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1 Machine Learning for Software-Defined Networking
1.1 Introduction of Software-Defined Networking
1.1.1 Software-Defined Wide Area Network
1.1.2 Software-Defined Data Center Networks
1.2 Introduction of Machine Learning Techniques
1.2.1 Deep Reinforcement Learning1.2.2 Multi-Agent Reinforcement Learning
1.2.3 Graph Neural Network
2 Deep Reinforcement Learning-based Traffic Engineering in SD-WANs
2.1 Introduction of Traffic Engineering
2.2 Motivation2.2.1 Problems of Existing Solutions
2.2.2 Opportunity
2.3 Overview of ScaleDRL
2.4 Design Details of ScaleDRL
2.4.1 Pinning Control in the Offline Phase
2.4.1.1 Pinning Control
2.4.1.2 Link Selection Algorithm
2.4.2 DRL Implementation of the Online Phase
2.4.2.1 DRL Framework2.4.2.2 Customization of Neural Networks and Interfaces
2.5 Performance Evaluation
2.5.1 Simulation Setup
2.5.2 Comparison Scheme
2.5.3 Simulation Results
2.6 Conclusion
3 Multi-Agent Reinforcement Learning-based Controller Load Balancing in SD-WANs
3.1 Introduction of Controller Load Balancing
3.2 Motivation
3.2.1 Problems of Existing Solutions
3.2.2 Opportunity
3.3 Controller Load Balancing Problem Formulation
2.3.1 Control Plane Resource Utilization Modeling
2.3.2 Control Plane Load Balancing Problem Formulation
2.3.3 Problem Complexity Analysis
3.4 Overview of MARVEL3.5 Design Details of MARVEL
3.5.1 Training Phase
3.5.2 Working Phase
3.5.3 MARVEL Model Implementation
3.6 Performance Evaluation
3.6.1 Simulation Setup
3.6.2 Comparison Scheme3.6.3 Simulation Results
3.7 Conclusion
4 Deep Reinforcement Learning-based Flow Scheduling for Power Efficiency in Data Center Networks
4.1 Introduction of Data Center Networks
4.1.1 Traffic Classification4.1.2 Traffic Dynamic Analysis
4.2 Motivation
4.2.1 Problems of Existing Solutions
4.2.2 Opportunity
4.3 Problem formulation
4.3.1 Design Considerations
4.3.2 Problem Formulation
4.4 Overview of SmartFCT
4.5 Design Details of SmartFCT4.5.1 Flow Information Collection
4.5.2 DRL Algorithm Framework
4.5.3 DRL Implementation Details
4.6 Performance Evaluation
4.6.1 Simulation Setup
4.6.2 Comparison Scheme
4.6.3 Simulation Results
4.7 Conclusion
5 Graph Neural Network-based Coflow Scheduling in Data Center Networks
5.1 Introduction of Coflow
5.2 Motivation
5.2.1 Problems of Existing Solutions
5.2.2 Opportunity
5.3 Problem Formulation
5.4 Overview of DeepWeave
5.5 Design Details of DeepWeave
5.5.1 DRL Framework for Training
5.5.2 Neural Network Implementation5.5.3 Policy Converter
5.6 Performance Evaluation
5.6.1 Simulation Setup
5.6.2 Comparison Scheme
5.6.3 Simulation Results
5.7 Conclusion
6 Graph Neural Network-based Flow Migration for Network Function Virtualization
6.1 Introduction of Network Function Virtualization
6.1.1 Network Function Virtualization
6.1.2 State Migration in NFV
6.2 Motivation
6.2.1 Problems of Existing Solutions
6.2.2 Opportunity
6.3 Flow Migration Problem Formulation
6.4 Overview of DeepMigration
6.5 Design details of DeepMigration
6.5.1 Training Framework
6.5.2 GNN-based Function Approximator6.5.3 Training Process
6.6 Performance Evaluation
6.6.1 Simulation Setup
6.6.2 Comparison Scheme
6.6.3 Simulation Results
6.7 Conclusion
7 Conclusion and Future work
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