kasukawa A(1), Oike M(2) Matsuura H(2),
Shiba T(2). 1: Yokohama R&D Labs. Japan. 2: Fitel Photonics Lab.,
Japan
P2.8
OUTPUT POWER CONTROL AND WAVELENGTH MONITOR¬
ING IN WIDELY TUNABLE SAMPLED-GRATING DBR LASERS
USING INTEGRATED SEMICONDUCTOR OPTICAL AMPLIFIERS
MajewskiMLO), RakicADO), Coldren LA(2,3), Akulova Y(3). 1:
University of Queensland, Australia. 2: University of California at
Santa Barbara, USA. 3: Agility Communications Inc. USA
P2.9
WAVELENGTH CONVERSION EXPERIMENTS BY FOUR-WAVE
MIXING IN A MODE-LOCKED DBR LASER DIODE
Arahira S, Ogawa Y. Oki Electric Industry Co., Ltd., Japan
P2.10
ENGINEERING COUPLED DEFECTS FOR PHOTONIC CRYSTAL-
BASED OPTICAL DELAY LINES. ALL-OPTICAL SWITCHESAND
WAVEGUIDE INTERSECTIONS
Lan S, Kanamoto K, Nishikawa S, Sugimoto Y, Ikeda N, Yang T,
Asakawa K, Ishikawa H. The Femtosecond Technology Reseach
Association, Japan
P2.11
A PACKAGED 40Gb/s X-CUT LiNb03 MODULATOR WITH 3V-
DRIVE-VOLTAGE AND SUPPRESSED DC-DRIFT
Kondo JO), Kondo A(1), Aoki K(1), Mori T(1), Mizuno Y(1),
Takatsuji SO), Mitomi 0(1), Imaeda M(1), Kozuka Y(1), Minakata
M(2). 1: NGK Insulators, Ltd., Japan. 2: Shizuoka University, Ja¬
pan
P2.12
IMPROVEMENT OF SINGLE-MODE OPERATING RANGE IN
TUNABLE EXTENDED-CAVITY LASERS WITH INTRA-CAVITY
DYNAMIC HOLOGRAPHY
Godard A0,2), Pauliat G(1), Roosen G(1), Graindorge P(2).1:
Laboratoire Charles Fabry de I'lnstitut d'Optique, France. 2:
NetTest, Photonics Division, France
P2.13
CHARACTERIZATION AND DEVELOPMENT OF MICRO-MA¬
CHINED VARIABLE OPTICAL ATTENUATOR
DaiX, Zhao X, Cai B, Li W. Shanghai Jiaotong University, China
P2.14
ALL-OPTICAL WAVELENGTH CONVERTER BASED ON CROSS-
POLARIZATION MODULATION IN A SINGLE SEMICONDUC¬
TOR OPTICAL AMPLIFIER
Liu Y, Hill M T, Tangdiongga E, de Waardt H, Calabretta N, Khoe
G D, Dorren HJ S. Eindhoven University of Technology, The Neth¬
erlands
P2.15
A NOVEL RECEPTACLE-TYPE SMALL-FORM UN-COOLED DFB-
LASER MODULE WITH AN LD DRIVER IC FOR 10Gb/s
ETHERNET APPLICATION
Xakagi X, Fukushima N, Sato M, Kihara T, Nakabayashi T, Go H.
Sumitomo Electric Industries, Ltd., Japan
P2.17
80 Gb/s CLOCK RECOVERY USING A TWO-SECTION GAIN-
COUPLED DFB LASER
Li Y, Li G. University of Central Florida, USA
P2.18
2.5Gbit/s 85°C FLOOR-FREE OPERATION OF 1.3pm DFB LA¬
SERS UNDER EXTERNAL OPTICAL FEEDBACK FOR DIFFER¬
ENT REFLECTION DISTANCES
GrillotFO), Thedrez B(1), Gauthier-Lafaye 0(1), PyJ(1), Martineau
M F(1), Lafragette J L(1), Gentner J L(1), Silvestre L(2). 1: Alcatel
R&l, France. 2: Alcatel Optronics, France
P2.19
DESIGN AND FABRICATION OF HIGHLY EFFICIENT NON-LIN¬
EAR OPTICAL DEVICES FOR IMPLEMENTING HIGH-SPEED
OPTICAL PROCESSING
Barry L P(1), Krug T(2), Folliot H(2), Lynch M(2), Bradley A L(2),
Donegan J F(2), Roberts J S(3), Hill G(3). 1: Dublin City University,
Ireland. 2: Trinity College, Ireland. 3: University of Sheffield, UK
P2.20
A COMPACT(7cc), 8-CHANNEL-INTEGRATED PLC-BASED
OPTICAL MODULE WITH AUTOMATIC TUNABLE FILTER FOR
MULTI-RATE APPLICATIONS
Kimura H, Yoshida T, Kumozaki K, Nakamura M. NTT Corpora¬
tion, Japan
P2.21
MONOLITHICALLY INTEGRATED InP-BASED DYNAMIC
CHANNEL EQUALIZER USING WAVEGUIDE ELECTRO-AB¬
SORPTIVE ATTENUATORS - PHOTODE-TECTORS
Xolstikhin VI, Densmore A, Laframboise S, Noel J-P. Pimenov K.
MetroPhotonics Inc., Canada
P2.22
5W IN A MULTI-MODE FIBER FROM OF A SINGLE 980-nm-
EMITTING LASER DIODE
Deichsel E, J3ger R, Unger P. University of Ulm, Germany
Volume 3 - table of contents
P2.23
SOA CHARACTERISTICS FOR L-BAND SYSTEM APPLICATIONS
Xurukhin A, Lunardi L, Gonzales E, Vreeburg K(1). JDS Uniphase
Corporation, USA (1: The Netherlands)
P2.24
EXTERNAL CAVITY DIODE LASERS FOR NETWORK APPLICA¬
TIONS
Anthon D, Berger J D, Cheung K, Drake J, Dutta S, Fennema A,
Grade J D, Hrinya S, llkov F, Jerman H, King D, Lee H, Tselikov A,
Yasumura K. lolon, Inc., USA
P2.25
SHORT PULSE ABSORPTION DYNAMICS IN A P-l-N InGaAsP
MQW WAVEGUIDE SATURABLE ABSORBER
RomstadF(1), Ohman F(1), Mark J(1), Yvind K(1), Hvam J M(1),
Hanberg J(2). 1: COM, Technical University of Denmark, Den¬
mark. 2: Giga ApS-An Intel Company.
P2.26
MIRRORS WITH INTEGRATED POSITION SENSE ELECTRON¬
ICS FOR OPTICAL SWITCHING APPLICATIONS
Roessig XArakelian A, Brosnihan T, Clark B, Han D, Judy M, Juneau
T, Lemkin M, Sherman S(1), Swift J(1>. Analog Devices, USA.
(DAnalog Devices, UK
P2.27
METROTRANSMISSION PERFORMANCE OF UNCOOLED 1.55-
MICRON DFB LASERS OPERATING UP TO 85°C
ThieleHJ(1), Yatsu R(2), Morshed M(2), Funabashi M(2).
1: OFS, USA. 2: The Furukawa Electric Co., Japan
P2.28
SIMPLE MEASUREMENT OF THE CHIRP PARAMETER OF OP¬
TICAL MODULATORS USING PARTIAL OPTICAL FILTERING
Yan L-S, Yu Q, Willner A E.University of Southern California, USA
P2.29
LONG-TERM RELIABLE TAPERED 3-SECTION DBR WITH
20mW- 15.5nm FAST TUNING
Debr6geas-S/llardH, Plais A, David J, Vuong A, Le Gouezigou O,
Decobert J, Herrati D, Houe F, Serrano C, Doussiere P, Jacquet J.
Alcatel, France
P2.30
EXTREMELY BROADBAND TUNABLE SEMICONDUCTOR LA¬
SERS FOR OPTICAL COMMUNICATION
Lin C-F, Su Y-S, Chen C-H. National Taiwan University, Taiwan
P2.31
43 Gb/s MODULATOR DRIVER INTEGRATED CIRCUITWITH 6
VPP OUTPUT VOLTAGE FOR LONG HAUL TRANSMISSION
SYSTEMS WITH FEC
Karstensen H, Rozmann M, Bonthron A, Albers J. Multilink
Technology GmbH, Germany.
P2.32
4:1 MULTIPLEXER AND 1:4 DEMULTIPLEXER CHIPSET FOR
DATA RATES UP TO 50 Gb/s IN SiGe
TECHNOLOGY
Adamczyk O H, Woyciehowsky S P, Binkley J M, Otero A E,
Rozmann M, Albers J IM. Multilink Technology Corporation, USA
Systems technologies
P3.1
MODIFIED DUOBINARY SIGNAL GENERATION IN A MACH-
ZEHNDER MODULATOR WITH COUNTER-PROPAGATING OP¬
TICAL AND ELECTRICAL FIELDS
Enning B, Jagst V P. University of Applied Sciences, Germany
P3.2
ULTRA LOW TIMING JITTER OPTICAL SAMPLING SYSTEM
USING PASSIVELY MODE-LOCKED FIBER LASER
Yamada N, Ohta H, Nogiwa S. ANDO Electric Co. Ltd., Japan
P3.3
FIELD TRIAL OF OPTICAL DUOBINARY TRANSMISSION OVER
1720km At lOGb/s
Kaiser WO), Ehrhardt A(2), Rosenkranz W(1), Hanik N(2).
1: University of Kiel, Germany. 2: T-Systems Nova GmbH, Germany
P3.4
THE IMPACT OF POLARIZATION MODE DISPERSION (PMD)
ON OPTICAL DUOBINARY TRANSMISSION
Carena A, Curri V, Gaudino R, Poggiolini P. Dipartimento di
Elettronica, Politecnico di Torino, Italy
P3.5
OPTIMIZED POLARIZATION SCRAMBLERS FOR PMD DETEC¬
TION
Mirvoda V, Sandel D, Wust F, No6 R. University Paderbom, Ger¬
many
P3.6
PERIODIC POLARIZATION SCRAMBLING WITH UNIFORMLY
DISTRIBUTED SOPS ON THE POINCARE SPHERE
Yan L-S, Yu Q, Willner A E.University of Southern California, USA
P3.7
ON THE USE OF NRZ, RZAND CSRZ MODULATION FORMATS
FOR ULTRA-DENSEWDM AT 40 GBIT/S
Bosco G, Carena A, Curri V, Gaudino R, Poggiolini P. Diparimento
di Elettronica, Politecnico di Torino, Italy
Volume 3 - table of contents
P3.8
OPTIMUM SPLITTING RATIO FOR AMPLIFIER NOISE REDUC¬
TION BY AN ASYMMETRIC NONLINEAR OPTICAL LOOP MIR¬
ROR
Meissner M(1), Rdsch M(1), Korolkova N(1), Sizmann A(2),
Schmauss B(1), Leuchs G(1).1: Friedrich Alexander University,
Germany. 2: Innovance Networks, Canada
P3.9
lOGbit/sWAVELENGTHCONVERTER-RESHAPERBASEDON
MULTI-WAVELENGTHS SPECTRAL COMPONENTS GENERA¬
TION IN OPTICAL FIBRE
Tosi-Beleffi G M, Curti F, Matera F. Fondazione Ugo Bordoni, Italy
P3.10
DETERMINING AND MINIMISING PMD-INDUCED IMPAIR¬
MENTS IN WDM SYSTEMS WITH POLARISATION INTERLEAV¬
ING
Ciaramella E. CNIT, Italy
P3.11
OPTIMISATION OF A POLARISATION MULTIPLEXED SCHE¬
ME AT 1.28bit/s/Hz INFORMATION SPECTRAL DENSITY
Lanne S, Frignac Y, Charlet G, Idler W(1), Bigo S, Alcatel R&l,
France. (1) Alcatel R&l, Germany
P3.12
ALL-OPTICAL PASSIVE 2R REGENERATION FOR NX40 GBIT/S
WDM TRANSMISSION USING NOLM AND NOVEL FILTERING
TECHNIQUE
Boscolo S, Turitsyn S K, Blow K J. Aston University, UK
P3.13
MONITORING OF TRANSMISSION IMPAIRMENTS IN LONG-
HAUL TRANSMISSION SYSTEMS USING THE NOVEL DIGITAL
CONTROL MODULATION TECHNIQUE
Rohde M, Bachus E-J, Raub F. Heinrich-Hertz-lnstitut, Germany
P3.14
OPTICAL REGENERATION OF 40 Gb/s TRANSMISSION OVER
SMF USING PERIODIC BANDWIDTH MANAGEMENT OF DM
SOLITONS
WaiyapotS, Mezentsev V K, Turitsyn S K. Aston University, UK
P3.15
SHORT PERIOD DISPERSION MANAGEMENT OF 160 GB/S
SINGLE CHANNEL FIBER SYSTEM
XuZO), PeucheretCO), Le Q(2), Jeppesen P(1). 1: COM, Techni¬
cal University of Denmark. 2: OFS Fitel Denmark l/S, Denmark
P3.16
INTERPLAY OF FIBER NON-LINEARITY AND OPTICAL FILTER¬
ING IN ULTRA-DENSE WDM
Lyubomirsky I, Qiu T, Roman J, Nayfeh M, Frankel M, Taylor M G.
CIENA Corporation, USA
P3.17
NOVEL DISPERSION-BASED OPTICAL DELAY LINE USING
ARRAYED WAVEGUIDE GRATING FOR ANTENNA
BEAMFORMING APPLICATIONS
Vidal B, Madrid D, Corral J L, Polo V, Marti J. Polytechnic Univer¬
sity of Valencia, Spain
P3.18
BENEFITS OF BIT-TO-BIT POLARISATION INTERLEAVING FOR
NX40GBIT/S ALL-DISTRIBUTED RAMAN AMPLIFIED SUBMA¬
RINE TRANSMISSION
Le Meur G, Corbel E. Alcatel R&l, France
P3.19
ADAPTIVE CODE LENGTH FEC FOR UNCOMPENSATED MET¬
ROPOLITAN 320 GB/S DWDM NETWORKS
Lee H, Kim C, Kim Y, Park S, Kim B, Koh J, Hwang S,
Oh Y, Kang B. Samsung Electronics, Korea
P3.20
PRODUCT CODES FOR OPTICAL COMMUNICATION
Andersen J D. COM Technical University of Denmark, Denmark
P3.21
NOVEL SLOPE COMPENSATED DCF FOR NZDSF PERMITS
BROAD CAPACITY INCREASE FOR FUTURE PROOF ULTRA-
LONG HAULWDM SYSTEMS
Caspar C(1), Raub F(1), Bachus E-J(1), Breuer D(2), Hanik N(2),
McLeod S(3), Edwards M(3).1: Heinrich Hertz Institut, Germany.
2: T-Systems Nova, Germany. 2: Corning Optical Fiber, UK
P3.22
MODULATION FORMAT COMPARISON BETWEEN CHIRPED-
RZ AND CHIRPED-NRZ IN 37.5GHz SPACED 32 X 11.4Gbit/s
LONG-HAUL TRANSMISSION USING NON-ZERO DISPERSION
SHIFTED FIBRE SPAN
Yamauchi H, Shibano E, Taga H, Goto K. KDDI Submarine Cable
System Inc., Japan
P3.23
ENABLING C AND L BAND ULH TRANSMISSION BY MITIGAT¬
ING RAMAN PUMP FWM
Gertsvolf M, Pourbahri B, Harvey H J, Robinson A M, Luo B S,
Parent A. Ceyba Inc., Canada
P3.24
PERFORMANCE COMPARISON OF 4Nx40 Gb/s AND Nx160
Gb/s TRANSMISSION SYSTEMS
HodzicA, Konrad B, Randel S, Petermann K. Technical University
of Berlin, Germany
Volume 3 - table of contents
P3.25
DETAILED MODELING AND EXPERIMENTAL INVESTI-GATION
OF40 Gb/s MULTI-SPAN TRANSMISSION SYSTEMS IN STAND¬
ARD SMF FOR NRZ AND RZ MODULATION
BuxensA, Olesen D, Ellegaard L(1), Birk M, Brodsky M, Frigo N,
(2), Jeppesen P(3). 1: Tellabs Denmark, Denmark. 2: AT&T Labs-
Research, USA. 3: COM,Technical University of Denmark, Den¬
mark
P3.26
IMPACT OF SIGNAL DISTORTIONS ON SYSTEMS USING FEC
RethertJd), de Arruda Mello D A(2), FOrst C(1).1: Siemens AG,
Germany. 2: Munich University, Germany
P3.27
LDPC CODES FOR LONG HAUL OPTICAL COMMUNICATIONS
VasicB, Djordjevic I B. University of Arizona, USA
P3.28
WDM-TRANSMISSION OVER MIXED FIBER INFRASTRUC¬
TURES
BreuerDO), Hanik N<1), Caspar C(2), Raub F(2), Bramann G(2),
Rohde M(2), Bachus E-J(2), McLeod S(3), Edwards M(3). 1: T-Sys-
tems Nova, Germany. 2: Heinrich Hertz Institute, Germany.
3: Corning Optical, Fiber, UK.
P3.29
NONLINEAR PENALTY REDUCTION OF RZ-DBPSK VERSUS RZ-
OOK MODULATION FORMAT IN FIBER COMMUNICATIONS
Grigoryan VS, Cho P S, Shpantzer I, CeLight Inc., USA
P3.30
ANALYSIS OF BI-DIRECTIONAL AND SECOND-ORDER PUMP¬
ING IN LONG-HAUL SYSTEMS WITH DISTRIBUTED RAMAN
AMPLIFICATION
Martinelli C, Mongardien D, Antona J C, Simonneau C, Bayart D.
Alcatel R&l, France
P3.31
INFLUENCE OF BITWISE PHASE CHANGES ON THE PERFORM¬
ANCE OF 160 Gbit/s TRANSMISSION SYSTEMS
RandelS, Konrad B, HodzicA, Petermann K.Technical University
Berlin, Germany
P3.32
REDUCTION OF CHROMATIC DISPERSION EFFECTS AND
LINEARIZATION OF DUAL-DRIVE MACH-ZEHNDER MODU¬
LATOR BY USING SEMICONDUCTOR OPTICAL AMPLIFIER IN
ANALOG OPTICAL LINKS
Lee S-Y, Koo B-J, Jung H-D, Han S-K. Yonsei University, Korea
P3.33
BIDIRECTIONAL TRANSMISSION OF 32-QAM RADIO OVER
A SINGLE MULTIMODE FIBRE USING 850-nm VERTICAL-CAV¬
ITY HALF-DUPLEX TRANSCEIVERS
InghamJD(l). Webster M(1), Wake D(2), SeedsAJ(2), Penty R
V(1), White I H(1). 1: University of Cambridge, UK. 2: University
College London, UK
Networks and switching
P4.1
A NOVEL LABEL ERASER BASED ON LYOT-SAGNAC FILTER
Jia Z, Chen M, Xie S. Tsinghua University, China
P4.2
ASTUDY OF GAIN DYNAMICS OF ERBIUM-DOPED FIBER AM¬
PLIFIERS FOR BURST OPTICAL SIGNALS
ShiozakiX Fuse M, Morikura S. Matsushita Electric Industrial Co,
Ltd., Japan
P4.3
TOWARDS ALL-OPTICAL LOGICS OPERATING AT 1Tbit/s US¬
ING A SEMICONDUCTOR OPTICAL AMPLIFIER
YangX(1), Lenstra D(1,2), Dorren H J S(1). 1: Eindhoven Univer¬
sity of Technology, The Netherlands.2: Vrije University, The Neth¬
erlands
P4.4
A NEW ALL OPTICAL LABEL SWAPPING METHOD BASED ON
OPTICAL FSK HEADER ENCODING ON THE INTENSITY
MODULATED PAYLOAD
Lallas E, Skarmoutsos N, Syvridis D. University of Athens, Greece
P4.5
ULTRAFAST OPTICAL-DOMAIN PATH SETUP FOR OPTICAL
BURST SWITCHING USING OPTICAL-CODE BASED HEADER
PROCESSING
Kitayama K, Arakawa S, Murata M. Osaka University, Japan
P4.6
OPTICAL PACKET SWITCH MODELLING AND ITS
TRAFFIC SHAPING EFFECTS
Lam C, Simeonidou D. University of Essex, UK
P4.7
A SCALABLE OPTICAL PACKET SWITCH FOR VARIABLE
LENGTH PACKETS EMPLOYING SHARED ELECTRONIC BUFF¬
ERING
Bjeirnstad S, Hjelme D R, Stol N. Norwegian University of Science
and Technology, Norway
Volume 3 - table of contents
P4.8
ALL OPTICAL N-BIT XOR GATE WITH FEEDBACK FOR OPTI¬
CAL PACKET HEADER PROCESSING
MartinezJ M, Ramos F, Marti J, Herrera J, Llorente R. Universidad
Politecnica de Valencia, Spain
P4.9
A MINIMUM INTERFERENCE ROUTING ALGORITHM FOR
MULTI-PERIOD PLANNING OFWDM LIGHTPATH NETWORKS
WITHOUT TRAFFIC PREDICTION
Fukushima Y(1), Harai H(2), Arakawa S-i(1), Murata M(1).Miyahara
H(1). 1: Osaka University, Japan. 2: Communacations Research
Laboratory, Japan
P4.10
ALL-OPTICAL ADDRESS AND DATA SEPARATION FOR 10 Gb/
s PACKETS
PlerosNO), Bintjas C(1), Yiannopoulos K(1), Theophilopoulos G(1),
Kalyvas M(1), Vyrsokinos K(1), Avramopoulos H,(1), Guekos G(2).
1: National Technical University of Athens, Greece. 2: Swiss Fed¬
eral Institute of Tecnology, Switzerland
P4.11
PROTOCOL INTERWORKING IN THE CONTROL PLANE OF
TRANSPARENT ASONs
BuchwieserA, Goeger G, Fischler W, Haebel U, Nathansen M,
Schluter P, Stilling B. Siemens AG, Germany
P4.12
BPR ARCHITECTURE FOR DWDM/SCM FIBER-WIRELESS AC¬
CESS NETWORKS
Lin W-PO), Chi S(2). 1: Chien-Kuo Institute of Technology, Taiwan.
2: National Chiao-Tung University, Taiwan
P4.13
ARCHITECTING SELF-TUNING OPTICAL NETWORKS
Acharya S, Chang Y-J, Gupta B, Risbood P, Srivastava A. Lucent
Technologies Inc., USA
P4.14
FAST WAVELENGTH SELECTIVE ELECTROHOLOGRA-PHIC
SWITCHING FOR BURST SWITCHING APPLICATIONS
AgranatA JO,2), Secundo L(2), Bartal G(2). 1: Trellis Photonics
Ltd., Israel.2: The Hebrew University of Jerusalem, Israel
P4.15
FIELD DEMONSTRATION OF A SIMPLE & LOW-COST METRO
AREA NETWORK INTERCONNECTION USING AGBICTRANS-
CEIVER WITH A DIRECTLY MODULATED LASER OVER
1700KM DWDM LINK
Braun R-P, Ehrhardt A, Szuppa S, Haase R, Gladisch A. T-SystemsNova GmbH, Germany
P4.16
ROUTING AND WAVELENGTH ASSIGNMENT WITH QUAL-
ITY-OF-SIGNAL CONSTRAINTS IN WDM NETWORKS
Huang Y G, Gengata A, Heritage J P, Mukherjee B. University of
California, USA
P4.17
OPTIMAL CONFIGURATION OF OPTICAL LINE SYSTEMS UN¬
DER VARIOUS CONSTRAINTS
Alicherry M, Gogate S, Nagesh H, Poosala V. Lucent Technolo¬
gies, USA
P4.18
PROTECTING IP BACKBONE: MPLS VS. OPTICAL MESH RE¬
STORATION
Sengupta S, Sana D, Bontu S. Srinivas Bontu Tellium Inc., USA
P4.19
CATZ (CAPACITY ALLOCATION WITH TIME ZONES): A METH¬
ODOLOGY FOR COST-EFFICIENT BANDWIDTH ALLOCATION
AND RECONFIGURATION IN A WORLD-WIDE WDM NET¬
WORK
Gencata A(1,2), Mukherjee B(1). 1: University of California, USA.
2: Istanbul Technical University
P4.20
HELIOS: AN ALL-OPTICAL BROADCAST LAN ARCHITECTURE
Jackson L E, Baldine I. MCNC, USA
P3.16
INTERPLAY OF FIBER NON-LINEARITY AND OPTICAL FILTER¬
ING IN ULTRA-DENSE WDM
Lyubomirsky I, Qiu T, Roman J, Nayfeh M, Frankel M, Taylor M G.
CIENA Corporation, USA
P3.17
NOVEL DISPERSION-BASED OPTICAL DELAY LINE USING
ARRAYED WAVEGUIDE GRATING FOR ANTENNA BEAM-
FORMING APPLICATIONS
VidalB, Madrid D, Corral J L, Polo V, Martf J.Polytechnic Univer¬
sity of Valencia, Spain
P3.18
BENEFITS OF BIT-TO-BIT POLARISATION INTERLEAVING FOR
NX40GBIT/S ALL-DISTRIBUTED RAMAN AMPLIFIED SUBMA¬
RINE TRANSMISSION
Le Meur G, Corbel E. Alcatel R&l, France
P3.19
ADAPTIVE CODE LENGTH FEC FOR UNCOMPENSATED MET¬
ROPOLITAN 320 GB/S DWDM NETWORKS
Lee H, Kim C, Kim Y, Park S, Kim B, Koh J, Hwang S, Oh Y, Kang
B, Samsung Electronics, Korea
Volume 3 - table of contents
P3.20
PRODUCT CODES FOR OPTICAL COMMUNICATION
Andersen J D. COM Technical University of Denmark, Denmark
P3.21
NOVEL SLOPE COMPENSATED DCF FOR NZDSF PERMITS
BROAD CAPACITY INCREASE FOR FUTURE PROOF ULTRA-
LONG HAULWDM SYSTEMS
Caspar CO), Raub F(1), Bachus E-J(1), Breuer D(2), Hanik N(2),
McLeod S(3), Edwards M(3). 1: Heinrich Hertz Institut, Germany.
2: T-Systems Nova, Germany. 2: Corning Optical Fiber, UK
P3.22
MODULATION FORMAT COMPARISON BETWEEN CHIRPED-
RZ AND CHIRPED-NRZ IN 37.5GHz SPACED 32 X 11.4Gbit/s
LONG-HAULTRANSMISSION USING NON-ZERO DISPERSION
SHIFTED FIBRE SPAN
YamauchiH, Shibano E, Taga H, Goto K.KDDI Submarine Cable
System Inc., Japan
P3.23
ENABLING C AND L BAND ULH TRANSMISSION BY MITIGAT¬
ING RAMAN PUMP FWM
Gertsvolf M, Pourbahri B, Harvey H J, Robinson A M, Luo B S,
Parent A. Ceyba Inc., Canada
P3.24
PERFORMANCE COMPARISON OF 4Nx40 Gb/s AND Nx160
Gb/s TRANSMISSION SYSTEMS
HodzicA, Konrad B, Randel S, Petermann K.Technical University
of Berlin, Germany
P3.25
DETAILED MODELING AND EXPERIMENTAL INVESTI-GATION
OF 40 Gb/s MULTI-SPAN TRANSMISSION SYSTEMS IN STAND¬
ARD SMF FOR NRZ AND RZ MODULATION
BuxensA, Olesen D, Ellegaard L(1), Birk M, Brodsky M, Frigo N,
(2), Jeppesen P(3).1: Tellabs Denmark, Denmark. 2: AT&T Labs-
Research, USA. 3: COM,Technical University of Denmark, Den¬
mark
P3.26
IMPACT OF SIGNAL DISTORTIONS ON SYSTEMS
USING FEC
ReichertJ(l), de Arruda Mello D A(2), FQrst C(1). 1: Siemens AG,
Germany. 2: Munich University, Germany
P3.27
LDPC CODES FOR LONG HAUL OPTICAL COMMUNICATIONS
Vasic B, Djordjevic I B. University of Arizona, USA
P3.28
WDM-TRANSMISSION OVER MIXED FIBER INFRASTRUC¬
TURES
BreuerD(1), Hanik NO), Caspar C(2), Raub F(2), Bramann G(2),
Rohde M(2), Bachus E-J(2), McLeod S(3), Edwards M(3). 1: T-Sys-tems Nova, Germany. 2: Heinrich Hertz Institute, Germany.
3: Corning Optical, Fiber, UK.
P3.29
NONLINEAR PENALTY REDUCTION OF RZ-DBPSK VERSUS RZ-
OOK MODULATION FORMAT IN FIBER COMMUNICATIONS
Grigoryan VS, Cho P S, Shpantzer I. CeLight Inc., USA
P3.30
ANALYSIS OF BI-DIRECTIONAL AND SECOND-ORDER PUMP¬
ING IN LONG-HAUL SYSTEMS WITH DISTRIBUTED RAMAN
AMPLIFICATION
Martinelli C, Mongardien D, Antona J C, Simonneau C, Bayart D.
Alcatel R&l, France
P3.31
INFLUENCE OF BITWISE PHASE CHANGES ON THE PERFORM¬
ANCE OF 160 Gbit/s TRANSMISSION SYSTEMS
RandelS, Konrad B, HodzicA, Petermann K.Technical University
Berlin, Germany
P3.32
REDUCTION OF CHROMATIC DISPERSION EFFECTS AND
LINEARIZATION OF DUAL-DRIVE MACH-ZEHNDER MODU¬
LATOR BY USING SEMICONDUCTOR OPTICAL AMPLIFIER IN
ANALOG OPTICAL LINKS
Lee S-Y, Koo B-J, Jung H-D, Han S-K. Yonsei University, Korea
P3.33
BIDIRECTIONAL TRANSMISSION OF 32-QAM RADIO OVER
A SINGLE MULTIMODE FIBRE USING 850-nm VERTICAL-CAV¬
ITY HALF-DUPLEX TRANSCEIVERS
Ingham J DO), Webster M(1), Wake D(2), Seeds A J(2>, Penty R
V(1), White I H(1). 1: University of Cambridge, UK. 2: University
College London, UK
Networks and switching
P4.1
A NOVEL LABEL ERASER BASED ON LYOT-SAGNAC FILTER
JiaZ, Chen M, Xie S. Tsinghua University, China
P4.2
ASTUDY OF GAIN DYNAMICS OF ERBIUM-DOPED FIBER AM¬
PLIFIERS FOR BURST OPTICAL SIGNALS
Shiozaki X, Fuse M, Morikura S.Matsushita Electric Industrial Co.
Ltd., Japan
Volume 3 - table of contents
P4.3
TOWARDS ALL-OPTICAL LOGICS OPERATING AT 1Tbit/s US¬
ING A SEMICONDUCTOR OPTICAL AMPLIFIER
YangXO), Lenstra D(1,2), Dorren H J SO). 1: Eindhoven Univer¬
sity of Technology, The Netherlands. 2: Vrije University, The Neth¬
erlands
P4.4
A NEW ALL OPTICAL LABEL SWAPPING METHOD BASED ON
OPTICAL FSK HEADER ENCODING ON THE INTENSITY MO¬
DULATED PAYLOAD
Laltas E, Skarmoutsos N, Syvridis D, University of Athens, Greece
P4.5
ULTRAFAST OPTICAL-DOMAIN PATH SETUP FOR OPTICAL
BURST SWITCHING USING OPTICAL-CODE BASED HEADER
PROCESSING
Kitayama K, Arakawa S, Murata M. Osaka University, Japan
P4.6
.
OPTICAL PACKET SWITCH MODELLING AND ITS TRAFFIC
SHAPING EFFECTS
Lam C, Simeonidou D. University of Essex, UK
P4.7
A SCALABLE OPTICAL PACKET SWITCH FOR VARIABLE
LENGTH PACKETS EMPLOYING SHARED ELECTRONIC BUFF¬
ERING
BjornstadS, Hjelme D R, Stol N. Norwegian University of Science
and Technology, Norway
P4.8
ALL OPTICAL N-BIT XOR GATE WITH FEEDBACK FOR OPTI¬
CAL PACKET HEADER PROCESSING
MartinezJ M, Ramos F, Marti J, Herrera J, Llorente R. Universidad
Politecnica de Valencia, Spain
P4.9
A MINIMUM INTERFERENCE ROUTING ALGORITHM FOR
MULTI-PERIOD PLANNING OFWDM LIGHTPATH NETWORKS
WITHOUT TRAFFIC PREDICTION
Fukushima YO), Harai H(2), Arakawa S-i(1), Murata M(1).Miyahara
H(1). 1: Osaka University, Japan. 2: Communacatlons Research
Laboratory, Japan
P4.10
ALL-OPTICAL ADDRESS AND DATA SEPARATION FOR 10G/S
PACKETS
PlerosNO), BintjasCO), YiannopoulosK(1),TheophilopoulosG(1),
Kalyvas M(1), Vyrsokinos K(1), Avramopoulos H,(1), Guekos G(2).
1: National Technical University of Athens, Greece. 2: Swiss Fed¬
eral Institute of Tecnology, Switzerland
P4.11
PROTOCOL INTERWORKING IN THE CONTROL PLANE OF
TRANSPARENT ASONs
BuchwieserA, Goeger G, Fischler W, Haebel U, Nathansen M,
Schiuter P, Stilling B. Siemens AG, Germany
P4.12
BPR ARCHITECTURE FOR DWDM/SCM FIBER-WIRELESS AC¬
CESS NETWORKS
Lin W-P(1), Chi S(2). 1: Chien-Kuo Institute of Technology, Taiwan.
2: National Chiao-Tung University, Taiwan
P4.13
ARCHITECTING SELF-TUNING OPTICAL NETWORKS
Acharya S, Chang Y-J, Gupta B, Risbood P, Srivastava A.
Lucent Technologies Inc., USA
P4.14
FAST WAVELENGTH SELECTIVE ELECTROHOLOGRA-PHIC
SWITCHING FOR BURST SWITCHING
APPLICATIONS
Agranat A JO,2), Secundo L(2), Bartai G(2). 1: Trellis Photonics
Ltd., Israel. 2: The Hebrew University of Jerusalem, Israel
P4.15
FIELD DEMONSTRATION OF A SIMPLE & LOW-COST METRO
AREA NETWORK INTERCONNECTION USING A GBIC TRANS¬
CEIVER WITH A DIRECTLY MODULATED LASER OVER
1700KM DWDM LINK
Braun R-P, Ehrhardt A, Szuppa S, Haase R, Gladisch A. T-SystemsNova GmbH, Germany
P4.16
ROUTING AND WAVELENGTH ASSIGNMENT WITH QUAL-
ITY-OF-SIGNAL CONSTRAINTS IN WDM NETWORKS
Huang YG, Gengata A, Heritage J P, Mukherjee B. University of
California, USA
P4.17
OPTIMAL CONFIGURATION OF OPTICAL LINE SYSTEMS UN¬
DER VARIOUS CONSTRAINTS
Alicherry M, Gogate S, Nagesh H, Poosala V, Lucent Technolo¬
gies, USA
P4.18
PROTECTING IP BACKBONE: MPLS VS. OPTICAL MESH RES¬
TORATION
Sengupta S, Saha D, Bontu S. Srinivas Bontu Tellium Inc., USA
Volume 3 - table of contents
P4.19
CATZ (CAPACITY ALLOCATION WITH TIME ZONES): A METH¬
ODOLOGY FOR COST-EFFICIENT BANDWIDTH ALLOCATION
AND RECONFIGURATION IN A WORLD-WIDE WDM NET¬
WORK
Gencata A0,2), Mukherjee B(1). 1: University of California, USA.
2: Istanbul Technical University
P4.20
HELIOS: AN ALL-OPTICAL BROADCAST LAN ARCHITECTURE
Jackson L E, Baldine I. MCNC, USA