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<ol><li>Fog Computing: Concepts & Recent Advances.- 1.1 Introduction.- 1.2 Fog Computing Architectures.- 1.2.1 Hierarchical Architecture Model.- 1.2.2 Layered Architecture Model.- 1.3 Computation Offloading in Fog Computing Architectures.- 1.4 Key Technologies for Future Fog Computing Architectures .- 1.4.1 Communication and Networking Technologies.- 1.4.2 Virtualization Technologies .- 1.4.3 Storage Technologies.- 1.4.4 Privacy and Data Security Technologies .- 1.5 Conclusions.- 2 Applications of Fog Computing.- 2.1 Introduction.- 2.2 Typical Applications of Fog Computing.- 2.2.1 Healthcare.- 2.2.2 Smart Cities.- 2.2.3 Smart Grid.- 2.2.4 Industrial Robotics and Automation in Smart Factories.- 2.2.5 Agriculture.- 2.2.6 Logistics and Supply Chains.- 2.3 Summary and Conclusions.- .- 3 Cooperation for Distributed Task Offloading in Fog Computing Networks.- 3.1 Introduction.- 3.2 System Model.- 3.2.1 Fog Computing Networks.- 3.2.2 Computation Tasks.- 3.2.3 Computation Offloading Model.- 3.3 Cooperation-based Task Offloading Models.- 3.4 Open Research Issues.- 3.4.1 Data Fragmentation.- 3.4.2 Distribution of Fog Networks.- 3.4.3 Advances of Distributed Algorithms.- 3.4.4 Comprehensive Performance Analysis.- 3.5 Conclusions.- .- 4 Fog Resource Aware Framework for Adaptive Task Offloading in Fog-based IoT Systems.- 4.1 Introduction.- 4.2 Related Works.- 4.3 System Model and Problem Formulation.- 4.3.1 System Model.- 4.3.2 Problem Formulation 4.4 FRATO: Fog Resource Aware Task Offloading Framework.- 4.4.1 Offloading Strategies for Minimizing Service Provisioning Delay.- 4.4.2 Mathematical Formulation of FRATO .- 4.4.3 Solution Deployment Analysis.- 4.5 Distributed Resource Allocation in Fog.- 4.5.1 Task Priority-based Resource Allocation .- 4.5.2 Maximal Resource Utilization based Allocation .- 4.6 Simulation and Performance Evaluation.- 4.6.1 Simulation Environment Setup .- 4.6.2 Comparative Approaches.- 4.6.3 Evaluation and Analysis.- 4.6.4 Further Analysis of Computation Time and Complexity .- 4.7 Conclusions.- 4.8 Future Works.- 4.8.1 Data Fragmentation .- 4.8.2 Distribution of Fog Networks.- 4.8.3 Advance of Optimization Algorithms.- 4.8.4 Comprehensive Performance Analysis.- .- 5 Dynamic Collaborative Task Offloading in Fog computing Systems.- 5.1 Introduction.- 5.2 Related Works.- 5.3 System Model and Problem Formulation.- 5.3.1 System Model.- 5.3.2 Computation Task Model.- 5.3.3 Problem Formulation.- 5.4 Optimization Problem for Minimization of Task Execution Delay .- 5.5 Simulation and Performance Evaluation .- 5.5.1 Simulation Environment Setup.- 5.5.2 Evaluation and Analysis.- 5.6 Conclusions and Future Works.- 6 Fundamentals of Matching Theory.- 6.1 Introduction.- 6.2 Basic Concepts and Terminologies .- 6.3 Classification.- 6.3.1 One-to-One (OTO) Matching.- 6.3.2 Many-to-One (MTO) Matching.- 6.3.3 Many-to-Many (MTM) Matching.- 6.3.4 Variants of Matching Models.- 6.4 Matching Algorithms.- 6.5 Conclusions.- 7 Matching Theory for Distributed Computation Offloading in Fog Computing Systems.- 7.1 Introduction.- 7.2 System and Offloading Problem Description .- 7.2.1 System Model.- 7.2.2 Computation Tasks .- 7.2.3 Computation Offloading Models.- 7.2.4 Optimization Problems of Computational Offloading .- 7.3 Proposed Matching-based Models for Distributed Computation .- 7.3.1 One-to-One (OTO) Matching.- 7.3.2 Many-to-One (MTO) Matching7.- 7.3.3 Many-to-Many (MTM) Matching.- 7.4 Challenges and Open Research Issues.- 7.4.1 Matching With Dynamics.- 7.4.2 Matching with Groups.- 7.4.3 Matching with Externality.- 7.4.4 Security and Privacy of Data and End Users.- 7.4.5 New Offloading Application Scenarios.- 7.4.6 Application of AI and ML-Based Techniques.- 7.5 Conclusions.- 8 Distributed Computation Offloading Frameworks for Fog Networks.- 8.1 Introduction.- 8.2 Preliminary and Related Works.- 8.2.1 Preliminary of Many-to-One (M2O) Matching Model.- 8.2.2 Related Works.- 8.3 System Model.- 8.3.1 Fog Computing Networks .- 8.3.2 Computation Offloading Model.- 8.4 Problem Formulation.- 8.5 Description of DISCO Framework.- 8.5.1 Overview.- 8.5.2 PL Construction.- 8.5.3 Matching Algorithms.- 8.5.4 Optimal Task Offloading and Communication Scheduling Algorithm.- 8.5.5 Stability Analysis.- 8.6 Simulations and Performance Evaluation .- 8.6.1 Simulation Environment Setup .- 8.6.2 Evaluation and Analysis .- 8.7 Conclusions .- 9 Reinforcement Learning-based Resource Allocations in Fog Networks.- 9.1 Introduction.- 9.2 Fog Computing Environment.- 9.2.1 System Model.- 9.2.2 Resource Allocation Problems in Fog Computing Systems.- 9.3 Reinforcement Learning.- 9.3.1 Basic Concepts.- 9.3.2 Taxonomy of RL Algorithms.- 9.4 RL based Algorithms for Resource Allocation in FC Systems.- 9.4.1 Resource Sharing and Management.- 9.4.2 Task Scheduling.- 9.4.3 Task Offloading and Redistribution.- 9.5 Challenges and Open Issues of RL-based Resource Allocations.- 9.5.1 RL-related Challenges.- 9.5.2 Fog Computing Environment related Challenges.- 9.5.3 Computation Task related Challenges.- 9.6 Conclusions and Discussions.- .- .- 10 Bandit Learning and Matching based Distributed Task Offloading in Fog Networks.- 10.1 Introduction.- 10.2 Bacground and Related Works.- 10.2.1 One-to-One Matching-based Task Offloading.- 10.2.2 Bandit Learning-based Computation Offloading.- 10.3 System Model.- 10.3.1 Fog Computing networks.- 10.3.2 Computation Offloading Model.- 10.4 Design of BLM-DTO Algorithm.- 10.4.1 OTO Matching Model for Computation Offloading.- 10.4.2 Multi-Player Multi-Armed Bandit with TS.- 10.5 Simulation Results and Evaluation Analysis.- 10.5.1 Simulation Environment Configuration.- 10.5.2 Comparative Evaluation and Analysis.- 10.6 Conclusions and Discussions.&nbsp;<br></li></ol>

<b>Dr. Hoa Tran-Dang</b> is research professor, working in the ICT-Convergence research center, in the department of IT convergence engineering at Kumoh National Institute of Technology (KIT). His research interests include Fog/Edge computing, Wireless Communication Networks, Resource Optimization, Machine Learning, and AI.<br><div><br></div><div><b>Prof. Dong-Seong Kim</b> is Director of Networked System Laboratory/ICT-Convergence Research Center (ITRC program), supported by the Korean government, at Kumoh National Institute of Technology, Gumi, South Korea. He is a senior member of the IEEE, and ACM. His research interests include real-time IoT, industrial wireless control network, networked embedded system and Fieldbus.<br></div>

This informative text/reference presents a detailed review of the state of the art in fog computing paradigm. In particular, the book examines a broad range of important cooperative and distributed computation algorithms, along with their design objectives and technical challenges.<p>The coverage includes the conceptual fundamental of fog computing, its practical applications, cooperative and distributed computation algorithms using optimization, swarm intelligence, matching theory, and reinforcement learning methods. Discussions are also provided on remaining challenges and open research issues for designing and developing the efficient distributed computation solutions in the next-generation of fog-enabled IoT systems.</p>

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Describes the innovative concepts of fog computing for the next-generation fog-enabled IoT Reviews the key distributed computation solutions for fog computing-based IoT systems Proposes a set of novel cooperative and distributed computation algorithms