Introduction |
Introduction (Part I) / Part I: |
Novel Transponder Interfaces: Novel Modulation Formats / 1: |
Transmission of 8-Level 240 Gb/s RZ-DQPSK-ASK / 1.1: |
Four Bits per Symbol 16-ary Transmission Experiments / 1.3: |
Optical Rate Conversion Units / 1.4: |
Optical Packet Compression and Expansion / 1.4.1: |
Optical Compression/Expansion Loop / 1.4.2: |
Optical Delay Line Structure / 1.4.3: |
Scalable Packet Compression/Expansion Units / 1.4.4: |
Transmission Efficiency / 1.4.5: |
References |
Electronic Channel Equalization Techniques / 2: |
Electronic Equalizers / 2.1: |
Fundamental Limits of MLSE Performance with Large Number of States / 2.3: |
No PD-Filter, 8 Samples/Bit / 2.3.1: |
With PD-Filter, 2 Samples/Bit / 2.3.2: |
Large Optical Filter, 2 Samples/Bit / 2.3.3: |
Large Optical Filter, 1 Sample/Bit / 2.3.4: |
Compensation of SPM Using MLSE / 2.3.5: |
Nonlinear Electrical Equalization for Different Modulation Formats / 2.4: |
Introduction of NL-FFE-DFE / 2.4.1: |
System Setups and Parameters / 2.4.2: |
EDC Performance for Different Modulation Formats / 2.4.3: |
Optical Single Sideband Modulation / 2.5: |
Compensation of Optical Dispersion / 2.5.1: |
Reduction of Nonlinear Transmission Effects / 2.5.2: |
Enhancing the Performance DML Transmitters / 2.6: |
Conclusions / 2.7: |
Optical Signal Processing Techniques for Signal Regeneration and Digital Logic / 3: |
Optical Regeneration and Wavelength Conversion / 3.1: |
640 Gbit/s Wavelength Conversion Based on XPM in HNLF / 3.1.1: |
Wavelength Conversion and Regeneration Based on Supercontinuum Generation / 3.1.2: |
Multi-Wavelength Conversion at 10 Gb/s and 40 GHz Using a Hybrid Integrated SOA Mach-Zehnder Interferometer / 3.1.3: |
All-Optical Multi-Wavelength Regeneration Based on Quantum-Dot Semiconductor Optical Amplifiers for High Bit Rates / 3.1.4: |
Optoelectronic Clock Recovery, Retiming and OTDM Demultiplexing / 3.2: |
320 Gbit/s Clock Transmission and Channel Identification / 3.2.1: |
Filtering-Assisted Cross-Phase Modulation in a Semiconductor Optical Amplifier Enabling 320 Gb/s Clock Recovery / 3.2.2: |
640 Gbit/s Data Transmission and Clock Recovery Using an Ultra-Fast Periodically Poled Lithium Niobate Device / 3.2.3: |
All-Optical Clock Extraction Circuit Based on a Mode-Locked Ring Laser Comprising SOA and FP Filter / 3.2.4: |
OTDM Demux Based on Induced Modulation on an Auxiliary Carrier by Means of Super-Continuum Generation / 3.2.5: |
160 Gb/s Retiming Using Rectangular Pulses Generated Using a Superstructured Fibre Bragg Grating / 3.2.6: |
Timing Jitter Tolerant 640 Gb/s Demultiplexing Using a Long-Period Fibre Grating-Based Flat-Top Pulse Shaper / 3.2.7: |
Evolution of Optical Access Networks / 4: |
Introduction: FTTX Developments / 4.1: |
FTTX Architectures / 4.1.1: |
Current Standard PON Deployment Worldwide / 4.1.2: |
Emerging Standards for 100 Gbit Ethernet Access and Beyond / 4.2: |
Introduction - Why Higher Speed Ethernet? / 4.2.1: |
100 Gbit Ethernet Challenges / 4.2.2: |
Transparent Optical Transmission For 100 Gbit Ethernet / 4.2.3: |
Future Directions / 4.2.4: |
Interoperability of TDM and WDM PONs / 4.3: |
Network Architecture / 4.3.1: |
Network Routing Performance / 4.3.3: |
3G Radio Distribution over Fibre / 4.3.4: |
Optical Wireless for Last Mile Access / 4.4.1: |
FSO Networks / 4.5.1: |
Propagation Results / 4.5.3: |
Dynamic Bandwidth Allocation Protocols over GPONs / 4.5.4: |
Dynamic Bandwidth Allocation Protocols / 4.6.1: |
Innovative Architecture and Control Plane for Metro-Access Convergence / 4.6.3: |
Motivation for Metro-Access Convergence / 4.7.1: |
Unified Metro-Access Networks Criteria / 4.7.2: |
A Few Examples of Unified Metro-Access Networks (UMAN) / 4.7.3: |
The Success + Network / 4.7.4: |
The Success + Network Topology / 4.7.5: |
The Success + UMAN Control Plane / 4.7.6: |
Conclusion / 4.7.7: |
Protection Schemes for PONs / 4.8: |
Evolution of PON Protection Schemes / 4.8.1: |
Recent PON Protection Architectures / 4.8.2: |
Hybrid WDM/TDM PON / 4.8.3: |
Reliability Performance Evaluation / 4.8.4: |
Novel Switch Architectures / 5: |
Application of Quantum-Dot SOAs for the Realization of All-Optical Buffer Architectures up to 160 Gb/s / 5.1: |
Multiwavelength Optical Buffers / 5.3: |
New Buffer Architectures / 5.3.1: |
Scheduling Algorithms / 5.3.2: |
Performance Evaluation / 5.3.3: |
Multi-Stage Optical Switches with Optical Recirculation Buffers / 5.4: |
The Switching Fabric Architecture / 5.4.1: |
Scheduling Algorithms for the Single-Stage Shared FDL Switch / 5.4.2: |
Scheduling Algorithms for the Three-Stage Shared FDL Optical Clos-Network Switch / 5.4.3: |
Simulation Experiments / 5.4.4: |
Optical Asynchronous Packet Switch Architectures / 5.5: |
All-Optical Buffer Technologies / 5.5.1: |
Node Architectures / 5.5.2: |
Future Outlook (Part I) / 5.5.3: |
Introduction (Part II) / Part II: |
Cross-Layer Optimization Issues for Realizing Transparent Mesh Optical Networks / 6: |
An Impairment Aware Networking Approach for Transparent Mesh Optical Networks / 6.1: |
Transparent Optical Network Challenges / 6.1.1: |
Proposed Approach / 6.1.3: |
Mutual Impact of Physical Impairments and Traffic Grooming Capable Nodes with Limited Number of O/E/O / 6.2: |
Motivation / 6.2.1: |
Modelling the Physical Layer Impairments / 6.2.2: |
The Routing Model / 6.2.3: |
Simulation Results / 6.2.4: |
Performance Issues in Optical Burst/Packet Switching / 6.3: |
OBS/OPS Performance / 7.1: |
Introduction and State-of-the-Art / 7.2.1: |
On the Use of Balking for Estimation of the Blocking Probability for OBS Routers with FDL Lines / 7.2.2: |
A Performance Comparison of Synchronous Slotted OPS Switches / 7.2.3: |
A Performance Comparison of OBS and OpMiGua Paradigms / 7.2.4: |
Burstification Mechanisms / 7.3: |
Delay-Throughput Curves for Timer-Based OBS Burstifiers with Light Load / 7.3.2: |
Performance Evaluation of Adaptive Burst Assembly Algorithms in OBS Networks with Self-Similar Traffic Sources / 7.3.3: |
QoS Provisioning / 7.4: |
Performance Overview of QoS Mechanisms in OBS Networks / 7.4.1: |
Evaluation of Preemption Probabilities in OBS Networks with Burst Segmentation / 7.4.3: |
Routing Algorithms / 7.5: |
Optimization of Multi-Path Routing in Optical Burst Switching Networks / 7.5.1: |
TCP over OBS Networks / 7.6: |
Burst Reordering Impact on TCP over OBS Networks / 7.6.1: |
Multi-layer Traffic Engineering (MTE) in Grooming Enabled ASON/GMPLS Networks / 7.7: |
Routing and Grooming in Multi-layer Networks / 8.1: |
Basic Schemes / 8.2.1: |
Adaptive Integrated Multi-layer Routing / 8.2.2: |
Simulation Study / 8.2.3: |
Improvements for Multi-layer Routing and Grooming Schemes / 8.3: |
Online Optimization at Connection Teardown / 8.3.1: |
Admission Control for Improving Fairness / 8.3.2: |
Evaluation of Traffic and Network Patterns / 8.4: |
Network Resilience in Future Optical Networks / 9: |
Terminology / 9.1: |
Basic Resilience Techniques and Failure Management / 9.3: |
Resilient Network Performance Improvement, Evaluation Methods and Parameters / 9.4: |
Availability Calculation in Optical Network / 9.4.1: |
Recovery Time / 9.4.2: |
Network Performance Improvement through Differentiated Survivability / 9.4.3: |
Security Issues in Transparent Optical Networks / 9.5: |
Multilayer Resilience / 9.6: |
Single Layer Recovery in Multilayer Networks / 9.6.1: |
Interworking between Layers / 9.6.2: |
Multilayer Survivability Strategies / 9.6.3: |
Logical Topology Design / 9.6.4: |
Optical Storage Area Networks / 9.7: |
Storage Area Networks (SANS) / 10.1: |
Data Mirroring Techniques / 10.1.2: |
Network Architectures / 10.2: |
Proposed Mirroring Technique / 10.3: |
Single Section Ring Architecture / 10.4: |
Two Sections Ring Architecture / 10.4.2: |
Future Outlook (Part II) / 10.5: |
Introduction (Part III) / Part III: |
Software Tools and Methods for Modelling Physical Layer Issues / 11: |
Modelling of Optoelectronic Components (Lasers and Semiconductor Optical Amplifiers) / 11.1: |
Frequency-Domain Approaches / 11.1.1: |
Time-Domain Models / 11.1.3: |
Lumped-Element Models / 11.1.4: |
Distributed Time-Domain Models / 11.1.5: |
Modeling of Hybrid Mode-Locked Lasers / 11.1.6: |
Modelling of Travelling-Wave Semiconductor Optical Amplifiers / 11.1.7: |
Simulation Tool MOVE-IT / 11.2: |
Numerical Models for Simulation of Transient Effect in Raman Fibre Amplifiers / 11.3: |
Split-Step-Fourier-Method in Modeling of WDM Links / 11.4: |
Pre-simulated Local Errors S-SSMF / 11.4.1: |
Results / 11.4.2: |
Software Tools and Methods for Research and Education in Optical Networks / 11.4.3: |
Models and Simulations / 12.1: |
Modelling / 12.1.1: |
Simulation Techniques / 12.1.2: |
Simulation and Model Verification / 12.1.3: |
Summary on Modelling / 12.1.4: |
Tool Integration Perspectives / 12.2: |
Integration: Definitions / 12.2.1: |
Obstacles to Integration and Possible Diversions / 12.2.2: |
Conclusions and Future Outlook / 12.2.3: |
Modelling with OPNET: A Practical Example / 12.3: |
OPNET Domains / 12.3.1: |
The OPNET Project Editor / 12.3.2: |
Developing Models with OPNET: Conclusion / 12.3.3: |
Simulation of ASON/GMPLS Using OMNET++ Simulator / 12.4: |
The OMNET Simulator and the INET Framework / 12.4.1: |
IP/MPLS over ASON/GMPLS Simulator / 12.4.2: |
WDM Network Planning: The MatPlanWDM Tool / 12.4.3: |
Distinctions Between Planning Problems / 12.5.1: |
Integrated Tool / 12.5.2: |
Extension of the Tool / 12.5.3: |
The Javanco Environment / 12.6: |
History and Predecessors / 12.6.1: |
General Architecture / 12.6.2: |
Utilisations / 12.6.3: |
Future Developments and Conclusion / 12.6.4: |
IKR Simulation Library / 12.7: |
Conceptual Structure / 12.7.1: |
Libraries / 12.7.2: |
Application of the Simulation Library / 12.7.3: |
Summary / 12.7.4: |
Future Outlook (Part III) |
Future Outlook |